Assessment of the Reliability of Amplitude Histograms for Inhibitory Synaptic Currents in Rat Cortex Culture

We analyzed in detail the quantum parameters of evoked inhibitory postsynaptic currents (eIPSC) recorded from synaptically connected cultured cortex neurons using a whole-cell patch-clamp technique. The IPSC were evoked using minimum extracellular stimulation of a presynaptic unit with a frequency of 0.2 sec^-1 at the holding potential of -80 mV. Amplitude histograms for eIPSC demonstrated clearly detectable equally spaced peaks. For each histogram, we used a method based on autocorrelation analysis and Monte Carlo simulation to determine whether peaks in the amplitude histograms can result due to finite sampling from the sum of the Gaussian distributions. The autocorrelation function allowed us to measure the peak spacing (and, hence, the mean quantum size) for each histogram; this parameter was found to be 10 pA.     

Quantum Properties of GABA Release in Cultured Neurons from the Rat Cortex

We analyzed the properties of inhibitory synaptic transmission between neurons in low-density cultures of cortical cells. Miniature, spontaneous, and evoked inhibitory postsynaptic currents were studied using a whole-cell path-clamp technique at a holding potential of -80 mV. These postsynaptic currents were identified as GABA release-activated Cl^- currents mediated by GABA_A receptors. Fitting amplitude histograms of these currents with Gaussian curves and an autocorrelation technique revealed the presence of equidistant peaks corresponding to a mean quantum size of 10 pA.     

Potassium channel blocker-induced presynaptic modulation of inhibitory synaptic transmission in hippocampal neurons of rats

The effects of blockers of voltage-gated potassium channels, tetraethylammonium (TEA) and 4-aminopyridine (4-AP), on inhibitory postsynaptic currents (IPSC) evoked by local electrical stimulation of zones of unitary synaptic terminals on hippocampal neurons were studied using a voltage-clamp technique under conditions of low density cell culture. At activation of the transmitter release in the absence of action potentials (when the terminals are in a tetrodotoxin-containing medium), external application of 5 mM 4-AP reversibly increased the averaged IPSC amplitude by 90±30%, while a similar effect of 10 mM TEA reached only 20±7%. The amplitudes of individual evoked IPSC varied between 10 and more than 150 pA. Amplitude histograms of IPSC in all studied neurons (n=14) were of a polymodal nature and could not described by a Gaussian law. An increase in the averaged IPSC amplitude under the influence of potassium channel blockers cannot be described as resulting only from modification of the number of trials without transmitter release (blank events). The mechanism of potassium channel blocker-induced facilitation of IPSC evoked by single synaptic terminals is discussed.     

Urethane inhibits the GABAergic neurotransmission in the nucleus of the solitary tract of rat brain stem slices

Because urethane is a widely used anesthetic in animal experimentation, in the present study, we evaluated its effects on neurons of the nucleus of the solitary tract (NTS) in brain stem slices from young rats (25-30 days old). Using the whole cell configuration of the patch-clamp technique, spontaneous postsynaptic currents (sPSCs) and evoked excitatory postsynaptic currents (eEPSCs) were recorded. Urethane (20 mM) decreased by approximately 60% the frequency of GABAergic sPSCs (1.0 +/- 0.2 vs. 0.4 +/- 0.1 Hz) but did not change the frequency, amplitude, or half-width of glutamatergic events or TTX-resistant inhibitory sPSCs [miniature inhibitory postsynaptic currents (IPSCs)]. Miniature IPSCs were measured in the presence of urethane plus 1 mM diazepam (1 mM), and no changes were seen in their amplitude. This suggests that the GABA concentration in the NTS synapses is set at saturating level. We also evaluated the effect of urethane on eEPSCs, and no significant change was observed in the amplitude of N-methyl-d-aspartate [NMDA; 44.2 +/- 11.5 vs. 37.6 +/- 10.6 pA (holding potential = 40 mV)] and non-NMDA currents [204.4 +/- 35.5 vs. 196.6 +/- 31.2 pA (holding potential = -70 mV)]. Current-clamp experiments showed that urethane did not alter the action potential characteristics and passive membrane properties. These data suggest that urethane has an inhibitory effect on GABAergic neurons in the NTS but does not change the spontaneous or evoked excitatory responses.     

