Abstract 044: Stimulation Of Intrarenal Angiotensinogen Expression And The Development Of Hypertension And Kidney Injury In Angiotensin II-infused Hepatic Angiotensinogen Knockout Mice

Regulation of systemic and local angiotensinogen (AGT) levels is a key determinant of tissue angiotensin II (Ang II) levels and inappropriate AGT augmentation promotes the development of hypertension and tissue injury. Kidney and urinary AGT levels are increased in Ang II-mediated hypertension. Recent studies have demonstrated that circulating hepatocyte-derived AGT (hAGT) enters kidneys sustaining kidney and urinary AGT levels. However, roles of hAGT in blood pressure elevation and kidney injury in Ang II-mediated hypertension have not been delineated. This study tested if hAGT contributes to the development of the pathophysiological events in Ang II-infused mice. A low dose of Ang II (400 ng/kg/min) was infused to male wild type (WT) and hAGT gene knockout (KO) mice (N=9 and 13) for 4 weeks. The control group in each genotype received vehicle (Veh) infusion (N=5 and 6). Western blot confirmed non-detectable levels of hAGT in KO mice. hAGT KO markedly decreased plasma AGT levels (WT+Veh:12.2±0.6 vs. hAGT KO+Veh: 0.8±0.1 μg/ml). Ang II infusion did not elevate plasma AGT levels in either WT and hAGT KO mice. Although hAGT KO mice exhibited a lower baseline of systolic blood pressure (SBP) than WT mice, Ang II-mediated increases in SBP was not attenuated in hAGT KO mice (ΔSBP in WT+Ang II: 30.1±4.4 vs. hAGT KO+Ang II: 26.0±4.2 mmHg). Kidney AGT mRNA levels were increased by Ang II infusion to the same extent in both WT and hAGT mice (WT+Ang II: 1.30±0.04 vs. hAGT KO+Ang II: 1.34±0.06, ratio to control). Likewise, Ang II infusion increased IL-6 mRNA to the same magnitude in both WT and hAGT KO mice. Urinary AGT was sustained in hAGT KO+Veh mice (66±9%) compared to WT+Veh mice. Ang II infusion did not alter urinary AGT levels in both groups. Glomerular mesangial expansion and fibrosis by Ang II infusion were not observed. Ang II infusion developed tubulointerstitial fibrosis in renal cortex and medulla. hAGT KO prevented the fibrosis only in the medulla. These outcomes demonstrate that elevation of SBP, augmentation of intrarenal AGT and IL-6 expression, and the development of renal cortical fibrosis in Ang II-mediated hypertension do not require hAGT. In contrast, hAGT contributes to renal medullary fibrosis which may be due to the lower absolute levels of blood pressure.

Abstract 015: Immunosuppression Attenuates Intrarenal Angiotensinogen Augmentation in Angiotensin II Dependent Hypertension

Augmented intrarenal angiotensinogen (AGT) is a critical contributor to activation of intrarenal renin-angiotensin system (RAS) leading to the development of hypertension and associated kidney injury. It has been shown that treatment with mycophenolate mofetil (MMF), an immunosuppressive drug, mitigates the increased intrarenal angiotensin (Ang) II levels and blood pressure in hypertensive animal models, suggesting that an activated immune system mediates intrarenal RAS activation and consequent hypertension. Associated macrophage (MΦ) infiltration augments pro-inflammatory cytokine levels including interleukin-6 (IL-6), which plays a crucial role in augmentation of AGT expression in cultured renal proximal tubular cells. Accordingly, this study was performed to establish pathophysiological relevance for the effects of stimulated MΦ and IL-6 on intrarenal AGT augmentation in Ang II-dependent hypertension. Ang II (80 ng/min) was infused with/without daily MMF administration (50 ng/kg) to Sprague-Dawley rats for 2 weeks. Mean arterial pressure (MAP) in Ang II infused rats was slightly higher (169.7±6.1 mmHg) than MAP in Ang II+MMF group (154.7±2.0 mmHg) which was not statistically different than in control group. The augmentation of urinary AGT and urinary protein by Ang II infusion was attenuated by MMF treatment (AGT, control: 89.3±25.2, Ang II: 1,194±305.1, and Ang II+MMF: 389±192.0 ng/day). Importantly, the augmentation of urinary AGT by Ang II infusion was observed before the onset of proteinuria. Urinary 8-isoprostane levels were not altered by Ang II and/or MMF during the 2-week treatments. MMF treatment suppressed Ang II-induced renal MΦ infiltration and IL-6 elevation (IL-6 mRNA, Ang II: 32.4±7.5 and Ang II+MMF: 3.6±1.7, ratio to control). qRT-PCR, western blot and immunohistochemistry revealed elevated intrarenal AGT mRNA and protein levels in Ang II infused rats which were normalized by the MMF treatment (AGT mRNA, Ang II: 2.5±0.2 and Ang II+MMF: 1.5±0.1, ratio to control). These results indicate that stimulated IL-6 production in infiltrated MΦ contributes to intrarenal AGT augmentation in early stages of Ang II-dependent hypertension, which contributes to the development of kidney injury.

Abstract 564: Differential Expression and Regulation of Angiotensinogen in Renal Proximal Tubule Cells From S1, S2 and S3 Segments

In angiotensin II (Ang II)-dependent hypertension, intrarenal angiotensinogen (AGT) augmentation induced by Ang II and associated pathogenic factors including interleukin 6 (IL-6) cause further elevation of intratubular Ang II production, leading to the progression of hypertension and kidney injury. Recent studies have suggested that renal proximal straight tubules (S3 segment) are the main source of intrarenal AGT and that S1 and S2 segments do not express AGT mRNA under normal conditions. However, AGT expression and its regulation by Ang II and/or IL-6 in each proximal tubule segment have not been demonstrated an in vitro setting. The availability of specific cell lines derived from mouse S1, S2 and S3 segments provided an opportunity to decisively determine each segments’ capability to express AGT and respond to stimuli. Thus, this study was performed to determine AGT expression and its response to stimulation with Ang II and IL-6 in S1, S2 and S3 cell line. Basal AGT mRNA and protein levels were detected by RT-PCR and western blot analysis. Basal levels of Ang II type 1 receptor (AT1R) and STAT3, which is a transcription factor in IL-6 signaling pathway, were also measured. In addition, the cells were incubated with 100 nM Ang II and/or 400 nM IL-6 for 24 h. Basal AGT levels in S1 and S3 cells were lower than in mouse whole kidney (0.09-fold and 0.33-fold compared with mouse whole kidney). S2 cells exhibited the highest basal AGT levels (4.15-fold) among these cells. In S1 cells, AGT expression was stimulated by IL-6 (1.89 ± 0.32, ratio to control) and co-stimulation with Ang II and IL-6 (1.85 ± 0.28) although Ang II alone did not alter AGT levels. In S2 cells, only the co-stimulation increased AGT expression (1.35 ± 0.01). No changes were observed by similar treatments in S3 cells. Basal AT1R levels were lower in S3 than in S1 and S2 cells (0.97 ± 0.09 in S2, 0.32 ± 0.07 in S3, ratio to S1). S1 cells showed the highest basal levels of STAT3. Basal STAT3 levels in S3 cells were lower than that in S1 and S2 cells. These results indicate that S2 cells are main source of intrarenal AGT which can be augmented by Ang II and IL-6 during the development of Ang II-dependent hypertension. Furthermore, low basal levels of AT1R and STAT3 in S3 cells explain why these cells do not respond to Ang II and IL-6.

