Purinergic interplay between erythrocytes and platelets in diabetes-associated vascular dysfunction

Zhichao Zhou

doi:10.1007/s11302-021-09807-5

. 2021 Aug 19;17(4):705–712. doi: 10.1007/s11302-021-09807-5

Purinergic interplay between erythrocytes and platelets in diabetes-associated vascular dysfunction

Zhichao Zhou ^1,^✉

PMCID: PMC8677852 PMID: 34410591

Abstract

Cardiovascular complications in diabetes are the leading causes for high morbidity and mortality. It has been shown that alteration of purinergic signaling contributes to diabetes-associated cardiovascular complications. Red blood cells (RBCs) and platelets play a fundamental role in regulation of oxygen transport and hemostasis, respectively. Of note, these cells undergo purinergic dysfunction in diabetes. Recent studies have established a novel function of RBCs as disease mediators for the development of endothelial dysfunction in type 2 diabetes (T2D). RBC-released ATP is defective in T2D, which has implication for induction of vascular dysfunction by dysregulating purinergic signaling. Platelets are hyperactive in diabetes. ADP-mediated P2Y₁ and P2Y₁₂ receptor activation contributes to platelet aggregation and targeting P2Y receptors particularly P2Y₁₂ receptor in platelets is effective for the treatment of cardiovascular events. In contrast to other P2Y₁₂ receptor antagonists, platelet-targeting drug ticagrelor has potential to initiate purinergic signaling in RBCs for the beneficial cardiovascular outcomes. It is increasingly clear that altered vascular purinergic signaling mediated by various nucleotides and nucleoside contributes to diabetes-associated vascular dysfunction. However, the contribution of complex purinergic networks between RBCs and platelets to the vascular dysfunction in diabetes remains unclear. This study discusses the possible interplay of RBCs and platelets via the purinergic network for diabetes-associated vascular dysfunction.

Keywords: ATP, Circulation, Diabetes, Platelet, Purinergic receptor, Red blood cell

Introduction

Diabetes is an important risk factor for the development of a variety of cardiovascular diseases including atherosclerosis and ischemic heart disease. The vascular complications associated with diabetes are the leading causes for high morbidity and mortality worldwide [1, 2]. Vascular dysfunction plays a crucial role in the etiology of diabetes-induced vascular complications. This is characterized by imbalances between vasoconstrictor/inflammatory factors such as reactive oxygen species (ROS) or signaling pathways such as nucleot(s)ide-mediated vasoconstrictor purinergic signaling and vasodilator/anti-inflammatory factors such as nitric oxide (NO) or signaling pathways such as nucleot(s)ide-mediated vasodilator purinergic signaling [2]. These substances are released and/or initiated from the cardiovascular wall as well as circulating cells including red blood cells (RBCs) and platelets. The vasoconstrictor/inflammatory net effects of those substances acting on the vascular wall eventually result in vascular dysfunction [1]. Both purinergic P1 and P2 receptors are ubiquitously expressed in endothelial cells and smooth muscle cells in the vasculature [2]. It is increasingly clear that altered vascular purinergic signaling mediated by various nucleotides (e.g., ATP and ADP) and nucleoside (adenosine) significantly contributes to diabetes-associated vascular complications [2–5].

RBCs and platelets are the most abundant cells in the circulation, both of which play a fundamental role in cardiovascular homeostasis, due to their diverse functions including gas transportation, hemostasis, thrombosis, coagulation, and vascular regulation [1, 6]. Emerging studies have shown that RBCs act as disease mediators for the development of endothelial dysfunction in type 2 diabetes (T2D) [1, 7–10]. RBCs serve as ATP pool and release of ATP in response to low oxygen tension plays a crucial role in the regulation of tissue perfusion [11]. Of note, the release of ATP from RBCs in diabetes is defective, which results in less vasodilation in isolated muscle arterioles [12]. Of further interest, a recent study demonstrated that altered vascular purinergic signaling is involved in endothelial dysfunction induced by RBCs from patients with T2D [13]. Platelets are hyperactive in diabetes, which could further promote endothelial dysfunction and contribute to enhanced risk of development of atherothrombotic disease in various vasculatures including coronary and cerebral arteries [14, 15]. One of the important mechanisms of platelet activation is due to ADP-activated purinergic P2Y₁ and P2Y₁₂ receptors [14]. Therefore, targeting these receptors in particular P2Y₁₂ receptors have been applied widely in the clinic to cope with the cardiovascular/thrombotic event [16, 17].

