Presynaptic Effects Research Articles

Effect of short-term exposure to dichlorvos on synaptic plasticity of rat hippocampal slices: Involvement of acylpeptide hydrolase and α 7 nicotinic receptors

Dichlorvos is the active molecule of the pro-drug metrifonate used to revert the cognitive deficits associated with Alzheimer's disease. A few years ago it was reported that dichlorvos inhibits the enzyme acylpeptide hydrolase at lower doses than those necessary to inhibit acetylcholinesterase to the same extent. Therefore, the aim of our investigation was to test the hypothesis that dichlorvos can enhance synaptic efficacy through a mechanism that involves acylpeptide hydrolase instead of acetylcholinesterase inhibition. We used long-term potentiation induced in rat hippocampal slices as a model of synaptic plasticity. Our results indicate that short-term exposures (20 min) to 50 μM dichlorvos enhance long-term potentiation in about 200% compared to the control condition. This effect is correlated with approximately 60% inhibition of acylpeptide hydrolase activity, whereas acetylcholinesterase activity remains unaffected. Paired-pulse facilitation and inhibition experiments indicate that dichlorvos does not have any presynaptic effect in the CA3 → CA1 pathway nor affect gabaergic interneurons. Interestingly, the application of 100 nM methyllicaconitine, an α 7 nicotinic receptor antagonist, blocked the enhancing effect of dichlorvos on long-term potentiation. These results indicate that under the exposure conditions described above, dichlorvos enhances long-term potentiation through a postsynaptic mechanism that involves (a) the inhibition of the enzyme acylpeptide hydrolase and (b) the modulation of α 7 nicotinic receptors.

Noradrenergic Control of Associative Synaptic Plasticity by Selective Modulation of Instructive Signals

Synapses throughout the brain are modified through associative mechanisms in which one input provides an instructive signal for changes in the strength of a second coactivated input. In cerebellar Purkinje cells, climbing fiber synapses provide an instructive signal for plasticity at parallel fiber synapses. Here, we show that noradrenaline activates alpha2-adrenergic receptors to control short-term and long-term associative plasticity of parallel fiber synapses. This regulation of plasticity does not reflect a conventional direct modulation of the postsynaptic Purkinje cell or presynaptic parallel fibers. Instead, noradrenaline reduces associative plasticity by selectively decreasing the probability of release at the climbing fiber synapse, which in turn decreases climbing fiber-evoked dendritic calcium signals. These findings raise the possibility that targeted presynaptic modulation of instructive synapses could provide a general mechanism for dynamic context-dependent modulation of associative plasticity.

Inhibitory Potency of Choline Esterase Inhibitors on Acetylcholine Release and Choline Esterase Activity in Fresh Specimens of Human and Rat Neocortex

Fresh specimens of human and rat neocortex were used to determine direct and indirect inhibitory potencies of choline esterase inhibitors (ChEIs) on ChE and the release of acetylcholine (ACh), respectively. Km values of ChE in homogenates of rat and human neocortex did not differ significantly, whereas the specific activity of ChE was > times higher in the rat. Butyryl ChE exhibited a higher Km and a lower specific activity than ACh esterase in human neocortex. Inhibition of ChE in rat and human tissue was similar [IC50 (nM; human): donepezil: 14, physostigmine: 22, tacrine: 95, galanthamine: 575, rivastigmine: 9120]. In neocortex slices preincubated with [3H]choline, the electrically evoked release of [3H]ACh was inhibited up to 60% by ChEIs (IC50 (nM, rat): donepezil: 30, physostigmine: 39, tacrine: 302, galanthamine: 646, rivastigmine: >10000). Similar IC50-values were also estimated for ACh release in human neocortex, although the maximal inhibitory effects were much smaller ( approximately 20%). We conclude that in comparison to rats: 1) neocortical ChE concentrations are lower and 2) that ChEIs have weaker indirect (muscarine receptor-mediated) presynaptic inhibitory effects in the human brain. We further suggest that a combination of ChEIs with brain-selective muscarine autoreceptor antagonists might help to improve their clinical efficacy.

