Postsynaptic variability of firing in rat cortical neurons: the roles of input synchronization and synaptic NMDA receptor conductance.

Neurons in the functioning cortex fire erratically, with highly variable intervals between spikes. How much irregularity comes from the process of postsynaptic integration and how much from fluctuations in synaptic input? We have addressed these questions by recording the firing of neurons in slices of rat visual cortex in which synaptic receptors are blocked pharmacologically, while injecting controlled trains of unitary conductance transients, to electrically mimic natural synaptic input. Stimulation with a Poisson train of fast excitatory (AMPA-type) conductance transients, to simulate independent inputs, produced much less variability than encountered in vivo. Addition of NMDA-type conductance to each unitary event regularized the firing but lowered the precision and reliability of spikes in repeated responses. Independent Poisson trains of GABA-type conductance transients (reversing at the resting potential), which simulated independent activity in a population of presynaptic inhibitory neurons, failed to increase timing variability substantially but increased the precision of responses. However, introduction of synchrony, or correlations, in the excitatory input, according to a nonstationary Poisson model, dramatically raised timing variability to in vivo levels. The NMDA phase of compound AMPA-NMDA events conferred a time-dependent postsynaptic variability, whereby the reliability and precision of spikes degraded rapidly over the 100 msec after the start of a synchronous input burst. We conclude that postsynaptic mechanisms add significant variability to cortical responses but that substantial synchrony of inputs is necessary to explain in vivo variability. We suggest that NMDA receptors help to implement a switch from precise firing to random firing during responses to concerted inputs.     

Interactions between behaviorally relevant rhythms and synaptic plasticity alter coding in the piriform cortex

Understanding how neural and behavioral timescales interact to influence cortical activity and stimulus coding is an important issue in sensory neuroscience. In air-breathing animals, voluntary changes in respiratory frequency alter the temporal patterning olfactory input. In the olfactory bulb, these behavioral timescales are reflected in the temporal properties of mitral/tufted (M/T) cell spike trains. As the odor information contained in these spike trains is relayed from the bulb to the cortex, interactions between presynaptic spike timing and short-term synaptic plasticity dictate how stimulus features are represented in cortical spike trains. Here, we demonstrate how the timescales associated with respiratory frequency, spike timing, and short-term synaptic plasticity interact to shape cortical responses. Specifically, we quantified the timescales of short-term synaptic facilitation and depression at excitatory synapses between bulbar M/T cells and cortical neurons in slices of mouse olfactory cortex. We then used these results to generate simulated M/T population synaptic currents that were injected into real cortical neurons. M/T population inputs were modulated at frequencies consistent with passive respiration or active sniffing. We show how the differential recruitment of short-term plasticity at breathing versus sniffing frequencies alters cortical spike responses. For inputs at sniffing frequencies, cortical neurons linearly encoded increases in presynaptic firing rates with increased phase-locked, firing rates. In contrast, at passive breathing frequencies, cortical responses saturated with changes in presynaptic rate. Our results suggest that changes in respiratory behavior can gate the transfer of stimulus information between the olfactory bulb and cortex.     

Long-term Depression of Horizontal Connections in Rat Motor Cortex

The possibility for long-term depression (LTD) of synaptic transmission in layer 11/11 I horizontal connections within motor cortex was investigated using field potentials and intracellular recordings in rat brain slices. The LTD was induced by low-frequency stimulation at 2 Hz for 10 min in sites displaced horizontally by 0.5 mm from the stimulating electrode. Response amplitude measured 25-30 min after 2 Hz stimulation ended was 79% of baseline values ( n = 13) at half maximal stimulation and 59% when 2 Hz stimulus intensity was doubled ( n = 10). In 13/15 tested cases LTD in horizontal connections was specific to the activated pathway. Intracellular recordings from six neurons confirmed synaptic character of response depression. Horizontal connections in which LTD was induced retained the capability of increasing synaptic strength. Long-term potentiation could be induced in previously depressed pathways by simultaneous theta burst stimulation of two converging horizontal inputs combined with transient local application of GABAA receptor antagonist bicuculline methiodide (mean increase: 45 ± 8%, n = 6) or by simultaneous theta burst stimulation of converging horizontal and vertical inputs (mean change: 26 5 6%, n = 5). These data demonstrate that activity-dependent mechanisms may regulate bidirectionally the effectiveness of horizontal synaptic coupling between cortical neurons, thus forming a potential mechanism for plasticity of cortical connections and the representation patterns they support.     

