Post-translational Modifications: The Signals at the Intersection of Exercise, Glucose Uptake, and Insulin Sensitivity

Ben Stocks; Juleen R Zierath

doi:10.1210/endrev/bnab038

. 2021 Nov 3;43(4):654–677. doi: 10.1210/endrev/bnab038

Post-translational Modifications: The Signals at the Intersection of Exercise, Glucose Uptake, and Insulin Sensitivity

Ben Stocks ¹, Juleen R Zierath ^2,^3,^✉

PMCID: PMC9277643 PMID: 34730177

Abstract

Diabetes is a global epidemic, of which type 2 diabetes makes up the majority of cases. Nonetheless, for some individuals, type 2 diabetes is eminently preventable and treatable via lifestyle interventions. Glucose uptake into skeletal muscle increases during and in recovery from exercise, with exercise effective at controlling glucose homeostasis in individuals with type 2 diabetes. Furthermore, acute and chronic exercise sensitizes skeletal muscle to insulin. A complex network of signals converge and interact to regulate glucose metabolism and insulin sensitivity in response to exercise. Numerous forms of post-translational modifications (eg, phosphorylation, ubiquitination, acetylation, ribosylation, and more) are regulated by exercise. Here we review the current state of the art of the role of post-translational modifications in transducing exercise-induced signals to modulate glucose uptake and insulin sensitivity within skeletal muscle. Furthermore, we consider emerging evidence for noncanonical signaling in the control of glucose homeostasis and the potential for regulation by exercise. While exercise is clearly an effective intervention to reduce glycemia and improve insulin sensitivity, the insulin- and exercise-sensitive signaling networks orchestrating this biology are not fully clarified. Elucidation of the complex proteome-wide interactions between post-translational modifications and the associated functional implications will identify mechanisms by which exercise regulates glucose homeostasis and insulin sensitivity. In doing so, this knowledge should illuminate novel therapeutic targets to enhance insulin sensitivity for the clinical management of type 2 diabetes.

Keywords: exercise, glucose, insulin, phosphorylation, ubiquitination, acetylation

Graphical Abstract

ESSENTIAL POINTS

Exercise training improves insulin sensitivity and glycemic control in type 2 diabetes.
Insulin and exercise regulate a range of phospho-signaling pathways to control insulin sensitivity, glucose uptake, and metabolism.
Exercise- and insulin-sensitive signals converge on the Rab GTPase-activating proteins TBC1 domain family member 1 (TBC1D1) and 4 (TBC1D4; aka AS160) to facilitate GLUT4 translocation and glucose uptake.
Exercise regulates the ubiquitination or ubiquitin-like modification of glycolytic enzymes in skeletal muscle.
Proteins involved in the regulation of skeletal muscle glucose metabolism are acetylated in response to insulin stimulation or exercise training.
Insulin and exercise regulate the ADP ribosylome and thereby regulate energy metabolism, glucose homeostasis, and insulin sensitivity.
A deeper understanding of the wider regulatory signals that control glucose homeostasis may lead to the development of novel therapeutic strategies to improve insulin sensitivity in type 2 diabetes.

Diabetes is a global epidemic, affecting approximately 451 million adults worldwide (9% of the adult population), of which approximately 90% of the cases are type 2 diabetes. This figure is rising and is predicted to continue to do so in the subsequent decades (1, 2). People with diabetes have an almost 2-fold increase in all-cause mortality, including increased risk of death from renal disease, liver disorders, cardiovascular disease, infectious diseases, multiple forms of cancer, and mental health disorders (3). These data indicate the urgent need to develop and implement effective strategies to prevent and treat type 2 diabetes.

Type 2 diabetes pathogenesis is multifaceted. Alongside a genetic component (4), type 2 diabetes has a number of lifestyle-related risk factors, including inactivity, overeating, and being overweight or obese (5-7). In terms of pathophysiology, type 2 diabetes is characterized by altered whole-body and tissue-specific metabolism, hyperglycemia, hyperinsulinemia, and peripheral insulin resistance. Insulin resistance in metabolically active tissues, including skeletal muscle, adipose tissue, and liver, impairs glucose disposal, which, alongside reduced insulin-mediated suppression of hepatic glucose production, results in hyperglycemia. As skeletal muscle is the predominant site for insulin-stimulated glucose disposal (8), insulin resistance in this tissue is critical to the development of type 2 diabetes (9, 10). Thus, interventions targeting skeletal muscle are effective at opposing type 2 diabetes pathogenesis.

Physical activity and exercise training improve insulin sensitivity and glycemic control in a range of populations, including those with obesity, prediabetes, or type 2 diabetes (11-16) (Fig. 1A). Indeed, lifestyle interventions that include exercise are effective at reducing the incidence of type 2 diabetes in individuals with elevated plasma glucose (17). Furthermore, diet and exercise intervention can lead to disease remission in a substantial proportion of the type 2 diabetic cases (18). For the purposes of this review, we will focus on the mechanisms by which endurance exercise (ie, moderate-intensity continuous exercise, high-intensity exhaustive exercise, and high-intensity interval training Fig. 1B) regulates glucose uptake and insulin sensitivity.

Figure 1. — Exercise training, insulin sensitivity, and glycemic control in type 2 diabetes. (A) Repeated endurance exercise training improves insulin sensitivity and glycemic control, often leading to type 2 diabetes remission. (B) Endurance exercise training is an umbrella term for various forms of exercise that lead to improvements in aerobic capacity. For example, endurance exercise encompasses moderate-intensity continuous exercise, in which a constant load is maintained for an extended period of time (ie, 50-70% Wmax for >30 minutes), high-intensity interval training, in which periods of high (ie, >90% Wmax), and low (ie, <50% Wmax) intensities are alternated for numerous intervals, and high-intensity exhaustive exercise, in which high-intensity exercise (ie, >80% Wmax) is performed to exhaustion.

Cellular Mechanisms of Exercise-induced Glucose Uptake and Insulin Sensitivity in Skeletal Muscle

Acute Exercise

Exercise causes a large increase in energy utilization (19). Carbohydrates, in the form of plasma glucose and skeletal muscle glycogen, are predominant fuel sources in moderate- to high-intensity exercise (19). Thus, acute exercise increases glucose uptake into skeletal muscle during exercise in an insulin-independent manner and post exercise via both insulin-dependent and -independent mechanisms to replenish skeletal muscle glycogen stores (20-27). The acute increase in skeletal muscle glucose uptake occurs through the modulation of activity and subcellular localization of a number of signaling proteins, enzymes, and transporters. Therefore, the focus of this review will be on these signals.

The discovery of glucose transporter type 4 (GLUT4) as an insulin- and contraction-responsive glucose transporter (28-35) has formed the basis for our understanding of glucose uptake in skeletal muscle. In unstimulated muscle (ie, at rest and without insulin stimulation) GLUT4 is predominantly sequestered intracellularly (36) and glucose delivery and transport are rate-limiting factors to glucose uptake. However, upon the commencement of exercise, elevated skeletal muscle blood flow (37) and translocation of GLUT4 to the sarcolemma and T-tubules (38-44) removes these barriers and increases glucose uptake. Exercise-induced signaling cascades (discussed in subsequent sections) likely increase the rate of exocytosis and decrease the rate of endocytosis of GLUT4 vesicles (45, 46), although direct data in relation to skeletal muscle contraction are missing. Nonetheless, we have demonstrated the importance of GLUT4 for exercise-induced insulin-independent glucose uptake, showing that GLUT4 knockout mice have substantially reduced ex vivo glucose uptake following swimming exercise and during in vitro muscle contraction (47). These data have subsequently been recapitulated in GLUT4 muscle-specific knockout mice (48) and in vivo (49). Importantly, and in contrast to insulin-stimulated conditions (9), exercise-induced glucose uptake and GLUT4 translocation is not impaired in type 2 diabetes (38, 50), making exercise an effective glucose-lowering intervention in patients with type 2 diabetes.

Exercise also acutely increases insulin sensitivity. One bout of endurance exercise increases insulin-stimulated glucose disposal and skeletal muscle glucose uptake during the gold standard hyperinsulinemic–euglycemic clamp for at least 48 hours (25, 51-56). Furthermore, acute exercise improves glucose tolerance in response to the more physiological oral glucose tolerance test (57). Prior exercise increases insulin-stimulated glucose uptake by augmenting insulin-induced skeletal muscle perfusion (58, 59) and glucose transport capacity of the myocyte (38-43, 60). In the initial hours after exercise (0-2 hours post exercise), the insulin sensitizing effects of acute exercise on the myocyte are likely explained by increased GLUT4 content on the plasma membrane (38-43), with subsequent exposure to insulin slowing the rate of GLUT4 internalization (61). However, in the absence of insulin, plasma membrane GLUT4 content levels return to baseline within ~2 hours of recovery (42). Thereafter, prior exercise enhances the translocation of GLUT4 in response to insulin (43), suggesting that exercise primes the internal pool of GLUT4 for insulin-action. Indeed, exercise results in the redistribution of GLUT4 into insulin-responsive GLUT4 storage vesicles, which can more readily be activated by insulin (60).

The insulin-sensitizing effects of exercise on skeletal muscle are influenced by nutritional status. Carbohydrate refeeding abolishes the postexercise increased insulin-stimulated glucose uptake in humans and rats (51, 62-65), an effect that is unrelated to caloric intake in rats (62-64). Indeed, carbohydrate refeeding ablates the increase in insulin-stimulated GLUT4 translocation 18 hours after exercise in rats (64). The increased insulin sensitivity with carbohydrate deprivation is associated with prolonged depletion of skeletal muscle glycogen content, which is rapidly restored during carbohydrate feeding (51, 62-64). Furthermore, humans with the glycogen storage disease McCardle’s syndrome, who cannot breakdown glycogen and have elevated skeletal muscle glycogen content, have impaired insulin-stimulated glucose uptake (66). These data indicate that carbohydrate availability can influence acute exercise-induced insulin sensitivity.

Chronic Exercise Training

Endurance exercise training improves whole-body and skeletal muscle insulin sensitivity (11-16, 67, 68). In skeletal muscle, enhanced insulin sensitivity following exercise training is underpinned by enhancements in glucose delivery and the capacity to uptake, utilize, and store glucose as glycogen. Increased capillary density of skeletal muscle following exercise training ensures improved nutrient supply (69), while augmented GLUT4 and hexokinase 2 abundance results in an increased capacity for glucose uptake and conversion to glucose-6-phosphate for utilization or storage as glycogen (68, 70-75). Furthermore, increased mitochondrial volume and respiratory capacity with exercise training increases the capacity for energy metabolism (67, 76-82), which potentially plays a role in promoting insulin sensitivity (67, 83, 84). An additional metabolic outcome of exercise training is an altered storage of intramyocellular lipids (85). Intramyocellular lipid content and lipid droplet size negatively correlate with insulin sensitivity (85-88). However, intriguingly, both athletes and individuals with type 2 diabetes have elevated intramuscular lipid accumulation, despite being on opposite ends of the insulin sensitivity continuum (86). An explanation for this apparent paradox lies in how these lipids are stored within skeletal muscle of individuals who are either exercise-trained or type 2 diabetic. Individuals with type 2 diabetes predominantly store lipids in large subsarcolemmal droplets in type II fibers, while athletes store lipids in small intramyofibrillar droplets close to the mitochondria of type I fibers (85). Encouragingly, 12 weeks of combined exercise training (endurance and resistance) can reduce lipid droplet size in individuals with type 2 diabetes (85). Thus, these data suggest that localization and size of lipid droplets are sensitive to physical activity level and can contribute to insulin sensitivity.

Overall, exercise increases glucose uptake and insulin sensitivity of skeletal muscle and these effects are primarily mediated by increased GLUT4 translocation. In subsequent sections, mechanisms by which intracellular signaling converge on GLUT4 to induce glucose uptake and sensitize skeletal muscle to insulin are discussed.

Post-translational Modifications at the Intersection of Exercise and Insulin Sensitivity

Post-translational modifications refer to reversible or irreversible chemical alterations to a protein that occur after translation. There is a wide range of post-translational modifications including phosphorylation, ubiquitination and ubiquitin-like modifications, various forms of acylation (eg, acetylation, succinylation, malonylation, and palmitoylation), ribosylation, and many more. Post-translational modifications are crucial in controlling the function of proteins, by regulating conformation, localization, stability, complexing, and activity. Therefore, post-translational modifications represent major intracellular (and likely extracellular) signals.

Despite decades of research into post-translational modifications and their regulatory role, the comprehensive understanding of this biochemistry is still evolving. The sheer number of different modifications and the likelihood of multiple modifications on each protein give rise to an exponential number of permutations for modifications on even a single protein. Indeed, multiple modifications on a protein likely cooperate to govern protein function, while a coordinated regulation of modifications in a network of proteins is required to regulate any given biological process. Nonetheless, the functional relevance of a considerable number of site-specific post-translational modifications are known within intracellular signaling pathways, including insulin signaling (89). Furthermore, advances in modification-specific proteomic technologies are rapidly advancing the mapping and cartography of various post-translational modifications on an “omics” scale (90).

Phosphorylation

Phosphorylation is the reversible addition of a phosphoryl group (PO₃^2–) to amino acids, principally serine, threonine, and tyrosine. Phosphorylation is the most well-characterized post-translational modification within intracellular signaling, particularly in response to insulin. Phosphorylation is pervasive across the proteome with an estimated 75% of proteins reported to be phosphorylated (91).

Signals transduced by phosphorylation are critical to insulin action (Fig. 2A). Upon insulin binding, the insulin receptor (INSR) undergoes autophosphorylation and subsequently phosphorylates insulin receptor substrate 1 (IRS1), leading to phosphatidylinositol 3-kinase (PI3K) activation. PI3K activates protein kinase B (AKT), via 3-phosphoinositide-dependent protein kinase 1 and mammalian target of rapamycin complex 2 (mTORC2), and ras-related protein Rac1 (RAC1), which transmit parallel signals to affect GLUT4 translocation (92-96). AKT phosphorylates the Rab GTPase-activating proteins Tre-2, Bub2, and Cdc16 (TBC)1 domain family member 1 (TBC1D1) and 4 (TBC1D4; aka AS160), which relieve their inhibitory action on GLUT4 translocating Rab GTPases (97-101). In concert, PI3K activation of RAC1 orchestrates actin remodeling at the plasma membrane via actin-related protein 2 (ARP2) and 3 (ARP3) and cofilin (94-96, 102-106).

Figure 2. — Insulin- and exercise-sensitive phospho-signaling in skeletal muscle. (A) Insulin stimulation induces autophosphorylation on the insulin receptor, which results in the recruitment and phosphorylation of IRS1, leading to PI3K activation (92). PI3K indirectly activates AKT via mTORC2 and PDK1 (92-94). AKT phosphorylates TBC1D1 and TBC1D4, which prevents their inhibition of the GLUT4 translocating Rab GTPases (97-101). Furthermore, AKT phosphorylates GSK3 leading to the activation of glycogen synthase (GS) and synthesis of glycogen. PI3K also activates RAC1, which promotes GLUT4 translocation via ARP2/3- and cofilin-mediated actin remodeling (95, 96). (B) Exercise regulates a range of phospho-signaling pathways. AMPK is phosphorylated and activated by CAMKK and liver kinase B1 (LKB1) (170, 255-259). AMPK orchestrates a shift towards catabolic processes: GLUT4 translocation is promoted via phosphorylation of TBC1D1 and TBC1D4 (97-99, 119, 123, 129), net glycogen breakdown via inhibition of GS (260), fatty acid oxidation via inhibition of acetyl-CoA carboxylase (ACC) (261), and inhibition of protein synthesis through negative regulation of mTORC1 activity (262). AMPK also promotes the expression of metabolic genes, including GLUT4, through myocyte enhancer factor 2 (MEF2) and peroxisome proliferator activated receptor gamma coactivator 1 alpha (PGC1α) activation (202, 263, 264), which can also be activated via CAMKII and p38MAPK (265-267). Accumulation of cyclic AMP (cAMP) activates PKA, which phosphorylates cyclic AMP-responsive element binding protein (CREB) and promotes transcription of metabolic genes (268, 269).

Acute exercise influences a substantial proportion of the phosphoproteome (107-109), with exhaustive high-intensity cycling regulating approximately 10% of the phosphoproteome within human skeletal muscle (108). Pathway enrichment analysis within this exercise-induced human skeletal muscle phosphoproteome has identified various phosphorylation pathways that were regulated by exercise, including those of the canonical exercise response kinases 5′-adenosine monophosphate–activated protein kinase (AMPK), mitogen-activated protein kinases (MAPKs), protein kinase A (PKA), mTOR, ribosomal protein S6 kinase (p70S6K) and Ca²⁺/calmodulin-dependent protein kinases (CAMKs) (Fig. 2B), as well as pathways related to insulin signaling such as INSR, PI3K, AKT, and Rho signaling pathways (108). Indeed, the endurance exercise/contraction-induced regulation of these pathways are typically highly conserved across different species (ie, human, rat, and mouse) (107).

For the most part, exercise alone does not influence the activity of proximal proteins within the insulin signaling cascade (24, 44, 110-112), although phosphorylation of IRS1 at Ser 36, Ser 374, Ser 560, Ser 629, and Ser 1100 is increased following an exhaustive bout of high-intensity cycling (108). Nonetheless, insulin receptor knockout or inhibition of PI3K does not impair glucose uptake during exercise or contraction (24, 113, 114). Thus, alternative mechanisms must regulate contraction-induced insulin-independent glucose uptake. However, the insulin-induced activity of proteins within the proximal insulin signaling pathway (eg, PI3K and AKT) can be augmented following exercise in vivo (24, 44, 110, 112), although this is a far from consistent finding (54, 55, 113, 115, 116). Indeed, augmented proximal insulin signaling would be consistent with increased skeletal muscle blood flow and insulin delivery post exercise (58, 59).

Exercise and contraction per se increase the phosphorylation of TBC1D4 on multiple sites (Ser 318, Ser 341, Ser 588, Ser 600, Thr 642, Ser 704, and Ser 751) (107, 108, 117-122), although decreased phosphorylation of sites on TBC1D4 (Ser 318, Ser 597, Ser 666, and Thr 642) has also been reported immediately post exercise (107, 108). These apparent inconsistencies may be reflective of differences in the methodology of measurement (eg, total phosphorylation of TBC1D4 vs phospho-site–specific changes), the species, the exercise intensity, and/or the postexercise timepoint investigated. For example, although a time course analysis has yet to be performed within a single investigation in humans, phosphorylation of TBC1D4 on Ser 318 and Thr 642 decreases immediately after high-intensity exhaustive cycling (108), while it is increased 4 hours after 1 hour of single-legged kicking at 80% of peak power output (117), indicating a possible temporal regulation. In addition to phosphorylation by AKT, TBC1D4 is also a target of AMPK (119, 123). AMPK is activated during exercise via phosphorylation of the catalytic α-subunit on Thr 172 (107, 108, 120, 124-128), subsequently phosphorylating TBC1D4. AMPK also phosphorylates TBC1D1, another Rab inhibiting enzyme (97-99, 129), with the phosphorylation of TBC1D1 increased at Ser 108, Ser 159, Ser 231, Ser 301, Ser 614, Ser 660, and Ser 700 during exercise and contraction (97, 107, 108, 130). Phosphorylation of TBC1D1 and TBC1D4 persist for hours after exercise (115, 117, 121), potentially priming these proteins for further inhibition by insulin, thereby augmenting Rab GTPase activity. Indeed, insulin-induced TBC1D1 and TBC1D4 phosphorylation is augmented in the hours following an acute bout of exercise (115, 117, 121, 122, 131). Thus, TBC1D1 and TBC1D4 may represent a convergence point for insulin- and exercise-induced signals to promote GLUT4 translocation and glucose uptake (Fig. 3).

Figure 3. — Exercise- and insulin-sensitive signals converge on TBC1D1 and TBC1D4 to facilitate GLUT4 translocation. Exercise- and insulin-signaling cascades converge on TBC1D1 and TBC1D4. Insulin promotes AKT-mediated phosphorylation of TBC1D1 and TBC1D4, while AMPK and CAMKII mediate the exercise-induced phosphorylation of TBC1D1 and TBC1D4 on independent and overlapping sites to those targeted by AKT. Yellow phospho-sites represent insulin-induced phosphorylation. Red phospho-sites represent exercise-induced phosphorylation.

The importance of the AMPK–TBC1D1/TBC1D4 axes for increased glucose uptake and insulin sensitization has been demonstrated in the postexercise period. Knockout of AMPK isoforms impairs elevated glucose uptake following contraction and reduces the insulin-sensitizing effects of prior exercise and contraction (132-137). Furthermore, humans harboring a rare AMPK-activating mutation (R225W) display a trend toward elevated exercise-induced glucose uptake during a period that spanned exercise and recovery (138). Knockout of TBC1D1 reduces skeletal muscle glucose uptake following exercise (139, 140), while TBC1D4 is required for exercise to enhance skeletal muscle insulin sensitivity 3 hours after contraction (130). Electroporation of nonphosphorylatable TBC1D1/TBC1D4 mutants also impair contraction-stimulated glucose uptake (97, 123, 141). However, glucose uptake during contraction and exercise is normal in AMPKα1α2 and TBC1D1 knockout mice (140, 142). Furthermore, exercise-induced glucose uptake precedes the activation of AMPK in humans (143), while moderate-intensity exercise increases whole-body glucose disposal in the absence of AMPK activation after short-term exercise training in humans (144). Together, these data indicate that while AMPK and TBC1D1/TBC1D4 are critical in the regulation of glucose uptake and insulin sensitivity in the postexercise period, these signaling axes are not required for the increase in glucose uptake during contraction and exercise. However, whether these data point towards a limited involvement of AMPK in glucose uptake during exercise or a substantial redundancy with other pathways within this physiological system remains up for debate.

An additional target of AMPK is the phosphoinositide kinase, FYVE-type zinc finger containing (PIKFYVE) protein. Phosphorylation of PIKFYVE increases during ex vivo contraction, which occurs alongside the translocation of PIKFYVE to intracellular membranes (145). Although specific phosphorylation site(s) and upstream kinase(s) remain to be elucidated with respect to contraction, AMPK phosphorylates PIKFYVE on Ser 307, which promotes PIKFYVE colocalization with endosomes (145). Inhibition of PIKFYVE reduces insulin, contraction, and 5-aminoimidazole-4-carboxamide-1-β-D-ribofuranoside (AICAR)-stimulated glucose uptake in vitro (145), while skeletal muscle-specific knockdown of PIKFYVE reduces insulin-stimulated glucose uptake in soleus and extensor digitorum longus muscles (146). Nonetheless, the specific mechanism of PIKFYVE-mediated glucose uptake remains unclear. Furthermore, the phosphorylation of Ser 307 remains unchanged following endurance exercise in humans and mice (107, 108). Thus, the relevance of PIKFYVE to exercise-induced glucose uptake in vivo remains elusive.

AMPK may provide the link between glycogen content and glucose uptake into skeletal muscle. Exercise-induced AMPK activity and Thr 172 phosphorylation correlate with glycogen content in skeletal muscle (147-154). Indeed, AMPK physically binds to glycogen via its β-subunit (155-159). Autophosphorylation of AMPKβ on Thr 148, which lies in the carbohydrate binding domain, releases the AMPK complex from glycogen (157-159), increasing free AMPK and enhancing the activating phosphorylation of Thr 172 on the catalytic α-subunit. Glucose uptake, GLUT4 translocation, and AMPK activity are elevated when contraction is commenced with low glycogen in murine fast-twitch muscle (153, 154, 160). However, contraction increases glucose uptake independently of glycogen content and AMPK activation in slow-twitch muscle (153, 154). Therefore, while AMPK activation and glycogen content may regulate glucose uptake in fast-twitch muscle, AMPK is not the only regulator of exercise- or contraction-induced glucose uptake in skeletal muscle. The picture regarding glycogen content and exercise-induced glucose uptake is further complicated when considering data from human studies. When exercise was commenced with low skeletal muscle glycogen content, induced by 1-legged glycogen-depleting exercise performed the previous evening (16 hours prior), glucose uptake during exercise was enhanced in the prior exercised leg (low glycogen) compared with the control leg (normal glycogen) (161). However, when the same degree of glycogen depletion was induced by dietary means (ie, no prior exercise), leg glucose uptake during the first 90 minutes of exercise was not different between high and low carbohydrate (glycogen) trials. In fact, glucose uptake was reduced in the low carbohydrate trial (low muscle glycogen) after 120 minutes of exercise, likely owing to the low systemic glucose availability (161). However, the effects of skeletal muscle glycogen concentration are difficult to isolate from the confounding effects of prior exercise and dietary manipulation, including altered circulating metabolites and hormones. Therefore, the influence of glycogen on exercise-induced glucose uptake remains controversial.

Contraction of skeletal muscle is initiated by Ca²⁺ release from the sarcoplasmic reticulum. In addition to initiating contraction, elevated Ca²⁺ concentrations are sensed by CAMKs. The transduction of signals through this cascade are mediated by phosphorylation. Exercise increases the autophosphorylation of CAMKII on Thr 286, which is highly correlated with CAMKII activity in human skeletal muscle (162-164), and on a number of additional phospho-sites on various CAMKII subunits (107, 108). The activation of CAMKII may be necessary for contraction-induced glucose uptake. Inhibition of CAMKII reduces contraction-induced glucose uptake and GLUT4 translocation (165-167). Furthermore, inhibition of calmodulin and Ca²⁺/calmodulin-dependent protein kinase kinase (CAMKK), an upstream kinase of CAMKII, impairs contraction-induced glucose uptake (168, 169), an effect that may be partially mediated by reduced CAMKK phosphorylation of AMPK (166, 170). CAMKII- and AMPK-mediated glucose uptake are independent but not additive, suggesting a downstream convergence of these pathways (167). Indeed, similarly to AMPK, knockdown of CAMKII reduces the contraction-induced phosphorylation of TBC1D1 on Ser 231 and TBC1D4 on Thr 642 (167), providing a putative mechanism for CAMKII-mediated GLUT4 translocation and glucose uptake.

