The Prolyl Hydroxylase Oxygen-sensing Pathway is Cytoprotective and Allows Maintenance of Mitochondrial Membrane Potential During Metabolic Inhibition

Overview

Journal Am J Physiol Cell Physiol

Publisher American Physiological Society

Specialties Cell Biology
Physiology

Date 2006 Oct 20

PMID 17050618

Citations 16

Authors

Vijayalakshmi Sridharan

Jason Guichard

Rachel M Bailey

Harinath Kasiganesan

Craig Beeson

Gary L Wright

Affiliations

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Abstract

The cellular oxygen sensor is a family of oxygen-dependent proline hydroxylase domain (PHD)-containing enzymes, whose reduction of activity initiate a hypoxic signal cascade. In these studies, prolyl hydroxylase inhibitors (PHIs) were used to activate the PHD-signaling pathway in cardiomyocytes. PHI-pretreatment led to the accumulation of glycogen and an increased maintenance of ATP levels in glucose-free medium containing cyanide. The addition of the glycolytic inhibitor 2-deoxy-d-glucose (2-DG) caused a decline of ATP levels that was indistinguishable between control and PHI-treated myocytes. Despite the comparable levels of ATP depletion, PHI-preconditioned myocytes remained significantly protected. As expected, mitochondrial membrane potential (DeltaPsi(mito)) collapses in control myocytes during cyanide and 2-DG treatment and it fails to completely recover upon washout. In contrast, DeltaPsi(mito) is partially maintained during metabolic inhibition and recovers completely on washout in PHI-preconditioned cells. Inclusion of rotenone, but not oligomycin, with cyanide and 2-DG was found to collapse DeltaPsi(mito) in PHI-pretreated myocytes. Thus, continued complex I activity was implicated in the maintenance of DeltaPsi(mito) in PHI-treated myocytes, whereas a role for the "reverse mode" operation of the F(1)F(0)-ATP synthase was ruled out. Further examination of mitochondrial function revealed that PHI treatment downregulated basal oxygen consumption to only approximately 15% that of controls. Oxygen consumption rates, although initially lower in PHI-preconditioned myocytes, recovered completely upon removal of metabolic poisons, while reaching only 22% of preinsult levels in control myocytes. We conclude that PHD oxygen-sensing mechanism directs multiple compensatory changes in the cardiomyocyte, which include a low-respiring mitochondrial phenotype that is remarkably protected against metabolic insult.

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