Differential effects of GABA B autoreceptor activation on ethanol potentiation of local and lateral paracapsular GABAergic synapses in the rat basolateral amygdala

Many studies have demonstrated that GABAergic inhibition within the basolateral amygdala (BLA) plays an integral role in the regulation of anxiety, an important behavioral component in the etiology of alcoholism. Although ethanol has recently been shown to enhance BLA GABAergic inhibition via two distinct populations of inhibitory cells, local and lateral paracapsular (lpcs) interneurons, little is known about the mechanisms underlying ethanol potentiation of these two inhibitory pathways. Ethanol is known to enhance GABAergic inhibition in many brain regions via a complex array of pre- and postsynaptic mechanisms. In addition, ethanol's presynaptic effects are often subject to GABA B autoreceptor (GABA B-R) modulation. Therefore, in this study, we characterized GABA B-R function and modulation of ethanol actions at local and lpcs GABAergic synapses. At local synapses, we found significant paired-pulse depression (PPD, 250 ms inter-pulse interval) which was abated by SCH-50911 (GABA B-R antagonist). No significant PPD was detected at lpcs synapses, but SCH-50911 significantly potentiated lpcs-evoked IPSCs. Baclofen (GABA B-R agonist) had similar depressant effects on local- and lpcs-evoked IPSCs, however baclofen pretreatment only reduced ethanol potentiation at local synapses. Ethanol also significantly enhanced the frequency of spontaneous and miniature IPSCs, and these effects were also sensitive to GABA B-R modulators. Collectively, these data suggest that stimulus-independent inhibitory responses recorded from BLA principal neurons primarily reflect the activity of local GABAergic interneurons and provide additional evidence that ethanol potentiates local BLA inhibitory synapses primarily via a presynaptic enhancement of GABA release that is tightly regulated by GABA B-Rs. In contrast, ethanol potentiation of lpcs GABAergic synapses is not sensitive to GABA B-R activation and does not appear to involve increased presynaptic GABA release.

Alterations in corticostriatal synaptic plasticity in mice overexpressing human α-synuclein

Most forms of Parkinson's disease (PD) are sporadic in nature, but some have genetic causes as first described for the α-synuclein gene. The α-synuclein protein also accumulates as insoluble aggregates in Lewy bodies in sporadic PD as well as in most inherited forms of PD. The focus of the present study is the modulation of synaptic plasticity in the corticostriatal pathway of transgenic (Tg) mice that overexpress the human α-synuclein protein throughout the brain (ASOTg). Paired-pulse facilitation was detected in vitro by activation of corticostriatal afferents in ASOTg mice, consistent with a presynaptic effect of elevated human α-synuclein. However basal synaptic transmission was unchanged in ASOTg, suggesting that human α-synuclein could impact paired-pulse facilitation via a presynaptic mechanism not directly related to the probability of neurotransmitter release. Mice lacking α-synuclein or those expressing normal and A53T human α-synuclein in tyrosine hydroxylase-containing neurons showed, instead, paired-pulse depression. High-frequency stimulation induced a presynaptic form of long-term depression solely in ASOTg striatum. A presynaptic, N-methyl- d-aspartate receptor-independent form of chemical long-term potentiation induced by forskolin (FSK) was enhanced in ASOTg striatum, while FSK-induced cAMP levels were reduced in ASOTg synaptoneurosome fractions. Overall the results suggest that elevated human α-synuclein alters presynaptic plasticity in the corticostriatal pathway, possibly reflecting a reduction in glutamate at corticostriatal synapses by modulation of adenylyl cyclase signaling pathways. ASOTg mice may recapitulate an early stage in PD during which overexpressed α-synuclein dampens corticostriatal synaptic transmission and reduces movement.