Differential modulation by dopamine of responses evoked by excitatory amino acids in human cortex.

The responses of human neocortical neurons to iontophoretic application of excitatory amino acids and their modulation by dopamine (DA) were studied in vitro. Brain slices were obtained from children undergoing surgery for intractable epilepsy. Application of N-methyl-D-aspartate (NMDA) to the slices induced slow depolarizations accompanied by decreased input conductances and sustained action potentials in cortical neurons. Glutamate produced rapid depolarizations and firing with few changes in input conductances. Quisqualate also induced depolarization and firing, but input conductances increased during the rising phase of the membrane depolarization. Iontophoretic application of DA alone produced no change in membrane potential or input conductance. However, when DA was applied in conjunction with the excitatory amino acids, it produced contrasting effects. With either bath application of DA or when iontophoresis of DA preceded application of NMDA, the amplitude of the membrane depolarizations and the number of action potentials were increased, whereas the latency of these responses decreased. In contrast, DA decreased the amplitude of the depolarizations and the number of action potentials evoked by glutamate or quisqualate. The fact that DA affects responses to NMDA and glutamate or quisqualate in opposite directions is of considerable importance to the understanding of cellular mechanisms of neuromodulation and the role of DA in cognitive processing and in epilepsy.     

Back-propagating action potentials in pyramidal neurons: a putative signaling mechanism for the induction of Hebbian synaptic plasticity

A hallmark of synaptic plasticity is the associative, or Hebbian, nature of its induction. By associative, we mean that the timing relationships between activity of the pre- and postsynaptic elements of a synapse determine whether synaptic strengths are modified. lt is well-established that associativity results, in large part, from the dual requirements for activation of the N-methyl-D-aspartate receptor-ionophore, namely presynaptic neurotransmitter release and postsynaptic depolarization. However, the specific dendritic events that provide the postsynaptic depolarization have been relatively unexplored. Increasing evidence suggests that back-propagating (i.e., antidromic) Na(+) action potentials provide the necessary postsynaptic depolarization to allow induction of associative synaptic plasticities. In hippocampal CAI and neocortical layer V pyramidal neurons, these action potentials provide much greater levels of dendritic depolarization than would be expected from synaptic currents alone. Moreover, they provide a relatively brief and synchronous depolarization throughout the dendritic arbor, allowing timing relationships to more directly reflect pre- and postsynaptic cell firing. Interestingly, certain properties of the back-propagating actions potentials differ from axonal or somatic action potentials in ways that seem to reflect their function. For example, the all-or-none property of action potential amplitude does not hold in the dendrites. In this review we discuss the back-propagating action potential as a dendritic signal that provides information to synapses about the firing state of the postsynaptic neuron. First, we consider the evidence that action potentials propagate back from the axon. Second, we describe the characteristics of the back-propagating action potential in terms of interactions of its underlying ionic currents. Third, we describe how these properties contribute to the timing aspects of the induction of long-term potentiation. Finally, we discuss modulation of the underlying ion channels by neurotransmitter systems and other agents and speculate on their roles in learning and memory.     

Action potential backpropagation and somato-dendritic distribution of ion channels in thalamocortical neurons.

