Tulane University School of Medicine, Department of Physiology, New Orleans, Louisiana 70112
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ABSTRACT |
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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-[14C]citrulline from L-[14C]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 Ca2+-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, Ca2+-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 Ca2+-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 Ca2+-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.
endothelial nitric oxide synthase; neuronal nitric oxide synthase; inducible nitric oxide synthase; osmotic minipump; angiotensin II-induced hypertension; Western blot
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INTRODUCTION |
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LONG-TERM ADMINISTRATION of initially subpressor doses of angiotensin II (ANG II) elicits a progressive increase in arterial pressure after several days with a pressure profile and degree of hypertension similar to that observed in the two-kidney, one-clip (2K1C) Goldblatt hypertensive rat (7, 24, 25, 29). In these experimental models of hypertension, the renal vasoconstriction elicited by ANG II is partially attenuated by counteracting vasodilator factors (7, 21, 24). In support, we have previously demonstrated an enhanced influence of nitric oxide (NO) on the cortical circulation to maintain adequate renal blood flow (RBF) and glomerular filtration rate (GFR) in ANG II-induced hypertension (7). These observations indicate that NO serves as a major endogenous compensatory vasodilator system by its counteracting influence on the heightened ANG II-specific vasoconstrictor actions mediating the hypertensive state.
The differences in the regional blood flow responses to NO synthase (NOS) inhibition in control and hypertensive rats suggested that a differential regulation of intrarenal NOS activity accounts for differences between the cortical and medullary blood flow responses in the ANG II-infused hypertensive rats and the normotensive controls. In the ANG II-infused hypertensive rats, the progressive increases in arterial pressure and/or ANG II levels could lead to a greater endothelial shear stress to induce elevations in intracellular calcium and activate the Ca2+-dependent NOS activity (6, 9, 10, 18, 19, 28). Consequently, increased NO synthesis could partially counteract the ANG II-mediated renal cortical vasoconstrictor actions and allow preservation of renal hemodynamics. In line with this postulate, recent studies demonstrated that total kidney endothelial NOS protein, a calcium-dependent isoform, was significantly increased by 90% during chronic infusion of subpressor doses of ANG II for 10 days after pretreatment with converting enzyme inhibitors (9). These data suggest that ANG II may chronically increase NO synthesis by upregulating endothelial NOS protein and activity, but it was not determined whether this effect occurred primarily in the cortex or the medulla. Other studies (16, 22) have recently demonstrated that NO production is upregulated during the early phase (age 8-12 wk) in the spontaneously hypertensive rat (SHR), a genetic model of hypertension. The SHR showed significant increases in renal tissue endothelial and inducible NOS proteins compared with that in the Wistar-Kyoto (WKY) rats, thereby excluding the possibility of an impairment in the NO pathway contributing to the early phase of hypertension in SHR (22). Similarly, Nava et al. (16) reported that the Ca2+-independent NOS activity was greater in the renal cortex of SHR compared with the WKY rats.
To obtain more direct evidence for an altered differential regulation of NOS activity in the renal circulation, we performed further studies measuring the NOS enzyme activities and protein levels of the different NOS isoforms in the cortical and medullary regions in control and ANG II-infused hypertensive rats. Therefore, the objective of this study was to determine the NOS activities in the renal cortex and medulla of normotensive and ANG II-infused hypertensive rats by measuring the rate of formation of radiolabeled L-[14C]citrulline from L-[14C]arginine in renal tissues harvested from these rats. Additional experiments were performed to characterize the regional expression of endothelial (eNOS), neuronal (nNOS) and inducible (iNOS) NOS isoforms by Western blot analysis.
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METHODS |
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Male Sprague-Dawley rats (Charles River Laboratories, Wilmington, MA) were acclimatized in a temperature- and light-controlled room and allowed access to standard rat chow (Ralston-Purina, St. Louis, MO) and water ad libitum. The rats were randomly divided into control (n = 8; n = 5) and ANG II-infused (n = 8; n = 5) groups for the determination of NOS enzyme activity and protein levels by Western blot analysis, respectively. Preliminary surgery was performed in rats (200-220 g) anesthetized with pentobarbital sodium (50 mg/kg ip) to implant minipumps. In one group of rats, synthetic ANG II (Sigma Chemical, St. Louis, MO) was delivered continuously at a rate of 65 ng/min via osmotic minipumps (model 2002; Alza, Palo Alto, CA) implanted subcutaneously at the dorsum of the neck. A sham operation was performed on the normotensive control rats. Systolic arterial pressures were measured by tail-cuff plethysmography (Harvard Apparatus, South Natick, MA) before and on the 12th day after implantation of minipumps.