Ubiquitination and Ubiquitin-like Modifications

Protein turnover is critical for quality control and cellular homeostasis. Degradation is under the control of autophagy and the ubiquitin-proteasome system, both via ubiquitin signaling. Ubiquitin is a small 8.6 kDa protein that can be attached to proteins, principally via lysine residues. Protein ubiquitination is regulated by a 3-step cascade; ubiquitin activation by ubiquitin-activating (E1) enzymes, conjugation by ubiquitin-conjugating (E2) enzymes and ligation by ubiquitin-ligases (E3 ligases). In the ubiquitin-proteasome system the 26S proteasome recognizes, unfolds, and degrades short-lived proteins with K48-linked polyubiquitin chains. In addition, multiple other chains of ubiquitination and ubiquitin-like modifications occur, such as NEDDylation, allowing for a diversity of signals including enzyme activation and sub-cellular localization. Thus, ubiquitination is a major post-translational modification in the control of cellular homeostasis.

Dysregulation of the ubiquitin–proteasome system is implicated in the pathogenesis of many diseases (171), including type 2 diabetes (172-175). Aberrant ubiquitination in beta-cells impairs insulin secretion (176), while dysregulated ubiquitin–proteasome system activity in peripheral tissues (eg, liver and skeletal muscle) inhibits insulin-stimulated glucose metabolism (174), mitochondrial function (177), and muscle mass (178). Using 2-dimensional difference gel electrophoresis mass spectrometry we have identified dysregulated ubiquitin–proteasome system proteins within primary myotubes from individuals with type 2 diabetes, such as the proteasomal subunits alpha 1 (PSMA1), alpha 6 (PSMA6), and beta 2 (PSMB2) (179). Furthermore, siRNA silencing of PSMA1, PSMA6, and PSMB2 and proteasomal inhibition in human primary myotubes impaired basal and insulin-stimulated glucose incorporation into glycogen, recapitulating the diabetic phenotype (179). Indeed, there is growing evidence for the regulatory role of ubiquitination in the insulin signaling pathway (172). For example, INSR is ubiquitinated by multiple E3 ligases resulting in a diversity of signals mediating receptor internalization as well as proteasomal and lysosomal degradation (174, 180-182). Consequently, the metabolic role of several ligases and deubiquitinases has been investigated. For example, skeletal muscle overexpression of tripartite motif-containing protein 72 (MG53) induces insulin resistance via the degradation of INSR and IRS1 (174), while kelch-like ECH-associated protein 1 (KEAP1) knockdown stabilizes nuclear factor erythroid 2–related factor 2 (NRF2) and activates the NRF2 gene program, opposing the development of type 2 diabetes (175).

Acute endurance exercise alters proteasome activity and the skeletal muscle ubiquitinome (183, 184). Exhaustive high-intensity cycling activates the 26S proteasome through PKA-mediated phosphorylation of 26S proteasome non-ATPase regulatory subunit 11 (PSMD11) on Ser 14, which leads to a reduction in global ubiquitination (108, 183, 184) as damaged proteins are degraded. CAMKII can also regulate proteasomal activity via phosphorylation of 26S proteasome regulatory subunit 8 (PSMC5), albeit in HEK293T cells (185), providing an additional hypothetical avenue of contraction-regulated proteasomal activation. Furthermore, these data indicate the interplay between phosphorylation and ubiquitination in controlling protein degradation.

The effect of high-intensity exercise (~10 minutes of cycling at 77% to 88% Wmax to exhaustion) on ubiquitination and ubiquitin-like modifications in skeletal muscle was investigated by enrichment of K-GG (lysine-glycine/glycine)–modified peptides followed by mass spectrometry (184). During digestion by trypsin, ubiquitin and ubiquitin-like modifications are cleaved at their initial arginine, leaving a K-GG remnant on the modified peptide, which can be enriched by immunoprecipitation and detected by mass spectrometry (186). This poses a unique challenge when studying ubiquitination and ubiquitin-like modifications in this manner as the specific type of modification (eg, ubiquitin, NEDD8, or ISG15) cannot be discriminated, nor can chain length or branching be determined. Of the 1536 quantified K-GG-modified sites, 391 were regulated immediately after exercise (275 downregulated and 116 upregulated), with all sites returning to pre-exercise levels within 2 hours of recovery (184). Ubiquitin itself displayed site-specific regulation following exercise, with K-GG motifs decreased on K6, K11, K29, K48, and K63, while K27 increased, suggesting that exercise may differentially regulate specific ubiquitin chains (184).

Enriched within the proteins with regulated K-GG sites were proteins related to glycolysis (184). To illuminate how ubiquitin and ubiquitin-like modifications may regulate glucose homeostasis we reinterrogated this dataset with a specific focus on glucose metabolism and insulin signaling. INSR is ubiquitinated on Ser 1057 in human skeletal muscle, although this was not quantified sufficiently to assess the effect of exercise on this modification. The glycolytic proteins with exercise-regulated ubiquitination included fructose biphosphate aldolase a (ALDOA), beta-enolase (ENO3), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), phosphoglycerate mutase 1 (PGAM1), and phosphoglycerate mutase 1 (PGAM2) (Fig. 4). Of the regulated sites, ubiquitination was typically downregulated on these proteins, pointing towards a stabilization of glycolytic enzymes during high-intensity exercise. Aldolase also plays a regulatory role in GLUT4 translocation (187). Aldolase interacts with GLUT4 in 3T3L1 adipocytes, regulating the interaction between GLUT4 and filamentous actin and consequently insulin-stimulated GLUT4 exocytosis (187). Furthermore, calcium promotes the binding of aldolase to the cytoskeleton in skeletal muscle (188). Deubiquitination of glycolytic enzymes including ALDOA and GAPDH is mediated by joshepin-2 in cancer cells, which stabilizes these enzymes and promotes glycolysis (189). However, whether joshepin-2 is responsible for the deubiquitination of glycolytic enzymes during exercise remains unknown. Future investigations should delineate the specific ubiquitin and/or ubiquitin-like modifications on glycolytic enzymes that are regulated by exercise, as well as the ligases and/or deubiquitinating enzymes that mediate these effects.

Figure 4. — Exercise regulates the ubiquitination or ubiquitin-like modification of glycolytic enzymes in skeletal muscle. Glycolytic enzymes are enriched within proteins with K-GG remnants (ubiquitin and ubiquitin-like modifications) regulated by exercise (184). K-GG remnants on ALDOA, GAPDH, PGAM1, PGAM2, and ENO3 are regulated by exercise. Blue ubiquitin sites represent K-GG remnants downregulated by exercise. Red ubiquitin sites represent K-GG remnants upregulated by exercise.

AMPKα2 is ubiquitinated by the E3 ligases MG53 and E3 ubiquitin-protein ligase makorin-1 (MKRN1) leading to degradation (190, 191). Ubiquitination of AMPKα is increased in skeletal muscle of obese mice, while high glucose availability induces MG53-mediated degradation of AMPKα (190). Stabilization of AMPK via knockout of MKRN1 increases glucose uptake in mouse embryonic fibroblasts, while MKRN1 knockout mice display resistance to high fat diet–induced metabolic syndrome (191). Phosphorylation of AMPKα2 on Ser 491, a site of autophosphorylation and the target site of p70S6K1 (192, 193), is required for the interaction between AMPK and MG53, and the subsequent ubiquitin-mediated degradation of AMPKα2 (190). Indeed, phosphorylation of AMPKα2 on Ser 491 is inhibitory in biological systems (190, 192). Interestingly, acute endurance exercise and contraction increases phosphorylation of AMPKα2 on Ser 491 (107-109), advancing the hypothesis that AMPKα2 is ubiquitinated and degraded during exercise. Despite this, the AMPK complex was still activated following exercise (as assessed by the downstream phosphorylation of target proteins) (108), suggesting that Ser 491 either has additional functions or that activating phosphorylation (Thr 172) outweighs inhibitory phosphorylation (Ser 491) on AMPK during exercise.

Evidence is emerging for an interplay between phosphorylation, ubiquitination, and NEDDylation during exercise (184). Global NEDDylation increases and ubiquitination decreases in response to exercise and forskolin-stimulated PKA activation, with ubiquitination returning to baseline within 1 to 2 hours. However, when NEDDylation is inhibited, ubiquitination remains depressed following forskolin treatment, indicating that NEDDylation is required for the activation of E3 ligases to promote ubiquitination and continued flux through the ubiquitin–proteasome system (184). Nonetheless, whether and indeed how this interplay may influence insulin sensitivity remains unclear.

Acylation

Acylation is the process of adding an acyl group to a compound (eg, a protein), of which there are various forms, including succinylation, malonylation, palmitoylation, and more. The most well-studied form of protein acylation is acetylation. Acetylation is the reversible addition of an acetyl group from acetyl-coenzyme A (CoA) to an amino acid, the best characterized being lysine. Acetyltransferases catalyze the transfer of acetyl groups to the ε-amino acid side chain of lysine, while deacetylases remove them. Alternatively, acetylation can occur nonenzymatically from acetyl-CoA. Initially identified on histones, acetylation is pervasive across the proteome. In skeletal muscle, mitochondrial proteins, in particular those of the tricarboxylic cycle and the electron transport chain, make up the majority of acetylated proteins and also show elevated acetylation stoichiometry (194, 195). Furthermore, acetylation is sensitive to the cellular energetic state (196, 197), potentially linking metabolic flux to protein function and enzyme activity.

A regulatory role for acetylation on various components of the insulin signaling cascade has been reported (198) (Fig. 5). For example, the class I and II histone deacetylase inhibitor trichostatin A increases insulin-stimulated glucose uptake and glycogen synthesis in C2C12 cells via increased phosphorylation of INSR Tyr 1146, AKT Ser 473, and glycogen synthase kinase-3 beta (GSK3β) Ser 9 (199). Furthermore, insulin reduces the acetylation of AKT in skeletal muscle of fasted, but not fed, mice (200). However, acetylated peptides from proteins within the insulin signaling pathways have mostly been undetectable via mass spectrometry-based proteomics performed in rat and human skeletal muscle (194, 195), which might reflect technical challenges in their enrichment or their low abundance/absence. Conversely, proteins involved in glycolysis are abundantly acetylated within skeletal muscle (194, 195).

Figure 5. — Acetylation and palmitoylation in insulin signaling, GLUT4 translocation, and mitochondria. Acetylation and palmitoylation are apparent on numerous proteins in the insulin signaling cascade. Palmitoylation of GLUT4 by the palmitoyltransferase DHHC7 is critical for insulin-stimulated membrane translocation in adipocytes. Mitochondrial proteins are highly acetylated in skeletal muscle. Endurance exercise increases mitochondrial protein acetylation, including PDH, which the mitochondrial deacetylase SIRT3 opposes. Acetylation of PDH may regulate the flexibility between glucose and fatty acid oxidation. Exercise also increases histone acetylation, concomitant with the nuclear export of HDAC5, which may play a role in MEF2 activation and GLUT4 transcription.

In accordance with the initial characterization of acetylation on histones, this process also plays a regulatory role in transcription. Acetylation of histones can regulate chromatin conformation and therefore accessibility of regulatory factors (ie, transcription factors, coactivators and repressors) to DNA (201). As such, acetylation is likely to be involved in the transcriptional control of insulin sensitivity and the adaptive responses to exercise training. For example, dissociation of histone deacetylase 5 (HDAC5) from the transcription factor myocyte enhancer factor 2 (MEF2) and the MEF2 binding domain of the GLUT4 gene promoter induces GLUT4 transcription in human primary myotubes, an effect that is regulated by AMPK-mediated phosphorylation of HDAC5 (202). In vivo, skeletal muscle–specific knockout of histone deacetylase 3 (HDAC3) and loss of HDAC3 deacetylase activity impairs insulin sensitivity, although paradoxically this occurs alongside an increase in exercise capacity (203, 204). Furthermore, the deacetylase activity of sirtuin 1 (SIRT1), which has been proposed as a central regulator of mitochondrial biogenesis in skeletal muscle via its ability to regulate PGC1α cotranscriptional activity (205), is required for the insulin sensitizing effects of calorie restriction (206). Conversely, overexpression of SIRT1 does not prevent high-fat diet induced insulin resistance (207), while SIRT1 is also dispensable for contraction-induced glucose uptake (208) and the mitochondrial adaptations to exercise training (209). Metabolism and the development of insulin resistance are also predominantly unaffected by the individual knockout of nuclear-localized acetyltransferases. For example, skeletal muscle-specific deletion of general control of amino acid synthesis protein 5 (GCN5), which opposes SIRT1 by transferring an acetyl moiety to PGC1α, does not influence the metabolic adaptations to endurance exercise training (210). Furthermore, skeletal muscle-specific knockout of E1A binding protein p300 (p300) or CREB-binding protein (CBP) do not influence skeletal muscle insulin sensitivity (211), while p300 is not required for the metabolic adaptations to endurance exercise training (212). However, skeletal muscle-specific double knockout of p300 and CBP is lethal even when induced in adult mice (213), demonstrating both the importance of acetylation and the inherent redundancy within these systems. The series of studies identifying no discernible phenotype with individual knockout of p300 and CBP, but lethality with double knockout (211-213) also serve to highlight the experimental difficulty in probing these complex physiological systems.

Evidence for a role of acetylation in regulating skeletal muscle glucose metabolism and insulin sensitivity in vivo predominantly come from knockout and transgenic mouse models in which hyperacetylation of mitochondrial proteins are induced. Elevations in skeletal muscle acetylation can be achieved by individual and combined knockout of proteins controlling acetyl-CoA buffering (carnitine acetyltransferase; CrAT) and mitochondrial lysine acetylation (sirtuin 3; SIRT3) (197). Indeed, mice with skeletal muscle hyperacetylation display increased susceptibility to diet-induced insulin resistance (197, 214-216). However, this effect is independent of insulin signaling and GLUT4 translocation (216). The defect may lie at the level of glucose oxidation, which is reduced in skeletal muscle of SIRT3 knockout mice (217). Indeed, pyruvate dehydrogenase E1 component subunit alpha (PDH E1a) is hyperacetylated on Lys 336 and its enzyme activity is suppressed in SIRT3 knockout mice (217). Furthermore, pyruvate-linked respiration is impaired in CrAT knockout mice (214). By catalyzing the reaction of pyruvate to acetyl-CoA, PDH provides the link between glycolysis and the tricarboxylic acid cycle, and therefore the flexibility between carbohydrate and fat metabolism (218). Given that the product of PDH activity is acetyl-CoA, it is probably unsurprising that acetylation can mediate a negative feedback loop, preventing excess acetyl-CoA production from glucose metabolism.

In spite of mitochondrial acetylation being linked to insulin resistance (197, 214-216), we have shown that 5 weeks of high-intensity interval training increases acetylation within human skeletal muscle, predominantly within the mitochondria (195). Furthermore, increased acetylation of PDH E1a on Lys 336 was within the top 5 most regulated acetyl sites with exercise training (195). As exercise training increases insulin sensitivity (11-16), elevated acetylation within skeletal muscle is unlikely to cause insulin resistance. Rather, physiological hyperacetylation of PDH E1a may play a role in the increased preference for fatty acid oxidation following exercise training, which likely opposes the development of insulin resistance. Indeed, mitochondrial hyperacetylation increases the capacity for mitochondrial fatty acid metabolism (197).

In contrast to chronic exercise in humans, acute exercise in rodents decreases mitochondrial acetylation in skeletal muscle, particularly targets of the mitochondrial deacetylase SIRT3 (196). Whether acute exercise regulates the acetylome in human skeletal muscle remains to be determined.

However, targeted analysis of individual acetyl sites suggests that, in contrast to rodents (196, 209), SIRT1 and SIRT3 are not activated during moderate-intensity endurance exercise in humans, nor is pan-acetylation regulated by acute exercise (219). Sirtuins are an NAD⁺-dependent class of protein deacetylases. The discrepancy in exercise-induced sirtuin activation between rodents and humans likely arises from differences in NAD⁺ flux during exercise. In rodents, NAD⁺ increases during swimming exercise (220), while skeletal muscle NAD⁺ content remains unchanged during exercise in humans (219, 221-223). However, acetylation of histone 3 Lys 36 is increased immediately after 1 hour of moderate-to-high intensity cycling, which occurred concomitantly with a reduced nuclear abundance of HDAC4 and HDAC5, the latter of which was ubiquitinated by exercise (224). Further investigation into the skeletal muscle acetylome following acute exercise in humans is warranted, particularly as acetylation is regulated by numerous NAD⁺-dependent and -independent deacetylases and acetyltransferases, as well as via nonenzymatic mechanisms, of which many are yet to be investigated during exercise in human skeletal muscle.

One major consideration when assessing the contribution of protein acetylation to metabolic control is that acetylation stoichiometry is very low, even on mitochondrial proteins. In the liver, median acetyl stoichiometry is 0.05%, increasing to 0.11% in mitochondria (225). Thus, whether a relatively modest reduction or a chronic doubling (median fold change) in acetylation is sufficient to alter metabolism remains questionable. Nonetheless, physiological levels of mitochondrial malate dehydrogenase acetylation negatively correlate with its enzyme activity (196), indicating that acetylation can regulate the activity of individual metabolic enzymes in vivo.

In addition to acetylation, various other forms of acylation can modify lysine residues on proteins. Proteins can be post-translationally modified by succinylation, malonylation, glutarylation, and palmitoylation (226, 227). Like acetyl-CoA, the acyl substrates for these modifications (succinyl-CoA, malonyl-CoA, glutaryl-CoA, and palmitoyl-CoA) can be regulated by cellular energy status, exercise, insulin, and type 2 diabetes (228-231). As many of these modifications are directly related to fatty acid availability and oxidation, acylation is likely to be substantially disturbed in conditions of excess nutrient supply such as in obesity and type 2 diabetes.

The functional role of palmitoylation in the regulation of insulin-sensitive proteins has been explored, predominantly in adipocytes. Palmitoylation of cysteine residues occurs via reversible transfer of palmitate by palmitoyltransferases and removal by protein palmitoyl thioesterases. Palmitoylation adds a hydrophobic moiety to a protein that serves as a lipid anchor, aiding the membrane localization of proteins, thus it is of considerable interest in the context of glucose transport. Proteomic and targeted analyses of palmitoylated proteins in 3T3L1 adipocytes revealed palmitoylation of GLUT4, proteins involved in GLUT4 translocation (eg, vesicle associated membrane protein 2, TBC1D4, and ras-related protein rab14), and related signaling cascades (eg, AMPKα) (226). GLUT4 palmitoylation has subsequently been confirmed in skeletal muscle (232). Palmitoylation of GLUT4 at Cys 233 by palmitoyltransferase zinc finger DHHC-type containing 7 (DHHC7) is critical for insulin-stimulated membrane translocation (232, 233). Indeed, silencing of DHHC7 or serine substitution of Cys 233 (that cannot undergo palmitoylation) ablates GLUT4 translocation in 3T3L1 and primary adipocytes (232, 233). While it is currently unclear whether this mechanism translates to skeletal muscle, the regulation of skeletal muscle palmitoylation in response to insulin and exercise should be of considerable interest owing to its demonstrated role in GLUT4 translocation in adipocytes.

Adenosine Diphosphate Ribosylation

Adenosine diphosphate (ADP) ribosylation is a post-translational modification in which ADP ribose moieties are cleaved from NAD⁺ and covalently transferred to proteins either as mono-ADP-ribosylation (MARylation) or poly-ADP-ribosylation (PARylation). Poly-ADP ribose polymerases (PARP) 1 and 2 are enzymes whose nuclear poly-ADP-ribosylation activity regulate energy metabolism, glucose homeostasis and insulin sensitivity (234-237). However, as PARPs are NAD⁺ consumers, much of the metabolic adaptations resulting from altered PARP activity have been attributed to modulation of sirtuin activity, particularly SIRT1 (234-237), rather than ADP ribosylation per se. Nonetheless, ADP ribosylation is pervasive across the proteome and in various cellular compartments, with ADP ribosylation detected on proteins from various metabolic pathways within skeletal muscle (238, 239). Tankyrases (TNKSs) are a predominantly cytosolic family of PARP enzymes that may more directly regulate metabolism (Fig. 6). In humans, the TNKS gene, which encodes TNKS1, lies within a susceptibility locus for type 2 diabetes (240), and TNKS gene variants are associated with early-onset obesity (241). Oral dosing with the TNKS inhibitor G007-LK improves glucose tolerance and insulin sensitivity independently of body and fat mass in mice fed a high-fat diet (242). In obese diabetic db/db mice, G007-LK reduces body mass gain, fat mass and hepatic steatosis, which occurred alongside increased mitochondrial protein content and fatty acid oxidation in skeletal muscle (243). TNKS1/2 interacts with, and PARylates, PGC1α in skeletal muscle, which was speculated to mediate the effects on energy metabolism (243). In adipocytes, TNKS interacts with leucyl-cistinyl aminopeptidase (IRAP) on GLUT4 storage vesicles, and insulin induces MAPK-mediated phosphorylation of TNKS that increases the PARylation of IRAP (244). Furthermore, knockdown and inhibition of TNKS impairs GLUT4 translocation (245). Thus, PARylation, and in particular TNKS, can regulate metabolism and insulin sensitivity.

Figure 6. — ADP ribosylation via the TNKS family of PARPs may regulate metabolism via GLUT4 translocation and inhibition PGC1α. TNKS ADP-ribosylates the GLUT4 storage vehicle-related protein IRAP and inhibition of TNKS PARP activity impairs GLUT4 translocation in adipocytes. Conversely, TNKS impairs skeletal muscle oxidative metabolism via PGC1α PARylation and degradation.

To date, investigations into the effect of exercise on ADP ribosylation have primarily focused upon PARylation and PARP1 activation. In skeletal muscle, global PARylation increases following electrically evoked isometric contractions in mice (246), whereas autoPARylation of PARP1 is unaffected by moderate-intensity cycling in humans (247). PARP1 protein content increases following an acute bout of high-intensity interval training in young healthy males (248), and displays a trend to increase following moderate intensity exercise in a similar cohort (247). Conversely, in older individuals high-intensity interval training acutely decreases PARP1 protein content (248). Thus, while some studies have investigated PARylation in response to exercise this remains an immature field. Future studies should take advantage of emerging proteomic technologies to investigate how insulin and exercise regulate the ADP ribosylome (238, 239).

Future Directions

Despite the wealth of data collected regarding insulin signal transduction, and the interplay with exercise-sensitive cascades, the understanding of the signals that mediate exercise-induced glucose uptake and insulin sensitization is limited. Indeed, the identity of the signals that mediate glucose uptake during exercise remain unclear. Furthermore, the knowledge of signals transduced from insulin and exercise via post-translational modifications, aside from phosphorylation, is sparse. Future research efforts should be directed at decoding the diversity of ubiquitin and ubiquitin-like signals on metabolic enzymes, transporters, and signaling proteins. In addition, how fluxes in acyl-metabolites regulate protein acylation and consequently metabolism during exercise is of considerable interest, particularly in the context of palmitoylation and GLUT4 translocation. Furthermore, while the functional implications of canonical post-translational modifications in insulin- and exercise-sensitive signaling cascades are typically well characterized (for example phosphorylation on AKT Thr 308 and Ser 473, AMPK Thr172, and CAMKII Thr 286), little is known about the majority of insulin- and exercise-sensitive post-translational modifications. Exercise alone regulates over 1000 phospho-sites, nearly 400 ubiquitin-sites, and nearly 300 acetyl-sites (108, 184, 195). To truly understand how insulin and exercise induce glucose uptake in skeletal muscle, it is important to expand the understanding of the functional roles of post-translational modifications over and above canonical sites. Indeed, an understanding of the wider regulatory signals that control glucose homeostasis may lead to the development of new therapeutic targets.

Technical advances are enabling proteome-wide investigations of post-translational modifications (90). Nonetheless, skeletal muscle remains a challenging tissue for proteomic analyses, with the high dynamic range of protein abundance within skeletal muscle compromising quantification depth (249). However, advancing mass spectrometry technologies, emerging new acquisition methods, improving quantification algorithms, and the increased availability of effective enrichment techniques for a swathe of post-translational modifications (250-254) are collectively providing a powerful platform to study diverse signaling cascades and their responses to physiological stimuli on an “omics” scale (108, 184, 195-197, 238). Future studies should leverage these approaches to investigate the skeletal muscle landscape of previously underinvestigated post-translational modifications, as well as to provide multi-omic insights into the interplay between post-translational modifications, such as between phosphorylation and ubiquitination.

Owing to the nascent nature of techniques to study proteome-wide post-translational modifications, the wealth of data related to global changes in post-translational modifications in response to exercise stems from only a small number of studies (108, 184, 195, 196). This represents a limitation in terms of the diversity of the participants and the range of exercise interventions studied. Specifically, proteomic data into post-translational modifications following acute (phosphorylation and ubiquitination) or chronic (acetylation) exercise in humans currently arise from only 3 studies and a small number of male participants (108, 184, 195). Furthermore, the proteome-wide modifications that result from exercise other than acute high-intensity exhaustive cycling (108, 184) or chronic high-intensity interval training (195) remain unknown. Future studies should expand the mapping of exercise-induced post-translational modifications by investigating a range of exercise modalities, intensities, durations, and intermittency of exercise, as well as individuals of different ages, sex, race, and at various stages of metabolic disease development.

