Dual mechanisms of angiotensin-induced activation of mouse sympathetic neurones.

Ang II directly activates neurones in sympathetic ganglia. Our goal was to define the electrophysiological basis of this activation. Neurones from mouse aortic-renal and coeliac ganglia were identified as either 'tonic' or 'phasic'. With injections of depolarizing currents, action potentials (APs) were abundant and sustained in tonic neurones (TNs) and scarce or absent in phasic neurones (PNs). Resting membrane potentials were equivalent in TNs (-48 +/- 2 mV, n = 18) and PNs (-48 +/- 1 mV, n = 23) while membrane resistance was significantly higher in TNs. Ang II depolarized and increased membrane resistance equally in both TNs (n = 8) and PNs (n = 8) but it induced APs only in TNs, and enhanced current-evoked APs much more markedly in TNs (P < 0.05). The AT1 receptor antagonist losartan (2 microm, n = 6) abolished all responses to Ang II, whereas the AT2 receptor blocker PD123,319 had no effect. The transient K+ current (IA), which was more than twice as large in TNs as in PNs, was significantly inhibited by Ang II in TNs only whereas the delayed sustained K+ current (IK), which was comparable in both TNs and PNs, was not inhibited. M currents were more prominent in PNs and were inhibited by Ang II. The IA channel blocker 4-aminopyridine triggered AP generation in TNs and prevented the Ang II-induced APs but not the depolarization. Blockade of M currents by oxotremorine M or linopirdine prevented the depolarizing action of Ang II. The protein kinase C (PKC) inhibitor H7 (10 microm, n = 9) also prevented the Ang II-induced inhibition of IA and the generation APs but not the depolarization nor the inhibition of M currents. Conversely, the PKC agonist phorbol 12-myristate 13-acetate mimicked the Ang II effects by triggering APs. The results indicate that Ang II may increase AP generation in sympathetic neurones by inducing a PKC-dependent inhibition of IA currents, and a PKC-independent depolarization through inhibition of M currents. The differential expression of various K+ channels and their sensitivity to phosphorylation by PKC may determine the degree of activation of sympathetic neurones and hence may influence the severity of the hypertensive response.

Slow inactivation of sodium currents in the rat nodose neurons.

Nodose neurons express sodium currents that can be differentiated based on their sensitivity to tetrodotoxin. Several studies have demonstrated significant differences in voltage-dependence and kinetics of activation and inactivation between tetrodotoxin-sensitive and tetrodotoxin-resistant currents. However, little is known about the slow inactivation. Using whole cell patch-clamp technique fast and slow inactivation of sodium currents were studied in cultured rat nodose neurons. Tetrodotoxin-resistant currents recovered much more rapidly after a 15-ms depolarization than tetrodotoxin-sensitive currents. However, repeated 5-ms depolarizations at 10 Hz induced a cumulative inhibition that was more prolonged in tetrodotoxin-resistant compared to tetrodotoxin-sensitive currents. Consistent with these findings, slow inactivation proceeded more rapidly and was more complete for the tetrodotoxin-resistant than for tetrodotoxin-sensitive currents. While the voltage-dependence of fast inactivation differed significantly between the pharmacologically distinct currents, the voltage-dependence of slow inactivation was similar for both sodium currents. We conclude that slow inactivation of sodium currents can be triggered by trains of brief depolarizations. The resulting prolonged decrease in membrane excitability may contribute to the different patterns of action potential generation observed in primary afferent neurons.

Angiotensin selectively activates a subpopulation of postganglionic sympathetic neurons in mice.

