Salt-sensitive hypertension caused by long-term alpha-adrenergic blockade in the rat

Short exposure to high salt in drinking solution leads to a cardiovascular phenotype of hypertension without changes in the blood volume of rats

NEW FINDINGS

What is the central question of this study? Is the cardiovascular phenotype of high blood pressure observed in rats salt loaded with 2% NaCl in drinking solution a blood volume-dependent hypertension? What is the main finding and its importance? Animals exposed to 2% NaCl drinking solution develop hypertension, with dominance of sympathetic outflow and high [Na+ ] in the cerebrospinal fluid, but without changes in the blood volume. The phenotype of salt-dependent hypertension might be related to accumulation of [Na+ ] in the cerebrospinal fluid, which makes it an interesting animal model in which to study the neuronal pathways involved in control of the circulation in osmotic challenge conditions.

ABSTRACT

Evidence suggests that hypertension induced by high salt intake is correlated with an autonomic imbalance that favours sympathetic hyperactivity and an increase in vascular resistance, indicating a neurogenic component to this pathology. Although there are several animal models in which to study salt-induced hypertension with prolonged exposure to a high-sodium diet, here we sought to investigate whether the increase in arterial blood pressure of rats subjected to a short exposure to high salt, with 2% NaCl drinking solution instead of water, relies on changes in the circulating blood volume. Male Wistar rats were divided randomly into three groups: euhydrated (EU, n = 10), salt loaded (SL, n = 13) and water deprived (WD, n = 6). The SL rats exhibited a significant increase in mean arterial blood pressure, with a large low-frequency component of systolic arterial blood pressure variability, when compared with the EU group. Circulating blood volume did not differ between SL and EU rats, but it was lower in WD rats. Compared with EU rats, the [Na+ ] in cerebrospinal fluid was higher in SL rats and similar in magnitude to the WD rats. Plasma [Na+ ] did not differ between SL and EU rats, but it was higher in WD rats. Collectively, our data suggest that the hypertension induced by a short exposure to high salt intake closely resembles a neurogenic mechanism, but not a blood volume-dependent mechanism, with cumulative [Na+ ] in the cerebrospinal fluid that could be associated with changes in the neurochemistry of autonomic nuclei, which are highly susceptible to osmotic stress related to high salt consumption.

Chronic high-sodium diet intake after weaning lead to neurogenic hypertension in adult Wistar rats

In this study, we investigated some mechanisms involved in sodium-dependent hypertension of rats exposed to chronic salt (NaCl) intake from weaning until adult age. Weaned male Wistar rats were placed under high (0.90% w/w, HS) or regular (0.27% w/w, Cont) sodium diets for 12 weeks. Water consumption, urine output and sodium excretion were higher in HS rats compared to control. Blood pressure (BP) was directly measured by the arterial catheter and found 13.8% higher in HS vs Cont rats. Ganglionic blockade with hexamethonium caused greater fall in the BP of HS rats (33%), and central antagonism of AT₁ receptors (losartan) microinjected into the lateral ventricle reduced BP level of HS, but not of Cont group. Heart rate variability analysis revealed sympathetic prevalence on modulation of the systolic interval. HS diet did not affect creatinine clearance. Kidney histological analysis revealed no significant change in renal corpuscle structure. Sodium and potassium concentrations in CSF were found higher in HS rats despite no change in plasma concentration of these ions. Taken together, data suggest that animals exposed to chronic salt intake to a level close to that reported for human' diet since weaning lead to hypertension, which appears to rely on sodium-driven neurogenic mechanisms.

Subfornical organ lesion attenuates chronic hypotensive effects of losartan in salt-replete rats

Hypothesis/introduction Circumventricular organs are central nervous system brain sites thought to participate in neuroendocrine regulation of neural output. We have previously demonstrated a profound chronic hypotensive response to the angiotensin II (Ang II) AT1 antagonist, losartan (10 mg/kg/day), in normal rats. In addition, we have demonstrated that the area postrema, one of the circumventricular organs, partially mediates this response. The subfornical organ (SFO) is another circumventricular organ which has been shown to mediate actions of Ang II. The present study was designed to test the hypothesis that the SFO mediates the chronic hypotensive effects of losartan in normal rats.

Materials and methods Rats were randomly chosen for lesion of the SFO or sham operation and instrumented with intravenous catheters and radiotelemetric blood pressure transducers. After a control period, rats were infused with losartan (10 mg/kg/day) for nine days. Mean arterial pressure and heart rate responses were measured continuously throughout the protocol and examined as 12-hour day/night averages.

