Abstract
Background and aims
Obesity, hepatosteatosis, and hypertriglyceridemia are components of the metabolic syndrome and independent risk factors for cardiovascular disease. The lipid droplet-associated protein CIDEC (cell death-inducing DFFA-like effector C), known in mice as FSP27 (fat-specific protein 27), plays a key role in maintaining triacylglyceride (TAG) homeostasis in adipose tissue and liver, and controls circulating TAG levels in mice. Importantly, mutations and SNPs in CIDEC are associated with dyslipidemia and altered metabolic function in humans. Here we tested whether systemic silencing of Fsp27 using antisense oligonucleotides (ASOs) was atheroprotective in LDL receptor knock-out (Ldlr−/−) mice.
Methods
Atheroprone Ldlr−/− mice were fed a high-fat, high-cholesterol diet for 12 weeks while simultaneously dosed with saline, ASO-ctrl, or ASO-Fsp27.
Results
Data show that, compared to control treatments, silencing Fsp27 significantly reduced body weight gain and visceral adiposity, prevented diet-induced hypertriglyceridemia, and reduced athero-sclerotic lesion size both in en face aortas and in the aortic root.
Conclusions
Our findings suggest that therapeutic silencing of Fsp27 with ASOs may be beneficial in the prevention and management of atherogenic disease in patients with metabolic syndrome.
Keywords: FSP27, Atherosclerosis, Obesity, Hypertriglyceridemia, Antisense therapy
1. Introduction
Central obesity, non-alcoholic fatty liver disease, insulin resistance, and hypertriglyceridemia are core manifestations of the metabolic syndrome (MetS) (reviewed in Ref. [1]). A global epidemic affiicting both adults and children, MetS is associated with increased risk for atherogenic cardiovascular disease, which ultimately leads to myocardial infarction and stroke. Although the mechanisms that link MetS and atherogenesis are yet to be fully elucidated, it was proposed that persistent systemic inflammation and dyslipidemia synergize to promote endothelial dysfunction, fatty streak formation, and other intimal perturbations in the arterial wall.
Lipid droplets (LDs) are critical organelles for intracellular metabolic regulation [2]. LD-associated proteins define the metabolic fate of the lipids stored within the LD. CIDEC (cell death-inducing DFF45-like effector C; referred to as Fsp27 or fat specific protein 27 in mice) was originally identified as an abundant transcript in white and brown adipocytes [3], where it facilitates LD growth by both promoting LD fusion and inhibiting the action of lipases [4–7]. Two CIDEC/Fsp27 isoforms (α and β) that differ in 10 aa at the N-terminus are expressed via alternative promoters [8]. CIDEC/Fsp27 is barely detectable in the normal liver, but its expression is drastically elevated in the livers of obese patients [8–10] and mice [11–14], as well as in response to fasting in mice [11,15]. Recent studies showed that FSP27 activity modulates different physiological responses related to MetS. Fsp27−/− mice are lean, resistant to diet-induced obesity, and show enhanced insulin sensitivity [16,17]. Paradoxically, though, high-fat diet-fed Fsp27−/− [18], ob/ob × Fsp27−/− [18], and adipocyte-specific Fsp27−/− [19] mice develop severe lipodystrophy, fatty liver, and insulin resistance. On the other hand, antisense oligonucleotide (ASO)-mediated silencing of Fsp27 in genetic or dietary murine models of obesity and diabetes results in decreased visceral adiposity, reduced triacylglyceride (TAG) contents in fat pads, multilocular brown-like white adipocytes, reduced circulating VLDL-TAG, and improved whole-body glycemic control and multi-organ insulin sensitivity [12,20]. Acute shRNA-mediated knock-down of hepatic Fsp27 reduces fasting and diet-induced hepatosteatosis [11,14,21]. In contrast, long-term systemic ASO-mediated Fsp27 silencing abolishes diet-induced hepatic TAG accumulation only when used in combination with a fibrate [20], but not by itself [12,20]. Collectively, these reports suggest that silencing Fsp27 may provide atheroprotection by ameliorating several independent cardiovascular risk factors. Herein we tested the effects of ASO-based anti-Fsp27 therapy on the progression of arterial disease in high fat, high cholesterol-fed atheroprone Ldlr−/− mice.
