Presympathetic Vasomotor Neurons Research Articles

The differential modulation of the baroreflex control mechanism in fight, flight or freeze behaviour.

The differential modulation of the baroreflex control mechanism in fight, flight or freeze behaviour.

L-Cysteine and L-AP4 microinjections in the rat caudal ventrolateral medulla decrease arterial blood pressure.

The thiol amino acid L-cysteine increases arterial blood pressure (ABP) when injected into the cerebrospinal fluid space in conscious rats, indicating a pressor response to centrally acting L-cysteine. A prior synaptic membrane binding assay suggests that L-cysteine has a strong affinity for the L-2-amino-4-phosphonobutyric acid (L-AP4) binding site. The central action of L-cysteine may be vial-AP4 sensitive receptors. The present study investigated cardiovascular responses to L-cysteine and L-ap4 microinjected into the autonomic area of the caudal ventrolateral medulla (CVLM) where inhibitory neurons regulate ABP via pre-sympathetic vasomotor neurons. Both the injection of L-cysteine and L-AP4 in the CVLM sites identified with L-glutamate produced the same depressor and bradycardic responses in urethane-anesthetized rats. Neither a prior antagonist microinjection of MK801 for the N-methyl-D-aspartate (NMDA) receptor nor CNQX for the non-NMDA receptor attenuated the responses to L-cysteine, but the combination of the two receptor blocking with an additional prior injection abolished the response. In contrast, either receptor blockade alone abolished the response to L-AP4, indicating distinct mechanisms between responses to L-cysteine and L-AP4 in the CVLM. The results indicate that the CVLM is a central active site for L-cysteine's cardiovascular response. Central L-cysteine's action could be independent of the L-AP4 sensitive receptors. Cardiovascular regulation may involve endogenous L-cysteine in the CVLM. Further multidisciplinary examinations are required to elaborate on L-cysteine's functional roles in the CVLM.

Expression of the ghrelin receptor gene in neurons of the medulla oblongata of the rat

There is ambiguity concerning the distribution of neurons that express the ghrelin receptor (GHSR) in the medulla oblongata. In the current study we used a sensitive nonradioactive method to investigate GHSR mRNA distribution by in situ hybridization. Strong expression of the GHSR gene was confirmed in neurons of the facial nucleus (FacN, 7), the dorsal vagal complex (DVC), and the semicompact (but not compact) nucleus ambiguus (AmbSC and AmbC). In addition, expression of GHSR was found in other regions, where it had not been described before. GHSR-positive neurons were observed in the gustatory rostral nucleus tractus solitarius and in areas involved in vestibulo-ocular processing (such as the medial vestibular nucleus and the nucleus abducens). GHSR expression was also noted in ventral areas associated with cardiorespiratory control, including the gigantocellular reticular nucleus, the lateral paragigantocellular nucleus, the rostral and caudal ventrolateral medulla, the (pre)-Bötzinger complex, and the rostral and caudal ventrolateral respiratory group. However, GHSR-positive neurons in ventrolateral areas did not express markers for cardiovascular presympathetic vasomotor neurons, respiratory propriobulbar rhythmogenic neurons, or sensory interneurons. GHSR-positive cells were intermingled with catecholamine neurons in the dorsal vagal complex but these populations did not overlap. Thus, the ghrelin receptor occurs in the medulla oblongata in 1) second-order sensory neurons processing gustatory, vestibulo-ocular, and visceral sensation; 2) cholinergic somatomotor neurons of the FacN and autonomic preganglionic neurons of the DMNX and AmbSC; 3) cardiovascular neurons in the DVC, Gi, and LPGi; 4) neurons of as yet unknown function in the ventrolateral medulla.

