Vascular Biology Center, Departments of Surgery, Physiology, and Pharmacology and Toxicology, Medical College of Georgia, Augusta, Georgia 30912-2500
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ABSTRACT |
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Recent evidence suggests that endothelin-1 (ET-1), perhaps
through the ETB receptor, may participate in blood pressure
regulation through the control of sodium excretion. Mean arterial
pressure (MAP) was continuously measured via telemetry implants in male Sprague-Dawley rats. After 1 wk of baseline measurements, rats were given either high (10%) or low (0.08%) NaCl in chow for the remainder of the experiment (n = 5 in each group). MAP
was significantly increased in rats on a high-salt diet (115 ± 2 mmHg) compared with rats on the low-salt diet (103 ± 2 mmHg;
P < 0.05). All rats were then treated with the
ETB receptor antagonist A-192621 mixed with the food and
adjusted daily to ensure a dose of 30 mg · kg1 · day
1.
ETB blockade produced an increase in MAP within a few hours of treatment and was significantly higher in rats on the high-salt diet
over a 1-wk period (170 ± 3 vs. 115 ± 3 mmHg,
P < 0.01). To determine whether the increase in MAP
during A-192621 treatment was due to increased ETA receptor
activation, all rats were then given the ETA-selective
antagonist ABT-627 in the drinking water while a low-salt/high-salt
diet and ETB blockade were continued. ABT-627 decreased MAP
within a few hours in rats on either the high-salt (113 ± 3 mmHg)
or low-salt (101 ± 3 mmHg) diet. These results support the
hypothesis that endothelin, through the ETB receptor,
participates in blood pressure regulation in the response to salt loading.
blood pressure; hypertension; water-electrolyte balance
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INTRODUCTION |
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ENDOTHELIN-1 (ET-1) has been described as the most powerful vasoconstrictor yet discovered. Administration of exogenous ET-1 results in a transient vasodilation mediated by ETB receptors and a sustained vasoconstriction produced primarily through ETA receptors (20). Despite the predominance of ETA actions in this setting, physiological regulation of ET-1 action may be more dependent upon ETB receptor function (18). The ETB receptor has several distinct functions that may play a role in arterial pressure regulation (2, 12). First, there is evidence that ETB receptors bind and remove ET-1 from the circulation and thus minimize ETA receptor activation (4). Second, ETB receptors on vascular endothelium release nitric oxide and prostaglandins to produce vasodilation in numerous vascular beds including the renal medullary circulation (3, 6). ETB receptors are also located on other cell types and are in particular abundance on tubular epithelium of the renal medulla (8). ET-1 has been shown to inhibit reabsorption of sodium and water in vitro, effects that are mediated by the ETB receptor (11). We have recently observed that ETB receptors are upregulated in the kidneys of deoxycorticosterone acetate (DOCA)-salt hypertensive rats (13). These observations led us to hypothesize that the ETB receptor may play a role in the regulation of arterial pressure, and its actions may be influenced by sodium intake.
Experiments were conducted to determine whether the magnitude of the hypertension produced by chronic ETB receptor blockade was influenced by salt intake. Arterial pressure was measured in conscious rats by radiotelemetry before and during administration of the ETB receptor-selective antagonist A-192621 for 1 wk.
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METHODS |
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Telemetry blood pressure measurements. Telemetry transmitters (Data Sciences, St. Paul, MN) were implanted according to manufacturer's specifications into male Sprague-Dawley rats (200-220 g; Harlan Laboratories, Indianapolis, IN) while under Na pentobarbital anesthesia (65 mg/kg ip; Abbott Laboratories, North Chicago, IL). In brief, a midline incision was used to expose the abdominal aorta that was briefly occluded to allow insertion of the transmitter catheter. The catheter was secured in place with tissue glue. The transmitter body was sutured to the abdominal wall along the incision line as the incision was closed. The skin was closed with staples that were removed 7-10 days later after the incision was healed. Rats were allowed to recover from surgery and returned to individual housing for at least 1 wk prior to data acquisition was initiated. The individual rat cages were placed on top of the telemetry receivers, and arterial pressure waveforms were continuously recorded throughout the study except on days where rats were placed in metabolic cages (see below).
Protocol.