2. Materials and methods
2.1. Chemicals
Chimeric 2′-methoxyethyl control (5′-CCTTCCCTGAAGGTT CCTCC) and anti-Fsp27 (5′-CAGACTCTAATACCATTCAC) antisense oligonucleotides (ASOs) were synthesized and purified as described [22], suspended in saline, and stored at −20 °C until use.
2.2. Mouse studies
All animals were maintained in a 12 h/12 h light/dark cycle with ad libitum access to food and water. LDL-receptor knockout (Ldlr−/−) mice (Jackson Laboratories stock 002207) were bred in our facility and kept on a normal diet (PicoLab Rodent Diet 20). At 12 weeks of age, male mice were switched to a western diet (WD) containing 21% fat and 1.25% cholesterol (Research Diets D12108) for 12 weeks. While on WD, 100 μL ASOs (25 mg/kg) or saline were injected i. p. twice weekly (Monday and Thursday). Mice were sacrificed at 9–10 a.m. without prior fasting, and plasma, liver, and gonadal white adipose tissue (gWAT), were harvested for analysis. In a subset of mice within each experimental group, resident macrophages were collected from peritoneal lavages. Studies were conducted in conformity with the Public Health Service policy on humane care and use of laboratory animals, and approved by the IACUC at Saint Louis University.
2.3. Plasma analysis
Blood samples were collected one week prior to start of WD and treatment regimen via superficial temporal vein bleeds, and upon sacrifice via inferior vena cava. Total cholesterol and triglycerides were assayed enzymatically using colorimetric kits (Wako Chemicals, Richmond, VA). Lipoprotein profiles were obtained by a modified Column Lipoprotein Profile (CLiP) method [23]. Briefly, 20 μL of pooled plasma were diluted in 60 μL of saline, and 40 μL of this mixture was auto-injected into a Superose-6 column (GE Healthcare, Wilmington, MA) using elution buffer (saline, 2 mmol/L EDTA, pH 7.4) at a flow rate of 0.6 mL/min at 40 °C. The eluate was immediately mixed with cholesterol or triglyceride reagent (Pointe Scientific, Ann Arbor, MI) at a flow rate of 0.2 mL/min, and incubated at 40 °C in a 5 m KOT coiled reactor. The final mixture entered a capillary spectrophotometric detector set at 500 nm, and the profiles were collected in real time using LC Solution software (Shimadzu, Kyoto, Japan).
2.4. Tissue lipid analysis
Lipids were extracted into chloroform by a modified Folch method [24], solubilized in water, and quantitated enzymatically using kits for triglycerides, total cholesterol, and FFAs (Wako Chemicals). Results were normalized to protein.
2.5. RNA analysis
RNA was isolated from tissues using Direct-zol RNA miniprep kit (ZYMO Research, Irvine, CA), and analyzed by real-time quantitative PCR using PowerSybrGreen (Life Technologies, Carlsbad, CA) and a LightCycler LC480 instrument (Roche, Indianapolis, IN). Values were normalized to 36b4, and relative expression calculated using the ΔΔCt method. Primer sequences are available upon request.
2.6. Histology
Samples of livers and gWAT were fixed in 10% formalin and embedded in paraffin blocks. Sections (5 μm) were processed for hematoxylin and eosin staining using standard techniques.
2.7. Analysis of atherosclerotic lesions
Whole aortas were dissected from the heart to the iliac bifurcation. Aortas and the upper half of the hearts were fixed in formalin-sucrose buffer (10% formalin, 20 μmol/L EDTA, 5% sucrose, pH 7.4), and stored at 4 °C. En face preparations of the aorta were pinned and stained with oil red O. Hearts were embedded in paraffin, and 20 serial sections (5 μm) of the aortic root (covering 1 mm around the aortic valve) were stained with hematoxylin and eosin. Atheromata were quantified using ImageJ software by a single operator blind to the identity of the samples, as described [25]. Select sections of the aortic root were stained with a monoclonal rat anti-mouse CD68 antibody (1:400 dilution; AbD Serotec) or Masson’s trichrome to visualize macrophage and collagen content, respectively.
