Dietary sodium loading elevates blood pressure in baroreceptor denervated rats

Post-Ganglionic Sympathetic Neurons can Directly Sense Raised Extracellular Na+ via SCN7a/Nax

The relationship between dietary NaCl intake and high blood pressure is well-established, and occurs primarily through activation of the sympathetic nervous system. Nax, a Na+-sensitive Na+ channel, plays a pivotal role in driving sympathetic excitability, which is thought to originate from central regions controlling neural outflow. We investigated whether post-ganglionic sympathetic neurons from different ganglia innervating cardiac and vasculature tissue can also directly sense extracellular Na+. Using whole-cell patch clamp recordings we demonstrate that sympathetic neurons from three sympathetic ganglia (superior cervical, stellate and superior mesenteric/coeliac) respond to elevated extracellular NaCl concentration. In sympathetic stellate ganglia neurons, we established that the effect of NaCl was dose-dependent and independent of osmolarity, Cl- and membrane Ca2+ flux, and critically dependent on extracellular Na+ concentration. We show that Nax is expressed in sympathetic stellate ganglia neurons at a transcript and protein level using single-cell RNA-sequencing and immunohistochemistry respectively. Additionally, the response to NaCl was prevented by siRNA-mediated knockdown of Nax, but not by inhibition of other membrane Na+ pathways. Together, these results demonstrate that post-ganglionic sympathetic neurons are direct sensors of extracellular Na+ via Nax, which could contribute to sympathetic driven hypertension.

Reduced carotid baroreceptor distensibility-induced baroreflex resetting contributes to impairment of sodium regulation in rats fed a high-fat diet

Decreased carotid arterial compliance has been reported in obese subjects and animals. Carotid baroreceptors are located at the bifurcation of the common carotid artery, and respond to distension of the arterial wall, suggesting that higher pressure is required to obtain the same distension in obese subjects and animals. A hyperosmotic NaCl solution induces circulatory volume expansion and arterial pressure (AP) increase, which reflexively augment renal excretion. Thus, we hypothesized that sodium regulation via the baroreflex might be impaired in response to chronic hyperosmotic NaCl infusion in rats fed a high-fat diet. To examine this hypothesis, we used rats fed a high-fat (Fat) or normal (NFD) diet, and measured mean AP, water and sodium balance, and renal function in response to chronic infusion of hyperosmotic NaCl solution via a venous catheter. Furthermore, we examined arterial baroreflex characteristics with static open-loop analysis and distensibility of the common carotid artery. Significant positive water and sodium balance was observed on the 1st day of 9% NaCl infusion; however, this disappeared by the 2nd day in Fat rats. Mean AP was significantly higher during 9% NaCl infusion in Fat rats compared with NFD rats. In the open-loop analysis of carotid sinus baroreflex, a rightward shift of the neural arc was observed in Fat rats compared with NFD rats. Furthermore, distensibility of the common carotid artery was significantly reduced in Fat rats. These results indicate that a reduced baroreceptor distensibility-induced rightward shift of the neural arc might contribute to impairment of sodium regulation in Fat rats.

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.

Distinct rapid and slow phases of salt-induced hypertension in Dahl salt-sensitive rats

OBJECTIVE

To test the hypothesis that Dahl salt-sensitive (Dahl-S) rats exhibit distinct and separable phases of salt sensitivity.

METHODS

Blood pressure (BP) telemetry was used to describe the detailed time course of salt-induced hypertension in Dahl-S rats and in hybrid rats derived from Dahl-S and Dahl salt-resistant strains.