Conclusions

Exercise and skeletal muscle have a central role in promoting whole-body insulin sensitivity and opposing the development of type 2 diabetes. Exercise increases glucose uptake and insulin sensitivity through a range of mechanisms, though principally via GLUT4 translocation. A complex network of signals converge and interact to regulate glucose metabolism and insulin sensitivity in response to exercise (Fig. 7). Indeed, exercise regulates thousands of post-translational modifications on hundreds of proteins, though the functional relevance of such modifications is not always known. The field is poised to decode how numerous forms of post-translational modifications confer exercise-induced signals to modulate glucose uptake and insulin sensitivity. Further mapping of the proteomic and proteome-wide post-translational modification landscape will provide additional clarity into mechanisms orchestrating the development of peripheral insulin resistance and the adaptive responses to exercise.

Figure 7. — Complex signals interact within exercising skeletal muscle to regulate insulin sensitivity, glucose uptake, and metabolism. Numerous post-translational modifications interact to control glucose homeostasis. Phospho-signaling emanating from CAMKK, AMPK, and CAMKII regulate GLUT4 translocation via TBC1D1/TBC1D4 and PIKFYVE. Palmitoylation and ADP-ribosylation of GLUT4 and IRAP, respectively, may also contribute to GLUT4 translocation. Ubiquitination and/or ubiquitin-like modification of enzymes within the glycolytic pathway are decreased during exercise, while the 26S proteasome is activated via phosphorylation of proteasomal subunits by PKA. Endurance exercise training induces mitochondrial hyperacetylation, including acetylation of PDH E1A, which may facilitate elevated fatty acid oxidation. (Ac), acetylation; (Ad), ADP ribosylation; (P), phosphorylation; (Pa), palmitoylation; (Ub), ubiquitination and ubiquitin-like modifications; (GTP), GTP-bound protein.?; –, unconfirmed in exercising/contracting skeletal muscle.

Acknowledgments

We thank members of the Zierath laboratory (Stephen P. Ashcroft and Amy M. Ehrlich) and colleagues within the Novo Nordisk Foundation Center for Basic Metabolic Research (Atul S. Deshmukh and Jeppe Kjærgaard Larsen) for their constructive feedback and careful reading of the manuscript. Figures were created with BioRender.

Financial Support: This work was supported from the Swedish Research Council (Vetenskapsrådet) (2015-00165), the Knut and Alice Wallenberg Foundation (2018-0094), and the Novo Nordisk Foundation (NNF18CC0034900 and NNF14OC0011493). Ben Stocks was supported by a Rising Star Fellowship Award from European Foundation for the Study of Diabetes.

Glossary

Abbreviations

ACC: acetyl-CoA carboxylase
ADP: adenosine diphosphate
AICAR: 5-aminoimidazole-4-carboxamide-1-β-D-ribofuranoside
AKT: protein kinase B
ALDOA: fructose biphosphate aldolase a
AMP: adenosine monophosphate
AMPK: 5′-adenosine monophosphate–activated protein kinase
ARP: actin-related protein
CAMK: calmodulin-dependent protein kinase
CAMKK: calmodulin-dependent protein kinase kinase
cAMP: cyclic AMP
CBP: cyclic AMP-responsive element binding protein
CoA: coenzyme A
CrAT: carnitine acetyltransferase
CREB: cyclic AMP-responsive element binding protein
DHHC7: Zinc finger DHHC-type containing 7
E1: enzymes, ubiquitin-activating enzymes
E2: enzymes, ubiquitin-conjugating enzymes
E3: ligases, ubiquitin-ligases
ENO3: beta-enolase
GAPDH: glyceraldehyde-3-phosphate dehydrogenase
GLUT4: glucose transporter type 4
GS: glycogen synthase
GSK: glycogen synthase kinase
HDAC: histone deacetylase
INSR: insulin receptor
IRAP: leucyl-cistinyl aminopeptidase
IRS1: insulin receptor substrate 1
KEAP1: Kelch-like ECH-associated protein 1
LKB1: liver kinase B1
MAPK: mitogen-activated protein kinase
MARylation: mono-ADP ribosylation
MEF2: myocyte enhancer factor 2
MG53: tripartite motif-containing protein 72
MKRN1: makorin-1
mTOR: mammalian target of rapamycin
NAD: nicotinamide adenine dinucleotide
NRF2: nuclear factor erythroid 2-related factor 2
p300: E1A-binding protein p300
p70 S6K: ribosomal protein S6 kinase
PARylation: poly-ADP ribosylation
PARP: poly-ADP ribose polymerase
PDH: pyruvate dehydrogenase
PGAM: Phospoglycerate mutase
PGC1α: Peroxisome proliferator activated receptor gamma coactivator 1 alpha
PI3K: Phosphatidylinositol 3-kinase
PIKFYVE: Phosphoinositide kinase, FYVE-type zinc finger containing
PKA: protein kinase A
PSMA: proteasomal subunit alpha
PSMB: proteasomal subunit beta
PSMC5: 26S proteasome regulatry subunit 8
PSMD11: 26S proteasome ATPase regulatory subunit 11
RAC1: ras-related protein Rac1
SIRT: Sirtuin
TBC1D1: TBC1 domain family member 1
TBC1D4: TBC1 domain family member 4
TNKS: tankyrase

Contributor Information

Ben Stocks, Novo Nordisk Foundation Center for Basic Metabolic Research, University of Copenhagen, Copenhagen, Denmark.

Juleen R Zierath, Novo Nordisk Foundation Center for Basic Metabolic Research, University of Copenhagen, Copenhagen, Denmark; Departments of Molecular Medicine and Surgery and Physiology and Pharmacology, Karolinska Institutet, Stockholm, Sweden.

Additional Information

Disclosure Summary: The authors declare no conflicts of interest.

