Effect of paraventricular nucleus lesions on arterial pressure and heart rate after aortic baroreceptor denervation in the rat

Effect of carotid and aortic baroreceptors on cardiopulmonary reflex: the role of autonomic function

We determined the sympathetic and parasympathetic control of heart rate (HR) and the sensitivity of the cardiopulmonary receptors after selective carotid and aortic denervation. We also investigated the participation of the autonomic nervous system in the Bezold-Jarish reflex after selective removal of aortic and carotid baroreceptors. Male Wistar rats (220-270 g) were divided into three groups: control (CG, N = 8), aortic denervation (AG, N = 5) and carotid denervation (CAG, N = 9). AG animals presented increased arterial pressure (12%) and HR (11%) compared with CG, while CAG animals presented a reduction in arterial pressure (16%) and unchanged HR compared with CG. The sequential blockade of autonomic effects by atropine and propranolol indicated a reduction in vagal function in CAG (a 50 and 62% reduction in vagal effect and tonus, respectively) while AG showed an increase of more than 100% in sympathetic control of HR. The Bezold-Jarish reflex was evaluated using serotonin, which induced increased bradycardia and hypotension in AG and CAG, suggesting that the sensitivity of the cardiopulmonary reflex is augmented after selective denervation. Atropine administration abolished the bradycardic responses induced by serotonin in all groups; however, the hypotensive response was still increased in AG. Although the responses after atropine were lower than the responses before the drug, indicating a reduction in vagal outflow after selective denervation, our data suggest that both denervation procedures are associated with an increase in sympathetic modulation of the vessels, indicating that the sensitivity of the cardiopulmonary receptors was modulated by baroreceptor fibers.

Heterogeneous distribution of basal cyclic guanosine monophosphate within distinct neuronal populations in the hypothalamic paraventricular nucleus

The supraoptic (SON) and the paraventricular (PVN) hypothalamic nuclei constitute major neuronal substrates underlying nitric oxide (NO) effects on autonomic and neuroendocrine control. Within these nuclei, constitutively produced NO restrains the firing activity of magnocellular neurosecretory and preautonomic neurons, actions thought to be mediated by a cGMP-dependent enhancement of GABAergic inhibitory transmission. In the present study, we expanded on this knowledge by performing a detailed anatomical characterization of constitutive NO-receptive, cGMP-producing neurons within the PVN. To this end, we combined tract-tracing techniques and immunohistochemistry to visualize cGMP immunoreactivity within functionally, neurochemically, and topographically discrete PVN neuronal populations in Wistar rats. Basal cGMP immunoreactivity was readily observed in the PVN, both in neuronal and vascular profiles. The incidence of cGMP immunoreactivity was significantly higher in magnocellular (69%) compared with preautonomic ( approximately 10%) neuronal populations (P < 0.01). No differences were observed between oxytocin (OT) and vasopressin (VP) magnocellular neurons. In preautonomic neurons, the incidence of cGMP was independent of their subnuclei distribution, innervated target (i.e., intermediolateral cell column, nucleus tractus solitarii, or rostral ventrolateral medulla) or their neurochemical phenotype (i.e., OT or VP). Finally, high levels of cGMP immunoreactivity were observed in GABAergic somata and terminals within the PVN of eGFP-GAD67 transgenic mice. Altogether, these data support a highly heterogeneous distribution of basal cGMP levels within the PVN and further support the notion that constitutive NO actions in the PVN involve intricate cell-cell interactions, as well as heterogeneous signaling modalities.

Estrogen in the paraventricular nucleus attenuates L-glutamate-induced increases in mean arterial pressure through estrogen receptor beta and NO

Estrogen (E2) acts in the brain to decrease blood pressure (BP) responses to psychological stress. A likely site for the effects of E2 is the hypothalamic paraventricular nucleus (PVN), an important regulator of autonomic functions. We studied the effects of E2 in the PVN on BP and heart rate (HR) responses to l-glutamate injections into the PVN of male urethane-anesthetized rats. Microinjections of l-glutamate (50 nmol) into the PVN increased BP by 14+/-2.5 mm Hg and HR by 30+/-5.6 bpm. Microinjections of E2 (0.1, 1, and 10 pmol) into the PVN 30 minutes before l-glutamate dose-dependently attenuated the pressor response by 25%, 34%, and 59%, respectively, but did not affect HR. We determined that E2 receptor (ER) beta mediates the effect of E2, because activation of ERbeta with diarylpropionitrile (50 pmol) attenuated the response by 57%, whereas activation of ERalpha with propyl-pyrazole-triol (20 pmol) had no effect. Furthermore, inhibition of ERbeta with R,R-tetrahydrochrysene (50 pmol) blocked the effect of E2, but inhibition of ERalpha with methyl-piperidino-pyrazole (1 nmol) did not. Finally, we found that the effect of E2 is mediated by NO, because the NO synthase (NOS) inhibitor, N(G)-nitro-l-arginine methyl ester (2 nmol), the neuronal NOS inhibitor, 7-nitroindazole sodium salt (0.1 pmol), and the endothelial NOS inhibitor, N5-(1-iminoethyl)-l-ornithine (200 pmol) blocked the effect of E2. The effect was partially blocked with the gamma-aminobutyric acid(A) receptor inhibitor bicuculline. Our results demonstrate that E2 in the PVN attenuates the l-glutamate-induced pressor response and that this effect is mediated by ERbeta, NO produced by neuronal NO synthase and eNOS, and partly by gamma-aminobutyric acid.

