Comparison of the effects of phorbol dibutyrate and low-frequency stimulation of synaptic inputs on the excitability of myenteric AH neurons

Low-frequency stimulation of synaptic inputs to after-hyperpolarising (AH) neurons in the guinea-pig small intestine causes sustained increases in excitability that far outlast the stimulus period. This excitation has been called sustained, slow, post-synaptic excitation (SSPE). Intracellular microelectrodes were used to record the effects of the protein kinase C (PKC) stimulant, phorbol dibutyrate (PDBu), and compare these with changes seen during the SSPE, in AH neurons of the small intestine of the guinea-pig. PDBu (1 nM–1 µM) increased excitability, depolarised the membrane and increased input resistance concentration dependently, mimicking the effects of low-frequency stimulation of pre-synaptic inputs. These changes developed slowly after the start of infusion and were only slowly reversible after wash out. PDBu suppressed a late after-hyperpolarising potential (AHP) that depends on Ca²⁺ entry via voltage-gated Ca²⁺ channels during the action potential. The effects of PDBu (10 nM) on the late AHP were indistinguishable from those observed during the SSPE. PDBu, at a concentration that inhibited the AHP, had no effect on the action potential half-width or the slope of its first repolarisation phase (the early phase of repolarisation is slowed by the Ca²⁺ influx of the action potential). Thus PDBu inhibited K⁺ channel opening underlying the late AHP, but did not suppress Ca²⁺ entry during the action potential. The hyperpolarisation-activated cation current (I _h) in intrinsic primary afferent neurons (IPANs) was not affected by PDBu. We conclude that PDBu mimics the sustained excitation caused by low-frequency stimulation of synaptic inputs to IPANs by closing IK channels responsible for the AHP or restricting their opening by Ca²⁺ and by reducing the current carried by K⁺ channels that are active at rest. IK channels, the opening of which results in the AHP, have consensus sites for PKC and are likely targets for phosphorylation during the SSPE.     

Ryanodine-sensitive stores regulate the excitability of AH neurons in the myenteric plexus of guinea-pig ileum

Myenteric afterhyperpolarizing (AH) neurons are primary afferent neurons within the gastrointestinal tract. Stimulation of the intestinal mucosa evokes action potentials (AP) that are followed by a slow afterhyperpolarization (AHP(slow)) in the soma. The role of intracellular Ca(2+) ([Ca(2+)](i)) and ryanodine-sensitive Ca(2+) stores in modulating the electrical activity of myenteric AH neurons was investigated by recording membrane potential and bis-fura-2 fluorescence from 34 AH neurons. Mean resting [Ca(2+)](i) was approximately 200 nM. Depolarizing current pulses that elicited APs evoked AHP(slow) and an increase in [Ca(2+)](i), with similar time courses. The amplitudes and durations of AHP(slow) and the Ca(2+) transient were proportional to the number of evoked APs, with each AP increasing [Ca(2+)](i) by approximately 50 nM. Ryanodine (10 microM) significantly reduced both the amplitude and duration (by 60%) of the evoked Ca(2+) transient and AHP(slow) over the range of APs tested (1-15). Calcium-induced calcium release (CICR) was graded and proportional to the number of APs, with each AP triggering a rise in [Ca(2+)](i) of approximately 30 nM Ca(2+) via CICR. This indicates that CICR amplifies Ca(2+) influx. Similar changes in [Ca(2+)](i) and AHP(slow) were evoked by two APs in control and six APs in ryanodine. Thus, the magnitude of the change in bulk [Ca(2+)](i) and not the source of the Ca(2+) is the determinant of the magnitude of AHP(slow). Furthermore, lowering of free [Ca(2+)](i), either by reducing extracellular Ca(2+) or injecting high concentrations of Ca(2+) buffer, induced depolarization, increased excitability, and abolition of AHP(slow). In addition, activation of synaptic input to AH neurons elicited a slow excitatory postsynaptic potential (sEPSP) that was completely blocked in ryanodine. These results demonstrate the importance of [Ca(2+)](i) and CICR in sensory processing in AH neurons. Activity-dependent CICR may be a mechanism to grade the output of AH neurons according to the intensity of sensory input.     

