The contributions of muscarinic receptors and changes in plasma aldosterone levels to the anti-hypertensive effect of Tulbaghia violacea.

BACKGROUND: Tulbaghia violacea Harv. (Alliaceae) is used to treat various ailments, including hypertension (HTN) in South Africa. This study aims to evaluate the contributions of muscarinic receptors and changes in plasma aldosterone levels to its anti-hypertensive effect. METHODS: In the acute experiments, methanol leaf extracts (MLE) of T. violacea (30-120 mg/kg), muscarine (0.16 -10 µg/kg), and atropine (0.02 - 20.48 mg/kg), and/or the vehicle (dimethylsulfoxide (DMSO) and normal saline (NS)) were respectively and randomly administered intravenously in a group of spontaneously hypertensive (SHR) weighing 300 to 350 g and aged less than 5 months. Subsequently, T. violacea (60 mg/kg) or muscarine (2.5 µg/kg) was infused into eight SHRs, 20 min after atropine (5.12 mg/kg) pre-treatment. In the chronic (21 days) experiments, the SHRs were randomly divided into three groups, and given the vehicle (0.2 ml/day of DMSO and NS), T. violacea (60 mg/kg/day) and captopril (10 mg/kg/day) respectively into the peritoneum, to investigate their effects on blood pressure (BP), heart rate (HR), and plasma aldosterone levels. Systolic BP and HR were measured using tail-cuff plethysmography during the intervention. BP and HR were measured via a pressure transducer connecting the femoral artery and the Powerlab at the end of each intervention in the acute experiment; and on day 22 in the chronic experiment. RESULTS: In the acute experiments, T. violacea, muscarine, and atropine significantly (p < 0.05) reduced BP dose-dependently. T. violacea and muscarine produced dose-dependent decreases in HR, while the effect of atropine on HR varied. After atropine pre-treatment, dose-dependent increases in BP and HR were observed with T. violacea; while the BP and HR effects of muscarine were nullified. In the chronic experiments, the T. violacea-treated and captropril-treated groups had signicantly lower levels of aldosterone in plasma when compared to vehicle-treated group. Compared to the vehicle-treated group, significant reduction in BP was only seen in the captopril-treated group; while no difference in HR was observed among the groups. CONCLUSION: The results obtained in this study suggest that stimulation of the muscarinic receptors and a reduction in plasma aldosterone levels contribute to the anti-hypertesive effect of T. violacea.

Identification of the muscarinic pathway underlying cessation of sleep-related burst activity in rat thalamocortical relay neurons.

Modulation of the standing outward current (I (SO)) by muscarinic acetylcholine (ACh) receptor (MAChR) stimulation is fundamental for the state-dependent change in activity mode of thalamocortical relay (TC) neurons. Here, we probe the contribution of MAChR subtypes, G proteins, phospholipase C (PLC), and two pore domain K(+) (K(2P)) channels to this signaling cascade. By the use of spadin and A293 as specific blockers, we identify TWIK-related K(+) (TREK)-1 channel as new targets and confirm TWIK-related acid-sensitve K(+) (TASK)-1 channels as known effectors of muscarinic signaling in TC neurons. These findings were confirmed using a high affinity blocker of TASK-3 and TREK-1, namely, tetrahexylammonium chloride. It was found that the effect of muscarinic stimulation was inhibited by M(1)AChR-(pirenzepine, MT-7) and M(3)AChR-specific (4-DAMP) antagonists, phosphoinositide-specific PLCß (PI-PLC) inhibitors (U73122, ET-18-OCH(3)), but not the phosphatidylcholine-specific PLC (PC-PLC) blocker D609. By comparison, depleting guanosine-5'-triphosphate (GTP) in the intracellular milieu nearly completely abolished the effect of MAChR stimulation. The block of TASK and TREK channels was accompanied by a reduction of the muscarinic effect on I (SO). Current-clamp recordings revealed a membrane depolarization following MAChR stimulation, which was sufficient to switch TC neurons from burst to tonic firing under control conditions but not during block of M(1)AChR/M(3)AChR and in the absence of intracellular GTP. These findings point to a critical role of G proteins and PLC as well as TASK and TREK channels in the muscarinic modulation of thalamic activity modes.

Cholinergic activation of M2 receptors leads to context-dependent modulation of feedforward inhibition in the visual thalamus.

