Vasopressin-mediated slow EPSPs in a mammalian sympathetic ganglion

Arginine Vasopressin, Synaptic Plasticity, and Brain Networks

The arginine vasopressin (AVP), a neurohypophysial hormone, is synthesized within specific sites of the central nervous system and axonally transported to multiple areas, acting as a neurotransmitter/ neuromodulator. In this context, AVP acts primarily through vasopressin receptors A and B and is involved in regulating complex social and cognition behaviors and basic autonomic function. Many earlier studies have shown that AVP as a neuromodulator affects synaptic plasticity. This review updates our current understanding of the underlying molecular mechanisms by which AVP affects synaptic plasticity. Moreover, we discuss AVP modulatory effects on event-related potentials and blood oxygen level-dependent responses in specific brain structures, and AVP effects on the network level oscillatory activity. We aimed at providing an overview of the AVP effects on the brain from the synaptic to the network level.

Complementary Role of Oxytocin and Vasopressin in Cardiovascular Regulation

The neurons secreting oxytocin (OXY) and vasopressin (AVP) are located mainly in the supraoptic, paraventricular, and suprachiasmatic nucleus of the brain. Oxytocinergic and vasopressinergic projections reach several regions of the brain and the spinal cord. Both peptides are released from axons, soma, and dendrites and modulate the excitability of other neuroregulatory pathways. The synthesis and action of OXY and AVP in the peripheral organs (eye, heart, gastrointestinal system) is being investigated. The secretion of OXY and AVP is influenced by changes in body fluid osmolality, blood volume, blood pressure, hypoxia, and stress. Vasopressin interacts with three subtypes of receptors: V1aR, V1bR, and V2R whereas oxytocin activates its own OXTR and V1aR receptors. AVP and OXY receptors are present in several regions of the brain (cortex, hypothalamus, pons, medulla, and cerebellum) and in the peripheral organs (heart, lungs, carotid bodies, kidneys, adrenal glands, pancreas, gastrointestinal tract, ovaries, uterus, thymus). Hypertension, myocardial infarction, and coexisting factors, such as pain and stress, have a significant impact on the secretion of oxytocin and vasopressin and on the expression of their receptors. The inappropriate regulation of oxytocin and vasopressin secretion during ischemia, hypoxia/hypercapnia, inflammation, pain, and stress may play a significant role in the pathogenesis of cardiovascular diseases.

Effects of vasopressin on isolated rat adrenal chromaffin cells

It has been demonstrated that arginine vasopressin (AVP) is synthesized not only in specific hypothalamic nuclei, but also in the adrenal medulla where it is thought to regulate adrenal functions by autocrine and paracrine mechanisms. In order to further characterise the effects of AVP on rat adrenal chromaffin cells, we examined: (a) the mRNA expression for V(1a) and V(1b) AVP receptors in these cells; (b) the effects of AVP on the membrane potential and membrane currents measured with the whole-cell patch-clamp technique; and (c) effect of AVP on catecholamine release from single adrenal chromaffin cells measured with carbon fibre microelectrodes. Reverse transcription-polymerase chain reaction (RT-PCR) on tissue punch samples obtained from the adrenal medulla demonstrated message for both the V(1a) and V(1b) receptors, while material obtained from the adrenal cortex showed expression of the V(1a) receptor only. Single-cell RT-PCR conducted on acutely isolated chromaffin cells showed message for the V(1a) receptor in 84% of cells, while 38% of cells also contained message for the V(1b) receptor (n=45). Under current-clamp recording, responses to AVP application (4-40 microM) were variable; 22/34 (65%) tested cells were depolarised, 29% hyperpolarised, and the remaining cells showed a biphasic response. Changes in membrane potential of either direction were dose-dependent and accompanied by a decrease in cell membrane resistance. Under voltage-clamp (V(hold)=-60 mV), AVP evoked inward current in 27/52 (52%) and outward current in 16/52 (31%) chromaffin cells. Both types of AVP-evoked responses were blocked by co-application of a nonselective V(1a)/V(1b) antagonist. Application of AVP evoked prolonged bursts of amperometric currents (indicative of catecholamine release) in 4/9 tested cells, but reduced the currents evoked by ACh application in all tested cells (n=7). These findings demonstrate a complex action of AVP on adrenal chromaffin cells, with individual adrenal chromaffin cells responding with either excitation or inhibition. This response pattern may be related to the expression of V(1) receptor subtypes.

Serotonin receptor subtypes that depolarize guinea pig inferior mesenteric ganglion neurons