Postsynaptic Currents in Dorsal Root Ganglion Neurons Co-cultured with Spinal Cord Neurons

In co-cultured dorsal root ganglion (DRG) neurons and spinal cord neurons from newborn rats, using a voltage-clamp technique in the whole-cell configuration enabled us to observe in DRG neurons the effects evoked by extracellular local electrical stimulation of cells corresponding to spinal cord neurons in their morphological characteristics. Such stimulation caused the appearance of postsynaptic currents (PSC) in DRG neurons in 9% of the cases. The mean delay of these currents (measured from the stimulus leading edge) was 4.7 ± 0.29 msec, the mean time to peak was 2.6 ± 0.77 msec, and the decay time constant = 14.5 ± 1.04 msec. The reversal potential of evoked PSC (ePSC) was close to the equilibrium potential for chloride ions estimated by the Nernst equation. Application of 20 M bicuculline induced practically complete and reversible ePSC block. The conclusion was drawn that these currents arise due to activation of the chloride channels operated by GABA receptors and, hence, represent an inhibitory PSC. Thus, one may deem it proved that spinal cord neurons can establish functional inhibitory synapses with DRG neurons.     

Analysis of excitatory and inhibitory components of postsynaptic currents recorded in the pyramidal neurons and interneurons of the rat hippocampus

Postsynaptic currents recorded in the whole-cell configuration with patch-clamp method are actually the sum ofexcitatory (EPSC) and inhibitory (IPSC) components. An approach has been developed allowing the quantitative evaluation of the amplitude and the time course of EPSC and IPSC without treatment of the brain slice with pharmacological inhibitors. The approach is based on the substantial difference in the equilibrium potential values of incoming cationic and anionic currents as the existence of linear regions of corrent-voltage dependence of these currents. The comparison of the results obtained with the classical pharmacological method and with the suggested one demonstrated their coincidence. It allows analysing the postsynaptic currents in sigle neurons without altering the synaptic transmission in the whole brain slice. The contribution of inhibitory currents in the composite synaptic response of intemeurons turned out to be smaller in comparison with pyramidal neurons of CA1 field of the rat hippocampus.     

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.     

Presence of depolarization-induced suppression of inhibition in a fraction of gabaergic synaptic connections in rat neocortical cultures

Brief depolarization of postsynaptic neurons in hippocampus and cerebellum results in a transient depression of GABAergic inhibitory input, called "depolarization-induced suppression of inhibition" (DSI). We studied whether a similar phenomenon occurs in the rat neocortical neurons. Using patch-clamp technique in neocortical cell cultures we examined the effects of a 5-second depolarization of postsynaptic neurons on evoked GABAergic inhibitory post-synaptic currents (IPSCs). We found that the depolarization evoked a suppression of IPSC amplitude in 6 out of 26 neuronal pairs tested. The suppression of IPSC amplitude lasted for approximately 70 seconds and was accompanied by changes of paired-pulse ratio and IPSC coefficient of variation (CV), which is suggestive of a presynaptic mechanism. These results are in agreement with previous observations in hippocampal cell cultures and suggest that neocortical neurons express DSI.     