2.8. Macrophage studies
Macrophages from saline- and ASO-treated mice (n = 5 each) were isolated from the peritoneal cavity 4 days after injection of 2 mL of 3% thioglycollate broth. Red blood cells were removed with ACK lysis buffer (150 mmol/L NH4Cl, 10 mmol/L KHCO3, 0.1 mmol/L EDTA, pH 7.4), and pellets frozen for RNA extraction. Bone marrow cells were obtained from the tibias and femurs of chow-fed C57BL/6 mice, and differentiated to macrophages in media supplemented with 20 ng/mL M-CSF for 4 days, as described [26]. Cells were then incubated in media supplemented with PBS or 40 μg/mL oxLDL (AlfaAesar, Tewksbury, MA) overnight.
2.9. Statistical analysis
Data are shown as mean ± s. e.m. Differences between groups were analyzed by one-way ANOVA followed by post-hoc Bonferroni’s test, using SPSS version 20.0 (IBM, Armonk, NY). Differences were considered significant at p ≤ 0.05.
3. Results
To test the usefulness of therapeutic silencing of Fsp27 on atherogenesis, male Ldlr−/− mice were fed a western diet for 12 weeks, while dosed with saline, ASO-control, or ASO-Fsp27. Fig. 1A and B show that treatment with ASO-Fsp27 reduced body weight gain after 5 weeks, and led to a ~4 g reduction in body mass at the end of the 12-week feeding, compared to control mice. These changes occurred in the absence of significant differences in caloric intake (Fig. 1C). Analysis of plasma lipids in Fig. 1D–E revealed the expected diet-induced increase in TAG and cholesterol; however, treatment with ASO-Fsp27 resulted in a significant drop in VLDL-TAG. In contrast, no changes were observed in circulating cholesterol lipoprotein fractions.
Fig. 1.
ASO-Fsp27 therapy ameliorates diet-induced obesity and hypertriglyceridemia. Ldlr−/− mice were fed a WD for 12 weeks while injected twice weekly with saline, ASO-ctrl, or ASO-Fsp27.
(A) Weekly body weight gain. (B) Final body weight. (C) Caloric intake during the last week of the experiment. (D and E) Plasma lipid contents on weeks 0 and 12, and FPLC lipoprotein profiles on week 12. Data are shown as means ± s.e.m. (n = 14). *p ≤ 0.05, **p ≤ 0.01, compared to saline; ‡p ≤ 0.05, ‡‡p ≤ 0.01 compared to ASO-ctrl.
The effects of ASO-Fsp27 therapy on body weight are likely due to the reduction in visceral adiposity (Fig. 2A and B). Unexpectedly, ASO-ctrl modestly reduced gonadal fat pad mass, compared to saline. Fig. 2D shows that Fsp27 expression in epididymal white adipose tissue (eWAT) was efficiently and selectively silenced by ASO-Fsp27. Consistent with the data on tissue mass, eWAT TAG contents were reduced in ASO-treated mice, compared to saline; the effect of ASO-Fsp27, however, was considerably larger than that of ASO-ctrl (Fig. 2C). No changes were noted in tissue cholesterol contents. At the histological level, adipocytes in both the saline and ASO-ctrl groups appeared enlarged (Fig. 2E). In contrast, adipocytes from ASO-Fsp27-treated mice were smaller and heterogeneous, and ~10% of the cells were multilocular (Fig. 2E). Both the multilocular adipocytes and the large induction of Ucp1, Dio2, Cox4, and Cidea transcripts, compared to saline and ASO-ctrl groups (Fig. 2F), are consistent with a browning phenotype in response to Fsp27 silencing. The elevated expression of lipolytic Atgl and Hsl transcripts in the same ASO-Fsp27 samples (Supplementary Fig. 1A) is also indicative of increased oxidative capacity, which is generally associated to these brown adipocyte-like adipocytes and likely accounts for the reduction in gonadal fat pad mass.
