Behavioral and electrophysiological studies of peptide-induced emesis in dogs

The electrophysiological responses of neurons in the canine area postrema (AP) to ionophoretic application of neuropeptides and transmitters were studied and correlated with the presence or absence of an emetic response on systemic administration. Of 17 common neuropeptides 11 were emetic when applied systemically at doses of 0.03-0.35 mg/kg. The emesis was dose dependent and was no longer observed in animals with chronic ablation of the AP. The responses of 122 AP single units were recorded. Neurons were silent at rest, and most were excited by glutamate, apomorphine, and dopamine. Excitatory responses to each of eight emetic peptides were recorded in 22-65% of cells studied; no responses were found to two peptides that were not emetic. The response to glutamate was always a brief, high-frequency discharge; the responses to all 13 other excitatory substances were of long latency, low frequency, and long duration. With high ionophoretic current or multiple applications, units would frequently become spontaneously active for many minutes or longer. The similarity of response of so many substances on small neurons suggests a common ionic or metabolic mechanism underlying the response. The direct correlation between the occurrence of emesis on systemic administration and the presence of excitatory receptors on AP neurons provides strong support for the proposed role of the AP as the chemoreceptor trigger zone for emesis.     

Unit responses in area 5b of the suprasylvian gyrus to stimulation of the ventral posterolateral thalamic nucleus

Unanesthetized cats were immobilized with D-tubocurarine. Single unit responses in area 5b of the suprasylvian gyrus to stimulation of the ventral posterolateral thalamic nucleus were recorded extracellularly. Of the total number of neurons tested, 32% were excited and 3% inhibited. In 65% of neurons the responses were mixed, most of them being predominantly excitatory. Repetitive stimulation of the ventral posterolateral nucleus (6–9/sec) frequently intensified the excitatory component of the responses. Sometimes inhibition, present in the response to a single stimulus, was replaced by increased excitation. However, the same response as to a single stimulus frequently appeared in response to each consecutive stimulus of a series. Stimulation of the ventral posterolateral nucleus had a mainly excitatory effect on neurons in area 5b. Stimulation of the dorsal lateral nucleus, on the other hand, inhibited their activity. This antagonism could also be observed on the same neuron. It was concluded from the short latent periods of the orthodromic responses (3–6 msec) and from the antidromic responses of the cortical neurons to stimulation of the ventral posterolateral nucleus that this nucleus has direct two-way connections with the cortex of area 5b.     

Neural mechanisms of emesis

Emesis is a reflex, developed to different degrees in different species, that allows an animal to rid itself of ingested toxins or poisons. The reflex can be elicited either by direct neuronal connections from visceral afferent fibers, especially those from the gastrointestinal tract, or from humoral factors. Emesis from humoral factors depends on the integrity of the area postrema; neurons in the area postrema have excitatory receptors for emetic agents. Emesis from gastrointestinal afferents does not depend on the area postrema, but probably the reflex is triggered by projections to some part of the nucleus tractus solitarius. As with a variety of other complex motor functions regulated by the brain stem, it is likely that the sequence of muscle excitation and inhibition is controlled by a central pattern generator located in the nucleus tractus solitarius, and that information from humoral factors via the area postrema and visceral afferents via the vagus nerve converge at this point. This central pattern generator, like those for motor functions such as swallowing, presumably projects to the various motor nuclei, perhaps through interneuronal pathways, to elicit the sequential excitation and inhibition that controls the reflex.     

5'guanylyl-imidodiphosphate actions on adenylate cyclase in homogenates of rat cerebral cortex plus neuronal and capillary fractions

A variety of neurohumoral agents activate adenylate cyclase in homogenates of rat frontal cortex (norepinephrine, isoproterenol, dopamine, apomorphine, histamine, 4-Me-histamine and prostaglandins E₁, E₂ and A₂). The enzyme in homogenates of isolated cortical neurons is likewise sensitive to norepinephrine, isoproterenol, dopamine, apomorphine, histamine, 2-Me- and 4-Me-histamine, and prostaglandin F_2α. Capillary-enriched fractions from the cortex possess an enzyme that is activated by norepinephrine, isoproterenol and dopamine. Addition of 5′-guanylyl-imidodiphosphate (Gpp(NH)p) to the cortical homogenates and neuronal fractions resulted in enhanced enzyme responses to norepinephrine, isoproterenol, dopamine, 2-Me- and 4-Me-histamine and the prostaglandins E₁ and E₂. The actions of histamine and apomorphine were not increased by the GTP analog. The sensitivity of the catecholamine-induced adenylate cyclase activation in cortical capillaries was augmented by Gpp(NH)p. Thus various cellular types within the cerebral cortex may possess different receptor characteristics with respect to stimulation of adenylate cyclase by neurohormones.     

