Prolonged exposure to high dietary lipids is not associated with lipotoxicity in heart failure

Abstract

Previous studies have reported that elevated myocardial lipids in a model of mild-to-moderate heart failure increased mitochondrial function, but did not alter left ventricular function. Whether more prolonged exposure to high dietary lipids would promote a lipotoxic phenotype in mitochondrial and myocardial contractile function has not been determined. We tested the hypothesis that prolonged exposure to high dietary lipids, following coronary artery ligation, would preserve myocardial and mitochondrial function in heart failure. Rats underwent ligation or sham surgery and were fed normal (10% kcal fat) (SHAM, HF) or high fat diet (60% kcal saturated fat) (SHAM+FAT, HF+FAT) for sixteen weeks. Although high dietary fat was accompanied by myocardial tissue triglyceride accumulation (SHAM 1.47+/-0.14; SHAM+FAT 2.32+/-0.14; HF 1.34+/-0.14; HF+FAT 2.21+/-0.20 micromol/gww), fractional shortening was increased 16% in SHAM+FAT and 28% in HF+FAT compared to SHAM and HF, respectively. Despite increased medium-chain acyl-CoA dehydrogenase (MCAD) activity in interfibrillar mitochondria (IFM) of both SHAM+FAT and HF+FAT, dietary lipids also were associated with decreased state 3 respiration using palmitoylcarnitine (SHAM 369+/-14; SHAM+FAT 307+/-23; HF 354+/-13; HF+FAT 366+/-18 nAO min(-1) mg(-1)) in SHAM+FAT compared to SHAM and HF+FAT. State 3 respiration in IFM also was decreased in SHAM+FAT relative to SHAM using succinate and DHQ. In conclusion, high dietary lipids promoted myocardial lipid accumulation, but were not accompanied by alterations in myocardial contractile function typically associated with lipotoxicity. In normal animals, high dietary fat decreased mitochondrial respiration, but also increased MCAD activity. These studies support the concept that high fat feeding can modify multiple cellular pathways that differentially affect mitochondrial function under normal and pathological conditions.

Figure 1

Measurements of LV function. (A) peak LV +dP/dt and (B) peak LV −dP/dt obtained by LV cannulation as well as (C) fractional shortening and (D) ejection fraction obtained by echocardiography in SHAM, SHAM+FAT, HF, and HF+FAT sixteen weeks following coronary artery ligation surgery. Values are expressed as mean ± SEM. * p<0.05 vs SHAM; † p<0.05 vs SHAM+FAT; ‡ p<0.05 vs HF.

Figure 2

State 3 respiration in (A) SSM and (B) IFM using PC, OC, glutamate, succinate, and DHQ as respiratory substrates in SHAM, SHAM+FAT, HF, and HF+FAT sixteen weeks following coronary artery ligation surgery. Values are mean±SEM. *P<0.05 compared to SHAM; †P<0.05 compared to SHAM+FAT; ‡P<0.05 compared to HF. Abbreviations- SSM, subsarcolemmal mitochondria; IFM, interfibrillar mitochondria; PC, palmitoylcarnitine; OC, octanoylcarnitine; DHQ, durohydroquinone; nAO, nanoatoms oxygen.

Figure 3

State 4 respiration in (A) SSM and (B) IFM using PC, OC, glutamate, succinate, and DHQ as respiratory substrates in SHAM, SHAM+FAT, HF, and HF+FAT sixteen weeks following coronary artery ligation surgery. Values are mean±SEM. *P<0.05 compared to SHAM; †P<0.05 compared to SHAM+FAT; ‡P<0.05 compared to HF. Abbreviations- SSM, subsarcolemmal mitochondria; IFM, interfibrillar mitochondria; PC, palmitoylcarnitine; OC, octanoylcarnitine; DHQ, durohydroquinone; nAO, nanoatoms oxygen.