A cell culture model for human cardiac myogenesis is introduced. Human fetal myocardial cells were dissociated enzymatically, and cultured in a mitogen-rich medium that promoted the growth of presumptive cardiac myoblasts. Strains of human cardiac myoblasts were generated from different anatomical regions of the fetal heart. The cells could be cultured for at least 30 generations, or frozen and recovered for later use. Differentiation was induced by culturing the cardiac myoblasts in a mitogen-poor medium. Differentiation of cardiac myoblasts was marked primarily by transcriptional activation of the atrial natriuretic factor (ANF) gene. Evidence is presented that posttranscriptional processing of ANF transcripts is affected by the anatomical origin of the cardiac myoblasts and the presence of cocultured neuronal cells. Cardiac myoblasts induced to differentiate in culture synthesized only low levels of sarcomeric myosin and cardiac alpha-actin, suggesting that differentiation of these cells progresses through two phases: an initial, noncontractile phase that is represented by the differentiating cultured cells; and a later contractile phase, in which myofibrillar assembly is accentuated and modulated by secondary signals from the cardiac milieu.
We studied regulation of the AT 2 receptor by investigating the effect of bilateral nephrectomy (bNX) in Sprague–Dawley rats. The expression of aldosterone synthase (CYP11B2) and AT 2 receptor mRNA was detected by nonradioactive in situ hybridization. AT 2 receptor mRNA was detected in cells of the first two or three subcapsular cell layers of the zona glomerulosa (ZG) and in the medulla of sham-operated animals. After bNX, the number and area of distribution of AT 2 receptor-positive cells increased in the ZG. This was associated with an enlargement of the steroidogenic active ZG and with reduced proliferation rate (sham 5.9 ± 0.9%; bNX 2.4 ± 0.2%; p > 0.02). Infusion of angiotensin II (ANG II; 200 ng/kg/min SC for 56 hr) to bNX rats did not reverse the effect of nephrectomy on the distribution of AT 2 receptor expression, although mRNA levels per cell were reduced compared to NX alone. ANG II infusion decreased proliferation rate further (0.4 ± 0.07%; p > 0.001). In the adrenal medulla after bNX, decreased expression of the AT 2 receptor was associated with increased proliferation (2.6 ± 0.2% vs 6.6 ± 0.5%). These results demonstrate differential regulation of the AT 2 receptor in the adrenal gland and suggest that expression of the AT 2 receptor is involved in regulating proliferation and differentiation in the ZG and medulla. (J Histochem Cytochem 49:649–656, 2001)
Blockade of the renin-angiotensin system slows the progression of diabetic nephropathy but fails to abolish the development of end-stage nephropathy of diabetes. The prorenin-to-active renin ratio significantly increases in diabetes, and prorenin binding to its receptor in diabetic animal kidney induces the nephropathy without its conventional proteolytic activation, suggesting that angiotensin II (AngII) may not be the decisive factor causing the nephropathy. For identification of an AngII-independent mechanism, diabetes was induced in wild-type mice and AngII type 1a receptor gene-deficient mice by streptozotocin treatment, and their development and progression of diabetic nephropathy were assessed. In addition, prolonged inhibition of angiotensin-converting enzyme and prolonged prorenin receptor blockade were compared for their efficacy in preventing the nephropathy that occurred in diabetic AngII type 1a receptor gene-deficient mice. Only the prorenin receptor blockade with a short peptide of prorenin practically abolished the increased mitogen-activated protein kinase (MAPK) activation and nephropathy despite unaltered increase in AngII in diabetic kidney. These results indicate that the MAPK activation signal leads to the diabetic nephropathy but not other renin-angiotensin system-activated mechanisms in the glomeruli. It is not only AngII but also intraglomerular activation of MAPK by the receptor-associated prorenin that plays a pivotal role in diabetic nephropathy.