Dopaminergic modulation of visual responses in toads II. Influences of apomorphine on retinal ganglion cells and tectal cells

The behavioral studies of Part I have shown in common toads that after systemic administration of the dopamine agonist apomorphine the prey-directed orienting turning movements are suppressed while prey snapping is facilitated. Part II focusses on retinal and tectal single cell responses to moving objects. (1) After systemic administration of apomorphine, the discharge rates of retinal class R2 and R3 ganglion cell fibres – recorded from the retino-tectal projection – speeded up in response to visual objects traversing their excitatory receptive fields. This enhancing effect was independent of the recording site in the retino-tectal map. (2) The diameters of the excitatory receptive fields of R2 and R3 neurons doubled their sizes. Probably, apomorphine enhances the center-dominated excitatory responses at the expense of the strength of the inhibitory surround. (3) The apomorphine-induced effects were fully developed 20–35 min after drug administration. (4) At the same time the discharge rates of T5.1 and T5.2 tectal neurons were reduced under apomorphine. The effect was independent of the recording site in the retino-tectal map. The diameters of the excitatory receptive fields of these tectal neurons were not influenced. (5) To changes in configurational stimulus features, the basic pattern of discrimination was maintained. (6) It is suggested that tectal output to the turn-generating motor network – mediated by T5.1 and T5.2 neurons – is modulated by a pretecto-tectal pathway which involves dopaminergic pretectal cells. (7) The enhanced snapping can be interpreted in terms of a modulation of reticular/hypoglossal structures by dopaminergic preoptic/hypothalamic/solitary systems.     

Effects of glutamate-induced excitotoxicity on calretinin-expressing neuron populations in the area postrema of the rat

We mapped the distribution of calretinin-immunoreactive neuron populations in a circumventricular organ of the rat, the area postrema, and investigated their sensitivity to excitotoxic stimuli mediated by subcutaneously administered monosodium glutamate. We were specifically interested to ascertain whether the presence of calretinin can, per se, confer an in vivo intrinsic resistance for area postrema neurons to glutamate excitotoxicity. We found that dense populations of calretinin-positive neurons displayed a subregional compartmentation in coronal sections of the area postrema along its rostrocaudal axis. We demonstrated that calretinin-positive neurons differ in their sensitivities to monosodium glutamate depending on their position within the area postrema. Neurons in the caudal area postrema were the most sensitive ones, while those in the rostral area postrema were spared of degeneration. We conclude that calretinin-positive neurons in the area postrema are not uniformly protected against glutamate excitotoxicity. It is possible that differences in the local concentrations of monosodium glutamate due to regional heterogeneities in density and permeability of the capillary bed rather than neuronal expression of calretinin account for the observed effects.     

Area postrema: cholinergic and noradrenergic regulation of emesis. A new concept

In unanaesthetized cats the biochemical mechanisms and the functional characteristics of the emetic action of injection of noradrenaline and McN-A-343, a ganglionic muscarinic stimulant into the cerebral ventricle (i.c.v.) through chronically implanted cannulae were investigated. Both produced dose-dependent and shortlasting emetic response. The emesis evoked by noradrenaline was abolished, whereas the emesis induced by McN-A-343 was not completely blocked after ablation of the area postrema. Further, the emetic response to noradrenaline as well as to McN-A-343 was attenuated or blocked in cats pretreated with 6-hydroxydopamine (i.c.v.) and hemicholinium (i.c.v.); it was abolished in cats pretreated with reserpine (i.c.v.). On the other hand, the emetic response to i.c.v. noradrenaline and to i.c.v. McN-A-343 was not virtually altered in cats pretreated with bretylium (i.c.v.), alpha-methyl-p-tyrosine (i.c.v.) and 5,6-dihydroxytryptamine (i.c.v.). It is postulated that noradrenergic neurones as well as cholinergic axon terminals within the area postrema are necessary for the emetic action of noradrenaline, whereas cholinergic axon terminals within the area postrema subserve the emetic response to McN-A-343. A functional link between cholinergic terminals and noradrenergic neurones as well as a modulatory role of noradrenergic afferents on cholinergic afferents mediating emesis within the area postrema is further proposed. Thus, noradrenergic neurones might represent a common site of confluence of different inputs subserving the emesis in the area postrema. Finally, cholinergic terminals sometimes bypass this area and synapse in the emetic regions of the brainstem regulating emesis.     