Comparison of the effects of neurokinin-3 receptor blockade on two forms of slow synaptic transmission in myenteric AH neurons

AH neurons are intrinsic sensory neurons of the intestine that exhibit two types of slow synaptic event: slow excitatory postsynaptic potentials which increase their excitability for about 2-4 min, and sustained slow postsynaptic excitation which can persist for several hours, and may be involved in long-term changes in the sensitivity of the intestine to sensory stimuli. The effects of the neurokinin-3 tachykinin receptor antagonist, SR142801, on these two types of synaptic event in AH neurons of the myenteric ganglia of guinea-pig small intestine were compared. Slow excitatory postsynaptic potentials were evoked by stimulation of synaptic inputs at 10-20 Hz for 1s, and sustained slow postsynaptic excitation was evoked by stimulation of inputs at 1Hz for 4 min. SR142801 (1microM) reduced the amplitude of the slow excitatory postsynaptic potential to 26% of control, and also reduced the increase in input resistance and the extent of anode break excitation associated with the slow excitatory postsynaptic potential. In contrast, SR142801 did not reduce the increase in excitability, the increase in input resistance or the depolarisation that occur during the sustained slow postsynaptic excitation. SR142801 did not change the resting membrane potential or the resting input resistance.We conclude that tachykinins, acting through neurokinin-3 receptors, are involved in the generation of the slow excitatory postsynaptic potential, but not in the sustained slow postsynaptic excitation, and that the release of transmitters from synaptic inputs to AH neurons is frequency coded.     

Enhanced excitability of myenteric AH neurones in the inflamed guinea-pig distal colon

Proteinase-activated receptor 2 (PAR2) is a receptor for mast cell tryptase and trypsins and might participate in brain-gut communication. However, evidence that PAR2 activation can lead to afferent impulse generation is lacking. To address this issue, we examined the sensitivity of jejunal afferent nerves to a hexapeptide agonist of PAR2, SLIGRL-NH₂, and the modulation of the resulting response to treatment with drugs and vagotomy. Multiunit recordings of jejunal afferent activity were made using extracellular recording techniques in anaesthetised male rats. SLIGRL-NH₂ (0.001–1 mg kg⁻¹, I.V.) increased jejunal afferent firing and intrajejunal pressure. The reverse peptide sequence (1 mg kg⁻¹, I.V.), which does not stimulate PAR2, was inactive. Naproxen (10 mg kg⁻¹, I.V.), but not a cocktail of ω-conotoxins GVIA and SVIB (each at 25 μg kg⁻¹, I.V.), curtailed both the afferent response and the intrajejunal pressure rise elicited by the PAR2 agonist. Although neither treatment modulated the peak magnitude of the afferent firing, they each altered the intestinal motor response, unmasking an initial inhibitory component. Nifedipine (1 mg kg⁻¹, I.V.) reduced the peak magnitude of the afferent nerve discharge and abolished the initial rise in intrajejunal pressure produced by SLIGRL-NH₂. Vagotomy did not significantly influence the magnitude of the afferent response to the PAR2 agonist, which involves a contribution from capsaicin-sensitive fibres. In conclusion, intravenous administration of SLIGRL-NH₂ evokes complex activation of predominantly spinally projecting extrinsic intestinal afferent nerves, an effect that involves both direct and indirect mechanisms.     

Naloxone-induced depolarization and synaptic activation of myenteric neurons in morphine-dependent guinea pig ileum

To investigate the cellular basis of opiate dependence, intracellular microelectrodes were used to record from both electrophysiologically defined classes of neurons (S and AH) in myenteric plexus longitudinal muscle preparations from morphine pretreated guinea pigs. These preparations responded to naloxone with the characteristic contraction of the longitudinal smooth muscle, indicative of morphine dependence. Depolarization in response to naloxone was observed in 42% of S neurons, but there were no consistent changes in input resistance. In some cells the depolarization was reduced or abolished after blockade of synaptic transmission, suggesting that it was due in part to the release of an excitatory transmitter producing a slow depolarization in the impaled neuron. Synaptic activation of S neurons during withdrawal was further indicated by the observation that fast postsynaptic potentials appeared after abrupt displacement of morphine from its receptors by naloxone. Morphine withdrawal, therefore, involves both the final motor neurons and interneurons. During naloxone-induced withdrawal, 25% of S neurons discharged action potentials. In contrast, no action potentials were discharged in AH neurons. Furthermore, naloxone did not alter the resting membrane potential, input resistance, soma action potential configuration, or slow hyperpolarization following a soma spike in AH neurons. The specificity of the withdrawal response for S neurons and the relatively small proportion of neurons involved suggests that morphine withdrawal occurs in quite specific neuronal circuits in the myenteric plexus.     