References

1. Cho NH, Shaw JE, Karuranga S, et al. IDF Diabetes Atlas: global estimates of diabetes prevalence for 2017 and projections for 2045. Diabetes Res Clin Pract. 2018;138:271-281. [DOI] [PubMed] [Google Scholar]
2. Lin X, Xu Y, Pan X, et al. Global, regional, and national burden and trend of diabetes in 195 countries and territories: an analysis from 1990 to 2025. Sci Rep. 2020;10(1):14790. [DOI] [PMC free article] [PubMed] [Google Scholar]
3. Yang JJ, Yu D, Wen W, et al. Association of diabetes with all-cause and cause-specific mortality in Asia: a pooled analysis of more than 1 million participants. JAMA Netw Open. 2019;2(4):e192696. [DOI] [PMC free article] [PubMed] [Google Scholar]
4. Talmud PJ, Hingorani AD, Cooper JA, et al. Utility of genetic and non-genetic risk factors in prediction of type 2 diabetes: Whitehall II prospective cohort study. BMJ. 2010;340:b4838. [DOI] [PMC free article] [PubMed] [Google Scholar]
5. Hu FB, Li TY, Colditz GA, Willett WC, Manson JE. Television watching and other sedentary behaviors in relation to risk of obesity and type 2 diabetes mellitus in women. JAMA. 2003;289(14):1785-1791. [DOI] [PubMed] [Google Scholar]
6. Mokdad AH, Ford ES, Bowman BA, et al. Prevalence of obesity, diabetes, and obesity-related health risk factors, 2001. JAMA. 2003;289(1):76-79. [DOI] [PubMed] [Google Scholar]
7. Murray CJL, Aravkin AY, Zheng P, et al. Global burden of 87 risk factors in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet. 2020;396(10258):1223-1249. [DOI] [PMC free article] [PubMed] [Google Scholar]
8. Thiebaud D, Jacot E, DeFronzo RA, Maeder E, Jequier E, Felber JP. The effect of graded doses of insulin on total glucose uptake, glucose oxidation, and glucose storage in man. Diabetes. 1982;31(11):957-963. [DOI] [PubMed] [Google Scholar]
9. Zierath JR, He L, Gumà A, Odegoard Wahlström E, Klip A, Wallberg-Henriksson H. Insulin action on glucose transport and plasma membrane GLUT4 content in skeletal muscle from patients with NIDDM. Diabetologia. 1996;39(10):1180-1189. [DOI] [PubMed] [Google Scholar]
10. DeFronzo RA, Tripathy D. Skeletal muscle insulin resistance is the primary defect in type 2 diabetes. Diabetes Care. 2009;32(Suppl 2):S157-S163. [DOI] [PMC free article] [PubMed] [Google Scholar]
11. Edinburgh RM, Bradley HE, Abdullah NF, et al. Lipid metabolism links nutrient-exercise timing to insulin sensitivity in men classified as overweight or obese. J Clin Endocrinol Metab. 2020;105(3):660-676. [DOI] [PMC free article] [PubMed] [Google Scholar]
12. Ivey FM, Ryan AS, Hafer-Macko CE, Goldberg AP, Macko RF. Treadmill aerobic training improves glucose tolerance and indices of insulin sensitivity in disabled stroke survivors: a preliminary report. Stroke. 2007;38(10):2752-2758. [DOI] [PubMed] [Google Scholar]
13. Kirwan JP, Solomon TP, Wojta DM, Staten MA, Holloszy JO. Effects of 7 days of exercise training on insulin sensitivity and responsiveness in type 2 diabetes mellitus. Am J Physiol Endocrinol Metab. 2009;297(1):E151-E156. [DOI] [PMC free article] [PubMed] [Google Scholar]
14. Nassis GP, Papantakou K, Skenderi K, et al. Aerobic exercise training improves insulin sensitivity without changes in body weight, body fat, adiponectin, and inflammatory markers in overweight and obese girls. Metabolism. 2005;54(11):1472-1479. [DOI] [PubMed] [Google Scholar]
15. Dela F, Larsen JJ, Mikines KJ, Ploug T, Petersen LN, Galbo H. Insulin-stimulated muscle glucose clearance in patients with NIDDM. Effects of one-legged physical training. Diabetes. 1995;44(9):1010-1020. [DOI] [PubMed] [Google Scholar]
16. Coen PM, Tanner CJ, Helbling NL, et al. Clinical trial demonstrates exercise following bariatric surgery improves insulin sensitivity. J Clin Invest. 2015;125(1):248-257. [DOI] [PMC free article] [PubMed] [Google Scholar]
17. Knowler WC, Barrett-Connor E, Fowler SE, et al. ; Diabetes Prevention Program Research Group . Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med. 2002;346(6):393-403. [DOI] [PMC free article] [PubMed] [Google Scholar]
18. Taheri S, Zaghloul H, Chagoury O, et al. Effect of intensive lifestyle intervention on bodyweight and glycaemia in early type 2 diabetes (DIADEM-I): an open-label, parallel-group, randomised controlled trial. Lancet Diabetes Endocrinol. 2020;8(6):477-489. [DOI] [PubMed] [Google Scholar]
19. van Loon LJ, Greenhaff PL, Constantin-Teodosiu D, Saris WH, Wagenmakers AJ. The effects of increasing exercise intensity on muscle fuel utilisation in humans. J Physiol. 2001;536(Pt 1):295-304. [DOI] [PMC free article] [PubMed] [Google Scholar]
20. Goldstein MS, Mullick V, Huddlestun B, Levine R. Action of muscular work on transfer of sugars across cell barriers; comparison with action of insulin. Am J Physiol. 1953;173(2):212-216. [DOI] [PubMed] [Google Scholar]
21. Huycke EJ, Kruhoffer P. Effects of insulin and muscular exercise upon the uptake of hexoses by muscle cells. Acta Physiol Scand. 1955;34(2-3):232-249. [DOI] [PubMed] [Google Scholar]
22. Reichard GA, Issekutz B Jr, Kimbel P, Putnam RC, Hochella NJ, Weinhouse S. Blood glucose metabolism in man during muscular work. J Appl Physiol. 1961;16(6):1001-1005. [DOI] [PubMed] [Google Scholar]
23. Ploug T, Galbo H, Richter EA. Increased muscle glucose uptake during contractions: no need for insulin. Am J Physiol. 1984;247(6 Pt 1):E726-E731. [DOI] [PubMed] [Google Scholar]
24. Wojtaszewski JF, Higaki Y, Hirshman MF, et al. Exercise modulates postreceptor insulin signaling and glucose transport in muscle-specific insulin receptor knockout mice. J Clin Invest. 1999;104(9):1257-1264. [DOI] [PMC free article] [PubMed] [Google Scholar]
25. Mikines KJ, Sonne B, Farrell PA, Tronier B, Galbo H. Effect of physical exercise on sensitivity and responsiveness to insulin in humans. Am J Physiol. 1988;254(3 Pt 1):E248-E259. [DOI] [PubMed] [Google Scholar]
26. Devlin JT, Horton ES. Effects of prior high-intensity exercise on glucose metabolism in normal and insulin-resistant men. Diabetes. 1985;34(10):973-979. [DOI] [PubMed] [Google Scholar]
27. Price TB, Rothman DL, Taylor R, Avison MJ, Shulman GI, Shulman RG. Human muscle glycogen resynthesis after exercise: insulin-dependent and -independent phases. J Appl Physiol (1985). 1994;76(1):104-111. [DOI] [PubMed] [Google Scholar]
28. Birnbaum MJ. Identification of a novel gene encoding an insulin-responsive glucose transporter protein. Cell. 1989;57(2):305-315. [DOI] [PubMed] [Google Scholar]
29. Charron MJ, Brosius FC 3rd, Alper SL, Lodish HF. A glucose transport protein expressed predominately in insulin-responsive tissues. Proc Natl Acad Sci U S A. 1989;86(8):2535-2539. [DOI] [PMC free article] [PubMed] [Google Scholar]
30. James DE, Strube M, Mueckler M. Molecular cloning and characterization of an insulin-regulatable glucose transporter. Nature. 1989;338(6210):83-87. [DOI] [PubMed] [Google Scholar]
31. Ryder JW, Kawano Y, Chibalin AV, et al. In vitro analysis of the glucose-transport system in GLUT4-null skeletal muscle. Biochem J. 1999;342(Pt 2):321-328. [PMC free article] [PubMed] [Google Scholar]
32. Ryder JW, Yang J, Galuska D, et al. Use of a novel impermeable biotinylated photolabeling reagent to assess insulin- and hypoxia-stimulated cell surface GLUT4 content in skeletal muscle from type 2 diabetic patients. Diabetes. 2000;49(4):647-654. [DOI] [PubMed] [Google Scholar]
33. Koistinen HA, Galuska D, Chibalin AV, et al. 5-amino-imidazole carboxamide riboside increases glucose transport and cell-surface GLUT4 content in skeletal muscle from subjects with type 2 diabetes. Diabetes. 2003;52(5):1066-1072. [DOI] [PubMed] [Google Scholar]
34. Karlsson HK, Chibalin AV, Koistinen HA, et al. Kinetics of GLUT4 trafficking in rat and human skeletal muscle. Diabetes. 2009;58(4):847-854. [DOI] [PMC free article] [PubMed] [Google Scholar]
35. Furuzono S, Kubota T, Taura J, et al. A xanthene derivative, DS20060511, attenuates glucose intolerance by inducing skeletal muscle-specific GLUT4 translocation in mice. Commun Biol. 2021;4(1):994. [DOI] [PMC free article] [PubMed] [Google Scholar]
36. Ploug T, Ralston E. Anatomy of glucose transporters in skeletal muscle. Effects of insulin and contractions. Adv Exp Med Biol. 1998;441:17-26. [DOI] [PubMed] [Google Scholar]
37. Andersen P, Saltin B. Maximal perfusion of skeletal muscle in man. J Physiol. 1985;366(1):233-249. [DOI] [PMC free article] [PubMed] [Google Scholar]
38. Kennedy JW, Hirshman MF, Gervino EV, et al. Acute exercise induces GLUT4 translocation in skeletal muscle of normal human subjects and subjects with type 2 diabetes. Diabetes. 1999;48(5):1192-1197. [DOI] [PubMed] [Google Scholar]
39. Kristiansen S, Hargreaves M, Richter EA. Exercise-induced increase in glucose transport, GLUT-4, and VAMP-2 in plasma membrane from human muscle. Am J Physiol. 1996;270(1 Pt 1):E197-E201. [DOI] [PubMed] [Google Scholar]
40. Kristiansen S, Hargreaves M, Richter EA. Progressive increase in glucose transport and GLUT-4 in human sarcolemmal vesicles during moderate exercise. Am J Physiol. 1997;272(3 Pt 1):E385-E389. [DOI] [PubMed] [Google Scholar]
41. Lauritzen HP, Galbo H, Toyoda T, Goodyear LJ. Kinetics of contraction-induced GLUT4 translocation in skeletal muscle fibers from living mice. Diabetes. 2010;59(9):2134-2144. [DOI] [PMC free article] [PubMed] [Google Scholar]
42. Goodyear LJ, Hirshman MF, King PA, Horton ED, Thompson CM, Horton ES. Skeletal muscle plasma membrane glucose transport and glucose transporters after exercise. J Appl Physiol (1985). 1990;68(1):193-198. [DOI] [PubMed] [Google Scholar]
43. Hansen PA, Nolte LA, Chen MM, Holloszy JO. Increased GLUT-4 translocation mediates enhanced insulin sensitivity of muscle glucose transport after exercise. J Appl Physiol (1985). 1998;85(4):1218-1222. [DOI] [PubMed] [Google Scholar]
44. Thorell A, Hirshman MF, Nygren J, et al. Exercise and insulin cause GLUT-4 translocation in human skeletal muscle. Am J Physiol. 1999;277(4):E733-E741. [DOI] [PubMed] [Google Scholar]
45. Fazakerley DJ, Holman GD, Marley A, James DE, Stöckli J, Coster AC. Kinetic evidence for unique regulation of GLUT4 trafficking by insulin and AMP-activated protein kinase activators in L6 myotubes. J Biol Chem. 2010;285(3):1653-1660. [DOI] [PMC free article] [PubMed] [Google Scholar]
46. Yang J, Holman GD. Insulin and contraction stimulate exocytosis, but increased AMP-activated protein kinase activity resulting from oxidative metabolism stress slows endocytosis of GLUT4 in cardiomyocytes. J Biol Chem. 2005;280(6):4070-4078. [DOI] [PubMed] [Google Scholar]
47. Ryder JW, Kawano Y, Galuska D, et al. Postexercise glucose uptake and glycogen synthesis in skeletal muscle from GLUT4-deficient mice. FASEB J. 1999;13(15):2246-2256. [DOI] [PubMed] [Google Scholar]
48. Zisman A, Peroni OD, Abel ED, et al. Targeted disruption of the glucose transporter 4 selectively in muscle causes insulin resistance and glucose intolerance. Nat Med. 2000;6(8):924-928. [DOI] [PubMed] [Google Scholar]
49. Fueger PT, Li CY, Ayala JE, et al. Glucose kinetics and exercise tolerance in mice lacking the GLUT4 glucose transporter. J Physiol. 2007;582(Pt 2):801-812. [DOI] [PMC free article] [PubMed] [Google Scholar]
50. Martin IK, Katz A, Wahren J. Splanchnic and muscle metabolism during exercise in NIDDM patients. Am J Physiol. 1995;269(3 Pt 1):E583-E590. [DOI] [PubMed] [Google Scholar]
51. Bogardus C, Thuillez P, Ravussin E, Vasquez B, Narimiga M, Azhar S. Effect of muscle glycogen depletion on in vivo insulin action in man. J Clin Invest. 1983;72(5):1605-1610. [DOI] [PMC free article] [PubMed] [Google Scholar]
52. Steenberg DE, Jørgensen NB, Birk JB, et al. Exercise training reduces the insulin-sensitizing effect of a single bout of exercise in human skeletal muscle. J Physiol. 2019;597(1):89-103. [DOI] [PMC free article] [PubMed] [Google Scholar]
53. Richter EA, Mikines KJ, Galbo H, Kiens B. Effect of exercise on insulin action in human skeletal muscle. J Appl Physiol (1985). 1989;66(2):876-885. [DOI] [PubMed] [Google Scholar]
54. Wojtaszewski JF, Hansen BF, Gade, et al. Insulin signaling and insulin sensitivity after exercise in human skeletal muscle. Diabetes. 2000;49(3):325-331. [DOI] [PubMed] [Google Scholar]
55. Wojtaszewski JF, Hansen BF, Kiens B, Richter EA. Insulin signaling in human skeletal muscle: time course and effect of exercise. Diabetes. 1997;46(11):1775-1781. [DOI] [PubMed] [Google Scholar]
56. Frøsig C, Sajan MP, Maarbjerg SJ, et al. Exercise improves phosphatidylinositol-3,4,5-trisphosphate responsiveness of atypical protein kinase C and interacts with insulin signalling to peptide elongation in human skeletal muscle. J Physiol. 2007;582(Pt 3):1289-1301. [DOI] [PMC free article] [PubMed] [Google Scholar]
57. Heath GW, Gavin JR 3rd, Hinderliter JM, Hagberg JM, Bloomfield SA, Holloszy JO. Effects of exercise and lack of exercise on glucose tolerance and insulin sensitivity. J Appl Physiol Respir Environ Exerc Physiol. 1983;55(2):512-517. [DOI] [PubMed] [Google Scholar]
58. McConell GK, Sjøberg KA, Ceutz F, et al. Insulin-induced membrane permeability to glucose in human muscles at rest and following exercise. J Physiol. 2020;598(2):303-315. [DOI] [PubMed] [Google Scholar]
59. Sjøberg KA, Frøsig C, Kjøbsted R, et al. Exercise increases human skeletal muscle insulin sensitivity via coordinated increases in microvascular perfusion and molecular signaling. Diabetes. 2017;66(6):1501-1510. [DOI] [PubMed] [Google Scholar]
60. Knudsen JR, Steenberg DE, Hingst JR, et al. Prior exercise in humans redistributes intramuscular GLUT4 and enhances insulin-stimulated sarcolemmal and endosomal GLUT4 translocation. Mol Metab. 2020;39:100998. [DOI] [PMC free article] [PubMed] [Google Scholar]
61. Young DA, Wallberg-Henriksson H, Sleeper MD, Holloszy JO. Reversal of the exercise-induced increase in muscle permeability to glucose. Am J Physiol. 1987;253(4 Pt 1):E331-E335. [DOI] [PubMed] [Google Scholar]
62. Cartee GD, Young DA, Sleeper MD, Zierath J, Wallberg-Henriksson H, Holloszy JO. Prolonged increase in insulin-stimulated glucose transport in muscle after exercise. Am J Physiol. 1989;256(4 Pt 1):E494-E499. [DOI] [PubMed] [Google Scholar]
63. Host HH, Hansen PA, Nolte LA, Chen MM, Holloszy JO. Glycogen supercompensation masks the effect of a training induced increase in GLUT-4 on muscle glucose transport. J Appl Physiol (1985). 1998;85(1):133-138. [DOI] [PubMed] [Google Scholar]
64. Kawanaka K, Han DH, Nolte LA, Hansen PA, Nakatani A, Holloszy JO. Decreased insulin-stimulated GLUT-4 translocation in glycogen-supercompensated muscles of exercised rats. Am J Physiol. 1999;276(5):E907-E912. [DOI] [PubMed] [Google Scholar]
65. Kawanaka K, Nolte LA, Han DH, Hansen PA, Holloszy JO. Mechanisms underlying impaired GLUT-4 translocation in glycogen-supercompensated muscles of exercised rats. Am J Physiol Endocrinol Metab. 2000;279(6):E1311-E1318. [DOI] [PubMed] [Google Scholar]
66. Nielsen JN, Vissing J, Wojtaszewski JF, Haller RG, Begum N, Richter EA. Decreased insulin action in skeletal muscle from patients with McArdle’s disease. Am J Physiol Endocrinol Metab. 2002;282(6):E1267-E1275. [DOI] [PubMed] [Google Scholar]
67. Meex RC, Schrauwen-Hinderling VB, Moonen-Kornips E, et al. Restoration of muscle mitochondrial function and metabolic flexibility in type 2 diabetes by exercise training is paralleled by increased myocellular fat storage and improved insulin sensitivity. Diabetes. 2010;59(3):572-579. [DOI] [PMC free article] [PubMed] [Google Scholar]
68. O’Gorman DJ, Karlsson HK, McQuaid S, et al. Exercise training increases insulin-stimulated glucose disposal and GLUT4 (SLC2A4) protein content in patients with type 2 diabetes. Diabetologia. 2006;49(12):2983-2992. [DOI] [PubMed] [Google Scholar]
69. Andersen P, Henriksson J. Capillary supply of the quadriceps femoris muscle of man: adaptive response to exercise. J Physiol. 1977;270(3):677-690. [DOI] [PMC free article] [PubMed] [Google Scholar]
70. Frøsig C, Rose AJ, Treebak JT, Kiens B, Richter EA, Wojtaszewski JF. Effects of endurance exercise training on insulin signaling in human skeletal muscle: interactions at the level of phosphatidylinositol 3-kinase, Akt, and AS160. Diabetes. 2007;56(8):2093-2102. [DOI] [PubMed] [Google Scholar]
71. Daugaard JR, Nielsen JN, Kristiansen S, Andersen JL, Hargreaves M, Richter EA. Fiber type-specific expression of GLUT4 in human skeletal muscle: influence of exercise training. Diabetes. 2000;49(7):1092-1095. [DOI] [PubMed] [Google Scholar]
72. Dela F, Handberg A, Mikines KJ, Vinten J, Galbo H. GLUT 4 and insulin receptor binding and kinase activity in trained human muscle. J Physiol. 1993;469(1):615-624. [DOI] [PMC free article] [PubMed] [Google Scholar]
73. Gulve EA, Spina RJ. Effect of 7-10 days of cycle ergometer exercise on skeletal muscle GLUT-4 protein content. J Appl Physiol (1985). 1995;79(5):1562-1566. [DOI] [PubMed] [Google Scholar]
74. Houmard JA, Shinebarger MH, Dolan PL, et al. Exercise training increases GLUT-4 protein concentration in previously sedentary middle-aged men. Am J Physiol. 1993;264(6 Pt 1):E896-E901. [DOI] [PubMed] [Google Scholar]
75. Phillips SM, Han XX, Green HJ, Bonen A. Increments in skeletal muscle GLUT-1 and GLUT-4 after endurance training in humans. Am J Physiol. 1996;270(3 Pt 1):E456-E462. [DOI] [PubMed] [Google Scholar]
76. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Training intensity modulates changes in PGC-1α and p53 protein content and mitochondrial respiration, but not markers of mitochondrial content in human skeletal muscle. FASEB J. 2016;30(2):959-970. [DOI] [PubMed] [Google Scholar]
77. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Mitochondrial adaptations to high-volume exercise training are rapidly reversed after a reduction in training volume in human skeletal muscle. FASEB J. 2016;30(10):3413-3423. [DOI] [PubMed] [Google Scholar]
78. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Sprint-interval but not continuous exercise increases PGC-1α protein content and p53 phosphorylation in nuclear fractions of human skeletal muscle. Sci Rep. 2017;7:44227. [DOI] [PMC free article] [PubMed] [Google Scholar]
79. Meinild Lundby AK, Jacobs RA, Gehrig S, et al. Exercise training increases skeletal muscle mitochondrial volume density by enlargement of existing mitochondria and not de novo biogenesis. Acta Physiol. 2018;222(1):e12905. [DOI] [PubMed] [Google Scholar]
80. Montero D, Diaz-Cañestro C, Lundby C. Endurance training and V˙O2max: role of maximal cardiac output and oxygen extraction. Med Sci Sports Exerc. 2015;47(10):2024-2033. [DOI] [PubMed] [Google Scholar]
81. Hoppeler H, Howald H, Conley K, et al. Endurance training in humans: aerobic capacity and structure of skeletal muscle. J Appl Physiol (1985). 1985;59(2):320-327. [DOI] [PubMed] [Google Scholar]
82. Jacobs RA, Flück D, Bonne TC, et al. Improvements in exercise performance with high-intensity interval training coincide with an increase in skeletal muscle mitochondrial content and function. J Appl Physiol (1985). 2013;115(6):785-793. [DOI] [PubMed] [Google Scholar]
83. Kelley DE, He J, Menshikova EV, Ritov VB. Dysfunction of mitochondria in human skeletal muscle in type 2 diabetes. Diabetes. 2002;51(10):2944-2950. [DOI] [PubMed] [Google Scholar]
84. Petersen KF, Befroy D, Dufour S, et al. Mitochondrial dysfunction in the elderly: possible role in insulin resistance. Science. 2003;300(5622):1140-1142. [DOI] [PMC free article] [PubMed] [Google Scholar]
85. Daemen S, Gemmink A, Brouwers B, et al. Distinct lipid droplet characteristics and distribution unmask the apparent contradiction of the athlete’s paradox. Mol Metab. 2018;17:71-81. [DOI] [PMC free article] [PubMed] [Google Scholar]
86. Goodpaster BH, He J, Watkins S, Kelley DE. Skeletal muscle lipid content and insulin resistance: evidence for a paradox in endurance-trained athletes. J Clin Endocrinol Metab. 2001;86(12):5755-5761. [DOI] [PubMed] [Google Scholar]
87. Krssak M, Falk Petersen K, Dresner A, et al. Intramyocellular lipid concentrations are correlated with insulin sensitivity in humans: a 1H NMR spectroscopy study. Diabetologia. 1999;42(1):113-116. [DOI] [PubMed] [Google Scholar]
88. Pan DA, Lillioja S, Kriketos AD, et al. Skeletal muscle triglyceride levels are inversely related to insulin action. Diabetes. 1997;46(6):983-988. [DOI] [PubMed] [Google Scholar]
89. White MF, Kahn CR. Insulin action at a molecular level - 100 years of progress. Mol Metab. 2021;52:101304. [DOI] [PMC free article] [PubMed] [Google Scholar]
90. Olsen JV, Mann M. Status of large-scale analysis of post-translational modifications by mass spectrometry. Mol Cell Proteomics. 2013;12(12):3444-3452. [DOI] [PMC free article] [PubMed] [Google Scholar]
91. Sharma K, D’Souza RC, Tyanova S, et al. Ultradeep human phosphoproteome reveals a distinct regulatory nature of Tyr and Ser/Thr-based signaling. Cell Rep. 2014;8(5):1583-1594. [DOI] [PubMed] [Google Scholar]
92. Bouzakri K, Zachrisson A, Al-Khalili L, et al. siRNA-based gene silencing reveals specialized roles of IRS-1/Akt2 and IRS-2/Akt1 in glucose and lipid metabolism in human skeletal muscle. Cell Metab. 2006;4(1):89-96. [DOI] [PubMed] [Google Scholar]
93. Wang Q, Somwar R, Bilan PJ, et al. Protein kinase B/Akt participates in GLUT4 translocation by insulin in L6 myoblasts. Mol Cell Biol. 1999;19(6):4008-4018. [DOI] [PMC free article] [PubMed] [Google Scholar]
94. Sylow L, Kleinert M, Pehmøller C, et al. Akt and Rac1 signaling are jointly required for insulin-stimulated glucose uptake in skeletal muscle and downregulated in insulin resistance. Cell Signal. 2014;26(2):323-331. [DOI] [PubMed] [Google Scholar]
95. Ueda S, Kataoka T, Satoh T. Activation of the small GTPase Rac1 by a specific guanine-nucleotide-exchange factor suffices to induce glucose uptake into skeletal-muscle cells. Biol Cell. 2008;100(11):645-657. [DOI] [PubMed] [Google Scholar]
96. JeBailey L, Wanono O, Niu W, Roessler J, Rudich A, Klip A. Ceramide- and oxidant-induced insulin resistance involve loss of insulin-dependent Rac-activation and actin remodeling in muscle cells. Diabetes. 2007;56(2):394-403. [DOI] [PubMed] [Google Scholar]
97. Vichaiwong K, Purohit S, An D, et al. Contraction regulates site-specific phosphorylation of TBC1D1 in skeletal muscle. Biochem J. 2010;431(2):311-320. [DOI] [PMC free article] [PubMed] [Google Scholar]
98. Roach WG, Chavez JA, Mîinea CP, Lienhard GE. Substrate specificity and effect on GLUT4 translocation of the Rab GTPase-activating protein Tbc1d1. Biochem J. 2007;403(2):353-358. [DOI] [PMC free article] [PubMed] [Google Scholar]
99. Chavez JA, Roach WG, Keller SR, Lane WS, Lienhard GE. Inhibition of GLUT4 translocation by Tbc1d1, a Rab GTPase-activating protein abundant in skeletal muscle, is partially relieved by AMP-activated protein kinase activation. J Biol Chem. 2008;283(14):9187-9195. [DOI] [PMC free article] [PubMed] [Google Scholar]
100. Thong FS, Bilan PJ, Klip A. The Rab GTPase-activating protein AS160 integrates Akt, protein kinase C, and AMP-activated protein kinase signals regulating GLUT4 traffic. Diabetes. 2007;56(2):414-423. [DOI] [PubMed] [Google Scholar]
101. Kane S, Sano H, Liu SC, et al. A method to identify serine kinase substrates. Akt phosphorylates a novel adipocyte protein with a Rab GTPase-activating protein (GAP) domain. J Biol Chem. 2002;277(25):22115-22118. [DOI] [PubMed] [Google Scholar]
102. Raun SH, Ali M, Kjøbsted R, et al. Rac1 muscle knockout exacerbates the detrimental effect of high-fat diet on insulin-stimulated muscle glucose uptake independently of Akt. J Physiol. 2018;596(12):2283-2299. [DOI] [PMC free article] [PubMed] [Google Scholar]
103. Sylow L, Jensen TE, Kleinert M, et al. Rac1 signaling is required for insulin-stimulated glucose uptake and is dysregulated in insulin-resistant murine and human skeletal muscle. Diabetes. 2013;62(6):1865-1875. [DOI] [PMC free article] [PubMed] [Google Scholar]
104. Ueda S, Kitazawa S, Ishida K, et al. Crucial role of the small GTPase Rac1 in insulin-stimulated translocation of glucose transporter 4 to the mouse skeletal muscle sarcolemma. FASEB J. 2010;24(7):2254-2261. [DOI] [PMC free article] [PubMed] [Google Scholar]
105. Chiu TT, Patel N, Shaw AE, Bamburg JR, Klip A. Arp2/3- and cofilin-coordinated actin dynamics is required for insulin-mediated GLUT4 translocation to the surface of muscle cells. Mol Biol Cell. 2010;21(20):3529-3539. [DOI] [PMC free article] [PubMed] [Google Scholar]
106. Tong P, Khayat ZA, Huang C, Patel N, Ueyama A, Klip A. Insulin-induced cortical actin remodeling promotes GLUT4 insertion at muscle cell membrane ruffles. J Clin Invest. 2001;108(3):371-381. [DOI] [PMC free article] [PubMed] [Google Scholar]
107. Nelson ME, Parker BL, Burchfield JG, et al. Phosphoproteomics reveals conserved exercise-stimulated signaling and AMPK regulation of store-operated calcium entry. EMBO J. 2019;38(24):e102578. [DOI] [PMC free article] [PubMed] [Google Scholar]
108. Hoffman NJ, Parker BL, Chaudhuri R, et al. Global phosphoproteomic analysis of human skeletal muscle reveals a network of exercise-regulated kinases and AMPK substrates. Cell Metab. 2015;22(5):922-935. [DOI] [PMC free article] [PubMed] [Google Scholar]
109. Maier G, Delezie J, Westermark PO, Santos G, Ritz D, Handschin C. Transcriptomic, proteomic and phosphoproteomic underpinnings of daily exercise performance and zeitgeber activity of training in mouse muscle. J Physiol. Published online June 18, 2021. Doi: 10.1113/JP281535 [DOI] [PMC free article] [PubMed] [Google Scholar]
110. Howlett KF, Sakamoto K, Hirshman MF, et al. Insulin signaling after exercise in insulin receptor substrate-2-deficient mice. Diabetes. 2002;51(2):479-483. [DOI] [PubMed] [Google Scholar]
111. Koval JA, Maezono K, Patti ME, Pendergrass M, DeFronzo RA, Mandarino LJ. Effects of exercise and insulin on insulin signaling proteins in human skeletal muscle. Med Sci Sports Exerc. 1999;31(7):998-1004. [DOI] [PubMed] [Google Scholar]
112. Zhou Q, Dohm GL. Treadmill running increases phosphatidylinostol 3-kinase activity in rat skeletal muscle. Biochem Biophys Res Commun. 1997;236(3):647-650. [DOI] [PubMed] [Google Scholar]
113. Whitehead JP, Soos MA, Aslesen R, O’rahilly S, Jensen J. Contraction inhibits insulin-stimulated insulin receptor substrate-1/2-associated phosphoinositide 3-kinase activity, but not protein kinase B activation or glucose uptake, in rat muscle. Biochem J. 2000;349(Pt 3):775-781. [DOI] [PMC free article] [PubMed] [Google Scholar]
114. Yeh JI, Gulve EA, Rameh L, Birnbaum MJ. The effects of wortmannin on rat skeletal muscle. Dissociation of signaling pathways for insulin- and contraction-activated hexose transport. J Biol Chem. 1995;270(5):2107-2111. [DOI] [PubMed] [Google Scholar]
115. Funai K, Schweitzer GG, Castorena CM, Kanzaki M, Cartee GD. In vivo exercise followed by in vitro contraction additively elevates subsequent insulin-stimulated glucose transport by rat skeletal muscle. Am J Physiol Endocrinol Metab. 2010;298(5):E999-1010. [DOI] [PMC free article] [PubMed] [Google Scholar]
116. Goodyear LJ, Giorgino F, Balon TW, Condorelli G, Smith RJ. Effects of contractile activity on tyrosine phosphoproteins and PI 3-kinase activity in rat skeletal muscle. Am J Physiol. 1995;268(5 Pt 1):E987-E995. [DOI] [PubMed] [Google Scholar]
117. Treebak JT, Frøsig C, Pehmøller C, et al. Potential role of TBC1D4 in enhanced post-exercise insulin action in human skeletal muscle. Diabetologia. 2009;52(5):891-900. [DOI] [PMC free article] [PubMed] [Google Scholar]
118. Treebak JT, Glund S, Deshmukh A, et al. AMPK-mediated AS160 phosphorylation in skeletal muscle is dependent on AMPK catalytic and regulatory subunits. Diabetes. 2006;55(7):2051-2058. [DOI] [PubMed] [Google Scholar]
119. Kramer HF, Witczak CA, Fujii N, et al. Distinct signals regulate AS160 phosphorylation in response to insulin, AICAR, and contraction in mouse skeletal muscle. Diabetes. 2006;55(7):2067-2076. [DOI] [PubMed] [Google Scholar]
120. Treebak JT, Birk JB, Rose AJ, Kiens B, Richter EA, Wojtaszewski JF. AS160 phosphorylation is associated with activation of alpha2beta2gamma1- but not alpha2beta2gamma3-AMPK trimeric complex in skeletal muscle during exercise in humans. Am J Physiol Endocrinol Metab. 2007;292(3):E715-E722. [DOI] [PubMed] [Google Scholar]
121. Schweitzer GG, Arias EB, Cartee GD. Sustained postexercise increases in AS160 Thr642 and Ser588 phosphorylation in skeletal muscle without sustained increases in kinase phosphorylation. J Appl Physiol (1985). 2012;113(12):1852-1861. [DOI] [PMC free article] [PubMed] [Google Scholar]
122. Arias EB, Kim J, Funai K, Cartee GD. Prior exercise increases phosphorylation of Akt substrate of 160 kDa (AS160) in rat skeletal muscle. Am J Physiol Endocrinol Metab. 2007;292(4):E1191-E1200. [DOI] [PubMed] [Google Scholar]
123. Kramer HF, Witczak CA, Taylor EB, Fujii N, Hirshman MF, Goodyear LJ. AS160 regulates insulin- and contraction-stimulated glucose uptake in mouse skeletal muscle. J Biol Chem. 2006;281(42):31478-31485. [DOI] [PubMed] [Google Scholar]
124. Hawley SA, Davison M, Woods A, et al. Characterization of the AMP-activated protein kinase kinase from rat liver and identification of threonine 172 as the major site at which it phosphorylates AMP-activated protein kinase. J Biol Chem. 1996;271(44):27879-27887. [DOI] [PubMed] [Google Scholar]
125. Oakhill JS, Chen ZP, Scott JW, et al. β-Subunit myristoylation is the gatekeeper for initiating metabolic stress sensing by AMP-activated protein kinase (AMPK). Proc Natl Acad Sci U S A. 2010;107(45):19237-19241. [DOI] [PMC free article] [PubMed] [Google Scholar]
126. Birk JB, Wojtaszewski JF. Predominant alpha2/beta2/gamma3 AMPK activation during exercise in human skeletal muscle. J Physiol. 2006;577(Pt 3):1021-1032. [DOI] [PMC free article] [PubMed] [Google Scholar]
127. Fujii N, Hayashi T, Hirshman MF, et al. Exercise induces isoform-specific increase in 5’AMP-activated protein kinase activity in human skeletal muscle. Biochem Biophys Res Commun. 2000;273(3):1150-1155. [DOI] [PubMed] [Google Scholar]
128. Stocks B, Dent JR, Ogden HB, Zemp M, Philp A. Postexercise skeletal muscle signaling responses to moderate- to high-intensity steady-state exercise in the fed or fasted state. Am J Physiol Endocrinol Metab. 2019;316(2):E230-E238. [DOI] [PubMed] [Google Scholar]
129. Taylor EB, An D, Kramer HF, et al. Discovery of TBC1D1 as an insulin-, AICAR-, and contraction-stimulated signaling nexus in mouse skeletal muscle. J Biol Chem. 2008;283(15):9787-9796. [DOI] [PMC free article] [PubMed] [Google Scholar]
130. Kjøbsted R, Chadt A, Jørgensen NO, et al. TBC1D4 is necessary for enhancing muscle insulin sensitivity in response to AICAR and contraction. Diabetes. 2019;68(9):1756-1766. [DOI] [PubMed] [Google Scholar]
131. Pehmøller C, Brandt N, Birk JB, et al. Exercise alleviates lipid-induced insulin resistance in human skeletal muscle-signaling interaction at the level of TBC1 domain family member 4. Diabetes. 2012;61(11):2743-2752. [DOI] [PMC free article] [PubMed] [Google Scholar]
132. Mu J, Brozinick JT Jr, Valladares O, Bucan M, Birnbaum MJ. A role for AMP-activated protein kinase in contraction- and hypoxia-regulated glucose transport in skeletal muscle. Mol Cell. 2001;7(5):1085-1094. [DOI] [PubMed] [Google Scholar]
133. Lefort N, St-Amand E, Morasse S, Côté CH, Marette A. The alpha-subunit of AMPK is essential for submaximal contraction-mediated glucose transport in skeletal muscle in vitro. Am J Physiol Endocrinol Metab. 2008;295(6):E1447-E1454. [DOI] [PubMed] [Google Scholar]
134. Lee-Young RS, Griffee SR, Lynes SE, et al. Skeletal muscle AMP-activated protein kinase is essential for the metabolic response to exercise in vivo. J Biol Chem. 2009;284(36):23925-23934. [DOI] [PMC free article] [PubMed] [Google Scholar]