Abstract 565: Angiotensin Ii Type 1 Receptor Activation is Required for Angiotensin Ii and Interleukin 6-induced Augmentation of Angiotensinogen Expression in Mouse Renal Proximal Tubular Cells

In angiotensin II (AngII) dependent hypertension, an inappropriate elevation of intrarenal Ang II leads to the progression of hypertension and kidney injury. Intrarenal angiotensinogen (AGT), produced mainly by renal proximal tubular cells (PTC), is a crucial factor in regulation of intratubular Ang II. Increases in intrarenal AGT are associated with increases in intrarenal immune cells and interleukin 6 (IL-6) levels which contribute to Ang II-dependent AGT augmentation. These results suggest that Ang II and IL-6 synergize to increase AGT levels during progression of Ang II-dependent hypertension. However, the interactions among Ang II, Ang II type 1 receptors (AT1R) and IL-6 on AGT expression and the mechanisms have not been delineated. In this study, mouse PTC (WT-PTC) and AT1aR knockout strains (AT1aRKO-PTC) were used to test the existence of this synergism between Ang II and IL-6. Basal AGT mRNA expression levels in PTC were determined and compared with that in mouse mesangial cells which is another established AGT-expressing kidney cells. AGT mRNA expression levels were measured by real-time RT-PCR and normalized based on GAPDH levels. WT-PTC had 21.1-fold (± 2.0) higher basal AGT mRNA levels than mesangial cells, indicating markedly high AGT production by the PTC. Further, WT-PTC and AT1aRKO-PTC were incubated with 100 nM Ang II and/or 400 nM IL-6 for 24 h. Stimulation with either Ang II or IL-6 alone did not significantly alter AGT mRNA expression in both WT-PTC and AT1RaKO-PTC. Co-stimulation with Ang II and IL-6 increased AGT mRNA levels (1.59 ± 0.04, ratio to control) in WT-, but not AT1aRKO-PTC. To test for involvement of the NF-κB signaling pathway in the synergism between Ang II and IL-6, activation of NF-κB as an AT1R signaling pathway was evaluated by western blot analysis. Furthermore, WT-PCT were treated with an NF-κB inhibitor during the co-stimulation. In WT-PTC, IκB levels were decreased by the co-stimulation (0.61 ± 0.04, ratio to control) indicating NF-κB activation. Ten μM Parthenolide, an NF-κB inhibitor, attenuated the AGT mRNA increase induced by the co-stimulation. These results suggest that simultaneous AT1R activation acts synergistically with IL-6 to increase AGT expression in mouse PTC and that the signaling pathway involves NF-κB.

Abstract 401: Prostaglandin E2 Stimulates Renin Synthesis in Mouse Collecting Duct M-1 Cells via Ep1 Receptor Through Pkc/camp/creb Pathway

Prostaglandin E2 (PGE2) plays a major role in regulating renin expression and release by the renal juxtaglomerular (JG) cells. Recently it has been demonstrated that PGE2-dependent upregulation of renin in JG cells is mediated by activation of E prostaoind receptor type 4 (EP4) via cAMP accumulation. Renin is also produced by the principal cells of the collecting ducts (CD) and is upregulated during angiotensin II-dependent hypertension. However, the effects of PGE2 on CD renin remain unknown. Four types of receptors have been described in rat and mouse CD, EP1, EP3 and EP4. Here, we tested the hypothesis that renin is upregulated by PGE2 via activation of EP receptors in mouse CD M-1 cells. By immunostaining we confirmed the presence of EP1, EP3 and EP4 receptors, while EP2 was not detected. A dose response treatment with PGE2 showed increased levels of renin mRNA and protein with a maximum response at 1 μmol/L (mRNA: 19.3 ± 3.0; P<0.05; protein: 3.01 ± 0.08 fold change; P<0.05). To assess which EP receptor is involved in the renin upregulation we used specific EP receptor antagonists: ONO-8711 (EP1; 10 nmol/L), L-798106 (EP3; 10 μmol/L) and AH 23848 (EP4; 10 μmol/L). EP1 antagonist suppressed the PGE2-mediated upregulation of collecting duct renin mRNA and protein (mRNA: 1.0 ± 0.2; protein: 0.98 ± 0.13 fold change; P=NS), while EP4 antagonist only partially decreased it (mRNA: 11.2 ± 2.8; P<0.05; protein: 2.81 ± 0.07 fold change; P<0.05). EP3 antagonist exacerbated the PGE2 mediated-upregulation of renin (mRNA: 50.3 ± 6.0; P<0.05; protein: 3.56 ± 0.08; fold change; P<0.05). Because EP1 is a Gq linked receptor that activates PKC, we further assessed the effects of PKC inhibition using calphostin C and a PKCα dominant negative (DN) on renin expression. Calphostin C and PKCα-DN blunted the PGE2-induced renin upregulation. Importantly, the increases in cAMP levels and phosphorylation of the cAMP response element-binding transcription factor (CREB) mediated by PGE2 were also prevented by both treatments. The results indicate that in mouse CD cells, EP1 receptor activation upregulates renin synthesis via PKC/cAMP/CREB, suggesting that the presence of PGE2 in renal medullary tissues may contribute to the stimulation of collecting duct renin.

Transgenic mice expressing an intracellular fluorescent fusion of angiotensin II demonstrate renal thrombotic microangiopathy and elevated blood pressure

We have generated transgenic mice that express angiotensin II (ANG II) fused downstream of enhanced cyan fluorescent protein, expression of which is regulated by the mouse metallothionein promoter. The fusion protein, which lacks a secretory signal, is retained intracellularly. In the present study, RT-PCR, immunoblot analyses, whole-animal fluorescent imaging, and fluorescent microscopy of murine embryonic fibroblasts confirm expression of the fusion protein in vivo and in vitro. The transgene is expressed in all tissues tested (including brain, heart, kidney, liver, lung, and testes), and radioimmunoassay of plasma samples obtained from transgenic mice indicate no increase in circulating ANG II over wild-type levels, consistent with intracellular retention of the transgene product. Kidneys from transgenic and corresponding wild-type littermates were histologically evaluated, and abnormalities in transgenic mice consistent with thrombotic microangiopathy were observed; microthrombosis was frequently observed within the glomerular capillaries and small vessels. In addition, systolic and diastolic blood pressures, measured by telemetry (n = 8 for each group), were significantly higher in transgenic mice compared with wild-type littermates. Blood pressure of line A male transgenic mice was 125 + or - 1.7 over 97 + or - 1.6 compared with 109 + or - 1.7 over 83 + or - 1.4 mmHg in wild-type littermates (systolic over diastolic). In summary, overexpression of an intracellular fluorescent fusion protein of ANG II correlates with elevated blood pressure and kidney pathology. This transgenic model may be useful to further explore the intracellular renin-angiotensin system and its implication in abnormal kidney function and hypertension.

