Importance of Efferent Arteriolar Vascular Tone in Regulation of Proximal Tubule Fluid Reabsorption and Glomerulotubular Balance in the Rat

Overview

Journal J Clin Invest

Specialty General Medicine

Date 1980 May 1

PMID 7364945

Citations 23

Authors

I Ichikawa

B M Brenner

Affiliations

Soon will be listed here.

Abstract

Micropuncture study was performed in 21 mildly volume-expanded Munich-Wistar rats before and during partial aortic constriction to examine the effects of endogenous prostaglandins (PG) and angiotensin II (AII) on single nephron glomerular filtration rate (SNGFR) and absolute proximal reabsorption rate (APR). Animals received either vehicle (group 1), indomethacin (group 2), or indomethacin plus saralasin (group 3). Before aortic constriction, these inhibitors were without effect on values of SNGFR and APR. In group 1 rats, reduction in mean renal arterial perfusion pressure (RAP) to approximately 65 mm Hg resulted in marked and proportional declines in SNGFR and APR. With equivalent reduction in RAP in group 2 rats, however, SNGFR fell to a lesser extent and APR tended to increase slightly above preconstriction values. Indomethacin administration was therefore associated with disruption of glomerulotubular balance. In view of the roughly equivalent declines in afferent arteriolar resistance measured in groups 1 and 2, the magnitude of increase in efferent arteriolar resistance (R(E)) appeared to be of major importance in determining the observed presence or absence of glomerulotubular balance. Thus, the lesser fall in SNGFR in group 2 than in group 1 was a result of the higher value for glomerular capillary hydraulic pressure in group 2, a consequence of the higher value of R(E). The higher average value for APR during reduced RAP in group 2 than in group 1 is also attributable to this pronounced rise in R(E), the effect of which was to augment the net reabsorptive pressure both by favoring higher postglomerular oncotic pressure and lower downstream (peritubular capillary) hydraulic pressure. Since intrarenal release of AII is enhanced when RAP declines, and because AII is known to raise R(E) selectively, it is likely that endogenous AII brought about the marked increase in R(E) in group 2, which was readily demonstrable only in indomethacin-treated rats, presumably because endogenous PG synthesis was suppressed. In keeping with this conclusion, when the action of endogenous AII was inhibited by saralasin in group 3 rats, reduction in RAP failed to induce a rise in R(E), so that net filtration and reabsorption pressures again declined proportionally, as did SNGFR and APR. The present evidence therefore suggests that glomerulotubular balance is influenced to an important extent by the prevailing vasomotor tone of the efferent arteriole.

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