Results By day 7 of losartan treatment, night-time mean arterial pressure had dropped to 75±2 mmHg in sham rats (n=8) but only to 83±2 mmHg in SFO-lesioned rats (n=10). This trend continued throughout the treatment protocol.

Conclusions These results suggest that the SFO partially mediates the chronic hypotensive effects of chronic losartan treatment in normal rats.

Combining naltrexone and prazosin in a single oral medication decreases alcohol drinking more effectively than does either drug alone

BACKGROUND

Naltrexone (NTX) is underutilized in clinical treatment settings because its efficacy is modest, and it is not effective for all alcoholics and, when it is effective, a significant number of alcoholics fail to maintain initial treatment gains and subsequently relapse to heavy drinking. This has slowed acceptance of NTX by the treatment community, and there is a clear need for additional treatments for alcoholism and alcohol use disorders. Given that NTX and prazosin can each reduce alcohol drinking in rats selectively bred for alcohol preference and high voluntary alcohol drinking (alcohol-preferring "P" rats), we tested whether a combination of NTX + prazosin is more effective in decreasing alcohol drinking than is either drug alone.

METHODS

P rats were given access to a 15% (v/v) alcohol solution for 2 hours daily. Rats were fed NTX and prazosin, alone or in combination, prior to onset of the daily 2-hour alcohol access period for 4 weeks and the effect of drug treatment on alcohol and water intake was assessed.

RESULTS

During the first week of treatment, neither a low dose of NTX, nor prazosin, was effective in decreasing alcohol intake when each drug was administered alone, but combining the 2 drugs in a single medication significantly reduced alcohol intake. The combination was as effective as was a higher dose of NTX. Using a low dose of NTX in combination with prazosin may reduce the potential for undesirable side effects early in treatment which, in turn, may improve patient compliance and result in a more successful outcome when NTX is used for treating alcoholism and alcohol use disorders.

CONCLUSIONS

Combining low-dose NTX and prazosin in a single medication may be more useful than is either drug alone for treating both inpatient and outpatient alcoholics and heavy drinkers early in the treatment process.

Role of the Median Preoptic Nucleus in Arterial Pressure Regulation and Sodium and Water Homeostasis during High Dietary Salt Intake

Changes in the osmolality and level of angiotensin II (ANG II) are important peripheral signals modulating appropriate central sympathetic output and maintaining a normal arterial pressure during high salt intake. The median preoptic nucleus (MnPO) receives reciprocal inputs from the subfornical organ (SFO) and organum vasculosum of the lamina terminalis (OVLT), the circumventricular organs that have been shown to be necessary in multiple central effects of changes in the osmolality and circulating ANG II directed toward the maintenance of sodium and water homeostasis. We, therefore, hypothesized that the MnPO is a crucial part of the central neuronal mechanisms mediating the blood pressure control by altered osmolality and/or ANG II signaling during chronic high dietary salt intake. Male Sprague-Dawley rats were randomly assigned to either sham (operation), or electrolytic lesion of the MnPO. After a 7-day recovery, rats were instrumented with radiotelemetric transducers and aortic flow probes for the measurement of the mean arterial pressure + heart rate (HR) and cardiac output (CO), respectively. Femoral venous catheters were also implanted to collect blood for the measurements of plasma osmolality and sodium concentration, as well as plasma renin activity. Rats were given another 10 days to recover and then were subjected to a 28-day-long study protocol that included a 7-day control period (1.0% NaCl diet), followed by 14 days of high salt (4.0% NaCl), and a 7-day recovery period (1.0% NaCl). The data showed, that despite a slight increase in the MAP observed in both MnPO- (n = 12) and sham-lesioned (n = 8) rats during the high-salt period, there were no significant differences between the MAP, HR, and CO in the two groups throughout the study protocol. These findings do not support the hypothesis that the MnPO is necessary to maintain normal blood pressure during high dietary salt intake. However, MnPO-lesioned rats showed less sodium balance than sham-lesioned rats during the first 4 days of high salt intake. Although, these results may be explained partly by the plasma hyperosmolarity and hypernatremia observed in MnPO-lesioned rats; they also shed light on the role of the MnPO in central neuronal control of renal sodium handling during chronic high dietary salt intake.