Angiotensin II (Ang II) increases renal sympathetic nerve activity in anesthetized mice before and after ganglionic blockade, suggesting that Ang II may directly activate postganglionic sympathetic neurons. The present study directly tested this hypothesis in vitro. Neurons were dissociated from aortic-renal and celiac ganglia of C57BL/6J mice. Cytosolic Ca(2+) concentration ([Ca(2+)](i)) was measured with ratio imaging using fura 2. Ang II increased [Ca(2+)](i) in a subpopulation of sympathetic neurons. At a concentration of 200 nmol/L, 14 (67%) of 21 neurons responded with a rise in [Ca(2+)](i). The Ang II type 1 (AT(1)) receptor blocker (losartan, 2 micromol/L) but not the Ang II type 2 (AT(2)) receptor blocker (PD123,319, 4 micromol/L) blocked this effect. The Ang II-induced [Ca(2+)](i) increase was abolished by removal of extracellular Ca(2+) but not altered by depletion of intracellular Ca(2+) stores with thapsigargin. Ang II no longer elicited a [Ca(2+)](i) increase in the presence of lanthanum (25 micromol/L). The specific N-type and L-type Ca(2+) channel blockers, omega-conotoxin GVIA and nifedipine, respectively, significantly inhibited the Ang II-induced [Ca(2+)](i) increase. The protein kinase C inhibitor H7 but not the protein kinase A inhibitor H89 blocked the response to Ang II. These results demonstrate that Ang II selectively activates a subpopulation of postganglionic sympathetic neurons in aortic-renal and celiac ganglia, triggering Ca(2+) influx through voltage-gated Ca(2+) channels. This effect is mediated through AT(1) receptors and requires the activation of protein kinase C. The activation of a subgroup of sympathetic neurons by Ang II may exert unique effects on kidney function in pathological states associated with elevated Ang II.

Nitric oxide enhances slow inactivation of voltage-dependent sodium currents in rat nodose neurons.

Nitric oxide (NO) can alter neuronal excitability by decreasing the current through voltage-sensitive sodium channels. We hypothesized that NO inhibits sodium currents in part by promoting slow inactivation. We performed whole-cell voltage clamp experiments on sensory neurons from the nodose ganglion. The voltage-dependence of inactivation was determined after stepping the neurons to various potentials between -100 and 30 mV for 200 ms (fast inactivation) and 3 min (slow inactivation) prior to depolarization to 10 mV. NO shifted the voltage of half-inactivation for fast and slow inactivation to more hyperpolarized potentials by 7 and 12 mV, respectively. Sodium currents exhibited a more profound closed state and slow inactivation after exposure to NO. These results demonstrate for the fist time that the slow inactivation of sodium currents is subject to modulation. Due to its effects on fast and slow inactivation, NO may cause a prolonged decrease in neuronal excitability.

Reactive oxygen species and calcium homeostasis in cultured human intestinal smooth muscle cells.

Reactive oxygen species (ROS) significantly alter cell function. We examined the effects of hydrogen peroxide (H2O2) and xanthine/xanthine oxidase (X/XO) on isolated intestinal muscle cells. We assessed cell viability with the exclusion dye trypan blue and assayed the effects of H2O2 and X/XO on the intracellular redox state with the fluorescent probe 2',7'-dichlorofluorescein. Intracellular calcium concentration was measured in cells loaded with fura 2-acetoxymethyl ester, and we recorded whole membrane currents with conventional patch-clamp methods. Cells remained viable after a 5-min exposure to H2O2 and X/XO. H2O2 and X/XO led to a significant rise of the intracellular concentration of ROS. H2O2 (270 microM to 2.7 mM) as well as X/XO (0.25-16 mU; 0.5 mM xanthine) significantly increased intracellular calcium concentrations. Depletion of intracellular calcium with ryanodine or thapsigargin did not abolish the effect of ROS on the intracellular calcium concentration. In the absence of external calcium or in the presence of the calcium channel blocker nifedipine, H2O2 and X/XO still increased the intracellular calcium level. Thus calcium influx and calcium release from internal stores contributed to this rise in cytosolic calcium. Catalase and superoxide dismutase blunted or completely abolished the changes in calcium concentration elicited by H2O2 and X/XO. Exposure to ROS resulted in a rapid decline of the membrane resistance without significant changes in voltage-sensitive ion currents. We conclude that ROS disrupt the calcium homeostasis of cells at concentrations that do not lead to immediate cell death. The resulting elevation in cytosolic free calcium will activate a variety of biochemical reactions and may thus contribute to the cytotoxicity of reactive oxygen molecules.

Adenovirus-mediated gene transfer to cultured nodose sensory neurons.