Given both RBCs and platelets of diabetes origin induce endothelial dysfunction and the significant involvement of purinergic signaling in both cell types, whether there is interplay between RBCs and platelets via purinergic signaling (de)activating vascular purinergic signaling for the induction of diabetes-associated vascular complications remains incompletely understood. The present study discusses complex purinergic networks as possible links for an interplay between RBCs and platelets for the development of vascular dysfunction in diabetes.

RBC and purinergic signaling in diabetes

RBCs play a fundamental role in cardiovascular homeostasis because of their contribution to vascular function and integrity. RBCs become dysfunctional in diabetes, as evidenced by reduced NO bioactivity, enhanced oxidative stress, and ATP-mediated altered purinergic signaling [1, 8]. Such alterations may subsequently affect the vascular function and induce cardiovascular complications. Recent studies have revealed a novel function of RBCs as disease mediators for the development of T2D-associated endothelial dysfunction. It has been shown that RBCs from patients and rodents with T2D induced endothelial dysfunction and exacerbated cardiac ischemia–reperfusion injury [1, 7, 13, 18]. Interestingly, the detrimental effect of RBCs on endothelial function seems not to be solely induced by hyperglycemia, as evidenced by that RBCs of T2D patients with improved glycemic control could not attenuate endothelial injury [9]. The mechanisms underlying this potentially important function of RBCs for the development of cardiovascular dysfunction in T2D remain incompletely elucidated and warrant further investigations.

RBCs can release ATP in response to physiological stimuli [11, 12]. This is evidenced in studies that there is substantial ATP release from human RBCs in response to low oxygen tension without detectable hemolysis [12, 19]. In contrast, it is suggested that ATP release from RBCs occurs during cell lysis, which may be physiologically relevant during exercise and hypoxia when intravascular hemolysis of senescent cells is increased [20]. The ATP release in response to low oxygen tension requires increases in cAMP induced by activation of heterotrimeric G (Gi) protein-stimulated adenylyl cyclase (AC) [11]. ATP is suggested to be transported via pannexin-1 channels [21] (Fig. 1). The role of pannexin-1 in ATP release may need further validations, as one study using pannexin-1 knockout mice shows an unlikely involvement [22]. Once released, ATP can be degraded to ADP and adenosine by various nucleotidases. These adenine nucleotides activate their corresponding purinergic receptors to regulate blood flow and tissue perfusion [2, 11, 23]. RBC-derived ATP can bind to vasodilator P2 receptors on the endothelium to generate vasodilators and anti-inflammatory factors [e.g., NO and prostacyclin (PGI₂)] for subsequent vasodilation [11]. Interestingly, NO and PGI₂ interact with RBCs to inhibit hypoxia-induced ATP release and stimulate PGI₂ receptor-mediated ATP release via voltage-dependent anion channels, respectively [8, 11]. In addition to ATP release, RBCs express many purinergic receptors including both P1 and P2 receptors [24, 25]. A_2B, P2Y₁, P2Y₁₂, and P2Y₁₃ receptors are commonly expressed in RBCs, and the P2Y₁₃ receptors are most abundantly expressed in both RBCs and reticulocytes [24, 25]. ADP can activate P2Y₁₃ receptors in RBCs to affect cAMP levels leading to inhibition of ATP release [24]. In addition to vasodilation mediated by adenosine acting on adenosine receptors, adenosine is taken up by RBCs via equilibrative nucleoside transporter 1 (ENT1) for subsequent metabolism [1, 5, 26] (Fig. 1).