Signal Transduction Mechanisms Underlying Group I Mglur-Mediated Increase in Frequency and Amplitude of Spontaneous EPSCs in the Spinal Trigeminal Subnucleus Oralis of the Rat

Group I mGluRs (mGluR1 and 5) pre- and/or postsynaptically regulate synaptic transmission at glutamatergic synapses. By recording spontaneous EPSCs (sEPSCs) in the spinal trigeminal subnucleus oralis (Vo), we here investigated the regulation of glutamatergic transmission through the activation of group I mGluRs. Bath-applied DHPG (10 μM/5 min), activating the group I mGluRs, increased sEPSCs both in frequency and amplitude; particularly, the increased amplitude was long-lasting. The DHPG-induced increases of sEPSC frequency and amplitude were not NMDA receptor-dependent. The DHPG-induced increase in the frequency of sEPSCs, the presynaptic effect being further confirmed by the DHPG effect on paired-pulse ratio of trigeminal tract-evoked EPSCs, an index of presynaptic modulation, was significantly but partially reduced by blockades of voltage-dependent sodium channel, mGluR1 or mGluR5. Interestingly, PKC inhibition markedly enhanced the DHPG-induced increase of sEPSC frequency, which was mainly accomplished through mGluR1, indicating an inhibitory role of PKC. In contrast, the DHPG-induced increase of sEPSC amplitude was not affected by mGluR1 or mGluR5 antagonists although the long-lasting property of the increase was disappeared; however, the increase was completely inhibited by blocking both mGluR1 and mGluR5. Further study of signal transduction mechanisms revealed that PLC and CaMKII mediated the increases of sEPSC in both frequency and amplitude by DHPG, while IP3 receptor, NO and ERK only that of amplitude during DHPG application. Altogether, these results indicate that the activation of group I mGluRs and their signal transduction pathways differentially regulate glutamate release and synaptic responses in Vo, thereby contributing to the processing of somatosensory signals from orofacial region.

Pre- and postsynaptic effect of galanin on excitatory synaptic transmission in rat spinal dorsal horn neurons

Galanin, a 29 ⁄ 30 amino acid neuropeptide, and three types (GalR1-3) of receptors for this neuropeptide, which are expressed in rat dorsal root ganglion neurons and spinal dorsal horn neurons, play a pivotal role in regulating nociceptive transmission to the spinal dorsal horn from the periphery. Intrathecal administration of galanin in rats modulates nociceptive behavior in a biphasic manner such that galanin at low and high doses produces nociception and antinociception, respectively. In order to know cellular mechanisms for this effect, we investigated the effect of galanin on glutamatergic spontaneous excitatory synaptic transmission in substantia gelatinosa (SG) neurons of adult rat spinal cord slices by use of the whole cell patch-clamp technique. In 83% of the neurons examined (n=29), galanin (0.03 µM) superfused for 2 min increased the frequency of spontaneous excitatory postsynaptic current (sEPSC) recorded at -70 mV without a change in its amplitude and also in holding currents. The remaining neurons produced a small outward (n=4) or inward current (n=1). This presynaptic effect was dose-dependent with an EC50 value of 0.0029 µM, and was mimicked by a selective GalR2⁄R3 agonist galanin (2-11) but not a selective GalR1 agonist M617. Superfusing galanin at a higher dose such as 0.1 µM for 2 min produced an outward current in 39% of SG neurons tested (n=33). Twelve % of the SG neurons had an inward current and the remaining neurons did not change holding currents. The outward current produced by galanin had an EC50 value of 0.042 µM, and was mimicked by M617 but not galanin (2-11). The sEPSC frequency increase and outward current persisted in the presence of a Na+-channel blocker tetrodotoxin.It is concluded that galanin at lower doses enhances the spontaneous release of L-glutamate from nerve terminals by activating GalR2⁄R3 while galanin at higher doses produces a membrane hyperpolarization by activating GalR1 in the SG. This pre- and postsynaptic effects could contribute to at least a part of the behavioral effect of galanin.

