Presynaptic modulation of transmitter release by the early outward potassium current inAplysia

The mechanism involved in presynaptic modulation of transmitter release was studied in an identified synapse of Aplysia californica. Presynaptic hyperpolarization induces a decrease in he evoked postsynaptic potential amplitude. This is shown to be due to a reduction in the presynaptic spike amplitude during the hyperpolarization. The decreased presynaptic spike amplitude with hyperpolarization is explained s resulting from the superimposition of an early outward potassium current on the transient inward current. It is suggested that the presynaptic hyperpolarizing conditioning pulse decreases inactivation of the early outward current, which shunts the transient inward current. The superimposition of these two currents (transient inward current and the early outward current) induces a decrease in presynaptic spike amplitude, which in turn reduces the synaptic output from the terminal.     

Neurosteroid pregnenolone sulfate enhances glutamatergic synaptic transmission by facilitating presynaptic calcium currents at the calyx of Held of immature rats

Pregnenolone sulfate (PREGS) is an endogenous neurosteroid widely released from neurons in the brain, and is thought to play a memory-enhancing role. At excitatory synapses PREGS facilitates transmitter release, but the underlying mechanism is not known. We addressed this issue at the calyx of Held in rat brainstem slices, where direct whole-cell recordings from giant nerve terminals are feasible. PREGS potentiated nerve-evoked excitatory postsynaptic currents (EPSCs) without affecting the amplitude of miniature EPSCs, suggesting that its site of action is presynaptic. In whole-cell recordings from calyceal nerve terminals, PREGS facilitated Ca2+ currents, by accelerating their activation kinetics and shifting the half-activation voltage toward negative potentials. PREGS had no effect on presynaptic K+ currents, resting conductance or action potential waveforms. In simultaneous pre- and postsynaptic recordings, PREGS did not change the relationship between presynaptic Ca2+ influx and EPSCs, suggesting that exocytotic machinery downstream of Ca2+ influx is not involved in its effect. PREGS facilitated Ba2+ currents recorded from nerve terminals and also from HEK 293 cells expressed with recombinant N- or P/Q-type Ca2+ channels, suggesting that PREGS-induced facilitation of voltage-gated Ca2+ channels (VGCCs) is neither Ca2+ dependent nor VGCC-type specific. The PREGS-induced VGCC facilitation was blocked by the PREGS scavenger (2-hydroxypropyl)-beta-cyclodextrin applied from outside, but not from inside, of nerve terminals. We conclude that PREGS facilitates VGCCs in presynaptic terminals by acting from outside, thereby enhancing transmitter release. We propose that PREGS may directly modulate VGCCs acting on their extracellular domain.     

An arginine vasotocin-like neuropeptide is present in the nervous system of the marine mollusc Aplysia californica

Radioimmunoassays and high pressure liquid chromotography have been used to demonstrate the presence of an arginine-vasotocin-like peptide (AVT) in the anterior ganglia of Aplysia. Previously, AVT, using similar methods, was found to be present only in vertebrates. AVT when perfused over the abdominal ganglion (10⁻⁶–10⁻¹²M) was found to increase the bursting activity of R₁₅, to decrease the bursting activity of L₃–L₆ and to increase the CNS's suppressive influence over the gill withdrawal reflex evoked by siphon stimulation. The AVT present in the nervous system of Aplysia may mediate long-term suppression of gill reflex behaviors induced by factors such as satiation and, as well, regulate the activity of certain neurosecretory neurons.     

Paraoxon block of chloride conductance in cell R2 of Aplysia californica

In the presence of paraoxon, the amplitudes of chloride currents activated by acetylcholine (ACh) or gamma-aminobutyric acid (GABA) were reduced in cell R2 of Aplysia californica. IC₅₀ values were 12 and 9.7 μM for ACh and GABA responses, respectively. Paraoxon did not affect resting membrane potential, input resistance, or chloride reversal potential. Both the slopes and maxima of ACh and GABA concentration-response curves were reduced by paraoxon, suggesting that paraoxon antagonism of these responses is not competitive. The antagonism of ACh and GABA responses by paraoxon was not related to inhibition of acetylcholinesterase.     