Thalamocortical (TC) neurons of the dorsal thalamus integrate sensory inputs in an attentionally relevant manner during wakefulness and exhibit complex network-driven and intrinsic oscillatory activity during sleep. Despite these complex intrinsic and network functions, little is known about the dendritic distribution of ion channels in TC neurons or the role such channel distributions may play in synaptic integration. Here we demonstrate with simultaneous somatic and dendritic recordings from TC neurons in brain slices that action potentials evoked by sensory or cortical excitatory postsynaptic potentials are initiated near the soma and backpropagate into the dendrites of TC neurons. Cell-attached recordings demonstrated that TC neuron dendrites contain a nonuniform distribution of sodium but a roughly uniform density of potassium channels across the somatodendritic area examined that corresponds to approximately half the average path length of TC neuron dendrites. Dendritic action potential backpropagation was found to be active, but compromised by dendritic branching, such that action potentials may fail to invade relatively distal dendrites. We have also observed that calcium channels are nonuniformly distributed in the dendrites of TC neurons. Low-threshold calcium channels were found to be concentrated at proximal dendritic locations, sites known to receive excitatory synaptic connections from primary afferents, suggesting that they play a key role in the amplification of sensory inputs to TC neurons.     

Synaptic shunting by a baseline of synaptic conductances modulates responses to inhibitory input volleys in cerebellar Purkinje cells

When processing synaptic input in vivo, large neurons in the brain must cope with thousands of events each second. Much work has focused on the specific processing of synchronous excitatory input volleys, both in cerebellar and cerebral cortical research. Here we pursue the question of how a continuous background of ongoing 'noise' inputs interacts with the processing of synchronous inhibitory input volleys. Specifically we examine the processing of inhibitory input transients in cerebellar Purkinje cells, which by inducing pauses in Purkinje cell spike activity may lead to a disinhibition of the deep cerebellar nuclei and thus to cerebellar motor command signals. We use the technique of dynamic clamping in vitro to simulate controlled patterns of in vivo like background inputs. We use electrical stimulation of inhibitory interneurons in the deep or upper molecular layer to create inhibitory input transients that lead to spike pauses in Purkinje cell activity. These pauses were much longer in the absence than in the presence of background inputs applied with dynamic clamping. We found that a significant amount of the synaptic current elicited by electrical stimulation was shunted by the background inputs. The overall amount of background conductance as well as the pattern of background inputs modulated spike pause duration in a specific manner. This modulation by shunting may be employed in vivo to evaluate the salience of specific sensory input received by cerebellar cortex.     

Modulation of synaptic transmission in neocortex by network activities

Neocortical neurons integrate inputs from thousands of presynaptic neurons that fire in vivo with frequencies that can reach 20 Hz. An important issue in understanding cortical integration is to determine the actual impact of presynaptic firing on postsynaptic neuron in the context of an active network. We used dual intracellular recordings from synaptically connected neurons or microstimulation to study the properties of spontaneous and evoked single-axon excitatory postsynaptic potentials (EPSPs) in vivo, in barbiturate or ketamine-xylazine anaesthetized cats. We found that active states of the cortical network were associated with higher variability and decrease in amplitude and duration of the EPSPs owing to a shunting effect. Moreover, the number of apparent failures markedly increased during active states as compared with silent states. Single-axon EPSPs in vivo showed mainly paired-pulse facilitation, and the paired-pulse ratio increased during active states as compare to silent states, suggesting a decrease in release probability during active states. Raising extracellular Ca(2+) concentration to 2.5-3.0 mm by reverse microdialysis reduced the number of apparent failures and significantly increased the mean amplitude of individual synaptic potentials. Quantitative analysis of spontaneous synaptic activity suggested that the proportion of presynaptic activity that impact at the soma of a cortical neuron in vivo was low because of a high failure rate, a shunting effect and probably dendritic filtering. We conclude that during active states of cortical network, the efficacy of synaptic transmission in individual synapses is low, thus safe transmission of information requires synchronized activity of a large population of presynaptic neurons.     