All rats were given free access to regular rat chow (0.8% NaCl) during
a 1-wk baseline period. Rats were then given chow containing either low
(0.08%) or high (10%) NaCl along with tap water ad libitum. After 1 wk on either low or high NaCl, all rats were given the ETB
receptor antagonist A-192621 (19) at a dose of 30 mg · kg1 · day
1 in the
food. The concentration of antagonist in the food was adjusted daily to
maintain proper dosage. Following 1 wk of treatment with A-192621, all
rats were then given the ETA receptor antagonist ABT-627
(21) in drinking water at a concentration to deliver a
dose of 5 mg · kg
1 · day
1.
This treatment was continued for 1 wk. On the last day of each week,
rats were placed in metabolic cages to monitor food and water intake as
well as excretory variables.
Assays and chemicals. Urine concentrations of sodium were determined by ion-selective electrodes (Beckman EL-ISE), and sodium and water balance were calculated as the difference between intake and excretion. Urinary ET-1 concentrations were measured by radioimmunoassay (Amersham Pharmacia Biotech, Arlington Heights, IL). All normal and special NaCl content rat chow was obtained from Harlan Teklad (Madison, WI). A-192621 and ABT-627 were supplied courtesy of Dr. Jerry Wessale of Abbott Laboratories. Amiloride was obtained from Sigma Chemical (St. Louis, MO).
Statistical analysis. ANOVA for repeated measures combined with post hoc tests was used for statistical evaluation of mean values each week. Student's t-test for unpaired data was used to determine statistical differences between means at any given time period between the first two groups of rats. Values are reported as means ± SE with P < 0.05 being considered significant; n = 5 in all groups.
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RESULTS |
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During baseline periods while being given normal rat chow, rats
displayed a typical diurnal variation in arterial pressure (Fig.
1). The overall average mean arterial
pressure (MAP) for the entire week was 105 ± 2 mmHg in all rats
while on normal NaCl intake. Placing rats on a high-NaCl diet
significantly increased arterial pressure, whereas the low-NaCl diet
had no effect. The weekly average MAP was 103 ± 2 mmHg for rats
on low-NaCl and 115 ± 2 mmHg for rats on a high-NaCl diet
(P < 0.05). Heart rate remained unchanged by
alterations in NaCl intake.
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Treatment with the ETB-selective antagonist A-192621 (30 mg · kg1 · day
1)
significantly increased arterial pressure in all rats, although the
increase in rats on a high-NaCl diet was much larger than those on a
low-NaCl diet (Fig. 1). ETB blockade lowered heart rate and
eliminated the normal diurnal variation in rats on a high-NaCl
diet but not when on a low- NaCl diet. During the final week of
study, rats were given the ETA-selective antagonist ABT-627 (5 mg · kg
1 · day
1), which
lowered the arterial pressure to levels similar to that prior to
A-192621 treatment.
As expected, food and water consumption were greater in rats on a
high-NaCl diet, although this difference was not significant during the
week when rats were given A-192621 alone (Fig.
2). Sodium excretion and urine volume
were significantly elevated in rats on the high-Na diet compared with
baseline periods while they were on normal rat chow (Fig. 2). Sodium
excretion decreased below detectable levels in rats on the low-NaCl
diet. A-192621 had no significant effect on water intake, sodium
excretion, or urine volume, regardless of NaCl intake. Similarly,
ETA receptor blockade produced no further significant
changes in these variables.
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Figure 3 shows that urinary ET-1
excretion was significantly increased when rats were placed on a
high-Na diet compared with rats given low-Na chow. In contrast to what
has been reported for plasma ET-1 (19), treatment with the
ETB receptor antagonist had no effect on urinary ET-1
excretion, regardless of Na intake. Furthermore, additional
ETA receptor blockade had no effect on urinary ET-1
excretion.
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The next series of rats was first given a high-Na diet followed by
treatment with A-192621 at the higher dose (30 mg · kg1 · day
1). To
determine whether the hypertension could be reversed by inhibition of
epithelial Na channels, rats were given the diuretic amiloride (3 mg · kg
1 · day
1) during the
final week. Amiloride was unable to reduce arterial pressure in rats
made hypertensive by chronic ETB receptor blockade (Fig.
4).
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An additional series of rats was studied to determine the effect of a
lower dose of ETB antagonist in rats on high-NaCl chow (Fig. 5). Similar to results with a
higher dose, A-192621 significantly increased arterial pressure and
depressed heart rate. Subsequent treatment with the
ETA-selective antagonist, ABT-627, reversed these effects.