Exercise Training Differentially Affects Intrinsic Excitability of Autonomic and Neuroendocrine Neurons in the Hypothalamic Paraventricular Nucleus

Oxytocinergic and vasopressinergic brain stem projections have been shown to play an important role in mediating cardiovascular adjustments during exercise training (ET). The aim of the present work was to determine whether the intrinsic excitability of hypothalamic neurons giving rise to brain stem peptidergic projections is altered as a consequence of ET. Whole cell patch-clamp recordings were obtained from nucleus of the solitarii tract (NTS)-projecting paraventricular nucleus of the hypothalamus (PVN) neurons and from supraoptic nucleus (SON) and PVN magnocellular cells (MNCs), in hypothalamic slices obtained from sedentary (S) and ET rats. Our results indicate that intrinsic excitability of PVN neurons that innervate the NTS (PVN-NTS) is enhanced by ET, resulting in a more efficient input-output function (increase number of evoked actions potentials, steeper frequency/current relationships and slower decaying frequency/time relationships). Changes in input-output function were accompanied by smaller hyperpolarizing afterpotentials (HAPs) and afterhyperpolarizing potentials (AHPs), during and after trains of spikes, respectively. On the other hand, a decreased efficacy in the input-output function was observed in SON/PVN MNCs during ET. Altogether, our results indicate that ET differentially affects the intrinsic excitability of autonomic and neurosecretory SON and PVN neurons. Increased excitability in PVN-NTS neurons may contribute to enhanced release of OT and VP peptides in the dorsal brain stem, and cardiovascular fine-tuning during exercise training.

Nitric oxide inhibits the firing activity of hypothalamic paraventricular neurons that innervate the medulla oblongata: role of GABA

Nitric oxide (NO) has been shown to modulate autonomic function by acting both peripherally and centrally. A growing body of evidence indicates that the paraventricular nucleus of the hypothalamus (PVN), an important site for autonomic and endocrine homeostasis, constitutes an important locus mediating central NO actions. However, the cellular targets and mechanisms mediating NO actions within the PVN are not completely understood. Here, we examined whether NO influences the firing activity of identified PVN neurons that innervate two functionally different autonomic centers, the dorsal vagal complex (DVC) and the rostral ventrolateral medulla (RVLM). Perforated patch-clamp recordings were performed in hypothalamic slices containing retrogradely labeled PVN neurons innervating the DVC or the RVLM. Application of the NO donors dyethylamine- or 1-propanamine, 3-(2-hydroxy-2-nitroso-1-propylhydrazino) NONOate inhibited the firing activity of both DVC- and RVLM-projecting PVN neurons. Furthermore, application of 2-(4-carboxypheny)-4,4,5,5,-tetramethilimidazoline-1-oxyl-3-oxide (carboxy-PTIO), or the relatively selective neuronal nitric oxide synthase (nNOS) inhibitor 7-nitroindazole alone, increased their basal firing activity, suggesting the presence of an endogenous NO inhibitory tone. GABAergic synaptic activity in PVN neurons was potentiated by NO donors, an action that involved a presynaptic mechanism. Furthermore, the NO-mediated inhibition of firing activity was blocked by the GABA(A) receptor antagonist bicuculline, suggesting that NO-inhibitory actions involved potentiation of local GABAergic synaptic activity. Immunohistochemical studies showed that approximately 25% of DVC- and RVLM-projecting PVN neurons express nNOS, suggesting that a proportion of these medullary-projecting PVN neurons contribute to the cellular source of NO within the PVN. In summary, NO has been identified as an important molecule controlling autonomic function under physiological and pathological conditions. Here, we provide information on the cellular mechanisms mediating central NO actions. Our results demonstrate for the first time that NO modulates the activity of identified populations of PVN neurons that innervate the medulla oblongata, an action that is likely mediated by enhancing synaptic GABAergic function. This work suggests that NO-GABA interaction in PVN neurons that innervate the medulla constitutes an efficient cellular mechanism mediating NO central regulation of autonomic function.

Nitric oxide: a local signalling molecule controlling the activity of pre-autonomic neurones in the paraventricular nucleus of the hypothalamus

AIM

The gas molecule nitric oxide (NO) has been shown to modulate autonomic function by acting both peripherally and centrally. Accumulating evidence indicates that the paraventricular nucleus (PVN) of the hypothalamus is an important locus mediating central NO actions on autonomic function, under both physiological and pathological conditions. However, the cellular targets and mechanisms mediating NO actions within the PVN are still poorly understood.

RESULTS

By combining in vitro patch-clamp recordings with neuronal tract tracing techniques, we show that neuronal excitability of autonomic-related neurones in the PVN is tonically inhibited by an endogenous NO input. Furthermore, immunohistochemical studies show that approximately 25% of autonomic-related PVN neurones express neuronal nitric oxide synthase, suggesting that at least a proportion of them contribute to the cellular sources of NO within the PVN.

CONCLUSION

In summary, this work suggests that NO modulation of the firing activity of autonomic-related PVN neurones constitutes an efficient mechanism mediated central NO regulation of autonomic function.

Inhibition of sympathetic responses at birth in sheep by lesion of the paraventricular nucleus

Birth is characterized by a surge in sympathetic outflow, heart rate (HR), mean arterial blood pressure (MABP) and circulating catecholamines. The paraventricular nucleus (PVN) of the hypothalamus is an important central regulatory site of sympathetic activity, but its role in the regulation of sympathoexcitation at birth is unknown. To test the hypothesis that the PVN regulates sympathetic activity at birth, experiments were performed in chronically instrumented near-term (137- to 142-day gestation, term 145 days) sheep before and after delivery by cesarean section. Stereotaxic guided electrolytic lesioning of the PVN (n = 6) or sham lesioning (n = 6) was performed 48 h before study. At 30 min after birth, renal sympathetic nerve activity (RSNA) increased 128 +/- 26% above fetal values in the sham-lesioned animals (P < 0.05). In contrast, at a similar time point, RSNA decreased to 52 +/- 12% of the fetal value in the PVN-lesioned animals. Lesioning of the PVN did not affect the usual postnatal increases in MABP and epinephrine levels although HR failed to rise above fetal values. ANG II but not arginine vasopressin or norepinephrine levels increased in PVN-lesioned animals after birth, whereas all three hormones increased (P < 0.05) in sham-lesioned animals. Fetal and newborn HR baroreflex responses were similar in both groups. However, the usual postnatal attenuation of baroreflex-mediated inhibition of RSNA was blunted in the PVN-lesioned group. The results of this study demonstrate that ablation of the PVN abolishes sympathoexcitation with birth at near-term gestation. The PVN may play a critical role in physiological adaptation at birth.