Unitary, GABAergic volume transmission: presynaptic effects of single neurogliaform cells in the neocortex

Event Abstract Back to Event Unitary, GABAergic volume transmission: presynaptic effects of single neurogliaform cells in the neocortex Szabolcs Olah1*, Gergely Komlosi1, E. Toth1, Pal Barzo2 and Gabor Tamas1 1 Research Group for Cortical Microcircuits of the Hungarian Academy of Sciences, University of Szeged, Hungary 2 Department of Neurosurgery, University of Szeged, Hungary Neurogliaform cells have a unique position among cortical interneurons because they can elicit combined GABAA and GABAB receptor-mediated inhibition on postsynaptic cells. A distinctive feature of neurogliaform cells among cortical interneurons is the very dense axonal arborization in which presynaptic boutons on neighboring collaterals can be found a couple micrometers from one another. Presynaptically released GABA is estimated to reach receptors located up to 3 micrometers from the release site and thus we hypothesized that neurogliaform cells might fill the volume of their axonal field with effective concentrations of GABA. Ultrastructural analysis of combined GABAergic and electrical neurogliaform cell to interneuron connections confirmed the presence of gap junctions between the connected cells but could not detect chemical synaptic junctions suggesting that neurogliaform axons do not require a synaptic contact for eliciting postsynaptic potentials. In order to confirm these results on nonsynaptic communication, we tested the potential effect of neurogliaform cells on presynaptic terminals which do not receive synapses in the cortex. Simultaneous triple recordings were performed in cortical slices consisting of a synaptically coupled pair of neurons and an additional neurogliaform cell activated 120 ms before the tested synaptic connection. Preceding single spikes of a neurogliaform cell significantly suppressed the amplitude of excitatory or inhibitory synaptic potentials between the other two cells and were effective in changing the paired pulse ratio in the tested connection. These effects were absent if the axon of the neurogliaform cell did not overlap with the axon of the presynaptic cell in the tested connection or if axons of the presynaptic cell type could not be modulated by GABAB receptors. Changes of input resistance on the postsynaptic neuron of the tested connection could not be accounted for the modulatory effects of neurogliaform cells confirming that the effect was presynaptic. Heterosynaptic modulation by neurogliaform cells was effectively blocked by CGP35348 showing the involvement of GABAB receptors. In line with our hypothesis, heterosynaptic effects of neurogliaform cells could be enhanced by blocking the GABA transporter GAT-1 with NO711. In conclusion, neurogliaform cells are specialized to a unitary form of volume transmission. An action potential traveling along a single neurogliaform axon is sufficient to fill the volume of the axonal arborization with GABA concentrations effective not only at classical somatodendritic postsynaptic domains, but also on presynaptic terminals. This work was supported by the EURYI Award, the Wellcome Trust, National Institutes of Health Grant NS35915, Howard Hughes Medical Institute, National Office for Science and Technology (RET008/2004), Hungarian Research Fund (T049535), Hungarian Academy of Sciences and Boehringer Ingelheim Fonds. Conference: 12th Meeting of the Hungarian Neuroscience Society, Budapest, Hungary, 22 Jan - 24 Jan, 2009. Presentation Type: Poster Presentation Topic: Research on the cerebral cortex and related structures Citation: Olah S, Komlosi G, Toth E, Barzo P and Tamas G (2009). Unitary, GABAergic volume transmission: presynaptic effects of single neurogliaform cells in the neocortex. Front. Syst. Neurosci. Conference Abstract: 12th Meeting of the Hungarian Neuroscience Society. doi: 10.3389/conf.neuro.01.2009.04.215 Copyright: The abstracts in this collection have not been subject to any Frontiers peer review or checks, and are not endorsed by Frontiers. They are made available through the Frontiers publishing platform as a service to conference organizers and presenters. The copyright in the individual abstracts is owned by the author of each abstract or his/her employer unless otherwise stated. Each abstract, as well as the collection of abstracts, are published under a Creative Commons CC-BY 4.0 (attribution) licence (https://creativecommons.org/licenses/by/4.0/) and may thus be reproduced, translated, adapted and be the subject of derivative works provided the authors and Frontiers are attributed. For Frontiers’ terms and conditions please see https://www.frontiersin.org/legal/terms-and-conditions. Received: 09 Mar 2009; Published Online: 09 Mar 2009. * Correspondence: Szabolcs Olah, Research Group for Cortical Microcircuits of the Hungarian Academy of Sciences, University of Szeged, Szeged, Hungary, olah.szabolcs.neuro@gmail.com Login Required This action requires you to be registered with Frontiers and logged in. To register or login click here. Abstract Info Abstract The Authors in Frontiers Szabolcs Olah Gergely Komlosi E. Toth Pal Barzo Gabor Tamas Google Szabolcs Olah Gergely Komlosi E. Toth Pal Barzo Gabor Tamas Google Scholar Szabolcs Olah Gergely Komlosi E. Toth Pal Barzo Gabor Tamas PubMed Szabolcs Olah Gergely Komlosi E. Toth Pal Barzo Gabor Tamas Related Article in Frontiers Google Scholar PubMed Abstract Close Back to top Javascript is disabled. Please enable Javascript in your browser settings in order to see all the content on this page.