Differential regulation of spontaneous and evoked inhibitory synaptic transmission in somatosensory cortex by retinoic acid

Retinoic acid (RA), a developmental morphogen, has emerged in recent studies as a novel synaptic signaling molecule that acts in mature hippocampal neurons to modulate excitatory and inhibitory synaptic transmission in the context of homeostatic synaptic plasticity. However, it is unclear whether RA is capable of modulating neural circuits outside of the hippocampus, and if so, whether the mode of RA's action at synapses is similar to that within the hippocampal network. Here we explore for the first time RA's synaptic function outside the hippocampus and uncover a novel function of all‐trans retinoic acid at inhibitory synapses. Acute RA treatment increases spontaneous inhibitory synaptic transmission in L2/3 pyramidal neurons of the somatosensory cortex, and this effect requires expression of RA's receptor RARα both pre‐ and post‐synaptically. Intriguingly, RA does not seem to affect evoked inhibitory transmission assayed with either extracellular stimulation or direct activation of action potentials in presynaptic interneurons at connected pairs of interneurons and pyramidal neurons. Taken together, these results suggest that RA's action at synapses is not monotonous, but is diverse depending on the type of synaptic connection (excitatory versus inhibitory) and circuit (hippocampal versus cortical). Thus, synaptic signaling of RA may mediate multi‐faceted regulation of synaptic plasticity. In addition to its classic roles in brain development, retinoic acid (RA) has recently been shown to regulate excitatory and inhibitory transmission in the adult brain. Here, the authors show that in layer 2/3 (L2/3) of the somatosensory cortex (S1), acute RA induces increases in spontaneous but not action‐potential evoked transmission, and that this requires retinoic acid receptor (RARα) both in presynaptic PV‐positive interneurons and postsynaptic pyramidal (PN) neurons.     

Deafferentation Weakens Excitatory Synapses in the Developing Central Auditory System

Decreased excitatory synaptic activity during development often leads to pre- and postsynaptic atrophy, as assessed anatomically. The present study considers the effect of decreased excitatory transmission on the maturation of synaptic strength. Towards this end, cochlear nucleus neurons, which project to the ipsilateral lateral superior olive (LSO), were denervated in gerbils at postnatal day 7, before the onset of hearing. This manipulation was intended to disrupt spontaneous glutamatergic transmission in the LSO while sparing the glycinergic afferents from the medial nucleus of the trapezoid body (MNTB). Afferent-evoked synaptic activity was assessed 1–6 days after ablation in a brain slice preparation using whole-cell current- and voltage-clamp recordings. In control animals, ipsilaterally evoked excitatory postsynaptic potentials (EPSPs) were present in 91% of neurons tested, but were observed in only 60% of neurons following cochlea removal. The maximum EPSP amplitude was significantly smaller in manipulated neurons compared with controls, and this was accompanied by a higher incidence of ipsilaterally evoked inhibitory postsynaptic potentials (IPSPs). To study the efficacy of excitatory synapses in greater detail, voltage-clamp recordings were made in the presence of strychnine and AP-5 [d(O)-2-amino-5-phosphonopentanoic acid]. The minimum excitatory postsynaptic current (EPSC) amplitude, presumed to reflect the efficacy of a single glutamatergic afferent, was ～40% smaller in manipulated neurons. In contrast, MNTB-evoked IPSPs were similar in neurons from control and ablated animals. However, manipulated neurons often exhibited a rebound depolarization after a hyperpolarizing current pulse or an afferent-evoked IPSP. In 70% of manipulated neurons, synaptically evoked rebound depolarizations were reduced, but not eliminated, by glutamate receptor antagonists. The glycine receptor antagonist strychnine did eliminate the IPSP-associated depolarization in these neurons. Collectively, these results suggest that functional denervation of excitatory afferents decreases their synaptic efficacy as result of both cell loss as well as decreased strength of individual surviving synapses.     

Correlation of electrophysiology,shape and synaptic properties of myenteric AH neurons of the guinea pig distal colon