Recent advances have enabled transfer of genes to various types of cells and tissues. The goals of the present study were to transfer genes to nodose sensory neurons using replication-deficient adenovirus vectors and to define the conditions needed to optimize the gene transfer. Neurons were dissociated from rat nodose ganglia and maintained in culture. Cultures were exposed for 30 min to vectors containing the beta-galactosidase gene lacZ driven by either the Rous sarcoma virus (RSV) or the cytomegalovirus (CMV) promoter. Cultures were fixed and treated with X-gal to evaluate lacZ expression 1-7 days after exposure to virus. Increasing concentrations of virus led to dose-related increases in the number of neurons expressing lacZ. LacZ was expressed in 8 +/- 2, 39 +/- 6, and 82 +/- 3% of neurons 1 day after exposure to 10(7), 10(8), and 10(9) pfu/ml of AdRSVlacZ, respectively (P < 0.05). The same doses of AdCMVlacZ led to expression in 41 +/- 9, 60 +/- 10, and 86 +/- 4% of neurons. Expression driven by the CMV promoter was essentially maximal within 1 day and remained stable for at least 7 days. In contrast, expression driven by the RSV promoter was less on day 1 but increased over time (1-7 days). There was no lacZ expression in vehicle-treated cultures and exposure to the adenovirus vectors did not adversely influence cell viability. Exposure of the neuronal cultures to an adenovirus vector containing the gene for green fluorescent protein (AdRSVgfp, 10(9) pfu/ml) enabled visualization of successful gene transfer in living neurons. The results indicate that gene transfer to cultured nodose neurons can be accomplished using adenovirus vectors. The expression of the transferred gene persists for at least 7 days, occurs more rapidly when expression is driven by the CMV compared with the RSV promoter, and occurs without adversely affecting cell viability.

Norepinephrine release from guinea pig cardiac sympathetic nerves is insensitive to ryanodine under physiological conditions.

The activation of neurotransmitter release in nerve cells appears to be primarily dependent upon influx of extracellular Ca2+, most of which is thought to cross nerve terminal membranes through N-type Ca2+ channels. Events in skeletal and cardiac muscle, in contrast, are regulated to a greater extent by intracellular Ca2+ exchange between cytosol and intracellular organelles such as sarcoplasmic reticulum. It is not known to what extent corresponding intracellular organelles, i.e. endoplasmic reticulum (ER), contribute to cytosolic Ca2+ transients and norepinephrine (NE) release from cardiac sympathetic nerves. Heart rate and NE release were measured in isolated perfused guinea pig hearts during 1-min stimulations (5 V, 4 Hz, 2 ms) of the right stellate ganglia prior to (S1), during the administration of (S2), and after (S3) the removal of ryanodine (1 microM) from the perfusate. Ryanodine is a selective modulator of caffeine-sensitive Ca2+ stores in ER. Baseline heart rates decreased significantly in the presence of ryanodine, documenting its physiological effect on cardiac cells. However, there was no detectable effect of ryanodine on nerve-stimulated increase in heart rate or NE release. These results indicate that the ryanodine-sensitive intracellular Ca2+ stores do not play a major role in cardiac sympathetic neurotransmission.

Presynaptic regulation of cardiac sympathetic function in hypoxic guinea pigs.

In the normal heart, presynaptic cholinergic muscarinic and alpha 2-adrenergic mechanisms modify the fractional rate constant for norepinephrine (NE) synthesis (kNE), an index of sympathetic neural function. To evaluate presynaptic regulation of kNE, conscious guinea pigs subjected to normoxia and then hypoxia (n = 7-8 in each group) were pretreated with 1) vehicle; 2) a cholinergic muscarinic antagonist, methyl atropine; 3) an alpha 2-antagonist, yohimbine; or 4) a combination of the two. An increase of kNE was determined from incorporation of radiolabeled tyrosine into NE in a control period (arterial PO2 130 +/- 1.7 Torr, PCO2 36 +/- 0.5 Torr) and during a hypoxic state (PO2 49.6 +/- 1.0 Torr, PCO2 36 +/- 0.5 Torr). Hypoxia activated kNE in the atrioventricular node and right ventricular moderator band in vehicle-treated animals (P less than 0.05). Sympathetic activation was more general, however, because alpha 2-presynaptic influence acted to limit kNE in all tissues tested (P less than 0.05) except muscle, spleen, and posterior left ventricle. Cholinergic muscarinic presynaptic restraint on kNE was detected during hypoxia only in the left atrial appendage and lung (P less than 0.05). These data indicate that hypoxia increases kNE in the heart, but restraint by cholinergic muscarinic and alpha 2-adrenergic presynaptic mechanisms limits increases in neurotransmitter synthesis and noradrenergic activation regionally.

Ventricular hypertrophy and presynaptic regulation of sympathetic function.