A true champion of Hungarian kidney research and nephrology education--tribute to László Rosivall

This article pays tribute to the tremendous achievements of Dr. László Rosivall in renal (patho)physiology research and nephrology education in Hungary on the occasion of his 60th birthday. For the past several decades Dr. Rosivall has been a charismatic leader of academic institutions, national and international societies, foundations in physiology, nephrology and hypertension, but the most important of his many contributions, is his role as a scientist. He earned his MD with Summa cum Laude at Semmelweis University (1973) and was invited immediately after that to join the laboratory of Hársing. He studied the distribution of intra-renal blood flow employing then state-of-the-art methods as well as developed his own technique at Semmelweis University and at the University of Bergen with Knut Aukland. This led to his PhD thesis and degree in 1980. An important determinant of his early basic scientific training and development was his postdoctoral research fellowship and later many visiting professorships in the Nephrology Research and Training Center (NRTC) at the University of Alabama at Birmingham, Birmingham, AL, USA between 1981 and 1983. Actually, this research fellowship not only impacted his own future career, but it also cleared the path for many other young Hungarian scientists who later trained with Dr. Rosivall and then at UAB. The early 1980s were the years of significant scientific discoveries and the NRTC team at UAB made important contributions by their studies on renal and glomerular hemodynamics, the renin-angiotensin system (12, 19, 22) and by the development of classic experimental techniques like renal micropuncture, microperfusion, and the juxtamedullary nephron preparation (3) that are still being used worldwide. When Dr. Rosivall joined UAB in the 1980s, the team at the NRTC included Drs. Navar, Bell, Inscho, Carmines, Casellas, and Oparil, among many others, who share their fond memories of working with Dr. Rosivall in this article.

Intrarenal angiotensin II and angiotensinogen augmentation in chronic angiotensin II-infused mice

The objectives of this study were to determine the effects of chronic angiotensin II (ANG II) infusions on ANG II content and angiotensinogen expression in the mouse kidney and the role of the angiotensin II type 1 receptor (AT(1)R) in mediating these changes. C57BL/6J male mice were subjected to ANG II infusions at doses of 400 or 1,000 ng.kg(-1).min(-1) either alone or with an AT(1)R blocker (olmesartan; 3 mg.kg(-1).day(-1)) for 12 days. Systolic and mean arterial pressures were determined by tail-cuff plethysmography and radiotelemetry. On day 13, blood and kidneys were collected for ANG II determinations by radioimmunoanalysis and intrarenal angiotensinogen expression studies by quantitative RT-PCR, Western blotting, and immunohistochemistry. ANG II infusions at the low dose elicited progressive increases in systolic blood pressure (135 +/- 2.5 mmHg). In contrast, the high dose induced a rapid increase (152 +/- 2.5, P < 0.05 vs. controls, 109 +/- 2.8). Renal ANG II content was increased by ANG II infusions at the low dose (1,203 +/- 253 fmol/g) and the high dose (1,258 +/- 173) vs. controls (499 +/- 40, P < 0.05). Kidney angiotensinogen mRNA and protein were increased only by the low dose to 1.13 +/- 0.02 and 1.26 +/- 0.10, respectively, over controls (1.00, P < 0.05). These effects were not observed in mice infused at the high dose and those receiving olmesartan. The results indicate that chronic ANG II infusions augment mouse intrarenal ANG II content with AT(1)R-dependent uptake occurring at both doses, but only the low dose of infusion, which elicited a slow progressive response, causes an AT(1)R-dependent increase in intrarenal angiotensinogen expression.

Metabolic inhibition-induced transient Ca2+ increase depends on mitochondria in a human proximal renal cell line

During ischemia or hypoxia an increase in intracellular cytosolic Ca(2+) induces deleterious events but is also implicated in signaling processes triggered in such conditions. In MDCK cells (distal tubular origin), it was shown that mitochondria confer protection during metabolic inhibition (MI), by buffering the Ca(2+) overload via mitochondrial Na(+)-Ca(2+) exchanger (NCX). To further assess this process in cells of human origin, human cortical renal epithelial cells (proximal tubular origin) were subjected to MI and changes in cytosolic Ca(2+) ([Ca(2+)](i)), Na(+), and ATP concentrations were monitored. MI was accomplished with both antimycin A and 2-deoxyglucose and induced a 3.5-fold increase in [Ca(2+)](i), reaching 136.5 +/- 15.8 nM in the first 3.45 min. Subsequently [Ca(2+)](i) dropped and stabilized to 62.7 +/- 7.3 nM by 30 min. The first phase of the transient increase was La(3+) sensitive, not influenced by diltiazem, and abolished when mitochondria were deenergized with the protonophore carbonylcyanide p-trifluoromethoxyphenylhydrazone. The subsequent recovery phase was impaired in a Na(+)-free medium and weakened when the mitochondrial NCX was blocked with 7-chloro-5-(2-chlorophenyl)-1,5-dihydro-4,1-benzothiazepin-2(3H)-one (CGP-37157). Thus Ca(2+) entry is likely mediated by store-operated Ca(2+) channels and depends on energized mitochondria, whereas [Ca(2+)](i) recovery relied partially on the activity of mitochondrial NCX. These results indicate a possible mitochondrial-mediated signaling process triggered by MI, support the hypothesis that mitochondrial NCX has an important role in the Ca(2+) clearance, and overall suggest that mitochondria play a preponderant role in the regulation of responses to MI in human renal epithelial cells.

Induction of heme oxygenase-1 in renovascular hypertension is associated with inhibition of apoptosis

The goal of this study was to characterize the impact of induction or inhibition of the heme-HO system on renal apoptosis in clipped and non-clipped kidneys from 2K1C hypertensive rats. Male Sprague-Dawley rats had a 0.25 mm silver clip placed around the left renal artery. Four groups of rats were studied: sham operated animals, 2K1C control rats, 2K1C rats received weekly injections of CoPP (5 mg/100 g body wt, administered subcutaneously), and 2K1C rats pretreated with SnMP (5 mg/ 100g body wt, administered intraperitoneally three times a week). The animals were sacrificed three weeks after surgery. We measured systolic blood pressure, plasma renin activity, non-clipped and clipped kidney HO-1 and HO-2 protein expression, HO activity, heme content, nitrotyrosine levels, and activation of selected pro- and anti-apoptotic proteins. Systolic blood pressure and plasma renin activity were significantly higher in 2K1C rats compared to sham rats. Compared to kidneys from sham animals, clipped kidneys from 2K1C rats showed a significant increase in HO-1 expression with increases in HO activity (26%), heme content (47%) and nitrotyrosine levels (49%), accompanied by an increase in caspase-3 and caspase-9 activity. In contrast, non-clipped kidneys from 2K1C rats showed no differences in HO-1 expression, HO activity, heme content, nitrotyrosine levels and caspase activity compared to sham rats. In clipped kidneys from 2K1C rats, inhibition of HO activity by SnMP augmented caspase-3 and caspase-9 activity and decreased expression of the anti-apoptotic Bcl-2 protein, while induction of HO-1 with CoPP strongly inhibited the activity of both caspases and increased the induction of Bcl-2 and Bcl-xl proteins. These findings demonstrate that the clipped kidneys responded to decreased renal perfusion pressure and increased oxidative stress by activation of the heme-HO system, which exerts antiapoptotic action via mechanisms involving decreased caspase-3 and caspase-9 activity, and increased expression of antiapoptotic molecules.