In many brain regions, inhibition is mediated by numerous classes of specialized interneurons, but within the rodent dorsal lateral geniculate nucleus (dLGN), a single class of interneuron is present. dLGN interneurons inhibit thalamocortical (TC) neurons and regulate the activity of TC neurons evoked by retinal ganglion cells (RGCs), thereby controlling the visually evoked signals reaching the cortex. It is not known whether neuromodulation can regulate interneuron firing mode and the resulting inhibition. Here, we examine this in brain slices. We find that cholinergic modulation regulates the output mode of these interneurons and controls the resulting inhibition in a manner that is dependent on the level of afferent activity. When few RGCs are activated, acetylcholine suppresses synaptically evoked interneuron spiking, and strongly reduces disynaptic inhibition. In contrast, when many RGCs are coincidently activated, single stimuli promote the generation of a calcium spike, and stimulation with a brief train evokes prolonged plateau potentials lasting for many seconds that in turn lead to sustained inhibition. These findings indicate that cholinergic modulation regulates feedforward inhibition in a context-dependent manner.

Gq/11-induced and spontaneous waves of coordinated network activation in developing frontal cortex.

Repeated episodes of spontaneous large-scale neuronal bursting and calcium influx in the developing brain can potentially affect such fundamental processes as circuit formation and gene expression. Between postnatal day 3 (P3) and P7, the immature cortex can express one such form of activation whereby a wave of neuronal activity propagates through cortical networks, generating massive calcium influx. We previously showed that this activity could be triggered by brief stimulation of muscarinic receptors. Here, we show, by monitoring large cortical areas at low magnification, that although all areas respond to muscarinic agonists to some extent, only some areas are likely to generate the coordinated wave-like activation. The waves can be triggered repeatedly in frontal areas where, as we also show, waves occur spontaneously at a low frequency. In parietal and occipital areas, no such waves are seen. This selectivity may be related in part to differences in the cortical distribution of dopaminergic signaling, because we find that activation of dopamine receptors enables the response. Because M1 muscarinic receptors are typically coupled with G-alpha(q)/11, we investigated whether other receptors known to couple with this G-protein (group I glutamate metabotropic receptors, neurotensin type 1) could similarly elicit wave-like activation in responsive cortical areas. Our results suggest that multiple neurotransmitter systems can enable this form of activation in the frontal cortex. The findings suggest that a poorly recognized, developmentally regulated form of strong network activation found predominantly in the frontal cortex could potentially exert a profound influence on brain development.

Physiological properties of hypothalamic MCH neurons identified with selective expression of reporter gene after recombinant virus infection.

Neurons that synthesize melanin-concentrating hormone (MCH) may modulate arousal and energy homeostasis. The scattered MCH neurons have been difficult to study, as they have no defining morphological characteristics. We have developed a viral approach with AAV for selective long-term reporter gene (GFP) expression in MCH neurons, allowing the study of their cellular physiology in hypothalamic slices. MCH neurons showed distinct membrane properties compared to other neurons infected with the same virus with a cytomegalovirus promoter. Transmitters of extrahypothalamic arousal systems, including norepinephrine, serotonin, and the acetylcholine agonist muscarine, evoked direct inhibitory actions. Orexigenic neuropeptide Y was inhibitory by pre- and postsynaptic mechanisms; an anorexigenic melanocortin agonist had no effect. In contrast, the hypothalamic arousal peptide hypocretin/orexin evoked a direct inward current and increased excitatory synaptic activity and spike frequency in the normally silent MCH neurons. Together, these data support the view that MCH neurons may integrate information within the arousal system in favor of energy conservation.

Cholinergic modulation of purinergic and GABAergic co-transmission at in vitro hypothalamic synapses.

The lateral hypothalamus (LH) is an important center for the integration of autonomic and limbic information and is implicated in the modulation of visceral motor and sensory pathways, including those underlying feeding and arousal behaviors. LH neurons in vitro release both ATP and GABA. The control of ATP and GABA co-transmission in LH may underlie the participation of LH in basic aspects of arousal and reinforcement. LH neurons receive cholinergic input from the pedunculopontine and laterodorsal tegmental nuclei as well as from cholinergic interneurons within the LH per se. This study presents evidence for nicotinic acetylcholine receptor (nAChR)-mediated enhancement of GABAergic, but not of purinergic, transmission despite the co-transmission of ATP and GABA at LH synapses in vitro. Facilitation of GABAergic transmission by nicotine is inhibited by antagonists of (alphabeta)*-containing nAChRs, but is unaffected by an alpha7-selective antagonist, consistent with a nAChR-mediated enhancement of GABA release mediated by non-alpha7-containing nAChRs. Activation of muscarinic ACh receptors enhances the release of ATP while concomitantly depressing GABAergic transmission. The independent modulation of ATP/GABAergic transmission may provide a new level of synaptic flexibility in which individual neurons utilize more than one neurotransmitter but retain independent control over their synaptic activity.

