Abstract 118: Cholesteryl Ester Transfer Protein Overrides The Protective Effect Of APOA1 On Arterial APOB Lipoprotein Trapping And Atherosclerosis Progression In A Mouse Model Of Type 1 Diabetes

Abstract

Despite the benefits of LDL-cholesterol-reducing medications, patients with type 1 diabetes (T1D) continue to have an increased risk of incident CVD. Preclinical and clinical observations indicate that triglyceride-rich lipoproteins (TRLs) and their remnants may contribute significantly to CVD risk in T1D. Recently, we have shown that diabetes increases levels of atherogenic TRL remnants and that improvement of remnant clearance halts atherosclerosis in a mouse model of T1D. Cholesteryl ester transfer protein (CETP), which is normally absent in mice, links metabolism of TRLs to that of HDL by mediating the transfer of cholesteryl ester from HDL to VLDL and other APOB-containing lipoproteins in exchange for triglycerides. We hypothesized that CETP impairs the atheroprotective effects of APOA1 by altering TRL and HDL metabolism in diabetes. To test this hypothesis, we developed a virally-induced T1D mouse model expressing the human APOA1 transgene ( APOA1 Tg , Ldlr –/– ). Cohorts of these mice were injected with a liver-targeted adeno-associated virus to express human CETP, and the effects on lipoproteins, plasma apolipoproteins, HDL particle concentrations (HDL-P), and atherosclerosis in the presence and absence of diabetes were determined. This mouse model exhibits an HDL profile similar to humans, with small, medium and large HDL-P, whereas wildtype ( Ldlr -/- ) littermates have only one sized HDL-P. Expression of the APOA1 transgene significantly suppressed diabetes-accelerated necrotic core expansion and accumulation of APOB and APOE in the aortic sinus (compared to wildtype Ldlr -/- mice), while CETP impaired the protective effect of APOA1 on these parameters in diabetic APOA1 Tg , Ldlr –/– mice (n= 22-30, p < 0.05). Further characterization of plasma lipoproteins and apolipoproteins by targeted mass spectrometry, FPLC and differential ion mobility analysis indicated that CETP leads to smaller TRL remnant particles, increases triglyceride content in HDL, lower levels of plasma APOA1 and reduction in large HDL-P under diabetic conditions (n= 8-10, p < 0.05). Our results are consistent with the proposal that inhibition of CETP might be cardioprotective in the setting of T1D and highlight the close links between TRL and HDL metabolism in diabetes.