Effects of glutamate on the serotonin-induced responses of vestibular neurons

The aim of this work was to verify whether and how spontaneous or glutamate(GLU)-induced enhancements of the neuronal firing rate modified the responsiveness of the vestibular neurons to microiontophoretic application of serotonin (5-HT). During experiments performed on anaesthetized Wistar rats the responses to 5-HT applications were studied in neurons of the lateral vestibular nucleus identified by the antidromic activation upon stimulation of the vestibulospinal tract. The magnitude (in percent) of the 5-HT induced excitatory responses decreased (hyperbolic correlation, r = 0.91) when the background mean firing rate was enhanced spontaneously or by long-lasting application of GLU. Even in high-discharging units, the response never changed its sign. The trend to a depression of the response to 5-HT in function of the background discharge was observed when either the enhancement of firing occurred spontaneously and it was induced by an application of GLU, no significant difference (F-test) being found between the two cases. It is concluded that serotoninergic afferents can exert a strong control upon the vestibular neurons when the background activity is depressed, and only a weak influence when the neuronal firing is enhanced by other excitatory afferents. It remains to verify whether the type of interference observed between GLU and 5-HT is specific or can be also detected between 5-HT and other excitatory neuromediators.     

Possible involvement of serotonin receptors in the facilitatory effect of a hallucinogenic phenethylamine on single facial motoneurons

2,5-Dimethoxy-4-methylamphetamine (DOM, "STP") is a potent hallucinogen, proposed to be a serotonin receptor agonist. Its effects have not previously been tested upon central neurons where serotonin is excitatory and serotonin antagonists are effective. Extracellular single unit recordings were obtained from facial motoneurons in anaesthetized rats, and drugs were applied from five-barrelled micropipettes by iontophoresis. Facial motoneurons were commonly silent. During subthreshold application of glutamate, firing could be induced by dopamine and DOM. As reported by others, serotonin and noradrenaline also excited facial motoneurons under these conditions. Methysergide antagonized responses to serotonin and DOM but not those to noradrenaline; methysergide could not usually discriminate between responses to serotonin and dopamine. Ketanserin reversibly antagonized (but could not discriminate between) responses to serotonin, dopamine, and noradrenaline. Chlorpromazine antagonized responses to dopamine at doses that did not alter serotonin-induced excitation, and responses to DOM were not reduced by doses of chlorpromazine, that had no local anaesthetic effect on action potentials elicited by DOM and serotonin. These results suggest that DOM is an agonist on at least one type of central serotonin receptor. This receptor may also be a ketanserin (5-HT2) binding site.     

Effect of withdrawal from chronic ethanol ingestion on the cAMP response of cerebral cortical slices using the agonists histamine, serotonin, and other neurotransmitters.

The effect of ethanol withdrawal on the cAMP response of cerebral cortical brain slices was studied. The cAMP response was evoked in vitro by various neurotransmitters including norepinephrine (NE), histamine, serotonin, dopamine, acetylcholine, and gamma-aminobutyric acid (GABA). The cAMP response to NE and histamine was enhanced by ethanol withdrawal. Serotonin evoked a cAMP response in the brain slices from ethanol-withdrawal rats but not in pair-fed controls. The histamine and serotonin evoked responses were blocked by chlortripolon and methysergide, respectively. The responses to histamine and serotonin were also blocked by alpha- and beta-adrenergic antagonists, possibly because of the nonspecific membrane stablizing effect of these antagonists. GABA inhibited the NE stimulated cAMP response possibly through the hyperpolarizing action of GABA. The results support the hypothesis that ethanol withdrawal induces a nonspecific postjunctional supersensitivity. It is postulated that the supersensitivity involves a partial depolarization of the receptor membrane. Alternative hypotheses are reviewed.     