We investigated the actions of endothelin in anesthetized rats and cultured mesangial cells. Intravenous infusion of endothelin (10 pmol/min) decreased renal blood flow by 44% at 20 min without changing arterial pressure, which subsequently rose significantly from 124 +/- 3 to 133 +/- 4 mmHg over 60 min. Micropuncture during the nonhypertensive period revealed increases in afferent (65%) and efferent (82%) arteriolar resistances, thereby reducing nephron plasma flow rate. The glomerular ultrafiltration coefficient (Kf) fell from 0.097 +/- 0.035 to 0.031 +/- 0.011 nl/(s.mmHg) as did single nephron filtration rate (41 +/- 3 to 19 +/- 3 nl/min). Addition of 5 nM endothelin to mesangial cells plated on a silicone rubber substrate increased the intensity and number of tension-generated wrinkles, and caused their reappearance in forskolin prerelaxed cells. 20-30 s following exposure of fura-2 loaded mesangial cells to 10 nM endothelin, single cell intracellular calcium concentration ([Ca]i) increased from a mean baseline value of 66 +/- 11 (SE) to a peak of 684 +/- 250 nM (P less than 0.05) followed by a sustained elevation at 145 +/- 42 nM. Anion exchange HPLC revealed rapid (15 s) and dose-dependent stimulation of inositol 1,4,5-trisphosphate (IP3) generation following exposure of [3H]myoinositol preloaded mesangial cells to 10-100 nM endothelin. Endothelin also led to intracellular alkalinization of 2'7'-bis(2-carboxy-ethyl)-5(and-6)carboxyfluorescein (BCECF)-loaded mesangial cells and its addition was associated with dramatic augmentation of mitogenic activity. Thus, endothelin exerts potent constrictor effects on renal arterioles which precede its systemic hypertensive action. It lowers Kf and contracts mesangial cells, likely through stimulation of IP3 generation and elevation of [Ca]i. It is a potent mesangial cell mitogen. These studies define functional responses and signal transduction pathways for endothelin in the rat kidney and propose a potential role for this peptide in the control of mesangial cell function, glomerular filtration rate, and renal vascular tone.
Abstract To clarify contradicting observations on the identity of inactive renin and prorenin, inactive renin was completely purified from native human chorion laeve and the culture medium of human chorion cells. A 720,000-fold purification with 14% recovery was achieved from chorion laeve in 6 steps, including immunoaffinity chromatography on a monoclonal antibody to human renin coupled to Protein A-Sepharose CL-4B. A 3,100-fold purification with 40% recovery was achieved from chorion culture medium in 4 steps, including immunoaffinity chromatography. Inactive renin purified from the two different sources migrated as a single protein band with the same molecular weight of 47,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and consisted of multiple components that could be resolved by isoelectric focusing. Both had the same pI values which shifted downward upon activation by trypsin; however, relative peak heights were different between the two preparations. The purified inactive renin from chorion laeve was completely inactive and did not bind to pepstatin-aminohexyl-Sepharose; however, that from chorion culture medium was partially active and completely bound to the pepstatin gel, indicating that each molecule is partially activated. Trypsin-activated inactive renins from both sources were identical with human renal renin in terms of pH optimum and Km. Specific activities of trypsin-activated inactive renin from chorion laeve and chorion culture medium were 529 Goldblatt units/mg of protein and 449 Goldblatt units/mg of protein, respectively. Amino acid sequence analysis of both of the purified inactive renin preparations demonstrated a leucine residue at the amino terminus. The sequence of 11 additional amino acids was identical in both and agreed with that predicted from the base sequence of the renin gene. These findings indicate that preprorenin is converted to prorenin following removal of a 23-amino acid signal peptide and that the native inactive renin, whose amino acid sequence commences with Leu-Pro-Thr..., is prorenin.
The vast majority of the known biological effects of the renin–angiotensin system are mediated by the type-1 (AT 1 ) receptor, and the functions of the type-2 (AT 2 ) receptor are largely unknown. We investigated the role of the AT 2 receptor in the vascular and renal responses to physiological increases in angiotensin II (ANG II) in mice with targeted deletion of the AT 2 receptor gene. Mice lacking the AT 2 receptor (AT 2 -null mice) had slightly elevated systolic blood pressure (SBP) compared with that of wild-type (WT) control mice ( P < 0.0001). In AT 2 -null mice, infusion of ANG II (4 pmol/kg/min) for 7 days produced a marked and sustained increase in SBP [from 116 ± 0.5 to 208 ± 1 mmHg ( P < 0.0001) (1 mmHg = 133 Pa)] and reduction in urinary sodium excretion (U Na V) [from 0.6 ± 0.01 to 0.05 ± 0.002 mM/day ( P < 0.0001)] whereas neither SBP nor U Na V changed in WT mice. AT 2 -null mice had low basal levels of renal interstitial fluid bradykinin (BK), and cyclic guanosine 3′,5′-monophosphate, an index of nitric oxide production, compared with WT mice. In WT mice, dietary sodium restriction or ANG II infusion increased renal interstitial fluid BK, and cyclic guanosine 3′,5′-monophosphate by ≈4-fold ( P < 0.0001) whereas no changes were observed in AT 2 -null mice. These results demonstrate that the AT 2 receptor is necessary for normal physiological responses of BK and nitric oxide to ANG II. Absence of the AT 2 receptor leads to vascular and renal hypersensitivity to ANG II, including sustained antinatriuresis and hypertension. These results strongly suggest that the AT 2 receptor plays a counterregulatory protective role mediated via BK and nitric oxide against the antinatriuretic and pressor actions of ANG II.