392 OBESITY-RELATED HYPERTENSION IS ASSOCIATED WITH ALTERED SENSITIVTY OF CARDIOVASCULAR CONTROLLING NEURONS IN THE ROSTROVENTROLATERAL MEDULLA

Background: The gut and kidneys command >50% cardiac output postprandially, highlighting the importance of blood flow regulation to these regions. The gut hormone cholecystokinin (CCK) acts at vagal afferents to induce renal and splanchnic sympathoinhibition and vasodilation, via reflex inhibition of a subclass of cardiovascular-controlling neurons in the rostroventrolateral medulla (RVLM). Since these responses are blunted in obese hypertensive rats, our aim was to determine whether this is due to altered sensitivity of RVLM neurons. Methods: Male Sprague-Dawley rats (n = 32) were placed on a medium high fat diet (MHFD; n = 24) or low fat diet (LFD, control animals; n = 8) for 15 weeks. MHFD rats were classified as obesity prone (OP; upper tertile weight gain; n = 8) or obesity resistant (OR; lower tertile weight gain n = 8). In anaesthetized, artificially ventilated animals, arterial pressure (AP) and heart rate were monitored. Electrophysiological techniques were used to identify RVLM presympathetic vasomotor neurons, and responsiveness to CCK tested (0.05 – 4ug/kg; i.a.). Results: OP animals had elevated resting AP compared to OR/control animals (P < 0.05). Barosensitivity of RVLM neurons was significantly attenuated in OP animals (P < 0.05), suggesting altered baroreflex gain. CCK-induced inhibitory responses in OR/control animals were blunted/completely reversed in OP animals. Conclusion: Obesity-related hypertension is associated with altered responsiveness of RVLM neurons, possibly leading to blunted sympathoinhibitory and vasodilator effects in the renal and splanchnic vascular beds. In obesity, dietary changes and increased heomodynamic demand to these regions, together with blunted sympathoinhibitory mechanisms, may lead to increased regional vascular resistance and contribute to the development of hypertension.

Reply from Erica A. Wehrwein, Rita Basu, Ananda Basu, Timothy B. Curry, Robert A. Rizza and Michael J. Joyner

We thank Dr Verberne for furthering the discussion of our recent paper. To address his points, we will focus on three issues: (1) the differential control of sympathetic outflow, (2) the role of a subset of RVLM neurons in hypoglycaemic counterregulation recently described by Drs Verberne and Sartor, and (3) a further comment on these RVLM neurons. (1) In our recent paper (Wehrwein et al. 2010) we do, for the sake of simplicity and generation of a ‘straw man’ argument, refer to the sympathetic nervous system as a unit as we discuss sympathoinhibition as a mechanism for suppression of counterregulation during hyperoxia. Dr Verberne is indeed correct that the modern view of the sympathetic nervous system is that of differential outflow to various tissues. Human microneurography studies from our collaborator Dr Wallin from the 1970s and 1980s made similar points repeatedly. For example, it is well established that there is differential activation of skin sympathetic versus muscle sympathetic nerves (Delius et al. 1972a,b,c; Wallin et al. 1975), especially during common manoeuvres such as orthostasis and exercise (Vissing et al. 1994; Vissing, 1997). A review on the differential control of muscle sympathetic nerve activity by the muscle chemoreflex (Joyner, 1992) summarizes at least some of these ideas from the human studies. These findings are also consistent with the idea of a ‘sympathetic signature’ as put forth by Osborn and Fink in their recent review of this topic as it relates to Angiotensin II hypertension (Osborn & Fink, 2010). Finally, May and colleagues support this notion by showing a disconnect between the cardiac and renal sympathetic outflows in a sheep model of heart failure (May et al. 2010). Thus the concept of differential sympathetic control is clearly important and is relevant to our findings as we study the role of the carotid bodies in the sympathetic and adrenal pathways involved in hypoglycaemic counterregulation. (2) The recent work of Verberne & Sartor (2010) describing a subset of cells in the RVLM is important and it was not cited and discussed in our paper due to timing. Verberne and Sartor demonstrate that a subpopulation of RVLM neurons: (1) serve as baro-insensitive, central glucose sensors, (2) play a role in mediating the counterregulatory response to hypoglycaemia, and (3) drive the adrenomedullary release of adrenaline. As such these cells provide an important mechanistic explanation for our findings and suggest generalized sympathoinhibition does not occur during carotid body inhibition with hyperoxia. Importantly, these RVLM cells do not have cardiac rhythmicity or baroreflex-driven inhibition and are directly targeted to the adrenal gland allowing adrenal stimulation independent of baroreflex driven changes in sympathetic outflow from presympathetic vasomotor neurons in the same brain region. However, it is unclear what the link is between the carotid body chemoreceptors and these specific RVLM cells, or how they might interact to influence the counterregulatory response to hypoglycaemia. Since both type 1 glomus cells in the carotid body and the RVLM subpopulation of neurons described by Verberne and Sartor are glucose sensitive and can mediate counterregulation, we do not yet understand how these cells interact to generate an integrated counterregulatory response. (3) It is well established that the RVLM controls sympathetic vasomotor output and is integral to baroreflex control of MSNA and blood pressure. Activation of adrenaline secretion was known to occur with RVLM disinhinition but until Verberne and Sartor's work described above (Verberne & Sartor, 2010), it was presumed that the neurons controlling sympathetic vasomotor tone and adrenaline secretion were fundamentally similar. By contrast, Verberne and Sartor show that there is a subpopulation of RVLM neurons that are baro-insensitive and whose activity is affected by changes in blood glucose levels. These glucose-sensitive RVLM neurons are targeted specifically to the adrenal medulla and control adrenaline secretion in response to a central hypoglycaemic stimulus (i.e. adrenaline release mediates liver glucose mobilization and an increase in plasma glucose to correct for hypoglycaemia). Their paper is important because it: (1) identifies a subpopulation of RVLM neurons that sense, and mediate changes in, blood glucose and are independent of the classic view of a more uniform role of RVLM neurons, (2) brings to light an important new understanding of integrative physiology and homeostasis, and (3) offers explanation for some of the differential control within the sympathoadrenal system. In conclusion, we are pleased to have this added discussion on mechanisms that might explain some of our findings. We agree with the view that a sympathoadrenal system that functions en masse is not applicable to most physiological states and are pleased that our paper has stimulated discussion on these and related topics.