In normal heart, presynaptic cholinergic muscarinic and alpha 2-adrenergic mechanisms contribute to regional variations in the rate constant of norepinephrine turnover (kNE), an index of sympathetic neural function. To evaluate these mechanisms in the hypertrophied heart, pulmonary artery-constricted and sham-operated guinea pigs were pretreated with 1) saline vehicle (control) or 2) a combination of quinuclidinyl benzilate (Q), a muscarinic cholinergic antagonist, and yohimbine (Y), an alpha 2-adrenergic antagonist. An increase in kNE was determined in multiple regions of heart from incorporation of radiolabeled tyrosine into norepinephrine during a control period at 24 degrees C and again at 4 degrees C. In sham animals, kNE during cold stress was increased significantly (P less than 0.05) by Q + Y compared with vehicle, confirming that muscarinic cholinergic and/or alpha 2-adrenergic receptors exert a negative-feedback influence on sympathetic neurotransmitter synthesis. In pulmonary artery-constricted animals, in contrast, there were smaller increases in cardiac kNE compared with sham guinea pigs given Q + Y and subjected to cold stress. These data support the concept that muscarinic cholinergic and/or alpha 2-adrenergic presynaptic regulation of cardiac sympathetic function is altered in the hearts and vasculature of pulmonary artery-constricted guinea pigs.

Altered peripheral noradrenergic activity in intact and sinoaortic denervated Dahl rats.

Development of salt-induced hypertension in Dahl salt-sensitive (S) rats is dependent on sympathetic overactivity which may be partially related to arterial baroreflex dysfunction and, therefore, is regionally selective. Our first experiment was designed to determine which regions have elevated sympathetic activity in Dahl S compared with Dahl salt-resistant (R) rats. Weanling (4-week-old) female Dahl R and S rats were fed low or high salt diets (0.13% and 8% NaCl) until 10 weeks of age. Norepinephrine (NE) synthesis was blocked with alpha-methyl-p-tyrosine, and the fractional decline of NE concentration was measured in various tissues. Dahl S rats with increases in both arterial pressure and left ventricular weight demonstrated increased NE turnover in the sinoatrial node, the atrial appendages, the cardiac ventricles, and the renal cortex. In all of these tissues except the cardiac ventricle, increases were associated with high salt intake. Our second experiment was designed to test if arterial baroreflex dysfunction could account for regional increases in sympathetic activity. Separate groups of Dahl R and S rats fed high salt were subjected to either sham surgery or sinoaortic baroreceptor denervation 1 week prior to turnover determinations. Sinoaortic baroreceptor denervation abolished differences in NE turnover between salt-fed Dahl R and S rats in the cardiac sinoatrial node and the atrial appendages, but not in the cardiac ventricles and the renal cortex. Sinoaortic baroreceptor denervation also abolished differences between salt-fed Dahl S and R rats in the spleen but not the duodenum.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of intravenous infusions of vasopressin and angiotensin II on central and peripheral noradrenergic function in conscious rabbits.

Vasopressin (AVP) and angiotensin II (AII) are proposed to exert part of their cardiovascular effects via different actions within the central nervous system. These peptides are also known to alter central noradrenergic function. In the present study we determined the effects of these peptides administered intravenously on norepinephrine (NE) turnover in discrete brain regions thought to be involved in the regulation of circulation, and simultaneously, in various peripheral tissues. An index of NE turnover was determined by measuring the decline in tissue NE concentration 75 min after administration of alpha-methyl tyrosine (240 mg . kg-1 . min-1, i.p.). During NE synthesis blockade, five separate groups of rabbits were infused intravenously (1 h) with either saline, AVP (4 and 16 mU . kg-1 . min-1), AII (0.1 microgram . kg-1 . min-1), or phenylephrine (PE) (5 micrograms . kg-1 . min-1). The low dose of AVP produced an increased index of NE turnover in the median preoptic area and the paraventricular nucleus, and concomitantly, a decreased index of NE turnover in kidney and skeletal muscle. In contrast, AII produced an increased index of NE turnover in the locus ceruleus and the intestine. Neither the infusion of vehicle nor the infusion of phenylephrine, which increased arterial pressure comparable to AVP and AII, produced detectable changes in indices of central and peripheral norepinephrine turnover. A higher dose of AVP produced a different pattern of changes in NE turnover than the low dose. These results demonstrate that intravenous infusion of the low dose of AVP produced changes in noradrenergic function in specific central areas known to be involved in autonomic outflow.(ABSTRACT TRUNCATED AT 250 WORDS)

Choline and acetylcholine concentration in transplanted rat heart.