Effect of peripheral sympathetic nerve dysfunction on salt sensitivity of arterial pressure

1. Dysregulation of peripheral sympathetic pathways contributes to some forms of salt-dependent hypertension. However, at the present time it is not known whether salt-induced activation of sympathetic nerves or loss of normal sympathoinhibitory responses to salt-induced volume expansion contributes to neurogenic salt-dependent hypertension. The present study was performed to the test the hypothesis that loss of peripheral sympathetic nerve function results in salt-dependent hypertension. 2. The effect of three pharmacological interventions of sympathetic nerve function on the long-term salt-sensitivity of mean arterial pressure (MAP) were measured: (i) blockade of ganglionic transmission with hexamethonium (HEX; n = 5); (ii) destruction of sympathetic nerve terminals with guanethidine (GUAN; n = 7); and (iii) alpha-adrenoceptor blockade with two specific antagonists, namely prazosin (PRAZ; n = 7) and terazosin (TERAZ; n = 8). 3. Mean arterial pressure and heart rate were measured 24 h/day by radiotelemetry in conscious rats during 5 days of normal and 7 days of high (HNa) dietary sodium intake. Despite marked increases in both sodium and water intake during 7 days of the HNa diet, no statistically significant changes in MAP were observed in HEX, GUAN, PRAZ or TERAZ groups. 4. We conclude that loss of peripheral sympathetic neural pathways alone does not cause salt-dependent hypertension in the rat.

Chronic effects of angiotensin II and at1 receptor antagonists in subfornical organ-lesioned rats

1. Angiotensin (Ang) II is known to exert some of its effects centrally via circumventricular organs. These unique central nervous system areas lack the normal blood-brain barrier and, therefore, allow peptide hormones access to the brain. Of these, the subfornical organ (SFO) has been shown to be involved in many of the acute dipsogenic and pressor effects of AngII, but much less is known about the role of the SFO in the chronic effects of AngII. We hypothesized that the SFO is a central site involved in the chronic hypotensive effects of endogenous AT(1) receptor blockade, as well as the chronic hypertensive effects of exogenously administered AngII. 2. In order to test these hypotheses, SFO-lesioned (SFOx) or sham Sprague-Dawley rats were instrumented with venous catheters and radiotelemetric pressure transducers for intravenous administration of losartan or AngII and continuous measurement of blood pressure and heart rate. Rats were given 3 days of saline control infusion (7 mL/day of 0.9% NaCl) and were then infused with either losartan (10 mg/kg per day) or AngII (10 ng/kg per min) for 10 days. 3. By day 4 of losartan treatment, arterial pressure had decreased 24 +/- 2 and 18 +/- 2 mmHg in sham (n = 9) and SFOx (n = 10) rats, respectively. Furthermore, by day 5 of AngII infusion, arterial pressure had increased 12 +/- 3 mmHg in sham rats (n = 9), but only by 4 +/- 1 mmHg in SFOx rats (n = 9). In each treatment group, these attenuated pressure responses in SFOx rats continued through day 10 of treatment. 4. These results support the hypotheses that the SFO plays a role in both the hypotensive effects of chronic AT(1) receptor blockade and the chronic hypertensive phase of exogenously administered AngII.

Renal denervation causes chronic hypotension in rats: role of beta1-adrenoceptor activity

1. Renal denervation (RDNX) chronically lowers mean arterial pressure (MAP) in normal rats but mechanisms leading to this hypotensive response remain unknown. 2. We hypothesized that this sustained decrease in arterial pressure was because of a loss of beta1-adrenoceptor mediated renin secretion. Male Sprague-Dawley rats were assigned to sham (SHAM; n = 9), unilateral (UniRDNX; n = 9), or bilateral (RDNX; n = 10) renal denervation groups and instrumented for telemetric MAP measurements, plasma renin concentration (PRC) measurements and intravenous infusion. Twenty-four h MAP, heart rate, sodium and water balances were recorded 5 days before, 3 days during and 3 days after 1-adrenoceptor blockade with atenolol. 3. The 5-day control MAP was significantly lower in RDNX (97 +/- 1 mmHg) compared to SHAM (105 +/- 2 mmHg) and UniRDNX (102 +/- 2 mmHg) rats. No significant differences in basal PRC were observed between RDNX (2.2 +/- 0.3 ngAng1/mL per h), UniRDNX (2.6 +/- 0.4 ng/Ang1/mL per h) and SHAM (2.6 +/- 0.4 ngAng1/mL per h) rats. By day 1 of atenolol, PRC was significantly lower in UniRDNX rats (1.8 +/- 0.2 ngAg1/mL per h) compared to control values, but was unchanged during atenolol infusion in the other groups. By day 3 of atenolol, MAP was significantly decreased in all groups, but the absolute levels of MAP remained statistically different between RDNX (87 +/- 1 mmHg) and SHAM (91 +/- 1 mmHg) groups. 4. We conclude that the arterial pressure lowering effect of RDNX is not solely dependent on the loss of neural control of renin release.