Responses of myenteric S neurones to low frequency stimulation of their synaptic inputs

Previous experiments have shown that prolonged low frequency stimulation of presynaptic inputs causes excitation of AH neurones that considerably outlasts the period of stimulation in the guinea-pig small intestine. The present experiments compare the responses of S neurones (which are motor neurones and interneurones) with responses of AH neurones (intrinsic primary afferent neurones) to low frequency stimulation of synaptic inputs. Neurones in the myenteric plexus of isolated segments of guinea-pig small intestine were recorded from with intracellular microelectrodes. During their impalement, the neurones were filled with a marker dye and they were later processed to reveal their shapes and immunohistochemical properties. One group of neurones, inhibitory motor neurones to the circular muscle, was depolarised by stimulation of synaptic inputs at 1 Hz for 100 s to 4 min. With 4-min trains of stimuli, peak depolarisation was 21+/-2 mV (mean+/-S.E.M.), which was reached at about 110 s. Depolarisation was accompanied by increased excitability; before stimulation, a test intracellular pulse (500 ms) triggered 3 action potentials, at the peak of excitability this reached 16 action potentials. Depolarisation began to decline immediately at the end of stimulation. This contrasts with responses of AH neurones, in which depolarisation persisted after the end of the stimulus (peak depolarisation at 300 s). The excitation and depolarisation of inhibitory motor neurones was blocked by the neurokinin 1 tachykinin receptor antagonist, SR140333 (100 nM), but excitation of AH neurones was not affected. Small or no responses to 1 Hz stimulation were recorded from descending filamentous interneurones, longitudinal muscle motor neurones and excitatory circular muscle motor neurones. In conclusion, this study indicates that sustained slow postsynaptic excitation only occurs in AH neurones, and that one type of S neurones, inhibitory motor neurones to the circular muscle, responds substantially, but not beyond the period of stimulation, to activation of synaptic inputs at 1 Hz. This slow excitatory postsynaptic potential evoked by low frequency stimulation is mediated by tachykinins.     

Slow synaptic potentials in AH-type myenteric plexus neurons

Two types of slow depolarization were recorded in AH-type guinea pig myenteric plexus neurons when the myenteric plexus-longitudinal muscle preparation was stimulated transmurally with external electrodes. One depolarization was associated with a fall and the other with a rise in membrane resistance, the latter type (slow EPSP) being encountered about six times more commonly than the former. In some instances both types of potential were recorded in the same AH neuron. When this occurred the amplitude and duration of the slow EPSP was attenuated if it was timed to occur at about the same time as the other slow synaptic potential.     

Excitatory synaptic potentials due to activation of neurons with short projections in the myenteric plexus

Intracellular microelectrodes have been used to examine the effects, on excitatory inputs to myenteric nerve cells, of lesions of intrinsic pathways in the myenteric plexus of the guinea-pig small intestine. The lesions consisted of circumferential cuts (myotomies) which severed the external musculature to the depth of the submucosa and thus interrupted pathways in the myenteric plexus. Sufficient time was allowed between creating the lesions and recording from the neurons for the endings of severed neurites to degenerate and this was confirmed histochemically by examining the distribution of varicose fibres with 5-hydroxytryptamine immunoreactivity in myenteric ganglia from which recordings were made. Two types of excitatory input, eliciting fast and slow excitatory post-synaptic potentials, respectively, were demonstrable in response to focal stimulation of nerves in the ganglia from which recordings were made. There were no differences in the proportions of neurons in which fast or slow excitatory synaptic potentials were evoked in unoperated preparations (controls), in islands 1.5-4 mm wide between myotomies, or within 1 mm on the oral or anal sides of myotomies. Possible differences in the amplitudes, durations at half amplitude, and threshold numbers of stimuli for initiation of slow excitatory synaptic potentials were analyzed. The only significant differences were found when data from control and oral areas were pooled and compared with combined data from island and anal areas (this assessed differences that could arise from severing nerve fibres running from oral to anal).(ABSTRACT TRUNCATED AT 250 WORDS)     

Long-term enhancement of excitatory synaptic inputs to layer V parahippocampal neurons by low frequency stimulation in rat brain slices