Renal afferents and hypertension

The kidney and the autonomic nervous system are linked through renal nerves. Activation of efferent renal sympathetic nerves leads to changes in renal vascular resistance, renin release, and Na(+) and water retention. Evidence also exists indicating that the kidney is not just a target organ of sympathetic activity, but also acts as a sensor. Afferent renal nerves have been shown to carry information from renal chemoreceptors, which respond to changes in the composition of the interstitial fluid environment, and mechanoreceptors, which monitor hydrostatic pressure changes within the kidney, to the central nervous system. These afferent renal nerve inputs alter the activity of central integrative neuronal circuits that normally give rise to command signals that influence the function of effector organs. Renal receptors, through their connections at different levels of the neuraxis, are able to reflexly influence not only cardiovascular function through changes in sympathetic nerve discharge to a variety of vascular beds and the hypothalamic release of vasopressin, but also the function of the kidney. This increased sympathetic activity and hormonal release induced by activation of afferent renal nerves has been implicated in hypertension of diverse etiologies.

Electrophysiological and morphological properties of pre-autonomic neurones in the rat hypothalamic paraventricular nucleus

1. The cellular properties of pre-autonomic neurones in the hypothalamic paraventricular nucleus (PVN) were characterized by combining in vivo retrograde tracing techniques, in vitro patch-clamp recordings and three-dimensional reconstruction of recorded neurones in adult hypothalamic slices. 2. The results showed that PVN pre-autonomic neurones constitute a heterogeneous neuronal population. Based on morphological criteria, neurones were classified into three subgroups. Type A neurones (52 %) were located in the ventral parvocellular (PaV) subnucleus, and showed an oblique orientation with respect to the third ventricle (3V). Type B neurones (25 %) were located in the posterior parvocellular (PaPo) subnucleus, and were oriented perpendicularly with respect to the 3V. Type C neurones (23 %) were located in both the PaPo (82 %) and the PaV (18 %) subnuclei, and displayed a concentric dendritic configuration. 3. A morphometric analysis revealed significant differences in the dendritic configuration among neuronal types. Type B neurones had the most complex dendritic arborization, with longer and more branching dendritic trees. 4. Several electrophysiological properties, including cell input resistance and action potential waveforms, differed between cell types, suggesting that the expression and/or properties of a variety of ion channels differ between neuronal types. 5. Common features of PVN pre-autonomic neurones included the expression of a low-threshold spike and strong inward rectification. These properties distinguished them from neighbouring magnocellular vasopressin neurones. 6. In summary, these results indicate that PVN pre-autonomic neurones constitute a heterogeneous neuronal population, and provide a cellular basis for the study of their involvement in the pathophysiology of hypertension and congestive heart failure disorders.

Transneuronal tracing from sympathectomized lumbar epaxial muscle in female rats

Pseudorabies virus (PRV) has been used as a transneuronal tracer to study central neural networks, including the central control of the lordosis-producing, lumbar epaxial muscles. Within muscles, however, the sympathetic innervation of blood vessels poses a confounding source of tracer labeling in the CNS. The present study destroyed sympathetic nerves before injection of PRV, thereby allowing for a more selective uptake by somatic motoneurons. Specifically, a focal sympathectomy was created by the injection of dopamine-beta-hydroxylase immunotoxin (DHIT). When PRV was injected into control rats, both somatic motoneurons within the ventral horn of the spinal cord and sympathetic preganglionic neurons within the intermediolateral column (IML) of the spinal cord became labeled. Additionally, labeled neurons were observed in many brain regions, including those previously implicated in the control of the lordosis reflex (e.g., the medullary reticular formation; MRF) and those previously implicated in the control of vasomotor tone (e.g., the rostral ventrolateral medulla; RVLM). When injected into DHIT-pretreated animals, PRV labeling in ventral horn neurons persisted in many animals; however, labeling in IML was eliminated in almost every case. In these animals, PRV labeling was absent in brain areas traditionally associated with vasomotor tone, such as RVLM, whereas labeling persisted in brain areas previously implicated in the control of the lordosis response, such as MRF. The results support the connectivity of spinal and medullary structures with the somatic control of the lordosis-producing muscles and provide a more detailed description of these portions of the putative lordosis-relevant neurocircuitry.

Commissural NTS lesions and cardiovascular responses in aortic baroreceptor-denervated rats

Both acute (1 day) lesions of the commissural nucleus of the solitary tract (commNTS) and aortic baroreceptor denervation increase pressor responses to bilateral common carotid occlusion (BCO) during a 60-second period in conscious rats. In this study, we investigated the following: (1) the effects of commNTS lesions on basal mean arterial pressure (MAP) and heart rate (HR) of aortic denervated (ADNx) rats; (2) the effects of acute commNTS lesions on pressor responses to BCO in ADNx rats; and (3) the effects of chronic (10 days) commNTS lesions on the pressor response to BCO. ADNx increased basal MAP and HR in sham-lesioned rats. Acute commNTS lesions abolished the MAP and HR increases observed in ADNx rats. Acute commNTS lesions increased the pressor responses to BCO in rats with intact-baroreceptor innervation but produced no additional change in the pressor response to BCO in ADNx rats. Chronic commNTS lesions did not change the pressor responses to BCO in rats with intact-baroreceptor innervation. The data show that acute commNTS lesions abolish the MAP increase produced by aortic baroreceptor denervation. They also suggest that acute commNTS lesions enhance the pressor response to BCO by partial withdrawal of aortic baroreceptor inputs into the NTS. Chronically, reorganization in the remaining aortic baroreceptor or in the baroreflex function as a whole might produce normalization of the cardiovascular responses to BCO.