Role of a Responsive Sympathetic Nervous System in the Chronic Hypotensive Effects of Losartan in Normal Rats

We have previously demonstrated the chronic hypotensive effects of the AT1 antagonist losartan in normotensive, salt-replete rats. We hypothesized that the chronic effects of losartan are mediated in part by blockade of the central sympathoexcitatory actions of angiotensin II. To test this hypothesis, we have used a novel approach to effectively "clamp" the sympathetic nervous system at a fixed level through chronic administration of the ganglionic blocking agent hexamethonium (15 mg/kg/h) and the alpha agonist phenylephrine (2.26 mg/kg/d). Two of 3 groups of rats [CON and CLAMP(NNa)] were placed on (0.1%) NaCl diets, whereas the third [CLAMP(LNa)] was placed on a low (0.002%)-sodium diet. Continuous measurements of mean arterial pressure (MAP) were made via radiotelemetry. After 9 days of hexamethonium plus phenylephrine treatment in CLAMP(NNa) and CLAMP(LNa) rats, baseline MAP was not different in all 3 groups of rats: CON (104+/-4 mm Hg), CLAMP(NNa) (104+/-4 mm Hg), and CLAMP(LNa) (106+/-2 mm Hg). After 5 days of subsequent losartan treatment, a change in MAP of only -7+/-2 mm Hg was observed in CLAMP(NNa) rats compared with -22+/-2 mm Hg in CON and CLAMP(LNa) rats. These results do not support the hypothesis that the hypotensive actions of losartan are entirely dependent on a responsive sympathetic nervous system rats.

The vanilloid receptor and hypertension

Mammalian transient receptor potential (TRP) channels consist of six related protein sub-families that are involved in a variety of pathophysiological function, and disease development. The TRPV1 channel, a member of the TRPV sub-family, is identified by expression cloning using the "hot" pepper-derived vanilloid compound capsaicin as a ligand. Therefore, TRPV1 is also referred as the vanilloid receptor (VR1) or the capsaicin receptor. VR1 is mainly expressed in a subpopulation of primary afferent neurons that project to cardiovascular and renal tissues. These capsaicin-sensitive primary afferent neurons are not only involved in the perception of somatic and visceral pain, but also have a "sensory-effector" function. Regarding the latter, these neurons release stored neuropeptides through a calcium-dependent mechanism via the binding of capsaicin to VR1. The most studied sensory neuropeptides are calcitonin gene-related peptide (CGRP) and substance P (SP), which are potent vasodilators and natriuretic/diuretic factors. Recent evidence using the model of neonatal degeneration of capsaicin-sensitive sensory nerves revealed novel mechanisms that underlie increased salt sensitivity and several experimental models of hypertension. These mechanisms include insufficient suppression of plasma renin activity and plasma aldosterone levels subsequent to salt loading, enhancement of sympathoexcitatory response in the face of a salt challenge, activation of the endothelin-1 receptor, and impaired natriuretic response to salt loading in capsaicin-pretreated rats. These data indicate that sensory nerves counterbalance the prohypertensive effects of several neurohormonal systems to maintain normal blood pressure when challenged with salt loading. The therapeutic utilities of vanilloid compounds, endogenous agonists, and sensory neuropeptides are also discussed.

Role of the subfornical organ in the chronic hypotensive response to losartan in normal rats

Angiotensin II is known to act at a unique set of brain regions known as the circumventricular organs. These structures lack the normal blood-brain barrier and are therefore thought to participate in the central nervous system processing of neuroendocrine signals. We have reported that chronic treatment with the angiotensin type 1 (AT1) receptor antagonist, losartan, decreases arterial pressure in normotensive rats. Furthermore, this hypotension is attenuated in area postrema-lesioned rats, suggesting a role of endogenous angiotensin II at this circumventricular organ. Another circumventricular organ, the subfornical organ (SFO), has also been shown to mediate actions of angiotensin II. The present study tested the hypothesis that the SFO is a central site of action of endogenous angiotensin II at AT1 receptors. Adult male Sprague-Dawley rats were anesthetized and placed in a stereotaxic apparatus, and the SFO was sham or electrolytically lesioned. One week later, rats were instrumented with venous catheters and radiotelemetry pressure transducers for continuous infusion and monitoring of mean arterial pressure, respectively. After 3 days of control, losartan was administered intravenously (10 mg x kg(-1) x d(-1)) for 10 days in both SFO-lesioned and sham rats. By day 4 of losartan administration, mean arterial pressure had decreased to 75+/-2 mm Hg in sham rats (n=9) but had only fallen to 83+/-2 mm Hg in lesioned rats (n=10). This attenuated hypotensive response in SFO-lesioned rats continued through day 10 of losartan treatment. These results support the hypothesis that the SFO mediates part of the hypotensive effects of chronic AT1 receptor blockade in the normotensive rat.

