Background: Obesity and type 2 diabetes (T2D) are major risk factors for cardiovascular diseases (CVD). Dysregulated pro-apoptotic ceramide synthesis reduces β-cell insulin secretion, thereby promoting hyperglycemic states which may manifest as T2D. Pro-apoptotic ceramides modulate insulin sensitivity and glucose tolerance while being linked to poor cardiovascular outcomes. Sirtuin-1 (SIRT1) is a NAD + - dependent deacetylase that protects against pancreatic β-cell dysfunction; however, systemic levels are decreased in obese T2D mice and may promote pro-apoptotic ceramide synthesis and hyperglycemia. Herein, we aimed to assess the effects of restoring circulating SIRT1 levels to prevent metabolic imbalance in obese and diabetic mice.
Methods and results: Circulating SIRT1 levels were reduced in obese diabetic mice (db/db) as compared to age-matched non-diabetic db/+ controls. Restoration of SIRT1 plasma levels with recombinant murine SIRT1 for 4-weeks prevented body weight gain, improved glucose tolerance, insulin sensitivity and vascular function in mice models of obesity and T2D. Untargeted lipidomics revealed that SIRT1 restored insulin-secretory function of β-cells by reducing synthesis and accumulation of pro-apoptotic ceramides. Molecular mechanisms involved direct binding to and deacetylation of Toll-like receptor 4 (TLR4) by SIRT1 in β-cells thereby decreasing the rate limiting enzymes of sphingolipid synthesis SPTLC1/2 via AKT/NF-κB. Among T2D patients, those with high baseline plasma levels of SIRT1 prior to metabolic surgery displayed restored β-cell function (HOMA2- β) and were more likely to have T2D remission during follow-up.
Conclusion: Acetylation of TLR4 promotes β-cell dysfunction via ceramide synthesis in T2D, which is blunted by systemic SIRT1 replenishment. Hence, restoration of systemic SIRT1 may provide a novel therapeutic strategy to counteract toxic ceramide synthesis and mitigate cardiovascular complications of T2D.
Keywords: Sirtuin-1; cardiovascular disease; ceramide synthesis; post-translational modification; type 2 diabetes; β-cell function.
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