Gastric leptin: a novel role in cardiovascular regulation

Gastric-derived leptin affects satiety and gastrointestinal function via vagal mechanisms and has been shown to interact with the gut hormone cholecystokinin (CCK). CCK selectively inhibits splanchnic sympathetic nerve discharge (SND) and the activity of a subset of presympathetic vasomotor neurons in the rostroventrolateral medulla (RVLM). The present study sought to examine the effects of gastric leptin on arterial pressure (AP), heart rate (HR), SND, and RVLM neuronal activity to determine whether its effects on cardiovascular regulation are dependent on CCK(1) receptors and vagal afferent transmission. To mimic gastric leptin, leptin (15-30 microg/kg) was administered close to the coeliac artery in anesthetized, artificially ventilated Sprague-Dawley rats. Within 5 min, leptin selectively decreased the activity of RVLM neurons also inhibited by CCK (-27 +/- 4%; P < 0.001; n = 15); these inhibitory effects were abolished following administration of the CCK(1) receptor antagonist lorglumide. Leptin significantly decreased AP and HR (-10 +/- 2 mmHg, P < 0.001; and -8 +/- 2 beats/min, P < 0.01; n = 35) compared with saline (-1 +/- 2 mmHg, 3 +/- 2 beats/min; n = 30). In separate experiments, leptin inhibited splanchnic SND compared with saline (-9 +/- 2% vs. 2 +/- 3%, P < 0.01; n = 8). Bilateral cervical vagotomy abolished the sympathoinhibitory, hypotensive, and bradycardic effects of leptin (P < 0.05; n = 6). Our results suggest that gastric leptin may exert acute sympathoinhibitory and cardiovascular effects via vagal transmission and CCK(1) receptor activation and may play a separate role to adipose leptin in short-term cardiovascular regulation.

The acute effects of close arterial leptin administration on cardiovascular regulation and RVLM presympathetic vasomotor neurons