135. Abbott MJ, Bogachus LD, Turcotte LP. AMPKα2 deficiency uncovers time dependency in the regulation of contraction-induced palmitate and glucose uptake in mouse muscle. J Appl Physiol (1985). 2011;111(1):125-134. [DOI] [PubMed] [Google Scholar]
136. O’Neill HM, Maarbjerg SJ, Crane JD, et al. AMP-activated protein kinase (AMPK) beta1beta2 muscle null mice reveal an essential role for AMPK in maintaining mitochondrial content and glucose uptake during exercise. Proc Natl Acad Sci U S A. 2011;108(38):16092-16097. [DOI] [PMC free article] [PubMed] [Google Scholar]
137. Kjøbsted R, Munk-Hansen N, Birk JB, et al. Enhanced muscle insulin sensitivity after contraction/exercise is mediated by AMPK. Diabetes. 2017;66(3):598-612. [DOI] [PubMed] [Google Scholar]
138. Crawford SA, Costford SR, Aguer C, et al. Naturally occurring R225W mutation of the gene encoding AMP-activated protein kinase (AMPK)gamma(3) results in increased oxidative capacity and glucose uptake in human primary myotubes. Diabetologia. 2010;53(9):1986-1997. [DOI] [PubMed] [Google Scholar]
139. Stöckli J, Meoli CC, Hoffman NJ, et al. The RabGAP TBC1D1 plays a central role in exercise-regulated glucose metabolism in skeletal muscle. Diabetes. 2015;64(6):1914-1922. [DOI] [PubMed] [Google Scholar]
140. Kjøbsted R, Roll JLW, Jørgensen NO, et al. AMPK and TBC1D1 regulate muscle glucose uptake after, but not during, exercise and contraction. Diabetes. 2019;68(7):1427-1440. [DOI] [PubMed] [Google Scholar]
141. An D, Toyoda T, Taylor EB, et al. TBC1D1 regulates insulin- and contraction-induced glucose transport in mouse skeletal muscle. Diabetes. 2010;59(6):1358-1365. [DOI] [PMC free article] [PubMed] [Google Scholar]
142. Fentz J, Kjøbsted R, Birk JB, et al. AMPKα is critical for enhancing skeletal muscle fatty acid utilization during in vivo exercise in mice. FASEB J. 2015;29(5):1725-1738. [DOI] [PubMed] [Google Scholar]
143. Wojtaszewski JF, Mourtzakis M, Hillig T, Saltin B, Pilegaard H. Dissociation of AMPK activity and ACCbeta phosphorylation in human muscle during prolonged exercise. Biochem Biophys Res Commun. 2002;298(3):309-316. [DOI] [PubMed] [Google Scholar]
144. McConell GK, Lee-Young RS, Chen ZP, et al. Short-term exercise training in humans reduces AMPK signalling during prolonged exercise independent of muscle glycogen. J Physiol. 2005;568(Pt 2):665-676. [DOI] [PMC free article] [PubMed] [Google Scholar]
145. Liu Y, Lai YC, Hill EV, et al. Phosphatidylinositol 3-phosphate 5-kinase (PIKfyve) is an AMPK target participating in contraction-stimulated glucose uptake in skeletal muscle. Biochem J. 2013;455(2):195-206. [DOI] [PubMed] [Google Scholar]
146. Ikonomov OC, Sbrissa D, Delvecchio K, et al. Muscle-specific Pikfyve gene disruption causes glucose intolerance, insulin resistance, adiposity, and hyperinsulinemia but not muscle fiber-type switching. Am J Physiol Endocrinol Metab. 2013;305(1):E119-E131. [DOI] [PMC free article] [PubMed] [Google Scholar]
147. Bartlett JD, Louhelainen J, Iqbal Z, et al. Reduced carbohydrate availability enhances exercise-induced p53 signaling in human skeletal muscle: implications for mitochondrial biogenesis. Am J Physiol Regul Integr Comp Physiol. 2013;304(6):R450-R458. [DOI] [PubMed] [Google Scholar]
148. Lai YC, Zarrinpashneh E, Jensen J. Additive effect of contraction and insulin on glucose uptake and glycogen synthase in muscle with different glycogen contents. J Appl Physiol (1985). 2010;108(5):1106-1115. [DOI] [PubMed] [Google Scholar]
149. Philp A, MacKenzie MG, Belew MY, et al. Glycogen content regulates peroxisome proliferator activated receptor-∂ (PPAR-∂) activity in rat skeletal muscle. PLoS One. 2013;8(10):e77200. [DOI] [PMC free article] [PubMed] [Google Scholar]
150. Steinberg GR, Watt MJ, McGee SL, et al. Reduced glycogen availability is associated with increased AMPKalpha2 activity, nuclear AMPKalpha2 protein abundance, and GLUT4 mRNA expression in contracting human skeletal muscle. Appl Physiol Nutr Metab. 2006;31(3):302-312. [DOI] [PubMed] [Google Scholar]
151. Wojtaszewski JF, MacDonald C, Nielsen JN, et al. Regulation of 5’AMP-activated protein kinase activity and substrate utilization in exercising human skeletal muscle. Am J Physiol Endocrinol Metab. 2003;284(4):E813-E822. [DOI] [PubMed] [Google Scholar]
152. Yeo WK, McGee SL, Carey AL, et al. Acute signalling responses to intense endurance training commenced with low or normal muscle glycogen. Exp Physiol. 2010;95(2):351-358. [DOI] [PubMed] [Google Scholar]
153. Derave W, Ai H, Ihlemann J, et al. Dissociation of AMP-activated protein kinase activation and glucose transport in contracting slow-twitch muscle. Diabetes. 2000;49(8):1281-1287. [DOI] [PubMed] [Google Scholar]
154. Derave W, Lund S, Holman GD, Wojtaszewski J, Pedersen O, Richter EA. Contraction-stimulated muscle glucose transport and GLUT-4 surface content are dependent on glycogen content. Am J Physiol. 1999;277(6):E1103-E1110. [DOI] [PubMed] [Google Scholar]
155. Hudson ER, Pan DA, James J, et al. A novel domain in AMP-activated protein kinase causes glycogen storage bodies similar to those seen in hereditary cardiac arrhythmias. Curr Biol. 2003;13(10):861-866. [DOI] [PubMed] [Google Scholar]
156. McBride A, Ghilagaber S, Nikolaev A, Hardie DG. The glycogen-binding domain on the AMPK beta subunit allows the kinase to act as a glycogen sensor. Cell Metab. 2009;9(1):23-34. [DOI] [PMC free article] [PubMed] [Google Scholar]
157. Polekhina G, Gupta A, Michell BJ, et al. AMPK beta subunit targets metabolic stress sensing to glycogen. Curr Biol. 2003;13(10):867-871. [DOI] [PubMed] [Google Scholar]
158. Oligschlaeger Y, Miglianico M, Chanda D, et al. The recruitment of AMP-activated protein kinase to glycogen is regulated by autophosphorylation. J Biol Chem. 2015;290(18):11715-11728. [DOI] [PMC free article] [PubMed] [Google Scholar]
159. Oligschlaeger Y, Miglianico M, Dahlmans V, et al. The interaction between AMPKβ2 and the PP1-targeting subunit R6 is dynamically regulated by intracellular glycogen content. Biochem J. 2016;473(7):937-947. [DOI] [PubMed] [Google Scholar]
160. Hespel P, Richter EA. Glucose uptake and transport in contracting, perfused rat muscle with different pre-contraction glycogen concentrations. J Physiol. 1990;427:347-359. [DOI] [PMC free article] [PubMed] [Google Scholar]
161. Steensberg A, van Hall G, Keller C, et al. Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. J Physiol. 2002;541(Pt 1):273-281. [DOI] [PMC free article] [PubMed] [Google Scholar]
162. Rose AJ, Hargreaves M. Exercise increases Ca2+-calmodulin-dependent protein kinase II activity in human skeletal muscle. J Physiol. 2003;553(Pt 1):303-309. [DOI] [PMC free article] [PubMed] [Google Scholar]
163. Rose AJ, Kiens B, Richter EA. Ca2+-calmodulin-dependent protein kinase expression and signalling in skeletal muscle during exercise. J Physiol. 2006;574(Pt 3):889-903. [DOI] [PMC free article] [PubMed] [Google Scholar]
164. Combes A, Dekerle J, Webborn N, Watt P, Bougault V, Daussin FN. Exercise-induced metabolic fluctuations influence AMPK, p38-MAPK and CaMKII phosphorylation in human skeletal muscle. Physiol Rep. 2015;3(9):e12462. [DOI] [PMC free article] [PubMed] [Google Scholar]
165. Witczak CA, Jessen N, Warro DM, et al. CaMKII regulates contraction- but not insulin-induced glucose uptake in mouse skeletal muscle. Am J Physiol Endocrinol Metab. 2010;298(6):E1150-E1160. [DOI] [PMC free article] [PubMed] [Google Scholar]
166. Park DR, Park KH, Kim BJ, Yoon CS, Kim UH. Exercise ameliorates insulin resistance via Ca2+ signals distinct from those of insulin for GLUT4 translocation in skeletal muscles. Diabetes. 2015;64(4):1224-1234. [DOI] [PubMed] [Google Scholar]
167. Li Z, Yue Y, Hu F, et al. Electrical pulse stimulation induces GLUT4 translocation in C2C12 myotubes that depends on Rab8A, Rab13, and Rab14. Am J Physiol Endocrinol Metab. 2018;314(5):E478-E493. [DOI] [PubMed] [Google Scholar]
168. Wright DC, Hucker KA, Holloszy JO, Han DH. Ca2+ and AMPK both mediate stimulation of glucose transport by muscle contractions. Diabetes. 2004;53(2):330-335. [DOI] [PubMed] [Google Scholar]
169. Ihlemann J, Galbo H, Ploug T. Calphostin C is an inhibitor of contraction, but not insulin-stimulated glucose transport, in skeletal muscle. Acta Physiol Scand. 1999;167(1):69-75. [DOI] [PubMed] [Google Scholar]
170. Jensen TE, Rose AJ, Jørgensen SB, et al. Possible CaMKK-dependent regulation of AMPK phosphorylation and glucose uptake at the onset of mild tetanic skeletal muscle contraction. Am J Physiol Endocrinol Metab. 2007;292(5):E1308-E1317. [DOI] [PubMed] [Google Scholar]
171. Popovic D, Vucic D, Dikic I. Ubiquitination in disease pathogenesis and treatment. Nat Med. 2014;20(11):1242-1253. [DOI] [PubMed] [Google Scholar]
172. Balaji V, Pokrzywa W, Hoppe T. Ubiquitylation pathways in insulin signaling and organismal homeostasis. Bioessays. 2018;40(5):e1700223. [DOI] [PubMed] [Google Scholar]
173. Yang XD, Xiang DX, Yang YY. Role of E3 ubiquitin ligases in insulin resistance. Diabetes Obes Metab. 2016;18(8):747-754. [DOI] [PubMed] [Google Scholar]
174. Song R, Peng W, Zhang Y, et al. Central role of E3 ubiquitin ligase MG53 in insulin resistance and metabolic disorders. Nature. 2013;494(7437):375-379. [DOI] [PubMed] [Google Scholar]
175. Uruno A, Furusawa Y, Yagishita Y, et al. The Keap1-Nrf2 system prevents onset of diabetes mellitus. Mol Cell Biol. 2013;33(15):2996-3010. [DOI] [PMC free article] [PubMed] [Google Scholar]
176. Kawaguchi M, Minami K, Nagashima K, Seino S. Essential role of ubiquitin-proteasome system in normal regulation of insulin secretion. J Biol Chem. 2006;281(19):13015-13020. [DOI] [PubMed] [Google Scholar]
177. Yamada T, Murata D, Adachi Y, et al. Mitochondrial stasis reveals p62-mediated ubiquitination in parkin-independent mitophagy and mitigates nonalcoholic fatty liver disease. Cell Metab. 2018;28(4):588-604.e5. [DOI] [PMC free article] [PubMed] [Google Scholar]
178. Price SR, Bailey JL, Wang X, et al. Muscle wasting in insulinopenic rats results from activation of the ATP-dependent, ubiquitin-proteasome proteolytic pathway by a mechanism including gene transcription. J Clin Invest. 1996;98(8):1703-1708. [DOI] [PMC free article] [PubMed] [Google Scholar]
179. Al-Khalili L, de Castro Barbosa T, Ostling J, et al. Proteasome inhibition in skeletal muscle cells unmasks metabolic derangements in type 2 diabetes. Am J Physiol Cell Physiol. 2014;307(9):C774-C787. [DOI] [PubMed] [Google Scholar]
180. Nagarajan A, Petersen MC, Nasiri AR, et al. MARCH1 regulates insulin sensitivity by controlling cell surface insulin receptor levels. Nat Commun. 2016;7:12639. [DOI] [PMC free article] [PubMed] [Google Scholar]
181. Tawo R, Pokrzywa W, Kevei É, et al. The ubiquitin ligase CHIP integrates proteostasis and aging by regulation of insulin receptor turnover. Cell. 2017;169(3):470-482.e13. [DOI] [PMC free article] [PubMed] [Google Scholar]
182. Ahn BH, Kim HS, Song S, et al. A role for the mitochondrial deacetylase Sirt3 in regulating energy homeostasis. Proc Natl Acad Sci U S A. 2008;105(38):14447-14452. [DOI] [PMC free article] [PubMed] [Google Scholar]
183. VerPlank JJS, Lokireddy S, Zhao J, Goldberg AL. 26S Proteasomes are rapidly activated by diverse hormones and physiological states that raise cAMP and cause Rpn6 phosphorylation. Proc Natl Acad Sci U S A. 2019;116(10):4228-4237. [DOI] [PMC free article] [PubMed] [Google Scholar]
184. Parker BL, Kiens B, Wojtaszewski JFP, Richter EA, James DE. Quantification of exercise-regulated ubiquitin signaling in human skeletal muscle identifies protein modification cross talk via NEDDylation. FASEB J. 2020;34(4):5906-5916. [DOI] [PubMed] [Google Scholar]
185. Djakovic SN, Schwarz LA, Barylko B, DeMartino GN, Patrick GN. Regulation of the proteasome by neuronal activity and calcium/calmodulin-dependent protein kinase II. J Biol Chem. 2009;284(39):26655-26665. [DOI] [PMC free article] [PubMed] [Google Scholar]
186. Udeshi ND, Svinkina T, Mertins P, et al. Refined preparation and use of anti-diglycine remnant (K-ε-GG) antibody enables routine quantification of 10,000s of ubiquitination sites in single proteomics experiments. Mol Cell Proteomics. 2013;12(3):825-831. [DOI] [PMC free article] [PubMed] [Google Scholar]
187. Kao AW, Noda Y, Johnson JH, Pessin JE, Saltiel AR. Aldolase mediates the association of F-actin with the insulin-responsive glucose transporter GLUT4. J Biol Chem. 1999;274(25):17742-17747. [DOI] [PubMed] [Google Scholar]
188. Chen-Zion M, Lilling G, Beitner R. The dual effects of Ca2+ on binding of the glycolytic enzymes, phosphofructokinase and aldolase, to muscle cytoskeleton. Biochem Med Metab Biol. 1993;49(2):173-181. [DOI] [PubMed] [Google Scholar]
189. Krassikova L, Zhang B, Nagarajan D, et al. The deubiquitinase JOSD2 is a positive regulator of glucose metabolism. Cell Death Differ. 2021;28(3):1091-1109. [DOI] [PMC free article] [PubMed] [Google Scholar]
190. Jiang P, Ren L, Zhi L, et al. Negative regulation of AMPK signaling by high glucose via E3 ubiquitin ligase MG53. Mol Cell. 2021;81(3):629-637.e5. [DOI] [PubMed] [Google Scholar]
191. Lee MS, Han HJ, Han SY, et al. Loss of the E3 ubiquitin ligase MKRN1 represses diet-induced metabolic syndrome through AMPK activation. Nat Commun. 2018;9(1):3404. [DOI] [PMC free article] [PubMed] [Google Scholar]
192. Dagon Y, Hur E, Zheng B, Wellenstein K, Cantley LC, Kahn BB. p70S6 kinase phosphorylates AMPK on serine 491 to mediate leptin’s effect on food intake. Cell Metab. 2012;16(1):104-112. [DOI] [PMC free article] [PubMed] [Google Scholar]
193. Hawley Simon A, Ross Fiona A, Gowans Graeme J, Tibarewal P, Leslie Nicholas R, Hardie DG. Phosphorylation by Akt within the ST loop of AMPK-α1 down-regulates its activation in tumour cells. Biochem J. 2014;459(2):275-287. [DOI] [PMC free article] [PubMed] [Google Scholar]
194. Lundby A, Lage K, Weinert BT, et al. Proteomic analysis of lysine acetylation sites in rat tissues reveals organ specificity and subcellular patterns. Cell Rep. 2012;2(2):419-431. [DOI] [PMC free article] [PubMed] [Google Scholar]
195. Hostrup M, Lemminger AK, Stocks B, et al. High-intensity interval training remodels the proteome and acetylome of human skeletal muscle. bioRxiv. 2021:2021.2002.2010.430602. [DOI] [PMC free article] [PubMed] [Google Scholar]
196. Overmyer KA, Evans CR, Qi NR, et al. Maximal oxidative capacity during exercise is associated with skeletal muscle fuel selection and dynamic changes in mitochondrial protein acetylation. Cell Metab. 2015;21(3):468-478. [DOI] [PMC free article] [PubMed] [Google Scholar]
197. Williams AS, Koves TR, Davidson MT, et al. Disruption of acetyl-lysine turnover in muscle mitochondria promotes insulin resistance and redox stress without overt respiratory dysfunction. Cell Metab. 2020;31(1):131-147.e11. [DOI] [PMC free article] [PubMed] [Google Scholar]
198. LaBarge S, Migdal C, Schenk S. Is acetylation a metabolic rheostat that regulates skeletal muscle insulin action? Mol Cells. 2015;38(4):297-303. [DOI] [PMC free article] [PubMed] [Google Scholar]
199. Sun C, Zhou J. Trichostatin A improves insulin stimulated glucose utilization and insulin signaling transduction through the repression of HDAC2. Biochem Pharmacol. 2008;76(1):120-127. [DOI] [PubMed] [Google Scholar]
200. Sundaresan NR, Pillai VB, Wolfgeher D, et al. The deacetylase SIRT1 promotes membrane localization and activation of Akt and PDK1 during tumorigenesis and cardiac hypertrophy. Sci Signal. 2011;4(182):ra46. [DOI] [PubMed] [Google Scholar]
201. Li B, Carey M, Workman JL. The role of chromatin during transcription. Cell. 2007;128(4):707-719. [DOI] [PubMed] [Google Scholar]
202. McGee SL, van Denderen BJ, Howlett KF, et al. AMP-activated protein kinase regulates GLUT4 transcription by phosphorylating histone deacetylase 5. Diabetes. 2008;57(4):860-867. [DOI] [PubMed] [Google Scholar]
203. Hong S, Zhou W, Fang B, et al. Dissociation of muscle insulin sensitivity from exercise endurance in mice by HDAC3 depletion. Nat Med. 2017;23(2):223-234. [DOI] [PMC free article] [PubMed] [Google Scholar]
204. Song S, Wen Y, Tong H, et al. The HDAC3 enzymatic activity regulates skeletal muscle fuel metabolism. J Mol Cell Biol. 2019;11(2):133-143. [DOI] [PMC free article] [PubMed] [Google Scholar]
205. Gerhart-Hines Z, Rodgers JT, Bare O, et al. Metabolic control of muscle mitochondrial function and fatty acid oxidation through SIRT1/PGC-1alpha. EMBO J. 2007;26(7):1913-1923. [DOI] [PMC free article] [PubMed] [Google Scholar]
206. Schenk S, McCurdy CE, Philp A, et al. Sirt1 enhances skeletal muscle insulin sensitivity in mice during caloric restriction. J Clin Invest. 2011;121(11):4281-4288. [DOI] [PMC free article] [PubMed] [Google Scholar]
207. White AT, Philp A, Fridolfsson HN, et al. High-fat diet-induced impairment of skeletal muscle insulin sensitivity is not prevented by SIRT1 overexpression. Am J Physiol Endocrinol Metab. 2014;307(9):E764-E772. [DOI] [PMC free article] [PubMed] [Google Scholar]
208. Kang JH, Park JE, Dagoon J, et al. Sirtuin 1 is not required for contraction-stimulated glucose uptake in mouse skeletal muscle. J Appl Physiol (1985). 2021;130(6):1893-1902. [DOI] [PMC free article] [PubMed] [Google Scholar]
209. Philp A, Chen A, Lan D, et al. Sirtuin 1 (SIRT1) deacetylase activity is not required for mitochondrial biogenesis or peroxisome proliferator-activated receptor-gamma coactivator-1alpha (PGC-1alpha) deacetylation following endurance exercise. J Biol Chem. 2011;286(35):30561-30570. [DOI] [PMC free article] [PubMed] [Google Scholar]
210. Dent JR, Martins VF, Svensson K, et al. Muscle-specific knockout of general control of amino acid synthesis 5 (GCN5) does not enhance basal or endurance exercise-induced mitochondrial adaptation. Mol Metab. 2017;6(12):1574-1584. [DOI] [PMC free article] [PubMed] [Google Scholar]
211. Martins VF, Dent JR, Svensson K, et al. Germline or inducible knockout of p300 or CBP in skeletal muscle does not alter insulin sensitivity. Am J Physiol Endocrinol Metab. 2019;316(6):E1024-E1035. [DOI] [PMC free article] [PubMed] [Google Scholar]
212. LaBarge SA, Migdal CW, Buckner EH, et al. p300 is not required for metabolic adaptation to endurance exercise training. FASEB J. 2016;30(4):1623-1633. [DOI] [PMC free article] [PubMed] [Google Scholar]
213. Svensson K, LaBarge SA, Sathe A, et al. p300 and cAMP response element-binding protein-binding protein in skeletal muscle homeostasis, contractile function, and survival. J Cachexia Sarcopenia Muscle. 2020;11(2):464-477. [DOI] [PMC free article] [PubMed] [Google Scholar]
214. Muoio DM, Noland RC, Kovalik JP, et al. Muscle-specific deletion of carnitine acetyltransferase compromises glucose tolerance and metabolic flexibility. Cell Metab. 2012;15(5):764-777. [DOI] [PMC free article] [PubMed] [Google Scholar]
215. Hirschey MD, Shimazu T, Jing E, et al. SIRT3 deficiency and mitochondrial protein hyperacetylation accelerate the development of the metabolic syndrome. Mol Cell. 2011;44(2):177-190. [DOI] [PMC free article] [PubMed] [Google Scholar]
216. Lantier L, Williams AS, Williams IM, et al. SIRT3 is crucial for maintaining skeletal muscle insulin action and protects against severe insulin resistance in high-fat-fed mice. Diabetes. 2015;64(9):3081-3092. [DOI] [PMC free article] [PubMed] [Google Scholar]
217. Jing E, O’Neill BT, Rardin MJ, et al. Sirt3 regulates metabolic flexibility of skeletal muscle through reversible enzymatic deacetylation. Diabetes. 2013;62(10):3404-3417. [DOI] [PMC free article] [PubMed] [Google Scholar]
218. Constantin-Teodosiu D, Constantin D, Stephens F, Laithwaite D, Greenhaff PL. The role of FOXO and PPAR transcription factors in diet-mediated inhibition of PDC activation and carbohydrate oxidation during exercise in humans and the role of pharmacological activation of PDC in overriding these changes. Diabetes. 2012;61(5):1017-1024. [DOI] [PMC free article] [PubMed] [Google Scholar]
219. Stocks B, Ashcroft SP, Joanisse S, et al. Nicotinamide riboside supplementation does not alter whole-body or skeletal muscle metabolic responses to a single bout of endurance exercise. J Physiol. 2021;599(5):1513-1531. [DOI] [PubMed] [Google Scholar]
220. Cantó C, Jiang LQ, Deshmukh AS, et al. Interdependence of AMPK and SIRT1 for metabolic adaptation to fasting and exercise in skeletal muscle. Cell Metab. 2010;11(3):213-219. [DOI] [PMC free article] [PubMed] [Google Scholar]
221. Henriksson J, Katz A, Sahlin K. Redox state changes in human skeletal muscle after isometric contraction. J Physiol. 1986;380(1):441-451. [DOI] [PMC free article] [PubMed] [Google Scholar]
222. Sahlin K. NADH in human skeletal muscle during short-term intense exercise. Pflugers Arch. 1985;403(2):193-196. [DOI] [PubMed] [Google Scholar]
223. Sahlin K, Katz A, Henriksson J. Redox state and lactate accumulation in human skeletal muscle during dynamic exercise. Biochem J. 1987;245(2):551-556. [DOI] [PMC free article] [PubMed] [Google Scholar]
224. McGee SL, Fairlie E, Garnham AP, Hargreaves M. Exercise-induced histone modifications in human skeletal muscle. J Physiol. 2009;587(Pt 24):5951-5958. [DOI] [PMC free article] [PubMed] [Google Scholar]
225. Weinert BT, Moustafa T, Iesmantavicius V, Zechner R, Choudhary C. Analysis of acetylation stoichiometry suggests that SIRT3 repairs nonenzymatic acetylation lesions. EMBO J. 2015;34(21):2620-2632. [DOI] [PMC free article] [PubMed] [Google Scholar]
226. Ren W, Jhala US, Du K. Proteomic analysis of protein palmitoylation in adipocytes. Adipocyte. 2013;2(1):17-28. [DOI] [PMC free article] [PubMed] [Google Scholar]
227. Hirschey MD, Zhao Y. Metabolic regulation by lysine malonylation, succinylation, and glutarylation. Mol Cell Proteomics. 2015;14(9):2308-2315. [DOI] [PMC free article] [PubMed] [Google Scholar]
228. Bandyopadhyay GK, Yu JG, Ofrecio J, Olefsky JM. Increased malonyl-CoA levels in muscle from obese and type 2 diabetic subjects lead to decreased fatty acid oxidation and increased lipogenesis; thiazolidinedione treatment reverses these defects. Diabetes. 2006;55(8):2277-2285. [DOI] [PubMed] [Google Scholar]
229. Odland LM, Howlett RA, Heigenhauser GJ, Hultman E, Spriet LL. Skeletal muscle malonyl-CoA content at the onset of exercise at varying power outputs in humans. Am J Physiol. 1998;274(6):E1080-E1085. [DOI] [PubMed] [Google Scholar]
230. Odland LM, Heigenhauser GJ, Lopaschuk GD, Spriet LL. Human skeletal muscle malonyl-CoA at rest and during prolonged submaximal exercise. Am J Physiol. 1996;270(3 Pt 1):E541-E544. [DOI] [PubMed] [Google Scholar]
231. Zhao Z, Lee YJ, Kim SK, et al. Rosiglitazone and fenofibrate improve insulin sensitivity of pre-diabetic OLETF rats by reducing malonyl-CoA levels in the liver and skeletal muscle. Life Sci. 2009;84(19-20):688-695. [DOI] [PMC free article] [PubMed] [Google Scholar]
232. Du K, Murakami S, Sun Y, Kilpatrick CL, Luscher B. DHHC7 palmitoylates glucose transporter 4 (Glut4) and regulates Glut4 membrane translocation. J Biol Chem. 2017;292(7):2979-2991. [DOI] [PMC free article] [PubMed] [Google Scholar]
233. Ren W, Sun Y, Du K. Glut4 palmitoylation at Cys223 plays a critical role in Glut4 membrane trafficking. Biochem Biophys Res Commun. 2015;460(3):709-714. [DOI] [PMC free article] [PubMed] [Google Scholar]
234. Bai P, Canto C, Brunyánszki A, et al. PARP-2 regulates SIRT1 expression and whole-body energy expenditure. Cell Metab. 2011;13(4):450-460. [DOI] [PMC free article] [PubMed] [Google Scholar]
235. Bai P, Cantó C, Oudart H, et al. PARP-1 inhibition increases mitochondrial metabolism through SIRT1 activation. Cell Metab. 2011;13(4):461-468. [DOI] [PMC free article] [PubMed] [Google Scholar]
236. Mohamed JS, Hajira A, Pardo PS, Boriek AM. MicroRNA-149 inhibits PARP-2 and promotes mitochondrial biogenesis via SIRT-1/PGC-1α network in skeletal muscle. Diabetes. 2014;63(5):1546-1559. [DOI] [PubMed] [Google Scholar]
237. Pirinen E, Cantó C, Jo YS, et al. Pharmacological Inhibition of poly(ADP-ribose) polymerases improves fitness and mitochondrial function in skeletal muscle. Cell Metab. 2014;19(6):1034-1041. [DOI] [PMC free article] [PubMed] [Google Scholar]
238. Leutert M, Menzel S, Braren R, et al. Proteomic characterization of the heart and skeletal muscle reveals widespread arginine ADP-ribosylation by the ARTC1 ectoenzyme. Cell Rep. 2018;24(7):1916-1929.e5. [DOI] [PubMed] [Google Scholar]
239. Hendriks IA, Larsen SC, Nielsen ML. An advanced strategy for comprehensive profiling of ADP-ribosylation sites using mass spectrometry-based proteomics. Mol Cell Proteomics. 2019;18(5):1010-1026. [DOI] [PMC free article] [PubMed] [Google Scholar]
240. Pezzolesi MG, Nam M, Nagase T, et al. Examination of candidate chromosomal regions for type 2 diabetes reveals a susceptibility locus on human chromosome 8p23.1. Diabetes. 2004;53(2):486-491. [DOI] [PubMed] [Google Scholar]
241. Scherag A, Dina C, Hinney A, et al. Two new Loci for body-weight regulation identified in a joint analysis of genome-wide association studies for early-onset extreme obesity in French and german study groups. PLoS Genet. 2010;6(4):e1000916. [DOI] [PMC free article] [PubMed] [Google Scholar]
242. Zhong L, Ding Y, Bandyopadhyay G, et al. The PARsylation activity of tankyrase in adipose tissue modulates systemic glucose metabolism in mice. Diabetologia. 2016;59(3):582-591. [DOI] [PubMed] [Google Scholar]
243. Wang H, Kuusela S, Rinnankoski-Tuikka R, et al. Tankyrase inhibition ameliorates lipid disorder via suppression of PGC-1α PARylation in db/db mice. Int J Obes (Lond). 2020;44(8):1691-1702. [DOI] [PMC free article] [PubMed] [Google Scholar]
244. Chi NW, Lodish HF. Tankyrase is a golgi-associated mitogen-activated protein kinase substrate that interacts with IRAP in GLUT4 vesicles. J Biol Chem. 2000;275(49):38437-38444. [DOI] [PubMed] [Google Scholar]
245. Yeh TY, Sbodio JI, Tsun ZY, Luo B, Chi NW. Insulin-stimulated exocytosis of GLUT4 is enhanced by IRAP and its partner tankyrase. Biochem J. 2007;402(2):279-290. [DOI] [PMC free article] [PubMed] [Google Scholar]
246. Mohamed JS, Wilson JC, Myers MJ, Sisson KJ, Alway SE. Dysregulation of SIRT-1 in aging mice increases skeletal muscle fatigue by a PARP-1-dependent mechanism. Aging (Albany NY). 2014;6(10):820-834. [DOI] [PMC free article] [PubMed] [Google Scholar]
247. Stocks B, Ashcroft SP, Joanisse S, et al. Nicotinamide riboside supplementation does not alter whole-body or skeletal muscle metabolic responses to a single bout of endurance exercise. J Physiol. 2021;599(5):1513-1531. [DOI] [PubMed] [Google Scholar]
248. Cobley JN, Sakellariou GK, Murray S, et al. Lifelong endurance training attenuates age-related genotoxic stress in human skeletal muscle. Longev Healthspan. 2013;2(1):11. [DOI] [PMC free article] [PubMed] [Google Scholar]
249. Deshmukh AS, Murgia M, Nagaraj N, Treebak JT, Cox J, Mann M. Deep proteomics of mouse skeletal muscle enables quantitation of protein isoforms, metabolic pathways, and transcription factors. Mol Cell Proteomics. 2015;14(4):841-853. [DOI] [PMC free article] [PubMed] [Google Scholar]
250. Demichev V, Messner CB, Vernardis SI, Lilley KS, Ralser M. DIA-NN: neural networks and interference correction enable deep proteome coverage in high throughput. Nat Methods. 2020;17(1):41-44. [DOI] [PMC free article] [PubMed] [Google Scholar]
251. Bekker-Jensen DB, Martínez-Val A, Steigerwald S, et al. A compact quadrupole-orbitrap mass spectrometer with FAIMS interface improves proteome coverage in short LC gradients. Mol Cell Proteomics. 2020;19(4):716-729. [DOI] [PMC free article] [PubMed] [Google Scholar]
252. Hansen FM, Tanzer MC, Brüning F, et al. Data-independent acquisition method for ubiquitinome analysis reveals regulation of circadian biology. Nat Commun. 2021;12(1):254. [DOI] [PMC free article] [PubMed] [Google Scholar]
253. Humphrey SJ, Karayel O, James DE, Mann M. High-throughput and high-sensitivity phosphoproteomics with the EasyPhos platform. Nat Protoc. 2018;13(9):1897-1916. [DOI] [PubMed] [Google Scholar]
254. Ludwig C, Gillet L, Rosenberger G, Amon S, Collins BC, Aebersold R. Data-independent acquisition-based SWATH-MS for quantitative proteomics: a tutorial. Mol Syst Biol. 2018;14(8):e8126. [DOI] [PMC free article] [PubMed] [Google Scholar]
255. Abbott MJ, Edelman AM, Turcotte LP. CaMKK is an upstream signal of AMP-activated protein kinase in regulation of substrate metabolism in contracting skeletal muscle. Am J Physiol Regul Integr Comp Physiol. 2009;297(6):R1724-R1732. [DOI] [PubMed] [Google Scholar]
256. Hawley SA, Pan DA, Mustard KJ, et al. Calmodulin-dependent protein kinase kinase-beta is an alternative upstream kinase for AMP-activated protein kinase. Cell Metab. 2005;2(1):9-19. [DOI] [PubMed] [Google Scholar]
257. Hurley RL, Anderson KA, Franzone JM, Kemp BE, Means AR, Witters LA. The Ca2+/calmodulin-dependent protein kinase kinases are AMP-activated protein kinase kinases. J Biol Chem. 2005;280(32):29060-29066. [DOI] [PubMed] [Google Scholar]
258. Sakamoto K, McCarthy A, Smith D, et al. Deficiency of LKB1 in skeletal muscle prevents AMPK activation and glucose uptake during contraction. EMBO J. 2005;24(10):1810-1820. [DOI] [PMC free article] [PubMed] [Google Scholar]
259. Thomson DM, Porter BB, Tall JH, Kim HJ, Barrow JR, Winder WW. Skeletal muscle and heart LKB1 deficiency causes decreased voluntary running and reduced muscle mitochondrial marker enzyme expression in mice. Am J Physiol Endocrinol Metab. 2007;292(1):E196-E202. [DOI] [PubMed] [Google Scholar]
260. Jørgensen SB, Nielsen JN, Birk JB, et al. The alpha2-5’AMP-activated protein kinase is a site 2 glycogen synthase kinase in skeletal muscle and is responsive to glucose loading. Diabetes. 2004;53(12):3074-3081. [DOI] [PubMed] [Google Scholar]
261. Vavvas D, Apazidis A, Saha AK, et al. Contraction-induced changes in acetyl-CoA carboxylase and 5’-AMP-activated kinase in skeletal muscle. J Biol Chem. 1997;272(20):13255-13261. [DOI] [PubMed] [Google Scholar]
262. Inoki K, Zhu T, Guan KL. TSC2 mediates cellular energy response to control cell growth and survival. Cell. 2003;115(5):577-590. [DOI] [PubMed] [Google Scholar]
263. Ojuka EO, Jones TE, Nolte LA, et al. Regulation of GLUT4 biogenesis in muscle: evidence for involvement of AMPK and Ca⁽²⁺⁾. Am J Physiol Endocrinol Metab. 2002;282(5): E1008-E1013. [DOI] [PubMed] [Google Scholar]
264. Jäger S, Handschin C, St-Pierre J, Spiegelman BM. AMP-activated protein kinase (AMPK) action in skeletal muscle via direct phosphorylation of PGC-1alpha. Proc Natl Acad Sci U S A. 2007;104(29):12017-12022. [DOI] [PMC free article] [PubMed] [Google Scholar]
265. Puigserver P, Rhee J, Lin J, et al. Cytokine stimulation of energy expenditure through p38 MAP kinase activation of PPARgamma coactivator-1. Mol Cell. 2001;8(5):971-982. [DOI] [PubMed] [Google Scholar]
266. McGee SL, Hargreaves M. Exercise and myocyte enhancer factor 2 regulation in human skeletal muscle. Diabetes. 2004;53(5):1208-1214. [DOI] [PubMed] [Google Scholar]
267. Zhao M, New L, Kravchenko VV, et al. Regulation of the MEF2 family of transcription factors by p38. Mol Cell Biol. 1999;19(1):21-30. [DOI] [PMC free article] [PubMed] [Google Scholar]
268. Mehrani H, Storey KB. Control of glycogenolysis and effects of exercise on phosphorylase kinase and cAMP-dependent protein kinase in rainbow trout organs. Biochem Cell Biol. 1993;71(11-12):501-506. [DOI] [PubMed] [Google Scholar]
269. Ray Hamidie RD, Yamada T, Ishizawa R, Saito Y, Masuda K. Curcumin treatment enhances the effect of exercise on mitochondrial biogenesis in skeletal muscle by increasing cAMP levels. Metabolism. 2015;64(10):1334-1347. [DOI] [PubMed] [Google Scholar]