Experiments were performed on the 13th day after implantation of minipumps or sham operation to determine the enzyme activity and protein levels in the cortical and medullary regions of the kidney. Rats were anesthetized with pentobarbital sodium (50 mg/kg ip) and placed on a thermoregulated surgical table to maintain body temperature at 37°C. The abdominal cavity was exposed via a midline incision. Both kidneys were removed and sectioned sagittally, facilitating separation of the medulla from the cortex for analysis of NOS activity and protein levels by Western blot analysis. The dissected samples were placed on a weighing paper over dry ice. Frozen tissues were directly homogenized manually in a homogenization buffer in volumes three times the weight of the tissues. The homogenization buffer containing 320 mM sucrose, 50 mM Tris base, 0.1 mM EDTA, 1 mM dithiothreitol, 10 µg/ml leupeptin, 10 µg/ml soybean trypsin inhibitor, and 2 µg/ml aprotinin was adjusted to pH 7.0 with HCl before addition of 10 mg/ml of phenylmethylsulfonyl fluoride (PMSF) (15, 16, 20). The crude homogenates were then centrifuged at 14,000 g for 40 min at 4°C. The supernatants were analyzed for determination of NOS activity.
NOS activity assay. NOS activity was
determined by measuring the rate of formation of radiolabeled
L-[14C]citrulline
from
L-[14C]arginine
(50 µCi/ml with specific activity of 303 mCi/mmol, Amersham Life
Science) as modified from previously described methods (15, 16, 20).
Tissue extracts contained in 20 µl of supernatant were incubated in a
total volume of 100 µl of assay buffer containing 50 mM potassium
dihydrogen phosphate, 1 mM magnesium chloride, 2 mM calcium chloride,
and 1 mM NADPH at pH 7.0, with 22 µM
L-arginine and 3 µM
radiolabeled
L-[14C]arginine.
Duplicate samples were incubated for 1 h at 37°C without any
inhibitors, with addition of EGTA (4 mM), and with addition of EGTA
plus
N-nitro-L-arginine
methyl ester (L-NAME, 5 mM) to
determine the levels of
Ca2+-dependent and
Ca2+-independent NOS activities,
respectively. The reactions were terminated with the addition of 1.5 ml
of a 1:1 suspension of Dowex 50W
(Na+ form, Sigma Chemical) in
water to bind and remove the remaining L-arginine. The
Na+ form of Dowex 50W was prepared
by washing the H+ form of the
resin with 1 N NaOH in approximately equal proportions for
four washes and then washing with distilled water until the pH was
below 7.4. The efficiency of the resin in capturing
L-arginine was greater than 99%
of the total activity in the assay buffer. The above mixture was then
centrifuged before and after the extraction procedure. Five milliliters
of distilled water was added to all samples for extraction, and the
suspension was allowed to precipitate for 20 min at room temperature. A
4-ml aliquot of the supernatant containing radiolabeled
L-[14C]citrulline
was mixed with 10 ml of scintillation fluid to quantitate the
radioactivity by a Beckman LS-9000 counter. The
Ca2+-dependent NOS activity was
calculated as the difference between the amount of
L-[14C]citrulline
formed in control tubes and the amount formed in the tubes incubated
with EGTA. The Ca2+-independent
NOS activity was calculated as the difference between the amount of
L-[14C]citrulline
formed in tubes incubated with EGTA alone and the amount formed in the
tubes incubated with EGTA plus
L-NAME (20). NOS enzyme activity
level was expressed as picomoles of
L-[14C]citrulline
formed per minute per gram wet kidney weight.