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Another series of rats served as time controls in that they were given a high-NaCl diet from the second week on, but no other treatments. Again, there was a small, but significant increase in arterial pressure in rats on the high-NaCl diet that remained elevated for the duration of the experiment (data not shown). The average MAP for the initial week was 98 ± 2 mmHg, which was significantly increased to 108 ± 3, 109 ± 3, and 110 ± 2 mmHg for the remaining 3 wk while animals were on the high-NaCl diet.
A final series of rats was studied to examine the reversibility of
ETB antagonist-induced hypertension. In rats on a high NaCl
intake, A-192621 produced a sustained hypertension as in previous
groups (Fig. 6). Although it took
3-4 days, arterial pressure did return to baseline after A-192621
treatment was discontinued.
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DISCUSSION |
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Our laboratory has recently provided evidence that the ETB receptor is upregulated in a model of high-salt hypertension, the DOCA-salt-treated rat (13). This model is characterized by elevated endothelin synthesis and ETA-dependent hypertension (1, 9, 10, 16). Furthermore, blockade of the ETB receptor in the DOCA-salt hypertensive rat exacerbated the hypertension (13). The current study extends these initial findings to explore the role of the ET-1 in normotensive rats on either a high- or low-salt diet. We observed that chronic ETB receptor blockade increases arterial pressure in normal rats and that this hypertension was much greater in rats on a high-salt diet compared with a low-salt diet. The increase in arterial pressure during ETB blockade was much larger than that predicted solely from the elevated salt intake such that there was a significant shift in the pressure-natriuresis relationship. These findings provide strong evidence that ET-1 plays a role in regulating arterial pressure during conditions of high salt intake. Further support for this hypothesis is demonstrated by the observation that renal ET-1 production, as assessed by urinary ET-1 excretion, was increased during high salt intake. Similar conclusions are consistent with our recent findings in the DOCA-salt hypertensive rat (13).
The ETB receptor appears to function in a variety of ways. ETB receptors located on renal tubular epithelium may function to inhibit sodium and water reabsorption (7, 17), whereas those located on vascular endothelium mediate vasodilation, which could also contribute to the natriuretic and diuretic actions attributed to ET-1 (6). The ETB receptor also appears to function as a regulator of ET-1 concentrations within the circulation, i.e., as a "clearance" receptor (4). During ETB receptor blockade, circulating levels of ET-1 increase (14, 19), which results in a greater probability of ETA receptor activation. Therefore, we proposed that ETA receptor activation accounts for most, if not all, of the hypertension associated with chronic ETB blockade. Chronic ETA receptor blockade dramatically reduced the hypertension produced by chronic ETB receptor blockade. Since the increase in arterial pressure was greater in rats on a high-salt diet, these findings suggest that a combination of mechanisms account for the hypertension associated with inhibition of the ETB receptor, including both reduced ETB and increased ETA receptor-mediated events.
One of the more interesting findings of the current study is that urinary ET-1 excretion was increased by a high-salt diet and was unaffected by either ETA or ETB receptor antagonism. These findings suggest that renal ET-1 synthesis is elevated in response to salt loading and are consistent with the hypothesis that ET-1 plays an important role within the kidney in the regulation of sodium excretion (12). Furthermore, urinary ET-1 levels did not change in response to ETB blockade, which is in contrast to what has been reported for plasma levels of ET-1 (14, 19). Our data suggest that ETB receptors within the kidney, most likely the tubular system of the renal medulla, do not play a role in the clearance of ET-1 but most likely respond to high salt intake. Reduction of arterial pressure with ETA blockade also had no influence on the response to salt load, indicating that urinary ET-1 excretion is more closely related to salt intake rather than systemic arterial pressure.