Excitatory inputs to layer V neurons of the parasubiculum and medial entorhinal cortex were examined in rat brain slices with intracellular and field potential recordings. Single extracellular stimuli to layer V evoked subthreshold excitatory postsynaptic potentials (EPSPs) or a long duration (>100 ms) depolarization that sustained high frequency firing. Repetitive stimulation at low frequencies (from 1/10 s to 1/min) induced stable long-lasting decreases in the threshold for firing in individual cells or population events, and also induced stable long-lasting increases in evoked intracellular or field response amplitudes. More stimuli were required to produce the equivalent changes in threshold and amplitude in the presence of MCPG (200 microM). Smaller changes in amplitude, but equivalent changes in threshold were elicited in the presence of CPP (10 microM), or CPPG (20 microM). No changes in threshold or amplitude were detected in the presence of CNQX (10 microM), even when used in combination with picrotoxin (100 microM). EPSP facilitation was enhanced greatly by firing in postsynaptic cells. It is suggested that stable changes in excitatory inputs to layer V parahippocampal neurons involve the activation of NMDA and metabotropic glutamate receptors, but requires AMPA receptor activation and postsynaptic cell firing.     

Analysis of purinergic and cholinergic fast synaptic transmission to identified myenteric neurons

Types and projections of neurons that received cholinergic, purinergic and other fast excitatory synaptic inputs in myenteric ganglia of the guinea-pig distal colon were identified using combined electrophysiological recording, application of selective antagonists, marker dye filling via the recording microelectrode, and immunohistochemical characterisation. Fast synaptic inputs were recorded from all major subtypes of uniaxonal neurons including Dogiel type I neurons, filamentous interneurons, circular muscle motor neurons and longitudinal muscle motor neurons. Fast excitatory postsynaptic potentials were completely blocked by the nicotinic receptor antagonists hexamethonium or mecamylamine in 62% of neurons tested and were partially inhibited in the remaining neurons. The P2 purine receptor antagonist, pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid, reduced the amplitudes of fast excitatory postsynaptic potentials in 20% of myenteric neurons. The 5-hydroxytryptamine(3) receptor antagonist granisetron reduced the amplitude of fast excitatory postsynaptic potentials in only one of 15 neurons tested. In five of five neurons tested, the combination of a nicotinic antagonist, pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid, granisetron and 6-cyano-7-nitroquinoxaline-2,3-dione did not completely block the fast excitatory postsynaptic potentials. Immunohistochemical studies of the neurons that had been identified electrophysiologically and morphologically imply that P2X(2) receptors may mediate fast transmission in some neurons, and that other P2X receptor subtypes may also be involved in fast synaptic transmission to myenteric neurons of the guinea-pig distal colon. Neurons with nicotinic and pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid-sensitive fast excitatory postsynaptic potentials were present in both ascending and descending pathways in the distal colon. Thus, neither cholinergic nor mixed cholinergic/purinergic synaptic responses are confined to a particular class of neuron. The results indicate that acetylcholine and ATP are the major fast excitatory neurotransmitters in guinea-pig distal colon myenteric ganglia.     

Age-related effects of Ginkgo biloba extract on synaptic plasticity and excitability

EGb 761 is a standardized extract from the Ginkgo biloba leaf and is purported to improve age-related memory impairment. The acute and chronic effect of EGb 761 on synaptic transmission and plasticity in hippocampal slices from young adult (8-12 weeks) and aged (18-24 months) C57Bl/6 mice was tested because hippocampal plasticity is believed to be a key component of memory. Acutely applied EGb 761 significantly increased neuronal excitability in slices from aged mice by reducing the population spike threshold and increased the early phase of long-term potentiation, though there was no effect in slices from young adults. In chronically treated mice fed for 30 days with an EGb 761-supplemented diet, EGb 761 significantly increased the population spike threshold and long-term potentiation in slices from aged animals, but had no effect on slices from young adults. The rapid effects of EGb 761 on plasticity indicate a direct interaction with the glutamatergic system and raise interesting implications with respect to a mechanism explaining its effect on cognitive enhancement in human subjects experiencing dementia.     