可视膜片钳法记录初级传入纤维介导的脊髓背角神经元突触后电流

本文描述了用明胶半包埋法制备带背根脊髓薄片的实验步骤,和在脊髓背角记录由初级传入纤维介导的突触后电流的可视膜片钳法。手术制备一段带背根的脊髓标本,并用20％的明胶包埋在琼脂块上,再用振动切片机切片获得带背根的脊髓薄片。通过红外线可视的引导,在脊髓背角神经元上建立全细胞封接模式。在钳制电压为-70mV条件下,记录自发的和背根刺激引起的兴奋性突触后电流。以传入纤维的传导速度与刺激阈值为指标,可以区分A样纤维与C样纤维兴奋性突触后电流。在钳制电压为0mV条件下,记录自发的和背根刺激引起的抑制性突触后电流。用5μmol／L的士宁或20μmol／L的荷包牡丹碱分离出γ-氨基丁酸能或甘氨酸能的抑制性突触后电流。用可视膜片钳方法可以准确测量脊髓背角神经元的突触后电流,从而研究初级传入突触的传递过程。更重要的是,在红外线可视观察的帮助下,建立膜片钳封接的成功率显著提高,同时也使记录研究脊髓背角深层神经元变得更加容易。本研究为探索初级传入突触传递过程提供了一个有效的方法。     

Sodium channels in cultured chick dorsal root ganglion neurons

Isolated Na currents were studied in cultured chick sensory neurons using the patch clamp technique. On membrane depolarization, whole cell currents showed the typical transient and voltage-dependent time course as in nerve fibres. Na currents appeared at about-40 mV and reached maximum amplitude at around-10 mV. At low voltages (-30 to 0 mV), their turning-on was sigmoidal and inactivation developed exponentially. The ratio of inactivation time constants was found to be smaller than in squid axons and comparable to that of mammalian nodes of Ranvier. Peak conductance and steady-state inactivation were strongly voltage-dependent, with maximum slopes at-17 and-40 mV, respectively. The reversal potential was close to the Nernst equilibrium potential, indicating a high degree of ion-selectivity for the channel. Addition of 3M TTX, or replacement of Na by Choline in the external bath, abolished these currents. Internal pronase (1 mg/ml) and N-bromoacetamide (0.4 mM) made inactivation incomplete, with little effect on its rate of decay.Single Na channel currents were studied in outside-out membrane patches, at potentials between-50 and-20 mV. Their activation required large negative holding potentials (-90 mV). They were fully blocked by addition of TTX (3 M) to the external bath. At-40 mV their mean open time was about 2ms and the amplitude distribution could be fitted by a single Gaussian curve, indicating the presence of a homogeneous population of channels with a conductance of 11±2 pS. Probability of opening increased and latency to first opening decreased with increasing depolarization. Inactivation of the channel became faster with stronger depolarizations, as measured from the inactivation time course of sample averages. Internal pronase (0.1 mg/ml) produced effects on inactivation comparable to those on whole cell currents. Openings of the channel had a tendency to occur in bursts and showed little inactivation during pulses of 250 ms duration. The open lifetime of the channel at low potentials (-50,-40 mV) was only three times larger than in control patches, suggesting that Na channels in chick sensory neurons can close several times before entering an inactivating absorbing state.     

Phorbol esters that activate protein kinase C induce long-term changes of membrane excitability and postsynaptic currents in neocortical neurons

Intracellularly injected tumor promoter phorbol esters (PhEs) that activate protein kinase C (PKC) increased the excitability and altered the postsynaptic responses of neurons of the motor cortex of awake cats. PhEs increased the amplitude and duration of EPSPs and decreased the amplitude and durations of IPSPs. No consistent changes in resting membrane parameters that would account for these modifications were found. Corresponding changes in peak excitatory and inhibitory postsynaptic currents (EPSCs, IPSCs) were measured directly with the single electrode voltage clamp technique. The changes lasted for 50 min or longer. Quantitative analysis of EPSCs in response to ventrolateral thalamic stimulation and IPSCs in response to pyramidal tract stimulation made in a subgroup of fast PT cells suggested that PhE acted within the injected neuron rather than presynaptically to alter the synaptic currents. PhE also reduced a voltage-dependent, 3-aminopyridine sensitive fast outward current (IA) and an apamin and EGTA sensitive slow outward current (IK(Ca]. Control injections of a phorbol ester that did not activate PKC failed to induce changes in synaptic responses or resting membrane properties. These observations provide the first evidence that activation of PKC, in vivo, can induce long-lasting changes in synaptic responses of neocortical neurons by direct modification of postsynaptic ion channel conductivities.     