Measurement of NOS activity based on the conversion of L-arginine to L-citrulline is currently the standard assay to characterize NO formation in both crude and purified enzyme preparations. The specificity of this assay for the NOS enzymatic pathway is due mainly to the direct enzymatic conversion of L-arginine to L-citrulline, which is stoichiometric with the formation of NO in eukaryotic cells. However, biological tissues contain variable amounts of endogenous levels of L-arginine substrate as well as additional metabolic pathways that can compete for the substrate and independently form the L-citrulline product (15). It is therefore important, as presented in this study, to define the EGTA + L-NAME-inhibitable formation of L-citrulline to characterize the NOS-specific activity. In addition, the presence of endogenous levels of L-arginine in the tissue homogenates could lead to the dilution of the radiolabeled substrate with reduced formation of L-[14C]citrulline, resulting in an underestimate of NOS activity as previously suggested (15). In the present study, nonlabeled L-arginine was added to buffer the influence of regional differences in the amount of endogenous levels of L-arginine.
Western blot analysis. For Western
blot analysis, frozen tissues were homogenized with the Polytron in
RIPA buffer containing 20 mM Tris · HCl, pH 7.4, 150 mM NaCl, 0.5% sodium deoxycholate, 1% Igepal, and 0.1%
Triton X-100 in volumes two times the tissue weight with
the additions of 30 µl/g of 10 mg/ml PMSF and 10 µl/ml of
100 mM sodium orthovanadate, according to Brugge and Erikson (from
1977) with modifications (5, 17). The homogenates were centrifuged at 100,000 g for 1 h at
4°C. The protein concentration of the supernatant was determined
with the Bio-Rad protein assay kit (Bio-Rad, Hercules, CA). Kidney
tissue samples (160 µg of protein for the cortex and 100 µg for the
medulla) were electrophoretically size-fractionated on 6%
polyacrylamide Tris-glycine precast gel (Novex, San Diego, CA) at 125 V
for 90-120 min. High-range molecular weight marker proteins were
myosin (205 kDa), -galactosidase (121 kDa), bovine serum albumin (74 kDa), and ovalbumin (47 kDa, Bio-Rad). After electrophoresis, the
proteins were transferred to Immun-Blot polyvinylidene
difluoride membrane (Bio-Rad) at 25 V for 2 h. The membranes were then
incubated with polyclonal rabbit anti-NOS antibodies (Santa Cruz
Biotechnology, San Diego, CA) in Tris-buffered saline containing 0.1%
Tween-20 and 5% nonfat dry milk overnight at 4°C. Polyclonal
antibodies for eNOS, nNOS, and iNOS were diluted to 1:200 for the renal
cortical protein samples and 1:500 for the medullary samples. The
membranes were washed for 30 min, with the wash buffer changed every 10 min before incubation with the horseradish peroxidase-labeled goat
anti-rabbit IgG (1:1,000) and 5% nonfat dry milk in Tris-buffered
saline for 2 h at 4°C. The washes were again repeated for 30 min
before the membrane was detected for the bound antibody by
chemiluminescence using the ECL detection reagents (Amersham,
Piscataway, NJ) on X-ray film (Hyperfilm-ECL; Amersham). The films were
scanned with the densitometer (Alpha Innotech, San Leandro, CA) to
determine the integrated density values. When the control values were
detectable, the data were normalized to the densitometric ratio of the
average control value.
Statistical analysis. Data are expressed as means ± SE. Student's unpaired t-test was performed to determine statistical differences between two separate groups. Statistical significance was defined as P < 0.05 or exceeding the 95% critical value.
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RESULTS |
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Before implantation of osmotic minipumps, systolic blood pressure (SBP)
values in the conscious rats were not statistically different between
the groups, averaging 125 ± 3 and 126 ± 4 mmHg in control
(n = 13) and ANG II-infused rats
(n = 13), respectively. In accordance
with previous studies (7, 24, 25, 29), ANG II-infused rats exhibited
progressive increases in SBP over the course of a 12-day period. As
shown in Fig. 1, SBP in ANG II-infused rats
increased from a control value of 126 ± 4 to 182 ± 3 mmHg by
day 12. In control rats, SBP remained
relatively unchanged at 127 ± 2 mmHg. The body weights of the rats
averaged 295 ± 6 g in the ANG II-infused hypertensive rats and 305 ± 5 g in the normotensive controls.
