Contribution of chloride conductance increase to slow EPSC and tachykinin current in guinea‐pig myenteric neurones.

Bertrand, Paul; Galligan, James J.

doi:10.1113/jphysiol.1994.sp020418

Cited by 53 publications

(41 citation statements)

References 32 publications

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“…SP activates voltage-dependent Ca 2ϩ channels, voltage-dependent K ϩ conductances, Cl Ϫ currents, Ih currents, voltage-dependent Na ϩ channels, and nonselective cationic channels (Adams et al, 1983;Stanfield et al, 1985;Bley and Tsien, 1990;Shen and North, 1992;Bertrand and Galligan, 1994;Aosaki and Kawaguchi, 1996). In most neurons, SP depolarizes membrane potential by decreasing resting K ϩ conductances (Akasu et al, 1996;Lepre et al, 1996;Ptak et al, 2000;Yasuda et al, 2001).…”

Section: Discussionmentioning

confidence: 99%

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Peña¹,

Ramirez²

2004

J. Neurosci.

145

144

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Neuromodulators are integral parts of a neuronal network, and unraveling how these substances alter neuronal activity is critical for understanding how networks generate patterned activity and, ultimately, behavior. In this study, we examined the cellular mechanisms underlying the excitatory action of substance P (SP) on the respiratory network isolated in spontaneously active transverse slice preparation of mice. SP produced a slow depolarization in all recorded inspiratory pacemaker and non-pacemaker neurons. Ion exchange experiments and blockers for different ion channels suggest that the slow depolarization is caused by the activation of a low-threshold TTX-insensitive cationic current that carries mostly Na ϩ . The SP-induced slow depolarization increased tonic discharge in nonpacemaker neurons and primarily enhanced the frequency of bursting in Cd 2ϩ -insensitive pacemaker neurons. In the Cd 2ϩ -sensitive pacemaker neuron, the burst frequency was not significantly affected, whereas burst duration and amplitude were more enhanced than in Cd 2ϩ -insensitive pacemaker neurons. In a subset of non-pacemaker neurons that produced NMDA-dependent subthreshold oscillations, SP caused the production of bursts of action potentials. We conclude that the degree of pacemaker activity in the respiratory network is not fixed but dynamically regulated by neuromodulators such as SP. This finding may have clinical implications for Rett syndrome in which SP levels along with other neuromodulators are decreased in the brainstem.

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Section: Discussionmentioning

confidence: 99%

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Peña¹,

Ramirez²

2004

J. Neurosci.

145

144

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“…An involvement of Cl Ϫ conductance is also unlikely (Bertrand and Galligan, 1994), because the equilibrium potential for the Cl Ϫ ions would be less than Ϫ52 mV, which is close to the resting membrane potential of the neurons, assuming that the ion concentrations of the cells become almost equal to that of the patch-pipette solution. Although our experiments by no means excluded the possible blocking actions of SP on channels such as K ϩ and Ca 2ϩ at the suprathreshold levels, our findings strongly imply that the SP-induced TTXinsensitive cation current accounts for virtually all of the inward current at rest in the large aspiny interneurons.…”

Section: Discussionmentioning

confidence: 99%

“…Electrophysiological studies on neurons in the other brain areas have shown that SP modulates several ionic conductances, and that the ionic mechanisms of SP actions differ considerably among neuronal types (Adams et al, 1983;Stanfield et al, 1985;Bley and Tsien, 1990;Shen and North, 1992;Bertrand and Galligan, 1994).…”

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confidence: 99%

Actions of Substance P on Rat Neostriatal NeuronsIn Vitro

Aosaki

Kawaguchi

1996

J. Neurosci.

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Actions of substance P (SP) on the neostriatal neurons in in vitro rat slice preparations were studied via whole-cell patch-clamp recording. Almost all large aspiny neurons (cholinergic cells) and half of the low-threshold spike (LTS) cells (somatostatin/ NOS-positive cells) showed depolarization or an inward shift of the holding currents in response to bath-applied SP in a dosedependent manner. In contrast, no responses were observed in fast-spiking (FS) cells (parvalbumin-positive cells) and medium spiny cells. Spike discharges followed by slow EPSPs/EPSCs were evoked by intrastriatal electrical stimulation in the large aspiny neurons. Pretreatment with [D-Arg 1 ,D-Pro 2 ,DTrp 7,9 ,Leu 11 ]-SP, an antagonist of the SP receptor, reversibly suppressed the induction of the slow EPSPs/EPSCs and unmasked slow IPSCs. The SP-induced inward current, although almost unchanged even after the blockade of I h channels and voltage-dependent Na ϩ , Ca 2ϩ , and K ϩ channels, changed its amplitude according to the Na ϩ concentration used in both the large aspiny neurons and LTS cells. Thus, the cation current could account for virtually all of the inward current at resting levels in both neurons. These results suggest that the firing of afferent neurons such as striatonigral medium spiny neurons, one of the possible sources of SP, would increase the firing probability of the two types of interneurons of the neostriatum by SP-receptor-mediated opening of tetrodotoxin-insensitive cation channels.Key words: striatum; basal ganglia; cholinergic; somatostatin; interneurons; substance P; tachykinin; neuropeptide; cations; slice preparations; patch clampThe undecapeptide substance P (SP), one of the neuropeptides known as tachykinins, is thought to play an important role as a neurotransmitter/neuromodulator in the CNS (Otsuka and Yoshioka, 1993). Evidence suggests that SP-containing fiber terminals in the striatum originate from thalamocaudate neurons in the center median-parafascicular complex (Sugimoto et al., 1984). There are two distinct populations of SP-containing medium-sized neurons in the striatum: the striatonigral medium-sized spiny projection neurons (Hong et al., 1977; Brownstein et al., 1983;Gerfen and Young, 1988) and the medium-sized aspiny interneurons with indented nuclei (Bolam et al., 1983). The striatum has also been shown to contain three G-protein-coupled neurokinin receptor subtypes: NK1, NK2, and NK3, among which SP preferentially binds to the first. The NK1 receptor is not expressed, however, in the medium spiny neurons but, rather, in the somatostatinergic and large cholinergic interneurons of the striatum of the rat (Gerfen, 1991;Kaneko et al., 1993), as well as nonhuman primates and human (Aubry et al., 1994;Parent et al., 1995). Both cell types have been reported to have synapses on their somatodendritic trees at the SP-containing terminals (Bolam and Izzo, 1988). However, the cholinergic neurons are especially important because, although they represent only a small population in the striatum, their wi...