Our previous studies indicated that serotonin (5-HT) depolarized a majority of guinea pig inferior mesenteric ganglion (IMG) neurons and may be another transmitter for the noncholinergic late slow excitatory postsynaptic potential (ls-EPSP) in the IMG. However, the subtypes of 5-HT receptor mediating these responses have not yet been identified. Using intracellular recording, we examined the effect of 5-HT receptor antagonists with specificity to various 5-HT receptor subtypes on the 5-HT-mediated depolarization and ls-EPSP in IMG neurons in vitro. Cyproheptadine, a 5-HT(1/2) receptor antagonist, reversibly inhibited the slow, but not the fast, depolarization and ls-EPSP in the 5-HT-sensitive neurons. Both mianserin and spiperone, 5-HT(2) and 5-HT(1A) receptor antagonists, did not significantly alter either the fast or slow depolarizing responses or the ls-EPSP. The 5-HT(3) receptor antagonist MDL 72222 (Bemesetron) completely inhibited the fast depolarization with little diminution of the slow depolarization and ls-EPSP. Superfusion of putative 5-HT(1P) receptor antagonist, BRL 24924 (Renzapride), reversibly attenuated both the depolarization and ls-EPSP. However, 5-HT-insensitive neurons with ls-EPSP were found to be insensitive to both cyproheptadine and BRL 24924. In most 5-HT-sensitive neurons, the 5-HT(3) receptor agonist, 2-methyl-5-HT, and the selective 5-HT(1P) agonist, MCPP or 5-OHIP, evoked a fast and a slow depolarization in 55.6 and 71.4% of the neurons, respectively, without a significant effect on the membrane potential in 85.7 and 100% of the 5-HT-insensitive neurons. In 5-HT-sensitive neurons, MDL 72222 reversibly abolished the fast depolarization induced by 2-methyl-5-HT; BRL 24924 significantly inhibited the slow depolarization induced by MCPP or 5-OHIP, but not by SP. Prolonged superfusion of 5-HT-sensitive neurons with MCPP abolished the evoked ls-EPSP without inhibition of action potential. These results suggest that the fast and slow depolarizations in these neurons are mediated by 5-HT(3) and 5-HT(1P) receptor subtypes, respectively. The latter may also mediate the ls-EPSP in 5-HT-sensitive neurons.

Effects of vasopressin and related peptides on neurons of the rat lateral septum and ventral hippocampus

The effects of vasopressin (VP), VP fragments and propressophysin glycopeptide on neuronal activities in the septum-hippocampus complex of rats were studied in vitro and in vivo. The frequency of the hippocampus theta rhythm in Brattleboro rats homozygous for diabetes insipidus was significantly slower than that of heterozygous litter mates and normal rats. Intracerebroventricular micro-injection of des-glycine-amide vasopressin corrected for several hours the frequency deficit of the theta rhythm in the homozygous Brattleboro rats and the centrally administered VP slowed down theta rhythm in normal rats. Microinotophoretically administered VP excited single neurons in the lateral septum of ventral hippocampus, and/or facilitated the responses of these neurons to glutamate and to stimulation of the glutamatergic afferent fibers in the fimbria bundle. The excitatory effects of VP vanished within seconds after termination of the peptide administration, however, the peptide-induced enhancement of glutamate and syntatically induced excitations were sustained for up to 60 min after the peptide administration. In vitro, pM concentrations of VP, VP 4-8 and C-terminus glycopeptide of propresophysin facilitated for 30-60 min the glutamate-mediated EPSPs in neurons of the lateral septum or the ventral hippocampus. The EPSPs increase in the lateral septum neurons was not prevented by pretreatment with antagonist of the V1a type of the vasopressin receptor. The resting membrane potential and input resistance were not affected by the peptides. A low-frequency electrical stimulation in the diagonal Band of Broca or in the Bed nucleus of the stria terminals, sources of the vasopressinergic innervation of the septum, facilitated the negative wave of the filed potentials responses evoked in the lateral septum by stimulating the fimbria bundle fibers in control Long-Evans and Brattleboro rats heterozygous for diabetes insipidus. The field potential increase was sustained for several hours after the stimulation, and it was not occluded by long-term potentiation elicited by high frequency stimulation of the fimbria bundle afferent fibers. Brattleboro rats homozygous for diabetes insipidus failed to show the filed potential increase after the diagonal band stimulation. It is suggested that the long-lasting facilitation of glutamate-mediated excitations might be a physiological action of the propressophysin-derived peptides in the septum-hippocampus complex which, in concert with other forms of synaptic plasticity like the long-term potentiation, facilitates the hippocampus-mediated forms of learning and memory. This action is presumably related to the memory enhancing effect of the propressophysin-derived peptides.

Vasopressin/serotonin interactions in the anterior hypothalamus control aggressive behavior in golden hamsters

Studies in several species of rodents show that arginine vasopressin (AVP) acting through a V1A receptor facilitates offensive aggression, i.e., the initiation of attacks and bites, whereas serotonin (5-HT) acting through a 5-HT1B receptor inhibits aggressive responding. One area of the CNS that seems critical for the organization of aggressive behavior is the basolateral hypothalamus, particularly the anterior hypothalamic region. The present studies examine the neuroanatomical and neurochemical interaction between AVP and 5-HT at the level of the anterior hypothalamus (AH) in the control of offensive aggression in Syrian golden hamsters. First, specific V1A and 5-HT1B binding sites in the AH are shown by in vitro receptor autoradiography. The binding for each neurotransmitter colocalizes with a dense field of immunoreactive AVP and 5-HT fibers and putative terminals. Putative 5-HT synapses on AVP neurons in the area of the AH are identified by double-staining immunocytochemistry and laser scanning confocal microscopy. These morphological data predispose a functional interaction between AVP and 5-HT at the level of the AH. When tested for offensive aggression in a resident/intruder paradigm, resident hamsters treated with fluoxetine, a selective 5-HT reuptake inhibitor, have significantly longer latencies to bite and bite fewer times than vehicle-treated controls. Conversely, AVP microinjections into the AH significantly shorten the latency to bite and increase biting attacks. The action of microinjected AVP to increase offensive aggression is blocked by the pretreatment of hamsters with fluoxetine. These data suggest that 5-HT inhibits fighting, in part, by antagonizing the aggression-promoting action of the AVP system.