Slow synchronized bursts of inhibitory postsynaptic currents (0.1-0.3 Hz) by cholinergic stimulation in the rat frontal cortex in vitro.

Cholinergic inputs from the basal forebrain to cortex exert profound effects on cortical activities, such as a rhythmic synchronization. For these modulatory effects inhibitory interneurons could play crucial roles within the cortical circuitry. To study cholinergic modulation of GABA-mediated inhibition, we recorded inhibitory postsynaptic current (IPSC) during application of cholinergic agonists in the rat frontal cortex in vitro. Both carbachol and muscarine caused two temporally different patterns of IPSC modulation in both pyramidal cells and inhibitory interneurons: tonic or periodic increase of GABA-A receptor-mediated inhibition. The tonic pattern showed a continuous increase of IPSC frequency, while the periodic increase manifested itself as rhythmic (0.1-0.3 Hz, mean 0.2 Hz) bursts of IPSC (frequency: 6-69 Hz, mean 24 Hz; burst duration: 1.2-4.3 s, mean 2.2 s). Both types of increase were suppressed by atropine or pirenzepine, muscarinic-receptor antagonists. The periodical IPSC bursts were not affected by antagonists for ionotropic glutamate receptors. Following cholinergic stimulation, periodic IPSC bursts in nearby cells were synchronized as a whole, but individual inhibitory events within the bursts were not always temporally correlated, suggesting synchronized depolarizations of several presynaptic interneurons. It has been revealed that slow rhythmic depolarizations accompanying spike firing can be generated within the cortex. In addition to this periodic excitation of cortical circuits, these results indicate that cortical inhibitory interneurons have their own acetylcholine-dependent mechanism generating the slow rhythm independent of the excitatory circuits.

Coordinated transitions in neurotransmitter systems for the initiation and propagation of spontaneous retinal waves.

Spontaneous waves of excitation in the developing mammalian retina are mediated, to a large extent, by neurotransmission. However, it is unclear how the underlying neurotransmitter systems interact with each other to play specific roles in the formation of retinal waves at various developmental stages. In particular, it is puzzling why the waves maintain a similar propagation pattern even after underlying neurotransmitter systems have undergone drastic developmental changes. Using Ca(2+) imaging and patch clamp in a whole-mount preparation of the developing rabbit retina, we discovered two dramatic and coordinated transitions in the excitatory drive for retinal waves: one from a nicotinic to a muscarinic system, and the other from a fast cholinergic to a fast glutamatergic input. Retinal waves before the age of postnatal day 1 (P1) were blocked by nicotinic antagonists, but not by muscarinic or glutamatergic antagonists. After P3, however, the spontaneous wave, whose basic spatiotemporal pattern remained similar, was completely inhibited by muscarinic or glutamate antagonists, but not by nicotinic antagonists. We also found that the muscarinic drive, mediated primarily by M1 and M3 receptors, was particularly important for wave propagation, whereas the glutamatergic drive seemed more important for local excitation. Our results suggest (1) a novel mechanism by which a neurotransmitter system changes its functional role via a switch between two completely different classes of receptors for the same transmitter, (2) the cholinergic system plays a critical role in not only early but also late spontaneous waves, and (3) the continued participation of the cholinergic system may provide a network basis for the consistency in the overall propagation pattern of spontaneous retinal waves.

Heterologous expression of a green fluorescent protein-pertussis toxin S1 subunit fusion construct disrupts calcium channel modulation in rat superior cervical ganglion neurons.

The fusion construct pEGFP-PTXS1 was assembled by ligating cDNA encoding the S1 subunit of Bordetella pertussis toxin (PTX) into the plasmid pEGFP-C1 (which codes for enhanced green fluorescent protein). Microinjection of pEGFP-PTXS1 (1-100 ng/microl) into the nucleus of dissociated rat sympathetic ganglion neurons resulted in functional expression as determined from the diffuse green fluorescence and disruption of norepinephrine-mediated N-type Ca2+ channel modulation. The heterologously expressed toxin retained specificity for G alpha(i/o)-dependent pathways as VIP-mediated modulation of N-type Ca2+ channels and muscarine-mediated inhibition of M-type K+ channels persisted in pEGFP-PTXS1 expressing neurons. These data demonstrate that the S1 subunit of PTX is readily expressed in mammalian neurons and remains functional following fusion to the C-terminus of another protein.