Well-defined correlations between morphology, electrophysiological properties and the types of synaptic inputs received are established for myenteric neurons in the guinea pig ileum. However, in the distal colon, the correlations between AH electrophysiological properties, presence of fast excitatory post-synaptic potentials (EPSPs) and neuronal shape have been inadequately resolved and it is unknown whether any colon neurons receive synaptic inputs that generate sustained excitation. In this work, we have used intracellular recording, dye filling via the recording electrode, and immunohistochemistry to classify distal colon neurons. Neurons (24 of 168) had Dogiel type II morphology and 42% of these were dendritic type II neurons, compared to about 10% in the ileum. All Dogiel type II neurons had AH electrophysiological properties, including a prolonged post-spike after-hyperpolarization (AHP). None of these received fast excitatory post-synaptic potentials, 11 of 22 tested exhibited sustained slow post-synaptic excitation (SSPE) in response to 1 Hz pre-synaptic stimulation and 13 of 15 tested were immunoreactive for calbindin. Neurons (127) had Dogiel type I, filamentous or other uniaxonal cell shape and S type electrophysiology. Neurons of this group had fast excitatory post-synaptic responses to stimulation of synaptic inputs, but did not exhibit a prolonged post-spike after-hyperpolarization or sustained slow post-synaptic excitation. Another group of neurons (17) had both AH electrophysiological characteristics and fast excitatory post-synaptic potentials. These neurons had Dogiel type I, filamentous or other uniaxonal shapes, but none had Dogiel type II morphology and none showed sustained slow post-synaptic excitation. It is concluded that Dogiel type II neurons are all AH neurons and are probably intrinsic sensory neurons that could be involved in long-term changes in excitability in the colon. All other neurons are monoaxonal; these are motor neurons and interneurons, and most are S neurons, electrophysiologically. A small number of monoaxonal neurons display AH electrophysiology and also receive fast excitatory synaptic inputs. These include motor and interneurons, but not sensory neurons.     

Selective Functional Interactions between Excitatory and Inhibitory Cortical Neurons and Differential Contribution to Persistent Activity of the Slow Oscillation

The neocortex depends upon a relative balance of recurrent excitation and inhibition for its operation. During spontaneous Up states, cortical pyramidal cells receive proportional barrages of excitatory and inhibitory synaptic potentials. Many of these synaptic potentials arise from the activity of nearby neurons, although the identity of these cells is relatively unknown, especially for those underlying the generation of inhibitory synaptic events. To address these fundamental questions, we developed an in vitro submerged slice preparation of the mouse entorhinal cortex that generates robust and regular spontaneous recurrent network activity in the form of the slow oscillation. By performing whole-cell recordings from multiple cell types identified with green fluorescent protein expression and electrophysiological and/or morphological properties, we show that distinct functional subpopulations of neurons exist in the entorhinal cortex, with large variations in contribution to the generation of balanced excitation and inhibition during the slow oscillation. The most active neurons during the slow oscillation are excitatory pyramidal and inhibitory fast spiking interneurons, receiving robust barrages of both excitatory and inhibitory synaptic potentials. Weak action potential activity was observed in stellate excitatory neurons and somatostatin-containing interneurons. In contrast, interneurons containing neuropeptide Y, vasoactive intestinal peptide, or the 5-hydroxytryptamine (serotonin) 3a receptor, were silent. Our data demonstrate remarkable functional specificity in the interactions between different excitatory and inhibitory cortical neuronal subtypes, and suggest that it is the large recurrent interaction between pyramidal neurons and fast spiking interneurons that is responsible for the generation of persistent activity that characterizes the depolarized states of the cortex.     

Intrinsic and synaptic properties of the dorsomedial nucleus of the intercollicular complex,an area known to be involved in distance call production in Bengalese finches

The dorsomedial nucleus of the intercollicular complex (DM) of the midbrain in the Bengalese finch is essential for the vocal production of distance calls that have sexually-dimorphic acoustic structures in the adult. Anatomical tracing of the vocal control system shows that DM neurons of adult males receive axonal inputs from the robust nucleus of the archistriatum (RA), and the inputs are considered to be crucial for the male-typical features of distance calls. In order to investigate the neural mechanisms underlying distance call patterns of male finches in DM, we characterized neurons in DM and examined their synaptic responses to RA inputs in brain slice preparations. By using whole-cell recording techniques, we could classify at least three types of neurons based on electrophysiological and morphological characteristics. Type I neurons exhibited regular and high-frequency trains of action potentials in response to depolarizing current pulses. Type II neurons had large somata and action potential trains accommodating during depolarization. Type III neurons were characterized by a few spikes followed by a slow depolarization during current injection. Their somata were markedly small and their axons often projected toward the contralateral DM or the thalamic nucleus uvaeformis (Uva). In all these cell types, electrical stimulation of an area including DM-projecting RA axons often elicited both excitatory postsynaptic currents (EPSCs) mediated mainly by non-NMDA glutamate receptors and inhibitory postsynaptic currents (IPSCs) mediated by GABA(A) receptors. These intrinsic properties of DM neurons and their excitatory and inhibitory synaptic inputs may play important roles in generating the acoustic patterns of distance calls in male finches.     