Long-term potentiation of intrinsic excitability in LV visual cortical neurons

Neuronal excitability has a large impact on network behavior, and plasticity in intrinsic excitability could serve as an important information storage mechanism. Here we ask whether postsynaptic excitability of layer V pyramidal neurons from primary visual cortex can be rapidly regulated by activity. Whole cell current-clamp recordings were obtained from visual cortical slices, and intrinsic excitability was measured by recording the firing response to small depolarizing test pulses. Inducing neurons to fire at high-frequency (30-40 Hz) in bursts for 5 min in the presence of synaptic blockers increased the firing rate evoked by the test pulse. This long-term potentiation of intrinsic excitability (LTP-IE) lasted for as long as we held the recording (>60 min). LTP-IE was accompanied by a leftward shift in the entire frequency versus current (F-I) curve and a decrease in threshold current and voltage. Passive neuronal properties were unaffected by the induction protocol, indicating that LTP-IE occurred through modification in voltage-gated conductances. Reducing extracellular calcium during the induction protocol, or buffering intracellular calcium with bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid, prevented LTP-IE. Finally, blocking protein kinase A (PKA) activation prevented, whereas pharmacological activation of PKA both mimicked and occluded, LTP-IE. This suggests that LTP-IE occurs through postsynaptic calcium influx and subsequent activation of PKA. Activity-dependent plasticity in intrinsic excitability could greatly expand the computational power of individual neurons.     

Action potential afterdepolarization mediated by a Ca2+-activated cation conductance in myenteric AH neurons

We investigated the nature of afterdepolarizing potentials in AH neurons from the guinea-pig duodenum using whole-cell patch-clamp recordings in intact myenteric ganglia. Afterdepolarizing potentials were minimally activated following action-potential firing under normal conditions, but after application of charybdotoxin (40 nM) or tetraethyl ammonium (TEA; 10-20 mM) to the bathing solution, prominent afterdepolarizing potentials followed action potentials. The whole-cell current underlying afterdepolarizing potentials (I(ADP)) in the presence of TEA (10-20 mM) reversed at -38 mV and was not voltage-dependent. Reduction of NaCl in the bathing (Krebs) solution to 58 mM shifted the reversal potential of the I(ADP) to -58 mV, suggesting that the current underlying the afterdepolarizing potential was carried by a mixture of cations. The relative contributions of Na(+) and K(+) to this current were estimated to be about 1:5. Substitution of external Na(+) with N-methyl D-glucamine blocked the current while replacement of internal Cl(-) with gluconate did not block the I(ADP). The I(ADP) was also inhibited when CsCl-filled patch pipettes were used. The I(ADP) was blocked or substantially decreased in amplitude in the presence of N-type Ca(2+) channel antagonists, omega-conotoxin GVIA and omega-conotoxin MVIIC, respectively, and was eliminated by external Cd(2+), indicating that it was dependent on Ca(2+) entry. The I(ADP) was also inhibited by ryanodine (10-20 microM), indicating that Ca(2+)-induced Ca(2+) release was involved in its activation. Niflumic acid consistently inhibited the I(ADP) with an IC(50) of 63 microM. Using antibodies against the pore-forming subunits of L-, N- and P/Q-type voltage-gated Ca(2+) channels, we have demonstrated that myenteric AH neurons express N- and P/Q, but not L-type voltage-gated Ca(2+) channels. We conclude that the ADP in myenteric AH neurons, in the presence of an L-type Ca(2+)-channel blocker, is generated by the opening of Ca(2+)-activated non-selective cation channels following action potential-mediated Ca(2+) entry mainly through N-type Ca(2+) channels. Ca(2+) release from ryanodine-sensitive stores triggered by Ca(2+) entry contributes significantly to the activation of this current.     

Long-term effects of brain-derived neurotrophic factor on the frequency of inhibitory synaptic events in the rat superficial dorsal horn

Chronic constriction injury (CCI) of rat sciatic nerve produces a specific pattern of electrophysiological changes in the superficial dorsal horn that lead to central sensitization that is associated with neuropathic pain. These changes can be recapitulated in spinal cord organotypic cultures by long term (5–6 days) exposure to brain-derived neurotrophic factor (BDNF) (200 ng/ml). Certain lines of evidence suggest that both CCI and BDNF increase excitatory synaptic drive to putative excitatory neurons while reducing that to putative inhibitory interneurons. Because BDNF slows the rate of discharge of synaptically-driven action potentials in inhibitory neurons, it should also decrease the frequency of spontaneous inhibitory postsynaptic currents (sIPSCs) throughout the superficial dorsal horn. To test this possibility, we characterized superficial dorsal horn neurons in organotypic cultures according to five electrophysiological phenotypes that included tonic, delay and irregular firing neurons. Five to 6 days of treatment with 200 ng/ml BDNF decreased sIPSC frequency in tonic and irregular neurons as might be expected if BDNF selectively decreases excitatory synaptic drive to inhibitory interneurons. The frequency of sIPSCs in delay neurons was however increased. Further analysis of the action of BDNF on tetrodotoxin-resistant miniature inhibitory postsynaptic currents (mIPSC) showed that the frequency was increased in delay neurons, unchanged in tonic neurons and decreased in irregular neurons. BDNF may thus reduce action potential frequency in those inhibitory interneurons that project to tonic and irregular neurons but not in those that project to delay neurons.     