Effects of ginseng saponins on responses induced by various receptor stimuli.

We investigated the effects of four ginseng saponins, ginsenoside-Rb1, -Rg2, -Rg3 and -Ro, on the responses induced by receptor stimulation of various stimuli. Ginsenoside-Rg2 (1-100 microM) reduced the secretions of catecholamines from bovine adrenal chromaffin cells stimulated by acetylcholine and gamma-aminobutyric acid but not by angiotensin II, bradykinin, histamine and neurotensin. In guinea-pig, the ginsenoside also diminished the nicotine-induced secretion of catecholamines from the adrenal chromaffin cells, but it did not affect the muscarine- and the histamine-induced ileum contractions. On the other hand, ginsenoside-Rg3 (1-100 microM) reduced not only the acetylcholine-, the gamma-aminobutyric acid- and the neurotensin-induced secretions but also, at a higher concentration (100 microM), the angiotensin II-, the bradykinin- and the histamine-induced secretions from the bovine chromaffin cells. Furthermore, the saponin (3-100 microM) significantly inhibited the muscarine- and the histamine-induced ileum contractions of the guinea-pig. Ginsenoside-Rb1 and -Ro had no marked effect on their responses. These results strongly suggest that ginsenoside-Rg2 is a potent selective blocker of nicotinic acetylcholine and gamma-aminobutyric acid receptors (ionotropic receptors) and ginsenoside-Rg3 is not only a blocker of ionotropic receptors but also an antagonist of muscarinic or histamine receptors.

G protein specificity of the muscarine-induced increase in an inward rectifier potassium current in AtT-20 cells.

Muscarine and somatostatin enhance an inward rectifier K+ conductance in the AtT-20 pituitary cell line. Both effects are abolished by pertussis toxin (PTX). To determine which PTX-sensitive G protein mediates these agonist effects, we made cDNAs encoding mutant PTX-insensitive Gi alpha subtypes, in which the cysteine residue fourth from the C terminus was replaced with serine. The mutated cDNA was transfected into AtT-20 cells, resulting in stable cell lines overexpressing a Gi alpha subtype. As controls, wild-type Gi alpha cDNA was transfected into AtT-20 cells. The agonist-induced increase of the inward rectifier K+ conductance in the transfectants was examined with the whole-cell clamp method. Only in the cell lines into which the mutated (PTX-insensitive) Gi2 alpha cDNA was transfected, did the muscarine response become PTX-insensitive, suggesting that Gi2 couples to the muscarinic receptor and enhances the activity of the inward rectifier K+ channel. However, PTX-insensitive somatostatin responses were not obtained in any of the cell lines transfected with a mutated Gi alpha cDNA, suggesting either that none of the Gi subtypes is a transducer for the somatostatin effect or that the mutation prevents the coupling of the Gi alpha to the somatostatin receptor.

Muscarine induces an anomalous inhibition of synaptic transmission in rat auditory thalamic neurons in vitro.

Muscarinic receptor-mediated inhibition of central synaptic transmission was studied in a monosynaptic pathway connecting the inferior colliculus and the auditory thalamus in in vitro rat brain explants. Extra- and intracellular synaptic responses were recorded by sharp electrode and whole-cell patch clamp techniques in the ventral nucleus of the medial geniculate body after electrical stimulation of the brachium of the inferior colliculus. Stimulation of tectal afferents evoked either a high-frequency burst or a single-spike synaptic response in ventral geniculate neurons. Bath application of muscarinic receptor agonists abolished responses consisting of a high-frequency burst, but not responses consisting of a single spike. In the majority of single-spike cells muscarinic agonists often induced a synaptic facilitation. The burst blocking effect was mimicked by a moderate elevation of extracellular potassium. Intracellular recordings showed that the burst synaptic responses similar to that recorded extracellularly were induced by an excitatory postsynaptic potential. This synaptic potential, by first activating a low-threshold spike, was able to evoke a burst of sodium spike discharges. Muscarinic agonists caused a slow membrane depolarization that inactivated the low-threshold spike, leading to a blockade of the burst response. This mechanism is tentatively termed here as EPSP-LTS decoupling. Our results therefore support the hypothesis that part of the muscarinic receptor-mediated synaptic inhibition previously reported in anesthetized animal preparations in vivo represents a membrane depolarization rather than pre- or postsynaptic inhibition.

