15 research outputs found
Renal autacoids are involved in the stimulation of renin gene expression by low perfusion pressure
Renal autacoids are involved in the stimulation of renin gene expression by low perfusion pressure. This study aimed to examine the role of local autacoids for the regulation of renin secretion and renin gene expression by the renal perfusion pressure. To this end the effects of unilateral reduction of renal perfusion by 0.2 mm clips on plasma renin activity and on renal renin mRNA levels were examined in rats treated with the cyclooxygenase inhibitor meclofenamate (8 mg/kg body wt, twice a day), with the NO-synthase inhibitor nitro-L-arginine-methylester (L-NAME, 40 mg/kg body wt, twice a day) or with a combination of both. L-NAME alone decreased basal PRA values from 9.9 to 5.4 ng Ang I/hr times ml, while meclofenamate alone and the combination meclofenamate/L-NAME had no consistent effect on basal PRA. Unilateral renal artery clipping increased PRA values from 9.9 ng Ang I/hr times ml to 34, 27, and 16 ng Ang I/hr times ml in vehicle, meclofenamate, and L-NAME treated animals, respectively, but did not increase PRA in meclofenamate/L-NAME treated rats (9.5 ng Ang I/hr times ml). Renal renin mRNA levels in the clipped kidneys increased 4.8-, 2.6-, 2.5- and 1.8-fold in the clipped kidneys in vehicle, meclofenamate, L-NAME and meclofenamate/L-NAME injected animals, respectively. These findings indicate that both the inhibition of prostaglandin synthesis and of the formation of endothelium-derived relaxing factor (EDRF) attenuate the increase of renin gene expression and of renin secretion in response to acute unilateral renal hypoperfusion and that the effects of both maneuvers are additive. The data suggest that the stimulations of renin gene expression in response to low renal perfusion pressure require both intact prostaglandin and EDRF formation
Role of the macula densa in the control of renal renin gene expression in two-kidney/one-clip rats
This study was designed to examine whether macula densa function is involved in the changes of renal renin gene expression upon acute hypoperfusion of one kidney. To block macula densa function, rats with free access to salt and water were subcutaneously infused with furosemide (12 mg/day) for 6 days. Then, 4 days after the start of the infusion, the left renal arteries were clipped with 0.2-mm silver clips and renin mRNA levels in ipsilateral and contralateral kidneys, as well as plasma renin activities (PRA), were determined 48 h after clipping. In non-clipped animals furosemide increased PRA from 10 to 47 ng angiotensin I.h-1.ml-1 and raised renin mRNA levels in both kidneys 2.5-fold. In vehicle-infused animals, clipping of the left renal artery increased PRA to 37 ng angiotensin I.h-1.ml-1 and led to a 5-fold rise of renin mRNA levels in the ipsilateral kidneys and to a suppression to 20% of the control values in the contralateral kidneys. PRA values in clipped and furosemide-infused animals were 45 ng angiotensin I.h-1.ml-1. In these animals renin mRNA levels increased in the ipsilateral kidneys to similar absolute values as in vehicle-infused rats, whilst contralateral renin mRNA levels fell to about 25% of the respective controls. These findings indicate that the stimulations of renin gene expression by inhibition of macula densa salt transport and by renal artery clipping are not additive, suggesting that the macula densa mechanism may participate in the stimulation of renin gene expression upon hypoperfusion.(ABSTRACT TRUNCATED AT 250 WORDS
Role of calcium ions in the pressure control of renin secretion from the kidneys