Gariepy et al. (5) have recently demonstrated that rats deficient in ETB receptor expression display salt-sensitive hypertension. These findings are somewhat similar to our observations with chronic ETB receptor blockade. These investigators hypothesized that the ETB receptor normally functions as a regulator of renal tubular sodium reabsorption through inhibition of the amiloride-sensitive epithelial sodium channel. They were able to demonstrate that 3 days of amiloride treatment could normalize arterial pressure increases produced by a high-salt diet in the ETB-deficient rats. Although provocative, their studies do not directly address the influence of ETB receptors on Na channel activity. We conducted similar studies by giving amiloride to rats on a high-salt diet and chronic ETB receptor blockade. In contrast to the findings of Gariepy et al. amiloride had no effect on the hypertension produced by chronic ETB receptor blockade. The reasons for these differences in results are not clear. There were minor differences in the protocols, but it is not clear that these differences could account for the different findings. Although the daily dose of amiloride was similar, in the current study the drug was administered in the drinking water, whereas Gariepy et al. used once-a-day intraperitoneal injection. In the later study treated animals with amiloride for only 3 days, whereas our rats were treated for a full week. There was also a minor difference in the sodium content of the high-NaCl diet; i.e., our rats were consuming 10% NaCl, whereas the others received 8% NaCl. Clearly, further investigation is needed to contrast the effects of pharmacological vs. genetic "blockade" of ETB receptors.
The use of radiotelemetry allowed us to observe typical circadian rhythms in arterial pressure. During the hypertension produced by ETB receptor blockade, we observed that the arterial pressure differences between day and night were much greater when the overall MAP was at its highest level. Thus the mechanisms responsible for the normal circadian fluctuations in arterial pressure remain intact and may even be potentiated during ETB receptor blockade. In contrast, heart rate was initially decreased by ETB blockade, and the typical circadian pattern was abolished. Heart rate slowly increased during the period of ETB blockade without any restoration of a circadian pattern. Changes in heart rate may be due to baroreceptor resetting; however, an ETA receptor influence on cardiac contractility cannot be ruled out (15).
In conclusion, our results support an important role for ET-1 and the ETB receptor in the regulation of arterial pressure through the control of salt balance. High salt intake is a consistent stimulus for renal ET-1 production, which appears to shift the balance between ETA and ETB receptor activity. The complex nature of ETB receptor-mediated actions requires further investigation into the mechanism of how ETB receptor activation controls salt handling within the kidney, whether it is via control of renal tubular transport mechanisms, control of intrarenal hemodynamics, or both.
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ACKNOWLEDGEMENTS |
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We thank Hiram Ocasio and Deborah Garner for expert technical assistance. Additional thanks go to Dr. Jerry L. Wessale of Abbott Laboratories for supplying the endothelin antagonists.
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FOOTNOTES |
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These studies were supported by an American Heart Association Scientist Development Grant and by National Heart, Lung, and Blood Institute Grants HL-60653 and HL-34776.
Address for reprint requests and other correspondence: D. M. Pollock, Vascular Biology Center, Medical College of Georgia, 1459 Laney Walker Blvd., Augusta, GA 30912-2500 (E-mail: dpollock{at}mail.mcg.edu).
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. Section 1734 solely to indicate this fact.
Received 7 November 2000; accepted in final form 20 February 2001.
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REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1.
Allcock, GH,
Venema RC,
and
Pollock DM.
ETA receptor blockade attenuates the hypertension but not renal dysfunction in DOCA-salt rats.
Am J Physiol Regulatory Integrative Comp Physiol
275:
R245-R252,
1998
2.
Clozel, M,
and
Breu V.
The role of ETB receptors in normotensive and hypertensive rats as revealed by the non-peptide selective ETB receptor antagonist Ro 46-8443.
FEBS Lett
383:
42-45,
1996[ISI][Medline].
3.
De Nucci, G,
Gryglewski RJ,
Warner TD,
and
Vane JR.
Receptor-mediated release of endothelium-derived relaxing factor and prostacyclin from bovine aortic endothelial cells is coupled.
Proc Natl Acad Sci USA
85:
2334-2338,
1988[Abstract].
4.
Fukuroda, T,
Fukikawa T,
Ozaki S,
Ishikawa K,
Yano M,
and
Nishikibe M.
Clearance of circulating endothelin-1 by ETB receptors in rats.
Biochem Biophys Res Commun
199:
1461-1465,
1994[ISI][Medline].
5.
Gariepy, CE,
Ohuchi T,
Williams SC,
Richardson JA,
and
Yanagisawa M.
Salt-sensitive hypertension in endothelin-B receptor-deficient rats.
J Clin Invest
105:
925-933,
2000
6.
Gurbanov, K,
Rubinstein I,
Hoffman A,
Abassi Z,
Better OS,
and
Winaver J.
Differential regulation of renal regional blood flow by endothelin-1.
Am J Physiol Renal Fluid Electrolyte Physiol
271:
F1166-F1172,
1996
7.
Harris, PJ,
Zhuo J,
Mendelsohn FA,
and
Skinner SL.