[CIT0001] 1. Cho NH, Shaw JE, Karuranga S, et al. IDF Diabetes Atlas: global estimates of diabetes prevalence for 2017 and projections for 2045. Diabetes Res Clin Pract. 2018;138:271-281. [DOI] [PubMed] [Google Scholar]

[CIT0002] 2. Lin X, Xu Y, Pan X, et al. Global, regional, and national burden and trend of diabetes in 195 countries and territories: an analysis from 1990 to 2025. Sci Rep. 2020;10(1):14790. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0003] 3. Yang JJ, Yu D, Wen W, et al. Association of diabetes with all-cause and cause-specific mortality in Asia: a pooled analysis of more than 1 million participants. JAMA Netw Open. 2019;2(4):e192696. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0004] 4. Talmud PJ, Hingorani AD, Cooper JA, et al. Utility of genetic and non-genetic risk factors in prediction of type 2 diabetes: Whitehall II prospective cohort study. BMJ. 2010;340:b4838. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0005] 5. Hu FB, Li TY, Colditz GA, Willett WC, Manson JE. Television watching and other sedentary behaviors in relation to risk of obesity and type 2 diabetes mellitus in women. JAMA. 2003;289(14):1785-1791. [DOI] [PubMed] [Google Scholar]

[CIT0006] 6. Mokdad AH, Ford ES, Bowman BA, et al. Prevalence of obesity, diabetes, and obesity-related health risk factors, 2001. JAMA. 2003;289(1):76-79. [DOI] [PubMed] [Google Scholar]

[CIT0007] 7. Murray CJL, Aravkin AY, Zheng P, et al. Global burden of 87 risk factors in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet. 2020;396(10258):1223-1249. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0008] 8. Thiebaud D, Jacot E, DeFronzo RA, Maeder E, Jequier E, Felber JP. The effect of graded doses of insulin on total glucose uptake, glucose oxidation, and glucose storage in man. Diabetes. 1982;31(11):957-963. [DOI] [PubMed] [Google Scholar]

[CIT0009] 9. Zierath JR, He L, Gumà A, Odegoard Wahlström E, Klip A, Wallberg-Henriksson H. Insulin action on glucose transport and plasma membrane GLUT4 content in skeletal muscle from patients with NIDDM. Diabetologia. 1996;39(10):1180-1189. [DOI] [PubMed] [Google Scholar]

[CIT0010] 10. DeFronzo RA, Tripathy D. Skeletal muscle insulin resistance is the primary defect in type 2 diabetes. Diabetes Care. 2009;32(Suppl 2):S157-S163. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0011] 11. Edinburgh RM, Bradley HE, Abdullah NF, et al. Lipid metabolism links nutrient-exercise timing to insulin sensitivity in men classified as overweight or obese. J Clin Endocrinol Metab. 2020;105(3):660-676. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0012] 12. Ivey FM, Ryan AS, Hafer-Macko CE, Goldberg AP, Macko RF. Treadmill aerobic training improves glucose tolerance and indices of insulin sensitivity in disabled stroke survivors: a preliminary report. Stroke. 2007;38(10):2752-2758. [DOI] [PubMed] [Google Scholar]

[CIT0013] 13. Kirwan JP, Solomon TP, Wojta DM, Staten MA, Holloszy JO. Effects of 7 days of exercise training on insulin sensitivity and responsiveness in type 2 diabetes mellitus. Am J Physiol Endocrinol Metab. 2009;297(1):E151-E156. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0014] 14. Nassis GP, Papantakou K, Skenderi K, et al. Aerobic exercise training improves insulin sensitivity without changes in body weight, body fat, adiponectin, and inflammatory markers in overweight and obese girls. Metabolism. 2005;54(11):1472-1479. [DOI] [PubMed] [Google Scholar]

[CIT0015] 15. Dela F, Larsen JJ, Mikines KJ, Ploug T, Petersen LN, Galbo H. Insulin-stimulated muscle glucose clearance in patients with NIDDM. Effects of one-legged physical training. Diabetes. 1995;44(9):1010-1020. [DOI] [PubMed] [Google Scholar]

[CIT0016] 16. Coen PM, Tanner CJ, Helbling NL, et al. Clinical trial demonstrates exercise following bariatric surgery improves insulin sensitivity. J Clin Invest. 2015;125(1):248-257. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0017] 17. Knowler WC, Barrett-Connor E, Fowler SE, et al. ; Diabetes Prevention Program Research Group . Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med. 2002;346(6):393-403. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0018] 18. Taheri S, Zaghloul H, Chagoury O, et al. Effect of intensive lifestyle intervention on bodyweight and glycaemia in early type 2 diabetes (DIADEM-I): an open-label, parallel-group, randomised controlled trial. Lancet Diabetes Endocrinol. 2020;8(6):477-489. [DOI] [PubMed] [Google Scholar]

[CIT0019] 19. van Loon LJ, Greenhaff PL, Constantin-Teodosiu D, Saris WH, Wagenmakers AJ. The effects of increasing exercise intensity on muscle fuel utilisation in humans. J Physiol. 2001;536(Pt 1):295-304. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0020] 20. Goldstein MS, Mullick V, Huddlestun B, Levine R. Action of muscular work on transfer of sugars across cell barriers; comparison with action of insulin. Am J Physiol. 1953;173(2):212-216. [DOI] [PubMed] [Google Scholar]

[CIT0021] 21. Huycke EJ, Kruhoffer P. Effects of insulin and muscular exercise upon the uptake of hexoses by muscle cells. Acta Physiol Scand. 1955;34(2-3):232-249. [DOI] [PubMed] [Google Scholar]

[CIT0022] 22. Reichard GA, Issekutz B Jr, Kimbel P, Putnam RC, Hochella NJ, Weinhouse S. Blood glucose metabolism in man during muscular work. J Appl Physiol. 1961;16(6):1001-1005. [DOI] [PubMed] [Google Scholar]

[CIT0023] 23. Ploug T, Galbo H, Richter EA. Increased muscle glucose uptake during contractions: no need for insulin. Am J Physiol. 1984;247(6 Pt 1):E726-E731. [DOI] [PubMed] [Google Scholar]

[CIT0024] 24. Wojtaszewski JF, Higaki Y, Hirshman MF, et al. Exercise modulates postreceptor insulin signaling and glucose transport in muscle-specific insulin receptor knockout mice. J Clin Invest. 1999;104(9):1257-1264. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0025] 25. Mikines KJ, Sonne B, Farrell PA, Tronier B, Galbo H. Effect of physical exercise on sensitivity and responsiveness to insulin in humans. Am J Physiol. 1988;254(3 Pt 1):E248-E259. [DOI] [PubMed] [Google Scholar]

[CIT0026] 26. Devlin JT, Horton ES. Effects of prior high-intensity exercise on glucose metabolism in normal and insulin-resistant men. Diabetes. 1985;34(10):973-979. [DOI] [PubMed] [Google Scholar]

[CIT0027] 27. Price TB, Rothman DL, Taylor R, Avison MJ, Shulman GI, Shulman RG. Human muscle glycogen resynthesis after exercise: insulin-dependent and -independent phases. J Appl Physiol (1985). 1994;76(1):104-111. [DOI] [PubMed] [Google Scholar]

[CIT0028] 28. Birnbaum MJ. Identification of a novel gene encoding an insulin-responsive glucose transporter protein. Cell. 1989;57(2):305-315. [DOI] [PubMed] [Google Scholar]

[CIT0029] 29. Charron MJ, Brosius FC 3rd, Alper SL, Lodish HF. A glucose transport protein expressed predominately in insulin-responsive tissues. Proc Natl Acad Sci U S A. 1989;86(8):2535-2539. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0030] 30. James DE, Strube M, Mueckler M. Molecular cloning and characterization of an insulin-regulatable glucose transporter. Nature. 1989;338(6210):83-87. [DOI] [PubMed] [Google Scholar]

[CIT0031] 31. Ryder JW, Kawano Y, Chibalin AV, et al. In vitro analysis of the glucose-transport system in GLUT4-null skeletal muscle. Biochem J. 1999;342(Pt 2):321-328. [PMC free article] [PubMed] [Google Scholar]

[CIT0032] 32. Ryder JW, Yang J, Galuska D, et al. Use of a novel impermeable biotinylated photolabeling reagent to assess insulin- and hypoxia-stimulated cell surface GLUT4 content in skeletal muscle from type 2 diabetic patients. Diabetes. 2000;49(4):647-654. [DOI] [PubMed] [Google Scholar]

[CIT0033] 33. Koistinen HA, Galuska D, Chibalin AV, et al. 5-amino-imidazole carboxamide riboside increases glucose transport and cell-surface GLUT4 content in skeletal muscle from subjects with type 2 diabetes. Diabetes. 2003;52(5):1066-1072. [DOI] [PubMed] [Google Scholar]

[CIT0034] 34. Karlsson HK, Chibalin AV, Koistinen HA, et al. Kinetics of GLUT4 trafficking in rat and human skeletal muscle. Diabetes. 2009;58(4):847-854. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0035] 35. Furuzono S, Kubota T, Taura J, et al. A xanthene derivative, DS20060511, attenuates glucose intolerance by inducing skeletal muscle-specific GLUT4 translocation in mice. Commun Biol. 2021;4(1):994. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0036] 36. Ploug T, Ralston E. Anatomy of glucose transporters in skeletal muscle. Effects of insulin and contractions. Adv Exp Med Biol. 1998;441:17-26. [DOI] [PubMed] [Google Scholar]

[CIT0037] 37. Andersen P, Saltin B. Maximal perfusion of skeletal muscle in man. J Physiol. 1985;366(1):233-249. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0038] 38. Kennedy JW, Hirshman MF, Gervino EV, et al. Acute exercise induces GLUT4 translocation in skeletal muscle of normal human subjects and subjects with type 2 diabetes. Diabetes. 1999;48(5):1192-1197. [DOI] [PubMed] [Google Scholar]

[CIT0039] 39. Kristiansen S, Hargreaves M, Richter EA. Exercise-induced increase in glucose transport, GLUT-4, and VAMP-2 in plasma membrane from human muscle. Am J Physiol. 1996;270(1 Pt 1):E197-E201. [DOI] [PubMed] [Google Scholar]

[CIT0040] 40. Kristiansen S, Hargreaves M, Richter EA. Progressive increase in glucose transport and GLUT-4 in human sarcolemmal vesicles during moderate exercise. Am J Physiol. 1997;272(3 Pt 1):E385-E389. [DOI] [PubMed] [Google Scholar]

[CIT0041] 41. Lauritzen HP, Galbo H, Toyoda T, Goodyear LJ. Kinetics of contraction-induced GLUT4 translocation in skeletal muscle fibers from living mice. Diabetes. 2010;59(9):2134-2144. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0042] 42. Goodyear LJ, Hirshman MF, King PA, Horton ED, Thompson CM, Horton ES. Skeletal muscle plasma membrane glucose transport and glucose transporters after exercise. J Appl Physiol (1985). 1990;68(1):193-198. [DOI] [PubMed] [Google Scholar]

[CIT0043] 43. Hansen PA, Nolte LA, Chen MM, Holloszy JO. Increased GLUT-4 translocation mediates enhanced insulin sensitivity of muscle glucose transport after exercise. J Appl Physiol (1985). 1998;85(4):1218-1222. [DOI] [PubMed] [Google Scholar]

[CIT0044] 44. Thorell A, Hirshman MF, Nygren J, et al. Exercise and insulin cause GLUT-4 translocation in human skeletal muscle. Am J Physiol. 1999;277(4):E733-E741. [DOI] [PubMed] [Google Scholar]

[CIT0045] 45. Fazakerley DJ, Holman GD, Marley A, James DE, Stöckli J, Coster AC. Kinetic evidence for unique regulation of GLUT4 trafficking by insulin and AMP-activated protein kinase activators in L6 myotubes. J Biol Chem. 2010;285(3):1653-1660. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0046] 46. Yang J, Holman GD. Insulin and contraction stimulate exocytosis, but increased AMP-activated protein kinase activity resulting from oxidative metabolism stress slows endocytosis of GLUT4 in cardiomyocytes. J Biol Chem. 2005;280(6):4070-4078. [DOI] [PubMed] [Google Scholar]

[CIT0047] 47. Ryder JW, Kawano Y, Galuska D, et al. Postexercise glucose uptake and glycogen synthesis in skeletal muscle from GLUT4-deficient mice. FASEB J. 1999;13(15):2246-2256. [DOI] [PubMed] [Google Scholar]

[CIT0048] 48. Zisman A, Peroni OD, Abel ED, et al. Targeted disruption of the glucose transporter 4 selectively in muscle causes insulin resistance and glucose intolerance. Nat Med. 2000;6(8):924-928. [DOI] [PubMed] [Google Scholar]

[CIT0049] 49. Fueger PT, Li CY, Ayala JE, et al. Glucose kinetics and exercise tolerance in mice lacking the GLUT4 glucose transporter. J Physiol. 2007;582(Pt 2):801-812. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0050] 50. Martin IK, Katz A, Wahren J. Splanchnic and muscle metabolism during exercise in NIDDM patients. Am J Physiol. 1995;269(3 Pt 1):E583-E590. [DOI] [PubMed] [Google Scholar]

[CIT0051] 51. Bogardus C, Thuillez P, Ravussin E, Vasquez B, Narimiga M, Azhar S. Effect of muscle glycogen depletion on in vivo insulin action in man. J Clin Invest. 1983;72(5):1605-1610. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0052] 52. Steenberg DE, Jørgensen NB, Birk JB, et al. Exercise training reduces the insulin-sensitizing effect of a single bout of exercise in human skeletal muscle. J Physiol. 2019;597(1):89-103. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0053] 53. Richter EA, Mikines KJ, Galbo H, Kiens B. Effect of exercise on insulin action in human skeletal muscle. J Appl Physiol (1985). 1989;66(2):876-885. [DOI] [PubMed] [Google Scholar]

[CIT0054] 54. Wojtaszewski JF, Hansen BF, Gade, et al. Insulin signaling and insulin sensitivity after exercise in human skeletal muscle. Diabetes. 2000;49(3):325-331. [DOI] [PubMed] [Google Scholar]

[CIT0055] 55. Wojtaszewski JF, Hansen BF, Kiens B, Richter EA. Insulin signaling in human skeletal muscle: time course and effect of exercise. Diabetes. 1997;46(11):1775-1781. [DOI] [PubMed] [Google Scholar]

[CIT0056] 56. Frøsig C, Sajan MP, Maarbjerg SJ, et al. Exercise improves phosphatidylinositol-3,4,5-trisphosphate responsiveness of atypical protein kinase C and interacts with insulin signalling to peptide elongation in human skeletal muscle. J Physiol. 2007;582(Pt 3):1289-1301. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0057] 57. Heath GW, Gavin JR 3rd, Hinderliter JM, Hagberg JM, Bloomfield SA, Holloszy JO. Effects of exercise and lack of exercise on glucose tolerance and insulin sensitivity. J Appl Physiol Respir Environ Exerc Physiol. 1983;55(2):512-517. [DOI] [PubMed] [Google Scholar]

[CIT0058] 58. McConell GK, Sjøberg KA, Ceutz F, et al. Insulin-induced membrane permeability to glucose in human muscles at rest and following exercise. J Physiol. 2020;598(2):303-315. [DOI] [PubMed] [Google Scholar]

[CIT0059] 59. Sjøberg KA, Frøsig C, Kjøbsted R, et al. Exercise increases human skeletal muscle insulin sensitivity via coordinated increases in microvascular perfusion and molecular signaling. Diabetes. 2017;66(6):1501-1510. [DOI] [PubMed] [Google Scholar]

[CIT0060] 60. Knudsen JR, Steenberg DE, Hingst JR, et al. Prior exercise in humans redistributes intramuscular GLUT4 and enhances insulin-stimulated sarcolemmal and endosomal GLUT4 translocation. Mol Metab. 2020;39:100998. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0061] 61. Young DA, Wallberg-Henriksson H, Sleeper MD, Holloszy JO. Reversal of the exercise-induced increase in muscle permeability to glucose. Am J Physiol. 1987;253(4 Pt 1):E331-E335. [DOI] [PubMed] [Google Scholar]

[CIT0062] 62. Cartee GD, Young DA, Sleeper MD, Zierath J, Wallberg-Henriksson H, Holloszy JO. Prolonged increase in insulin-stimulated glucose transport in muscle after exercise. Am J Physiol. 1989;256(4 Pt 1):E494-E499. [DOI] [PubMed] [Google Scholar]

[CIT0063] 63. Host HH, Hansen PA, Nolte LA, Chen MM, Holloszy JO. Glycogen supercompensation masks the effect of a training induced increase in GLUT-4 on muscle glucose transport. J Appl Physiol (1985). 1998;85(1):133-138. [DOI] [PubMed] [Google Scholar]

[CIT0064] 64. Kawanaka K, Han DH, Nolte LA, Hansen PA, Nakatani A, Holloszy JO. Decreased insulin-stimulated GLUT-4 translocation in glycogen-supercompensated muscles of exercised rats. Am J Physiol. 1999;276(5):E907-E912. [DOI] [PubMed] [Google Scholar]

[CIT0065] 65. Kawanaka K, Nolte LA, Han DH, Hansen PA, Holloszy JO. Mechanisms underlying impaired GLUT-4 translocation in glycogen-supercompensated muscles of exercised rats. Am J Physiol Endocrinol Metab. 2000;279(6):E1311-E1318. [DOI] [PubMed] [Google Scholar]

[CIT0066] 66. Nielsen JN, Vissing J, Wojtaszewski JF, Haller RG, Begum N, Richter EA. Decreased insulin action in skeletal muscle from patients with McArdle’s disease. Am J Physiol Endocrinol Metab. 2002;282(6):E1267-E1275. [DOI] [PubMed] [Google Scholar]

[CIT0067] 67. Meex RC, Schrauwen-Hinderling VB, Moonen-Kornips E, et al. Restoration of muscle mitochondrial function and metabolic flexibility in type 2 diabetes by exercise training is paralleled by increased myocellular fat storage and improved insulin sensitivity. Diabetes. 2010;59(3):572-579. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0068] 68. O’Gorman DJ, Karlsson HK, McQuaid S, et al. Exercise training increases insulin-stimulated glucose disposal and GLUT4 (SLC2A4) protein content in patients with type 2 diabetes. Diabetologia. 2006;49(12):2983-2992. [DOI] [PubMed] [Google Scholar]

[CIT0069] 69. Andersen P, Henriksson J. Capillary supply of the quadriceps femoris muscle of man: adaptive response to exercise. J Physiol. 1977;270(3):677-690. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0070] 70. Frøsig C, Rose AJ, Treebak JT, Kiens B, Richter EA, Wojtaszewski JF. Effects of endurance exercise training on insulin signaling in human skeletal muscle: interactions at the level of phosphatidylinositol 3-kinase, Akt, and AS160. Diabetes. 2007;56(8):2093-2102. [DOI] [PubMed] [Google Scholar]

[CIT0071] 71. Daugaard JR, Nielsen JN, Kristiansen S, Andersen JL, Hargreaves M, Richter EA. Fiber type-specific expression of GLUT4 in human skeletal muscle: influence of exercise training. Diabetes. 2000;49(7):1092-1095. [DOI] [PubMed] [Google Scholar]

[CIT0072] 72. Dela F, Handberg A, Mikines KJ, Vinten J, Galbo H. GLUT 4 and insulin receptor binding and kinase activity in trained human muscle. J Physiol. 1993;469(1):615-624. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0073] 73. Gulve EA, Spina RJ. Effect of 7-10 days of cycle ergometer exercise on skeletal muscle GLUT-4 protein content. J Appl Physiol (1985). 1995;79(5):1562-1566. [DOI] [PubMed] [Google Scholar]

[CIT0074] 74. Houmard JA, Shinebarger MH, Dolan PL, et al. Exercise training increases GLUT-4 protein concentration in previously sedentary middle-aged men. Am J Physiol. 1993;264(6 Pt 1):E896-E901. [DOI] [PubMed] [Google Scholar]

[CIT0075] 75. Phillips SM, Han XX, Green HJ, Bonen A. Increments in skeletal muscle GLUT-1 and GLUT-4 after endurance training in humans. Am J Physiol. 1996;270(3 Pt 1):E456-E462. [DOI] [PubMed] [Google Scholar]

[CIT0076] 76. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Training intensity modulates changes in PGC-1α and p53 protein content and mitochondrial respiration, but not markers of mitochondrial content in human skeletal muscle. FASEB J. 2016;30(2):959-970. [DOI] [PubMed] [Google Scholar]

[CIT0077] 77. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Mitochondrial adaptations to high-volume exercise training are rapidly reversed after a reduction in training volume in human skeletal muscle. FASEB J. 2016;30(10):3413-3423. [DOI] [PubMed] [Google Scholar]

[CIT0078] 78. Granata C, Oliveira RS, Little JP, Renner K, Bishop DJ. Sprint-interval but not continuous exercise increases PGC-1α protein content and p53 phosphorylation in nuclear fractions of human skeletal muscle. Sci Rep. 2017;7:44227. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0079] 79. Meinild Lundby AK, Jacobs RA, Gehrig S, et al. Exercise training increases skeletal muscle mitochondrial volume density by enlargement of existing mitochondria and not de novo biogenesis. Acta Physiol. 2018;222(1):e12905. [DOI] [PubMed] [Google Scholar]

[CIT0080] 80. Montero D, Diaz-Cañestro C, Lundby C. Endurance training and V˙O2max: role of maximal cardiac output and oxygen extraction. Med Sci Sports Exerc. 2015;47(10):2024-2033. [DOI] [PubMed] [Google Scholar]

[CIT0081] 81. Hoppeler H, Howald H, Conley K, et al. Endurance training in humans: aerobic capacity and structure of skeletal muscle. J Appl Physiol (1985). 1985;59(2):320-327. [DOI] [PubMed] [Google Scholar]