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Comparison of the average data for the activity representing absolute
amount of L-citrulline
formed revealed that in the presence of EGTA plus
L-NAME when presumably all of
the NOS-dependent
L-citrulline formation
was blocked, there was much higher NOS-independent formation of
L-citrulline in the
cortex than in the medulla for both groups, averaging 142 ± 14 vs.
5 ± 2 pmol · min1 · g
1,
respectively, in the control rats and 90 ± 8 vs. 1 ± 0.9 pmol · min
1 · g
1
in the ANG II-infused rats. The conversion of
L-arginine to
L-citrulline in the
presence of EGTA plus L-NAME
provides evidence of additional metabolic pathways other than the NOS
enzymatic pathway for the synthesis of
L-citrulline from
L-arginine in renal cortical tissue.
The NOS activity was expressed as picomoles of radiolabeled
L-[14C]citrulline
formation per minute per gram wet kidney weight. The
Ca2+-dependent NOS activity was
increased by about twofold in the renal cortex of ANG II-infused rats
(91 ± 11 pmol · min1 · g
1)
compared with normotensive controls, which averaged 42 ± 12 pmol · min
1 · g
1
(Fig. 2). This was accompanied by a marked
increase in the renal cortical eNOS protein as well as in the nNOS
protein levels in the ANG II-infused rats compared with normotensive
controls (Figs. 3 and 4). Cortical nNOS
protein level was substantially increased by 73% in the ANG II-infused
hypertensive rats compared with the control rats (Fig.
4). Representative Western blots of eNOS
(140 kDa) and nNOS (150 kDa) are shown in the
top of Figs. 3 and 4, respectively.
Barely detectable signals for the eNOS protein were observed in the
renal cortex of normotensive controls, but marked induction was
observed in the ANG II-infused rats.
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In both groups, the Ca2+-dependent
NOS activity was significantly greater in the renal medulla than in the
cortex, averaging 516 ± 110 and 510 ± 78 pmol · min1 · g
1
in control and ANG II-infused rats, respectively (Fig. 2). No differences in the Ca2+-dependent
NOS activity were observed in the renal medulla between the groups.
Likewise, eNOS protein levels in the renal medulla did not differ
between the groups (Fig. 3). However, medullary nNOS protein levels
were decreased by 45% in the ANG II-treated rats compared with the
controls (Fig. 4). These data are in accordance with previous studies
in which the medullary tissue has been reported to have about a 10-fold
higher NOS activity compared with that in the cortex in normotensive
controls (15).
For the Ca2+-independent NOS
activities (Fig. 5), the trend was
reversed, with the renal cortex exhibiting a greater activity in the
control rats (174 ± 23 pmol · min1 · g
1)
than in ANG II-infused rats (101 ± 10 pmol · min
1 · g
1).
Similarly, iNOS protein levels were diminished by 47% in the renal
cortex of the ANG II-infused rats compared with control rats (Fig.
6). A representative Western blot of the
iNOS (130 kDa) is shown in the top of
Fig. 6. In the medulla,
Ca2+-independent NOS activity was
much lower than the Ca2+-dependent
NOS activity; and no differences in the
Ca2+-independent NOS activity were
observed between the control rats (24 ± 5 pmol · min
1 · g
1)
and the ANG II-infused rats (28 ± 8 pmol · min
1 · g
1).
In agreement, we did not detect iNOS protein in the renal medulla in
either the control or the ANG II-treated rats.
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DISCUSSION |
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The present study provides evidence of an altered differential regulation of NOS activity and protein levels in the kidneys of ANG II-infused hypertensive rats compared with normotensive controls. In normotensive rats, the Ca2+-dependent NOS activity level was considerably higher in the renal medulla than in the cortex. Likewise, the relative level of eNOS protein was higher in the renal medulla than in the cortex. These results indicate that the renal medulla has substantially greater capacity to generate NO via a Ca2+-dependent NOS mechanism. In accordance with our results, Moridani and Kline (15) recently demonstrated that the renal medulla had about a 10-fold higher NOS activity compared with that in the cortex. Moreover, Nava et al. (16) showed that the renal medulla had a much higher Ca2+-dependent NOS activity than the cortex in control rats. Similarly, biochemical studies by Biondi and Romero (4) indicate that the renal medulla has a greater potential for the NO-dependent formation of cGMP than does the renal cortex in basal and stimulated conditions with acetylcholine. Furthermore, these observations are consistent with our whole kidney studies in which acute systemic inhibition of NO synthesis led to a greater relative decrease in medullary blood flow than in cortical blood flow in control rats (7). Collectively, these data indicate that NO exerts a greater modulatory influence on the medullary than on the cortical circulation in normotensive control rats.
