Hypertension, Vol 21, 415-419, Copyright © 1993 by American Heart Association
B Kennedy, H Elayan and MG Ziegler
Several drugs that block epinephrine synthesis by inhibiting
phenylethanolamine N-methyltransferase (PNMT) lower blood pressure in
hypertensive rats. We investigated the mechanism by which these drugs lower
blood pressure in rats made hypertensive with the glucocorticoid
dexamethasone. We performed adrenalectomy or sham operation on several rats
and then gave them either dexamethasone chronically or vehicle. The
dexamethasone-treated adrenalectomized rats also received either the
centrally acting PNMT inhibitor SKF 64139 chronically or an equal dose of
the primarily peripherally acting PNMT inhibitor SKF 29661. Both SKF 64139
and SKF 29661 reduced blood pressure by more than 25 mm Hg. SKF 64139 also
reduced PNMT activity in hypothalamus, medulla oblongata, skeletal muscle,
and cardiac atria and ventricles; SKF 29661 inhibited PNMT in muscle and
heart tissue by 40-75%, did not inhibit PNMT in hypothalamus, and inhibited
PNMT by only 29% in medulla oblongata. PNMT activity in peripheral tissues
was also more highly correlated with blood pressure than was PNMT activity
in the brain areas studied. Neither drug reduced tissue epinephrine levels,
but SKF 64139 elevated dopamine or norepinephrine levels or both in several
tissues. We conclude that the blood pressure-lowering action of PNMT-
inhibiting drugs in glucocorticoid hypertensive rats may be due to
inhibition of peripheral nonadrenal PNMT. We speculate that elevations in
nonadrenal PNMT may mediate glucocorticoid hypertension.
ARTICLES
Glucocorticoid hypertension and nonadrenal phenylethanolamine N- methyltransferase
Department of Medicine, University of California, San Diego, Medical Center 92103-8341.
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