[CIT0082] 82. Jacobs RA, Flück D, Bonne TC, et al. Improvements in exercise performance with high-intensity interval training coincide with an increase in skeletal muscle mitochondrial content and function. J Appl Physiol (1985). 2013;115(6):785-793. [DOI] [PubMed] [Google Scholar]

[CIT0083] 83. Kelley DE, He J, Menshikova EV, Ritov VB. Dysfunction of mitochondria in human skeletal muscle in type 2 diabetes. Diabetes. 2002;51(10):2944-2950. [DOI] [PubMed] [Google Scholar]

[CIT0084] 84. Petersen KF, Befroy D, Dufour S, et al. Mitochondrial dysfunction in the elderly: possible role in insulin resistance. Science. 2003;300(5622):1140-1142. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0085] 85. Daemen S, Gemmink A, Brouwers B, et al. Distinct lipid droplet characteristics and distribution unmask the apparent contradiction of the athlete’s paradox. Mol Metab. 2018;17:71-81. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0086] 86. Goodpaster BH, He J, Watkins S, Kelley DE. Skeletal muscle lipid content and insulin resistance: evidence for a paradox in endurance-trained athletes. J Clin Endocrinol Metab. 2001;86(12):5755-5761. [DOI] [PubMed] [Google Scholar]

[CIT0087] 87. Krssak M, Falk Petersen K, Dresner A, et al. Intramyocellular lipid concentrations are correlated with insulin sensitivity in humans: a 1H NMR spectroscopy study. Diabetologia. 1999;42(1):113-116. [DOI] [PubMed] [Google Scholar]

[CIT0088] 88. Pan DA, Lillioja S, Kriketos AD, et al. Skeletal muscle triglyceride levels are inversely related to insulin action. Diabetes. 1997;46(6):983-988. [DOI] [PubMed] [Google Scholar]

[CIT0089] 89. White MF, Kahn CR. Insulin action at a molecular level - 100 years of progress. Mol Metab. 2021;52:101304. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0090] 90. Olsen JV, Mann M. Status of large-scale analysis of post-translational modifications by mass spectrometry. Mol Cell Proteomics. 2013;12(12):3444-3452. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0091] 91. Sharma K, D’Souza RC, Tyanova S, et al. Ultradeep human phosphoproteome reveals a distinct regulatory nature of Tyr and Ser/Thr-based signaling. Cell Rep. 2014;8(5):1583-1594. [DOI] [PubMed] [Google Scholar]

[CIT0092] 92. Bouzakri K, Zachrisson A, Al-Khalili L, et al. siRNA-based gene silencing reveals specialized roles of IRS-1/Akt2 and IRS-2/Akt1 in glucose and lipid metabolism in human skeletal muscle. Cell Metab. 2006;4(1):89-96. [DOI] [PubMed] [Google Scholar]

[CIT0093] 93. Wang Q, Somwar R, Bilan PJ, et al. Protein kinase B/Akt participates in GLUT4 translocation by insulin in L6 myoblasts. Mol Cell Biol. 1999;19(6):4008-4018. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0094] 94. Sylow L, Kleinert M, Pehmøller C, et al. Akt and Rac1 signaling are jointly required for insulin-stimulated glucose uptake in skeletal muscle and downregulated in insulin resistance. Cell Signal. 2014;26(2):323-331. [DOI] [PubMed] [Google Scholar]

[CIT0095] 95. Ueda S, Kataoka T, Satoh T. Activation of the small GTPase Rac1 by a specific guanine-nucleotide-exchange factor suffices to induce glucose uptake into skeletal-muscle cells. Biol Cell. 2008;100(11):645-657. [DOI] [PubMed] [Google Scholar]

[CIT0096] 96. JeBailey L, Wanono O, Niu W, Roessler J, Rudich A, Klip A. Ceramide- and oxidant-induced insulin resistance involve loss of insulin-dependent Rac-activation and actin remodeling in muscle cells. Diabetes. 2007;56(2):394-403. [DOI] [PubMed] [Google Scholar]

[CIT0097] 97. Vichaiwong K, Purohit S, An D, et al. Contraction regulates site-specific phosphorylation of TBC1D1 in skeletal muscle. Biochem J. 2010;431(2):311-320. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0098] 98. Roach WG, Chavez JA, Mîinea CP, Lienhard GE. Substrate specificity and effect on GLUT4 translocation of the Rab GTPase-activating protein Tbc1d1. Biochem J. 2007;403(2):353-358. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0099] 99. Chavez JA, Roach WG, Keller SR, Lane WS, Lienhard GE. Inhibition of GLUT4 translocation by Tbc1d1, a Rab GTPase-activating protein abundant in skeletal muscle, is partially relieved by AMP-activated protein kinase activation. J Biol Chem. 2008;283(14):9187-9195. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0100] 100. Thong FS, Bilan PJ, Klip A. The Rab GTPase-activating protein AS160 integrates Akt, protein kinase C, and AMP-activated protein kinase signals regulating GLUT4 traffic. Diabetes. 2007;56(2):414-423. [DOI] [PubMed] [Google Scholar]

[CIT0101] 101. Kane S, Sano H, Liu SC, et al. A method to identify serine kinase substrates. Akt phosphorylates a novel adipocyte protein with a Rab GTPase-activating protein (GAP) domain. J Biol Chem. 2002;277(25):22115-22118. [DOI] [PubMed] [Google Scholar]

[CIT0102] 102. Raun SH, Ali M, Kjøbsted R, et al. Rac1 muscle knockout exacerbates the detrimental effect of high-fat diet on insulin-stimulated muscle glucose uptake independently of Akt. J Physiol. 2018;596(12):2283-2299. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0103] 103. Sylow L, Jensen TE, Kleinert M, et al. Rac1 signaling is required for insulin-stimulated glucose uptake and is dysregulated in insulin-resistant murine and human skeletal muscle. Diabetes. 2013;62(6):1865-1875. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0104] 104. Ueda S, Kitazawa S, Ishida K, et al. Crucial role of the small GTPase Rac1 in insulin-stimulated translocation of glucose transporter 4 to the mouse skeletal muscle sarcolemma. FASEB J. 2010;24(7):2254-2261. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0105] 105. Chiu TT, Patel N, Shaw AE, Bamburg JR, Klip A. Arp2/3- and cofilin-coordinated actin dynamics is required for insulin-mediated GLUT4 translocation to the surface of muscle cells. Mol Biol Cell. 2010;21(20):3529-3539. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0106] 106. Tong P, Khayat ZA, Huang C, Patel N, Ueyama A, Klip A. Insulin-induced cortical actin remodeling promotes GLUT4 insertion at muscle cell membrane ruffles. J Clin Invest. 2001;108(3):371-381. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0107] 107. Nelson ME, Parker BL, Burchfield JG, et al. Phosphoproteomics reveals conserved exercise-stimulated signaling and AMPK regulation of store-operated calcium entry. EMBO J. 2019;38(24):e102578. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0108] 108. Hoffman NJ, Parker BL, Chaudhuri R, et al. Global phosphoproteomic analysis of human skeletal muscle reveals a network of exercise-regulated kinases and AMPK substrates. Cell Metab. 2015;22(5):922-935. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0109] 109. Maier G, Delezie J, Westermark PO, Santos G, Ritz D, Handschin C. Transcriptomic, proteomic and phosphoproteomic underpinnings of daily exercise performance and zeitgeber activity of training in mouse muscle. J Physiol. Published online June 18, 2021. Doi: 10.1113/JP281535 [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0110] 110. Howlett KF, Sakamoto K, Hirshman MF, et al. Insulin signaling after exercise in insulin receptor substrate-2-deficient mice. Diabetes. 2002;51(2):479-483. [DOI] [PubMed] [Google Scholar]

[CIT0111] 111. Koval JA, Maezono K, Patti ME, Pendergrass M, DeFronzo RA, Mandarino LJ. Effects of exercise and insulin on insulin signaling proteins in human skeletal muscle. Med Sci Sports Exerc. 1999;31(7):998-1004. [DOI] [PubMed] [Google Scholar]

[CIT0112] 112. Zhou Q, Dohm GL. Treadmill running increases phosphatidylinostol 3-kinase activity in rat skeletal muscle. Biochem Biophys Res Commun. 1997;236(3):647-650. [DOI] [PubMed] [Google Scholar]

[CIT0113] 113. Whitehead JP, Soos MA, Aslesen R, O’rahilly S, Jensen J. Contraction inhibits insulin-stimulated insulin receptor substrate-1/2-associated phosphoinositide 3-kinase activity, but not protein kinase B activation or glucose uptake, in rat muscle. Biochem J. 2000;349(Pt 3):775-781. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0114] 114. Yeh JI, Gulve EA, Rameh L, Birnbaum MJ. The effects of wortmannin on rat skeletal muscle. Dissociation of signaling pathways for insulin- and contraction-activated hexose transport. J Biol Chem. 1995;270(5):2107-2111. [DOI] [PubMed] [Google Scholar]

[CIT0115] 115. Funai K, Schweitzer GG, Castorena CM, Kanzaki M, Cartee GD. In vivo exercise followed by in vitro contraction additively elevates subsequent insulin-stimulated glucose transport by rat skeletal muscle. Am J Physiol Endocrinol Metab. 2010;298(5):E999-1010. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0116] 116. Goodyear LJ, Giorgino F, Balon TW, Condorelli G, Smith RJ. Effects of contractile activity on tyrosine phosphoproteins and PI 3-kinase activity in rat skeletal muscle. Am J Physiol. 1995;268(5 Pt 1):E987-E995. [DOI] [PubMed] [Google Scholar]

[CIT0117] 117. Treebak JT, Frøsig C, Pehmøller C, et al. Potential role of TBC1D4 in enhanced post-exercise insulin action in human skeletal muscle. Diabetologia. 2009;52(5):891-900. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0118] 118. Treebak JT, Glund S, Deshmukh A, et al. AMPK-mediated AS160 phosphorylation in skeletal muscle is dependent on AMPK catalytic and regulatory subunits. Diabetes. 2006;55(7):2051-2058. [DOI] [PubMed] [Google Scholar]

[CIT0119] 119. Kramer HF, Witczak CA, Fujii N, et al. Distinct signals regulate AS160 phosphorylation in response to insulin, AICAR, and contraction in mouse skeletal muscle. Diabetes. 2006;55(7):2067-2076. [DOI] [PubMed] [Google Scholar]

[CIT0120] 120. Treebak JT, Birk JB, Rose AJ, Kiens B, Richter EA, Wojtaszewski JF. AS160 phosphorylation is associated with activation of alpha2beta2gamma1- but not alpha2beta2gamma3-AMPK trimeric complex in skeletal muscle during exercise in humans. Am J Physiol Endocrinol Metab. 2007;292(3):E715-E722. [DOI] [PubMed] [Google Scholar]

[CIT0121] 121. Schweitzer GG, Arias EB, Cartee GD. Sustained postexercise increases in AS160 Thr642 and Ser588 phosphorylation in skeletal muscle without sustained increases in kinase phosphorylation. J Appl Physiol (1985). 2012;113(12):1852-1861. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0122] 122. Arias EB, Kim J, Funai K, Cartee GD. Prior exercise increases phosphorylation of Akt substrate of 160 kDa (AS160) in rat skeletal muscle. Am J Physiol Endocrinol Metab. 2007;292(4):E1191-E1200. [DOI] [PubMed] [Google Scholar]

[CIT0123] 123. Kramer HF, Witczak CA, Taylor EB, Fujii N, Hirshman MF, Goodyear LJ. AS160 regulates insulin- and contraction-stimulated glucose uptake in mouse skeletal muscle. J Biol Chem. 2006;281(42):31478-31485. [DOI] [PubMed] [Google Scholar]

[CIT0124] 124. Hawley SA, Davison M, Woods A, et al. Characterization of the AMP-activated protein kinase kinase from rat liver and identification of threonine 172 as the major site at which it phosphorylates AMP-activated protein kinase. J Biol Chem. 1996;271(44):27879-27887. [DOI] [PubMed] [Google Scholar]

[CIT0125] 125. Oakhill JS, Chen ZP, Scott JW, et al. β-Subunit myristoylation is the gatekeeper for initiating metabolic stress sensing by AMP-activated protein kinase (AMPK). Proc Natl Acad Sci U S A. 2010;107(45):19237-19241. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0126] 126. Birk JB, Wojtaszewski JF. Predominant alpha2/beta2/gamma3 AMPK activation during exercise in human skeletal muscle. J Physiol. 2006;577(Pt 3):1021-1032. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0127] 127. Fujii N, Hayashi T, Hirshman MF, et al. Exercise induces isoform-specific increase in 5’AMP-activated protein kinase activity in human skeletal muscle. Biochem Biophys Res Commun. 2000;273(3):1150-1155. [DOI] [PubMed] [Google Scholar]

[CIT0128] 128. Stocks B, Dent JR, Ogden HB, Zemp M, Philp A. Postexercise skeletal muscle signaling responses to moderate- to high-intensity steady-state exercise in the fed or fasted state. Am J Physiol Endocrinol Metab. 2019;316(2):E230-E238. [DOI] [PubMed] [Google Scholar]

[CIT0129] 129. Taylor EB, An D, Kramer HF, et al. Discovery of TBC1D1 as an insulin-, AICAR-, and contraction-stimulated signaling nexus in mouse skeletal muscle. J Biol Chem. 2008;283(15):9787-9796. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0130] 130. Kjøbsted R, Chadt A, Jørgensen NO, et al. TBC1D4 is necessary for enhancing muscle insulin sensitivity in response to AICAR and contraction. Diabetes. 2019;68(9):1756-1766. [DOI] [PubMed] [Google Scholar]

[CIT0131] 131. Pehmøller C, Brandt N, Birk JB, et al. Exercise alleviates lipid-induced insulin resistance in human skeletal muscle-signaling interaction at the level of TBC1 domain family member 4. Diabetes. 2012;61(11):2743-2752. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0132] 132. Mu J, Brozinick JT Jr, Valladares O, Bucan M, Birnbaum MJ. A role for AMP-activated protein kinase in contraction- and hypoxia-regulated glucose transport in skeletal muscle. Mol Cell. 2001;7(5):1085-1094. [DOI] [PubMed] [Google Scholar]

[CIT0133] 133. Lefort N, St-Amand E, Morasse S, Côté CH, Marette A. The alpha-subunit of AMPK is essential for submaximal contraction-mediated glucose transport in skeletal muscle in vitro. Am J Physiol Endocrinol Metab. 2008;295(6):E1447-E1454. [DOI] [PubMed] [Google Scholar]

[CIT0134] 134. Lee-Young RS, Griffee SR, Lynes SE, et al. Skeletal muscle AMP-activated protein kinase is essential for the metabolic response to exercise in vivo. J Biol Chem. 2009;284(36):23925-23934. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0135] 135. Abbott MJ, Bogachus LD, Turcotte LP. AMPKα2 deficiency uncovers time dependency in the regulation of contraction-induced palmitate and glucose uptake in mouse muscle. J Appl Physiol (1985). 2011;111(1):125-134. [DOI] [PubMed] [Google Scholar]

[CIT0136] 136. O’Neill HM, Maarbjerg SJ, Crane JD, et al. AMP-activated protein kinase (AMPK) beta1beta2 muscle null mice reveal an essential role for AMPK in maintaining mitochondrial content and glucose uptake during exercise. Proc Natl Acad Sci U S A. 2011;108(38):16092-16097. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0137] 137. Kjøbsted R, Munk-Hansen N, Birk JB, et al. Enhanced muscle insulin sensitivity after contraction/exercise is mediated by AMPK. Diabetes. 2017;66(3):598-612. [DOI] [PubMed] [Google Scholar]

[CIT0138] 138. Crawford SA, Costford SR, Aguer C, et al. Naturally occurring R225W mutation of the gene encoding AMP-activated protein kinase (AMPK)gamma(3) results in increased oxidative capacity and glucose uptake in human primary myotubes. Diabetologia. 2010;53(9):1986-1997. [DOI] [PubMed] [Google Scholar]

[CIT0139] 139. Stöckli J, Meoli CC, Hoffman NJ, et al. The RabGAP TBC1D1 plays a central role in exercise-regulated glucose metabolism in skeletal muscle. Diabetes. 2015;64(6):1914-1922. [DOI] [PubMed] [Google Scholar]

[CIT0140] 140. Kjøbsted R, Roll JLW, Jørgensen NO, et al. AMPK and TBC1D1 regulate muscle glucose uptake after, but not during, exercise and contraction. Diabetes. 2019;68(7):1427-1440. [DOI] [PubMed] [Google Scholar]

[CIT0141] 141. An D, Toyoda T, Taylor EB, et al. TBC1D1 regulates insulin- and contraction-induced glucose transport in mouse skeletal muscle. Diabetes. 2010;59(6):1358-1365. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0142] 142. Fentz J, Kjøbsted R, Birk JB, et al. AMPKα is critical for enhancing skeletal muscle fatty acid utilization during in vivo exercise in mice. FASEB J. 2015;29(5):1725-1738. [DOI] [PubMed] [Google Scholar]

[CIT0143] 143. Wojtaszewski JF, Mourtzakis M, Hillig T, Saltin B, Pilegaard H. Dissociation of AMPK activity and ACCbeta phosphorylation in human muscle during prolonged exercise. Biochem Biophys Res Commun. 2002;298(3):309-316. [DOI] [PubMed] [Google Scholar]

[CIT0144] 144. McConell GK, Lee-Young RS, Chen ZP, et al. Short-term exercise training in humans reduces AMPK signalling during prolonged exercise independent of muscle glycogen. J Physiol. 2005;568(Pt 2):665-676. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0145] 145. Liu Y, Lai YC, Hill EV, et al. Phosphatidylinositol 3-phosphate 5-kinase (PIKfyve) is an AMPK target participating in contraction-stimulated glucose uptake in skeletal muscle. Biochem J. 2013;455(2):195-206. [DOI] [PubMed] [Google Scholar]

[CIT0146] 146. Ikonomov OC, Sbrissa D, Delvecchio K, et al. Muscle-specific Pikfyve gene disruption causes glucose intolerance, insulin resistance, adiposity, and hyperinsulinemia but not muscle fiber-type switching. Am J Physiol Endocrinol Metab. 2013;305(1):E119-E131. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0147] 147. Bartlett JD, Louhelainen J, Iqbal Z, et al. Reduced carbohydrate availability enhances exercise-induced p53 signaling in human skeletal muscle: implications for mitochondrial biogenesis. Am J Physiol Regul Integr Comp Physiol. 2013;304(6):R450-R458. [DOI] [PubMed] [Google Scholar]

[CIT0148] 148. Lai YC, Zarrinpashneh E, Jensen J. Additive effect of contraction and insulin on glucose uptake and glycogen synthase in muscle with different glycogen contents. J Appl Physiol (1985). 2010;108(5):1106-1115. [DOI] [PubMed] [Google Scholar]

[CIT0149] 149. Philp A, MacKenzie MG, Belew MY, et al. Glycogen content regulates peroxisome proliferator activated receptor-∂ (PPAR-∂) activity in rat skeletal muscle. PLoS One. 2013;8(10):e77200. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0150] 150. Steinberg GR, Watt MJ, McGee SL, et al. Reduced glycogen availability is associated with increased AMPKalpha2 activity, nuclear AMPKalpha2 protein abundance, and GLUT4 mRNA expression in contracting human skeletal muscle. Appl Physiol Nutr Metab. 2006;31(3):302-312. [DOI] [PubMed] [Google Scholar]

[CIT0151] 151. Wojtaszewski JF, MacDonald C, Nielsen JN, et al. Regulation of 5’AMP-activated protein kinase activity and substrate utilization in exercising human skeletal muscle. Am J Physiol Endocrinol Metab. 2003;284(4):E813-E822. [DOI] [PubMed] [Google Scholar]

[CIT0152] 152. Yeo WK, McGee SL, Carey AL, et al. Acute signalling responses to intense endurance training commenced with low or normal muscle glycogen. Exp Physiol. 2010;95(2):351-358. [DOI] [PubMed] [Google Scholar]

[CIT0153] 153. Derave W, Ai H, Ihlemann J, et al. Dissociation of AMP-activated protein kinase activation and glucose transport in contracting slow-twitch muscle. Diabetes. 2000;49(8):1281-1287. [DOI] [PubMed] [Google Scholar]

[CIT0154] 154. Derave W, Lund S, Holman GD, Wojtaszewski J, Pedersen O, Richter EA. Contraction-stimulated muscle glucose transport and GLUT-4 surface content are dependent on glycogen content. Am J Physiol. 1999;277(6):E1103-E1110. [DOI] [PubMed] [Google Scholar]

[CIT0155] 155. Hudson ER, Pan DA, James J, et al. A novel domain in AMP-activated protein kinase causes glycogen storage bodies similar to those seen in hereditary cardiac arrhythmias. Curr Biol. 2003;13(10):861-866. [DOI] [PubMed] [Google Scholar]

[CIT0156] 156. McBride A, Ghilagaber S, Nikolaev A, Hardie DG. The glycogen-binding domain on the AMPK beta subunit allows the kinase to act as a glycogen sensor. Cell Metab. 2009;9(1):23-34. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0157] 157. Polekhina G, Gupta A, Michell BJ, et al. AMPK beta subunit targets metabolic stress sensing to glycogen. Curr Biol. 2003;13(10):867-871. [DOI] [PubMed] [Google Scholar]

[CIT0158] 158. Oligschlaeger Y, Miglianico M, Chanda D, et al. The recruitment of AMP-activated protein kinase to glycogen is regulated by autophosphorylation. J Biol Chem. 2015;290(18):11715-11728. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0159] 159. Oligschlaeger Y, Miglianico M, Dahlmans V, et al. The interaction between AMPKβ2 and the PP1-targeting subunit R6 is dynamically regulated by intracellular glycogen content. Biochem J. 2016;473(7):937-947. [DOI] [PubMed] [Google Scholar]

[CIT0160] 160. Hespel P, Richter EA. Glucose uptake and transport in contracting, perfused rat muscle with different pre-contraction glycogen concentrations. J Physiol. 1990;427:347-359. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0161] 161. Steensberg A, van Hall G, Keller C, et al. Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. J Physiol. 2002;541(Pt 1):273-281. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0162] 162. Rose AJ, Hargreaves M. Exercise increases Ca2+-calmodulin-dependent protein kinase II activity in human skeletal muscle. J Physiol. 2003;553(Pt 1):303-309. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0163] 163. Rose AJ, Kiens B, Richter EA. Ca2+-calmodulin-dependent protein kinase expression and signalling in skeletal muscle during exercise. J Physiol. 2006;574(Pt 3):889-903. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0164] 164. Combes A, Dekerle J, Webborn N, Watt P, Bougault V, Daussin FN. Exercise-induced metabolic fluctuations influence AMPK, p38-MAPK and CaMKII phosphorylation in human skeletal muscle. Physiol Rep. 2015;3(9):e12462. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0165] 165. Witczak CA, Jessen N, Warro DM, et al. CaMKII regulates contraction- but not insulin-induced glucose uptake in mouse skeletal muscle. Am J Physiol Endocrinol Metab. 2010;298(6):E1150-E1160. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0166] 166. Park DR, Park KH, Kim BJ, Yoon CS, Kim UH. Exercise ameliorates insulin resistance via Ca2+ signals distinct from those of insulin for GLUT4 translocation in skeletal muscles. Diabetes. 2015;64(4):1224-1234. [DOI] [PubMed] [Google Scholar]

[CIT0167] 167. Li Z, Yue Y, Hu F, et al. Electrical pulse stimulation induces GLUT4 translocation in C2C12 myotubes that depends on Rab8A, Rab13, and Rab14. Am J Physiol Endocrinol Metab. 2018;314(5):E478-E493. [DOI] [PubMed] [Google Scholar]

[CIT0168] 168. Wright DC, Hucker KA, Holloszy JO, Han DH. Ca2+ and AMPK both mediate stimulation of glucose transport by muscle contractions. Diabetes. 2004;53(2):330-335. [DOI] [PubMed] [Google Scholar]

[CIT0169] 169. Ihlemann J, Galbo H, Ploug T. Calphostin C is an inhibitor of contraction, but not insulin-stimulated glucose transport, in skeletal muscle. Acta Physiol Scand. 1999;167(1):69-75. [DOI] [PubMed] [Google Scholar]

[CIT0170] 170. Jensen TE, Rose AJ, Jørgensen SB, et al. Possible CaMKK-dependent regulation of AMPK phosphorylation and glucose uptake at the onset of mild tetanic skeletal muscle contraction. Am J Physiol Endocrinol Metab. 2007;292(5):E1308-E1317. [DOI] [PubMed] [Google Scholar]

[CIT0171] 171. Popovic D, Vucic D, Dikic I. Ubiquitination in disease pathogenesis and treatment. Nat Med. 2014;20(11):1242-1253. [DOI] [PubMed] [Google Scholar]

[CIT0172] 172. Balaji V, Pokrzywa W, Hoppe T. Ubiquitylation pathways in insulin signaling and organismal homeostasis. Bioessays. 2018;40(5):e1700223. [DOI] [PubMed] [Google Scholar]

[CIT0173] 173. Yang XD, Xiang DX, Yang YY. Role of E3 ubiquitin ligases in insulin resistance. Diabetes Obes Metab. 2016;18(8):747-754. [DOI] [PubMed] [Google Scholar]

[CIT0174] 174. Song R, Peng W, Zhang Y, et al. Central role of E3 ubiquitin ligase MG53 in insulin resistance and metabolic disorders. Nature. 2013;494(7437):375-379. [DOI] [PubMed] [Google Scholar]

[CIT0175] 175. Uruno A, Furusawa Y, Yagishita Y, et al. The Keap1-Nrf2 system prevents onset of diabetes mellitus. Mol Cell Biol. 2013;33(15):2996-3010. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0176] 176. Kawaguchi M, Minami K, Nagashima K, Seino S. Essential role of ubiquitin-proteasome system in normal regulation of insulin secretion. J Biol Chem. 2006;281(19):13015-13020. [DOI] [PubMed] [Google Scholar]