Intrarenal renin-angiotensin system and counteracting protective mechanisms in angiotensin II-dependent hypertension

It is now well accepted that alterations in kidney function, due either to primary renal disease or to inappropriate hormonal influences on the kidney, are a cardinal characteristic in all forms of hypertension, and lead to a reduced ability of the kidneys to excrete sodium and the consequent development of elevated arterial pressures. However, it is also apparent that many extrarenal factors are important contributors to altered kidney function and hypertension. Central to many hypertensinogenic processes is the inappropriate activation of the renin-angiotensin system (RAS) and its downstream consequences by various pathophysiologic mechanisms. There may also be derangements in arachidonic acid metabolites, endothelium derived factors such as nitric oxide and carbon monoxide, and various paracrine and neural systems that normally interact with or provide a counteracting balance to the actions of the RAS. Thus, when the capacity of the kidneys to maintain sodium balance and extracellular fluid volume within appropriate ranges is compromised, increases in arterial pressure become necessary to re-establish normal balance.

Megalin binds and internalizes angiotensin-(1-7)

Megalin is a multiligand receptor heavily involved in protein endocytosis. We recently demonstrated that megalin binds and mediates internalization of ANG II. Although there is a strong structural resemblance between ANG II and ANG-(1-7), their physiological actions and their affinity for the angiotensin type 1 receptor (AT(1)R) are dissimilar. Therefore, the hypothesis of the present work was to test whether megalin binds and internalizes ANG-(1-7). The uptake of ANG-(1-7) was determined by exposure of confluent monolayers of BN/MSV cells (a model representative of the yolk sac epithelium) to fluorescently labeled ANG-(1-7) (100 nM) and measurement of the amount of cell-associated fluorescence after 4 h by flow cytometry. Anti-megalin antisera and an AT(1)R blocker (olmesartan) were used to interfere with uptake via megalin and the AT(1)R, respectively. ANG-(1-7) uptake was prevented by anti-megalin antisera (63%) to a higher degree than olmesartan (13%) (P < 0.001). In analysis by flow cytometry of binding experiments performed in brush-border membrane vesicles isolated from kidneys of CD-1 mice, anti-megalin antisera interfered with ANG-(1-7) binding more strongly than olmesartan (P < 0.05 against positive control). Interactions of megalin with ANG-(1-7) at a molecular level were studied by surface plasmon resonance, demonstrating that ANG-(1-7) binds megalin dose and time dependently and with an affinity similar to ANG II. These results show that the scavenger receptor megalin binds and internalizes ANG-(1-7).

Megalin binds and internalizes angiotensin II

Megalin is an abundant membrane protein heavily involved in receptor-mediated endocytosis. The major functions of megalin in vivo remain incompletely defined as megalin typically faces specialized milieus such as glomerular filtrate, airways, epididymal fluid, thyroid colloid, and yolk sac fluid, which lack many of its known ligands. In the course of studies on ANG II internalization, we were surprised when only part of the uptake of labeled ANG II into immortalized yolk sac cells (BN-16 cells) was blocked by specific peptide inhibitors and direct competitors of the angiotensin type 1 receptor. This led us to test if megalin was a receptor for ANG II. Four lines of direct evidence demonstrate that megalin and, to a lesser extent, its chaperone protein cubilin are receptors for ANG II. First, in BN-16 cells anti-megalin and anti-cubilin antisera interfere with ANG II uptake. Second, also in BN-16 cells, pure ANG II competes for uptake of a known megalin ligand. Third, in proximal tubule cell brush-border membrane vesicles extracted from mice, anti-megalin antisera interfere with ANG II binding. Fourth, purified megalin binds ANG II directly in surface plasmon resonance experiments. The finding that megalin is a receptor for ANG II suggests a major new function for the megalin pathway in vivo. These results also indicate that ANG II internalization in some tissues is megalin dependent and that megalin may play a role in regulating proximal tubule ANG II levels.

Genetic disruption of atrial natriuretic peptide receptor-A alters renin and angiotensin II levels

We have studied cardiovascular and renal phenotypes in Npr1 (genetic determinant of natriuretic peptide receptor-A; NPRA) gene-disrupted mutant mouse model. The baseline systolic arterial pressure (SAP) in 0-copy mutant (-/-) mice (143 +/- 2 mmHg) was significantly higher than in 2-copy wild-type (+/+) animals (104 +/- 2 mmHg); however, the SAP in 1-copy heterozygotes (+/-) was at an intermediate value (120 +/- 4 mmHg). To determine whether Npr1 gene function affects the renin-angiotensin-aldosterone system (RAAS), we measured the components of RAAS in plasma, kidney, and adrenal gland of 0-copy, 1-copy, and 2-copy male mice. Newborn (2 days after the birth) 0-copy pups showed 2.5-fold higher intrarenal renin contents compared with 2-copy wild-type counterparts (0-copy 72 +/- 12 vs. 2-copy 30 +/- 7 microg ANG I. mg protein(-1). h(-1), respectively). The intrarenal ANG II level in 0-copy pups was also higher than in 2-copy controls (0-copy 33 +/- 5 vs. 2-copy 20 +/- 2 pg/mg protein, respectively). However, both young (3 wk) and adult (16 wk) 0-copy mutant mice showed a dramatic 50-80% reduction in plasma renin concentrations (PRCs) and in expression of renal renin message compared with 2-copy control animals. In contrast, the adrenal renin content and mRNA expression levels were 1.5- to 2-fold higher in 0-copy adult mice than in 2-copy animals. The results suggest that inhibition of renal and systemic RAAS is a compensatory response that prevents greater increases in elevated arterial pressures in adult NPRA null mutant mice. However, the greater renin and ANG II levels seen in 0-copy newborn pups provide evidence that the direct effect of NPRA activation on renin is an inhibitory response.

Enhancement of angiotensinogen expression in angiotensin II-dependent hypertension

Chronic infusion of angiotensin (Ang) II leads to the development of hypertension and enhances intrarenal Ang II content to levels greater than can be explained from the circulating concentrations of the peptide. We previously reported that renal angiotensinogen (Ao) mRNA is enhanced in Ang II-dependent hypertension and may contribute to augmented intrarenal Ang II levels, but the Ao protein levels were not significantly increased. Because a high-salt diet (H/S) has been shown to suppress renal expression of Ao mRNA, we examined the effects of chronic Ang II infusion on kidney and liver Ao mRNA and protein levels in male Sprague-Dawley rats (n=12) maintained on an 8% salt diet. Ang II was administered via osmotic minipumps (40 ng/min) to 1 group (n=6) while the remaining rats were sham-operated. A H/S diet alone did not alter systolic blood pressure in sham animals (109+/-6 mm Hg at day 12); however, Ang II infusions to the H/S rats significantly increased systolic blood pressure (167+/-7 at day 12) and intrarenal Ang II content (459+/-107 fmol/g versus 270+/-42) despite a marked suppression of plasma renin activity (0.9+/-0.2 ng Ang I. mL(-1). h(-1) versus 2.8+/-1.3). Ang II infusions significantly increased kidney Ao mRNA compared with the H/S diet alone by 1.9+/-0.1-fold. Western blot analysis of kidney protein extracts showed that the Ang II-infused rats had increased kidney Ao protein levels compared with the H/S diet alone (1.9+/-0.1-fold). Liver Ao mRNA and protein and plasma Ao protein were also significantly increased by Ang II infusions. These data demonstrate the effects of Ang II infusion to stimulate Ao mRNA and protein. Thus, the augmented intrarenal Ang II in Ang II-dependent hypertension may result, in part, by a positive amplification mechanism to activate renal expression of AO:

Nitric oxide in the control of renal hemodynamics and excretory function

Experimental evidence has now been amassed to indicate that inhibition of nitric oxide (NO) synthase reduces total or regional renal blood flow by approximately 25 to 30% and markedly increases the renal vascular resistance, demonstrating that basal release of NO helps to maintain the relatively low vascular resistance that is characteristic for the kidney. It has been demonstrated that intraarterial administration of NO synthase inhibitors causes marked reductions in sodium excretion without changes in filtered load and suppressed the arterial pressure-induced natriuretic responses in the kidney. We also demonstrated that a constant rate infusion of a NO donor in dogs pretreated with a NOS inhibitor resulted in increases in sodium excretion but failed to restore the slope of the relation between arterial pressure and sodium excretion, suggesting that an alteration in intrarenal NO production rate during changes in arterial pressure is involved in the mediation of pressure natriuresis. Further experiments in dogs performed in our laboratory have confirmed that there is a direct relationship between changes in arterial pressure and intrarenal NO activity measured using NO-sensitive microelectrodes in the renal tissue. These arterial pressure-induced changes in intrarenal NO activity were seen positively correlated with the changes in urinary excretion rates of sodium. Collectively, these data suggest that acute changes in arterial pressure alter intrarenal NO production, which inhibits tubular sodium reabsorption to manifest the phenomenon of pressure natriuresis.

Interactions of adenosine A1 and A2a receptors on renal microvascular reactivity

Adenosine vasoconstricts preglomerular arterioles via adenosine A1 receptors. Because adenosine also activates adenosine A2 receptors, its overall renal vascular actions are complex and not fully understood. The present study was performed to determine the relative contributions of adenosine A1 and A2a receptors to the responsiveness of the renal microvasculature to adenosine. Afferent and efferent arteriolar diameters were monitored in vitro using the blood-perfused rat juxtamedullary nephron preparation. Basal afferent and efferent arteriolar diameters averaged 17.1 +/- 0.5 (n = 35) and 17.8 +/- 0.5 (n = 20) microm, respectively. Superfusion with 0.1 and 1 micromol/l adenosine did not significantly alter afferent and efferent arteriolar diameters; however, 10 micromol/l adenosine significantly reduced afferent and efferent arteriolar diameters (-8.2 +/- 0.8 and -5.7 +/- 0.6%, respectively). The afferent and efferent arteriolar vasoconstrictor responses to adenosine waned at a dose of 100 micromol/l, such that diameters returned to values not significantly different from control within 2 min. During adenosine A1 receptor blockade with 8-noradamantan-3-yl-1,3-dipropylxanthine (KW-3902: 10 micromol/l), 10 and 100 micromol/l adenosine significantly increased afferent diameter by, respectively, 8.1 +/- 1.2 and 13.7 +/- 1.3% (n = 14) and efferent arteriolar diameter by 6.4 +/- 1.3 and 9.3 +/- 1.2% (n = 8). The afferent and efferent arteriolar vasodilatory responses to adenosine in the presence of KW-3902 were significantly attenuated by addition of the adenosine A2a receptor antagonist 1,3-dipropyl-7-methyl-8-(3,4-dimethoxystyryl)xanthine (KF-17837: 15 micromol/l, n = 7 and 6, respectively). The addition of KF-17837 alone significantly enhanced afferent (n = 15) and efferent (n = 6) arteriolar vasoconstrictor responses to 1, 10, and 100 micromol/l adenosine. These results indicate the presence of adenosine A1 and A2a receptors on afferent and efferent arterioles of juxtamedullary nephrons, such that adenosine A2a receptor-mediated vasodilation partially buffers adenosine-induced vasoconstriction in both pre- and postglomerular segments of the renal microvasculature.

Nitric oxide dependency of arterial pressure-induced changes in renal interstitial hydrostatic pressure in dogs

A direct relationship between renal arterial pressure (RAP) and renal interstitial hydrostatic pressure (RIHP) has been shown under conditions of efficient renal blood flow autoregulation. Experiments were performed in six anesthetized dogs to evaluate whether these RIHP responses to changes in RAP were modified during nitric oxide (NO) inhibition with nitro-L-arginine (NLA) or after administration of NO donor agents. A microtip catheter transducer was placed underneath the renal capsule to measure RIHP. Stepwise reductions in RAP (140 to 80 mm Hg) during control conditions resulted in decreases in RIHP from its basal value of 4.7+/-1.1 mm Hg with a slope of 0.04+/-0.026 mm Hg. mm Hg(-)(1) along with decreases in urinary nitrate/nitrite excretion rate (U(NOx)V). Renal cortical and medullary blood flows, measured by laser-Doppler flowmetry, exhibited high autoregulatory efficiency over this RAP range. The changes in RIHP during alterations in RAP were positively correlated (r=0.743; P:<0.001) with the changes in U(NOx)V but not with cortical or medullary blood flow. NLA infusion decreased RIHP to 1.9+/-0.5 mm Hg and also reduced U(NOx)V from 1.8+/-0.2 to 0.9+/-0.01 nmol. min(-)(1). g(-)(1). Infusion of NO donors restored RIHP (4.3+/-0.9 mm Hg) and U(NOx)V (1.5+/-0.2 nmol. min(-)(1). g(-)(1)). During NLA infusion, the RIHP responses to reductions in RAP were markedly attenuated and were not restored even during constant-rate infusion of NO donors. The results suggest that changes in RIHP in response to alterations in RAP are associated with changes in intrarenal NO, suggesting a direct effect of NO to regulate RIHP.

Renal interstitial atp responses to changes in arterial pressure during alterations in tubuloglomerular feedback activity

We recently demonstrated a direct relationship between autoregulation-related changes in renal vascular resistance (RVR) and renal interstitial ATP concentrations. To assess the possible role for extracellular ATP in the regulation of tubuloglomerular feedback (TGF)-mediated autoregulatory adjustments in RVR, renal interstitial ATP concentrations were measured with microdialysis probes in anesthetized dogs at different renal arterial pressures (RAPs) within the autoregulatory range during augmented and diminished activity of the TGF mechanism. Stepwise reductions in RAP from ambient pressure (129+/-3 mm Hg) to 102+/-2 mm Hg (step 1) and 75+/-1 mm Hg (step 2) resulted in significant decreases in ATP concentrations from 9.0+/-0.8 to 6.3+/-0.6 nmol/L in step 1 and to 4.2+/-0.5 nmol/L in step 2. Changes in RVR were highly correlated with changes in ATP concentrations (r=0.86, P<0.001, n=12). Acetazolamide (100 microgram. kg(-1). min(-1), n=6), which increases solute delivery to the macula densa, thus augmenting TGF activity, significantly decreased renal blood flow (RBF) by -16+/-2% and glomerular filtration rate (GFR) by -22+/-4% and increased ATP concentrations from 8.4+/-0.7 to 15.5+/-1.4 nmol/L. Although basal RBF and GFR levels were reduced by the acetazolamide infusion, autoregulation efficiency was maintained, and interstitial ATP concentrations were significantly decreased in response to reductions in RAP by -36+/-4% in step 1 and by -54+/-2% in step 2. The relationship between changes in RVR and interstitial ATP concentrations was preserved during acetazolamide treatment (r=0.80, P<0.01). Inhibition of the TGF mechanism by furosemide significantly increased RBF by 33+/-6% and GFR by 13+/-2% and decreased ATP concentrations from 8.9+/-1.4 to 5.0+/-0.8 nmol/L (n=6). Furosemide caused marked impairment of RBF and GFR autoregulatory efficiency (by -14+/-3% and -11+/-3% in step 1 and by -26+/-2% and -18+/-4% in step 2, respectively). In the furosemide-treated kidneys, interstitial ATP levels remained low and were not altered during reductions in RAP (4.7+/-0.7 nmol/L in step 1 and 4.7+/-0.8 nmol/L in step 2), and changes in RVR did not exhibit a correlation with changes in ATP concentrations (r=0.22, P=0.30). These data support the hypothesis that extracellular ATP contributes to autoregulatory adjustments in RVR that are mediated by changes in activity of the TGF mechanism.