In this study we examined the role of calcium ions in the control of renin release by the renal artery pressure. For this purpose renin secretion rates (RSR) were measured in isolated rat kidneys perfused at pressures of 140, 100, 80 and 40 mmHg (19, 13, 11, 5 kPa) with media containing either 1.5 mmol/l ("normal") or zero calcium concentrations (calcium-free perfusate with 0.5 mmol/l EGTA). At normal calcium the RSR was inversely related to the renal artery pressure, whereas calcium withdrawal resulted in an almost linear and proportional relationship between RSR and perfusion pressure. As a consequence, RSR at 140 mm Hg (19 kPa) with a calcium-free medium was similar to renin release at 40 mm Hg (5 kPa) with normal calcium. The nitric oxide (NO) donor sodium nitroprusside (1 mumol/l) stimulated RSR in a pressure-dependent fashion at a calcium concentration of 1.5 mmol/l. With a calcium-free perfusate, sodium nitroprusside did not restore the inverse pressure dependence of RSR seen with normal calcium but almost doubled the RSR across the whole pressure range. Whilst RSR was significantly reduced by angiotensin II (1 nmol/l) in the range between 40 mmHg and 140 mmHg (5-19 kPa) with normal calcium, withdrawal of extracellular calcium ions practically abolished the inhibitory action of angiotensin II. Since angiotensin II attenuated RSR especially at low renal perfusion pressure, our results indicate that renin release in this pressure range is still inhibitable by calcium mobilization in renal juxtaglomerular cells. Thus, the enhancement of renin secretion at lower pressures cannot be explained by a decreased sensitivity of renin release towards calcium ions.(ABSTRACT TRUNCATED AT 250 WORDS
Endothelium derived relaxing factor is involved in the pressure control of renin gene expression in the kidney
To study the influence of endothelium derived relaxing factor/nitric oxide (EDNO) on renin gene expression, the effects of a 2-day treatment with the NO-synthase inhibitor nitro-L-arginine-methylester (L-NAME, 40 mg/kg twice a day) on plasma renin activity (PRA) and renal and adrenal renin m-RNA levels were examined in conscious rats with and without unilateral renal clips (0.2 mm). In sham-clipped animals L-NAME led to a decrease of PRA from 7.5 to 2.5 ng angiotensin (ANGI).h-1.ml-1 and to a 35% decrease of renal renin m-RNA levels. Unilateral renal artery clipping increased PRA to 35 and to 13 ng ANGI.h-1.ml-1 in vehicle and in L-NAME-treated rats, respectively. In the clipped kidneys renin m-RNA levels increased to 450% of control values in vehicle-treated animals and to 220% of control values in L-NAME-treated animals. In the contralaterals as opposed to clipped kidneys, renin m-RNA levels decreased to 16% and 50% of the control values in vehicle- and in L-NAME-treated animals, respectively. In the adrenal glands renin m-RNA levels were not significantly changed either by clipping of one renal artery or by treatment of animals with L-NAME. The NO-donor sodium nitroprusside (100 microM) was found to increase renin secretion and renin m-RNA levels in primary cultures of renal juxtaglomerular cells. These findings suggest that EDNO is involved in the control of the renin gene by the renal perfusion pressure
Interrelation between renin mRNA levels, renin secretion, and blood pressure in two-kidney, one clip rats
To examine the interrelation between renin mRNA levels, renin secretion, and blood pressure in rats, we clipped the left renal arteries of rats and measured renin mRNA levels in both kidneys, plasma renin activity, and blood pressure. One and 2 days after clipping, renin mRNA levels increased 3-fold and 4.3-fold in the stenosed kidney and were suppressed to 52% and 26% of controls in the intact kidneys; plasma renin activity increased from 8 to 16.5 and to 30.5 ng angiotensin I.h-1.mL-1 and systolic blood pressure rose from 114 to 123 and to 137 mm Hg. We found a strong correlation (P < .001) between plasma renin activity and renin mRNA levels in the clipped kidneys. We also found significant correlations (P < .05) between mRNA levels in the clipped and intact kidneys and between plasma renin activity and blood pressure for the individual animals. Treatment of normal rats with the converting enzyme inhibitor ramipril (5 mg/kg twice a day) for 2 days increased renin mRNA levels in both kidneys fourfold. In animals with unilateral clips, additional treatment with ramipril increased renin mRNA levels 6.4-fold in the stenosed and 3.3-fold in the intact kidneys. These findings suggest that endogenous angiotensin II exerts an inhibitory effect on renin mRNA expression in normal kidneys, clipped kidneys, and their contralaterals. Suppression of the renin gene in contralateral kidneys seems not to be directly mediated by the rise of plasma renin activity or by the rise of blood pressure in two-kidney, one clip rats