To obtain further insight regarding the regulation of NOS activity in the early phase of hypertension, we examined the differential regulation of Ca2+-dependent and Ca2+-independent NOS activities and protein levels of the different NOS isoforms in the kidneys of ANG II-infused hypertensive rats. As previously reported, chronic infusion of initially subpressor doses of ANG II over the course of 13 days leads to a slowly developing hypertension resembling the early phase of 2K1C Goldblatt renovascular hypertension (7, 24, 25, 29). In these models of hypertension, RBF and GFR are either within the normal range or only slightly diminished, despite elevated blood pressure and circulating ANG II levels (21, 24, 25). Previous data have suggested that the renal vasoconstriction elicited by elevated intrarenal ANG II levels is partially counteracted by enhanced activity of vasodilator factors. We have previously demonstrated that one of these factors is an increased NO synthesis during the early phase of ANG II-induced hypertension (7). Acute systemic inhibition of NO synthesis led to greater increases in arterial pressure in the ANG II-infused hypertensive rats compared with the normotensive controls. Despite the greater increases in blood pressure, cortical blood flow and total RBF were concomitantly reduced to a greater extent in the hypertensive rats than in the controls. These results are consistent with the hypothesis that a compensatory increase in NOS activity counteracts the vasoconstrictor influences of elevated circulating and intrarenal ANG II levels to sustain renal hemodynamics. In accordance with these functional observations, the increased Ca2+-dependent NOS enzyme activity as well as elevated protein expression of eNOS and nNOS in the cortical tissue provide further evidence of an upregulation of renal Ca2+-dependent NOS activity in the renal cortex of ANG II-infused hypertensive rats.
Although the Ca2+-dependent NOS
activities were higher in the renal medulla than in the cortex, there
were no differences between the control and hypertensive rats.
Likewise, medullary eNOS protein levels were not different and nNOS
protein levels were actually reduced in the ANG II-infused rats
compared with control rats. Furthermore, the renal medulla has
substantial potential to synthesize NO, but its overall contribution to
the total amount of NO formation is limited due to the much greater
cortical mass. An enhanced production of NO in the cortical region of
the kidney could explain the greater renal vasoconstrictor responses
observed with pharmacological inhibitors of NOS. These observations are
in accordance with our previous study (7) in which
N-nitro-L-arginine
(NLA), an inhibitor of NO synthesis, led to a greater decrease in
cortical blood flow, which represents the major fraction of total RBF,
in the ANG II-infused hypertensive rats compared with normotensive controls.
The present results support previous findings that the medullary blood flow responses to NLA were less in the ANG II-infused hypertensive rats than in the normotensive controls. The mechanisms responsible for a differential regulation of NOS activity in the medullary circulation remain unclear. It is possible that the greater increases in arterial pressure concomitantly blunted the NLA-induced decreases in medullary blood flow to a greater extent in the ANG II-infused rats, thereby masking the actual level of NOS activity. In support, eNOS protein levels in the medulla did not differ between the groups. The present finding of the decreased expression of nNOS in the renal medulla of ANG II-infused rats is consistent with recent studies performed by Ichihara et al. (11) regarding the differential effect of nNOS inhibition in the juxtamedullary microvasculature of control and ANG II-infused hypertensive rats. Superfusion with the specific nNOS inhibitor, S-methyl-L-thiocitrulline, under conditions of enhanced flow to the loop of Henle, led to greater afferent arteriolar constriction in controls than in ANG II-infused hypertensive rats (11). Previous studies have demonstrated that the most abundant NOS identified in the kidney is the nNOS specifically found in the macula densa cells, glomeruli, renal vasculature, collecting duct, and inner medullary thin limb and that the detection of eNOS has been more difficult (2, 3). It is possible that our failure to detect the low-level constitutive eNOS expression in the renal cortex of control rats is due to the limited sensitivity of the Western blotting technique.