On the role of calcium ions in the presynaptic alpha-receptor mediated inhibition of [H]noradrenaline release from rat brain cortex synaptosomes

Rat brain cortex synaptosomes, previously labeled by incubation with [³H]noradrenaline ([³H]NA) were continuously superfused with Krebs-Ringer media. Release of [³H]NA was induced by superfusion with medium containing either 15 mM K⁺, 20 μM veratrine or 1 μM of the calcium-ionophore A 23187 and was strongly dependent on the concentration of Ca²⁺ in the medium. Noradrenaline (1μM, in the presence of the uptake inhibitor desipramine) inhibited K⁺-induced [³H]NA release by activation of presynaptic alpha-receptors. When the Ca²⁺-concentration in the medium was reduced, or the Mg²⁺-concentration increased, [³H]NA release appeared to be more susceptible to alpha-receptor mediated inhibition.Noradrenaline (1 μM) inhibited [³H]NA release induced by 15 mM K⁺, in the presence of 0.075 Ca²⁺ and 10 mM Mg²⁺, by 86%. Veratrine-induced release was also inhibited by alpha-receptor activation. However, [³H]NA release induced by the calcium-ionophore was not affected by alpha-receptor agonists. These results strongly support the view that alpha-receptor activation results in a decrease of the availability of Ca²⁺ for stimulus-secretion coupling processes. Presumably this is effected by an inhibition of voltage-sensitive calcium channels in the neuronal membrane associated with neurotransmitter release.     

On the role of calcium ions in the presynaptic alpha-receptor mediated inhibition of [3H]noradrenaline release from rat brain cortex synaptosomes

Rat brain cortex synaptosomes, previously labeled by incubation with [3H]noradrenaline ([3H]NA) were continuously superfused with Krebs-Ringer media. Release of [3H]NA was induced by superfusion with medium containing either 15 mM K+, 20 microM veratrine or 1 microM of the calcium-ionophore A 23187 and was strongly dependent on the concentration of Ca2+ in the medium. Noradrenaline (1 microM, in the presence of the uptake inhibitor desipramine) inhibited K+-induced [3H]NA release by activation of presynaptic alpha-receptors. When the Ca2+-concentration in the medium was reduced, or the Mg2+-concentration increased, [3H]NA release appeared to be more susceptible to alpha-receptor mediated inhibition. Noradrenaline (1 microM) inhibited [3H]NA release induced by 15 mM K+, in the presence of 0.075 Ca2+ and 10 mM Mg2+, by 86%. Veratrine-induced release was also inhibited by alpha-receptor activation. However, [3H]NA release induced by the calcium-ionophore was not affected by alpha-receptor agonists. These results strongly support the view that alpha-receptor activation results in a decrease of the availability of Ca2+ for stimulus-secretion coupling processes. Presumably this is effected by an inhibition of voltage-sensitive calcium channels in the neuronal membrane associated with neurotransmitter release.     

Dopamine selects glutamatergic inputs to neostriatal neurons

Glutamatergic synaptic potentials induced by micromolar concentrations of the potassium conductance blocker 4-aminopyridine (4-AP) were recorded intracellularly from rat neostriatal neurons in the presence of 10 μM bicuculline (BIC). These synaptic potentials originate from neostriatal cortical and thalamic afferents and were completely blocked by 10 μM 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) plus 100 μM D-2-amino-5-phosphonovaleric acid (2-APV). Their inter-event time intervals could be fitted to exponential distributions, suggesting that they are induced randomly. Their amplitude distributions had most counts around 1 mV and fewer counts with values up to 5 mV. Since input resistance of the recorded neurons is about 40 MΩ, the amplitudes agree to quantal size measurements in mammalian central neurons. The action of a D₂ agonist, quinpirole, was studied on the frequency of these events. Mean amplitude of synaptic potentials was preserved in the presence of 2–10 μM quinpirole, but the frequency of 4-AP-induced glutamatergic synaptic potentials was reduced in 35% of cases. The effect was blocked by the D₂ antagonist sulpiride (10 μM). Input resistance, membrane potential, or firing threshold did not change during quinpirole effect, suggesting a presynaptic site of action for quinpirole in some but not all glutamatergic afferents that make contact on a single cell. The present experiments show that dopaminergic presynaptic modulation of glutamatergic transmission in the neostriatum does not affect all stimulated afferents, suggesting that it is selective towards some of them. This may control the quality and quantity of afferent flow upon neostriatal neurons. Synapse 25:185–195, 1997. © 1997 Wiley-Liss, Inc.     

突触前神经末梢的钙离子通道

突触前神经末梢的主要作用是以量子方式释放神经递质 ,并以此激活突触后的靶细胞。突触前神经末梢有大量的离子通道 ,在递质释放的每个步骤都有大量离子通道参与。这些离子通道主要包括 :钙离子 (Ca2 )通道、钾离子通道、Ca2 门控的钾离子通道、钠离子通道、氯离子通道、突触前配体 门控的离子通道及其他一些离子通道 ,其中Ca2 通道在递质释放的过程中尤为重要。Ca2 通道存在多种类型 ,不同类型的分子构成不同 ,性质也不同 ,它们分布在不同的生物组织中。不同Ca2 通道之间还存在着协同关系以促进递质释放。此外 ,大量存在的Ca2 通道是在生理和药理方面对递质释放进行更有效调节的基础。     

Baclofen has a presynaptic action at the crayfish neuromuscular junction

The action of baclofen, a GABA analog, was studied at the crayfish neuromuscular junction (NMJ). Baclofen depressed the amplitude of excitatory junction potentials (ejps) without affecting muscle input resistance and reduced the frequency of spontaneous miniature ejps without affecting their size. Thus, baclofen may mediate presynaptic inhibition by depressing transmitter release from the excitatory nerve. The site of baclofen's effect at the crayfish NMJ may parallel its site of action in the vertebrate nervous system.     

