The oxygen-sensing prolyl hydroxylase domain proteins (PHDs) regulate cellular metabolism, but their role in neuronal metabolism during stroke is unknown. Here we report that PHD1 deficiency provides neuroprotection in a murine model of permanent brain ischemia. This was not due to an increased collateral vessel network. Instead, PHD1-/- neurons were protected against oxygen-nutrient deprivation by reprogramming glucose metabolism. Indeed, PHD1-/- neurons enhanced glucose flux through the oxidative pentose phosphate pathway by diverting glucose away from glycolysis. As a result, PHD1-/- neurons increased their redox buffering capacity to scavenge oxygen radicals in ischemia. Intracerebroventricular injection of PHD1-antisense oligonucleotides reduced the cerebral infarct size and neurological deficits following stroke. These data identify PHD1 as a regulator of neuronal metabolism and a potential therapeutic target in ischemic stroke.
Deletion or inhibition of the oxygen sensor PHD1 protects against ischemic stroke via reprogramming of neuronal metabolism / A. Quaegebeur, I. Segura, R. Schmieder, D. Verdegem, I. Decimo, F. Bifari, T. Dresselaers, G. Eelen, D. Ghosh, S.M. Davidson, S. Schoors, D. Broekaert, B. Cruys, K. Govaerts, C. De Legher, A. Bouché, L. Schoonjans, M.S. Ramer, G. Hung, G. Bossaert, D.W. Cleveland, U. Himmelreich, T. Voets, R. Lemmens, C..F. Bennett, W. Robberecht, K. De Bock, M. Dewerchin, B. Ghesquière, S. Fendt, P. Carmeliet. - In: CELL METABOLISM. - ISSN 1550-4131. - 23:2(2016 Feb), pp. 280-291. [10.1016/j.cmet.2015.12.007]
Deletion or inhibition of the oxygen sensor PHD1 protects against ischemic stroke via reprogramming of neuronal metabolism
F. Bifari;
2016
Abstract
The oxygen-sensing prolyl hydroxylase domain proteins (PHDs) regulate cellular metabolism, but their role in neuronal metabolism during stroke is unknown. Here we report that PHD1 deficiency provides neuroprotection in a murine model of permanent brain ischemia. This was not due to an increased collateral vessel network. Instead, PHD1-/- neurons were protected against oxygen-nutrient deprivation by reprogramming glucose metabolism. Indeed, PHD1-/- neurons enhanced glucose flux through the oxidative pentose phosphate pathway by diverting glucose away from glycolysis. As a result, PHD1-/- neurons increased their redox buffering capacity to scavenge oxygen radicals in ischemia. Intracerebroventricular injection of PHD1-antisense oligonucleotides reduced the cerebral infarct size and neurological deficits following stroke. These data identify PHD1 as a regulator of neuronal metabolism and a potential therapeutic target in ischemic stroke.
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