Cholecystokinin octapeptide: effects on the excitability of cultured spinal neurons

The actions of cholecystokinin octapeptide (CCK) on the membrane properties of mouse spinal neurons grown in monolayer culture were examined using intracellular recording techniques. In a subpopulation of cells, application of CCK (0.2-100 micron) by pressure ejection from micropipettes produced a small (approximately 2 mV) membrane depolarization that was accompanied by a decrease in membrane conductance (approximately 11 percent). These effects were associated with an enhanced tendency of the cells to generate action potentials when stimulated with intracellular depolarizing current. The unsulfated analog of CCK, which possesses weak biological activity in the gut, had little or no effect on cultured spinal neurons. A number of differences were noted between the responses to CCK and the excitatory amino acid glutamate. First, the effects of CCK were more delayed in onset (approximately 17 sec) and prolonged in duration (approximately 124 sec). Second, the depolarizations produced by glutamate were of larger magnitude and associated with variable effects on membrane conductance. Third, the response to CCK showed tachyphylaxis with repeated applications whereas glutamate remained effective as often as it was applied. It is concluded that CCK facilitates the excitability of spinal neurons in a manner distinct from that of the conventional excitant glutamate.     

Excitation of neurons in the canine area postrema by prostaglandins

The effects of prostaglandins on electrical activity of neurons in the canine area postrema were studied using the techniques of extracellular recording with iontophoresis. Excitatory responses were obtained upon application of prostaglandins A1, B1, B2, E1, F1 alpha, and F2 alpha in between 24 and 50% of the cells studied. The excitation was very similar in pattern to that observed to apomorphine, biogenic amines, and several neuropeptides in that it had a relatively long latency, low maimal frequency, and prolonged duration. Since the area postrema is known to play a central receptive role in initiating emesis to circulating toxins, these results suggest that prostaglandins may play a role in the initiation of some forms of emesis.     

The modulation of excitatory amino acid responses by serotonin in the cat neocortexin vitro

1. The electrophysiological actions of excitatory amino acids and serotonin were investigated in slices from cat neocortex in vitro. Intracellular recordings were obtained from neurons (mainly in layer V) and the drugs applied extracellularly to the same neurons by microiontophoresis. 2. Serotonin, and to some extent noradrenaline, facilitated the excitatory actions of N-methyl-D-aspartate (NMDA), glutamate, and quisqualate but caused no changes in the passive neuronal membrane properties when presented alone. Serotonin had no effect on evoked excitatory postsynaptic potentials (EPSPs) or spike afterhyperpolarizations. 3. The facilitatory effect of serotonin on the responses to NMDA was observed with both somatic and dendritic applications. It persisted during Mg2+ depletion and in the presence of tetrodotoxin and tetraethylammonium. The effect was attenuated by the serotonin antagonist cinanserin but not by methysergide. A possible underlying receptor modulation is discussed.     

The emetic effect of B-HT 920 and apomorphine in the dog: antagonism by haloperidol

Recent investigations have suggested that the alpha 2-adrenoreceptor agonist B-HT 920 is also a dopamine (DA) agonist with a selectivity for presynaptic receptors. In the present study, the emetic effect of B-HT 920 was investigated. Intravenous injections of B-HT 920 (0.32-10.0 micrograms/kg) and a DA2-agonist apomorphine (3.2-100.0 micrograms/kg) caused dose-dependent emesis. The ED50 of B-HT 920 and apomorphine were 3.2 and 12.3 micrograms/kg, respectively. When haloperidol (10.0-24.5 micrograms/kg i.v.), a DA2-antagonist, was given 5 minutes before B-HT 920 (10 micrograms/kg) or apomorphine (32 micrograms/kg), it caused a dose-dependent prevention of B-HT 920- and apomorphine-induced emesis. The ED50 of haloperidol in preventing the emetic effect of both drugs was identical (13.5 micrograms/kg). In contrast, haloperidol (32 micrograms/kg i.v.) did not prevent the emetic effect of ouabain (40 micrograms/kg i.v.). Neither did yohimbine (0.1 mg/kg i.v.), an alpha 2-adrenoreceptor antagonist, prevent the emetic effect of B-HT 920 (10 micrograms/kg). These results suggest that B-HT 920, acting like apomorphine, induces emesis by activating DA2-receptors probably in the chemoreceptor trigger zone of the area postrema.     

The effects of striatal lesion on turning behavior and globus pallidus single unit response to dopamine agonist administration

In normal rats, globus pallidus neurons are excited by the systemic administration of postsynaptically active doses of apomorphine. The role of the striatum in mediating this phenomenon was examined by investigating the effects of apomorphine on neuronal activity in the globus pallidus and on turning behavior in rats with unilateral quinolinic acid lesions of the striatum. The lesion markedly reduced striatal choline acetyltransferase activity and GABA content and significantly attenuated apomorphine's effect on the activity of pallidal neurons. Both the extent of attenuation of the electrophysiological response of pallidal neurons in lesioned animals and the neurotoxin-induced decreases in choline acetyltransferase activity and GABA content in the caudal striatum were correlated with the degree of apomorphine-induced turning. The data indicate that striatopallidal neurons contribute to apomorphine's excitatory effect on the activity of pallidal neurons in normal animals.     