Renal complications are one of the leading causes of mortality in sickle cell anemia (SCA). Sickle nephropathy (SN) encompasses a spectrum of renal pathologies including tubular defects [e.g., impaired urine concentrating ability (UCA)/hyposthenuria] and glomerular defects [albuminuria, focal segmental glomerulosclerosis (FSGS) and end-stage renal disease (ESRD)]. Sickling of RBCs in the hypoxic hyperosmotic renal medulla causes vaso-occlusion in the vasa-recta, ischemia, loss of osmotic gradient, and papillary necrosis, resulting in hyposthenuria. However, the mechanism underlying glomerulopathy is unknown and assumed to be secondary to sickling-associated injury. Angiotensin converting enzyme-inhibitors (ACE-I) have been tested in small clinical trials for adults with SCA with albuminuria, based on their reno-protective properties in nonsickle nephropathies, and are included in the NHLBI guidelines for SCA.1 We recently showed that high circulating angiotensin-II (AT) in mice and humans with SCA increases mobilization of hematopoietic stem/progenitor cells.2 Angiotensin-II (AT), signals through tissue-bound AT receptors-1 (AT1R) and −2 (AT2R). While the detrimental role of increased AT signaling is known in non-SCA nephropathies, its role in SCA, and specifically SN, has not been studied. We investigated whether high AT was secondary to increased renin in SCA. Renin catalyzes generation of AT from its precursor angiotensinogen (Supporting Information Figure S1a). Hypoxia increases renin expression, thereby increasing AT production, which is the basis of reno-vascular hypertension. We postulated that in SCA, hypoxia from vaso-occlusions in vasa-recta could increase renin and consequently AT production. However, renin expression was not increased in kidneys of young sickle mice, despite high urinary AT levels (AT, a small octapeptide, readily filters through the glomerulus, and urine AT level reflects circulating and renal-generated AT) (Supporting Information Figure S1b-d). Moreover, high AT was present in young children with SCA, in the absence of hypertension (Supporting Information Figure S1e-f). Hence, renin signaling does not appear to be the cause of high AT levels; its levels rise secondarily in older animals. We next transplanted normal/wild-type mice (WT) mice with bone marrow from SS mice (SS→WT) to attain fully chimeric sickle mice (WT→WT chimeras were transplant controls). SS chimeras, but not WT chimeras, had hyperangiotensinemia (Supporting Information Figure S1g), demonstrating that this effect was not secondary to transplant-induced vasculopathy. This data suggests that perhaps sickle hematopoiesis mediates hyperangiotensinemia, although the mechanism needs to be explored. We investigated the role of high AT in SN. The features of SN seen in humans were closely mimicked in both SCA mouse models (Berkeley sickle [SS] mice and knock-in-SS mice, both exclusively carrying human sickle hemoglobin), including glomerular hyper-filtration, albuminuria, hyposthenuria, and progressively worsening FSGS. Indeed, the renal pathology in older SS mice was similar to that in a SCA patient with macro-albuminuria (Supporting Information Figure S2a-f). These SCA mouse models were used for mechanistic studies. We blocked AT signaling with captopril (ACE-I), or losartan (AT1R blocker) in SS mice. Both captopril and losartan abrogated albuminuria within 8-weeks, an effect sustained when treatment was continued for another 8-weeks (Figure 1A). This amelioration in glomerular defect was accompanied with improved renal histology (glomerulosclerosis, and mesangial proliferation) compared to the untreated SS controls (Figure 1B, Supporting Information Figure S3a-d). This effect of AT inhibition was also observed in WT mice transplanted with sickle hematopoiesis (SS/WT chimera); the albuminuria that developed in the SS/WT chimeric mice post-transplant was normalized with AT blockade (Figure 1C). Like with other nonsickle nephropathies,3 SS mice had increased renal (glomerular) active TGFβ1 and Smad-2/3 (Supporting Information Figure S4a-d), that were corrected by blocking AT-signaling with captopril/losartan (Figure 1B). Hyperangiotensinemia in SCA promotes glomerulopathy (via AT1R signaling), but plays an important role in sustaining urine concentrating ability (via both AT1R and AT2R signaling) in the setting of SCA-associated hyposthenuria. (A) Temporal progression of albuminuria, shown as urine albumin/creatinine ratio (Y-axis), in