Spontaneous activity and barosensitivity of the barosensitive neurons in the rostral ventrolateral medulla of hypertensive rats induced by transection of aortic depressor nerves

In order to determine the role of the rostral ventrolateral medulla (RVLM) in the development of neurogenic hypertension, the aortic depressor nerves of rats were transected (tADN) to produce neurogenic hypertension. The rate and pattern of firing of the barosensitive RVLM neurons of the treated rats were studied. In neurogenic hypertensive rats, the RVLM barosensitive neurons exhibited a faster firing rate and a shorter interspike interval (ISI) than the corresponding values of the control and sham groups, indicating an enhanced spontaneous activity of these neurons in the hypertensive rats. The coefficient of variation (cv) and skewness (sk) of the ISI histogram, parameters reflecting the regularity of neuronal firing, were smaller in neurogenic hypertensive than in the control and sham-operated rats. Following tADN, the responsiveness of these neurons to blood pressure changes was attenuated, suggesting a reduced intrinsic barosensitivity of neurons and/or a reduced baroreceptor input. The increase in spontaneous activity and firing regularity of RVLM barosensitive neurons imply an enhancement in the efficacy of outflow from these neurons. The increased efficacy of the outflow from the RVLM barosensitive neurons and the resetting of the baroreflex may contribute to the genesis of neurogenic hypertension.

Afferent renal inputs to paraventricular nucleus vasopressin and oxytocin neurosecretory neurons

Extracellular single-unit recording experiments were done in pentobarbital sodium-anesthetized rats to investigate the effects of electrical stimulation of afferent renal nerves (ARN) and renal vein (RVO) or artery (RAO) occlusion on the discharge rate of putative arginine vasopressin (AVP) and oxytocin (Oxy) neurons in the paraventricular nucleus of the hypothalamus (PVH). PVH neurons antidromically activated by electrical stimulation of the neurohypophysis were classified as either AVP or Oxy secreting on the basis of their spontaneous discharge patterns and response to activation of arterial baroreceptors. Ninety-eight putative neurosecretory neurons in the PVH were tested for their response to electrical stimulation of ARN: 44 were classified as putative AVP and 54 as putative Oxy neurons. Of the 44 AVP neurons, 52% were excited, 7% were inhibited, and 41% were nonresponsive to ARN stimulation. Of the 54 Oxy neurons, 43% were excited, 6% inhibited, and 51% were not affected by ARN. An additional 45 neurosecretory neurons (29 AVP and 16 Oxy neurons) were tested for their responses to RVO and/or RAO. RVO inhibited 42% of the putative AVP neurons and 13% of the putative Oxy neurons. On the other hand, RAO excited 33% of the AVP and 9% of the Oxy neurons. No AVP or Oxy neurons were found to be excited by RVO or inhibited by RAO. These data indicate that sensory information originating in renal receptors alters the activity of AVP and Oxy neurons in the PVH and suggest that these renal receptors contribute to the hypothalamic control of AVP and Oxy release into the circulation.

Food restriction attenuates the blood pressure response to paraventricular hypothalamic nuclei lesions in aortic coarctation hypertension

Chronic food restriction reduces blood pressure (BP) and sympathetic support of BP in aortic coarctation hypertension. The purpose of this study was to test the hypothesis that chronic food restriction would reduce sympathetic support of BP mediated by the paraventricular hypothalamic nuclei (PVN). Hypertension was induced in male Sprague-Dawley rats (n=40) by suprarenal aortic coarctation. Rats were assigned to either an ad libitum fed (AL) group or a food restricted (FR) group that received 60% of the food consumed by AL for 3 weeks. One week prior to data collection, catheters were implanted in the left carotid artery and right jugular vein. BP was measured for 2 days prior to, and 7 days after rats in AL and FR groups received either bilateral electrolytic lesions of the PVN (PVNx) or sham lesions (SHAM). Prior to either PVNx or SHAM, FR rats had significantly lower BP (AL=152+/-5; FR=113+/-2 mmHg), less of a depressor response to ganglionic blockade (AL=-58+/-4; FR=-35+/-2 mmHg), and lower plasma norepinephrine levels (AL=758+/-71; FR=380+/-23 pg/ml) compared to AL. PVNx reduced BP in both AL and FR rats (AL-PVNx=105+/-6 mmHg, FR-PVNx=101+/-3 mmHg). PVNx also lowered the depressor response to ganglionic blockade (AL-PVNx=-28+/-5 mmHg, FR-PVNx=-29+/-4 mmHg) and plasma norepinephrine levels (AL-PVNx=372+/-74 pg/ml, FR-PVNx=248+/-31 pg/ml). FR decreased the magnitude of the reductions in resting BP and in sympathetic activity in response to PVNx. These results indicate that intact PVN are required for maintenance of aortic coarctation hypertension, and implicate the PVN as a site involved in BP reductions produced by chronic food restriction.

Effect of aortic baroreceptor deafferentation on plasma vasopressin and oxytocin in the conscious rat

Experiments were done in conscious, unrestrained rats to investigate the effects of selective aortic baroreceptor deafferentation (ABD) on circulating levels of the neurohypophysial hormones arginine vasopressin (AVP) and oxytocin (OXY). Plasma concentration of AVP and OXY were measured by radioimmunoassay before and 1-13 days after cutting the aortic depressor nerves, bilaterally. Arterial pressure was significantly elevated by approximately 12-39 mmHg above control levels after ABD. On day one after ABD, plasma AVP increased from control levels of 3.21 +/- 1.56 pg/ml to 8.29 +/- 4.66 pg/ml (258%) and plasma OXY increased from 2.53 +/- 4.24 pg/ml to 8.16 +/- 1.49 pg/ml (323%). However, by the third day after ABD, plasma AVP and OXY levels had returned to pre-ABD control levels. On days 8 and 13 after ABD, AVP levels were elevated again by approximately 2- and 9-fold, respectively, whereas the OXY levels remained at control levels. These data suggest that in the awake rat, the release of AVP and OXY is modulated differentially after ABD and that the increased circulating levels of AVP may be one of the mechanisms that contributes to the elevated arterial pressure in neurogenic hypertension.

