Variability of neurotransmitter concentration and nonsaturation of postsynaptic AMPA receptors at synapses in hippocampal cultures and slices

To understand the elementary unit of synaptic communication between CNS neurons, one must know what causes the variability of quantal postsynaptic currents and whether unitary packets of transmitter saturate postsynaptic receptors. We studied single excitatory synapses between hippocampal neurons in culture. Focal glutamate application at individual postsynaptic sites evoked currents (I(glu)) with little variability compared with quantal excitatory postsynaptic currents (EPSCs). The maximal I(glu) was >2-fold larger than the median EPSC. Thus, variations in [glu]cleft are the main source of variability in EPSC size, and glutamate receptors are generally far from saturation during quantal transmission. This conclusion was verified by molecular antagonism experiments in hippocampal cultures and slices. The general lack of glutamate receptor saturation leaves room for increases in [glu]cleft as a mechanism for synaptic plasticity.     

Joint application of the independent component analysis and the nonstationary fluctuation analysis for the investigation of early stages of long-term potentiation in the rat hippocampus

An invariable interest in mechanisms of synaptic plasticity gave birth to several specific methods of evoked postsynaptic responses analysis: quantal analysis, component analysis, nonstationary fluctuation analysis (NSFA) etc. The major part of these methods are not standardized yet however, that can lead to obtaining different (and even contradictory) results in similar experiments performed by different scientific groups. This paper issues the experiments for revealing pre- or postsynaptic location of the synaptic plasticity mechanisms during the early phases of the long-term potentiation (LTP). On a model we analyse how an estimation of the single-channel current made by the NSFA is influenced by changes in the evoked postsynaptic currents shape variability. A hypothesis is made that the apparent increase in the AMPA-receptor single-channel current, reported in some works for early LTP stages, could be concerned with the increase in the postsynaptic response shape variability rather then with real increase in AMPA-receptor channels conductivity. The shape of the postsynaptic responses can become more variable after LTP-associated unsilencing of the previously silent synapses. A new method of independent component analysis (ICA) is introduced to check this hypothesis first on model and than on physiological data. The results of the experiments in general agree with the hypothesis suggested.     

Actions of endomorphins on synaptic transmission of aδ-fibers in spinal cord dorsal horn neurons

The effects of endogenous mu-opioid ligands, endomorphins, on Adelta-afferent-evoked excitatory postsynaptic currents (EPSCs) were studied in substantia gelatinosa neurons in spinal cord slices. Under voltage-clamp conditions, endomorphins blocked the evoked EPSCs in a dose-dependent manner. To determine if the block resulted from changes in transmitter release from glutamatergic synaptic terminals, the opioid actions on miniature excitatory postsynaptic currents (mEPSCs) were examined. Endomorphins (1 microM) reduced the frequency but not the amplitude of mEPSCs, suggesting that endomorphins directly act on presynaptic terminals. The effects of endomorphins on the unitary (quantal) properties of the evoked EPSCs were also studied. Endomorphins reduced unitary content without significantly changing unitary amplitude. These results suggest that in addition to presynaptic actions on interneurons, endomorphins also inhibit evoked EPSCs by reducing transmitter release from Adelta-afferent terminals.     

Intrasynaptic ephaptic feedback in central synapses]

A review is given of experiments performed in the author's laboratory on slices from the rat visual cortex and hippocampus. The aim was to test the existence of the positive feedback in central synapses according to a mechanism of electrical (ephatic) linking proposed by A. L. Byzow. The hypothesis predicts that, in a subset of central synapses, artificial postsynaptic membrane potential (MP) hyperpolarization should increase the amplitude of the excitatory postsynaptic current (EPSC) and potential (EPSP) not only due to a deviation from the equilibrium potential but also due to increased presynaptic transmitter release. In a part of the experiments, we found changes in several traditional parameters of transmitter release during hyperpolarization: number of response failures, coefficient of variation of response amplitude and quantal content of minimal EPSC/EPSP. The effects were especially prominent for the giant mossy fibre-CA3 synapses. For them, "supralinear" amplitude-voltage relations at hyperpolarized membrane potentials and voltage--dependent paired--pulse facilitation ratios were found. All these "non-classical" effects disappeared when composite, rather than minimal, EPSCs were evoked. These data were consistent with simulation experiments performed on the Byzov's synaptic model with the ephaptic feedback and therefore they strengthen the hypothesis. Independent of their interpretation, the data reveal a novel feedback mechanism. The mechanism provides a possibility for the central postsynaptic neurone to control the efficacy of a subset of synapses via postsynaptic MP modifications. The mechanism can essentially increase the efficacy of large ("perforated") synapses. It explains the significance of the increased number of such synapses following experimental challenges such as leading to induction of the long-term potentiation or to behavioural conditioning.     