Excitatory and inhibitory effects of norepinephrine on myenteric neurons of the guinea-pig gastric corpus

The effects of norepinephrine on the electrical and synaptic behaviour of gastric myenteric neurons were investigated in vitro by using conventional intracellular recording methods. Application of norepinephrine (0.1–10 M) evoked an excitatory effect in 40% of all cells tested. Excitation consisted of a depolarization of the membrane potential associated with increased spike discharge. Phentolamine or prazosin reversibly abolished and (–)phenylephrine mimicked the excitatory norepinephrine response. Yohimbine and clonidine had no effect. Focal electrical stimulation of interganglionic fibre tracts evoked fast excitatory postsynaptic potentials (fEPSPs) in all neurons. Only a minority of these fEPSPs were blocked by norepinephrine. However, fEPSPs evoked by stimulating presumably extrinsic nerves were always totally blocked by norepinephrine. The inhibitory effect of norepinephrine on fEPSPs could be reversed by phentolamine and yohimbine and mimicked by clonidine. Prazosin and phenylephrine had no effect. Isoproterenol and propranolol modified neither the excitatory nor the inhibitory effects. The results indicate that the excitatory effects of norepinephrine on gastric myenteric neurons are mediated by postsynaptic ₁ receptors, whereas the inhibitory effects are mediated by presynaptic ₂ receptors, which are located presumably on vagal extrinsic nerves. There was no evidence for -receptor-mediated effects in gastric myenteric neurons     

Mechanism of action of galanin on myenteric neurons

1. Conventional intracellular recording methods were used to investigate the mechanism of action of galanin on electrical behavior of AH/type 2 myenteric neurons in the guinea pig small intestine. 2. The overall action of galanin was inhibitory and consisted of membrane hyperpolarization, decreased input resistance, and suppression of excitability. 3. The action of galanin was on the somatic membrane. There were no effects on spike initiation or propagation velocity in the processes. 4. The reversal potential for the hyperpolarizing action of galanin was near the estimated K+ equilibrium potential and was dependent on the concentration of K+ in the bathing medium. 5. Treatment with tetraethylammonium (TEA) broadened the action-potential and enhanced long-lasting hyperpolarizing after-potentials (AH). Application of galanin or depletion of Ca2+ in the bathing medium offset the effects of TEA on the spike and the AH. Galanin or reduced Ca2+ had the same effect when both TEA and tetrodotoxin (TTX) were present. 6. Simultaneous application of TEA and 4-aminopyridine (4-AP) evoked spontaneous spike discharge with broadened spikes and enhanced AH. This activity was suppressed by galanin. 7. Intrasomatic injection of Cs+ in the presence of TTX appeared to abolish all K+ conductances leaving pure Ca2+ spikes in response to depolarizing current pulse. Galanin abolished these Ca2+ spikes. 8. The results suggest two major mechanisms of action for galanin. One is to open K+ channels, decrease input resistance, and hyperpolarize the membrane toward EK+. The second is blockade of voltage gated Ca2+ channels and suppression of the AH by indirect prevention of opening of Ca2+-dependent K+ channels.     

Synaptic plasticity in myenteric neurons of the guinea-pig distal colon: presynaptic mechanisms of inflammation-induced synaptic facilitation