nontransplanted WT mice or SS mice (that were untreated, or treated with losartan or captopril). The weeks of drug treatment shown on the X-axis. SS mice were started on drug treatment at 8–12 weeks of age. UACR was determined on 24 hour-urine samples by the urine albumin to creatinine ratio and data are expressed in µg albumin/mg creatinine. (B) H &E staining (60× magnification), PAS staining (60× magnification) and immunohistochemistry for phosphorylated Smad-2/3 (100× magnification) in the kidneys of WT mice, untreated -SS control mice, or SS mice treated with captopril or losartan for 12 weeks. A single representative glomerulus is shown. Improvement in glomerular pathology including congestion, FSGS and mesangial proliferation is seen in SS mice on captopril or losartan compared to the untreated SS mice. Increased pSmad2/3 expression (brown staining) is seen in untreated SS compared to SS mice on captopril/losartan. (C) C57Bl/6 mice (WT; recipient) were transplanted with SS or WT donor bone marrow at 8–12 weeks of age following lethal irradiation (1275cGy) in a donor: recipient ratio of 1:7. Only SS/WT chimeras determined to be fully chimeric for SS by HPLC for hemoglobin S, 3 months after transplantation, were further analyzed for experiments. Untreated WT/WT chimeras (WT/WT-Ctrl; red bar), untreated SS chimeric mice (SS/WT-Ctrl; black bar), SS chimeric mice placed on captopril 3 months after transplant (SS/WT-Cap; blue bar) and SS chimeric mice placed on losartan 3 months after transplant (SS/WT-Los; green bar) were compared. Urine albumin and creatinine was analyzed 12 months after establishment of chimerism. UACR was determined on 24-hr urine samples by the urine albumin to creatinine ratio and data are expressed in µg albumin/mg creatinine is shown (n= 6–8 mice/group. (D) UACR levels in WT, AT1R-/- and AT2R-/- recipient mice transplanted with WT (red bars) or SS (black bars) donor bone marrow. Mice fully chimeric for WT or SS bone marrow at three months were analyzed. UACR was determined on 24-hr urine samples by the urine albumin to creatinine ratio and data are expressed in µg albumin/mg creatinine is shown (n = 6–20 mice per group). (E) Urine albumin in SS mice (untreated or placed on only AT1R antagonist Losartan (Los) or placed on a combination of AT2R agonist C21, and Los; n = 10–20 mice/group. (F) Temporal progression of UCA, measured by urine osmolality (Y-axis) in nontransplanted WT mice and SS mice (that were untreated, or treated with captopril or losartan) with weeks of drug treatment shown on the X-axis. Mice were started on drug treatment at 8–12 weeks of age. Urine osmolality could only be measured in captopril-treated mice if they were given additionally water without captopril, due to high mortality from severe dehydration. The urine osmolality data are expressed in mmol/kg and was measured in 24-hr urine collections (G) C57Bl/6 mice (WT; recipient) were transplanted with SS or WT donor bone marrow at 8–12 weeks of age following lethal irradiation (1275cGy) in a donor: recipient ratio of 1:7. Only SS/WT chimeras determined to be fully chimeric for SS by HPLC for hemoglobin S, 3 months after transplantation, were further analyzed for experiments. Untreated WT/WT chimeras (WT/WT-Ctrl; red bar), untreated SS chimeric mice (SS/WT-Ctrl; black bar), SS chimeric mice placed on captopril 3 months after transplant (SS/WT-Cap; blue bar) and SS chimeric mice placed on losartan 3 months after transplant (SS/WT-Los; green bar) were compared. Urine osmolality analyzed 12 months after establishment of donor chimerism. The urine osmolality data are expressed in mmol/kg and was measured in 24-hr urine (n = 6–20 mice/group). (H) Kaplan-Meier survival curve in nontransplanted WT mice and SS mice (that were untreated or treated with captopril or losartan) for 20 weeks (X-axis). The percentage of mice surviving at the end of the experiment is indicated against the survival curve of each group. (I) Urine osmolality in WT, AT1R-/- and AT2R-/- recipient mice transplanted with WT (red bars) or SS (black bars) donor bone marrow. Mice fully chimeric for WT or SS bone marrow at three months were analyzed for urine osmolality (n = 5–9 mice per group), in a 24 hour-urine collection sample. (J) Urine osmolality in SS mice (untreated or placed on only AT1R antagonist Losartan (Los) or placed on a combination of AT2R agonist C21 and Los; n = 10–20 mice/group. All data are plotted as mean ±SEM. Statistical analysis was done