The mammalian sympathetic prevertebral ganglia: integrative properties and role in the nervous control of digestive tract motility

The prevertebral ganglia which are a constitutive part of the sympathetic system have long been considered as a simple relay on this efferent pathway. In fact, these ganglia must be considered as true peripheral nervous centres. They possess various integrative properties, such as projections of central and peripheral inputs onto the ganglionic neurones, gating of these projections and pacemaker activity of the ganglionic neurones. These properties explain the ability of these ganglia to participate in the regulation of various visceral functions, including digestive tract motility.

Modulation by opioid peptides of mechanosensory pathways supplying the guinea-pig inferior mesenteric ganglion

1. Radioimmunological techniques were used in isolated guinea-pig inferior mesenteric ganglion (IMG)-colon preparations to determine whether opioid peptides and neurotensin8-13 (NT8-13), the C-terminal region of NT1-13 recognized by neurotensin receptors, modulate distension-induced release of substance P (SP)- and vasoactive intestinal polypeptide (VIP)-like immunoreactive (LI) material. 2. Colonic distension significantly increased the amount of SP- and VIP-LI material released in the ganglionic superfusate. A low-Ca2+ (0.1 mM), high-Mg2+ (15 mM) solution blocked their release. 3. In vivo capsaicin pretreatment abolished release of SP-LI material during colonic distension but had no significant effect on distension-induced release of VIP-LI material. 4. The addition of [Leu5]enkephalin, [Met5]enkephalin, PL017 (a mu-receptor agonist) and DPDPE (a delta-receptor agonist) to the ganglion side of a two-compartment chamber blocked distension-induced release of SP-LI material. The addition of naloxone and ICI-174,864 (a delta-receptor antagonist) to the ganglion compartment reversed the inhibitory effect of the mu- and delta-receptor agonists. 5. Addition of [Leu5]enkephalin and [Met5]enkephalin to the ganglion compartment had no significant effect on release of VIP-LI material during colonic distension. 6. Addition of NT8-13 to the ganglion compartment significantly increased in the amount of SP-LI material released during colonic distension but had no affect on distension-induced release of VIP-LI material. 7. The results suggest the hypothesis that under in vivo conditions, enkephalinergic nerves decrease and neurotensinergic nerves increase the release of SP from peripheral branches of primary afferent sensory nerves.

Long-lasting enhancement of synaptic excitability of CA1/subiculum neurons of the rat ventral hippocampus by vasopressin and vasopressin(4-8)

Vasopressin (VP) is axonally distributed in many brain structures, including the ventral hippocampus. Picogram quantities of VP injected into the hippocampus improve the passive avoidance response of rats, presumably by enhancing memory processes. Vasopressin is metabolized by the brain tissue into shorter peptides, such as [pGlu4,Cyt6]VP(4-9) and [pGlu4,Cyt6]VP(4-8), which preserve the behavioral activity but lose the peripheral activities of the parent hormone. Using brain slices, we investigated whether VP or VP(4-8) affects excitatory postsynaptic potentials (EPSPs) and/or membrane responses to depolarization in neurons of the CA1/subiculum of the ventral hippocampus. The EPSPs were evoked by stimulating the striatum radiatum of the CA1 field; the membrane responses were elicited by current injections. Exposure of slices for 15 min to 0.1 nM solution of these peptides resulted in an increase in the amplitude and slope of the EPSPs in 21 neurons (67%) tested. No consistent change in either the resting membrane potential or the input resistance of the neurons was observed. The peptide-induced increase in EPSPs reached a maximum 30-45 min after peptide application. In 14 of these neurons (66%), the peptide-induced increase in EPSPs remained throughout the entire 60-120 min washout period. In the remaining 7 neurons (33%), the initial increase in EPSPs amplitude was followed by a gradual decline to the pre-administration level. The increase in EPSP amplitude was often, but not always, associated with a decrease in the threshold and increase in the number of action potentials in response to depolarizing current injection. Suppression of GABAA receptor-mediated inhibition and N-methyl-D-aspartate (NMDA) receptor-mediated excitation did not prevent the effects of VP and VP(4-8) on the EPSP amplitude or the threshold for action potentials. The results demonstrate that 0.1 nM concentrations of these neuropeptides can elicit a long-lasting enhancement of the excitability of CA1/subiculum neurons of the ventral hippocampus to excitatory, glutamatergic synaptic input. This novel action of VP and its metabolite in the ventral hippocampus may be the physiological action, mediating the memory-enhancing effect of these peptides.

Vasopressin inhibits food intake in pygmy goats by activation of alpha 1-adrenergic receptors

The hypophagic effect of intraperitoneally injected VP (1.5 micrograms/kg) was blocked by concomitant injection of the alpha 1-adrenergic antagonist prazosin (27 and 40 micrograms/kg). Both the alpha 2-adrenergic antagonists idazoxan (300 micrograms/kg) and yohimbine (500 micrograms/kg) and the beta-adrenergic antagonist propranolol (500 micrograms/kg) failed to block the hypophagia induced by VP (1.5 micrograms/kg). The results suggest that the hypophagic effect of VP is mediated by alpha 1-adrenergic receptors.