The gastric source of leptin may exert its effects directly by paracrine activation of vagal afferents, different to the mode of action for adipose leptin. Evidence is emerging for an interactive relationship between leptin and the gastrointestinal hormone cholecystokinin (CCK). The aim of this study was to examine the acute effects of close arterial injection of leptin (10–30 μg/kg) on arterial pressure (AP), heart rate (HR) and firing rate (FR) of presympathetic vasomotor neurons in the rostroventrolateral medulla (RVLM). We recorded AP, HR and RVLM neuronal discharge in anesthetised, paralysed, male Sprague‐Dawley rats. The effects of baroreflex activation, von Bezold‐Jarisch reflex activation (phenylbiguanide, PBG; 5 μg/kg i.v.) and CCK (1 μg/kg, i.v.) were examined. Close arterial leptin administration produced a significant decrease in HR (369 + 12 bpm to 357 + 14 bpm; n=6; P &lt; 0.05; paired t‐test) and AP (107 + 3 mmHg to 85 + 6 mmHg; n=6; P &lt; 0.05) within 5 minutes of administration. All RVLM neurons studied were inhibited by increases in AP and PBG. The FR of RVLM neurons inhibited by CCK (n=3) was significantly attenuated by leptin administration (from 10.6 + 5 to 8.7 + 5 spikes/s) despite the fall in AP, whereas the FR of those not inhibited by CCK (n=3) was either increased or unaffected. These results suggest that leptin may be exerting its cardiovascular effects via a CCK‐dependent mechanism.

Pancreatic vasoconstrictor responses are regulated by neurons in the rostral ventrolateral medulla

The pancreas receives sympathetic input which arises from several premotor cell groups in the CNS including the rostral ventrolateral medulla (RVLM). In this study, we examined the influence of electrical stimulation of the RVLM on pancreatic blood flow measured by laser Doppler flowmetry and gastric blood flow measured by ultrasonic Doppler flowmetry in halothane-anesthetized rats. The laser Doppler flow measurement technique was validated by demonstration that pancreatic conductance was reduced by systemic administration of the vasoconstrictor phenylephrine and increased by the vasodilator sodium nitroprusside. Sympathetic vasomotor withdrawal induced by either administration of phenylbiguanide (2 and 10 μg/kg, i.v.) or electrical stimulation of the central end of the cervical vagal trunk (5 Hz, 2 ms, 50–150 μA) produced depressor responses and increases in pancreatic and gastric vascular conductance. Electrical stimulation of the RVLM (50 Hz, 0.5 ms, 25–75 μA) produced pressor and tachycardic responses accompanied by decreases in pancreatic and gastric vascular conductance. All responses to RVLM stimulation were abolished by blockade of ganglionic neurotransmission (hexamethonium bromide, 20 mg/kg, i.v.). These data suggest that RVLM presympathetic vasomotor neurons are a primary source of tonic sympathetic vasomotor drive to the pancreatic and gastric vasculature.

An enteric signal regulates putative gastrointestinal presympathetic vasomotor neurons in rats

Ingestion of a meal results in gastrointestinal (GI) hyperemia and is associated with systemic and paracrine release of a number of peptide hormones, including cholecystokinin (CCK) and 5-hydroxytryptamine (5-HT). Systemic administration of CCK octapeptide inhibits a subset of presympathetic neurons of the rostroventrolateral medulla (RVLM) that may be responsible for driving the sympathetic vasomotor tone to the GI viscera. The aim of this study was to determine whether endogenous release of CCK and/or 5-HT also inhibits CCK-sensitive RVLM neurons. The effects of intraduodenal administration of the secretagogues sodium oleate (SO) and soybean trypsin inhibitor (SBTI) on circulating levels of CCK and 5-HT were examined. In separate experiments, the discharge rates of barosensitive, medullospinal, CCK-sensitive RVLM presympathetic vasomotor neurons were recorded after rapid intraduodenal infusion of SO-SBTI or water. Alternatively, animals were pretreated with the CCK1 receptor antagonists devazepide and lorglumide or the 5-HT3 antagonist MDL-72222 before SO-SBTI administration. Secretagogue infusion significantly increased the level of circulating CCK, but not 5-HT. SO-SBTI significantly decreased (58%) the neuronal firing rate of CCK-sensitive RVLM neurons compared with water (5%). CCK1 receptor antagonists did not reverse SO-SBTI-induced neuronal inhibition (58%), whereas the 5-HT3 antagonist significantly attenuated the effect (22%). This study demonstrates a functional relation between a subset of RVLM presympathetic vasomotor neurons and meal-related signals arising from the GI tract. It is likely that endogenously released 5-HT acts in a paracrine fashion on GI 5-HT3 receptors to initiate reflex inhibition of these neurons, resulting in GI vasodilatation by withdrawal of sympathetic tone.

Cocaine- and amphetamine-regulated transcript in catecholamine and noncatecholamine presympathetic vasomotor neurons of rat rostral ventrolateral medulla.