The purpose of this study was to investigate the pre- and postsynaptic mechanisms that contribute to synaptic facilitation in the myenteric plexus of the trinitrobenzene sulphonic acid-inflamed guinea-pig distal colon. Intracellular recordings of evoked fast excitatory postsynaptic potentials (fEPSPs) in myenteric S neurons were evaluated, and the density of synaptic terminals was morphometrically analysed by transmission electron microscopy. In inflamed tissue, fEPSPs were reduced to control levels by the protein kinase A (PKA) inhibitor, H89, but H89 did not affect the fEPSPs in control tissue. This PKA activation in inflamed tissue did not appear to involve 5-HT₄ receptors because the antagonist/inverse agonist, GR 125487, caused comparable decreases of fEPSPs in both tissues. Inhibition of BK channels with iberiotoxin did not alter the fEPSPs in inflamed tissue, but increased the fEPSPs in control tissue to the amplitude detected in inflamed tissue. During trains of stimuli, run-down of EPSPs was less extensive in inflamed tissue and there was a significant increase in the paired pulse ratio. Depolarizations in response to exogenous neurotransmitters were not altered in inflamed tissue. These inflammation-induced changes were not accompanied by alterations in the pharmacological profile of EPSPs, and no changes in synaptic density were detected by electron microscopy. Collectively, these data indicate that synaptic facilitation in the inflamed myenteric plexus involves a presynaptic increase in PKA activity, possibly involving an inhibition of BK channels, and an increase in the readily releasable pool of synaptic vesicles.     

Methamphetamine produces bidirectional, concentration-dependent effects on dopamine neuron excitability and dopamine-mediated synaptic currents

Amphetamine-like compounds are commonly used to enhance cognition and to treat attention deficit/hyperactivity disorder, but they also function as positive reinforcers and are self-administered at doses far exceeding clinical relevance. Many of these compounds (including methamphetamine) are substrates for dopamine reuptake transporters, elevating extracellular dopamine by inhibiting uptake and promoting reverse transport. This produces an increase in extracellular dopamine that inhibits dopamine neuron firing through autoreceptor activation and consequently blunts phasic dopamine neurotransmission, an important learning signal. However, these mechanisms do not explain the beneficial behavioral effects observed at clinically useful concentrations. In the present study, we have used patch-clamp electrophysiology in slices of mouse midbrain to show that, surprisingly, low concentrations of methamphetamine actually enhance dopamine neurotransmission and increase dopamine neuron firing through a dopamine transporter-mediated excitatory conductance. Both of these effects are reversed by higher concentrations of methamphetamine, which inhibit firing through dopamine D2 autoreceptor activation and decrease the peak amplitude of dopamine-mediated synaptic currents. These competing, concentration-dependent effects of methamphetamine suggest a mechanistic interplay by which lower concentrations of methamphetamine can overcome autoreceptor-mediated inhibition at the soma to increase phasic dopamine transmission.     

Neurofilament formation and synaptic activity are delayed in the myenteric neurons of the rat fetus with gastroschisis

Gastroschisis is a malformation characterized by prenatal evisceration of the midgut into the amniotic cavity. Because of the harmful effects of the amniotic fluid, the intestinal loops appear matted, thickened, and covered by a peel. At birth, the newborn presents altered intestinal motility. In a previous publication, we reported a delay in the myenteric ganglia organization and neuronal maturity in a rat model of gastroschisis. In the present study, the neurofilament formation and synaptic activity were immunohistochemically investigated in the myenteric neurons of this animal model. The expression of low, medium and high molecular weight neurofilament proteins and of a protein of the synaptic vesicles, the synaptophysin, were similar to those found at earlier embryonic ages. These findings demonstrate delayed cytoskeletal organization and reduced synaptic activity in the myenteric neurons in the rat model of gastroschisis.     

Serotonin effects on frequency tuning of inferior colliculus neurons

We investigated the modulatory effects of serotonin on the tuning of 114 neurons in the central nucleus of the inferior colliculus (ICc) of Mexican free-tailed bats and how serotonin-induced changes in tuning influenced responses to complex signals. We obtained a "response area" for each neuron, defined as the frequency range that evoked discharges and the spike counts evoked by those frequencies at a constant intensity. We then iontophoretically applied serotonin and compared response areas obtained before and during the application of serotonin. In 58 cells, we also assessed how serotonin-induced changes in response areas correlated with changes in the responses to brief frequency-modulated (FM) sweeps whose structure simulated natural echolocation calls. Serotonin profoundly changed tone-evoked spike counts in 60% of the neurons (68/114). In most neurons, serotonin exerted a gain control, facilitating or depressing the responses to all frequencies in their response areas. In many cells, serotonergic effects on tones were reflected in the responses to FM signals. The most interesting effects were in those cells in which serotonin selectively changed the responsiveness to only some frequencies in the neuron's response area and had little or no effect on other frequencies. This caused predictable changes in responses to the more complex FM sweeps whose spectral components passed through the neurons' response areas. Our results suggest that serotonin, whose release varies with behavioral state, functionally reconfigures the circuitry of the IC and may modulate the perception of acoustic signals under different behavioral states.