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“…Previous investigations have determined that NK 1 and NK 3 receptors mediate prolonged depolarizations in the myenteric plexus of the intestine and that tachykinins likely contribute to slow EPSPs in myenteric neurons (1,25,26). Because the result of the experiments in the presence of TTX indicated that a component of the PGE 2 -mediated depolarization may be indirect and due to release of neuroactive compounds from nearby nerve terminals, additional experiments were conducted to investigate a possible role of tachykinins in the generation of the indirect or presynaptic effects of PGE 2 observed in myenteric AH cells.…”

Section: Nk Receptor Antagonists Significantly Inhibit Pge 2 -Mediatementioning

confidence: 99%

Effects of PGE₂ in guinea pig colonic myenteric ganglia

Manning

Sharkey

Mawe

2002

American Journal of Physiology-Gastrointestinal and Liver Physi

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is a proinflammatory mediator that can influence many cell types. This study was conducted to determine whether PGE2 alters the electrical activity of distal colonic myenteric neurons, because colitis is typically associated with altered motility and changes in neural signaling may be involved. The electrical properties of intact myenteric neurons were evaluated with intracellular microelectrodes. Acute application of PGE 2 elicited a prolonged depolarization in both AH and S neurons with little effect on input resistance or electrical excitability. PGE 2 effects were suppressed by tetrodotoxin (TTX) or neurokinin (NK) receptor antagonists, indicating that PGE 2 acts directly and indirectly to depolarize colonic neurons. PGE 2-evoked depolarization was concentration dependent (ϳ3 M EC 50) and was attenuated by the E prostanoid (EP)1/2 receptor antagonist, AH-6809. When preparations were maintained for 48 h in the presence of the stable PGE 2 analog PGE2-ethanolamide (10 M), neurons exhibited a significant membrane depolarization and enhanced excitability. These results suggest that PGE 2 can play a role in altered motility in colitis by evoking changes in the electrical properties of myenteric neurons. motility; inflammation; colitis; innervation; enteric nervous system THE NERVOUS SYSTEM OF THE bowel, which is known as the enteric nervous system (ENS) regulates visceromotor, secretomotor, and vasomotor activities in the wall of the intestines. Given that much of the morbidity associated with inflammatory bowel disease is caused by disordered gastrointestinal motor function and that colonic smooth muscle function is regulated by the ENS, it is quite possible that alterations in the excitability of the enteric neurons contribute to intestinal dysmotility. A variety of immune-mediated inflammatory disorders exist, including Crohn's disease and ulcerative colitis, and dysmotility, hypersecretion, and enhanced perception of pain are common features (17,22,23,46). It is now clear that cutaneous and visceral inflammations lead to enhanced excitability of extrinsic primary afferent neurons and altered reflex activity (5,8,14,48). Changes may also occur in the afferent components of intrinsic enteric neural circuitry, and such changes could contribute to altered motor reflex activity in the inflamed bowel.In guinea pig bowel, it is possible to identify the functional role of a given neuron on the basis of consensus knowledge regarding the electrical, morphological, chemical coding, and axonal projection patterns of these cells. For example, a class of cells known as AH neurons, on the basis of electrical properties, functions as the afferent limb of the peristaltic reflex circuit (19) and is considered to have roles as intrinsic primary afferent neurons and interneurons (for review, see Ref. 30). These cells have a Dogiel type II morphology (multiple processes) and extend projections to other ganglia and to the lamina propria (7,34,40,42), where they could respond to stimuli originating at the mucosal surface. Therefor...

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Contribution of chloride conductance increase to slow EPSC and tachykinin current in guinea‐pig myenteric neurones.

Cited by 53 publications

References 32 publications

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Actions of Substance P on Rat Neostriatal NeuronsIn Vitro

Effects of PGE₂ in guinea pig colonic myenteric ganglia

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Contribution of chloride conductance increase to slow EPSC and tachykinin current in guinea‐pig myenteric neurones.

Cited by 53 publications

References 32 publications

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Substance P-Mediated Modulation of Pacemaker Properties in the Mammalian Respiratory Network

Actions of Substance P on Rat Neostriatal NeuronsIn Vitro

Effects of PGE2 in guinea pig colonic myenteric ganglia

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Effects of PGE₂ in guinea pig colonic myenteric ganglia