Fig. 1 — Red blood cells (RBCs) and purinergic signaling in diabetes. ATP is released from RBCs via voltage-dependent anion channels and likely pannexin 1. ATP can activate various P2X, P2Y₁, P2Y₂, and P2Y₄ receptors on the endothelium leading to nitric oxide (NO) and prostacycline (PGI₂) productions. ATP is degraded to ADP acting on P2Y₁ on the endothelium. The further degradation product adenosine (Ado) activates A_2A and A_2B on the vasculature leading to vasodilation. NO and PGI₂ interact with RBCs to inhibit hypoxia-induced ATP release and stimulate PGI₂ receptor-mediated ATP release, respectively. ADP activates P2Y₁₃ receptors in RBCs having negative feedback effect on ATP release. Ado is taken up by equilibrative nucleoside transporter 1 (ENT1) in RBCs for its metabolism. In diabetes, ATP release from RBCs is impaired. Accordingly, the downregulated ATP and its degradation products affect the corresponding purinergic receptors leading to less vasodilation. Moreover, endothelial dysfunction induced by RBCs of diabetes is through alteration of vascular purinergic P2X₇ and A₁ receptors. Increased reactive oxygen species (ROS) is speculated to activate vascular ATP release for the activation of vasoconstrictor P2X₇ and A₁ receptors. The effects of NO and PGI₂ as well as ADP-mediated P2Y₁₃ activation on ATP release from the RBCs in diabetes remain to be determined. Solid lines indicate established pathways, while dash lines indicate the pathways need to be proved in the future studies. Black arrows toward up indicate increasing effects, while black arrows toward down indicate decreasing effects. Question mark indicates the role that is currently under controversy

The release of ATP from RBCs is defective in diabetic patients [11, 12]. One study suggests that such impairment is associated with more senescent RBCs in diabetes [27]. As RBC P2Y₁₃ receptors exert negative feedback effect for ATP release [24], it is of interest to investigate whether this receptor is involved in impairment of the ATP release in diabetes. Of further importance, the impaired ATP release from RBCs is associated with less vasodilation in arteries incubated with RBCs from patients with T2D [12] (Fig. 1). One proposed mechanism is pointed to less activation of ATP/ADP-mediated P2Y₁ receptors and subsequent less NO and PGI₂ production [2, 11]. It is possible that less PGI₂ production in diabetes further downregulates PGI₂ receptor-mediated ATP release in RBCs. The negative feedback effect of less NO generation in diabetes on ATP release in RBCs remains unclear, however. On the other hand, the impaired vasodilation could be partially attributed to upregulation of vasoconstrictor purinergic receptors activated by RBCs of T2D. This is supported by a recent study showing that vasoconstrictor A₁ and P2X₇ receptors are involved in endothelial dysfunction induced by RBCs from T2D patients [13] (Fig. 1). However, activation of those vascular purinergic receptors is unlikely due to a direct stimulus of the impaired ATP release from RBCs. The authors speculated that increased ROS formation derived from RBCs in diabetes may stimulate ATP release in other (endothelial) cells than RBCs to activate P2X₇ receptors in endothelium and the degraded product adenosine could then activate the vasoconstrictor A₁ receptors [13]. More studies are needed to elucidate the key purinergic signaling transmitted between the RBCs and vascular wall.

Platelet and purinergic signaling in diabetes

Platelets play a crucial role in the regulation of hemostasis, thrombosis, coagulation, and vascular function [6, 28]. A close interaction with vascular wall has been well recognized that platelet activation and the local initiation of the coagulation cascade that lead to thrombus formation are usually observed at the site of vascular injury [6, 14]. Of note, platelets are hyperactive in diabetes, as is reflected by several dysregulated signaling pathways (e.g., hyperglycemia and oxidative stress) in platelets that lead to an increased tendency to activate and aggregate in response to even a low-grade stimulus [14, 15]. This leads to the pathology by not only promoting thrombus formation but also causing microvascular embolization and endothelial dysfunction that accelerate progression of local vascular damage [14, 29]. This process significantly contributes to diabetes-associated cardiovascular events such as myocardial infarction and stroke [30].