Two differential frequency-dependent mechanisms regulating tonic firing of thalamic reticular neurons

Transmission through the thalamus activates circuits involving the GABAergic neurons of the thalamic reticular nucleus (TRN). TRN cells receive excitatory inputs from thalamocortical and corticothalamic cells and send inhibitory projections to thalamocortical cells. The inhibitory output of TRN neurons largely depends on the level of excitatory drive to these cells but may also be partly under the control of mechanisms intrinsic to the TRN. We examined two such possible mechanisms, short-term plasticity at glutamatergic synapses in the TRN and intra-TRN inhibition. In rat brain slices, responses of TRN neurons to brief trains of stimuli applied to glutamatergic inputs were recorded in voltage- or current-clamp mode. In voltage clamp, TRN cells showed no change in α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) receptor-mediated excitatory postsynaptic current amplitudes to stimulation at non-gamma frequencies (< 30 Hz), simulating background activity, but exhibited short-term depression in these amplitudes to stimulation at gamma frequencies (> 30 Hz), simulating sensory transmission. In current clamp, TRN cells increased their spike outputs in burst and tonic firing modes to increasing stimulus-train frequencies. These increases in spike output were most likely due to temporal summation of excitatory postsynaptic potentials. However, the frequency-dependent increase in tonic firing was attenuated at gamma stimulus frequencies, indicating that the synaptic depression selectively observed in this frequency range acts to suppress TRN cell output. In contrast, intra-TRN inhibition reduced spike output selectively at non-gamma stimulus frequencies. Thus, our data indicate that two intrinsic mechanisms play a role in controlling the tonic spike output of TRN neurons and these mechanisms are differentially related to two physiologically meaningful stimulus frequency ranges.     

Interplay of excitation and inhibition elicited by tonal stimulation in pyramidal neurons of primary auditory cortex

Tonal responses of neurons in the primary auditory cortex are a function of frequency, intensity and ear of stimulation. These responses occasionally display suppression. This review discusses how excitatory and inhibitory synaptic inputs interact to form suppressive responses and how changes in stimulus attributes affect the magnitude and timing of those responses.Stimulation at the characteristic frequency evokes a stereotyped sequence of depolarization (excitatory) and then hyperpolarization (inhibitory), as predicted from the canonical circuitry. Some neurons stimulated at higher sound intensities display a prominent increase in the magnitude of hyperpolarization or a decrease in its latency, both enabling counteraction with the preceding excitation. These interactions, in part, underlie the non-monotonic suppression. Furthermore, monaural non-dominant ear stimulation elicits such a powerful hyperpolarization as to cancel out the depolarization elicited at dominant ear stimulation, suggesting a linear mechanism for the binaural suppression. Alternatively, it elicits a depolarization almost equal in magnitude and time course to that elicited at binaural stimulation, suggesting a nonlinear interaction responsible for the suppression. Laminar differences are also noted for these inhibitory interactions.     

The cortically evoked secondary depolarization affects the integrative properties of thalamic reticular neurons