Changes in ganglion nodosum neurons associated with stress-related cardiac deficiency

Cell bodies of cardio-vascular receptors localized in the ganglion nodosum of rabbits exposed to experimental emotional stress were studied with the light and electron microscope and histochemically. Under emotional stress some rabbits demonstrated almost unchanged arterial pressure and only a small increase in heart rate, while other animals displayed strongly marked disturbances of their blood circulation leading to the acute heart deficiency at the end of the experiment. In the stress-resistant rabbits, microscopic anatomy and ultrastructure of neurons indicated their increased activity. Activities of lysosomal enzymes--acid phosphatase and aminopeptidase--were found to be at the control level, while the activity of mitochondrial enzyme--glutamate dehydrogenase--was slightly increased. On the other hand morphological evidence of severe hyperactivity and exhaustion was revealed in neurons of the stress-predisposed rabbits. Moreover the activities of all three enzymes studied were significantly increased. These results indicate correlation between the structural and metabolic changes occurring under experimental emotional stress in nodosal neurons and the extent of hemodynamic changes.

Lesions in rostral ventromedial or rostral ventrolateral medulla block neurogenic hypertension

Neurogenic hypertension results from the removal of inhibitory baroreceptor afferent input to vasomotor systems in the central nervous system. We sought to determine whether the bilateral destruction of neurons in the rostral ventrolateral or rostral ventromedial medulla, made using microinjections of N-methyl-D-aspartic acid (30 nmol in 200 nL), would block the acute increase in arterial pressure after sinoaortic deafferentation in pentobarbital-anesthetized rats. Bilateral lesions of the rostral ventrolateral or rostral ventromedial medulla decreased mean arterial pressure (107 +/- 4 to 78 +/- 5 and 115 +/- 3 to 94 +/- 3 mm Hg, respectively). In rostral ventrolateral or rostral ventromedial medulla lesioned rats, sinoaortic deafferentation failed to increase arterial pressure. Sham lesions or lesions placed rostral to the rostral ventrolateral or rostral ventromedial medulla did not significantly lower arterial pressure. Subsequent sinoaortic deafferentation significantly increased mean arterial pressure (109 +/- 3 to 145 +/- 4 and 109 +/- 5 to 141 +/- 3 mm Hg, respectively). In eight rats we used an infusion of angiotensin II to return arterial pressure to control levels after lesion of the rostral ventrolateral (n = 4) or rostral ventromedial (n = 4) medulla. In these animals, sinoaortic deafferentation failed to increase arterial pressure. We conclude that neurons in the rostral ventrolateral and rostral ventromedial medulla are involved in the normal maintenance of arterial pressure and the development of hypertension after sinoaortic deafferentation in pentobarbital-anesthetized rats.

Neurons in the hypothalamic paraventricular nucleus mediate the serotonergic stimulation of renin secretion

The aim of the present study was to resolve which hypothalamic nucleus is necessary for the serotonergic control of renin secretion. RU 24969 is considered a serotonin (5-HT1A/5-HT1B) agonist, while p-chloroamphetamine is a 5-HT releaser. Both drugs reliably elevate plasma levels of renin when injected peripherally. Previous studies suggest that serotonergic neurons, projecting to the hypothalamus, mediate the effect of p-chloroamphetamine on renin secretion. Discrete cell-selective lesions were made with ibotenic acid in three hypothalamic sites: the paraventricular, the dorsomedial or the ventromedial nuclei. Two weeks after surgery rats were injected with RU 24969 (5 mg/kg, i.p.) or p-chloroamphetamine (8 mg/kg, i.p.). The renin response to both RU 24969 and p-chloroamphetamine was significantly reduced in rats with histologically verified paraventricular lesions compared to vehicle treated controls. In contrast, the renin response to p-chloroamphetamine remained unchanged in rats with either dorsomedial or ventromedial hypothalamic lesions. Thus, these results are consistent with the hypothesis that 5-HT receptors located on cell bodies in the paraventricular nucleus mediate the renin response to a serotonin agonist and releaser. Furthermore, they confirm previous studies that suggest that 5-HT neurons regulate renin secretion through central receptors.

Sympathoadrenal control by paraventricular hypothalamic beta-endorphin in hypertension

The paraventricular hypothalamus regulates autonomic nerve outflow and is innervated with beta-endorphin-immunoreactive nerve terminals. This study examined the effects of beta-endorphin microinjected into the paraventricular hypothalamus on blood pressure, heart rate, and plasma catecholamine and glucose concentrations in conscious, unrestrained spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats at the age of about 9 weeks. Thirty minutes after paraventricular hypothalamic injection of [125I] beta-endorphin (3.5 micrograms), most of the recovered radioactivity was detectable within +/- 0.5 mm from the injection site in the coronal, sagittal, and horizontal planes. Unilateral paraventricular hypothalamic injections of beta-endorphin (1 and 0.1 microgram/0.1 microliter) increased blood pressure and heart rate in both strains in a dose-independent manner with significantly greater increases in SHR. Plasma catecholamine and glucose concentrations were measured 15, 30, and 60 minutes after beta-endorphin injection. Norepinephrine concentrations were not significantly altered in WKY rats but increased in SHR. Epinephrine concentrations increased in both strains with significantly greater increases in SHR. Increases in catecholamine concentrations were not dose-related. Glucose concentrations also increased in both strains with significantly greater increases in SHR only at the lower dose. Ganglionic blockade with pentolinium significantly reduced beta-endorphin-induced pressor and tachycardiac responses in SHR. Pretreatment of the paraventricular hypothalamus with naltrexone (1.1 micrograms) in SHR blocked the initial pressor and tachycardiac responses to beta-endorphin (0.1 microgram) and blunted increases in epinephrine and glucose levels. When the animals were anesthetized with alpha-chloralose 2-5 days after the study in conscious animals, there were no differences in blood pressure or heart rate between strains after beta-endorphin (0.1 microgram) injection. The results indicate that conscious SHR show enhanced cardiovascular and sympathoadrenal responses to beta-endorphin injected into the paraventricular hypothalamus, suggesting that alterations in the activity of the paraventricular hypothalamic beta-endorphin system can modulate the development of hypertension in SHR.

