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Literature DB >> 12456489

Regulation of the brain's vascular responses to oxygen.

Ivan T Demchenko¹, Tim D Oury, James D Crapo, Claude A Piantadosi.

Abstract

The mechanism of oxygen-induced cerebral vasoconstriction has been sought for more than a century. Using genetically altered mice to enhance or disrupt extracellular superoxide dismutase (EC-SOD, SOD3), we tested the hypothesis that this enzyme plays a critical role in the physiological response to oxygen in the brain by regulating nitric oxide (NO*) availability. Cerebral blood flow responses in these genetically altered mice to changes in PO2 demonstrate that SOD3 regulates equilibrium between superoxide (*O2-) and NO*, thereby controlling vascular tone and reactivity in the brain. That SOD3 opposes inactivation of NO* is shown by absence of vasoconstriction in response to PO2 in the hyperbaric range in SOD3+/+ mice, whereas NO-dependent relaxation is attenuated in SOD3-/- mutants. Thus, EC-SOD promotes NO* vasodilation by scavenging *O2- while hyperoxia opposes NO* and promotes constriction by enhancing endogenous *O2- generation and decreasing basal vasodilator effects of NO*.

Entities: Chemical Disease Gene Species

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Year: 2002 PMID： 12456489 DOI： 10.1161/01.res.0000043500.03647.81

Source DB: PubMed Journal: Circ Res ISSN： 0009-7330 Impact factor: 17.367

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Cited

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