Self-Protection by Cardiac Myocytes Against Hypoxia and Hyperoxia

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Circulation Research. 1999;85:690-698

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(Circulation Research. 1999;85:690-698.)
© 1999 American Heart Association, Inc.

Cellular Biology

Self-Protection by Cardiac Myocytes Against Hypoxia and Hyperoxia

Saul Winegrad, Daniel Henrion, Lydie Rappaport, Jane Lise Samuel

From the Department of Physiology (S.W.), School of Medicine, University of Pennsylvania, Philadelphia, Pa, and INSERM Unit 127 (L.R., J.L.S.), IFR Circulation, Université D. Diderot, and INSERM Unit 141 (D.H.), Hôpital Lariboisière, Paris, France.

Correspondence to Saul Winegrad, Department of Physiology, School of Medicine, University of Pennsylvania, Philadelphia, PA 19104-6085. E-mail bsg{at}mail.med.upenn.edu

Abstract—Cardiac muscle must maintain a continuous balancebetween its energy supply and work performed. An important mechanisminvolved in achievement of this balance is cross talk via chemicalsignals between cardiac myocytes and the cardiac muscle vascularsystem . This has been demonstrated by incubating isolated cardiacmyocytes in different concentrations of oxygen and then assayingthe conditioned media for vasoactive substances on isolatedaortic rings and small-resistance arteries. With increasingoxygen concentrations above 6%, cardiac myocytes produce increasingamounts of angiotensin I, which is converted to angiotensinII by the blood vessel. The angiotensin II stimulates vascular endothelialcells to secrete endothelin and increase vascular tone. Below6% oxygen, cardiac myocytes secrete adenosine, which acts directlyon vascular smooth muscle to block the effect of ${alpha}$ -adrenergicagonists and reduce vascular tone. In an intact heart, the neteffect of these 2 regulatory systems would be the maintenanceof oxygen concentration within a narrow range at the cardiacmyocytes. By acting as oxygen sensors, cardiac myocytes modulatevascular tone according to the needs of the myocytes and reducepotential problems of hypoxia and extensive formation of reactiveoxygen species.

Key Words: adenosine • angiotensin • cardiac myocyte • endothelin • regulation of blood flow

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