Short latency intracortical inhibition: one of the most popular tools in human motor neurophysiology

Short latency intracortical inhibition: one of the most popular tools in human motor neurophysiology

Caffeine drinking potentiates cannabinoid transmission in the striatum: Interaction with stress effects

Caffeine, the psychoactive ingredient of coffee and of many soft drinks, is frequently abused by humans especially during stressful live events. The endocannabinoid system is involved in the central effects of many psychoactive compounds and of stress. Whether caffeine alters the cannabinoid system and interferes with stress-induced synaptic alterations is however unknown. We have studied electrophysiologically the sensitivity of cannabinoid receptors modulating synaptic transmission in the striatum of mice exposed to caffeine in their drinking solution. Chronic caffeine assumption sensitized GABAergic synapses to the presynaptic effect of cannabinoid CB1 receptor stimulation by exo- and endocannabinoids. Caffeine was conversely unable to affect the sensitivity of cannabinoid receptors modulating glutamate transmission. The synaptic effects of caffeine were slowly reversible after its removal from the drinking solution. Furthermore, although exposure to caffeine for only 24 h did not produce measurable changes of the sensitivity of cannabinoid CB1 receptors, it was able to contrast the down-regulation of CB1 receptor-mediated responses after social defeat stress. Our data suggest that the cannabinoid system is implicated in the psychoactive properties of caffeine and in the ability of caffeine to reduce the pathological consequences of stress.

The Effect of Lidocaine on Cholinergic Neurotransmission in an Identified Reconstructed Synapse

The presynaptic effect of lidocaine on cholinergic synaptic transmission is unclear because of the difficulty in identifying presynaptic neurons and the complexity of the central nervous system in vivo. To clarify the effect of lidocaine on cholinergic synapse, we reconstructed a cultured soma-soma chemical synapse model consisting of two identified visceral dorsal 4 (VD4) and left pedal e-1 (LPeD1) neurons from the snail, Lymnaea stagnalis, in vitro, and used it to determine how lidocaine affects cholinergic synaptic transmission. The response to acetylcholine and excitatory postsynaptic potential (EPSP) amplitude was recorded in the reconstructed chemical synaptic transmission model composed of VD4 and LPeD1 neurons. The currents for acetylcholine measurements were made under voltage-clamp in the presynaptic VD4 and postsynaptic LPeD1 neurons. Lidocaine inhibited both EPSP and the response for acetylcholine of the postsynaptic neuron. EPSP amplitude was reduced in a voltage-dependent manner in the presynaptic neuron, and lidocaine induced a hyperpolarization shift of the voltage-dependent inactivation curves of EPSP amplitude. Lidocaine inhibits cholinergic synaptic transmission with a voltage-dependent inactivation of EPSP amplitude through the membrane potential depolarization of presynaptic neurons.

Dendritic NMDA Receptors Activate Axonal Calcium Channels

NMDA receptor (NMDAR) activation can alter synaptic strength by regulating transmitter release from a variety of neurons in the CNS. As NMDARs are permeable to Ca(2+) and monovalent cations, they could alter release directly by increasing presynaptic Ca(2+) or indirectly by axonal depolarization sufficient to activate voltage-sensitive Ca(2+) channels (VSCCs). Using two-photon microscopy to measure Ca(2+) excursions, we found that somatic depolarization or focal activation of dendritic NMDARs elicited small Ca(2+) transients in axon varicosities of cerebellar stellate cell interneurons. These axonal transients resulted from Ca(2+) entry through VSCCs that were opened by the electrotonic spread of the NMDAR-mediated depolarization elicited in the dendrites. In contrast, we were unable to detect direct activation of NMDARs on axons, indicating an exclusive somatodendritic expression of functional NMDARs. In cerebellar stellate cells, dendritic NMDAR activation masquerades as a presynaptic phenomenon and may influence Ca(2+) -dependent forms of presynaptic plasticity and release.