[CIT0177] 177. Yamada T, Murata D, Adachi Y, et al. Mitochondrial stasis reveals p62-mediated ubiquitination in parkin-independent mitophagy and mitigates nonalcoholic fatty liver disease. Cell Metab. 2018;28(4):588-604.e5. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0178] 178. Price SR, Bailey JL, Wang X, et al. Muscle wasting in insulinopenic rats results from activation of the ATP-dependent, ubiquitin-proteasome proteolytic pathway by a mechanism including gene transcription. J Clin Invest. 1996;98(8):1703-1708. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0179] 179. Al-Khalili L, de Castro Barbosa T, Ostling J, et al. Proteasome inhibition in skeletal muscle cells unmasks metabolic derangements in type 2 diabetes. Am J Physiol Cell Physiol. 2014;307(9):C774-C787. [DOI] [PubMed] [Google Scholar]

[CIT0180] 180. Nagarajan A, Petersen MC, Nasiri AR, et al. MARCH1 regulates insulin sensitivity by controlling cell surface insulin receptor levels. Nat Commun. 2016;7:12639. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0181] 181. Tawo R, Pokrzywa W, Kevei É, et al. The ubiquitin ligase CHIP integrates proteostasis and aging by regulation of insulin receptor turnover. Cell. 2017;169(3):470-482.e13. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0182] 182. Ahn BH, Kim HS, Song S, et al. A role for the mitochondrial deacetylase Sirt3 in regulating energy homeostasis. Proc Natl Acad Sci U S A. 2008;105(38):14447-14452. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0183] 183. VerPlank JJS, Lokireddy S, Zhao J, Goldberg AL. 26S Proteasomes are rapidly activated by diverse hormones and physiological states that raise cAMP and cause Rpn6 phosphorylation. Proc Natl Acad Sci U S A. 2019;116(10):4228-4237. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0184] 184. Parker BL, Kiens B, Wojtaszewski JFP, Richter EA, James DE. Quantification of exercise-regulated ubiquitin signaling in human skeletal muscle identifies protein modification cross talk via NEDDylation. FASEB J. 2020;34(4):5906-5916. [DOI] [PubMed] [Google Scholar]

[CIT0185] 185. Djakovic SN, Schwarz LA, Barylko B, DeMartino GN, Patrick GN. Regulation of the proteasome by neuronal activity and calcium/calmodulin-dependent protein kinase II. J Biol Chem. 2009;284(39):26655-26665. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0186] 186. Udeshi ND, Svinkina T, Mertins P, et al. Refined preparation and use of anti-diglycine remnant (K-ε-GG) antibody enables routine quantification of 10,000s of ubiquitination sites in single proteomics experiments. Mol Cell Proteomics. 2013;12(3):825-831. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0187] 187. Kao AW, Noda Y, Johnson JH, Pessin JE, Saltiel AR. Aldolase mediates the association of F-actin with the insulin-responsive glucose transporter GLUT4. J Biol Chem. 1999;274(25):17742-17747. [DOI] [PubMed] [Google Scholar]

[CIT0188] 188. Chen-Zion M, Lilling G, Beitner R. The dual effects of Ca2+ on binding of the glycolytic enzymes, phosphofructokinase and aldolase, to muscle cytoskeleton. Biochem Med Metab Biol. 1993;49(2):173-181. [DOI] [PubMed] [Google Scholar]

[CIT0189] 189. Krassikova L, Zhang B, Nagarajan D, et al. The deubiquitinase JOSD2 is a positive regulator of glucose metabolism. Cell Death Differ. 2021;28(3):1091-1109. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0190] 190. Jiang P, Ren L, Zhi L, et al. Negative regulation of AMPK signaling by high glucose via E3 ubiquitin ligase MG53. Mol Cell. 2021;81(3):629-637.e5. [DOI] [PubMed] [Google Scholar]

[CIT0191] 191. Lee MS, Han HJ, Han SY, et al. Loss of the E3 ubiquitin ligase MKRN1 represses diet-induced metabolic syndrome through AMPK activation. Nat Commun. 2018;9(1):3404. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0192] 192. Dagon Y, Hur E, Zheng B, Wellenstein K, Cantley LC, Kahn BB. p70S6 kinase phosphorylates AMPK on serine 491 to mediate leptin’s effect on food intake. Cell Metab. 2012;16(1):104-112. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0193] 193. Hawley Simon A, Ross Fiona A, Gowans Graeme J, Tibarewal P, Leslie Nicholas R, Hardie DG. Phosphorylation by Akt within the ST loop of AMPK-α1 down-regulates its activation in tumour cells. Biochem J. 2014;459(2):275-287. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0194] 194. Lundby A, Lage K, Weinert BT, et al. Proteomic analysis of lysine acetylation sites in rat tissues reveals organ specificity and subcellular patterns. Cell Rep. 2012;2(2):419-431. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0195] 195. Hostrup M, Lemminger AK, Stocks B, et al. High-intensity interval training remodels the proteome and acetylome of human skeletal muscle. bioRxiv. 2021:2021.2002.2010.430602. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0196] 196. Overmyer KA, Evans CR, Qi NR, et al. Maximal oxidative capacity during exercise is associated with skeletal muscle fuel selection and dynamic changes in mitochondrial protein acetylation. Cell Metab. 2015;21(3):468-478. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0197] 197. Williams AS, Koves TR, Davidson MT, et al. Disruption of acetyl-lysine turnover in muscle mitochondria promotes insulin resistance and redox stress without overt respiratory dysfunction. Cell Metab. 2020;31(1):131-147.e11. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0198] 198. LaBarge S, Migdal C, Schenk S. Is acetylation a metabolic rheostat that regulates skeletal muscle insulin action? Mol Cells. 2015;38(4):297-303. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0199] 199. Sun C, Zhou J. Trichostatin A improves insulin stimulated glucose utilization and insulin signaling transduction through the repression of HDAC2. Biochem Pharmacol. 2008;76(1):120-127. [DOI] [PubMed] [Google Scholar]

[CIT0200] 200. Sundaresan NR, Pillai VB, Wolfgeher D, et al. The deacetylase SIRT1 promotes membrane localization and activation of Akt and PDK1 during tumorigenesis and cardiac hypertrophy. Sci Signal. 2011;4(182):ra46. [DOI] [PubMed] [Google Scholar]

[CIT0201] 201. Li B, Carey M, Workman JL. The role of chromatin during transcription. Cell. 2007;128(4):707-719. [DOI] [PubMed] [Google Scholar]

[CIT0202] 202. McGee SL, van Denderen BJ, Howlett KF, et al. AMP-activated protein kinase regulates GLUT4 transcription by phosphorylating histone deacetylase 5. Diabetes. 2008;57(4):860-867. [DOI] [PubMed] [Google Scholar]

[CIT0203] 203. Hong S, Zhou W, Fang B, et al. Dissociation of muscle insulin sensitivity from exercise endurance in mice by HDAC3 depletion. Nat Med. 2017;23(2):223-234. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0204] 204. Song S, Wen Y, Tong H, et al. The HDAC3 enzymatic activity regulates skeletal muscle fuel metabolism. J Mol Cell Biol. 2019;11(2):133-143. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0205] 205. Gerhart-Hines Z, Rodgers JT, Bare O, et al. Metabolic control of muscle mitochondrial function and fatty acid oxidation through SIRT1/PGC-1alpha. EMBO J. 2007;26(7):1913-1923. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0206] 206. Schenk S, McCurdy CE, Philp A, et al. Sirt1 enhances skeletal muscle insulin sensitivity in mice during caloric restriction. J Clin Invest. 2011;121(11):4281-4288. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0207] 207. White AT, Philp A, Fridolfsson HN, et al. High-fat diet-induced impairment of skeletal muscle insulin sensitivity is not prevented by SIRT1 overexpression. Am J Physiol Endocrinol Metab. 2014;307(9):E764-E772. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0208] 208. Kang JH, Park JE, Dagoon J, et al. Sirtuin 1 is not required for contraction-stimulated glucose uptake in mouse skeletal muscle. J Appl Physiol (1985). 2021;130(6):1893-1902. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0209] 209. Philp A, Chen A, Lan D, et al. Sirtuin 1 (SIRT1) deacetylase activity is not required for mitochondrial biogenesis or peroxisome proliferator-activated receptor-gamma coactivator-1alpha (PGC-1alpha) deacetylation following endurance exercise. J Biol Chem. 2011;286(35):30561-30570. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0210] 210. Dent JR, Martins VF, Svensson K, et al. Muscle-specific knockout of general control of amino acid synthesis 5 (GCN5) does not enhance basal or endurance exercise-induced mitochondrial adaptation. Mol Metab. 2017;6(12):1574-1584. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0211] 211. Martins VF, Dent JR, Svensson K, et al. Germline or inducible knockout of p300 or CBP in skeletal muscle does not alter insulin sensitivity. Am J Physiol Endocrinol Metab. 2019;316(6):E1024-E1035. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0212] 212. LaBarge SA, Migdal CW, Buckner EH, et al. p300 is not required for metabolic adaptation to endurance exercise training. FASEB J. 2016;30(4):1623-1633. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0213] 213. Svensson K, LaBarge SA, Sathe A, et al. p300 and cAMP response element-binding protein-binding protein in skeletal muscle homeostasis, contractile function, and survival. J Cachexia Sarcopenia Muscle. 2020;11(2):464-477. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0214] 214. Muoio DM, Noland RC, Kovalik JP, et al. Muscle-specific deletion of carnitine acetyltransferase compromises glucose tolerance and metabolic flexibility. Cell Metab. 2012;15(5):764-777. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0215] 215. Hirschey MD, Shimazu T, Jing E, et al. SIRT3 deficiency and mitochondrial protein hyperacetylation accelerate the development of the metabolic syndrome. Mol Cell. 2011;44(2):177-190. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0216] 216. Lantier L, Williams AS, Williams IM, et al. SIRT3 is crucial for maintaining skeletal muscle insulin action and protects against severe insulin resistance in high-fat-fed mice. Diabetes. 2015;64(9):3081-3092. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0217] 217. Jing E, O’Neill BT, Rardin MJ, et al. Sirt3 regulates metabolic flexibility of skeletal muscle through reversible enzymatic deacetylation. Diabetes. 2013;62(10):3404-3417. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0218] 218. Constantin-Teodosiu D, Constantin D, Stephens F, Laithwaite D, Greenhaff PL. The role of FOXO and PPAR transcription factors in diet-mediated inhibition of PDC activation and carbohydrate oxidation during exercise in humans and the role of pharmacological activation of PDC in overriding these changes. Diabetes. 2012;61(5):1017-1024. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0219] 219. Stocks B, Ashcroft SP, Joanisse S, et al. Nicotinamide riboside supplementation does not alter whole-body or skeletal muscle metabolic responses to a single bout of endurance exercise. J Physiol. 2021;599(5):1513-1531. [DOI] [PubMed] [Google Scholar]

[CIT0220] 220. Cantó C, Jiang LQ, Deshmukh AS, et al. Interdependence of AMPK and SIRT1 for metabolic adaptation to fasting and exercise in skeletal muscle. Cell Metab. 2010;11(3):213-219. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0221] 221. Henriksson J, Katz A, Sahlin K. Redox state changes in human skeletal muscle after isometric contraction. J Physiol. 1986;380(1):441-451. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0222] 222. Sahlin K. NADH in human skeletal muscle during short-term intense exercise. Pflugers Arch. 1985;403(2):193-196. [DOI] [PubMed] [Google Scholar]

[CIT0223] 223. Sahlin K, Katz A, Henriksson J. Redox state and lactate accumulation in human skeletal muscle during dynamic exercise. Biochem J. 1987;245(2):551-556. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0224] 224. McGee SL, Fairlie E, Garnham AP, Hargreaves M. Exercise-induced histone modifications in human skeletal muscle. J Physiol. 2009;587(Pt 24):5951-5958. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0225] 225. Weinert BT, Moustafa T, Iesmantavicius V, Zechner R, Choudhary C. Analysis of acetylation stoichiometry suggests that SIRT3 repairs nonenzymatic acetylation lesions. EMBO J. 2015;34(21):2620-2632. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0226] 226. Ren W, Jhala US, Du K. Proteomic analysis of protein palmitoylation in adipocytes. Adipocyte. 2013;2(1):17-28. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0227] 227. Hirschey MD, Zhao Y. Metabolic regulation by lysine malonylation, succinylation, and glutarylation. Mol Cell Proteomics. 2015;14(9):2308-2315. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0228] 228. Bandyopadhyay GK, Yu JG, Ofrecio J, Olefsky JM. Increased malonyl-CoA levels in muscle from obese and type 2 diabetic subjects lead to decreased fatty acid oxidation and increased lipogenesis; thiazolidinedione treatment reverses these defects. Diabetes. 2006;55(8):2277-2285. [DOI] [PubMed] [Google Scholar]

[CIT0229] 229. Odland LM, Howlett RA, Heigenhauser GJ, Hultman E, Spriet LL. Skeletal muscle malonyl-CoA content at the onset of exercise at varying power outputs in humans. Am J Physiol. 1998;274(6):E1080-E1085. [DOI] [PubMed] [Google Scholar]

[CIT0230] 230. Odland LM, Heigenhauser GJ, Lopaschuk GD, Spriet LL. Human skeletal muscle malonyl-CoA at rest and during prolonged submaximal exercise. Am J Physiol. 1996;270(3 Pt 1):E541-E544. [DOI] [PubMed] [Google Scholar]

[CIT0231] 231. Zhao Z, Lee YJ, Kim SK, et al. Rosiglitazone and fenofibrate improve insulin sensitivity of pre-diabetic OLETF rats by reducing malonyl-CoA levels in the liver and skeletal muscle. Life Sci. 2009;84(19-20):688-695. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0232] 232. Du K, Murakami S, Sun Y, Kilpatrick CL, Luscher B. DHHC7 palmitoylates glucose transporter 4 (Glut4) and regulates Glut4 membrane translocation. J Biol Chem. 2017;292(7):2979-2991. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0233] 233. Ren W, Sun Y, Du K. Glut4 palmitoylation at Cys223 plays a critical role in Glut4 membrane trafficking. Biochem Biophys Res Commun. 2015;460(3):709-714. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0234] 234. Bai P, Canto C, Brunyánszki A, et al. PARP-2 regulates SIRT1 expression and whole-body energy expenditure. Cell Metab. 2011;13(4):450-460. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0235] 235. Bai P, Cantó C, Oudart H, et al. PARP-1 inhibition increases mitochondrial metabolism through SIRT1 activation. Cell Metab. 2011;13(4):461-468. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0236] 236. Mohamed JS, Hajira A, Pardo PS, Boriek AM. MicroRNA-149 inhibits PARP-2 and promotes mitochondrial biogenesis via SIRT-1/PGC-1α network in skeletal muscle. Diabetes. 2014;63(5):1546-1559. [DOI] [PubMed] [Google Scholar]

[CIT0237] 237. Pirinen E, Cantó C, Jo YS, et al. Pharmacological Inhibition of poly(ADP-ribose) polymerases improves fitness and mitochondrial function in skeletal muscle. Cell Metab. 2014;19(6):1034-1041. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0238] 238. Leutert M, Menzel S, Braren R, et al. Proteomic characterization of the heart and skeletal muscle reveals widespread arginine ADP-ribosylation by the ARTC1 ectoenzyme. Cell Rep. 2018;24(7):1916-1929.e5. [DOI] [PubMed] [Google Scholar]

[CIT0239] 239. Hendriks IA, Larsen SC, Nielsen ML. An advanced strategy for comprehensive profiling of ADP-ribosylation sites using mass spectrometry-based proteomics. Mol Cell Proteomics. 2019;18(5):1010-1026. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0240] 240. Pezzolesi MG, Nam M, Nagase T, et al. Examination of candidate chromosomal regions for type 2 diabetes reveals a susceptibility locus on human chromosome 8p23.1. Diabetes. 2004;53(2):486-491. [DOI] [PubMed] [Google Scholar]

[CIT0241] 241. Scherag A, Dina C, Hinney A, et al. Two new Loci for body-weight regulation identified in a joint analysis of genome-wide association studies for early-onset extreme obesity in French and german study groups. PLoS Genet. 2010;6(4):e1000916. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0242] 242. Zhong L, Ding Y, Bandyopadhyay G, et al. The PARsylation activity of tankyrase in adipose tissue modulates systemic glucose metabolism in mice. Diabetologia. 2016;59(3):582-591. [DOI] [PubMed] [Google Scholar]

[CIT0243] 243. Wang H, Kuusela S, Rinnankoski-Tuikka R, et al. Tankyrase inhibition ameliorates lipid disorder via suppression of PGC-1α PARylation in db/db mice. Int J Obes (Lond). 2020;44(8):1691-1702. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0244] 244. Chi NW, Lodish HF. Tankyrase is a golgi-associated mitogen-activated protein kinase substrate that interacts with IRAP in GLUT4 vesicles. J Biol Chem. 2000;275(49):38437-38444. [DOI] [PubMed] [Google Scholar]

[CIT0245] 245. Yeh TY, Sbodio JI, Tsun ZY, Luo B, Chi NW. Insulin-stimulated exocytosis of GLUT4 is enhanced by IRAP and its partner tankyrase. Biochem J. 2007;402(2):279-290. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0246] 246. Mohamed JS, Wilson JC, Myers MJ, Sisson KJ, Alway SE. Dysregulation of SIRT-1 in aging mice increases skeletal muscle fatigue by a PARP-1-dependent mechanism. Aging (Albany NY). 2014;6(10):820-834. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0247] 247. Stocks B, Ashcroft SP, Joanisse S, et al. Nicotinamide riboside supplementation does not alter whole-body or skeletal muscle metabolic responses to a single bout of endurance exercise. J Physiol. 2021;599(5):1513-1531. [DOI] [PubMed] [Google Scholar]

[CIT0248] 248. Cobley JN, Sakellariou GK, Murray S, et al. Lifelong endurance training attenuates age-related genotoxic stress in human skeletal muscle. Longev Healthspan. 2013;2(1):11. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0249] 249. Deshmukh AS, Murgia M, Nagaraj N, Treebak JT, Cox J, Mann M. Deep proteomics of mouse skeletal muscle enables quantitation of protein isoforms, metabolic pathways, and transcription factors. Mol Cell Proteomics. 2015;14(4):841-853. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0250] 250. Demichev V, Messner CB, Vernardis SI, Lilley KS, Ralser M. DIA-NN: neural networks and interference correction enable deep proteome coverage in high throughput. Nat Methods. 2020;17(1):41-44. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0251] 251. Bekker-Jensen DB, Martínez-Val A, Steigerwald S, et al. A compact quadrupole-orbitrap mass spectrometer with FAIMS interface improves proteome coverage in short LC gradients. Mol Cell Proteomics. 2020;19(4):716-729. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0252] 252. Hansen FM, Tanzer MC, Brüning F, et al. Data-independent acquisition method for ubiquitinome analysis reveals regulation of circadian biology. Nat Commun. 2021;12(1):254. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0253] 253. Humphrey SJ, Karayel O, James DE, Mann M. High-throughput and high-sensitivity phosphoproteomics with the EasyPhos platform. Nat Protoc. 2018;13(9):1897-1916. [DOI] [PubMed] [Google Scholar]

[CIT0254] 254. Ludwig C, Gillet L, Rosenberger G, Amon S, Collins BC, Aebersold R. Data-independent acquisition-based SWATH-MS for quantitative proteomics: a tutorial. Mol Syst Biol. 2018;14(8):e8126. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0255] 255. Abbott MJ, Edelman AM, Turcotte LP. CaMKK is an upstream signal of AMP-activated protein kinase in regulation of substrate metabolism in contracting skeletal muscle. Am J Physiol Regul Integr Comp Physiol. 2009;297(6):R1724-R1732. [DOI] [PubMed] [Google Scholar]

[CIT0256] 256. Hawley SA, Pan DA, Mustard KJ, et al. Calmodulin-dependent protein kinase kinase-beta is an alternative upstream kinase for AMP-activated protein kinase. Cell Metab. 2005;2(1):9-19. [DOI] [PubMed] [Google Scholar]

[CIT0257] 257. Hurley RL, Anderson KA, Franzone JM, Kemp BE, Means AR, Witters LA. The Ca2+/calmodulin-dependent protein kinase kinases are AMP-activated protein kinase kinases. J Biol Chem. 2005;280(32):29060-29066. [DOI] [PubMed] [Google Scholar]

[CIT0258] 258. Sakamoto K, McCarthy A, Smith D, et al. Deficiency of LKB1 in skeletal muscle prevents AMPK activation and glucose uptake during contraction. EMBO J. 2005;24(10):1810-1820. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0259] 259. Thomson DM, Porter BB, Tall JH, Kim HJ, Barrow JR, Winder WW. Skeletal muscle and heart LKB1 deficiency causes decreased voluntary running and reduced muscle mitochondrial marker enzyme expression in mice. Am J Physiol Endocrinol Metab. 2007;292(1):E196-E202. [DOI] [PubMed] [Google Scholar]

[CIT0260] 260. Jørgensen SB, Nielsen JN, Birk JB, et al. The alpha2-5’AMP-activated protein kinase is a site 2 glycogen synthase kinase in skeletal muscle and is responsive to glucose loading. Diabetes. 2004;53(12):3074-3081. [DOI] [PubMed] [Google Scholar]

[CIT0261] 261. Vavvas D, Apazidis A, Saha AK, et al. Contraction-induced changes in acetyl-CoA carboxylase and 5’-AMP-activated kinase in skeletal muscle. J Biol Chem. 1997;272(20):13255-13261. [DOI] [PubMed] [Google Scholar]

[CIT0262] 262. Inoki K, Zhu T, Guan KL. TSC2 mediates cellular energy response to control cell growth and survival. Cell. 2003;115(5):577-590. [DOI] [PubMed] [Google Scholar]

[CIT0263] 263. Ojuka EO, Jones TE, Nolte LA, et al. Regulation of GLUT4 biogenesis in muscle: evidence for involvement of AMPK and Ca⁽²⁺⁾. Am J Physiol Endocrinol Metab. 2002;282(5): E1008-E1013. [DOI] [PubMed] [Google Scholar]

[CIT0264] 264. Jäger S, Handschin C, St-Pierre J, Spiegelman BM. AMP-activated protein kinase (AMPK) action in skeletal muscle via direct phosphorylation of PGC-1alpha. Proc Natl Acad Sci U S A. 2007;104(29):12017-12022. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0265] 265. Puigserver P, Rhee J, Lin J, et al. Cytokine stimulation of energy expenditure through p38 MAP kinase activation of PPARgamma coactivator-1. Mol Cell. 2001;8(5):971-982. [DOI] [PubMed] [Google Scholar]

[CIT0266] 266. McGee SL, Hargreaves M. Exercise and myocyte enhancer factor 2 regulation in human skeletal muscle. Diabetes. 2004;53(5):1208-1214. [DOI] [PubMed] [Google Scholar]

[CIT0267] 267. Zhao M, New L, Kravchenko VV, et al. Regulation of the MEF2 family of transcription factors by p38. Mol Cell Biol. 1999;19(1):21-30. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CIT0268] 268. Mehrani H, Storey KB. Control of glycogenolysis and effects of exercise on phosphorylase kinase and cAMP-dependent protein kinase in rainbow trout organs. Biochem Cell Biol. 1993;71(11-12):501-506. [DOI] [PubMed] [Google Scholar]

[CIT0269] 269. Ray Hamidie RD, Yamada T, Ishizawa R, Saito Y, Masuda K. Curcumin treatment enhances the effect of exercise on mitochondrial biogenesis in skeletal muscle by increasing cAMP levels. Metabolism. 2015;64(10):1334-1347. [DOI] [PubMed] [Google Scholar]

PERMALINK

Post-translational Modifications: The Signals at the Intersection of Exercise, Glucose Uptake, and Insulin Sensitivity

Ben Stocks

Juleen R Zierath

Abstract

Graphical Abstract

Graphical Abstract.

ESSENTIAL POINTS

Figure 1.

Cellular Mechanisms of Exercise-induced Glucose Uptake and Insulin Sensitivity in Skeletal Muscle

Acute Exercise

Chronic Exercise Training

Post-translational Modifications at the Intersection of Exercise and Insulin Sensitivity

Phosphorylation

Figure 2.

Figure 3.

Ubiquitination and Ubiquitin-like Modifications

Figure 4.

Acylation

Figure 5.

Adenosine Diphosphate Ribosylation

Figure 6.

Future Directions

Conclusions

Figure 7.

Acknowledgments

Glossary

Abbreviations

Contributor Information

Additional Information

References

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

Post-translational Modifications: The Signals at the Intersection of Exercise, Glucose Uptake, and Insulin Sensitivity

Ben Stocks

Juleen R Zierath

Abstract

Graphical Abstract

Graphical Abstract.

ESSENTIAL POINTS

Figure 1.

Cellular Mechanisms of Exercise-induced Glucose Uptake and Insulin Sensitivity in Skeletal Muscle

Acute Exercise

Chronic Exercise Training

Post-translational Modifications at the Intersection of Exercise and Insulin Sensitivity

Phosphorylation

Figure 2.

Figure 3.

Ubiquitination and Ubiquitin-like Modifications

Figure 4.

Acylation

Figure 5.

Adenosine Diphosphate Ribosylation

Figure 6.

Future Directions

Conclusions

Figure 7.

Acknowledgments

Glossary

Abbreviations

Contributor Information

Additional Information

References

ACTIONS

PERMALINK

RESOURCES

Similar articles

Cited by other articles

Links to NCBI Databases