Isolation of functional presynaptic complexes from CNS neurons: a cell-free preparation for the study of presynaptic compartments in vitro

The difficulty in developing successful treatments to facilitate nerve regeneration has prompted a number of new in vitro experimental methods. We have recently shown that functional presynaptic boutons can be formed when neuronal cells are cocultured with surface-modified artificial substrates including poly(d-lysine)-coated beads and supported lipid bilayer-coated beads (Lucido(2009) J. Neurosci.29, 12449-12466; Gopalakrishnan(2010) ACS Chem. Neurosci.1, 86-94). We demonstrate here, using confocal microscopy combined with immunocytochemistry, that it is possible to isolate such in vitro presynaptic endings in an exclusive fashion onto glass substrates through a simple "sandwich/lift-off" technique (Perez(2006) Adv. Funct. Mater.16, 306-312). Isolated presynaptic complexes are capable of releasing and recycling neurotransmitter in response to an external chemical trigger. These bead-presynaptic complexes are facile to prepare and are readily dispersible in solution. They are thus compatible with many experimental methods whose focus is the study of the neuronal presynaptic compartment.     

Spectra of neurotransmitter receptors and ionic responses on cerebral A and B neurons in Aplysia californica

Receptors to putative transmitters on A and B cells of Aplysia californica were identified and characterized. Neurons within each cluster were similar in responses to transmitters, but the neurons in A and B clusters differed. Both exhibited receptors to acetylcholine, dopamine, gamma-aminobutyric acid, glutamate, histamine and serotonin but not to octopamine or phenylethanolamine. Bi- or multiphasic responses to a single transmitter were common on both cell types. Inhibitory responses were more common on A than B cells where glutamate, histamine and serotonin were all excitatory. Each of these clusters appear homogeneous both in terms of presence of receptors and the ionic channels activated by the receptors.     

GABAB receptors mediate frequency-dependent depression of excitatory potentials in rat perirhinal cortex in vitro

Excitatory synaptic transmission in the perirhinal cortex exhibits marked homosynaptic paired pulse depression (PPD) at inter-pulse intervals between 100 and 1000 ms, being maximal at 200 ms. Additionally, there is greater PPD with stimulation of the pathway from the temporal cortex side than with stimulation of the pathway from the entorhinal cortex side. We establish that this frequency-dependent depression relies on the activation of GABAB (gamma-aminobutyric acid) receptors. PPD in both temporal and entorhinal pathways is abolished by either of the selective GABAB receptor antagonists, 3-N[1-(S)-(3, 4-dichlorophenyl)ethyl]amino-2-(S)-hydroxypropyl-p-benzyl-phosphinic acid (CGP55845A) or 3-amino-propyl(diethoxymethyl)phosphinic acid (CGP35348). Barium which blocks G-protein-coupled, inwardly rectifying potassium channels, does not block PPD. Heterosynaptic depression mediated by GABAB receptors was also observed. The depression of the entorhinal pathway by stimulation of the temporal pathway is greater than depression of the temporal pathway by stimulation of the entorhinal pathway. Moreover, PPD increases with stimulus strength and the depression is enhanced by short trains of stimuli, consistent with stronger stimulation resulting in more GABA reaching GABAB receptors on excitatory glutamatergic synapses. Synaptic activation of GABAB receptors may be important in regulating excitability in a frequency-dependent manner with maximal depression occurring at approximately 5 Hz, which approximates to the theta rhythm. That homosynaptic and heterosynaptic depression by stimulation of the temporal pathway is greater than by stimulation of the entorhinal pathway suggests that activation of temporal feedforward connections to the perirhinal cortex can dominate the GABAergic control of synaptic activity within the perirhinal cortex.     