One of the mechanisms underlying platelet activation has been shown to be due to the involvement of ADP-mediated purinergic signaling [6, 31] (Fig. 2). Several purinergic receptors including A_2A, A_2B, P2X₁, P2Y₁, and P2Y₁₂ receptors are expressed and functional in human platelets [26, 32]. Activation of pannexin-1 in platelets via collagen leads to an exchange of calcium and ATP [30]. Extracellular ATP activates P2X₁ receptors leading to platelet shape change through extracellular calcium influx [4, 31]. ATP is subsequently degraded to ADP and adenosine [31]. ADP exerts a positive feedback on platelet reactivity. Activation of the P2Y₁ receptor in response to ADP leads to shape change and initiation of platelet aggregation. The activation of P2Y₁ receptors stimulates phospholipase C (PLC)-inositol triphosphate (IP3) axis leading to mobilization of intracellular calcium [31]. ADP-activated P2Y₁ receptors also exert synergistic effect to potentiate the ATP-P2X₁ receptor-mediated action [4, 31]. In addition to activating P2Y₁ receptors, ADP activates Gi-coupled P2Y₁₂ receptors resulting in stabilization of platelet aggregation [31]. The Gαi2 subunit inhibits AC, thereby reducing cAMP levels. Although inhibition of AC is a key feature of platelet activation by ADP, this process has no causal relationship to platelet aggregation [33]. There is a complex signaling interaction between P2Y₁ and P2Y₁₂ receptors. Activation of P2Y₁₂ receptors positively regulates P2Y₁ receptor-mediated action, while activation of P2Y₁ receptors negatively regulates the effect of P2Y₁₂ receptors [34]. In contrast, adenosine could exert inhibitory effects on platelet activation via A_2A and A_2B receptors resulting in increased cAMP formation mainly during tissue injury and inflammation [26, 31] (Fig. 2).

Accumulative evidence has shown an alteration of purinergic components in platelets in diabetes (Fig. 2). Platelet ATP and ADP levels from patients with diabetes were higher than in platelets from healthy subjects [35]. Stimulation with thrombin in those platelets caused greater release of ATP and ADP than in the healthy group [35]. Significant correlations between platelet ATP/ADP and platelet activities have been found in diabetic patients [35]. There are also more abundantly expressed P2Y₁ and P2Y₁₂ receptors in platelets in diabetes [15]. Nucleoside triphosphate diphosphohydrolase (NTPDase), an enzyme that hydrolyzes ATP and ADP, was found to be elevated in platelet-rich plasma preparations from diabetic patients and rats [36–41]. Studies on the role for 5’-nucleotidase that degrades AMP to adenosine are not consistent. The enzyme activity in diabetes was observed to be decreased [36], unaltered [41], or increased [37–40]. Adenosine deaminase was found to be either increased or unaltered in platelets of diabetic rats [36, 38]. There is also evidence showing hyperglycemia has direct impact on ATP, ADP, and AMP hydrolysis in T2D patients [42]. In addition to the platelet activation upon vascular injury, activated platelets in diabetes have shown to cause endothelial dysfunction in healthy vasculature by increasing vascular oxidative stress, thromboxane A₂ production, and reducing NO bioavailability [29], suggesting a vicious circle for promoting vascular injury (Fig. 2). However, the functional implications of the altered adenine nucleotides and enzymes in platelets for the diabetes-associated vascular complications remain to be determined.