either using Mann Whitney U test, where two groups are compared or using ANOVA (Dunnet's multiple comparisons test) while comparing between multiple groups. Statistical significance is denoted by *P < .05, **P < .01, ***P < .001, ****P < .0001 To confirm the pharmacological data, we transplanted sickle hematopoiesis into mice genetically deficient in AT1R, or AT2R, to create mice with SCA that lacked either AT1R (SS/AT1R-deficient) or AT2R (SS/AT2R-deficient), and compared them with sickle mice with intact AT1R + AT2R (SS/WT) (Figure 1D). Notably, only the SS/AT1R-deficient mice failed to develop sickle glomerulopathy: absent albuminuria and histopathological findings of FSGS and lack of increased TGFβ1-Smad2/3 signaling (Figure 1D, Supporting Information Figure S4e,f). We also generated knock-in-SS/AT1R deficient mice via interbreeding the knock-in-SS mice with AT1R-deficient mice. Knock-in-SS/AT1R-deficient mice also had no albuminuria, unlike the knock-in mice with intact AT1R (Supporting Information Figure S5a). AT2R signaling has been found to be glomerular-protective in other chronic renal injury disease models.4 However, we found that AT signaling via AT2R did not cause sickle glomerulopathy since SS/AT2R-deficient mice developed albuminuria and FSGS similar to SS/WT chimeras (Figure 1D, Supporting Information Figure S4e). Next, we augmented AT2R signaling with C21 (an AT2R agonist) in the context of AT1R blockade. SS mice that were administered C21 with losartan showed no improvement/worsening of albuminuria, as compared to losartan alone. Therefore, neither abrogation nor augmentation of AT2R signaling affected the sickle glomerulopathy (Figure 1E). Taken together, our pharmacological data and genetic models show that increased AT signaling promotes sickle glomerulopathy solely via AT1R. Next, we analyzed how AT affected UCA. As expected, SS mice have significantly impaired UCA from sickling-mediated injury to vasa-recta and resultant loss of osmotic gradient. AT/AT1R signaling is known to increase sodium absorption from proximal tubules, and increase aquaporin expression, to concentrate urine.5 Therefore, it was not surprising that the reduced UCA in SS mice (or SS/WT chimeras) worsened further with AT1R inhibition with losartan/captopril (Figure 1F,G). When SS mice (or SS/WT chimeras) were placed on captopril, however, we observed unusually high mortality from severe dehydration (Figure 1H). Urine osmolality (and urine albumin) in this treatment group could only be measured in the "fittest"/least dehydrated sickle mice when they were additionally given noncaptopril containing water supplementation. The significant increase in mortality from dehydration with captopril (that reduces AT production, thus interrupting AT signaling via both receptors; Supporting Information Figure S1a), but not with losartan (that only blocks AT1R signaling), suggests that AT may be improving UCA through AT2R as well. The anti-inflammatory and antifibrotic effects of AT2R activation have been proposed to be protective in glomerular injury; however its role in maintaining tubular function, specifically UCA, has not been explored. AT2R stimulation causes natriuresis and blood pressure regulation, and its deficiency is associated with severe experimentally-induced acute tubular necrosis.4 We hypothesized that increased AT2R signaling probably compensates for loss of UCA with losartan, which may explain the captopril effect. We therefore determined urine osmolality in SS/AT1R-deficient and SS/AT2R-deficient chimeric mice and compared them to SS/WT chimeras (Figure 1I). As expected, SS/WT mice had significantly lower urine osmolality than WT/WT mice. Both SS/AT1R-deficient and WT/AT1R-deficient mice had significantly lower UCA than their respective control hematopoietic chimeras i.e. SS/WT and WT/WT, highlighting the important role of AT1R in UCA. Moreover, SS/AT1R-deficient chimeras had the lowest UCA, from the dual effect of sickling-mediated hyposthenuria and lack of AT1R→aquaporin signaling. This was not a transplant effect, or an effect restricted to the SS mouse model, as UCA was also reduced in knock-in-SS/AT1R deficient mice (Supporting Information Figure S5b). Urine osmolality in WT/WT versus WT/AT2R-deficient chimeras, however, was similar, suggesting that in healthy mice, AT2R plays no role in maintaining UCA. However, SS/AT2R-deficient mice had significantly lower urine osmolality than SS/WT chimeras demonstrating that AT2R is