Brain-specific Knock-out of Hypoxia-inducible Factor-1alpha Reduces Rather Than Increases Hypoxic-ischemic Damage

Overview

Journal J Neurosci

Specialty Neurology

Date 2005 Apr 22

PMID 15843612

Citations 111

Authors

Rob Helton

Jiankun Cui

John R Scheel

Julie A Ellison

Chris Ames

Claire Gibson

Barbara Blouw

Ling Ouyang

Ioannis Dragatsis

Scott Zeitlin

Randall S Johnson

Stuart A Lipton

Carrolee Barlow

Affiliations

Soon will be listed here.

Abstract

Hypoxia-inducible factor-1alpha (HIF-1alpha) plays an essential role in cellular and systemic O(2) homeostasis by regulating the expression of genes important in glycolysis, erythropoiesis, angiogenesis, and catecholamine metabolism. It is also believed to be a key component of the cellular response to hypoxia and ischemia under pathophysiological conditions, such as stroke. To clarify the function of HIF-1alpha in the brain, we exposed adult mice with late-stage brain deletion of HIF-1alpha to hypoxic injuries. Contrary to expectations, the brains from the HIF-1alpha-deficient mice were protected from hypoxia-induced cell death. These surprising findings suggest that decreasing the level of HIF-1alpha can be neuroprotective. Gene chip expression analysis revealed that, contrary to expectations, the majority of hypoxia-dependent gene-expression changes were unaltered, whereas a specific downregulation of apoptotic genes was observed in the HIF-1alpha-deficient mice. Although the role of HIF-1alpha has been extensively characterized in vitro, in cancer models, and in chronic preconditioning paradigms, this is the first study to evaluate the role of HIF-1alpha in vivo in the brain in response to acute hypoxia/ischemia. Our data suggest, that in acute hypoxia, the neuroprotection found in the HIF-1alpha-deficient mice is mechanistically consistent with a predominant role of HIF-1alpha as proapoptotic and loss of function leads to neuroprotection. Furthermore, our data suggest that functional redundancy develops after excluding HIF-1alpha, leading to the preservation of gene expression regulating the majority of other previously characterized HIF-dependent genes.

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