Cardiovascular responses to bicuculline in the paraventricular nucleus of the rat

The present study was undertaken to determine whether gamma-aminobutyric acid in the paraventricular nucleus contributes to the regulation of cardiovascular function. Blood pressure and heart rate were recorded and plasma catecholamines were measured in conscious rats receiving microinfusions of either artificial cerebrospinal fluid or a gamma-aminobutyric acid antagonist, bicuculline methiodide, bilaterally into the paraventricular nucleus. Artificial cerebrospinal fluid had no effect on any of the recorded variables. In contrast, infusion of bicuculline into the region of the paraventricular nucleus produced increases in blood pressure (20 +/- 2 mm Hg), heart rate (110 +/- 11 beats/min), and plasma concentrations of norepinephrine (640 +/- 107 pg/ml) and epinephrine (1,266 +/- 267 pg/ml). Pretreatment with a ganglionic blocking agent abolished both the blood pressure (-1 +/- 2 mm Hg) and heart rate (5 +/- 18 beats/min) effects. Bilateral adrenal medullectomy reduced the changes in plasma norepinephrine concentrations (81 +/- 14 pg/ml) significantly and abolished the changes in plasma epinephrine concentrations (5 +/- 4 pg/ml). Conversely, adrenal medullectomy reduced the pressor effects (18 +/- 2 mm Hg) only slightly while the heart rate responses were attenuated (42 +/- 9 beats/min) by approximately 50%. These results suggest that an endogenous gamma-aminobutyric acid system exerts a tonic inhibitory effect on the sympathetic nervous system at the level of the paraventricular nucleus of the hypothalamus.

Central regulation of stress responses: regulation of the autonomic nervous system and visceral function by corticotrophin releasing factor-41

Our understanding of the role of CRF in mediating integrated endocrine, autonomic and visceral stress responses is rudimentary at best. Delineating the large number of neurochemical factors that influence the activity of CRF-containing hypophyseotrophic neurones offers one direction for future research in this area. Another approach might be to examine the neuropharmacological actions of transmitters which are co-localized within CRF-containing neurones. For example, CRF and dynorphin-related peptides coexist within a subpopulation of paraventricular neurones (Roth et al, 1983), suggesting the potential for their simultaneous release and possible functional interactions between them. Interestingly, CRF and dynorphin-related peptides exhibit reciprocal actions on the release of each other in vitro and in vivo. CRF stimulates the release of immunoreactive dynorphin from rat hypothalamic slices (Nikolarakis et al, 1986) while dynorphin A1-17 inhibits the basal secretion of immunoreactive CRF from rat hypothalami (Yajima et al, 1986). In vivo experiments demonstrate that i.c.v. administration of dynorphin A1-13 reduces basal and hypotension-induced secretion of CRF into hypophyseal portal blood (Plotsky, 1986). Recent studies suggest that, in addition to their interactions at the level of release, these peptides may also modify the CNS actions of each other on autonomic and cardiovascular function (Overton and Fisher, 1989b). Thus, CRF-induced elevations of arterial pressure, heart rate and plasma catecholamine levels are attenuated by co-administration of low doses of dynorphin A1-17. The reciprocal release actions and neuropharmacological interactions between CRF and dynorphin A1-17 suggest that local integration or perhaps feedback regulation of stress-induced autonomic and cardiovascular responses may be achieved by the co-release of multiple neurotransmitters from a single source. In summary, the combined anatomical, pharmacological and physiological data provide support for the involvement of CRF neuronal systems in mediating the integration of endocrine, autonomic, and visceral functions, particularly in response to stress. Future research in this area may contribute to our understanding of the neurobiology of CRF as well as the CNS mechanisms governing homeostasis.

Excitotoxic lesions of the paraventricular hypothalamus: metabolic and cardiac effects

The excitotoxin, N-methyl-D-aspartic acid (NMDA), was used to lesion cell bodies, but not fibers-of-passage, in the paraventricular hypothalamus. Bilateral injections of NMDA (12.6 nmol/100 nl) were made into the paraventricular hypothalamus in halothane-anesthetized male Sprague-Dawley rats. Water intake, food intake, urine output and body weight were measured daily for 26 days after lesioning. Lesioned rats exhibited a modest, but significant, reduction in the rate of gain of body weight, which was most closely correlated with decreases in food intake. Water intake and urine output were not significantly different among the groups. Resting blood pressure, heart rate and baroreflex sensitivity (using the infusion of phenylephrine method) were similar in conscious animals of both groups, 4-5 weeks after lesioning. Neuronal loss, primarily of parvocellular elements, was evident in the paraventricular hypothalamus and neuronal loss frequently extended into the ventro-medial thalamus adjacent to the paraventricular hypothalamus in NMDA-lesioned rats. In a second experiment, injections of NMDA were given acutely into the paraventricular hypothalamus of halothane-anesthetized rats. Upon recovery from anesthesia, behavioral excitation and increases in blood pressure and heart rate were evident for 1-2 hr. Histological examination of hearts taken 48 hr after injection of NMDA revealed a largely mononuclear inflammatory infiltration, hyperemia and myocardial hemorrhage and focal myocardial necrosis. Inflammatory and degenerative changes were most prominent in the left ventricular subendocardium. The cardiomyopathy possessed similarities with catecholamine-induced myocardial necrosis. The results indicated that NMDA-induced lesions of parvocellular elements of the paraventricular hypothalamus did not cause hyperphagia or obesity or alter the resting systemic circulatory function. However, an inflammatory cardiomyopathy, termed "excitotoxin-induced myocardial necrosis", was associated with injections of NMDA into the hypothalamus. Excitotoxin-induced myocardial necrosis may complicate any hemodynamic studies performed in rats in which lesions of the CNS have been produced by means of application of excitotoxins.