important in maintaining UCA in SCA, where it is likely recruited because the normal urine concentrating mechanisms are severely compromised (Figure 1I). Indeed, stimulation of AT2R signaling by giving SS mice C21, along with concomitant blockade of AT1R with losartan, improved their UCA to levels seen in control SS mice, showing that the effect of AT1R-deficiency on UCA could be compensated for, by increased AT2R signaling. (Figure 1J). In a diabetic rat model, C21 treatment has been shown to be effective in reducing tubulointerstitial fibrosis.4 Our data of improved UCA in SCA with C21 highlights another important reno-protective role of increased AT2R signaling. Taken together, our data shows that in SCA, AT signaling via both AT1R and AT2R compensates for the sickling-mediated loss of UCA. Notably, ACE-I have been evaluated for their effect on albuminuria in patients with SCA, although urine osmolality was not assessed in these trials.6 It is conceivable that ACE-I may worsen UCA in SCA patients, which is either compensated for with increased water consumption and worsened enuresis/nocturia, or it results in dehydration (and consequently predisposes SCA patients to increased vaso-occlusion). In a recent Phase-II losartan study published by our group, losartan tended to lower urine osmolality in SCA patients with macro-albuminuria, although the difference was not statistically significant. Future studies should carefully assess UCA while addressing improvement in sickle glomerulopathy with AT blockade. In conclusion, we show that the hyperangiotensinemia in SCA plays a protective role in preserving UCA in face of SCA-associated hyposthenuria, via both AT1R and AT2R signaling. However, the chronically increased AT1R signaling promotes glomerular pathology. Our data also reveals a novel reno-protective role of AT-AT2R signaling in promoting UCA in SCA. While worsened AT1R-induced hyposthenuria can compromise the quality of life of patients with SCA from nocturia/enuresis, it can be compensated by increased fluid intake. Sickle glomerulopathy, on the other hand, is an organ pathology that is important to prevent, as it leads to progressive albuminuria, FSGS and ESRD. Our study suggests that targeted blockade of AT1R along with agonism of AT2R signaling could preserve UCA and prevent sickle glomerulopathy. Materials and methods (are available as supplemental material). This study was supported by research funding from NIH-NHLBI R34 HL 108752 (PM) and the Excellence in Hemoglobinopathy Research Award (EHRA), U01HL117709 (PM). PR was the Translational Research Scholar on the EHRA U01HL117709. We would like to thank Dr. Charles Quinn for his helpful review and comments on the manuscript. SR performed the experiments, analyzed, plotted and interpreted the data, PR and MSEMM plotted and interpreted the data, KHC and JAC performed and interpreted the angiotensin assays, SKS and KV analyzed histopathology, TI generated the AT2R-/- mice, BA and JAC had intellectual discussions on the project with PM, PM conceived the project and designed the experiments and interpreted the data, SR, PR, MSEMM and PM wrote the manuscript, all authors reviewed and edited the manuscript. The authors have no conflicts of interest. Additional Supporting Information may be found online in the supporting information tab for this article. Supplemental Figures 1 Supplemental Figures 2 Supplemental Figures 3 Supplemental Figures 4 Supplemental Figures 5 Supplemental Figures 6 Supplemental Methods Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. 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Abstract. Since the kidney is one of the major sites of action for atrial natriuretic peptide (ANP) and immunoreactive ANP has been detected in tissue extract by radioimmunoassay, we have applied the immunohistochemical technique by using the avidin-biotin complex method to investigate ANP binding sites in the rat kidney. Although no immunostaining was observed in the kidney of control rats, immunoreactive ANP was present in the juxtaglomerular cells, the vascular walls of interlobular arteries, arcuate arteries, arterioles including vas afferens and vas efferens, and the medullary peritubular capillary of ANP-pretreated rats. In contrast, no tubular structure was stained. These results suggest that ANP may affect renin secretion via its direct action on the juxtaglomerular cells and that it predominantly induces natriuresis by its effects on renal hemodynamics.