Antidromic inhibition of acetylcholine release from presynaptic nerve terminals in bullfrog's sympathetic ganglia

In isolated bullfrog's sympathetic ganglia it was examined if the release of acetylholine (ACh) from presynaptic nerve terminals was changed when postsynaptic ganglion cells were activated antidromically. The fast excitatory postsynaptic potential (fast EPSP) of ganglion cells was found to be depressed, whereas the nicotinic ACh potential of these cells was not depressed, immediately after these ganglion cells were activated by antidromic axonal or direct intracellular stimulations. This indicates that activation of ganglion cells results in inhibition of the release of ACh from their presynaptic nerve terminals. Such an antidromic inhibition of ACh release could not be clearly observed when preparations were perfused with Ca²⁺-deficient solution or when adrenaline (10⁻⁵ M) was added to the superfusion solution. Frequency of the spontaneous miniature EPSP was also found to be decreased after antidromic activation of ganglion cells. On the basis of these results it was concluded that some kind of transmitter was released from activated ganglion cells which inhibited ACh release by acting on preganglionic nerve terminals. This putative neurotransmitter was suggested to be adrenaline.     

Trimethadione effects on cholinergic responses in Aplysia neurons

The anticonvulsant, trimethadione (TMO), was tested for effects on cholinergic responses to iontophoretic application of ACh on identified neurons in Aplysia. TMO (1–10 mM) depressed the amplitudes of depolarizing responses mediated by Na⁺ and hyperpolarizing responses mediated by Cl⁻ but did not affect hyperpolarizing responses mediated by K⁺. Such a combination of effects on cholinergic responses distinguishes the action of this anti-absence drug from agents effective against tonic-clonic seizures and from convulsant drugs.     

Regulation of single potassium channels by serotonin in the cell bodies of the tail mechanosensory neurons ofAplysia californica

Sensory neurons in the pleural ganglion ofAplysia mediate the afferent portion of the tail withdrawal reflex. Previous work has shown that in these neurons and in the siphon sensory neurons ofAplysia, serotonin modulates a steady-state non-inactivating potassium current called the S current. Using the technique of patch clamping, we have examined the kinetics of single potassium channels and found that they share the properties of the S potassium channel of the siphon sensory neurons. This channel has an elementary slope conductance of73 ± 9.98pS(x±S.E.M.) and shows Goldman rectification. It is active at the resting potential and does not inactivate with maintained depolarization. Bath application of serotonin in a majority of experiments decreased the functional number of channels in the patch.     

Signals from cone photoreceptors to L-type horizontal cells are differentially modulated by low calcium in carp retina

Ca2+ plays crucial roles in both phototransduction and calcium-dependent glutamate release from the photoreceptor terminal. Modulation, by lowering extracellular Ca2+, of red-sensitive (R-) and short wavelength-sensitive (S-) cone-driven light responses of L-type horizontal cells (LHCs) was studied in the isolated superfused carp retina using intracellular recording techniques. Low Ca2+ (nominally Ca2+-free) Ringer's reduced responses of LHCs to both green (500 nm) and red (680 nm) flashes in darkness, with the former being suppressed more substantially than the latter. This differential suppression became more significant when contribution of R-cones to the green-light-induced responses was diminished by a moderate red (680 nm) background light. Application of IBMX, an inhibitor of phosphodiesterase (PDE), increased LHC responses to both red and green flashes equally, resembling the effect of low Ca2+ on phototransduction. In addition, photopic electroretinographic P III responses, reflecting the activity of cones, to red flashes were more potentiated by low Ca2+, compared to those to green flashes, whilst they were both equally potentiated by IBMX. Furthermore, low Ca2+ caused a more pronounced suppression of LHC responses to red flashes than those to green flashes in the presence of IBMX. It is postulated that reduction of LHC responses in low Ca2+ may be due to the 'saturation suppression' caused by the increased glutamate release from the photoreceptor terminal and the differential modulation may reflect a consequence of the dual action of low Ca2+ on the PDE activity in the photoreceptor outer segment and the synaptic strength between cones and LHCs.     

Depolarization-induced suppression of inhibition mediated by endocannabinoids at synapses from fast-spiking interneurons to medium spiny neurons in the striatum

Endogenous cannabinoids (endocannabinoids) act as retrograde inhibitory messengers in various regions of the brain. We have recently reported that endocannabinoids mediate short-term retrograde suppression of excitatory synaptic transmission from the neocortex to medium spiny (MS) neurons, the major projection neurons from the striatum. However, it remains unclear whether endocannabinoids modulate inhibitory transmission in the striatum. Here we show that depolarization of MS neurons induces transient suppression of inhibition that is mediated by retrograde endocannabinoid signalling. By paired recording from a fast-spiking (FS) interneuron and an MS neuron, we demonstrated that FS-MS inhibitory synapses undergo endocannabinoid-mediated retrograde suppression. We verified that GABAergic inhibitory terminals immunopositive for parvalbumin (PV), a marker for FS interneurons, expressed CB1 receptors. These PV-CB1 double-positive terminals surrounded dopamine D1 receptor-positive and D2 receptor-positive MS neurons; these constitute direct and indirect pathways, respectively. These results suggest that endocannabinoid-mediated retrograde suppression of inhibition influences information flow along both direct and indirect pathways, depending on the activity of MS neurons.