Isolation of cholinergic active ingredients in aqueous extracts of Mareya micrantha using the longitudinal muscle of isolated guinea-pig ileum as a pharmacological activity marker.

In our attempt to isolate the pharmacologically active ingredients in the aqueous extracts of Mareya micrantha, we have selected the contractions of the longitudinal muscle of the isolated guinea-pig ileum preparation as a pharmacological marker to monitor retention of pharmacological activity during the chromatographic separation. The aqueous extracts of Mareya micrantha elicited concentration-dependent contractions of the preparation. The maximum response elicited by the aqueous extracts was 50% of the maximum response elicited by the maximum dose of acetylcholine (ACh), 10(-7) M. Mepenzolate (10(-8)-10(-5) M), a specific muscarinic receptor antagonist, similarly antagonized contractions elicited by the aqueous extracts suggesting that the cholinergic ingredient(s) in the extract are acting at the muscarinic receptors of the preparation. Fraction 2-4, which was separated from the aqueous extracts by Sephadex gel chromatography, dose-dependently elicited contractions of the preparation. The maximum response was 80% of the maximum response elicited by the maximum dose of ACh suggesting that separation has enhanced the cholinergic activity of the content in the extract.

Acetylcholine causes rapid nicotinic excitation in the medial habenular nucleus of guinea pig, in vitro.

The actions of ACh in the medial habenular nucleus (MHb) were investigated using extra- and intracellular recording techniques in guinea pig thalamic slice maintained in vitro. Applications of ACh to MHb neurons resulted in rapid excitation followed by inhibition. Neither of these responses was abolished by blockade of synaptic transmission, indicating that they are consequences of ACh action directly on MHb cells. Local applications of the nicotinic agonists nicotine and cytisine caused long-lasting excitation, while applications of another nicotinic agonist, 1,1-dimethyl-4-phenylpiperazinium caused both the excitatory and inhibitory responses. Applications of the muscarinic agonists DL-muscarine and acetyl-beta-methylcholine did not consistently cause either the excitatory or inhibitory response. Adding the nicotinic antagonist hexamethonium to the bathing medium blocked both the excitatory and inhibitory ACh responses, while addition of the muscarinic antagonists atropine or scopolamine had no effect. These results indicate that the effects of ACh on MHb neurons are mediated by nicotinic receptors. Intracellular recordings revealed that ACh or nicotine cause an increase in membrane conductance associated with depolarizations that had an average reversal potential of -16 to -11 mV. These results indicate that the ACh-induced excitation is due to an increase in membrane cation conductance. The inhibitory response that follows ACh-induced depolarization and repetitive firing was associated with a hyperpolarization and an increase in membrane conductance. Similar postexcitatory inhibition could also be elicited by direct depolarization or by applications of glutamate, indicating that the hyperpolarizing response to ACh may be an endogenous postexcitatory potential that is not directly coupled to activation of nicotinic receptors. These results suggest that cholinergic transmission in the MHb may be largely of the nicotinic type. This nucleus may be of one of the major regions of the nervous system through which nicotine mediates its central effects.

A comparison of the muscarinic antagonist actions of pancuronium and alcuronium.

1 In the pithed rat, muscarine (2.5-10 microgram/kg i.v.) normally produced bradycardias, but tachycardias were seen in the presence of pancuronium (0.1-1.0 mg/kg i.v.) and alcuronium (0.1-5.0 mg/kg i.v.). 2 The tachycardia was probably a result of muscarinic receptor stimulation, because it was antagonized by atropine (10 microgram/kg i.v.) and pirenzepine (10-30 microgram/kg i.v.). The location of these muscarinic receptors is probably within the sympathetic ganglia since the tachycardias were inhibited by pretreatment with propranolol (1 mg/kg i.v.) or reserpine (5 mg/kg i.p. 24 h prior to study). 3 In the rat isolated atria preparation, pancuronium was 86 times more potent as an antagonist of the effects of muscarine than in the rat isolated superior cervical ganglion. The mechanism of action in both tissues may be non-competitive. 4 Pancuronium selectivity antagonized atrial inhibitory muscarinic responses compared to excitatory muscarinic responses in sympathetic ganglia in the rat.