Blood pressure and NaCl-sensitive hypertension are influenced by angiotensin-converting enzyme gene expression in transgenic mice

ACE plays an important role in the regulation of arterial pressure; however, a linear relationship between ACE expression and arterial pressure has not been demonstrated. The present study employed telemetric monitoring in female transgenic mice to determine the influence of partial and complete deletion of the ACE gene on basal arterial pressure and arterial pressure responses to a high-NaCl diet. On the basal NaCl diet, 24-hour mean arterial pressure was significantly correlated with the number of functional copies of the ACE gene; ie, arterial pressure was lowest in 0-copy (80 +/- 1 mm Hg), intermediate in 1-copy (100 +/- 1 mm Hg), and highest in 2-copy (113 +/- 1 mm Hg) ACE mice. The high-NaCl diet significantly increased mean arterial pressure in 0-copy (99 +/- 1 mm Hg) and 1-copy (108 +/- 1 mm Hg) mice but not in 2-copy mice (114 +/- 1 mm Hg). These results demonstrate a copy-dependent relationship between ACE gene expression and both basal arterial pressure and arterial pressure responses to a high-NaCl diet, suggesting that either partial or complete reduction in the ACE gene can alter arterial pressure.

Angiotensin and osmoreceptor inputs to the area postrema: role in long-term control of fluid homeostasis and arterial pressure

1. The role of the area postrema (AP) in the long-term control of body fluid homeostasis and arterial pressure under conditions of increased dietary salt intake is reviewed. A model is proposed in which sympathetic nerve activity is suppressed when dietary salt is increased. It is hypothesized that the AP acts as an essential integrative site in the hind-brain for this response. 2. An essential component of the hypothesis is that basal levels of circulating angiotensin II support arterial pressure in animals consuming a normal salt diet by acting on the AP to drive sympathetic nerve activity. This hypothesis is supported by the observation that the long-term hypotensive response to losartan, the AT1 receptor antagonist, is attenuated in AP-lesioned (APx) rats. 3. The role of hepatoportal sodium receptors in signalling the AP about changes in dietary salt intake is discussed. Intragastric hypertonic saline infusion increases portal venous, but not systemic plasma, osmolality and increases Fos-like immunoreactivity in the AP, nucleus tractus solitarius and the supraoptic, paraventricular and lateral parabrachial nuclei. Other studies have shown that stimulation of these receptors decreases renal sympathetic nerve activity. 4. The hypothesis that the AP is critical in long-term control of arterial pressure and body fluid homeostasis under conditions of altered dietary salt intake was studied. The responses of arterial pressure and sodium and water balance to changes in dietary salt intake were measured in intact and APx rats. Contrary to the hypothesis, APx rats did not exhibit impaired regulation of arterial pressure or water balance. However, APx rats did demonstrate an impaired ability to excrete sodium when salt intake was elevated. 5. Based on these observations, it is concluded that the AP is important in the control of sodium balance, but not arterial pressure, when dietary salt intake is altered.

The chronic infusion of hexamethonium and phenylephrine to effectively clamp sympathetic vasomotor tone. A novel approach

There are several ways to assess the sympathetic nervous system (i.e. , nerve recording, sympathectomy, etc.), each of which has its own limitations. The present study was conducted to establish a standard, testable chronic ganglionic blockade protocol with a fixed level of adrenergic vasomotor tone. Rats were instrumented with radio telemetry pressure transducers and venous catheters for continuous measurement of arterial pressure and infusion of pharmacologic agents, respectively. After 3 days of control measurements, rats were infused for 9 days with a continuous dose of the ganglionic blocking agent, hexamethonium and the alpha-adrenergic agonist, phenylephrine. In this way, sympathetic tone was effectively "clamped," which maintained a normal level of arterial pressure. Control pressure between hexamethonium + phenylephrine (HEX + PE) treated rats (101+/-2 mm Hg) and saline (VEHICLE) treated rats (101+/-2 mmHg) was not different. By day 9 of the infusion, there was no difference in arterial pressure between groups (VEHICLE: 101+/-3 mm Hg, HEX + PE: 103+/-3 mm Hg) or from the control period, although heart rate was significantly less in HEX + PE rats (VEHICLE: 406+/-9 beats/min vs. HEX + PE: 343+/-6 beats/min). The effectiveness of this technique was validated by measuring cardiac baroreceptor reflex sensitivity, as well as the pressor response to the direct ganglionic stimulating agent, 1, 1-dimethyl-4-phenylpiperazinium iodide (DMPP). Compared to VEHICLE rats, HEX + PE rats showed no tachycardic response to depressor stimuli and an absence of a pressor response to DMPP. We conclude that this protocol is a useful technique to chronically, yet reversibly, block the sympathetic nervous system in experimental settings.