RESULTS

Switching to a high salt (4% NaCl) diet led to a biphasic increase in BP. Phase-1 reached a plateau in 4 days whereas phase-2 progressed slowly over the subsequent 5 weeks. In hybrid rats, phase-1 was present in each rat whereas phase-2 was absent in many individuals. A correlation of the amplitude of the first and second phases was of borderline significance in Dahl-S rats (P = 0.053, R2 = 0.44, n = 9) but was clearly significant in hybrid rats (P < 0.0001, R2 = 0.78, n = 22). Increases in BP were reversible following 1 week of high salt but progressively less so after 4 and 7 weeks. Estimation of the chronic pressure-natriuresis relationship suggests that phase-1 is attributable to a reduced slope of this relationship. In contrast, phase-2 corresponds with a further reduction in slope and a progressive and irreversible resetting of the relationship to higher BP levels.

CONCLUSIONS

Two phases of salt sensitivity coexist and provide distinct contributions to salt-induced hypertension in Dahl-S rats. Our data also suggest that short-term measures of salt-sensitivity may be predictive of the effect of salt on the eventual progression of salt-induced hypertension.

A neural set point for the long-term control of arterial pressure: beyond the arterial baroreceptor reflex

Arterial baroreceptor reflex control of renal sympathetic nerve activity (RSNA) has been proposed to play a role in long-term control of arterial pressure. The hypothesis that the “set point” of the acute RSNA baroreflex curve determines the long-term level of arterial pressure is presented and challenged. Contrary to the hypothesis, studies on the long-term effects of sinoaortic denervation (SAD) on arterial pressure and RSNA, as well as more recent studies of chronic baroreceptor “unloading” on arterial pressure, suggest that the basal levels of sympathetic nerve activity and arterial pressure are regulated independent of arterial baroreceptor input to the brainstem. Studies of the effect of SAD on the long-term salt sensitivity of arterial pressure are consistent with a short-term role, rather than a long-term role for the arterial baroreceptor reflex in regulation of arterial pressure during changes in dietary salt intake. Renal denervation studies suggest that renal nerves contribute to maintenance of the basal levels of arterial pressure. However, evidence that baroreflex control of the kidney plays a role in the maintenance of arterial pressure during changes in dietary salt intake is lacking. It is proposed that a “baroreflex-independent” sympathetic control system must exist for the long-term regulation of sympathetic nerve activity and arterial pressure. The concept of a central nervous system “set point” for long-term control of mean arterial pressure (CNS-MAP set point), and its involvement in the pathogenesis of hypertension, is discussed.

Digoxin prevents ouabain and high salt intake-induced hypertension in rats with sinoaortic denervation

Digoxin prevents ouabain-induced hypertension in rats. In the present study, we tested whether this effect of digoxin depends on its sensitizing effect on baroreflex function or is due to an antagonistic action on exogenous ouabain or endogenous ouabain-like activity ("ouabain") in the brain. In Wistar rats, resting mean arterial pressure (MAP) was significantly increased by long-term subcutaneous (SC) ouabain (75 microg/d) plus high salt (8%) intake for 12 days (but not after only 5 days). In rats with chronic sinoaortic denervation (SAD), MAP was increased within 5 days of ouabain treatment to the same extent as MAP after 12 days of treatment in intact rats. The effect of ouabain and high salt was prevented when digoxin was given SC concomitantly via osmotic minipump (200 microg x kg(-1) x d(-1)). Resting MAP was not changed in rats treated with digoxin alone. In a second set of rats with chronic SAD or sham surgery, high salt intake was given for 14 days, with or without SC digoxin (200 microg x kg(-1) x d(-1)) or intracerebroventricular (ICV) antibody Fab fragments (200 microg/d), which bind "ouabain" with high affinity. On day 14, MAP, central venous pressure, heart rate, and renal sympathetic nerve activity were recorded in conscious rats at rest and in response to air-jet stress, IV phenylephrine and nitroprusside, and acute volume expansion with 5% dextrose IV. In rats with SAD versus sham surgery, high salt significantly increased resting MAP as well as excitatory responses of MAP, heart rate, and renal sympathetic nerve activity to air stress. These effects of high salt in rats with SAD were prevented by digoxin or Fab fragments. Arterial baroreflex function was blunted but cardiopulmonary baroreflex function was not affected in rats with SAD. Digoxin and Fab fragments had no effects on either function. In an in vitro assay for the inhibitory effects on Na+, K(+)-ATPase activity, 20 ng of ouabain caused 29% inhibition, but 20 ng of ouabain plus 13 or 53 ng of digoxin caused only 16% or 4% inhibition, respectively. These data indicate that the arterial baroreflex opposes sympathoexcitatory responses to ouabain and "ouabain" in the brain, thereby delaying ouabain- and preventing high salt-induced hypertension in Wistar rats. In addition to possible effects on the arterial baroreflex, digoxin appears to act centrally to prevent the sympathoexcitatory and pressor effects of increased brain "ouabain" or ouabain.