A liquid chromatographic assay was used to determine the choline and acetylcholine concentrations in the four chambers of rat hearts 2, 4, and 8 days after transplantation into an abdominal site. Corresponding measurements were made in the hearts of host rats. We found regional cardiac acetylcholine concentrations in controls follow the nonuniform pattern seen with choline acetyltransferase (CAT) activity, being highest in the atria (8-12 nmol/g) and lower in the ventricles (0.7-1.6 nmol/g). Following transplantation, acetylcholine levels decreased significantly only in the right ventricle after 8 days. Following a unilateral vagotomy (random, left or right), acetylcholine concentrations in the distal portion of the severed nerve decreased to half the value of the intact contralateral side by 4 days. The continued presence of acetylcholine, despite significantly reduced CAT activity in the severed nerve and transplanted heart, suggests that acetylcholine is preserved, perhaps by vesiculation in nonstimulated postganglionic terminals. The localized decrease in acetylcholine in the right ventricle after 8 days suggests that transplantation may interrupt the postganglionic fibers to this area.

A microcomputer program for determining turnover rates before and after intervention in a single animal.

A set of three programs to calculate the turnover of biomolecules whose metabolism follows a steady-state precursor-product relationship and follows the open, single-compartment kinetics model has been written in MS-BASIC. The programs comprise a system for determining two values of turnover, before and after an intervention which may alter the turnover rate, in a single animal. The programs have been extensively tested in our laboratory for the determination of norepinephrine turnover under differing physiological and pharmacological conditions. The utility of the programs lies in their ability to readily adapt to turnover determinations for any substance whose metabolic pathway conforms to the model constraints. This includes the biogenic amine neurotransmitters, peptides and proteins, and many small biological molecules or pharmacological agents.

Presynaptic regulation of cardiac sympathetic function in guinea pigs.

Cold stress (4 degrees C) induces a pressor response and variable increases in an index of sympathetic neural function, the rate constant of norepinephrine turnover, kNE. In heart, presynaptic cholinergic muscarinic and alpha-2 adrenergic influences may contribute to regional variation in responses of kNE to cold stress. Animals were pretreated with vehicle, a muscarinic cholinergic antagonist, quinuclidinyl benzilate (QNB), an alpha-2 adrenergic antagonist, yohimbine (YOH) or combined QNB + YOH. An increase in kNE was determined from incorporation of radiolabeled tyrosine into norepinephrine in a control period at 24 degrees C and again at 4 degrees C. The increment in kNE factored by the increment in blood pressure indicated the extent of increased sympathetic function in each cardiac region. In sino-atrial node, sympathetic function was increased significantly (P less than .05) by QNB + YOH compared to other treatments, suggesting that both cholinergic and alpha-2 adrenergic presynaptic influences were important. In contrast, in right and left ventricles, YOH or QNB + YOH, but not QNB alone, increased sympathetic function significantly, suggesting that only alpha-2 adrenergic influences were important. These data support the concept that presynaptic regulation of cardiac sympathetic function differs in sino-atrial node and ventricles of guinea pigs during activation with cold stress.

Selective sympathetic neural changes in hypertrophied right ventricle.

Selective pressure overload of the right ventricle in guinea pigs resulted in early and sustained reductions in tyrosine hydroxylase and dopamine-beta-hydroxylase activities in the right ventricle. No changes in tyrosine hydroxylase activity were detected in stellate ganglia sinoatrial (SA) nodal region, atrioventricular (AV) nodal region, or left ventricle. Reductions in tyrosine hydroxylase activity in stressed right ventricle were similar regardless of duration of pulmonary artery constriction, extent of hypertrophy, presence or absence of hepatic congestion, and preservation or depletion of catecholamines. The changes may represent localized loss of sympathetic nerve fibers; factors involved directly in the process of pressure-overload-induced hypertrophy may be responsible. However, sympathetic nerves remaining in hypertrophied ventricle respond normally to cold-induced sympathetic activation. The reduction in tyrosine hydroxylase activity and the maintenance of norepinephrine turnover in residual innervation to hypertrophied right ventricle support the concept that sympathetic neural regulation of hypertrophied cardiac tissue is altered but not lost.