Antihypertensive mechanisms underlying a novel salt-sensitive hypertensive model induced by sensory denervation

A novel model of hypertension recently developed in our laboratory shows that neonatal degeneration of capsaicin-sensitive sensory nerves renders a rat responsive to a salt load with a significant rise in blood pressure. To determine the role of the renin-angiotensin system and the sympathetic nervous system in the development of hypertension in this model, newborn Wistar rats were given capsaicin 50 mg/kg SC on the first and second days of life. Control rats were treated with vehicle. After they were weaned, male rats were divided into 6 groups and subjected to the following treatments for 2 weeks: control+high sodium diet (4%) (CON-HS), capsaicin+normal sodium diet (0.5%) (CAP-NS), capsaicin+high sodium diet (CAP-HS), capsaicin+high sodium diet+losartan (10 mg/kg per day) (CAP-HS-LO), capsaicin+high sodium diet+prazosin (3 mg/kg per day) (CAP-HS-PR), and capsaicin+high sodium diet+hydralazine (10 mg/kg per day) (CAP-HS-HY). Levels of calcitonin gene-related peptide in dorsal root ganglia were decreased by capsaicin treatment (P<0.05). Both tail-cuff systolic blood pressure and mean arterial pressure were higher in CAP-HS and CAP-HS-PR than in CON-HS, CAP-NS, CAP-HS-LO, and CAP-HS-HY (P<0.05). The 24-hour urinary volume and sodium excretion were increased when a high sodium diet was given (P<0.05), but they were lower in CAP-HS, CAP-HS-LO, CAP-HS-PR, and CAP-HS-HY than in CON-HS (P<0.05). Urinary potassium excretion was not different among all 6 groups. We conclude that blockade of the angiotensin type 1 receptor with losartan but not antagonism of the alpha1-adrenoreceptor with prazosin prevents the development of salt-sensitive hypertension induced by sensory denervation. Sensory denervation impairs urinary sodium and water excretion in response to a high sodium intake, regardless of blood pressure, suggesting that sensory innervation plays a direct role in regulating the natriuretic response to sodium loading.

The area postrema does not modulate the long-term salt sensitivity of arterial pressure

The hindbrain circumventricular organ, the area postrema (AP), receives multiple signals linked to body fluid homeostasis. In addition to baroreceptor input, AP cells contain receptors for ANG II, vasopressin, and atrial natriuretic peptide. Hence, it has been proposed that the AP is critical in long-term adjustments in sympathetic outflow in response to changes in dietary NaCl. The present study was designed to test the hypothesis that long-term control of arterial pressure over a range of dietary NaCl requires an intact AP. Male Sprague-Dawley rats were randomly selected for lesion of the AP (APx) or sham lesion. Three months later, rats were instrumented with radiotelemetry transmitters for continuous monitoring of mean arterial pressure (MAP) and heart rate and were placed in individual metabolic cages. Rats were given 1 wk postoperative recovery. The dietary salt protocol consisted of a 7-day period of 1.0% NaCl (control), 14 days of 4.0% NaCl (high), 7 days of 1.0% NaCl, and finally 14 days of 0.1% NaCl (low). The results are reported as the average arterial pressure observed on the last day of the given dietary salt period: APx (n = 7) 114 +/- 2 (1.0%), 110 +/- 3 (4.0%), 110 +/- 3 (1.0%), and 114 +/- 4 (0.1%) mmHg; sham (n = 6) 115 +/- 2 (1.0%), 114 +/- 3 (4.0%), 111 +/- 3 (1. 0%), and 113 +/- 2 (0.1%) mmHg. Neither group of rats demonstrated significant changes in MAP throughout the entire dietary salt protocol. Furthermore, no significant differences in MAP were detected between groups throughout the protocol. All lesions were histologically verified. These results suggest that the area postrema plays no role in long-term control of arterial pressure during chronic changes in dietary salt.