Muscarinic inhibition of two potassium currents in guinea-pig prevertebral neurons: differentiation by extracellular cesium

Muscarinic responses were studied in dissociated guinea-pig celiac ganglion neurons using the whole-cell voltage-clamp technique. Muscarine (0.025-1 mM; EC50 = 95 microM) administered to cells for 1.5 s evoked inward shifts in holding current in 53 of 74 cells. The amplitude of the inward current transients decreased with hyperpolarization and the null potential averaged -71 +/- 3.4 mV (n = 11). The currents that underlie the responses to muscarine were examined with hyperpolarizing voltage stepping protocols to -100 mV from a holding potential of -30 mV. Eighty-one per cent of cells displayed voltage-dependent current relaxations characteristic of the M-potassium current. Twenty per cent of responding cells displayed no M-current but only a voltage-independent current consistent with a leak current. In the latter type of cells, the muscarine-evoked inward currents reversed near EK and became outward at more hyperpolarized potentials. Analysis of steady state I-V relationships before and after bath application of muscarine showed that the two muscarine-sensitive potassium currents were distributed differently among three types of cells: (i) with M-current (18%); (ii) with leak current (18%); and (iii) with M-current and with leak current (64%). Cesium and barium were used to differentiate the M-current and the muscarine-sensitive leak current. Barium (2 mM) reduced the M-current and the leak potassium current, whereas cesium (2 mM) reduced the M-current but did not affect leak current. Thus, barium reduced the amplitude of muscarinic responses by 79% but cesium reduced them by only 14%. We conclude that muscarinic responses in guinea-pig celiac neurons are produced by suppression of two K+ currents: the M-current and a muscarine-sensitive leak current. These two currents are differentially susceptible to the potassium channel blockers barium and cesium.

Vasopressin induction of long-lasting potentiation of synaptic transmission in the dentate gyrus

Vasopressin receptors are present in both the developing and mature dentate gyrus of the rat brain and are of the V1 vasopressor type. Because vasopressin has been shown to influence memory function when injected into the dentate gyrus, the influence of this peptide on an electrophysiological model of learning and memory using the field excitatory postsynaptic potential (EPSP) of the dentate gyrus was investigated. Results of these studies showed that nanomolar concentrations of [Arg8]-vasopressin induced a prolonged increase in the amplitude and slope of the evoked population response in the presence of 1.5 mM calcium. Moreover, the expression of the vasopressin-induced potentiation of the EPSP persisted following removal of vasopressin from the perfusion medium. The vasopressin-induced sustained increase has been termed long-term vasopressin potentiation (LTVP). The closely related neuropeptide oxytocin had no effect upon the EPSP of the dentate gyrus. Preincubation of hippocampal slices in a selective V1 antagonist blocked the expression of LTVP. The ability of the V1 antagonist to block LTVP demonstrates that the potentiation induced by vasopressin is receptor-specific. In the presence of 2.5 mM calcium, the effect of vasopressin was opposite to that observed in 1.5 mM calcium. Under the conditions of 2.5 calcium, vasopressin induced a prolonged depression in the amplitude and slope of the EPSP. Expression of both potentiation and depression appeared within 5 minutes of application and persisted for the length of the observation, 60 minutes. These experiments demonstrate that vasopressin can induce long-lasting changes in the excitability of dentate gyrus neurons that are both calcium-dependent and receptor-specific.

Mechanisms of vasopressin's anorectic effect

The present experiments investigated the effect of vasopressin (VP) on food intake in rats under various conditions. VP (1.25-10 micrograms/kg body weight = b.wt.) injected intraperitoneally (IP) at the onset of the dark phase of the lighting cycle inhibited feeding in a dose-dependent manner. The suppression of feeding induced by VP was primarily due to a delayed onset of the first meal after injection and was reversed by a V1-receptor antagonist (7 micrograms/kg b.wt., IP), by the Ca(++)-channel blocker verapamil (5 mg/kg b.wt., IP) and by the alpha-adrenergic receptor antagonist phentolamine (500 micrograms/kg b.wt.), but not by dissection of the hepatic branch of the vagus. In further experiments VP inhibited gastric emptying. This effect was not reversed by phentolamine. VP had also an aversive effect, but this effect was weaker than that of LiCl and probably not involved in VP-induced hypophagia. The results suggest that VP reduces feeding through a V1-receptor-mediated activation of an alpha-adrenergic mechanism. The inhibition of gastric emptying or a possible stimulation of hepatic oxidative metabolism by VP seems to be not essential for VP's effect on feeding. The results are consistent with a role of VP in stress-induced anorexia in rats.

The role of serotonin in non-cholinergic excitatory transmission in the guinea pig inferior mesenteric ganglion