Presympathetic vasomotor adrenergic (C1) and nonadrenergic (non-C1) neurons in the rostral ventrolateral medulla (RVLM) provide the main excitatory drive to cardiovascular sympathetic preganglionic neurons in the spinal cord. C1 and non-C1 neurons contain cocaine- and amphetamine-regulated transcript (CART), suggesting that CART may be a common marker for RVLM presympathetic neurons. To test this hypothesis, we first used double-immunofluorescence staining for CART and tyrosine hydroxylase (TH) to quantify CART-immunoreactive (-IR) catecholamine and noncatecholamine neurons in the C1 region. Next, we quantified the proportion of CART-IR RVLM neurons that expressed Fos in response to a hypotensive stimulus, using peroxidase immunohistochemistry for Fos and dual immunofluorescence for CART and TH. Finally, we fluorescently detected CART immunoreactivity in electrophysiologically identified, juxtacellularly labeled RVLM presympathetic neurons. In the RVLM, 97% of TH-IR neurons were CART-IR, and 74% of CART-IR neurons were TH-IR. Nitroprusside infusion significantly increased the number of Fos-IR RVLM neurons compared with saline controls. In nitroprusside-treated rats, virtually all Fos/TH neurons in the RVLM were immunoreactive for CART (98% +/- 1.3%, SD; n = 7), whereas 29% +/- 8.3% of CART-positive, TH-negative neurons showed Fos immunoreactivity. Six fast (2.8-5.8 m/second, noncatecholamine)-, two intermediate (2.1 and 2.2 m/second)-, and five slow (<1 m/second, catecholamine)-conducting RVLM presympathetic vasomotor neurons were juxtacellularly labeled. After fluorescent detection of CART and biotinamide, all 13 neurons were found to be CART-IR. These results suggest that, in rat RVLM, all catecholamine and noncatecholamine presympathetic vasomotor neurons contain CART.

CCK-induced inhibition of presympathetic vasomotor neurons: dependence on subdiaphragmatic vagal afferents and central NMDA receptors in the rat.

Systemic administration of cholecystokinin (CCK) inhibits a subpopulation of rostral ventrolateral medulla (RVLM) presympathetic vasomotor neurons. This study was designed to determine whether this effect involved subdiaphragmatic vagal afferents and/or central N-methyl-d-aspartic acid (NMDA) receptors. Recordings were made from CCK-sensitive RVLM presympathetic vasomotor neurons in halothane-anesthetized, paralyzed male Sprague-Dawley rats. The responses of the neurons to CCK (2 and 4 microg/kg iv), phenylephrine (PE; 5 microg/kg iv), and phenylbiguanide (PBG; 5 microg/kg iv) were tested before and after application of the local anesthetic lidocaine (2% wt/vol gel; 1 ml) to the subdiaphragmatic vagi at the level of the esophagus. In seven separate experiments, lidocaine markedly reduced the inhibitory effects of CCK on RVLM presympathetic neuronal discharge rate. In other experiments, the effect of systemic administration of dizocilpine (1 mg/kg iv), a noncompetitive antagonist at NMDA receptor ion channels, on the RVLM presympathetic neuronal responses to CCK, PBG, and PE was tested. In all cases (n = 6 neurons in 6 individual rats), dizocilpine inhibited the effects of CCK, PBG, and PE on RVLM presympathetic neuronal discharge. These results suggest that the effects of systemic CCK on the discharge of RVLM presympathetic neurons is mediated via an action on receptors located on subdiaphragmatic vagal afferents. Furthermore, the data suggest that CCK activates a central pathway involving NMDA receptors to produce inhibition of RVLM presympathetic neuronal discharge.

Phenotypic identification of rat rostroventrolateral medullary presympathetic vasomotor neurons inhibited by exogenous cholecystokinin.