Effects of a high NaCl diet on eating and drinking patterns in pygmy goats

Eating and drinking patterns of eight pygmy goats were recorded under two diets with different NaCl content. A 3% NaCl diet in comparison to a 0.5% NaCl diet caused a long lasting depression of food intake, whereas water intake did not change. Therefore, the ratio between cumulative water and food intake increased significantly. Feeding the 3% NaCl diet mainly decreased food intake through a decrease in the size (31%) and frequency (16%) of meals which were not associated with drinking. Size and frequency of meals associated with drinking were not substantially affected by the 3% NaCl diet. Size and frequency of drafts were not altered. Size of meals associated with drinking was generally bigger than that of meals not associated with drinking. These findings can best be explained by control of feeding through osmolality of rumen fluid. Ruminal osmolality seems to be less important for control of drinking.

Area postrema lesion attenuates the long-term hypotensive effects of losartan in salt-replete rats

We reported that the AT1 receptor antagonist losartan decreases arterial pressure in sodium-replete rats and that this response is attenuated in area postrema-lesioned (APx) rats (J. P. Collister, B. J. Hornfeldt, and J. W. Osborn. Hypertension 27: 598-606, 1996). In that study, food intake for the 3-wk period after sham lesion was restricted to that observed in APx rats. Food-restricted sham rats had lower arterial pressures and attenuated responses to losartan compared with control rats fed ad libitum. The present study examined whether these differences persisted months, rather than weeks after APx or sham lesions. Losartan was administered for 10 days to APx and two groups of sham rats 3 mo after APx or sham surgery. The first sham group was food restricted (SFR) for 3 wk after surgery, whereas the second sham group was allowed ad libitum (SAL) access to food. By day 8 of losartan administration, both sham groups demonstrated a marked hypotension (SFR: -38 +/- 4; SAL: -33 +/- 4 mmHg). This response was attenuated (P < 0.05) on the same day in APx rats (-17 +/- 3 mmHg). This trend continued throughout days 9 and 10. Because both sham groups responded similarly to losartan (yet significantly different from APx rats), these results demonstrate that transient decreases in food intake do not affect the response to losartan if rats are allowed an adequate recovery period. We conclude that the area postrema mediates part of the long-term hypotensive effects of AT1 receptor blockade in the conscious rat.

Interactions between angiotensin II and the sympathetic nervous system in the the long-term control of arterial pressure

1. The role of the renin-angiotensin system in long-term control of sympathetic activity and arterial pressure is reviewed. 2. There is evidence that favours a necessary role for the sympathetic nervous system in long-term arterial pressure regulation. First, appropriate changes in sympathetic activity appear to be produced in response to chronic changes in blood volume or blood pressure. Second, prevention of the normal homeostatic decrease in sympathetic activity in response to an increase in sodium intake produces hypertension. 3. Long-term changes in sympathetic activity cannot be mediated by the baroreceptor reflex, because it adapts to sustained changes in pressure. Therefore, an hypothesis is presented that evokes a key role for angiotensin II (AngII) in determining the chronic level of sympathetic activity. The key feature of this model is that the role of AngII is non-adaptive: chronic changes in extracellular fluid volume produce sustained reciprocal changes in AngII, and long-term increases in AngII produce sustained increases in sympathetic activity. 4. Evidence is reviewed that suggests that a lack of the normal suppression in AngII and/or sympathetic activity in response to an increase in sodium intake produces salt-sensitive hypertension.

Hormones as long-term error signals for the sympathetic nervous system: importance of a new perspective

1. A hormonal-sympathetic reflex model for long-term control of arterial pressure is presented. It is hypothesized that the hormonal-sympathetic reflex regulates arterial pressure during chronic dietary salt loading by decreasing sympathetic tone. This sympathetic response is mediated by an increase in plasma vasopressin (AVP) and a decrease in plasma angiotensin (AngII). 2. Three new models of neurogenic salt-dependent hypertension are presented. All models are theoretically based on an impaired hormonal-sympathetic reflex. 3. In the first model, sympathetic responsiveness is 'clamped' by long-term alpha-adrenergic blockade with prazosin. Prazosin treated rats exhibit marked salt-dependent hypertension despite normal suppression of the renin-angiotensin system. 4. In the second model, the ability of the central nervous system to respond to salt-induced changes in AVP and AngII concentrations was prevented by long-term administration of antagonists selective for the AVP-V1 and AT1. This 'clamp' of the afferent hormonal signal resulted in salt-dependent hypertension identical in magnitude to that observed in prazosin treated rats. 5. In the third model, the long-term arterial pressure responses to increasing dietary salt were examined in sino-aortic denervated (SAD) rats. SAD rats exhibited salt-dependent hypertension, of lesser magnitude than that observed with 'clamped' afferent and efferent pathways of the hormonal-sympathetic reflex. 6. A primary role for hormonal 'error signals' is presented and the impact this perspective has on past and future investigations of central mechanisms of long-term arterial pressure regulation is discussed.