Interplay between RBCs and platelets

Platelets have been thought to be the first cells being recruited to the site of vascular injury. However, this was challenged by a study showing that RBCs were the first cells adhering to the injured endothelium/vascular wall followed by recruitment of platelets [43]. Both RBCs and platelets of T2D origin induce vascular injury through increased formation of ROS, decreased NO bioavailability, and possibly altering purinergic signaling [7, 29]. However, the current knowledge regarding the purinergic signaling regulating a functional interaction between RBCs and platelets in the circulation in diabetes is sparse. NO and PGI₂ have been established as potent inhibitors for platelet aggregation [6, 28]. Decreased NO bioactivity and PGI₂ from endothelial cells and RBCs (likely via impaired ATP release) in diabetes further promote platelet activation (Fig. 3). Platelets are hyperactive in diabetes, which are more sensitive to activation even by a weak stimulation of purines [15]. Despite less ATP/ADP released from RBCs, it can be speculated that platelets could still be activated by impaired RBC-derived ATP and subsequent less degradation product of ADP in diabetes (Fig. 3). In contrast to impairment of ATP release from RBCs, platelet-derived ATP-ADP signaling is enhanced in diabetes, which exerts positive feedback on P2Y₁ and P2Y₁₂ receptors on platelets promoting platelet activation and aggregation [31]. As mentioned above, ATP release from RBCs is defective in diabetes, which results in less vasodilation [2]. It is unlikely that enhanced platelet-derived ATP-ADP signaling exerts any compensatory or beneficial effects on vascular function, as the overall effect of platelets isolated from diabetic animals is to induce endothelial dysfunction [29]. Instead, enhanced platelet-derived ATP in diabetes may stimulate vascular vasoconstrictor purinergic receptors in the circulation that are upregulated by the dysfunctional RBCs [13] (Fig. 3). More studies are needed to investigate the contribution of enhanced platelet-derived ATP/ADP to the activation of vascular purinergic receptors in diabetes. Moreover, how platelet-derived ADP in diabetes affects P2Y₁₃ receptors on RBCs for the subsequent ATP release remains unknown and is of interest for further investigations.

Fig. 3 — Interplay between RBCs and platelets in diabetes. ATP release from RBCs in diabetes is defective, which together with its degradation products induces less vasodilation. Platelets become sensitive to stimuli in diabetes; the less amount of ATP and ADP derived from RBCs may still activate platelets via P2X₁, P2Y₁, and P2Y₁₂ receptors. Decreased bioavailability of nitric oxide (NO) and prostacyclin (PGI₂) and increased reactive oxygen species (ROS) from endothelial cells as well as RBCs could promote platelet activation. Enhanced platelet-derived purine/adenosine (Ado) may activate vasoconstrictor purinergic receptors (e.g., A₁ and P2X₇) upregulated by dysfunctional RBCs resulting in vascular injury. Whether there is a crosstalk between enhanced platelet-derived purine/Ado and P2Y₁₃ receptors in RBCs remains unclear. Ticagrelor has been thought to mainly target P2Y₁₂ receptors in platelets for platelet aggregation. The pleiotropic cardiovascular effects by ticagrelor in diabetes are proposed to be via its additional actions on ATP release and inhibition of Ado uptake from RBCs. Whether ticagrelor directly activates P2Y₁₂ receptor in RBCs remains to be determined. Solid lines indicate established pathways, while dash lines indicate the pathways need to be proved in the future studies. Black arrows toward up indicate increasing effects, while black arrows toward down indicate decreasing effects. Yellow lines indicate the effects of ticagrelor on purinergic signaling between erythrocytes and platelets in diabetes