Adrenal versus nonadrenal sympathetic preganglionic neurones in the lower thoracic intermediolateral nucleus of the cat: effects of serotonin, substance P, and thyrotropin-releasing hormone.

Adrenal and nonadrenal sympathetic preganglionic neurones (SPNs) in the intermediolateral nucleus of spinal segments T8-T10 in the cat were compared according to their responses to iontophoretic application of serotonin, substance P, and thyrotropin-releasing hormone (TRH). Responses of both types of SPN to iontophoretic application of serotonin were characterized by an increase in the rate of discharge that was slow in onset (mean +/- SD = 36 +/- 21 s) and prolonged in afterdischarge (115 +/- 70 s) following termination of application. Depression was never observed and responses were similar whether using serotonin at a pH of 3.3 or 4.5, suggesting that the absence of a depressant effect cannot be accounted for by pH, as has been reported with cortical neurones. Iontophoretic application of methysergide resulted in a decrease in the rate of discharge of both types of SPN and blocked the excitatory responses to serotonin. Adrenal and nonadrenal SPNs were excited by iontophoretic application of substance P. Responses of both types of SPN were similar and were characterized by a gradual increase in the rate of discharge that was slow in onset (42 +/- 27 s) and prolonged in afterdischarge (96 +/- 42 s). Finally, adrenal and nonadrenal SPNs were also weakly excited by iontophoretic application of TRH. These responses were slow in onset (48 +/- 27 s) and prolonged in afterdischarge (78 +/- 35 s). These data indicate that serotonin, substance P, and TRH exert excitatory effects on functionally dissimilar sympathetic preganglionic neurones and support the possibility that they may be chemical mediators of synaptic transmission in the intermediolateral nucleus. In addition, these data may be interpreted to support the notion that serotonin, substance P, and TRH are involved in global activation of the sympathetic nervous system.     

Intranuclear coupling of hypothalamic magnocellular nuclei by glutamate synaptic circuits

Magnocellular neurons of the supraoptic nucleus (SON) and paraventricular nucleus (PVN) display bursting activity that is synchronized under certain conditions. They receive excitatory synaptic inputs from intrahypothalamic glutamate circuits, some of which are activated by norepinephrine. Ascending noradrenergic afferents and intrahypothalamic glutamate circuits may be responsible for the generation of synchronous bursting among oxytocin neurons and/or asynchronous bursting among vasopressin neurons located in the bilateral supraoptic and paraventricular nuclei. Here, we tested whether magnocellular neurons of the PVN receive excitatory synaptic input from the contralateral PVN and the region of the retrochiasmatic SON (SONrx) via norepinephrine-sensitive internuclear glutamate circuits. Whole cell patch-clamp recordings were performed in PVN magnocellular neurons in coronal hypothalamic slices from male rats, and the ipsilateral SONrx region and contralateral PVN were stimulated using electrical and chemical stimulation. Electrical and glutamate microdrop stimulation of the ipsilateral SONrx region or contralateral PVN elicited excitatory postsynaptic potentials/currents (EPSP/Cs) in PVN magnocellular neurons mediated by glutamate release, revealing internuclear glutamatergic circuits. Microdrop application of norepinephrine also elicited EPSP/Cs, suggesting that these circuits could be activated by activation of noradrenergic receptors. Repetitive electrical stimulation and drop application of norepinephrine, in some cases, elicited bursts of action potentials. Our data reveal glutamatergic synaptic circuits that interconnect the magnocellular nuclei and that can be activated by norepinephrine. These internuclear glutamatergic circuits may provide the functional architecture to support burst generation and/or burst synchronization in hypothalamic magnocellular neurons under conditions of activation.     

