Dbh(-/-) mice are hypotensive, have altered circadian rhythms, and have abnormal responses to dieting and stress

doi:10.1152/ajpregu.00405.2003

Dbh(-/-) mice are hypotensive, have altered circadian rhythms, and have abnormal responses to dieting and stress

Steven J. Swoap,¹ David Weinshenker,² Richard D. Palmiter,² and Graham Garber¹

¹Department of Biology, Williams College, Williamstown, Massachusetts 01267; and ²Howard Hughes Medical Institute and Department of Biochemistry, University of Washington, Seattle, Washington 95195

Submitted 21 July 2003 ; accepted in final form 10 September 2003

We used mice deficient in dopamine ${beta}$ -hydroxylase [Dbh(-/-)] andtheir littermate controls [Dbh(+/-)] to examine the role ofepinephrine (Epi) and norepinephrine (NE) in the maintenanceof cardiovascular parameters during 7 days of caloric restrictionand acute exposure to environmental stress. Cardiovascular parametersof the mice were monitored using blood pressure radiotelemetersat an ambient temperature of 29°C. Under normal conditions,Dbh(-/-) mice had a low heart rate, were severely hypotensive,and displayed an attenuated circadian blood pressure rhythm.Upon 50% caloric restriction, Dbh(+/-) mice exhibited decreasesin heart rate and mean blood pressure. However, the blood pressuresof Dbh(-/-) mice did not fall significantly in response to caloricrestriction, and the bradycardia associated with caloric restrictionwas attenuated in these mice. In response to an open-field test,the blood pressure and heart rate of Dbh(+/-) mice increasedsubstantially and rapidly, whereas Dbh(-/-) mice had bluntedchanges in blood pressures and no change in heart rate. Thesedata suggest a primary role of Epi and NE in mediating the hypotensioninduced by dieting. Furthermore, Epi and NE play a smaller,but still significant, role in the bradycardia induced by caloricrestriction. In contrast, Epi and NE are required for the tachycardiain an open field but are not required for the increase in bloodpressure.

hypertension; blood pressure; food restriction; sympathetic nervous system; radiotelemetry; dopamine ${beta}$ -hydroxylase-deficient mice

Address for reprint requests and other correspondence: S. J. Swoap, Dept. of Biology, Williams College, Williamstown, MA 01267 (E-mail: sswoap{at}williams.edu).

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