Several P2Y₁₂ receptor antagonists like clopidogrel and ticagrelor have been developed and are commonly prescribed to target ADP-mediated P2Y₁₂ receptor activation in platelets for the treatment of thrombosis, stroke, and myocardial infarction in millions of patients with/without diabetes [16]. In addition to targeting platelets, ticagrelor is the only drug influencing RBCs [26], which may have a great potential to be involved in the interplay between RBCs and platelets. Indeed, ticagrelor can induce substantial amount of ATP release from RBCs by changing the membrane potential of RBCs, which are inhibited by anion transporter inhibitors 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) and probenecid [44]. Although P2Y₁₂ receptors are present in the human RBCs [24], it remains unknown whether ticagrelor could activate P2Y₁₂ receptors in RBCs for the ATP release. Of further interest, ticagrelor can target RBC ENT1 to inhibit adenosine uptake by RBCs, thereby increasing concentration of adenosine in the circulation [45]. Through these two pathways, ticagrelor-induced ATP release from RBCs may compensate for the impairment of ATP release from RBCs in T2D, thereby attenuating diabetes-associated vascular complications [26]. On the other hand, ticagrelor-inhibited adenosine uptake may counteract the ADP-mediated platelet activation via activation of A_2A and A_2B receptors [46] (Fig. 3). This hypothesis may increase the insights into understanding the potential mechanisms underlying the pleiotropic cardiovascular effects by ticagrelor in diabetes. These beneficial effects include anti-inflammation, increase in NO bioavailability, improvement in endothelial function, and decrease in major adverse cardiovascular event [47–49]. Given the abundance of RBCs and platelets and the active purinergic communication in the circulation, the RBCs and platelets may serve as potential therapeutic targets for the treatment of diabetes-associated vascular complications. The fact that the concentrations of RBCs exceed those of platelets in the circulation may require a higher dose of the future pharmacological agent to achieve an effective effect on RBCs.

Conclusion

Both RBC- and platelet-derived purinergic signaling play a significant role in the regulation of vascular function in diabetes. There are complex purinergic networks communicating with each other between RBCs and platelets in the vasculature. However, the contribution of purinergic (in)activation derived from dysfunctional RBCs and platelets to the vascular dysfunction in diabetes remains unclear. Experimental studies to evaluate the proposed interaction of purinergic signaling between RBCs and platelets for diabetes-associated vascular dysfunction are warranted. A better understanding of the purinergic communication between these cells will enhance their potentials as targets for the treatment of diabetes-associated vascular complications.

Zhichao Zhou

is Assistant Professor of Division of Cardiology, Department of Medicine Solna at Karolinska Institutet, Sweden. He obtained his PhD in 2013 at the Erasmus University Medical Center Rotterdam, the Netherlands. He worked as a post-doctorate research fellow at the West Virginia University in USA (2014-2015) and Karolinska Institutet in Sweden (2015-2018). His research goals are to elucidate the novel disease mechanisms underlying cardiovascular complications and ultimately find the effective therapies. His current focus is on the role of erythrocyte as disease mediator of cardiovascular dysfunction in various cardiovascular and metabolic disorders. graphic file with name 11302_2021_9807_Figa_HTML.jpg

Author contribution

Z.Z. conceived and designed the study; Z.Z. wrote and edited the manuscript.

Funding

Open access funding provided by Karolinska Institute. This study was supported by the Swedish Heart and Lung Foundation 20190341 and 20200326, the Loo and Hans Ostermans Foundation 2018–01213 and 2020–01209, the Eva and Oscar Alréns Foundation 2021–1233, and the Karolinska Institute grants 2018–01837 and 2020–02285.

Data availability

Not applicable.

Code availability

Not applicable.

Declarations

Conflict of interest

The author declares no competing interests.

Ethical approval

This article does not contain any studies with human participants or animals performed by the author.

Footnotes

Publisher's note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Not applicable.