Excitotoxin-induced myocardial necrosis

The excitotoxins, kainic acid and N-methyl-D-aspartic acid (NMDA), were injected bilaterally into the paraventricular hypothalamus of rats. Kainic acid elicited pressor responses, tachycardia and sudden cardiac death in Nembutal-anesthetized rats. Injections of NMDA caused cardiovascular stimulation on cessation of halothane anesthesia. Intramyocardial hemorrhage, hyaline myocardial necrosis and predominantly mononuclear inflammation were evident 48 h following NMDA. Labetalol pretreatment did not protect from nor did i.v. NMDA cause these changes. Intrahypothalamic excitotoxin injections cause deleterious myocardial changes.

Effect of septal ablation on choline acetyltransferase in the paraventricular nucleus

To determine whether there is a cholinergic projection from the lateral septum to the paraventricular nucleus of the hypothalamus (PVH), a quantitative histochemical analysis of the effects of unilateral ablation (0.5 microliter of a 10 micrograms/ml solution of ibotenic acid) of the lateral septum (LSV) on the choline acetyltransferase (ChAT) activity of the PVH and surrounding perinuclear area was undertaken. Comparisons of the ChAT activity of the PVH region ipsilateral to the LSV lesion (lesioned side) with that of the PVH contralateral (nonlesioned side) to the ablated LSV showed a 20% reduction (p less than 0.05) of ChAT activity in 2 areas of the PVH on the lesioned side. When ChAT activity of LSV-ablated and intact control rats was compared, a 20% difference in activity (p less than 0.05) was noted in four areas on the nonlesioned side and a 35% difference (p less than 0.05) of ChAT activity was noted in five regions of the PVH on the lesioned side of LSV-ablated animals. Taken together these data suggest that the pathway from the LSV to the PVH contains a small, bilateral cholinergic component. However, the data also indicate that this is not the only cholinergic projection to the PVH.

The renin response to aortic occlusion is enhanced by stimulation of the hypothalamus

The sympathetic nervous system is an important factor that can induce increased renin secretion by the kidney. In recent years, the notion has arisen that the sympathetic nervous system may also function to set the level of responsiveness of the kidney to nonneural stimuli for renin secretion. However, evidence in favor of this possibility has come primarily from studies employing direct electrical stimulation of renal nerves, and no attempt has been made to determine if central neural sites can also influence the responsiveness of the kidney. In the present study, the ability of hypothalamic activation to enhance the renin response to suprarenal aortic occlusion was investigated. Conscious, freely moving rats with an inflatable cuff placed around the aorta were used to determine the relationship between renal-perfusion pressure and plasma renin activity in the control state and during continuous low-level stimulation of the paraventricular nucleus. The stimulation resulted in a rightward shift in the curve that related renal perfusion pressure to plasma renin activity; that is, for any given decrease in renal perfusion pressure, the plasma renin activity was greater during the ongoing stimulation. This rightward shift appeared to be mediated by increased renal nerve activity, since renal denervation prevented the shift. These data indicate that the hypothalamus, which plays an important role in regulating sympathetic activity, is capable of increasing the sensitivity of the kidney to a nonneural stimulus for renin secretion. This effect may become important in certain hypertensive and prehypertensive states where central neural activity is thought to be enhanced.

Electrophysiological properties of paraventriculo-spinal neurones in the rat

In rats anaesthetized with urethane, electrical stimulation of the thoracic cord at T9-10 evoked antidromic response in neurones in the parvocellular portion of the ipsilateral paraventricular nucleus. Estimated conduction velocities in the spinally-projecting axons ranged from 0.6-5.9 m/sec. The majority (97%) of spinally projecting neurones were quiescent. Increases or decreases in the level of baroreceptor stimulation produced by intravenous injection of phenylephrine (1-5 micrograms) or sodium nitroprusside (10-15 micrograms) inhibited and excited amino acid-induced activity in 5/8 and 4/11 neurones respectively. Stimulation of vagal afferent endings by rapid bolus injection of 5-HT, to evoke the Bezold-Jarisch reflex. inhibited amino acid-induced activity in 15/18 cells. Activation of gastric vagal afferents by distension of the stomach had no effect on paraventriculo-spinal cells. It is suggested that at rest the excitability of paraventriculo-spinal neurones is depressed by a tonic inhibitory input which arises from vagal afferent fibres in the heart.