Re-examination of the determinants of synaptic strength from the perspective of superresolution imaging

Synaptic strength is thought to be determined by the number of presynaptic release sites, release probability and postsynaptic response to quantal release. Changes in these parameters are directly relevant to synaptic plasticity. However, our understanding of these determinants as they relate to synaptic function has been reformed by recent work on nanoscale organizations of synaptic proteins. Specifically, release probability is distributed heterogeneously among multiple release sites within a single active zone, and the quantal postsynaptic response depends strongly on the local distribution of receptors around the release site. These nanoscale characteristics reveal a new deeper layer of modulation of synaptic transmission and plasticity.     

Analytical description of the activation of multi-state receptors by continuous neurotransmitter signals at brain synapses.

Chemical synaptic transmission is a fundamental component of interneuronal communications in the central nervous system (CNS). Discharge of a presynaptic vesicle containing a few thousand molecules (a quantum) of neurotransmitter into the synaptic cleft generates a transmitter concentration signal that drives postsynaptic ion-channel receptors. These receptors exhibit multiple states, with state transition kinetics dependent on neurotransmitter concentration. Here, a novel and simple analytical approach for describing gating of multi-state receptors by signals with complex continuous time courses is used to describe the generation of glutamate-mediated quantal postsynaptic responses at brain synapses. The neurotransmitter signal, experienced by multi-state N-methyl-D-aspartate (NMDA)- and L-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA)-type glutamate receptors at specific points in a synaptic cleft, is approximated by a series of step functions of different intensity and duration and used to drive a Markovian, multi-state kinetic scheme that describes receptor gating. Occupancy vectors at any point in time can be computed interatively from the occupancy vectors at the times of steps in transmitter concentration. Multi-state kinetic schemes for both the low-affinity AMPA subtype of glutamate receptor and for the high-affinity NMDA subtype are considered, and expected NMDA and AMPA components of synaptic currents are calculated. The amplitude of quantal responses mediated by postsynaptic receptor clusters having specific spatial distributions relative to foci of quantal neurotransmitter release is then calculated and related to the displacement between the center of the postsynaptic receptor cluster and the focus of synaptic vesicle discharge. Using this approach we show that the spatial relation between the focus of release and the center of the postsynaptic receptor cluster affects synaptic efficacy. We also show how variation in this relation contributes to variation in synaptic current amplitudes.     

Effects of ethimizol on frog neuromuscular junction

The effects were studied of ethimizol, a substance activating memory processes, on features of synaptic transmission during experiments on frog cutaneous pectoris muscle. It was found that the presynaptic action of ethimizol consists of raising the frequency of miniature potentials, when used at a concentration of 0.5–10 mM, and modulating quantal content of synaptic transmission due to changes in binomial quantal release parameters p and n when 0.5–2 mM ethimizol was used. This substance facilitated transmission at synapses with a low initial level of transmitter release. This substance facilitated transmission at synapses with a low initial level of transmitter release. Ethimizol was also found to have a postsynaptic action, consisting of reducing amplitude at a concentration of 5–10 mM and prolonging synaptic currents and potentials when concentrations of 0.5–10 mM were used. The latter effect produced a considerable increase in the time integral of endplate potentials. The postsynaptic action of ethimizol is perhaps seen in its effects on features of postsynaptic ionic channels. The effects of ethimizol are discussed with a view to how it may act within the central nervous system as a nonspecific modulator.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 17, No. 6, pp. 757–763, November–December, 1985.     