Early diabetes mellitus stimulates proximal tubule renin mRNA expression in the rat

BACKGROUND

Enhanced intrarenal angiotensin II (Ang II) activity may contribute to diabetic nephropathy. The proximal tubule is a proposed site of significant intrarenal Ang II production. We determined the effect of early diabetes on mRNA expression of components of the proximal tubule renin-angiotensin system.

METHODS

Three groups of male Sprague-Dawley rats were studied after two weeks: (1) control (C), (2) streptozotocin-induced diabetes (STZ), and (3) STZ-induced diabetes, with normoglycemia maintained by insulin implants (STZ-I). Competitive reverse transcription-polymerase chain reaction was used to assay mRNA for renin, angiotensinogen, and angiotensin-converting enzyme in suspensions of proximal tubules; plasma and kidney levels of Ang II were measured by radioimmunoassay, and Western analysis of Ang II subtype 1 (AT1) receptors was performed.

RESULTS

STZ rats tended to have increased plasma and intrarenal levels of Ang II compared with C and STZ-I rats. In proximal tubules, mRNA for renin was significantly increased in STZ rats, with reversal to control values in STZ-I rats (C, 2432 +/- 437 vs. STZ, 5688 +/- 890 fg/0.25 microg RNA, P < 0.05 vs. C, N = 9, vs. STZ-I, 1676 +/- 376 fg/0.25 microg RNA, P = NS vs. C). In STZ rats, the AT1 receptor antagonist losartan caused a further fivefold increase in proximal tubule renin mRNA, associated with proximal tubular renin immunostaining. STZ had no significant effect on mRNA expression for angiotensinogen or angiotensin-converting enzyme in proximal tubules. By Western blot analysis, cortical and proximal tubule AT1 receptor protein expression was significantly decreased in STZ rats.

CONCLUSIONS

These data suggest activation of the proximal tubule renin-angiotensin system in early STZ diabetes, mediated at least partly by enhanced expression of renin mRNA. Increased local production of Ang II could contribute to tubulointerstitial injury in this model.

Dynamic interaction between myogenic and TGF mechanisms in afferent arteriolar blood flow autoregulation

The dynamic activity of afferent arteriolar diameter (AAD) and blood flow (AABF) responses to a rapid step increase in renal arterial pressure (100-148 mmHg) was examined in the kidneys of normal Sprague-Dawley rats (n = 11) before [tubuloglomerular feedback (TGF)-intact] and after interruption of distal tubular flow (TGF-independent). Utilizing the in vitro blood-perfused juxtamedullary nephron preparation, fluctuations in AAD and erythrocyte velocity were sampled by using analog-to-digital computerized conversion, video microscopy, image shearing, and fast-frame, slow-frame techniques. These assessments enabled dynamic characterization of the autonomous actions and collective interactions between the myogenic and TGF mechanisms at the level of the afferent arteriole. The TGF-intact and TGF-independent systems exhibited common initial (0-24 vs. 0-13 s, respectively) response slope kinetics (-0.53 vs. -0.47% DeltaAAD/s; respectively) yet different maximum vasoconstrictive magnitude (-11.28 +/- 0.1 vs. -7. 02 +/- 0.9% DeltaAAD; P < 0.05, respectively). The initial AABF responses similarly exhibited similar kinetics but differing magnitudes. In contrast, during the sustained pressure input (13-97 s), the maximum vasoconstrictor magnitude (-7.02 +/- 0.9% DeltaAAD) and kinetics (-0.01% DeltaAAD/s) of the TGF-independent system were markedly blunted whereas the TGF-intact system exhibited continued vasoconstriction with slower kinetics (-0.20% DeltaAAD/s) until a steady-state plateau was reached (-25.9 +/- 0.4% DeltaAAD). Thus the TGF mechanism plays a role in both direct mediation of vasoconstriction and in modulation of the myogenic response.

Roles of ANG II and bradykinin in the renal regional blood flow responses to ACE inhibition in sodium-depleted dogs

The relative contributions of ANG II and bradykinin (BK) to the renal regional blood flow responses during angiotensin-converting enzyme (ACE) inhibition remain unclear. This study was performed to evaluate renal cortical (CBF) and medullary blood flow (MBF) responses to intrarterial administration of enalaprilat (33 microg. kg(-1). min (-1)) after blockade of the ANG II AT(1 )receptors with candesartan (100 microg) in 7 dogs fed a low-salt diet (0.01%) for 5 days. Laser-Doppler flowmetry was used to measure relative changes in CBF and MBF. Candesartan alone increased CBF (+20 +/- 2%) and MBF (+22 +/- 7%). Enalaprilat infusion after candesartan administration resulted in further increases in both CBF (+21 +/- 5%) and MBF (+41 +/- 8%). However, the relative changes in MBF were significantly greater (P < 0.01) than those in CBF. Administration of the BK B(2) receptor blocker icatibant (300 microg) after enalaprilat returned CBF and MBF to values seen with candesartan alone. These data support a substantive role for BK potentiation during ACE inhibitor-induced renal vasodilation in dogs maintained on a low-sodium diet, with a relatively greater effect on MBF compared to CBF.

Impairment of pressure-natriuresis and renal autoregulation in ANG II-infused hypertensive rats

Chronic infusions of initially subpressor doses of angiotensin II (ANG II) lead to progressive hypertension over a 2-wk period and to augmented intrarenal ANG II levels. The present study was performed to investigate total renal blood flow (RBF) and medullary blood flow (MBF) autoregulatory behavior and pressure-natriuresis in ANG II-infused hypertensive rats and how these are modified by concomitant treatment with an ANG II AT(1) receptor antagonist. ANG II-infused rats (n = 27) were prepared by administration of ANG II at 60 ng/min via osmotic minipump for 13 days. Twelve of the ANG II-infused hypertensive rats were treated with losartan in the drinking water (30 mg. kg.(-1) day(-1)). Rats were anesthetized with pentobarbital sodium (50 mg/kg, ip) and prepared for renal function measurements. An aortic clamp was placed above the junction of the left renal artery to reduce renal arterial pressure. Autoregulatory responses for renal plasma flow, overall RBF, and glomerular filtration rate were impaired in ANG II-infused hypertensive rats; however, MBF autoregulation was not disrupted. Most strikingly, pressure-natriuresis was markedly suppressed in ANG II-infused hypertensive rats. Chronic treatment with losartan prevented the impairment of the pressure-natriuresis relationship caused by chronic ANG II infusion. These findings demonstrate that chronic ANG II infusion leads to marked impairment of sodium excretion and suppression of the pressure-natriuresis relationship, which may contribute to the progressive hypertension that occurs in this model. These renal effects are prevented by simultaneous treatment with an AT(1) receptor blocker.