17 beta-Estradiol inhibits angiotensin II activation of area postrema neurons

It is well established that the area postrema, as a circumventricular organ, is susceptible to modulation by circulating hormones and peptides. Furthermore, activation of the area postrema has been shown to modulate central neurons involved in the regulation of cardiovascular function and blood pressure. In particular, the vasoactive peptide angiotensin II (ANG II) has been shown to inhibit baroreflex regulation of heart rate and increase sympathetic outflow and blood pressure via activation of area postrema neurons. Estrogen is thought to protect against hypertension in both humans and animal models and has been shown in a number of systems to alter the effects of ANG II. The purpose of the present study was to determine the effects of estrogen on ANG II activation of area postrema neurons. In this study, the effects of ANG II and KCl on fura 2-measured cytosolic Ca2+ concentration ([Ca2+]i) responses in cultured area postrema neurons in the presence and absence of 12-h exposure to 100 nM 17 beta-estradiol (E2) were evaluated. In neurons incubated in control vehicle media, 50 nM ANG II increased [Ca2+]i by 92 +/- 12%. In neurons preincubated with 100 nM E2, ANG II increased [Ca2+]i by only 68 +/- 11%, for a total inhibition of the ANG II-evoked response of 24%. Coapplication of the estrogen receptor antagonist ICI-182,780 did not inhibit the effects of E2. In the same cells in which the effects of E2 on ANG II-evoked responses were tested, the effects of incubation in E on the depolarization-induced increased [Ca2+2]i due to 60 mM KCl were also tested. Incubation of the cells with 100 nM E increased the KCl-evoked [Ca2+2]i response, and this response was blocked by ICI-182,780. These results suggest that in the area postrema, estrogen may utilize multiple pathways to modulate neural activity and responses to ANG II.     

Pharmacological properties of canine intrapulmonary blood vessels

The contractile response of ring segments of large, medium, and small pulmonary arteries and veins of the dog to histamine, norepinephrine, and serotonin have been studied. The maximum contractile response to these drugs was normalized with respect to the maximal response obtained in stimulation with 127 mM K+. The small pulmonary artery was more reactive to histamine, norepinephrine, and serotonin when compared with large and medium pulmonary arteries. The medium and large pulmonary artery showed no difference in reactivity to histamine. However, the mean effective dose (ED50) values for these agonists among the different segments of pulmonary arteries showed no significant difference. The small and medium pulmonary veins demonstrated increased reactivity to histamine, but not norepinephrine and serotonin. The ED50 values also indicated that both small and medium veins were more sensitive to histamine when compared with the large pulmonary vein. The log concentration percent response curves for both small and medium pulmonary veins were displaced leftward (increased sensitivity) with respect to that for the large pulmonary vein. However, the reactivity and sensitivity to histamine between medium and small pulmonary veins were no different. The reactivity and sensitivity of different segments of pulmonary veins to norepinephrine and serotonin showed no significant differences among them. We conclude that histamine and other vasoactive substances, which are directly or indirectly related to mast cell degranulation, exert pharmacological effects on the pulmonary vasculature which possesses differential responsiveness at various levels of the vascular tree.     

Homologous Desensitization of Muscarinic Cholinergic, Histaminergic, Adrenergic, and Serotonergic Receptors Coupled to Phospholipase C in Cerebellar Granule Cells

Cultured cerebellar granule cells express phospholipase C-coupled muscarinic cholinergic, histaminergic, alpha 1-adrenergic, and serotonergic receptors. In an attempt to study desensitization of these neurotransmitter receptors, cells were prestimulated with saturating concentrations of carbachol, histamine, norepinephrine, or serotonin during the labeling of cells with myo-[3H]inositol and then rechallenged with various receptor agonists for their ability to elicit accumulation of [3H]inositol monophosphate in the presence of lithium. Prestimulation with each of these receptor agonists was found to cause a time-dependent desensitization to subsequent stimulation with the desensitizing agonist. Thus, prestimulation for 0.5, 4, and 18 h decreased carbachol response to 87 +/- 4, 52 +/- 2, and 40 +/- 1% of the control, respectively; histamine response to 37 +/- 2, 24 +/- 2, and 18 +/- 2%, respectively; norepinephrine response to 55 +/- 5, 14 +/- 1, and 10 +/- 1%, respectively; and serotonin response to 36 +/- 1, 18 +/- 1, and 9 +/- 2%, respectively. In all cases, the responses mediated by receptors which were not prestimulated remained virtually unchanged, thus indicating homologous desensitization. Dose-response studies indicate that the desensitization was associated with a major reduction in the maximal extent of agonist-induced responses. The basal accumulation was markedly enhanced following 0.5- and 4-h prestimulation, but returned to near normal after 18-h pretreatment. Biologically active phorbol ester, 4 beta-phorbol 12-myristate 13-acetate, rapidly attenuated basal phospholipase C activity, as well as the responses mediated by carbachol, histamine, norepinephrine, and serotonin, suggesting that activation and translocation of protein kinase C might play a role in the desensitization of phospholipase C-coupled receptors.(ABSTRACT TRUNCATED AT 250 WORDS)