With regard to the
Ca2+-independent NOS activities,
the trend was reversed, with the renal cortex exhibiting a greater
activity in the control rats than in ANG II-infused hypertensive rats. Likewise, the iNOS protein expression was greater in the renal cortex
of normotensive controls than in the ANG II-treated group. Moreover, no
differences were observed in the renal medulla between the groups. We
were not able to detect even low-level iNOS expression in the renal
medulla. Our results for the
Ca2+-independent NOS activity in
the renal medulla are similar to previous studies performed in SHR and
WKY rats with values averaging 40 ± 13 and 40 ± 12 pmol · min1 · g
1,
respectively (16). Using reverse transcription-polymerase chain
reaction, the presence of inducible NOS mRNA expression was
demonstrated in the arcuate and interlobular arteries, glomeruli, and
proximal tubules, which are primarily localized in the renal cortex, as
well as in the thick ascending limbs and collecting ducts (1, 14). The
constitutive expression of this particular NOS isoform indicates its
contributory role in the normal homeostatic regulation of the kidney
apart from its role induced during pathological states (12). Mattson et
al. (13) demonstrated that acute systemic infusion of aminoguanidine, a
selective inhibitor of iNOS enzyme, to anesthetized rats significantly
decreased urine flow in the absence of any alterations in blood
pressure or renal cortical blood flow, suggesting that iNOS may
participate in the homeostatic regulation of the kidney possibly via
its renal tubular effects.
It is not clear why the
Ca2+-independent NOS activity was
reduced in the renal cortex of ANG II-induced hypertensive rats.
Previous studies have demonstrated that the vascular smooth muscle iNOS activity is depressed in SHR compared with cultured cells derived from
WKY rats (8). Presumably, the downregulation of iNOS expression under
such conditions of elevated ANG II levels could result from the
stimulated production of cytokines, growth factors, or hormones. In
line with this observation, studies have demonstrated that ANG II
stimulates the expression of transforming growth factor- (TGF-
)
in cultured renal cells (27). Moreover, glomerular TGF-
1 mRNA
expression was shown to be upregulated in the nonclipped kidneys of
2K1C hypertensive rats compared with control kidneys (26).
In terms of its role in inducing iNOS expression, TGF-
1 appears to
negatively modulate renal iNOS expression in vivo. These findings are
supported by recent studies in the TGF-
1 knockout mice that exhibit
increased levels of iNOS expression in the kidney (23). Accordingly, it
is possible that ANG II may facilitate the ability of TGF-
to
counteract the vascular trophic effects of ANG II by downregulating the
Ca2+-independent iNOS expression
in the early phase of ANG II-induced hypertension. Thus the nonimmune
regulation of the constitutive Ca2+-independent iNOS could be one
mechanism to counteract the vascular growth-promoting action of
elevated intrarenal ANG II levels in the renal circulation.
In conclusion, these data indicate that there is a differential distribution of NOS activity in the kidney, with the Ca2+-dependent activity and protein expression higher in the renal cortex of ANG II-infused rats compared with control rats. These findings exclude the possibility of NO deficiency as a primary contributor to ANG II-induced hypertension and further support the hypothesis that enhanced constitutive NOS activity exerts a protective effect during the early phases of ANG II-induced hypertension to maintain adequate renal cortical blood flow and partially compensate for the hypertensinogenic and vasoconstrictive effects of elevated ANG II levels.
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ACKNOWLEDGEMENTS |
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We thank Dr. Edwin Rabon, Natalia Louneva, Sam Rulli, Hector Licea Vargas, Ginny Primrose, Dr. Su-Teh Li, and Dr. Lisa Harrison-Bernard for technical assistance.
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FOOTNOTES |
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This study was supported by National Heart, Lung, and Blood Institute Grant HL-26371. S. Y. Chin is a predoctoral fellow supported by the Louisiana Board of Regents Educational Quality Support Fund. C. Moreno is a predoctoral fellow in the Department of Physiology of the University of Murcia, Spain, who was a visiting graduate student at Tulane.
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: L. G. Navar, Tulane Univ. School of Medicine, Dept. of Physiology SL39, 1430 Tulane Ave., New Orleans, LA 70112 (E-mail: Navar{at}mailhost.TCS.Tulane.edu).
Received 31 December 1998; accepted in final form 30 June 1999.
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