Abstract
BackgroundTissue hypoxia is a key feature of several endemic hepatic diseases, including alcoholic and non-alcoholic fatty liver disease, and organ failure. Hypoxia imposes a severe metabolic challenge on the liver, potentially disrupting its capacity to carry out essential functions including fuel storage and the integration of lipid metabolism at the whole-body level. Mitochondrial respiratory function is understood to be critical in mediating the hepatic hypoxic response, yet the time-dependent nature of this response and the role of the respiratory chain in this remain unclear.ResultsHere, we report that hepatic respiratory capacity is enhanced following short-term exposure to hypoxia (2 days, 10% O2) and is associated with increased abundance of the respiratory chain supercomplex III2+IV and increased cardiolipin levels. Suppression of this enhanced respiratory capacity, achieved via mild inhibition of mitochondrial complex III, disrupted metabolic homeostasis. Hypoxic exposure for 2 days led to accumulation of plasma and hepatic long chain acyl-carnitines. This was observed alongside depletion of hepatic triacylglycerol species with total chain lengths of 39-53 carbons, containing palmitic, palmitoleic, stearic, and oleic acids, which are associated with de novo lipogenesis. The changes to hepatic respiratory capacity and lipid metabolism following 2 days hypoxic exposure were transient, becoming resolved after 14 days in line with systemic acclimation to hypoxia and elevated circulating haemoglobin concentrations.ConclusionsThe liver maintains metabolic homeostasis in response to shorter term hypoxic exposure through transient enhancement of respiratory chain capacity and alterations to lipid metabolism. These findings may have implications in understanding and treating hepatic pathologies associated with hypoxia.
Highlights
Tissue hypoxia is a key feature of several endemic hepatic diseases, including alcoholic and nonalcoholic fatty liver disease, and organ failure
It has been suggested that alterations in respiratory function play a key role in linking tissue hypoxia, oxidative stress and lipid metabolism in the liver, with the role of the mitochondria having been identified as a specific knowledge gap in current understanding of pathological hepatic hypoxia [3]
We demonstrate that maintenance of hepatic metabolic homeostasis during short-term hypoxic exposure is dependent on enhanced respiratory capacity, a response associated with mitochondrial respiratory supercomplex formation
Summary
Tissue hypoxia is a key feature of several endemic hepatic diseases, including alcoholic and nonalcoholic fatty liver disease, and organ failure. Hypoxia imposes a severe metabolic challenge on the liver, potentially disrupting its capacity to carry out essential functions including fuel storage and the integration of lipid metabolism at the whole-body level. The liver plays a key role in integrating fuel storage and systemic metabolism, in particular lipid metabolism and requires significant O2 to perform this role. This results in steep O2 gradients across liver lobules and a high susceptibility to hypoxia [2]. It has been suggested that alterations in respiratory function play a key role in linking tissue hypoxia, oxidative stress and lipid metabolism in the liver, with the role of the mitochondria having been identified as a specific knowledge gap in current understanding of pathological hepatic hypoxia [3]. The electron transfer system (ETS), and signalling via CIII, is integral to the metabolic response to hypoxic exposure
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