Fig. 2.
ASO-Fsp27 induces browning of gonadal adipose tissue.
(A) Representative macroscopic appearance of left gonadal fat pads in each experimental group. (B) Average tissue weight. (C) Relative lipid contents, normalized to protein contents. (D) Relative expression of Fsp27. (E) Representative micrographs of hematoxylin and eosin-stained sections. Scale bars represent 50 μm. Arrows indicate multilocular cells. Insert is magnified to show brown-like adipocytes. (F) Relative mRNA expression of thermogenesis/browning markers in the same samples. Data are shown as means ± s.e.m. (n = 14 for panel B; n = 6 for panels C, D, and F). *p ≤ 0.05, **p ≤ 0.01, compared to saline; ‡p ≤ 0.05, ‡‡p ≤ 0.01 compared to ASO-ctrl.
Fig. 3 shows that treatment with ASO-Fsp27 resulted in a slight enlargement of the liver, compared to the control groups. The reason for this is unknown, but it might reflect elevated water or glycogen contents. As expected, ASO-Fsp27 silenced Fsp27 expression by ~90%, compared to saline. Unexpectedly, ASO-ctrl also reduced, albeit modestly, the expression of Fsp27, compared to saline. TAG contents were similarly reduced in mice injected with ASO-ctrl or ASO-Fsp27, compared to saline. No differences in hepatic cholesterol contents were found among groups. Consistent with changes in TAG contents, histological analysis revealed large areas of macrovesicular steatosis in the saline group, which were absent in the slightly darker livers from mice injected with either ASO. Similar to eWAT, loss of Fsp27 expression resulted in a compensatory increase in Cidea mRNA. The expression of transcripts encoding other hepatic lipid droplet-associated proteins (Plin2, Plin5) was reduced by either ASO, compared to saline, likely a consequence of reduced tissue lipid contents; however, no major differences were noted comparing ASO-ctrl and ASO-Fsp27 treatments. Additionally, the expression of Atgl and Hsl was reduced and induced, respectively, in ASO-treated mice compared to saline, but no differences were noted between ASO treatment groups (Supplementary Fig. 1B). In contrast to WAT, the expression of Angptl transcripts remained unchanged among groups (Supplementary Fig. 1B). Overall, major differences among groups in both hepatic TAG content and mRNA profiles were largely mediated by oligonucleotide delivery, independent on silencing Fsp27.
Fig. 3.
ASO-Fsp27 does not impact hepatic steatosis.
(A) Representative macroscopic appearance of the livers in each experimental group. (B) Average liver weight. (C) Relative lipid contents, normalized to protein. (D) Representative micrographs of hematoxylin and eosin-stained sections. Scale bars represent 50 μm. (E) Relative mRNA expression of Fsp27 and other transcripts encoding LD-associated proteins. Data are shown as means ± s.e.m. (n = 14 for panel B; n = 6 for panels C and E). *p ≤ 0.05, **p ≤ 0.01, compared to saline; ‡p ≤ 0.05, ‡‡p ≤ 0.01 compared to ASO-ctrl.
Finally, analysis of atherosclerotic lesions both in en face preparations of the aorta (Fig. 4A) and in the aortic root (Fig. 4B) revealed a significant reduction in lesion size in the ASO-Fsp27 group, compared to saline and ASO-ctrl groups. CD68+ macrophage contents and collagen staining were increased in the roots of ASO-Fsp27–treated mice, compared to saline or ASO-ctrl (Fig. 4B); in contrast, necrotic core areas were smaller in the ASO-Fsp27 group, compared with control animals. These latter results are consistent with less advanced lesions in the ASO-Fsp27–treated mice. Collectively, the data suggest a potent atheroprotective effect following silencing of Fsp27. Since we used only male mice in this study, additional experiments are needed to establish whether the atheroprotection extends to female animals.
Fig. 4.
ASO-Fsp27 attenuates the progression of atherosclerosis.