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[CR33] 33.Cattaneo M. Bleeding manifestations of congenital and drug-induced defects of the platelet P2Y12 receptor for adenosine diphosphate. Thromb Haemost. 2011;105(Suppl 1):S67–74. doi: 10.1160/THS10-11-0742. [DOI] [PubMed] [Google Scholar]

[CR34] 34.Hardy AR, Jones ML, Mundell SJ, Poole AW. Reciprocal cross-talk between P2Y1 and P2Y12 receptors at the level of calcium signaling in human platelets. Blood. 2004;104(6):1745–1752. doi: 10.1182/blood-2004-02-0534. [DOI] [PubMed] [Google Scholar]

[CR35] 35.Michno A, Bielarczyk H, Pawelczyk T, Jankowska-Kulawy A, Klimaszewska J, Szutowicz A. Alterations of adenine nucleotide metabolism and function of blood platelets in patients with diabetes. Diabetes. 2007;56(2):462–467. doi: 10.2337/db06-0390. [DOI] [PubMed] [Google Scholar]

[CR36] 36.Pereira ADS, de Oliveira LS, Lopes TF, Baldissarelli J, Palma TV, Soares MSP, Spohr L, Morsch VM, de Andrade CM, Schetinger MRC, Spanevello RM. Effect of gallic acid on purinergic signaling in lymphocytes, platelets, and serum of diabetic rats. Biomed Pharmacother. 2018;101:30–36. doi: 10.1016/j.biopha.2018.02.029. [DOI] [PubMed] [Google Scholar]

[CR37] 37.Stefanello N, Schmatz R, Pereira LB, Cardoso AM, Passamonti S, Spanevello RM, Thome G, de Oliveira GMT, Kist LW, Bogo MR, Morsch VM, Schetinger MRC. Effects of chlorogenic acid, caffeine and coffee on components of the purinergic system of streptozotocin-induced diabetic rats. J Nutr Biochem. 2016;38:145–153. doi: 10.1016/j.jnutbio.2016.08.015. [DOI] [PubMed] [Google Scholar]

[CR38] 38.Schmatz R, Mann TR, Spanevello R, Machado MM, Zanini D, Pimentel VC, Stefanello N, Martins CC, Cardoso AM, Bagatini M, Gutierres J, Leal CA, Pereira LB, Mazzanti C, Schetinger MR, Morsch VM. Moderate red wine and grape juice consumption modulates the hydrolysis of the adenine nucleotides and decreases platelet aggregation in streptozotocin-induced diabetic rats. Cell Biochem Biophys. 2013;65(2):129–143. doi: 10.1007/s12013-012-9407-5. [DOI] [PubMed] [Google Scholar]

[CR39] 39.Miron VR, Bauermann L, Morsch AL, Zanin RF, Correa M, da Silva AC, Mazzanti C, Morsch VM, Lunkes GI, Schetinger MR. Enhanced NTPDase and 5'-nucleotidase activities in diabetes mellitus and iron-overload model. Mol Cell Biochem. 2007;298(1–2):101–107. doi: 10.1007/s11010-006-9357-6. [DOI] [PubMed] [Google Scholar]

[CR40] 40.Lunkes GI, Lunkes DS, Morsch VM, Mazzanti CM, Morsch AL, Miron VR, Schetinger MR. NTPDase and 5'-nucleotidase activities in rats with alloxan-induced diabetes. Diabetes Res Clin Pract. 2004;65(1):1–6. doi: 10.1016/j.diabres.2003.11.016. [DOI] [PubMed] [Google Scholar]

[CR41] 41.Lunkes GI, Lunkes D, Stefanello F, Morsch A, Morsch VM, Mazzanti CM, Schetinger MR. Enzymes that hydrolyze adenine nucleotides in diabetes and associated pathologies. Thromb Res. 2003;109(4):189–194. doi: 10.1016/s0049-3848(03)00178-6. [DOI] [PubMed] [Google Scholar]

[CR42] 42.Lunkes GI, Lunkes DS, Leal D, Araujo Mdo C, Correa M, Becker L, Rosa CS, Morsch VM, Schetinger MR. Effect of high glucose levels in human platelet NTPDase and 5'-nucleotidase activities. Diabetes Res Clin Pract. 2008;81(3):351–357. doi: 10.1016/j.diabres.2008.06.001. [DOI] [PubMed] [Google Scholar]