Sinoaortic denervation produces sodium retention in Dahl salt-sensitive rats

The role of the arterial baroafferent signals in sodium (Na) homeostasis was examined in salt-sensitive rats. Sodium balances, water balances, and systolic arterial pressure (SAP) were measured for 3 weeks in sinoaortic denervated (SAD) or sham denervated (Sham) Dahl salt-sensitive (S) and salt-resistant (R) rats fed a standard-salt diet (0.4% NaCl). In R rats, there was no significant difference in Na balance, water balance, or SAP between the SAD and Sham animals. In the S rats, urinary Na excretion was suppressed in the SAD but not in the Sham animals, resulting in Na retention. SAD significantly increased SAP and mean arterial pressure. High salt challenge (8% NaCl diet) markedly increased SAP and Na and water balances in both S-SAD and S-Sham rats. However, no significant difference was found in SAP or cumulative Na and water balances between S-SAD and S-Sham rats. These results suggest that the baroafferent signals may have some role on the regulation of Na balance in salt-sensitive animals under a standard-salt condition, although a high-salt load masked the baroafferent-dependent sodium excretion.

Importance of cardiac, but not vascular, hypertrophy in the cardiac baroreflex deficit in spontaneously hypertensive and stroke-prone rats

In the present study, we examined whether antihypertensive treatment of young and adult hypertensive rats with the angiotensin-converting enzyme (ACE) inhibitor perindopril could restore the baroreflex vagal deficit and whether this was related to prevention of cardiac or vascular hypertrophy. Spontaneously hypertensive (SHR), stroke-prone spontaneously hypertensive (SHR-SP), and Wistar-Kyoto (WKY) rats were untreated or treated with perindopril (3 mg/kg/day) in the drinking water from 4-9 and from 14-20 weeks of age. Steady-state sigmoidal mean arterial pressure (MAP)-heart rate (HR) reflex curves were obtained in the conscious rats by the injection of pressor and depressor agents before and after atenolol (vagal component). Increased left ventricle to bodyweight ratio (LV/BW) indicated cardiac hypertrophy. After ganglion blockade, the minimum MAP produced by nitroprusside and the maximum produced by methoxamine were used as indications of vascular hypertrophy. Perindopril treatment reduced cardiac and vascular hypertrophy to different extents in SHR and SHR-SP. The 4-9 and 14-20 week treatments reduced MAP and both minimum and maximum blood pressure of the SHR to the levels of the untreated WKY. However, only in the older animals was LV/BW restored. In the SHR-SP, early treatment had a much greater effect on vascular hypertrophy than on LV/BW. The reverse occurred for the 14-20 week animals. In untreated hypertensive animals the baroreflex curves were shifted to the right with reduced vagal HR range. Perindopril treatment shifted the baroreflex curves back towards the WKY curves. Vagal HR range was strongly correlated with the LV/BW, whereas vagal HR range was less well related to the level of vascular hypertrophy or blood pressure. These results suggest that antihypertensive treatment can restore cardiac baroreflex function and that it is related to the reduction in cardiac hypertrophy. Although the mechanism of this relationship remains to be elucidated, these findings suggest that cardiac vagal afferents may be important.