Refractoriness of sural nerve in humans

High-frequency stimulation of peripheral nerve bundles is frequently used in clinical tests and physiologic experiments to study presynaptic and postsynaptic effects. To understand the postsynaptic effects, it is important to ensure that each pulse in the train is equally effective in stimulating the presynaptic nerve bundle; however, the optimal interpulse interval (IPI) and the stimulus intensity at which each pulse is equally effective in stimulating the same number of axons are not known. The magnitude of the compound action potential produced by each pulse in a train was tested on the sural nerve of 4 healthy human subjects. The stimulus train (2-4 pulses) was applied to the sural nerve at the lateral malleolus, and neural responses were recorded from just below the knee. With 2-pulse trains, families of curves between IPIs (1-6 ms) and normalized amplitudes of the second response were plotted for different stimulus intensities. Visual inspection of the data showed that the curves fell into 2 groups: with stimulus intensities <2.5x perception threshold (Th), the test response appeared partially at longer IPIs, whereas with stimulus intensities > or = 3x Th, partial recovery of the test response was earlier. The interval for complete recovery was statistically the same for low- and high-intensity stimulation. With more than 2 pulses in a stimulus train (IPI = 5 ms), the amplitude of the compound action potential (CAP) was not affected significantly. These results are important in understanding both the presynaptic and postsynaptic responses when presynaptic axon bundles are stimulated at high frequencies.

Elevated synaptophysin I in the prefrontal cortex of human chronic alcoholics

Convergent lines of evidence suggest potentiation of glutamatergic synapses after chronic ethanol exposure, and indicate that the presynaptic effect hereof is on modulators of synaptic strength rather than on executors of glutamate release. To address this hypothesis in the context of ethanol dependence in humans, we used semiquantitative immunoblotting to compare the immunoreactivities of synaptophysin I, syntaxin 1A, synaptosome-associated protein 25, and vesicle-associated membrane protein in the prefrontal and motor cortices between chronic alcoholics and control subjects. We found a region-specific elevation in synaptophysin I immunoreactivity in the prefrontal cortex of alcoholics, but detected no significant differences between the groups in the immunoreactivities of the other three proteins. Our findings are consistent with an effect of repeated ethanol exposure on modulators of synaptic strength but not on executors of glutamate release, and suggest a role for synaptophysin I in the enduring neuroplasticity in the prefrontal cortical glutamate circuitry that is associated with ethanol dependence.

Inotropes and Vasopressors

Inotropic and vasopressor agents have increasingly become a therapeutic cornerstone for the management of several important cardiovascular syndromes. In broad terms, these substances have excitatory and inhibitory actions on the heart and vascular smooth muscle, as well as important metabolic, central nervous system, and presynaptic autonomic nervous system effects. They are generally administered with the assumption that short- to medium-term clinical recovery will be facilitated by enhancement of cardiac output (CO) or vascular tone that has been severely compromised by often life-threatening clinical conditions. The clinical efficacy of these agents has been investigated largely through examination of their impact on hemodynamic end points, and clinical practice has been driven in part by expert opinion, extrapolation from animal studies, and physician preference. Our aim is to review the mechanisms of action of common inotropes and vasopressors and to examine the contemporary evidence for their use in important cardiac conditions.

