Carlos E. Giammattei scite author profile

The renin-angiotensin system is critically important to fetal cardiovascular function and organ development. The feedback regulation of renin secretion by ANG II develops early in gestation yet does not linearly progress from fetal life to adulthood. Renin secretion is elevated in late gestation compared with earlier or postnatal time periods, which suggests that some component of the negative feedback regulation of renin secretion is less sensitive in late gestation. We examined in fetal sheep the age-related consequence of chronic in vivo manipulation of ANG II on renal renin secretion measured in vitro. Immature (101-103 days of gestation) and mature (130-133 days of gestation) fetuses were treated for 72 h with enalaprilat, ANG II or vehicle. Content and basal and isoproterenol-stimulated secretion of prorenin (PR) and active renin (AR) from fetal kidney cortical slices were determined. Enalaprilat pretreatment in vivo increased renal renin content and basal and stimulated secretion of PR and AR in vitro even in immature animals. Immunohistochemical localization showed that enalaprilat treatment caused an age-related recruitment of renin-containing juxtaglomerular cells. Conversely, ANG II pretreatment decreased basal and stimulated PR and AR secretion from immature fetal kidneys, but only inhibited PR secretion from mature kidneys. It also caused an age-related decrease in the percentage of renin-containing juxtaglomerular cells. These results suggest that ANG II feedback modulates not only the synthesis and content of renin, but the sensitivity of the coupling between stimulus and secretion. A critical observation of our study is that the higher renal tissue concentrations of prorenin and active renin in late gestation may be a consequence of reduced sensitivity to ANG II feedback; this is consistent with the increased plasma concentrations of renin found in near-term mammals.

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Platelet-activating factor and solute transport processes in the kidney

Handa

Strandhoy

Giammattei

et al. 2003

American Journal of Physiology-Renal Physiology

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We examined the hemodynamic and tubular transport mechanisms by which platelet-activating factor (PAF) regulates salt and water excretion. In anesthetized, renally denervated male Wistar rats, with raised systemic blood pressure and renal arterial blood pressure maintained at normal levels, intrarenal PAF infusion at 2.5 ng. min(-1) x kg(-1) resulted in a small fall in systemic blood pressure (no change in renal arterial blood pressure) and an increase in renal blood flow and urinary water, sodium, and potassium excretion rates. The PAF-induced changes in cardiovascular and renal hemodynamic function were abolished and renal excretory function greatly attenuated by treating rats with a nitric oxide synthase inhibitor. To determine whether a tubular site of action was involved in the natriuretic effect of PAF, cortical proximal tubules were enzymatically dissociated from male Wistar rat kidneys, and oxygen consumption rates (Qo(2)) were used as an integrated index of transcellular sodium transport. PAF at 1 nM maximally inhibited Qo(2) in both untreated and nystatin-stimulated (sodium entry into renal cell is not rate limiting) proximal tubules by approximately 20%. Blockade of PAF receptors or Na(+)-K(+)-ATPase pump activity with BN-52021 or ouabain, respectively, abolished the effect of PAF on nystatin-stimulated proximal tubule Qo(2). Inhibition of nitric oxide synthase or guanylate cyclase systems did not alter PAF-mediated inhibition of nystatin-stimulated proximal tubule Qo(2), whereas phospholipase A(2) or cytochrome-P-450 monooxygenase inhibition resulted in a 40-60% reduction. These findings suggest that stimulation of PAF receptors on the proximal tubule decreases transcellular sodium transport by activating phospholipase A(2) and the cytochrome-P-450 monooxygenase pathways that lead to the inhibition of an ouabain-sensitive component of the basolateral Na(+)-K(+)-ATPase pump. Thus PAF can activate both an arachidonate pathway-mediated suppression of proximal tubule sodium transport and a nitric oxide pathway-mediated dilatory action on renal hemodynamics that likely contributes to the natriuresis and diuresis observed in vivo.

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Immunocytochemical localization of renin in the developing ovine fetus

Jc²,

Ms³

et al. 1996

Reprod. Fertil. Dev.

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The ontogeny of renin distribution in the outer cortical segments was studied by immunocytochemistry in two groups of ovine fetal kidneys; one set of fetal kidneys was obtained at 104-106 days (0.73 gestation, n = 6), and the other at 138-140 days (0.96 gestation, n = 6). Similar studies were performed in kidneys obtained from a lamb (2 weeks old) and from non-pregnant adult sheep, n = 4. Using rabbit anti-mouse renin antiserum that was proven to cross react with sheep renin and 0.033% 3',3'-diamino benzidine tetrachloride as a chromogen, immunoreactivity was found to be localized in the classical juxtaglomerular apparatus and the afferent arteriole in the immature fetuses, newborn lamb and adult sheep. In the mature fetuses a more extensive distribution was noted. Immunoreactivity was found in the afferent arteriole and the juxtaglomerular apparatus as well as other segments of the arterial vascular tree. These findings suggest that renal renin distribution in the lamb fetus is developmentally regulated. The results also correlate well with reports about renal cortical renin content and plasma renin activity at the stages studied. These observations further support the hypothesis that increased renal renin expression occurs in the fetus just prior to birth.

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