Hypertension in obese Zucker rats. Role of angiotensin II and adrenergic activity

We designed our studies to determine whether blood pressure is elevated in obese Zucker rats compared with lean control rats and to test the importance of the renin-angiotensin and adrenergic nervous systems in long-term blood pressure control in this genetic model of obesity. We monitored mean arterial pressure 24 hours per day using computerized methods in 13- to 14-week-old lean and obese Zucker rats maintained on a fixed, normal sodium intake (3.3 mmol/d). Mean arterial pressure (average of 5 days) was higher in obese (100 +/- 1 mm Hg) than in lean (86 +/- 1) rats. Although control plasma renin activity was lower in obese than in lean rats (3.66 +/- 0.15 versus 5.48 +/- 0.11 ng angiotensin I/mL per hour), blood pressure sensitivity to exogenous angiotensin II was greater in obese than in lean rats. Blockade of endogenous angiotensin II receptors with losartan (10 mg/kg per day) for 7 days also caused a greater decrease in blood pressure in obese (36 +/- 2 mm Hg, n = 6) than in lean (25 +/- 1, n = 5) rats. However, combined alpha- and beta-adrenergic blockade with terazosin (10 mg/kg per day) and propranolol (10 mg/kg per day), respectively, for 8 days caused only modest decreases in blood pressure in obese (9 +/- 3 mm Hg, n = 8) and lean (4 +/- 2, n = 6) rats, despite effective alpha- and beta-adrenergic blockade. These results suggest that increased arterial pressure in obese Zucker rats depends in part on angiotensin II. However, additional mechanisms may also contribute to increased blood pressure in obese Zucker rats.

Hypotensive response to losartan in normal rats. Role of Ang II and the area postrema

We have reported that the angiotensin II (Ang II) AT1 receptor antagonist losartan markedly lowers arterial pressure in sodium-replete, normotensive rats. We hypothesized that this action of losartan was mediated by its blocking the effects of endogenous Ang II. To test this hypothesis, rats were instrumented with arterial and venous catheters for measurement of arterial pressure and infusion of losartan, respectively. After 3 days of control measurements, losartan was infused for 10 days (10 mg/kg/d) in rats on a normal daily sodium intake (NNa; approximately 2 mmol/d, n=6) and rats on a high daily sodium intake (HNa; approximately 15 mmol/d, n=7) to suppress endogenous Ang II. Although basal plasma renin activity was markedly suppressed in HNa rats (0.9 +/- 0.4 ng Ang I/ mL/h) compared with NNa rats (4.0 +/- 0.3 ng Ang I/mL/h), control arterial pressure was not different between NNa (113 +/- 4 mm Hg) and HNa (113 +/- 2 mm Hg) rats. Losartan decreased arterial pressure from control levels in NNa rats on the first day of infusion (-12 +/- 2 mm Hg) but had no effect on arterial pressure in HNa rats (+4 +/- 4 mm Hg). Furthermore, by day 10 of losartan infusion, arterial pressure had decreased further from control levels in NNa rats (-32 +/- 2 mm Hg) but remained unchanged compared with control in HNa rats (+5 +/- 6 mm Hg). A second study was conducted to test the hypothesis that the area postrema, a circumventricular organ proposed to mediate the long-term neurogenic pressor activity of Ang II is a site of action for losartan. After 3 control days, losartan was administered for 10 days to area postrema-lesioned rats (APx; n=11) or sham-lesioned rats (n=10) consuming an NNa diet. Control arterial pressure was similar in sham (95 +/- 3 mm Hg) and APx (96 +/- 2 mm Hg) rats. Basal plasma renin activity was not different between groups (sham, 4.1 +/- 1.5 versus APx, 5.3 +/- 1.6 mm Hg Ang I/mL/h). On day 1 of losartan treatment, arterial pressure decreased to a significantly lower level in sham (80 +/- 2 mm Hg) compared with APx (90 +/- 3 mm Hg) rats. This trend continued through day 4 of losartan infusion, in which arterial pressure in sham rats (72.2 +/- 2 mm Hg) was significantly lower than in APx rats (83 +/- 4 mm Hg). However, during the remainder of the losartan infusion, there were no significant differences between groups with the exception of day 8 (sham, 72 +/- 2 mm Hg; APx, 84 +/- 2 mm Hg). Taken together, these results support the hypothesis that the hypotensive actions of losartan in sodium-replete, normotensive rats are due to blockade of the physiological effects of endogenous Ang II. Furthermore, an intact area postrema is essential for full expression of the hypotensive actions of losartan in normal rats.