Corticothalamic terminals on thalamic reticular (RE) neurons account for most synapses from afferent pathways onto this nucleus and these inputs are more powerful than those from axon collaterals of thalamocortical neurons. Given the supremacy of cortical inputs, we analysed here the characteristics and possible mechanisms underlying a secondary component of the cortically elicited depolarization in RE neurons, recorded in cats under barbiturate anesthesia. Electrical stimulation of corticothalamic axons in the internal capsule evoked fixed and short-latency excitatory postsynaptic potentials (EPSPs) that, by increasing stimulation intensity and at hyperpolarized levels (< -70 mV), developed into low-threshold spikes and spindle oscillations. The threshold for spindle oscillations was 60% higher than that required for evoking minimal EPSPs. The evoked EPSPs included a secondary depolarizing component, which appeared approximately 5 ms after the peak of the initial component and was voltage dependent, i.e. most prominent between -70 mV and -85 mV, while being greatly reduced or absent at more hyperpolarized levels. The secondary depolarizing component was sensitive to QX-314 in the recording micropipette. We suggest that the secondary component of cortically evoked EPSPs in RE neurons is due to the dendritic activation of T-currents, with a probable contribution of the persistent Na+ current. This late component affected the integrative properties of RE neurons, including their spiking output and temporal summation of incoming cortical inputs.     

Long-term Potentiation in the Striatum is Unmasked by Removing the Voltage-dependent Magnesium Block of NMDA Receptor Channels

We have studied the effects of tetanic stimulation of the corticostriatal pathway on the amplitude of striatal excitatory synaptic potentials. Recordings were obtained from a corticostriatal slice preparation by utilizing both extracellular and intracellular techniques. Under the control condition (1.2 mM external Mg2+), excitatory postsynaptic potentials (EPSPs) evoked by cortical stimulation were reversibly blocked by 10 microM 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), an antagonist of dl-alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) ionotropic glutamate receptors, while they were not affected by 30 - 50 microM 2-amino-5-phosphonovalerate (APV), an antagonist of N-methyl-d-aspartate (NMDA) glutamate receptors. In the presence of 1.2 mM external Mg2+, tetanic activation of cortical inputs produced long-term depression (LTD) of both extracellularly and intracellularly recorded synaptic potentials. When Mg2+ was removed from the external medium, EPSP amplitude and duration increased. In Mg2+-free medium, cortically evoked EPSPs revealed an APV-sensitive component; in this condition tetanic stimulation produced long-term potentiation (LTP) of synaptic transmission. Incubation of the slices in 30 - 50 microM APV blocked striatal LTP, while it did not affect LTD. In Mg2+-free medium, incubation of the slices in 10 microM CNQX did not block the expression of striatal LTP. Intrinsic membrane properties (membrane potential, input resistance and firing pattern) of striatal neurons were altered neither by tetanic stimuli inducing LTD and LTP, nor by removal of Mg2+ from the external medium. These findings show that repetitive activation of cortical inputs can induce long-term changes of synaptic transmission in the striatum. Under control conditions NMDA receptor channels are inactivated by the voltage-dependent Mg2+ block and repetitive cortical stimulation induces LTD which does not require activation of NMDA channels. Removal of external Mg2+ deinactivates these channels and reveals a component of the EPSP which is potentiated by repetitive activation. Since the striatum has been involved in memory and in the storage of motor skills, LTD and LTP of synaptic transmission in this structure may provide the cellular substrate for motor learning and underlie the physiopathology of some movement disorders.     

Adenosine A1 antagonism increases specific synaptic forms of glutamate release during anoxia,revealing a unique source of excitation

The role of the adenosine A₁ receptor in the modulation of anoxia-induced synaptic glutamate release was examined in CA1 pyramidal neurons by whole-cell voltage-clamp recording in the rat hippocampal slice preparation. Anoxia leads to an increased action potential-independent synaptic glutamate release in the form of a higher frequency of miniature excitatory postsynaptic currents (mEPSCs). This increase is not significantly affected when slices are preincubated in the adenosine A₁ receptor antagonist, 8-cyclopentyl-1, 3-dipropylxanthine (DPCPX). A second population of spontaneous inward currents, however, occurs in DPCPX-treated slices during a well-defined period following the onset of anoxia. Their suppression by glutamate antagonists, tetrodotoxin, or by the cutting of the Schaffer collateral pathway indicates that they represent action potential-dependent, glutamatergic excitatory postsynaptic currents (ap-EPSCs) originating from CA3 pyramidal neurons. CA3 neurons were examined in current-clamp whole-cell patch mode to determine the origin of this increased orthodromic excitation. After the onset of anoxia, CA3 cells initially exhibit a small depolarization or hyperpolarization associated with a decrease in input resistance. This is followed by transient depolarization (the depolarizing “nub”), which is associated with an increase in input resistance. The nub evoked single as well as bursts of action potentials in CA3 neurons. The occurrence of these CA3 nub-elicited action potentials coincides with that of ap-EPSCs recorded in the CA1 cells. Recording with cesium- rather than standard potassium-containing electrodes results in the suppression of the nub and its associated increase in input resistance. In conclusion we have shown that adenosine tone plays an important role in suppressing anoxia-induced spontaneous ap-EPSCs but not action potential-independent mEPSCs in CA1 neurons. These EPSCs originate from a depolarization in CA3 pyramidal neurons, which is associated with an increase in resistance. This previously undescribed phenomenon likely results from a decrease in the conductance of an unidentified potassium channel. © 1996 Wiley-Liss, Inc.     