Role of paraventricular nucleus (PVH) in baroreflex-mediated changes in lumbar sympathetic nerve activity and heart rate

Electrophysiological and neuroanatomical studies indicate that reciprocal connections between the paraventricular nucleus (PVH) and medullary sites are involved in cardiovascular regulation. To determine whether the PVH is involved in the regulation of baroreflex responses, lumbar sympathetic nerve activity (LSNA) and heart rate (HR) changes were recorded in response to increases in arterial pressure (produced by bolus doses of phenylephrine i.v.) prior to, during, and 60 min following the injection of lidocaine (2% lidocaine, 200 nl) bilaterally in the PVH of chloralose-anesthetized rabbits. Baseline blood pressure, HR, and LSNA did not change in response to the administration of lidocaine in the PVH. The magnitude of 'baroreflex responses' in HR and LSNA were expressed as the ratios of maximal changes in these parameters divided by the corresponding maximal changes in blood pressure. Application of lidocaine to the PVH produced a significantly greater decrease in LSNA (greater than 50%) compared to prelidocaine responses to baroreceptor stimulation. This increase in baroreflex response returned to the normal level during the recovery phase. In contrast, there was no significant change in the response of the HR to baroreceptor stimulation. Administration of norepinephrine into the PVH, intended to simulate possible changes in noradrenergic function, did not affect either LSNA or HR responses to baroreceptor stimulation. Interruption of neural activity in the PVH, augmented the inhibitory response of LSNA but not HR to baroreceptor stimulation. These results indicate that changes in peripheral sympathetic nerve activity and HR in response to baroreceptor activation may be affected differentially by specific forebrain structures such as PVH.

Paraventricular lesions: hormonal and cardiovascular responses to hemorrhage

The responses of adrenocorticotropin (ACTH), renin, epinephrine and norepinephrine and arterial pressure and heart rate (HR) to hypotensive hemorrhage were examined before and 1 h after lesion of the paraventricular nuclei (PVN) in pentobarbital-anesthetized rats and 1 day before and 4 days after lesion of the PVN in conscious rats. The ACTH response to hemorrhage was abolished 1 h (n = 8) and 4 days (n = 14) after PVN lesion whereas the ACTH response in the sham groups (in both anesthetized and conscious studies, n = 8 and 16 respectively) remained intact. PVN lesion had no effect on basal ACTH levels 4 days after lesion. The responses of renin, epinephrine, norepinephrine and mean arterial blood pressure (MABP) and HR to hemorrhage were not affected 1 h or 4 days after PVN lesion. Resting levels of the above variables did not change 4 days after lesion. The PVN lesion had a small (but significant) effect on the baroreceptor reflex in the conscious study (reflex changes in HR caused by phenylephrine- or nitroglycerin-induced change in MABP) and had no effect on the baroreceptor reflex in the anesthetized study. The group with PVN lesions gained more weight 6 days after lesion than the group with sham lesions. We conclude that the PVN are part of a neural pathway involved in ACTH regulation during perturbations of the cardiovascular system and on weight gain and that PVN lesions have little or no effect on resting or stimulated (hemorrhage) levels of renin, epinephrine, norepinephrine, HR and MABP or on the baroreceptor reflex.

Contribution of forebrain mechanisms in the maintenance of deoxycorticosterone acetate-salt hypertension

A considerable amount of experimental evidence exists suggesting that forebrain structures are involved in the pathogenesis of hypertension. In particular, the paraventricular nucleus of the hypothalamus (PVH) has been implicated in the development and maintenance of the elevated arterial pressure (AP) in several different experimental models of hypertension. The present study was done to determine whether the PVH contributed to the maintenance of the increased AP in deoxycorticosterone acetate-salt (DOCA) hypertension in the rat. In the first series of experiments, using the hexokinase histochemical method, increased metabolic activity was observed in the PVH of DOCA-salt hypertensive rats. In addition, the lateral septal nucleus, median preoptic nucleus, bed nucleus of the stria terminalis, subfornical organ, nucleus circularis, supraoptic nucleus and central nucleus of the amygdala were observed to have increased metabolic activity. In the second series of experiments, bilateral lesions of the PVH resulted in a transient reduction in the elevated AP of DOCA-salt hypertensive animals. However, within approximately a week, the level of AP was not significantly different from sham-PVH lesioned DOCA-salt hypertensive rats. These data suggest that the PVH may be one of several forebrain structures that contributes to the elevated sympathetic activity in DOCA-salt hypertension and when absent other pressor systems are recruited to maintain the elevated AP.

Effect of transection in the brainstem on short-term maintenance of deoxycorticosterone-salt hypertension

Sections were made to determine supraspinal areas that participate in the maintenance of deoxycorticosterone (DOC)-salt hypertension. Blood pressure (BP) falls after cuts which severed: (a) the lateral connections between pons and midbrain, (b) the pathways between caudal hypothalamus and midbrain, and (c) parasagittal connections between medial and lateral hypothalamus. No changes in BP were found either after coronal cuts that severed a central area located at: (a) the pons-midbrain edge, (b) above the caudal hypothalamus, and (c) the level of the anterior hypothalamic area, or after parasagittal cuts at the level of the capsula interna or after a hypophysial stalk lesion. These results implicate the hypothalamus in the maintenance of DOC-salt hypertension. The hypothalamus-neural lobe system appears not to be involved in the lowering of BP found.

Kainic acid lesions of paraventricular nucleus neurons reverse the elevated arterial pressure after aortic baroreceptor denervation in the rat

The effect of selective destruction of neurons of the paraventricular nucleus of the hypothalamus (PVH) with kainic acid on the maintenance of the elevated arterial pressure (AP) and heart rate (HR) after aortic baroreceptor denervation was investigated in male Wistar rats. The average AP and HR were significantly elevated in two groups of animals which were subjected to bilateral aortic depressor nerve (ADN) transection compared to sham-ADN-transected animals. Microinjections of kainic acid bilaterally into the PVH-reduced the elevated AP and HR in ADN-transected animals to levels which were not significantly different from either sham-ADN-transected animals which received kainic acid injections into the PVH or from predenervation levels. AP and HR in the sham-ADN-transected animals which received bilateral PVH injections of kainic acid were not altered from prelesioned levels. As magnocellular neurons of the PVH have been shown to be resistant to the neurotoxic effects of kainic acid, these data indicate that PVH parvocellular neurons are required for the maintenance of the elevated AP and HR resulting from the removal of aortic baroreceptor inputs to the central nervous system.