Systemic administration of the gastrointestinal hormone cholecystokinin (CCK) selectively inhibits splanchnic sympathetic vasomotor discharge and differentially affects presympathetic vasomotor neurons of the rostroventrolateral medulla (RVLM). Stimulation of the sympathoexcitatory region of the periaqueductal grey (PAG) produces profound mesenteric vasoconstriction. In this study, our aim was to identify phenotypically different populations of RVLM presympathetic vasomotor neurons using juxtacellular neuronal labelling and immunohistochemical detection of the adrenergic neuronal marker phenylethanolamine-N-methyl transferase (PNMT) and to determine whether the PAG provides functional excitatory input to these neurons. Fifty-eight percent (36/62) of RVLM presympathetic neurons were inhibited by systemic administration of CCK. These cells had conduction velocities (3.6 +/- 0.2 m/sec) in the non-C-fiber range consistent with neurons possessing lightly myelinated spinal axons. Of these, 79% (22/28) were excited by PAG stimulation, and 59% (10/17) were not immunoreactive for PNMT. Conversely, 42% (26/62) of RVLM presympathetic neurons were either unaffected or activated by CCK administration and had slower conduction velocities (1.4 +/- 0.3 m/sec) than cells inhibited by CCK. Fifty percent (11/22) of these cells were driven by PAG stimulation, and most (11/14 or 79%) were PNMT-positive. These results suggest that cardiovascular responses elicited by PAG stimulation occur via activation of non-C1 and C1 RVLM presympathetic neurons. RVLM neurons inhibited by CCK were more likely to be driven by PAG stimulation and may be a subset of neurons responsible for driving gastrointestinal sympathetic vasomotor tone. CCK-induced inhibition of a subpopulation of RVLM presympathetic neurons may be implicated in postprandial hyperemia and postprandial hypotension.

Cholecystokinin selectively affects presympathetic vasomotor neurons and sympathetic vasomotor outflow.

Cholecystokinin (CCK) is a potential mediator of gastrointestinal vasodilatation during digestion. To determine whether CCK influences sympathetic vasomotor function, we examined the effect of systemic CCK administration on mean arterial blood pressure (MAP), heart rate (HR), lumbar sympathetic nerve discharge (LSND), splanchnic sympathetic nerve discharge (SSND), and the discharge of presympathetic neurons of the rostral ventrolateral medulla (RVLM) in alpha-chloralose-anesthetized rats. CCK (1-8 microg/kg iv) reduced MAP, HR, and SSND and transiently increased LSND. Vagotomy abolished the effects of CCK on MAP and SSND as did the CCK-A receptor antagonist devazepide (0.5 mg/kg iv). The bradycardic effect of CCK was unaltered by vagotomy but abolished by devazepide. CCK increased superior mesenteric arterial conductance but did not alter iliac conductance. CCK inhibited a subpopulation (approximately 49%) of RVLM presympathetic neurons whereas approximately 28% of neurons tested were activated by CCK. The effects of CCK on RVLM neuronal discharge were blocked by devazepide. RVLM neurons inhibited by exogenous CCK acting via CCK-A receptors on vagal afferents may control sympathetic vasomotor outflow to the gastrointestinal tract vasculature.

Vesicular glutamate transporter DNPI/VGLUT2 is expressed by both C1 adrenergic and nonaminergic presympathetic vasomotor neurons of the rat medulla.

The main source of excitatory drive to the sympathetic preganglionic neurons that control blood pressure is from neurons located in the rostral ventrolateral medulla (RVLM). This monosynaptic input includes adrenergic (C1), peptidergic, and noncatecholaminergic neurons. Some of the cells in this pathway are suspected to be glutamatergic, but conclusive evidence is lacking. In the present study we sought to determine whether these presympathetic neurons express the vesicular glutamate transporter BNPI/VGLUT1 or the closely related gene DNPI, the rat homolog of the mouse vesicular glutamate transporter VGLUT2. Both BNPI/VGLUT1 and DNPI/VGLUT2 mRNAs were detected in the medulla oblongata by in situ hybridization, but only DNPI/VGLUT2 mRNA was present in the RVLM. Moreover, BNPI immunoreactivity was absent from the thoracic spinal cord lateral horn. DNPI/VGLUT2 mRNA was present in many medullary cells retrogradely labeled with Fluoro-Gold from the spinal cord (T2; four rats). Within the RVLM, 79% of the bulbospinal C1 cells contained DNPI/VGLUT2 mRNA. Bulbospinal noradrenergic A5 neurons did not contain DNPI/VGLUT2 mRNA. The RVLM of six unanesthetized rats subjected to 2 hours of hydralazine-induced hypotension contained tenfold more c-Fos-ir DNPI/VGLUT2 neurons than that of six saline-treated controls. c-Fos-ir DNPI/VGLUT2 neurons included C1 and non-C1 neurons (3:2 ratio). In seven barbiturate-anesthetized rats, 16 vasomotor presympathetic neurons were filled with biotinamide and analyzed for the presence of tyrosine hydroxylase immunoreactivity and/or DNPI/VGLUT2 mRNA. Biotinamide-labeled neurons included C1 and non-C1 cells. Most non-C1 (9/10) and C1 presympathetic cells (5/6) contained DNPI/VGLUT2 mRNA. In conclusion, DNPI/VGLUT2 is expressed by most blood pressure-regulating presympathetic cells of the RVLM. The data suggest that these neurons may be glutamatergic and that the C1 adrenergic phenotype is one of several secondary phenotypes that are differentially expressed by subgroups of these cells.