(A) Lesion size in oil red O-stained en face preparations of the aortas, and representative images for each experimental group. (B) Left panel, total atheroma size and necrotic core size in the aortic root. Right panel, representative micrographs of serial sections stained with hematoxylin and eosin (H&E), Masson trichrome (collagen deposition in blue), and CD68 for macrophages (area corresponding to yellow rectangle in Masson panel; CD68 signal is dark brown). In both panels, each dot denotes a single animal.
A potential explanation for the reduced lesion size in ASO-Fsp27-treated mice could be that silencing Fsp27 expression in macrophages impairing cholesterol loading and thus limits the development of the initial fatty streak in the subendothelial space. To test this hypothesis, we harvested macrophages from peritoneal lavages in a subset of Ldlr−/− mice used above, and from an additional group of chow-fed (and thus, only mildly hypercholesterolemic) Ldlr−/− animals (Supplementary Fig. 2A). Representative photographs of oil red O-stained cells show that cells from WD-fed mice had more lipid droplets than those collected from chow-fed animals, but the variation in the numbers and size of intracellular lipid droplet was similar among the 3 WD-fed groups. Data show that Fsp27 is actually not expressed in these macrophages (Ct > 40 when using primers for either the α or β isoforms), independent on cholesterol loading. As anticipated, canonical LXR targets (Abca1 and Abcg1) and SREBP2 targets (Hmgcr, Sqs) were induced and repressed, respectively, in cells recovered from WD-fed mice, compared to those from chow-fed animals, but no differences in the levels of these transcripts were noted in cells from ASO-Fsp27–treated mice, compared to saline or ASO-ctrl (Supplementary Fig. 2A). Analysis of selected transcripts suggests that these peritoneal macrophages were predominantly M2-like cells (high Arg1 and Tgfβ; low Tnfα and Il6), and that ASO-Fsp27 did not affect macrophage polarization (Supplementary Fig. 2A). To further establish whether the expression of Fsp27 is modulated during foam cell formation, we cultured murine bone marrow-derived macrophages in the absence or presence of oxidized LDL (oxLDL) (Supplementary Fig. 2B). As expected, the expression of LXR and SREBP2 targets was increased and decreased, respectively, in response to oxLDL treatment. Data show that Fsp27 is again undetectable in these cells, independent on cholesterol loading. Taken together, the results in Supplementary Fig. 2 demonstrate that Fsp27 is absent in the murine macrophage, and strongly suggest that FSP27 activity does not play a role on lipid droplet growth during macrophage foam cell conversion in the early stages of atherogenesis.
4. Discussion
The role of FSP27 on adipocyte TAG metabolism has been firmly established. Biochemical studies showed that FSP27 dimerizes and mediates the fusion of small LDs and the transfer of lipids between them [27,28]. Other studies suggested that FSP27 also physically interacts with and inhibits the activity of lipases at the surface of the LD [29]. The overall result is that FSP27 activity promotes the expansion and growth of LDs. Whole-body [16–18] and adipocyte-specific [19] Fsp27−/− mice show a lipodystrophy-like phenotype with multilocular white adipocytes that validates the biochemical studies. Our studies using i.p. injected ASOs in chow-fed ob/ob [12], HFD-fed C57BL/6 [12], NASH-fed C57BL/6 [20], and Ldlr−/− (herein) mice have consistently shown reduced visceral adiposity following silencing Fsp27, but not lipodystrophy. Importantly, we report here that ASOs per se, independent on changes in Fsp27 expression, markedly reduced eWAT and liver TAG contents, compared to saline treatment. The reduction in hepatic TAG contents following injection of 2′-methoxyethyl oligonucleotides is known in the field, although the mechanism remains unknown. Hence, most published studies have focused only on changes compared to ASO-ctrl. In our hands, ASO-ctrl induced specific changes in the expression of several lipid-related genes in eWAT and liver, compared to saline, which likely explain the reduced TAG contents in these tissues. Consistent with our previous ASO studies, here we report that therapeutic silencing of Fsp27 further reduces eWAT size and TAG contents but has no effect on liver hepatosteatosis, compared to ASO-ctrl.