Quantal analysis of synaptic processes in the neocortex

The application of fluctuation analysis to studies of synaptic function in the neocortex is discussed. Analysis of failures of transmission has been valuable in indicating whether a presynaptic or a postsynaptic site is responsible for a change in synaptic efficacy. When combined with detailed ultrastructural verification of all synapses involved in an individual cell to cell connection, a reasonable estimate of quantal size and release probability under conditions of low frequency activity can be obtained. However, both the number of available release sites in functional terms and the probability that an action potential (AP) will release transmitter from any given site can vary from AP to AP at higher frequencies. A variety of presynaptic mechanisms that modulate release are now apparent. For example, one mechanism dominates release patterns at one class of connection which is insensitive to absolute firing frequency, but responsive to changes in frequency. At another class of connection, a different mechanism dominates, resulting in high sensitivity to frequency.     

Presynaptic effects induced by pretreatment with formamide of the neuromuscular junction of the mouse]

Some techniques to block muscular nerve evoked contraction involve pharmacological approaches using synaptic blocking agents. Such methods interfere with normal synaptic transmission, and could introduce artifacts making difficult the experimental interpretation. The method based on the use of formamide pre-treatment should not interfere with synaptic physiology, indeed previous works suggest that the mechanism involved in block of muscle activity could depend on the decrease in specific postsynaptic membrane capacitance, and on the disruption of the morphology of the transverse tubule system. To prove this assumption we evaluated before and after formamide pre-treatment, some pre and postsynaptic parameters related to the spontaneous quantal release (MEPC). By means of the Loose patch clamp technique, we demonstrated, that formamide pre-treatment increases in an irreversible manner the frequency of spontaneous quantal release. Morphology of MEPC appear not modified by formamide pretreatment, which does not interfere with postsynaptic cholinergic receptors activity.     

Changes in the kinetics of quanta secretion-effective mechanism of synaptic transmission modulation

It is widely accepted that the leading presynaptic mechanisms underlying the synaptic plasticity involve changes of the number of neurotransmitter quanta released by one nerve pulse (the quantal content of postsynaptic response) and of the size of a single quantum. In addition, the existence of one more effective though previously ignored mechanism of modulation of synaptic plasticity was suggested related to the change in the time course (kinetics) of secretion of single neurotransmitter quanta forming the multiquantal response. This article reviews current data (including the authors' own results) on the kinetics of evoked neurotransmitter quanta secretion from motor nerve endings in peripheral synapses, mechanisms of their modulation and methods of quantitative analysis.     

Quantal glutamate release is essential for reliable neuronal encodings in cerebral networks

Background

The neurons and synapses work coordinately to program the brain codes of controlling cognition and behaviors. Spike patterns at the presynaptic neurons regulate synaptic transmission. The quantitative regulations of synapse dynamics in spike encoding at the postsynaptic neurons remain unclear.

Methodology/Principal Findings

With dual whole-cell recordings at synapse-paired cells in mouse cortical slices, we have investigated the regulation of synapse dynamics to neuronal spike encoding at cerebral circuits assembled by pyramidal neurons and GABAergic ones. Our studies at unitary synapses show that postsynaptic responses are constant over time, such as glutamate receptor-channel currents at GABAergic neurons and glutamate transport currents at astrocytes, indicating quantal glutamate release. In terms of its physiological impact, our results demonstrate that the signals integrated from quantal glutamatergic synapses drive spike encoding at GABAergic neurons reliably, which in turn precisely set spike encoding at pyramidal neurons through feedback inhibition.

Conclusion/Significance

Our studies provide the evidences for the quantal glutamate release to drive the spike encodings precisely in cortical circuits, which may be essential for programming the reliable codes in the brain to manage well-organized behaviors.     

Expression mechanisms of long-term potentiation in the hippocampus

We have taken a number of different experimental approaches to address whether long-term potentiation (LTP) in hippocampal CA1 pyramidal cells is due primarily to presynaptic or postsynaptic modifications. Examination of miniature EPSCs or EPSCs evoked using minimal stimulation indicate that quantal size increasing during LTP. The conversion of silent to functional synapses may contribute to the LTP-induced changes in mEPSC frequency and failure rate that previously have been attributed to an increase in the probability if transmitter release.     