The non-cholinergic late slow excitatory postsynaptic potential (ls-EPSP) of the guinea pig inferior mesenteric ganglion (IMG) was previously believed to be mediated by substance P (SP) or several other neuropeptides. Yet, the pharmacological evidence presented here indicates that serotonin (5-HT) may be another transmitter for the ls-EPSP in the guinea pig IMG. Repetitive stimulation of the presynaptic nerves elicited ls-EPSP in about half of the IMG neurons. Application of 5-HT or SP caused, in a portion of the IMG neurons, a slow depolarization similar to ls-EPSP. Fifty-six out of 88 (63.6%) neurons with ls-EPSP and 13 out of 35 (37.1%) neurons with ls-EPSP were sensitive to 5-HT and SP, respectively. Superfusion of the ganglia with 5-HT markedly suppressed the ls-EPSP evoked in 5-HT sensitive neurons. Similarly, exogenously applied SP attenuated the ls-EPSP of SP-sensitive neurons. However, prolonged superfusion of 5-HT or SP had no effect on the ls-EPSP elicited in 5-HT or SP-insensitive neurons, respectively. Furthermore, the ls-EPSPs elicited in 5-HT-sensitive neurons as well as the 5-HT-induced depolarization were reversibly suppressed by cyproheptadine, a 5-HT antagonist, and enhanced by fluoxetine, a 5-HT reuptake inhibitor. In contrast, the ls-EPSP of 5-HT insensitive neurons and SP-induced depolarization were not appreciably changed by those two drugs. Pretreatment with p-chlorophenylalanine, a 5-HT biosynthesis inhibitor, did not change the general electrophysiological characteristics of the neurons and did not suppress nicotinic neurotransmission, but markedly reduced the occurrence rate of ls-EPSP from 53.8% to 15.1% (P less than 0.005). Collectively, our results indicate that, besides SP, 5-HT may be involved in mediating the ls-EPSP in a subpopulation of neurons in the guinea pig IMG. The type of transmitter mediating ls-EPSP is apparently not limited to 5-HT and SP, as about 30% of the neurons with ls-EPSP were found to be insensitive to both 5-HT and SP and prolonged superfusion with both did not affect appreciably the ls-EPSP elicited in these neurons.

Two actions of vasopressin on neurons in the rat ventral hippocampus: a microiontophoretic study

Vasopressin (VP), applied by brief iontophoretic pulses on ventral hippocampus neurons in vivo, excited approximately 30% of the neurons tested. Glutamate (Glu) and acetylcholine (ACh) excited nearly all neurons recorded. A selective antagonist of vasopressin V1 receptors suppressed the VP-induced excitation and, in addition, suppressed the excitations induced by Glu but not those by ACh. The specificity of the action in the brain of this VP antagonist must therefore be doubted. Two excitatory amino acid antagonists, D(-)-2-amino-5-phosphonovaleric acid (2APV) and glutamic acid diethyl ester (GDEE), suppressed the responses to Glu and also those to VP. ACh excitations, tested in the same neurons, were little affected by 2APV and GDEE. The remaining 70% of VH neurons were not excitable with VP. However, the responses of these neurons to Glu but not to Ach, increased markedly both while the peptide was released and for tens of minutes thereafter. The increase in Glu responses induced by VP could not be prevented by the VP or excitatory amino acid receptor antagonists applied before the peptide. The possibility that the excitation and the potentiation of Glu responses caused by VP originated from two different actions of the peptide is discussed.

Comparison of central versus peripheral nerve pathways to the guinea pig inferior mesenteric ganglion determined electrophysiologically after chronic nerve section

The contributions of central versus peripheral nerve pathways to neurons of the inferior mesenteric ganglion of guinea pigs were studied. Nerve trunks innervating neurons in the ganglion were surgically sectioned and intracellular electrical responses to nerve stimulation were measured 6-8 days after surgery. Guinea pigs were divided into two experimental groups: (1) those that had the lumbar sympathetic chain ganglia (LSG) L2 through L4 removed and (2) those that had the intermesenteric, lumbar colonic and hypogastric nerves sectioned leaving central connections intact. After 6-8 days fast excitatory postsynaptic potentials (EPSPs) and slow EPSPs were recorded intracellularly in randomly selected principal ganglionic neurons. The threshold stimulus voltage to elicit a fast EPSP, the amplitude of the slow EPSP and the number of neurons in which each type of synaptic potential occurred in response to stimulation of each of the nerve trunks was compared between surgically-sectioned animals and sham-operated controls. Neither section of preganglionic nerve trunks nor of postganglionic nerve trunks eliminated all synaptic input to neurons in the ganglion, indicating that neurons with cell bodies located central to the ganglion as well as in visceral target organs made synaptic connections in the ganglion. Both fast and slow synaptic potentials could be evoked by stimulation of postganglionic nerve trunks even after they were sectioned provided that preganglionic nerves were intact, indicating that axons of central origin which synapse in the ganglion may continue out into postganglionic nerve trunks. In like manner, evidence was obtained indicating that fibers from peripheral nerve trunks which initiate either fast or slow synaptic potentials in ganglionic neurons may continue out into the lumbar splanchnic nerves. These studies demonstrate that the synaptic potentials recorded in the inferior mesenteric ganglion arise not only from neurons with cell bodies central to the ganglion but also from neurons with cell bodies located in the visceral organs which this ganglion subserves.

Vasopressin and oxytocin express excitatory effects on respiratory and respiration-related neurones in the nuclei of the tractus solitarius in the cat

The effects of the iontophoretic application of vasopressin and oxytocin were examined on the activity of single neurones recorded in the region of the nuclei of the tractus solitarius (NTS) of the cat that were functionally classified as respiratory neurones or presumed reflex interneurones. The excitatory effects observed in half to two-thirds of these neurones tested (n = 37) suggest a role of these peptides in respiratory control and further support recent evidence that their involvement in autonomic control may include an action in NTS.