In the liver, CIDEC/FSP27 expression is strongly linked to TAG accumulation, both in patients [8–10] and in mice [11–14]. The functional consequences of loss of hepatic Fsp27 function are controversial, though. Acute knockdown of Fsp27 in the liver via adenoviral-mediated shRNA ameliorates fasting- [11] and diet[11,14,21] induced steatosis. In contrast, long-term silencing of Fsp27 via ASOs has no effect on hepatic TAG content in mouse models of obesity, diabetes, and fatty liver [12,20]. However, diet-induced murine hepatosteatosis is synergistically reduced when ASO-Fsp27 and fenofibrate (a PPARα synthetic agonist which does not reduce hepatic TAG contents by itself) are combined [20]. Metabolic labeling experiments in primary hepatocytes in culture demonstrated that Fsp27 activity reduces TAG turnover in the LD, and that efficient mitochondrial oxidation of fatty acids requires simultaneous Fsp27 knock-down and PPARα activation [11], nicely recapitulating the in vivo data [20].
Accelerated secretion of VLDL particles is a fundamental property of atherogenic dyslipidemia, which ultimately results in elevated numbers of atherogenic VLDL remnants and LDL particles [30,31]. Hence, hypertriglyceridemia has been identified as an independent risk factor for atherogenic cardiovascular disease, and it was proposed that cholesterol-rich VLDL-remnant particles generated by lipases in peripheral tissues can infiltrate the arterial sub-endothelial space and contribute to atherogenesis. Our data in previous reports [11,12,20] and herein suggest that hepatic FSP27 activity promotes VLDL-TAG secretion. Importantly, two SNPs in CIDEC are associated to elevated fasting triglyceridemia [32]. We hypothesize that the large reduction in circulating VLDL-TAG in ASO-Fsp27-treated mice is, at least in part, a driver for the atheroprotective phenotype in our study by limiting the availability of remnant particles. Importantly, despite both ASO-ctrl and ASO-Fsp27 treatments reduced hepatic TAG contents, the reduction in both plasma VLDL-TAG and atherosclerotic lesions were confined solely to the ASO-Fsp27–treated group; no significant differences in circulating lipids or atheromata were noted between the saline and ASO-ctrl groups. Additional experiments are currently in place to determine how FSP27 activity regulates VLDL maturation, secretion, or clearance. Interestingly, lipid lowering has been shown to increase collagen deposition and promote stability of atheromata by reducing the expression of matrix-degrading enzymes in lesional macrophages [33,34]. Our data showing reduced plasma lipids and increased collagen contents in the aortic roots of ASO-Fsp27-treted mice are consistent with this idea.
Cholesterol-laden foam cells in fatty streaks express various lipid droplet-associated proteins that promote pro- or anti-atherogenic phenotypes (reviewed in Ref. [35]). For example, loss of bone marrow-derived Plin1 [36] or Plin2 [37] expression results in reduced foam cell conversion and is atheroprotective in ApoE−/− mice. Notably, the changes in aortic lesion size in our study cannot be attributable to a role of FSP27 on foam cell formation. Indeed, we show that Fsp27 is essentially not expressed in cholesteryl esters-loaded peritoneal macrophages recovered from the Ldlr−/− mice. Additionally, Fsp27 expression is not induced following lipid loading with oxLDL in bone marrow-derived macrophages. Overall, these data suggest that the decrease in lesion size in the arterial wall in response to ASO-Fsp27 treatment is likely secondary to the availability of atherogenic mediators, rather than a defect in foam cell conversion.