The Role of Vasoactive Intestinal Polypeptide and Pituitary Adenylate Cyclase-Activating Polypeptide in the Neural Pathways Controlling the Lower Urinary Tract

Vasoactive intestinal polypeptide (VIP) and pituitary adenylate cyclase-activating polypeptide (PACAP) are expressed in the neural pathways regulating the lower urinary tract. VIP-immunoreactivity (IR) is present in afferent and autonomic efferent neurons innervating the bladder and urethra, whereas PACAP-IR is present primarily in afferent neurons. Exogenously applied VIP relaxes bladder and urethral smooth muscle and excites parasympathetic neurons in bladder ganglia. PACAP relaxes bladder and urethral smooth muscle in some species (pig) but excites the smooth muscle in other species (mouse). Intrathecal administration of VIP in cats with an intact spinal cord suppresses reflex bladder activity, but intrathecal administration of VIP or PACAP in rats enhances bladder activity and suppresses urethral sphincter activity. PACAP has presynaptic facilitatory effects and direct excitatory effects on lumbosacral parasympathetic preganglionic neurons. Chronic spinal cord transection produces an expansion of VIP-IR (cats) and PACAP-IR (rats) in primary afferent axons in the lumbosacral spinal cord and unmasks spinal excitatory effects of VIP on bladder reflexes in cats. Intrathecal administration of PACAP6-38, a PAC1 receptor antagonist, reduces bladder hyperactivity in chronic spinal-cord-injured rats. These observations raise the possibility that VIP or PACAP have a role in the control of normal or abnormal voiding.

Sympathetic histamine exerts different pre‐ and post‐synaptic functions according to the frequencies of nerve stimulation in guinea pig vas deferens

Histamine (HA) was found to be present in the sympathetic nerve terminals of guinea pig hearts and vasa deferentia in our previous study; however, little is known about the functions of this neurogenic HA. In this study, we used guinea pig vasa deferentia to investigate the pre- and post-synaptic functions of HA evoked by different frequencies of sympathetic nerve stimulation. We found that sympathetic nerve stimulation could evoke HA release, which was independent to mast cell degranulator compound 48/80 and mast cell stabilizer cromolyn, but was highly sensitive to Na(+) channel blocker tetrodotoxin and chemical sympathectomy with 6-hydroxydopamine. The neurogenically released HA evoked by 12.5 Hz of nerve stimulation activated only pre-synaptic H(3) receptors and mediated pre-synaptic inhibitory effects, while under 25 or 50 Hz stimulation condition, HA simultaneously activated both pre-synaptic H(3) receptors and post-synaptic H(1) receptors. However, the direct contractile responses evoked by sympathetic HA via H(1) receptors were observed at 50 Hz. HA release and HA-mediated contractile responses upon sympathetic nerve stimulation were significantly inhibited by pre-treatment of histidine decarboxylase inhibitor alpha-fluoromethylhistidine. Furthermore, application of exogenous HA could mimic these pre- and post-synaptic effects. Our findings indicate that HA in sympathetic neurons acts as a neurotransmitter and its functions vary from pre-synaptic inhibition, to post-synaptic facilitation, to direct post-synaptic contractile responses according to sympathetic nerve stimulation frequencies.

Sustained Inhibition of Neurotransmitter Release from Nontransient Receptor Potential Vanilloid Type 1-Expressing Primary Afferents by μ-Opioid Receptor Activation-Enkephalin in the Spinal Cord

Removing transient receptor potential vanilloid type 1 (TRPV1)-expressing primary afferent neurons reduces presynaptic mu-opioid receptors but potentiates opioid analgesia. However, the sites and underlying cellular mechanisms for this paradoxical effect remain uncertain. In this study, we determined the presynaptic and postsynaptic effects of the mu-opioid receptor agonist [D-Ala(2),N-Me-Phe(4),Gly-ol(5)]-enkephalin (DAMGO) using whole-cell patch-clamp recordings of lamina II neurons in rat spinal cord slices. Treatment with the ultrapotent TRPV1 agonist resiniferotoxin (RTX) eliminated TRPV1-expressing dorsal root ganglion neurons and their central terminals in the spinal dorsal horn and significantly reduced the basal amplitude of glutamatergic excitatory postsynaptic currents (EPSCs) evoked from primary afferents. Although RTX treatment did not significantly alter the concentration-response effect of DAMGO on evoked monosynaptic and polysynaptic EPSCs, it causes a profound long-lasting inhibitory effect of DAMGO on evoked EPSCs. Subsequent naloxone treatment did not reverse the prolonged inhibitory effect of DAMGO on evoked EPSCs. Furthermore, brief application of DAMGO produced a sustained inhibition of miniature EPSCs in RTX-treated rats. However, the concentration response and the duration of the effects of DAMGO on G protein-coupled inwardly rectifying K+ currents in lamina II neurons were not significantly different between vehicle- and RTX-treated groups. These data suggest that stimulation of mu-opioid receptors on non-TRPV1 afferent terminals causes extended inhibition of neurotransmitter release to spinal dorsal horn neurons. The differential effect of mu-opioid receptor agonists on different phenotypes of primary afferents provides a cellular basis to explain why the analgesic action of opioids on mechanonociception is prolonged when TRPV1-expressing primary afferents are removed.