Haemodynamic and renal tubular effects of low doses of endothelin in anaesthetized rats.
J Physiol (Lond)
433:
25-39,
1991[Abstract].
8.
Karet, FE,
Kuc RE,
and
Davenport AP.
Novel ligands BQ123 and BQ3020 characterize endothelin receptor subtypes ETA and ETB in human kidney.
Kidney Int
44:
36-42,
1993[ISI][Medline].
9.
Lariviere, R,
Deng LY,
Day R,
Sventek P,
Thibault G,
and
Schiffrin EL.
Increased endothelin-1 gene expression in the endothelium of coronary arteries and endocardium in the DOCA-salt hypertensive rat.
J Mol Cell Cardiol
27:
2123-2131,
1995[ISI][Medline].
10.
Lariviére, R,
Thibault G,
and
Schiffrin EL.
Increased endothelin-1 content in blood vessels of deoxycorticosterone acetate-salt hypertensive but not in spontaneously hypertensive rats.
Hypertension
21:
294-300,
1993[Abstract].
11.
Plato, CF,
Pollock DM,
and
Garvin JL.
Endothelin inhibits thick ascending limb chloride flux via ETB receptor-mediated NO release.
Am J Physiol Renal Physiol
279:
F334-F344,
2000
12.
Pollock, DM.
Renal endothelin in hypertension.
Curr Opin Nephrol Hypertens
9:
157-164,
2000[ISI][Medline].
13.
Pollock, DM,
Allcock GH,
Krishnan A,
Dayton BD,
and
Pollock JS.
Upregulation of endothelin B receptors in kidneys of DOCA-salt hypertensive rats.
Am J Physiol Renal Physiol
278:
F279-F286,
2000
14.
Rasmussen, TE,
Jougasaki M,
Supaporn T,
Hallett JW, Jr,
Brooks DP,
and
Burnett JC, Jr.
Cardiovascular actions of ET-B activation in vivo and modulation by receptor antagonism.
Am J Physiol Regulatory Integrative Comp Physiol
274:
R131-R138,
1998
15.
Rubanyi, GM,
and
Polokoff MA.
Endothelins: molecular biology, biochemistry, pharmacology, physiology, and pathophysiology.
Pharmacol Rev
46:
325-415,
1994[ISI][Medline].
16.
Schiffrin, EL,
Sventek P,
Li JS,
Turgeon A,
and
Reudelhuber T.
Antihypertensive effect of an endothelin receptor antagonist in DOCA-salt spontaneously hypertensive rats.
Br J Pharmacol
115:
1377-1381,
1995[Abstract].
17.
Schnermann, J,
Lorenz JN,
Briggs JP,
and
Keiser JA.
Induction of water diuresis by endothelin in rats.
Am J Physiol Renal Fluid Electrolyte Physiol
263:
F516-F526,
1992
18.
Strachan, FE,
Spratt JC,
Wilkinson IB,
Johnson NR,
Gray GA,
and
Webb DJ.
Systemic blockade of the endothelin-B receptor increases peripheral vascular resistance in healthy men.
Hypertension
33:
581-585,
1999
19.
Von Geldern, TW,
Tasker AS,
Sorensen BK,
Winn M,
Szczepankiewicz BG,
Dixon DB,
Chiou WJ,
Wang L,
Wessale JL,
Adler A,
Marsh KC,
Nguyen B,
and
Opgenorth TJ.
Pyrrolidine-3-carboxylic acids as endothelin antagonists. 4. Side chain conformational restriction leads to ET(B) selectivity.
J Med Chem
42:
3668-3678,
1999[ISI][Medline].
20.
Warner, TD.
Characterization of endothelin synthetic pathways and receptor subtypes: physiological and pathophysiological implications.
Eur Heart J
14:
42-47,
1993[ISI][Medline].
21.
Winn, M,
Von Geldern TW,
Opgenorth TJ,
Jae HS,
Tasker AS,
Boyd SA,
Kester JA,
Mantei RA,
Bal R,
Sorensen BK,
Wu-Wong JR,
Chiou WJ,
Dixon DB,
Novosad EI,
Hernandez L,
and
Marsh KC.
2,4-Diarylpyrrolidine-3-carboxylic acids: potent ETA selective endothelin receptor antagonists. 1. Discovery of A-127722.
J Med Chem
39:
1039-1048,
1996[ISI][Medline].