[CR43] 43.Barr JD, Chauhan AK, Schaeffer GV, Hansen JK, Motto DG. Red blood cells mediate the onset of thrombosis in the ferric chloride murine model. Blood. 2013;121(18):3733–3741. doi: 10.1182/blood-2012-11-468983. [DOI] [PMC free article] [PubMed] [Google Scholar]

[CR44] 44.Ohman J, Kudira R, Albinsson S, Olde B, Erlinge D. Ticagrelor induces adenosine triphosphate release from human red blood cells. Biochem Biophys Res Commun. 2012;418(4):754–758. doi: 10.1016/j.bbrc.2012.01.093. [DOI] [PubMed] [Google Scholar]

[CR45] 45.Cattaneo M, Schulz R, Nylander S. Adenosine-mediated effects of ticagrelor: evidence and potential clinical relevance. J Am Coll Cardiol. 2014;63(23):2503–2509. doi: 10.1016/j.jacc.2014.03.031. [DOI] [PubMed] [Google Scholar]

[CR46] 46.Johnston-Cox HA, Yang D, Ravid K. Physiological implications of adenosine receptor-mediated platelet aggregation. J Cell Physiol. 2011;226(1):46–51. doi: 10.1002/jcp.22379. [DOI] [PubMed] [Google Scholar]

[CR47] 47.Ahmed YM, Anwar B, El-Daly ME, Abo-Saif AA. Effects of ticagrelor, empagliflozin and tamoxifen against experimentally-induced vascular reactivity defects in rats in vivo and in vitro. Pharmacol Rep. 2019;71(6):1034–1043. doi: 10.1016/j.pharep.2019.06.004. [DOI] [PubMed] [Google Scholar]

[CR48] 48.Mangiacapra F, Panaioli E, Colaiori I, Ricottini E, Lauria Pantano A, Pozzilli P, Barbato E, Di Sciascio G. Clopidogrel versus ticagrelor for antiplatelet maintenance in diabetic patients treated with percutaneous coronary intervention: results of the CLOTILDIA study (Clopidogrel High Dose Versus Ticagrelor for Antiplatelet Maintenance in Diabetic Patients) Circulation. 2016;134(11):835–837. doi: 10.1161/CIRCULATIONAHA.116.023743. [DOI] [PubMed] [Google Scholar]

[CR49] 49.Bhatt DL, Steg PG, Mehta SR, Leiter LA, Simon T, Fox K, Held C, Andersson M, Himmelmann A, Ridderstrale W, Chen J, Song Y, Diaz R, Goto S, James SK, Ray KK, Parkhomenko AN, Kosiborod MN, McGuire DK, Harrington RA, Committee TS, Investigators, Ticagrelor in patients with diabetes and stable coronary artery disease with a history of previous percutaneous coronary intervention (THEMIS-PCI): a phase 3, placebo-controlled, randomised trial. Lancet. 2019;394(10204):1169–1180. doi: 10.1016/S0140-6736(19)31887-2. [DOI] [PubMed] [Google Scholar]

PERMALINK

Purinergic interplay between erythrocytes and platelets in diabetes-associated vascular dysfunction

Zhichao Zhou

Abstract

Introduction

RBC and purinergic signaling in diabetes

Fig. 1.

Platelet and purinergic signaling in diabetes

Fig. 2.

Interplay between RBCs and platelets

Fig. 3.

Conclusion

Zhichao Zhou

Author contribution

Funding

Data availability

Code availability

Declarations

Conflict of interest

Ethical approval

Footnotes

References

Associated Data

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

Purinergic interplay between erythrocytes and platelets in diabetes-associated vascular dysfunction

Zhichao Zhou

Abstract

Introduction

RBC and purinergic signaling in diabetes

Fig. 1.

Platelet and purinergic signaling in diabetes

Fig. 2.

Interplay between RBCs and platelets

Fig. 3.

Conclusion

Zhichao Zhou

Author contribution

Funding

Data availability

Code availability

Declarations

Conflict of interest

Ethical approval

Footnotes

References

Associated Data

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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