Vasopressin-sensitive neurons in the lateral paraventricular nucleus area in a guinea pig slice preparation

The effects of vasopressin (VP) on hypothalamic neurons located in the region of the paraventricular nucleus (PVN) were analyzed using intracellular techniques in slices of guinea pig brains. Two different classes of neurons were electrophysiologically identified in the magnocellular lateral part of the PVN and in the adjacent area. In the former area, vasopressinergic neurons were identified according to their phasic activity and their endogenous properties. These neurons were not responsive to VP, applied through the perfusion medium or locally by pressure. On the other hand, nonmagnocellular neurons exhibiting low-threshold Ca2+ spikes (LTS) were recorded in the area adjacent to the lateral part of the PVN. LTS were deinactivated at hyperpolarized membrane levels and induced short bursts of action potentials. On these neurons, VP evoked depolarizations accompanied by increases in firing, without modification of membrane resistance. VP effects were not blocked by TTX, suggesting a postsynaptic action of the peptide. These data indicate that VP controls the firing pattern of LTS neurons and suggest that this action may involve collaterals of axons originating from neighbouring vasopressinergic neurons.

Vasopressin-stimulated turnover of phosphatidylinositol in the decentralised superior cervical ganglion of the rat

Vasopressin (AVP) receptors have been demonstrated in the superior cervical ganglion (SCG) linked to the turnover of phosphatidylinositol (PI). We have investigated the effect of changes in autonomic function on the turnover of PI in the rat SCG in response to AVP and carbachol. Decentralisation of the SCG for 3 days causes a significant decrease in the response to AVP, while the response to carbachol is unaffected. The decrease in response to AVP is still present 21 days after decentralisation. A similar pattern of changes is present in ganglia from the homozygous Brattleboro rat. Pretreatment with reserpine has no effect on the response to AVP. The results suggest that AVP may be involved in ganglionic transmission in the autonomic nervous system, but that full expression of AVP-induced turnover of PI is dependent on an intact preganglionic input.

Electrophysiological evidence for oxytocin receptors on neurones located in the dorsal motor nucleus of the vagus nerve in the rat brainstem

Intracellular recordings were obtained from vagal neurones and their response to oxytocin was investigated in slices from the rat brainstem. Following recording, Lucifer Yellow was injected into the cells in order to verify their localization within the dorsal motor nucleus of the vagus nerve. Virtually all neurones throughout the rostro-caudal extent of the nucleus increased their rate of firing in the presence of 10-1000 nM oxytocin and their membrane depolarized in a reversible, concentration-dependent manner. This excitation was probably exerted directly on the impaled cells rather than being synaptically mediated, since it persisted in a low calcium-high magnesium medium or in the presence of tetrodotoxin. These data provide evidence for a direct membrane effect of oxytocin on a defined population of neurones in the rat brain.

Vasopressin stimulates the phosphorylation of an 83,000 Mr protein in the superior cervical ganglion

1. 32P-Labeled proteins from the superior cervical ganglion of the rat were separated by two-dimensional gel electrophoresis and visualized by autoradiography. 2. The most heavily labeled phosphoprotein in the ganglion had a relative molecular weight of 83,000 and a pI of 4.5. Phosphorylation of this protein was increased by phorbol 12,13-dibutyrate, an activator of the Ca2+/phospholipid-dependent protein kinase, protein kinase C. This protein appears to be similar or identical to a specific protein kinase C substrate that has been described in other tissues (Blackshear, P. J., et al., J. Biol. Chem. 261:1459-1469, 1986). 3. Phosphorylation of this protein was also increased by treatment of the ganglion with phospholipase C (Bacillus cereus) but was not increased by 8-bromo-cyclic AMP or by nicotinic agonists. Vasopressin increased the hydrolysis of inositol-containing phospholipids in the ganglion and also increased the labeling of the 83,000 Mr protein. Thus, vasopressin appears to activate protein kinase C in the ganglion. 4. Muscarine, which also increased phospholipid metabolism in the ganglion, did not increase the phosphorylation of the 83,000 Mr protein. Muscarine and vasopressin stimulate phospholipid metabolism in different structures within the ganglion (Horwitz, J., et al., J. Pharmacol. Exp. Ther. 237:312-317, 1986). Muscarine may increase phospholipid metabolism in structures that do not contain significant amounts of the 83,000 Mr protein.

Vasopressin-induced turnover of phosphatidylinositol in the sensory nervous system of the rat

Vasopressin and oxytocin immunoreactivity (AVP-IR, OT-IR) have been detected in the trigeminal and dorsal root ganglia (TG, DRG) of the rat. We have investigated whether AVP or OT have any neurotransmitter role in these tissues by measuring the effects of the peptides on levels of intracellular second messengers. AVP and OT at concentrations up to 3 x 10(-6) M have no effect on the accumulation of cAMP. However, in tissue prelabelled with 3H-inositol, and in the presence of 10 mM Li+, AVP and OT cause an increase in the accumulation of inositol phosphates (IP), in a dose-dependent manner. AVP causes a maximum stimulation of 1.7 fold of control in TG, (p less than 0.01) and of 2.5 fold in DRG (p less than 0.01) at a concentration of 3 x 10(-7) M. OT causes a maximum stimulation of 1.3 fold of control in TG, (p less than 0.01), and of 1.75 fold of control in DRG, at a concentration of 3 x 10(-6) M. The stimulation of IP turnover by AVP in both tissues is inhibited by the specific V1-antagonist, (CH2)5Tyr(Me)AVP, at a concentration of 2 x 10(-5) M. The V2-agonist, DDAVP, has no effect on IP accumulation in either tissue at concentrations up to 3 x 10(-6) M. The response to exogenous AVP is still present in ganglia incubated in media without added CaCl2. We conclude that the rat TG and DRG contain receptors for AVP, and that these receptors have characteristics associated with the V1 subtype.