Our results also underline the different outcomes of genetic (i.e., knock-out) and interventional (i.e., ASO) mouse models. Thus, the phenotype in high-fat diet-fed ASO-Fsp27–treated mice (reduced adiposity, no deleterious effects in liver, hypotriglyceridemia, enhanced insulin sensitivity in gWAT, liver, and muscle, and improved whole-body glycemic control) [12,20] sharply differs from that in high-fat diet-fed Fsp27−/− [18], ob/ob × Fsp27−/− [18], or adipocyte-specific Fsp27−/− [19] mice (lipodystrophy, fatty liver, hypertriglyceridemia, insulin resistance). We posit that the latter outcomes are secondary to the severe lipodystrophy in Fsp27−/− mice and subsequent ectopic liver lipid deposition. Residual Fsp27 activity in WAT, independent on dietary overload, likely prevents lipodystrophy and its consequences in ASO-Fsp27–treated mice. Further experiments where ASO-Fsp27 is administered for longer periods of time, though, are needed to verify that a prolonged reduction in visceral fat does not have deleterious consequences on liver function, and whole-body insulin sensitivity and glycemic control. It will also be important to establish whether sustained silencing of Fsp27 impacts the inflammatory state of the mice. Reduced systemic inflammation resulting from improved lipid homeostasis in liver and/or WAT might be an additional contributing mechanism for ASO-Fsp27–driven atheroprotection. Finally, whether therapeutic silencing of FSP27 can not only attenuate the progression of new plaques, but also promote the regression of pre-established atheromata remains to be established.
Lifestyle modifications that include improved diet, increased physical activity, and smoking and alcohol cessation, have long been established as beneficial for CVD patients [38]. The arsenal of pharmaceutical agents for these patients include anti-hypertensive, anti-thrombotic, and lipid-lowering drugs. Yet, despite these therapeutic tools, atherosclerotic CVD and its complications remain a major cause of death globally. Taken together, our data in this and previous reports suggest that, due its multifactorial beneficial effects on cardiovascular risk factors that include visceral adiposity, hepatosteatosis, glucose homeostasis, and hypertriglyceridemia, CIDEC/FSP27 may be exploited therapeutically in patients with metabolic syndrome who are at increased risk of atherosclerotic CVD.
In summary, this is the first report on the consequences of therapeutic silencing of Fsp27 on atherogenesis. Our data demonstrate that ASO-Fsp27 reduces diet-induced visceral obesity, circulating VLDL-TAG, and atheromata in Ldlr−/− mice. We also show that Fsp27 is not expressed in macrophages, which suggests that atheroprotection is not mediated by direct effects of ASO-Fsp27 on foam cell conversion in the plaque.
Supplementary Material
Acknowledgments
Financial support
This study was supported in part by NIH grant HL107794 and intramural PRF grant 9109 (to Á.B.) and an American Heart Association Clinical Health Profession Student Training Program fellowship 17CPRE33670519 (to A.R.).
We thank Grant Kolar and Barbara Nagel at the Research Microscopy and Histology Core at Saint Louis University for excellent technical support. We also thank Dr. Noemi Arias in the Baldan lab and the members of the Cardiovascular Research Center and the Liver Center at Saint Louis University for helpful discussions. Á.B. dedicates this paper to Bender (2010–2018): fly forever free, write songs across the sky.
Abbreviations
- ASO
antisense oligonucleotide
- CVD
cardiovascular disease
- CIDEC
cell death-inducing DFFA-like effector C
- FSP27
fat-specific protein 27
- gWAT
gonadal white adipose tissue
- HDL
high-density lipoprotein
- HFD
high-fat diet
- LD
lipid droplet
- LDL
low-density lipoprotein
- MetS
metabolic syndrome
- NASH
non-alcoholic steatohepatitis
- PPAR
peroxisome proliferator-activated receptor
- TAG
triacylglyceride
- VLDL
very low-density lipoprotein
- WD
western diet
Appendix A. Supplementary data
Supplementary data related to this article can be found at https://doi.org/10.1016/j.atherosclerosis.2018.05.045.
Footnotes
Conflicts of interest
A.R. and Á.B. declare no competing financial interests. R.G.L. is an employee and shareholder of Ionis Pharmaceuticals, Inc.
Author contributions
A.R. and Á.B. conceived and designed the study, and wrote the manuscript. A.R. performed the study and analyzed the data. R.G.L. provided the antisense oligonucleotides. All authors approved the manuscript.
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