Estimating synaptic parameters from mean, variance, and covariance in trains of synaptic responses

Fluctuation analysis of synaptic transmission using the variance-mean approach has been restricted in the past to steady-state responses. Here we extend this method to short repetitive trains of synaptic responses, during which the response amplitudes are not stationary. We consider intervals between trains, long enough so that the system is in the same average state at the beginning of each train. This allows analysis of ensemble means and variances for each response in a train separately. Thus, modifications in synaptic efficacy during short-term plasticity can be attributed to changes in synaptic parameters. In addition, we provide practical guidelines for the analysis of the covariance between successive responses in trains. Explicit algorithms to estimate synaptic parameters are derived and tested by Monte Carlo simulations on the basis of a binomial model of synaptic transmission, allowing for quantal variability, heterogeneity in the release probability, and postsynaptic receptor saturation and desensitization. We find that the combined analysis of variance and covariance is advantageous in yielding an estimate for the number of release sites, which is independent of heterogeneity in the release probability under certain conditions. Furthermore, it allows one to calculate the apparent quantal size for each response in a sequence of stimuli.     

Quantal Characteristics of Synaptic GABA Release under Conditions of Stimulation of Single Synaptic Terminals of Cultured Cortical Cells of the Rat

We studied evoked inhibitory postsynaptic currents (eIPSC) using local electrical stimulation of single presynaptic terminals of cultured rat neocortical neurons. According to pharmacological and kinetic properties, these currents were qualified as GABA_A-activated. Using autocorrelation analysis of distributions of the eIPSC amplitudes, which were in all cases polymodal, we examined quantal characteristics of the above eIPSC. These results were compared with the values of quantal parameters (N, p, Q, and m) of the current families obtained using approximation by binomial distribution. Amplitude histograms of spontaneous miniature IPSC recorded under conditions of the minimum quantal release of the neurotransmitter were normal (close to Gaussian) with the mode within a 10 pA range, which is very close to analogous parameters calculated using autocorrelation and binomial techniques.     

Synapse geometry and receptor dynamics modulate synaptic strength

Synaptic transmission relies on several processes, such as the location of a released vesicle, the number and type of receptors, trafficking between the postsynaptic density (PSD) and extrasynaptic compartment, as well as the synapse organization. To study the impact of these parameters on excitatory synaptic transmission, we present a computational model for the fast AMPA-receptor mediated synaptic current. We show that in addition to the vesicular release probability, due to variations in their release locations and the AMPAR distribution, the postsynaptic current amplitude has a large variance, making a synapse an intrinsic unreliable device. We use our model to examine our experimental data recorded from CA1 mice hippocampal slices to study the differences between mEPSC and evoked EPSC variance. The synaptic current but not the coefficient of variation is maximal when the active zone where vesicles are released is apposed to the PSD. Moreover, we find that for certain type of synapses, receptor trafficking can affect the magnitude of synaptic depression. Finally, we demonstrate that perisynaptic microdomains located outside the PSD impacts synaptic transmission by regulating the number of desensitized receptors and their trafficking to the PSD. We conclude that geometrical modifications, reorganization of the PSD or perisynaptic microdomains modulate synaptic strength, as the mechanisms underlying long-term plasticity.     

Presynaptic effects of biogenic amines modulating synaptic transmission between identified sensory neurons and giant interneurons in the first instar cockroach