Synaptic activation of slow depolarization in rat supraoptic nucleus neurones in vitro

1. The effects of synaptic activation on rat supraoptic nucleus (s.o.n.) neurones were studied in the hypothalamic slice preparation. Intracellular recordings were obtained from forty-one probable magnocellular neuroendocrine cells using microelectrodes filled with 3 M-potassium acetate. Responses to single and repetitive stimulation of the area dorsolateral to the s.o.n., which would be expected to activate a cholinergic pathway (Hatton, Ho & Mason, 1983), were analysed. 2. In forty of forty-one cells, responses to single stimuli consisted of a short-latency excitatory post-synaptic potential (e.p.s.p.), which was often followed by a brief burst of fast depolarizing events which resembled spontaneous e.p.s.p.s. When the membrane was depolarized, single stimuli could consistently produce a burst of action potentials. 3. Brief trains of orthodromic stimuli produced three effects in most cells. Spontaneous fast depolarizing events, which appeared to be primarily e.p.s.p.s. significantly increased in frequency after the train. A slow membrane depolarization, which lasted up to 1-2 min, was observed in twenty-eight of forty-one cells. In several cells the slow depolarization was accompanied by an increase in input resistance (Ri). In some cells an after-discharge occurred during the slow depolarization. Slow depolarizations were observed in each of eleven phasic neurones, and in a smaller percentage of non-phasic and silent cells. 4. All components of the response to dorsolateral stimulation could be reduced or blocked in low-Ca2+, high-Mg2+ bathing medium. 5. Slow depolarizations were observed when action potentials were not elicited by the stimulus train. The slow depolarization was still present after manipulations that blocked discharge during the stimulus train, including injection of hyperpolarizing current and diffusion of the quaternary ammonium compound QX314. These data argue that the slow depolarization can occur independent of spike depolarizing after-potentials (d.a.p.s). 6. In some cells antidromic stimulation at an intensity just suprathreshold for the recorded cell did not produce comparable bursts of fast depolarizing events or slow depolarizations; similar periods of depolarizing current injection, which produced repetitive discharge, also did not mimic the effects of orthodromic stimulation. 7. The fast depolarizing events appear to reflect spontaneous e.p.s.p.s; increases in the frequency of these events may reflect the after-discharge of nearby neurones that are presynaptic to the recorded neurone.(ABSTRACT TRUNCATED AT 400 WORDS)

Vasopressin and glucoprivic-feeding behavior: a new perspective on an 'old' peptide

The feeding responses induced by systemic administration of 2-deoxy-D-glucose (2-DG) and paraventricular hypothalamic injection of norepinephrine were assessed in Brattleboro rats deficient in vasopressin (VP). Controlling for the non-specific complications of diabetes insipidus, it was found that Brattleboro rats have a deficient 2-DG-feeding response, but an essentially normal noradrenergic-feeding response. Specific carbohydrate appetite abnormalities were also demonstrated. It is argued that VP influences 2-DG feeding by mobilizing endogenous energy stores following its acute release from the hypothalamoneurohypophysial system. A new function is thus ascribed for VP and the neural lobe of the pituitary. It is suggested that VP plays a role in stress-induced feeding and in specific aspects of carbohydrate appetite. The potential relevancy of vasopressin perturbations to bulimia nervosa and to the Prader-Willi obesity syndrome is also discussed.

Biochemical and electrophysiological evidence of functional vasopressin receptors in the rat superior cervical ganglion

Binding of radioactive vasopressin--but not of oxytocin--was detected by autoradiography and by labeling of membranes obtained from the rat superior cervical ganglion. In both instances binding could be displaced by V1 (smooth muscle-type) but not by V2 (kidney-type) agonists, indicating that the ganglionic vasopressin receptors are similar to those present on hepatocytes and vascular smooth muscle. In accordance with the V1 character of the receptors, vasopressin activated the turnover of membrane inositol lipids, and this effect was abolished by a structural analogue known to act as a vasopressor antagonist. A possible physiological role of vasopressin was suggested by intracellular recordings obtained from ganglion cells in vitro. Vasopressin induced a reduction in the amplitude of the fast excitatory postsynaptic potential evoked by electrical stimulation of the preganglionic nerve. This reduction in ganglionic transmission was antagonized by the same synthetic structural analogue that blocked the effect of vasopressin on inositol lipids. This study provides evidence for the presence of functional vasopressin receptors in a rat sympathetic ganglion and thus suggests that vasopressin may play a role in peripheral autonomic function.