Intrarenal angiotensin II augmentation in angiotensin II dependent hypertension

In several models of angiotensin II (ANG II) dependent hypertension, intrarenal ANG II levels increase to a much greater extent than the circulating levels even though the renal renin levels are decreased. The 2-kidney-1-clip (2K1C) Goldblatt rat model is particularly intriguing because hypertension develops in the presence of an intact kidney which would be expected to maintain sodium balance and protect against hypertension. Although the non-clipped kidney becomes renin depleted, it exhibits enhanced microvascular reactivity and increased tubular fractional sodium reabsorption. The non-clipped kidney ANG II content is either elevated or unchanged and proximal tubular fluid ANG II concentrations are not suppressed compared to the nanomolar concentrations found in normal rats. These results suggest that intrarenal ANG II content can be regulated independently of renal renin content. A similar hypertensive process occurs in rats infused chronically with low doses of ANG II. Renal ANG II content increases over 14 days to a greater extent than the circulating concentrations. Functionally, ANG II infused rats demonstrate reduced sodium excretion and marked suppression of pressure natriuresis. These ANG II dependent influences on kidney function contribute to the maintenance of hypertension. Renal augmentation of ANG II, hypertension, and suppressed sodium excretion are blocked by AT1 receptor blockers. To study the mechanisms responsible for intrarenal ANG II augmentation, we infused a different form of ANG II (Val5 ANG II), that can be separated from endogenous ANG II by HPLC. These results indicated that the increased renal ANG II content was due to accumulation of circulating ANG II in addition to continued production of endogenous ANG II. The renal accumulation of Val5-ANG II was markedly reduced by concomitant treatment with the AT1 receptor blocker, losartan. In addition, we found an unchanged overall ANG II-AT1 receptor protein which probably contributes to the maintained ANG II dependent influences. Collectively, the data support the concept that there is internalization of ANG II through an AT1 receptor mediated process and that some of the internalized ANG II is protected from degradation. The augmented intrarenal ANG II coupled with sustained levels of AT1 receptors contribute to the continued ANG II dependent suppression of renal function and sodium excretion thereby maintaining the hypertension.

Relation between renal interstitial ATP concentrations and autoregulation-mediated changes in renal vascular resistance

The present study was performed to examine the hypothesis that autoregulation-related changes in renal vascular resistance (RVR) are mediated by extracellular ATP. By use of a microdialysis method, renal interstitial concentrations of ATP and adenosine were measured at different renal arterial pressures (RAPs) within the autoregulatory range in anesthetized dogs (n=12). RAP was reduced in steps from the ambient pressure (131+/-4 mm Hg) to 105+/-3 mm Hg (step 1) and 80+/-2 mm Hg (step 2). Renal blood flow and glomerular filtration rate exhibited efficient autoregulation in response to these changes in RAP. RVR decreased by 22+/-2% in step 1 (P<0.01) and 38+/-3% in step 2 (P<0.01). The control renal interstitial concentration of ATP was 6.51+/-0.71 nmol/L and decreased to 4. 51+/-0.55 nmol/L in step 1 (P<0.01) and 2.77+/-0.47 nmol/L in step 2 (P<0.01). In contrast, the adenosine concentrations (117+/-6 nmol/L) were not altered significantly. Changes in ATP levels were highly correlated with changes in RVR (r=0.88, P<0.0001). Further studies demonstrated that stimulation of the tubuloglomerular feedback (TGF) mechanism by increasing distal volume delivery elicited with acetazolamide also led to increases in renal interstitial ATP concentrations, whereas furosemide, which is known to block TGF responses, reduced renal interstitial fluid ATP concentrations. The data demonstrate a positive relation between renal interstitial fluid ATP concentrations and both autoregulation- and TGF-dependent changes in RVR and thus support the hypothesis that changes in extracellular ATP contribute to the RVR adjustments responsible for the mechanism of renal autoregulation.

Nitric oxide-angiotensin II interactions in angiotensin II-dependent hypertension

Many studies indicate that renal haemodynamic function in angiotensin II- (ANG II) dependent hypertension is not reduced as much as would be predicted from the elevated ANG II levels suggesting that counteracting renoprotective mechanisms are activated. One important renoprotective effect is mediated by increased levels of nitric oxide. Recent studies using the ANG II-infused hypertensive rat model have shown that inhibition of nitric oxide synthesis (NOS) causes greater decreases in renal blood flow and glomerular filtration rate in ANG II-infused hypertensive rats than in control rats. This augmented nitric oxide-dependent influence is localized primarily in the cortex and to the preglomerular vasculature. The differential effects on the renal cortex and medulla are also reflected by the differences in NOS activities and protein expression. Ca2+-dependent NOS activity was significantly greater in the cortex but not the medulla of the ANG II-infused hypertensive rats compared with control rats. This was associated with marked activation of endothelial NOS protein levels and smaller increases in neuronal NOS protein levels in the cortex but not in the medulla. In contrast, the Ca2+-independent NOS activity and the inducible NOS protein levels in the cortex were significantly lower in the ANG II-infused hypertensive rats. These data support the hypothesis that cortical Ca2+-dependent NOS, primarily endothelial NOS, is stimulated during the early phases of ANG II-induced hypertension and exerts a renoprotective effect on cortical haemodynamics.

Renal responses to AT1 receptor blockade

Because of the importance of the renin-angiotensin system in the pathophysiology of hypertension and in mediating associated alterations in renal function, angiotensin II (Ang II) AT1 receptor blockers provide a direct means of protecting against influences of excessive Ang II levels. The kidney is an important site of action of Ang II AT1 receptor blockers because intrarenal Ang II not only vasoconstricts the renal vasculature but also reduces sodium excretion and suppresses the pressure natriuresis relationship. Even in normal conditions, intrarenal Ang II content is greater than can be explained on the basis of circulating Ang II and is compartmentalized with proximal tubule concentrations of Ang I and Ang II being several times higher than plasma concentrations. The localization of angiotensinogen in proximal tubule cells further supports the concept that the proximal tubule secretes Ang II or precursors of Ang II into the tubular fluid to activate luminal Ang II receptors. Recent immunohistochemical studies have demonstrated an abundance of AT1 receptors on the luminal surface of proximal and distal tubule cells as well as on vascular smooth muscle cells of afferent and efferent arterioles and on glomerular mesangial cells. Activation of luminal AT1 receptors stimulates the sodium hydrogen exchanger and increases reabsorption rate. The prominence of AT1 receptors in vascular and epithelial tissues in the kidney provides the basis for the powerful effects of AT1 receptor blockers on renal function especially in hypertensive conditions. In the two-kidney, one-clip (2K1C) Goldblatt hypertensive rat model, the nonclipped kidney is renin depleted but the intrarenal Ang II levels are not suppressed and Ang II concentrations in proximal tubular fluid remain high (10(-8) mol/L). AT1 receptor blockers such as candesartan have been shown to cause significant increases in glomerular filtration rate, renal blood flow and proportionately much greater increases in sodium excretion and fractional sodium excretion. Ang II blockade also markedly increases the slope of the pressure natriuresis relationship. The collective actions of Ang II blockers on tubular transport and renal hemodynamics provide long-term effects to regulate sodium balance, which contributes to the long-term control of hypertension.

