The absence of endogenous lipid oxidation in early stage heart failure exposes limits in lipid storage and turnover

JM O'Donnell, AD Fields, N Sorokina… - Journal of molecular and …, 2008 - Elsevier
JM O'Donnell, AD Fields, N Sorokina, ED Lewandowski
Journal of molecular and cellular cardiology, 2008Elsevier
Intramyocardial lipid handling in pressure-overload-induced heart failure remains poorly
understood, and the balance between endogenous and exogenous lipid utilization for
mitochondrial ATP production is essentially unknown. In this study, we determined the
contribution of endogenous triacylglycerols (TAG) to mitochondrial oxidation relative to that
of exogenous palmitate, glucose, and endogenous glycogen in the failing, pressure-
overloaded rat heart. TAG content and turnover were also assessed to determine if lipid …
Intramyocardial lipid handling in pressure-overload-induced heart failure remains poorly understood, and the balance between endogenous and exogenous lipid utilization for mitochondrial ATP production is essentially unknown. In this study, we determined the contribution of endogenous triacylglycerols (TAG) to mitochondrial oxidation relative to that of exogenous palmitate, glucose, and endogenous glycogen in the failing, pressure-overloaded rat heart. TAG content and turnover were also assessed to determine if lipid availability and mobility were altered. Dynamic-mode 13C NMR was performed in intact hearts from aortic banded and sham operated Spraque-Dawley rats perfused with 13C-labeled palmitate or glucose to assess TAG turnover rate and palmitate oxidation rate. The fractional contributions from palmitate, glucose, glycogen, and TAG to mitochondrial ATP production were determined from NMR analysis of heart extracts. TAG oxidation was not evident in HF, whereas the contribution of TAG to oxidative ATP production was significant in shams. TAG content was 39% lower in HF compared to sham, and TAG turnover rate was 60% lower in HF. During adrenergic challenge, TAG sources were again not oxidized in the HF group. In early cardiac failure, endogenous TAG oxidation was reduced in parallel to increased carbohydrate oxidation, with no change in exogenous palmitate oxidation. This finding was consistent with reduced TAG storage and mobilization. These data further elucidate the role of intermediary and lipid metabolism in the progression of LVH to failure, and contribute to emerging evidence linking the disruption of myocardial substrate use to cardiomyopathies.
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