Mutual Re-excitation with Post-Inhibitory Rebound: A Simulation Study on the Mechanisms for Locomotor Rhythm Generation in the Spinal Cord of Xenopus Embryos

We have used computer simulations as one way to test the hypothesis that locomotor rhythm production for swimming in frog embryo spinal cord depends on rebound from inhibition and is sustained by mutual re-excitation among spinal excitatory interneurons. All simulations were based on physiological and anatomical data on the neurons and circuitry of Xenopus embryo spinal cord. Model 'neurons' had resistively coupled axon, soma, and dendrite compartments. Membrane properties were based on Hodgkin - Huxley equations with resting potential at - 75 mV and where soma and dendrite had reduced K+ and Na+ conductance and slowed K+ conductance. These 'neurons' fired a single non-overshooting spike both to depolarizing current and after hyperpolarizing current given during imposed depolarization. Synapses were made on to the dendrite. Inhibitory and excitatory synaptic channels had Nernst potentials of - 80 and 0 mV, time constants for opening of 1 ms, and closing of 6 and 75 ms. When the short inhibitory postsynaptic potential occurred on the long (N-methyl-D-aspartate-type) excitatory postsynaptic potential, it led to rebound firing. A four 'neuron' symmetrical network was built with reciprocal inhibition and where excitatory 'neurons' re-excited themselves and the inhibitory 'neuron' on their own side. The rhythmic alternating activity with one spike per cycle produced reliably by this network was self-sustaining, initiated by a brief synaptic input, and closely resembled the spinal cord motor pattern during swimming. The robustness of this activity pattern was investigated by varying cellular and synaptic parameters, initiating inputs, and network connectivity. We conclude that cellular, synaptic, and network properties are all important and that mutual re-excitation, a form of positive feedback, could sustain motor rhythm production in the Xenopus embryo spinal cord.     

Ethanol alters synaptic activity in cultured spinal cord neurons

The acute effects of ethyl alcohol on mammalian central neurons were investigated using electrophysiological techniques and an in vitro model system, cultured fetal mouse spinal cord neurons. Intracellular recordings were made from the cultured neurons to evaluate the effect of alcohol (10-100 mM) on membrane potential, membrane permeability, amplitude of the action potential, sensitivity of the neurons to putative neurotransmitters and the process of synaptic transmission. Alcohol was applied by superfusion; putative amino acid neurotransmitters were applied by micropressure ejection. The most dramatic effect of alcohol on the spinal cord neurons was a reduction in the spontaneous activity (excitatory and inhibitory synaptic potentials and action potentials) and the glutamate evoked synaptic activity. Alcohol doses as low as 20-30 mM, concentrations which reflect blood levels during intoxication, were effective. Membrane potential, membrane permeability, and amplitude of the action potential were relatively resistant to these low doses of alcohol; at the higher alcohol doses, no effect or only modest alterations of these characteristics were observed. The responses of the neurons to the putative excitatory neuro-transmitter glutamate, and inhibitory transmitters GABA and glycine were also relatively resistant to alcohol exposure. These data indicate that acute exposure to alcohol has a predominantly inhibitory action on the activity of the cultured mammalian CNS neurons, and that this inhibition is most likely due to an alteration in the process of synaptic transmission.