Renal function in mice: effects of volume expansion and angiotensin II

The present study was performed to validate a simple means for assessing renal function in anesthetized mice and to characterize the renal hemodynamic responses to acute volume expansion and how these responses are altered by concurrent angiotensin II (AngII) infusions. Inulin and para-aminohippurate clearances were used to assess GFR and renal plasma flow (RPF) in three groups of male C57Bl/6 mice anesthetized with inactin (100 mg/kg, intraperitoneally) and ketamine (10 mg/kg). To avoid the hypotension associated with repeated blood sampling, a single blood sample was taken after three timed urine collections. Renal function and mean arterial pressure (MAP) were measured under euvolemic conditions (2.5 microl/min, intravenously, n = 7) during isotonic saline volume expansion (12.5 microl/min, intravenously, n = 5) and during volume expansion with concurrent AngII infusion (5 ng/min x g, n = 5). MAP in the control group was 77 +/- 2 mmHg; volume expansion alone did not change MAP significantly (83 +/- 2 mmHg), but led to significantly greater values in both GFR and RPF (1.35 +/- 0.14 versus 1.01 +/- 0.1 ml/min x g and 11.26 +/- 1.39 versus 6.29 +/- 0.5 ml/min x g, respectively). Infusion of AngII during volume expansion led to significant elevations of MAP (100 +/- 3 mmHg, P < 0.05) and prevented the increases in GFR and RPF elicited by volume expansion (0.77 +/- 0.08 and 5.35 +/- 0.48 ml/min x g, respectively). Volume expansion also elicited marked increases in absolute and fractional sodium excretion (6.1 +/- 1.0 versus 0.62 +/- 0.2 microEq/min x g and 3.1 +/- 0.7 versus 0.4 +/- 0.1%, respectively). AngII infusion attenuated the absolute and fractional sodium excretion responses to volume expansion (3.4 +/- 1.2 microEq/min x g and 2.5 +/- 0.5%, respectively). The present findings demonstrate that anesthetized mice exhibit marked renal hemodynamic and excretory responses to isotonic saline volume expansion. Concomitant AngII infusion attenuates these responses in spite of greater increases in arterial pressure.

Increased activity and expression of Ca(2+)-dependent NOS in renal cortex of ANG II-infused hypertensive rats

We have previously demonstrated that nitric oxide (NO) exerts a greater modulatory influence on renal cortical blood flow in ANG II-infused hypertensive rats compared with normotensive rats. In the present study, we determined nitric oxide synthase (NOS) activities and protein levels in the renal cortex and medulla of normotensive and ANG II-infused hypertensive rats. Enzyme activity was determined by measuring the rate of formation of L-[(14)C]citrulline from L-[(14)C]arginine. Western blot analysis was performed to determine the regional expression of endothelial (eNOS), neuronal (nNOS), and inducible (iNOS) isoforms in the renal cortex and medulla of control and ANG II-infused rats. Male Sprague-Dawley rats were prepared by the infusion of ANG II at a rate of 65 ng/min via osmotic minipumps implanted subcutaneously for 13 days and compared with sham-operated rats. Systolic arterial pressures were 127 +/- 2 and 182 +/- 3 mmHg in control (n = 13) and ANG II-infused rats (n = 13), respectively. The Ca(2+)-dependent NOS activity, expressed as picomoles of citrulline formed per minute per gram wet weight, was higher in the renal cortex of ANG II-infused rats (91 +/- 11) than in control rats (42 +/- 12). Likewise, both eNOS and nNOS were markedly elevated in the renal cortex of the ANG II-treated rats. In both groups of rats, Ca(2+)-dependent NOS activity was higher in the renal medulla than in the cortex; however, no differences in medullary NOS activity were observed between the groups. Also, no differences in medullary eNOS levels were observed between the groups; however, medullary nNOS was decreased by 45% in the ANG II-infused rats. For the Ca(2+)-independent NOS activities, the renal cortex exhibited a greater activity in the control rats (174 +/- 23) than in ANG II-infused rats (101 +/- 10). Similarly, cortical iNOS was greater by 47% in the control rats than in ANG II-treated rats. No differences in the activity were found for the renal medulla between the groups. There was no detectable signal for iNOS in the renal medulla for both groups. These data indicate that there is a differential distribution of NOS activity, with the Ca(2+)-dependent activity and protein expression higher in the renal cortex of ANG II-infused rats compared with control rats, and support the hypothesis that increased constitutive NOS activity exerts a protective effect in ANG II-induced hypertension to maintain adequate renal cortical blood flow.

Renal function in the AT1A receptor knockout mouse during normal and volume-expanded conditions

BACKGROUND

Genetically altered mice lacking the AT1A angiotensin II (Ang II) receptor were used to examine the role of AT1A receptors in regulating renal hemodynamics, sodium excretion, glomerulotubular balance, and Ang II levels in plasma and kidney during normal and volume-expanded conditions.

METHODS

AT1A receptor-deficient mice and their wild-type controls were anesthetized with inactin and ketamine, and were prepared to allow intravenous infusions of solutions and measurements of aortic pressure and urine collections. Inulin and para-aminohippurate (PAH) solutions were infused intravenously for clearance determinations under conditions of euvolemia (2.5 microliter/min infusion of isotonic saline) or volume-expansion conditions (12.5 microliter/min). After three 30-minute urine collections, blood samples were collected, and kidneys were harvested. Plasma and kidney Ang II measurements were made by radioimmunoassay.

RESULTS

In the euvolemic state, mean arterial pressures (MAPs) were significantly lower in the AT1A receptor-deficient mice (68 +/- 4 mm Hg) compared with wild-type controls (89 +/- 3 mm Hg). Despite the lower MAP, the glomerular filtration rate (GFR), renal plasma flow (RPF), absolute sodium excretion, and fractional sodium excretion were not significantly different between wild-type and AT1A-/- mice. Volume expansion did not alter MAP in wild-type mice, but significantly increased MAP in the AT1A-/- mice (68 +/- 4 to 83 +/- 5 mm Hg). Similar increases in GFR, RPF, absolute sodium excretion, and fractional sodium excretion in AT1A+/+ and AT1A-/- mice were observed. Glomerulotubular balance was not disrupted by the absence of AT1A receptors. During euvolemia, plasma Ang II concentrations were significantly higher in the AT1A-/- mice compared with wild-type mice (536 +/- 172 vs. 198 +/- 36 fmol/ml). Although volume expansion had no effect on plasma Ang II levels in the AT1A+/+ group, plasma Ang II concentrations were markedly suppressed in the AT1A-/- mice to levels that were not different from those in wild-type mice. In contrast, kidney tissue Ang II contents were reduced in the AT1A-/- mice and were not significantly altered during volume expansion in either the AT1A-/- or the AT1A+/+ mice.

CONCLUSIONS

The absence of AT1A receptors does not impair chronic regulation of renal blood flow, GFR, or glomerulotubular balance. The prompt restoration of MAP following volume expansion suggests that low blood pressure in the AT1A receptor-deficient mice is primarily due to reduced effective plasma and extracellular fluid volume. Normalization of plasma Ang II levels with volume expansion demonstrates a dominant effect of extracellular fluid volume and blood pressure over AT1A receptor-mediated short-loop feedback in the regulation of plasma Ang II levels.