Mu-opioid receptors are present in functionally identified sympathoexcitatory neurons in the rat rostral ventrolateral medulla.

Agonists of the mu-opioid receptor (MOR) produce profound hypotension and sympathoinhibition when microinjected into the rostral ventrolateral medulla (RVL). These effects are likely to be mediated by the inhibition of adrenergic and other presympathetic vasomotor neurons located in the RVL. The present ultrastructural studies were designed to determine whether these vasomotor neurons, or their afferents, contain MORs. RVL bulbospinal barosensitive neurons were recorded in anesthetized rats and filled individually with biotinamide by using a juxtacellular labeling method. Biotinamide was visualized by using a peroxidase method and MOR was identified by using immunogold localization of an antipeptide antibody that recognizes the cloned MOR, MOR1. The subcellular relationship of MOR1 to RVL neurons with fast- or slow-conducting spinal axons was examined by electron microscopy. Fast- and slow-conducting cells were not morphologically distinguishable. Immunogold-labeling for MOR1 was found in all RVL bulbospinal barosensitive neurons examined (9 of 9). MOR1 was present in 52% of the dendrites from both types of cells and in approximately half of these dendrites the MOR1 was at nonsynaptic plasmalemmal sites. A smaller portion of biotinamide-labeled dendrites (16%) from both types of cells were contacted by MOR1-containing axons or axon terminals. Together, these results suggest that MOR agonists can directly influence the activity of all types of RVL sympathoexcitatory neurons and that MOR agonists may also influence the activity of afferent inputs to these cells. The heterogenous distribution of MORs within individual RVL neurons indicates that the receptor is selectively targeted to specific pre- and postsynaptic sites.

Long term imipramtne effects are prevented by NMDA receptor blockade

The thiol amino acid l-cysteine increases arterial blood pressure (ABP) when injected into the cerebrospinal fluid space in conscious rats, indicating a pressor response to centrally acting l-cysteine. A prior synaptic membrane binding assay suggests that l-cysteine has a strong affinity for the l-2-amino-4-phosphonobutyric acid (l-AP4) binding site. The central action of l-cysteine may be via l-AP4 sensitive receptors. The present study investigated cardiovascular responses to l-cysteine and l-AP4 microinjected into the autonomic area of the caudal ventrolateral medulla (CVLM) where inhibitory neurons regulate ABP via pre-sympathetic vasomotor neurons. Both the injection of l-cysteine and l-AP4 in the CVLM sites identified with l-glutamate produced the same depressor and bradycardic responses in urethane-anesthetized rats. Neither a prior antagonist microinjection of MK801 for the N-methyl-d-aspartate (NMDA) receptor nor CNQX for the non-NMDA receptor attenuated the responses to l-cysteine, but the combination of the two receptor blocking with an additional prior injection abolished the response. In contrast, either receptor blockade alone abolished the response to l-AP4, indicating distinct mechanisms between responses to l-cysteine and l-AP4 in the CVLM. The results indicate that the CVLM is a central active site for l-cysteine's cardiovascular response. Central l-cysteine's action could be independent of the l-AP4 sensitive receptors. Cardiovascular regulation may involve endogenous l-cysteine in the CVLM. Further multidisciplinary examinations are required to elaborate on l-cysteine's functional roles in the CVLM.