Intracellular recording was used to investigate the modulatory effects of serotonin and octopamine on the identified synapses between filiform hair sensory afferents and giant interneurons in the first instar cockroach, Periplaneta americana. Serotonin at 10(-4) mol l(-1) to 10(-3) mol l(-1) reduced the amplitude of the lateral axon-to-ipsilateral giant interneuron 3 excitatory postsynaptic potentials. and octopamine at 10(-4) mol l(-1) increased their amplitude. Similar effects were seen on excitatory postsynaptic potentials in dorsal giant interneuron 6. Several lines of evidence suggest that both substances modulate the amplitude of excitatory postsynaptic potentials by acting presynaptically, rather than on the postsynaptic neuron. The fitting of simple binomial distributions to the postsynaptic potential amplitude histograms suggested that, for both serotonin and octopamine, the number of synaptic release sites was being modulated. Secondly, the amplitudes of miniature excitatory postsynaptic potentials recorded in the presence of tetrodotoxin were unaffected by either modulator. Finally, recordings from contralateral giant interneuron 3, which has two identifiable populations of synaptic inputs, showed that each modulator had a more pronounced effect on excitatory postsynaptic potentials evoked by the lateral axon than on those evoked by the medial axon. Immunocytochemistry confirmed that neuropilar processes containing serotonin are present in close proximity to these synapses.     

Physiological properties of newly formed synapses between sympathetic preganglionic neurons and sympathetic ganglion neurons

We have examined the physiological properties of transmission at newly formed synapses between sympathetic preganglionic neurons and sympathetic ganglion neurons in vitro. Chick neurons were labeled with fluorescent carbocyanine dyes before they were placed into culture (Honig and Hume, 1986), and were studied by making intracellular recordings during the first 2 weeks of coculture. Evoked monosynaptic excitatory postsynaptic potentials (EPSPs) were not observed until 48 h of coculture. Beyond this time, the frequency with which connected pairs could be found did not vary greatly with time. With repetitive stimulation, the evoked monosynaptic EPSPs fluctuated in amplitude from trial to trial and showed depression at frequencies as low as 1 Hz. To gain further information about the quantitative properties of transmission at newly formed synapses, we analyzed the pattern of fluctuations of delayed release EPSPs. In mature systems, delayed release EPSPs are known to represent responses to single quanta, or to the synchronous release of a small number of quanta. For more than half of the connections we studied, the histograms of delayed release EPSPs were extremely broad. This result suggested that either quantal reponses are drawn from a continuous distribution that has a large coefficient of variation or that there are several distinct size classes of quantal responses. The pattern of fluctuation of monosynaptic EPSPs was consistent with both of these possibilities, and was inconsistent with the possibility that monosynaptic EPSPs are composed of quantal subunits with very little intrinsic variation. Although variation in the size of responses to single quanta might arise in a number of ways, one attractive explanation for our results is that the density and type of acetylcholine receptors varies among the different synaptic sites on the surface of developing sympathetic ganglion neurons.     

Physiological properties of newly formed synapses between sympathetic preganglionic neurons and sympathetic ganglion neurons.

We have examined the physiological properties of transmission at newly formed synapses between sympathetic preganglionic neurons and sympathetic ganglion neurons in vitro. Chick neurons were labeled with fluorescent carbocyanine dyes before they were placed into culture (Honig and Hume, 1986), and were studied by making intracellular recordings during the first 2 weeks of coculture. Evoked monosynaptic excitatory postsynaptic potentials (EPSPs) were not observed until 48 h of coculture. Beyond this time, the frequency with which connected pairs could be found did not vary greatly with time. With repetitive stimulation, the evoked monosynaptic EPSPs fluctuated in amplitude from trial to trial and showed depression at frequencies as low as 1 Hz. To gain further information about the quantitative properties of transmission at newly formed synapses, we analyzed the pattern of fluctuations of delayed release EPSPs. In mature systems, delayed release EPSPs are known to represent responses to single quanta, or to the synchronous release of a small number of quanta. For more than half of the connections we studied, the histograms of delayed release EPSPs were extremely broad. This result suggested that either quantal responses are drawn from a continuous distribution that has a large coefficient of variation or that there are several distinct size classes of quantal responses. The pattern of fluctuations of monosynaptic EPSPs was consistent with both of these possibilities, and was inconsistent with the possibility that monosynaptic EPSPs are composed of quantal subunits with very little intrinsic variation. Although variation in the size of responses to single quanta might arise in a number of ways, one attractive explanation for our results is that the density and type of acetylcholine receptors varies among the different synaptic sites on the surface of developing sympathetic ganglion neurons.