Pre- and Postsynaptic Serotoninergic Excitation of Globus Pallidus Neurons

The basal ganglia (BG) play a critical role in the pathogenesis and pathophysiology of Parkinson's disease (PD). Recent studies indicate that serotoninergic systems modulate BG activity and may be implicated in the pathophysiology and treatment of PD. The globus pallidus (GP), the rodent homologue of the primate GPe, is the main central nucleus of the basal ganglia, affecting the striatum, the subthalamic nucleus (STN), and BG output structures. We therefore studied the effect of serotonin (5-HT) and specific 5-HT agonists and antagonists on GP neurons from rat brain slices. Using intra- and extracellular recordings of GP neurons we found that serotonin increases the firing rate of GP neurons. Analyzing the effects of specific 5-HT agonists and antagonists on the firing rate of GP neurons showed that the increase in firing rate is due to the activation of 5-HT1B and 5-HT1A receptors. Intracellular recordings in both voltage- and current-clamp modes revealed that serotonin mediates its effect via pre- and postsynaptic mechanisms. The presynaptic effect is mediated by attenuation of gamma-aminobutyric acid release, probably through activation of 5-HT1B receptors. Postsynaptically, serotonin activates a hyperpolarization-activated cation channel, probably via 5-HT1A receptors. Furthermore, serotonin decreases the fast synaptic depression characteristic of the striatal afferent input. The decreased serotonin concentrations in the BG nuclei in PD may contribute to depressed GP activity and enhance the emergence of BG pathological synchronous oscillations. We therefore suggest that future therapeutics of PD should be directed toward restoration of normal serotonin levels in BG nuclei.

Somatostatin receptor subtype 4 couples to the M-current to regulate seizures.

The K(+) M-current (I(M), Kv7) is an important regulator of cortical excitability, and mutations in these channels cause a seizure disorder in humans. The neuropeptide somatostatin (SST), which has antiepileptic properties, augments I(M) in hippocampal CA1 pyramidal neurons. We used SST receptor knock-out mice and subtype-selective ligands to investigate the receptor subtype that couples to I(M) and mediates the antiepileptic effects of SST. Using pentylenetetrazole as a chemoconvulsant, SST(2), SST(3), and SST(4) receptor knock-out mice all had shorter latencies to different seizure stages and increased seizure severity when compared with wild-type mice. However, the most robust differences were observed in the SST(4) knock-outs. When seizures were induced by systemic injection of kainate, only SST(4) knock-outs showed an increase in seizure sensitivity. We next examined the action of SST and subtype-selective SST agonists on electrophysiological parameters in hippocampal slices of wild-type and receptor knock-out mice. SST(2) and SST(4) appear to mediate the majority of SST inhibition of epileptiform activity in CA1. SST lacked presynaptic effects in mouse CA1, in contrast to our previous findings in rat. SST increased I(M) in CA1 pyramidal neurons of wild-type and SST(2) knock-out mice, but not SST(4) knock-out mice. Using M-channel blockers, we found that SST(4) coupling to M-channels is critical to its inhibition of epileptiform activity. This is the first demonstration of an endogenous enhancer of I(M) that is important in controlling seizure activity. SST(4) receptors could therefore be an important novel target for developing new antiepileptic and antiepileptogenic drugs.