A quantitative analysis of the interrelationships between subpopulations of rat sensory neurons containing arginine vasopressin or oxytocin and those containing substance P, fluoride-resistant acid phosphatase or neurofilament protein

In rat L5 dorsal root ganglia 50% of neurons contained arginine vasopressin-like immunoreactivity and 38% oxytocin-like immunoreactivity, the oxytocin entirely coexisting with the arginine vasopressin. Staining of alternate mirror-image sections with RT97 (an antibody to neurofilament protein, and a marker for large light neurons) and with arginine vasopressin antiserum showed that the two were entirely complementary, thus establishing arginine vasopressin as a marker for all small dark neurons. Mirror-image staining also showed that neurons containing substance P-like immunoreactivity and those containing fluoride-resistant acid phosphatase activity were each contained within the arginine vasopressin-positive population. Arginine vasopressin-like immunoreactivity was axonally transported in the dorsal root and (in greater quantity) in sciatic nerve. Arginine vasopressin-like immunoreactivity was present also in laminae I and II of the dorsal horn of the spinal cord and this reactivity was absent in animals which had been treated neonatally with capsaicin, suggesting that it was contained in primary afferent terminals. These results are discussed in terms of their implications for the classification of primary afferent neurons and of a possible physiological role for arginine vasopressin in these neurons.

Non-cholinergic transmission in a sympathetic ganglion of the guinea-pig elicited by colon distension

Sensory transmission from the colon was studied using a preparation of inferior mesenteric ganglion (i.m.g.) attached to a segment of distal colon in guinea-pigs, in vitro. Electrical responses to colon distension were recorded intracellularly from neurones of the i.m.g. Distension of the distal colon up to an intraluminal pressure of 20 cmH2O caused an increase in resting asynchronous synaptic activity and a concomitant slow depolarization. The asynchronous synaptic activity, but not the slow depolarization, was abolished by cholinergic antagonists. Distension-induced non-cholinergic depolarizations were elicited in 44% of i.m.g. neurons sampled. For distensions of 1 min at 10-20 cmH2O, depolarizations reached a mean amplitude of 3.4 +/- 0.3 mV and lasted 108 +/- 7 s. Continuous distension resulted in a tachyphylaxis of the depolarization. Tetrodotoxin (3 X 10(-7) M) superfused over the i.m.g. reversibly abolished the distension-induced non-cholinergic depolarization. Distension-induced non-cholinergic depolarizations were accompanied by an increase in input resistance of 21%. Neuronal excitability also increased, as sub-threshold potentials produced by intracellular current injection reached threshold for firing action potentials during colon distension. The amplitude of non-cholinergic depolarizations increased with colonic intraluminal pressure between 2 and 20 cmH2O, although the slope of the mean amplitude-pressure curve decreased progressively at higher pressures. The amplitude of distension-induced non-cholinergic depolarizations increased as membrane potential was manually hyperpolarized to approximately -80 mV, whereupon further hyperpolarization resulted in a decrease in response amplitude. Non-cholinergic slow excitatory post-synaptic potentials (e.p.s.p.s) evoked by repetitive presynaptic nerve stimulation were reversibly attenuated by 19 +/- 8% during depolarizations produced by distension. Systemic administration of capsaicin (50-350 mg/kg) reduced the number of i.m.g. neurones exhibiting the non-cholinergic mechanosensory response; direct superfusion of capsaicin over the i.m.g. attenuated the response in some neurones but had no effect in others. These results demonstrate the existence of a non-cholinergic mechanosensory pathway from the colon to the i.m.g., and suggest that non-cholinergic transmission in the ganglion participates in mediating gastrointestinal reflexes. One transmitter utilized by the non-cholinergic mechanosensory pathway may be substance P.

Fast and slow synaptic potentials produced in a mammalian sympathetic ganglion by colon distension

Radial distension of the large intestine produced a slow depolarization in a population of neurons in the inferior mesenteric ganglion of the guinea pig. The slow potentials often occurred simultaneously with cholinergic fast potentials [( excitatory postsynaptic potentials (EPSPs]) yet persisted in the presence of nicotinic and muscarinic cholinergic antagonists when all fast EPSPs were absent. The amplitude of the distension-induced noncholinergic slow depolarization increased with increasing distension pressure. For distensions of 1-min duration at pressures of 10-20 cm of water, the mean depolarization amplitude was 3.4 mV. The slow depolarization was associated with an increase in membrane resistance, and prolonged periods of colon distension resulted in a tachyphylaxis of the depolarization. Desensitization of ganglion cells to the peptide substance P attenuated the distension-induced slow potential by an average of 49% +/- 17%. Thus, two colonic mechanosensory afferent pathways converge on principal ganglion cells in the inferior mesenteric ganglion: one was previously described to be mediated by acetylcholine, and the other is described here, whose transmitter remains to be determined but which preliminary evidence suggests is mediated in part by substance P. The noncholinergic afferent pathway may enhance the intestinal inhibitory reflex mediated by cholinergic mechanosensory afferent input to the abdominal prevertebral sympathetic ganglia.

Neurohypophysial peptides depress cholinergic transmission in a mammalian sympathetic ganglion

The actions of arginine-vasopressin (AVP) and oxytocin (OXT) were investigated in the rat superior cervical ganglion (SCG). At micromolar concentrations AVP decreased the amplitude of fast excitatory postsynaptic potentials (f-EPSPs) evoked by preganglionic stimulation and in many cells depolarized the postsynaptic membrane. Both effects were reversibly abolished by a potent vasopressor antagonist. The peptide decreased the frequency of spontaneous miniature EPSPs and the quantal content of the f-EPSPs without affecting the sensitivity of the ganglion cells to acetylcholine. OXT exerted the same effects as AVP but was less powerful. It was concluded that neurohypophysial peptides exert a dual pre- and post-synaptic action mediated by specific receptors.