Single- and multi-channel currents recorded with patch electrodes in mouse eggs

Zona-free mouse eggs are amenable to patch recording as well as to whole-cell recording (Bland et al., 1984; Peres, 1986a). Although many patches are silent, others show spontaneous channel opening; the single channel current is 1.5 pA and inwardly directed at resting potential (RP). Current amplitudes distribute normally as a single population at RP, however at RP-50 mV the amplitude histogram indicates two channel populations. Open time distribution is exponential with a mean open time between 4 and 7 msec at RP. In three cases out of thirty-eight, in which depolarizations were given from a holding potential of RP-50 mV, microscopic currents very similar in kinetics and voltage-dependence to the whole-cell Ca2+ current were observed. No single-channel currents could be resolved in these traces. The results reported here indicate that the voltage-dependent Ca2+ current of the mouse egg goes through low-conductance channels located in high density spots on the egg surface.     

The inhibitory chloride channel of the lobster Panulirus penicillatus neuromuscular junction.

1. Single channel activity was recorded from muscle membranes of the lobster Panulirus penicillatus using the patch-clamp technique. 2. Cell-attached, outside-out and inside-out patches were prepared from the deep abdominal extensor muscle. 3. Low amplitude single channel currents were observed in most patches, and were identified as being chloride-currents. 4. The chloride channel was active spontaneously, and tended to desensitize when outside-out patches were exposed to a small jet of glutamate. 5. Amplitude histograms of single channel currents presented a well defined peak of 8 pA at a membrane potential of -160 mV, while open and closed time histograms were fit to single exponential functions with tau open of 3.27 msec and tau closed of 31.58 msec.     

Pharmacological and biophysical isolation of K+ currents encoded by ether-a-go-go-related genes in murine hepatic portal vein smooth muscle cells

Previous studies have shown that murine portal vein myocytes express ether-à-go-go related genes (ERGs) and exhibit distinctive currents when recorded under symmetrical K⁺ conditions. The aim of the present study was to characterize ERG channel currents evoked from a negative holding potential under conditions more pertinent to a physiological scenario to assess the possible functional impact of this conductance. Currents were recorded with ruptured or perforated patch variants of the whole cell technique from a holding potential of –60 mV. Application of three structurally distinct and selective ERG channel blockers, E-4031, dofetilide, and the peptide toxin BeKM-1, all inhibited a significant proportion of the outward current and abolished inward currents with distinctive "hooked" kinetics recorded on repolarization. Dofetilide-sensitive currents at negative potentials evoked by depolarization to +40 mV had a voltage-dependent time to peak and rate of decay characteristic of ERG channels. Application of the novel ERG channel activator PD-118057 (1–10 µM) markedly enhanced the hooked inward currents evoked by membrane depolarization and hyperpolarized the resting membrane potential recorded by current clamp and the perforated patch configuration by 20 mV. In contrast, ERG channel blockade by dofetilide (1 µM) depolarized the resting membrane potential by 8 mV. These data are the first record of ERG channel currents in smooth muscle cells under quasi-physiological conditions that suggest that ERG channels contribute to the resting membrane potential in these cells. vascular smooth muscle; voltage-dependent K⁺ current; membrane excitability     

Effect of Latrotoxin-Like Protein on Spontaneous Postsynaptic Activity in Hippocampal Cell Cultures

-Latrotoxin, an active component of black widow spider venom, is known to enhance spontaneous neurotransmitter release. In cultured rat hippocampal neurons, we studied the effects of latrotoxin-like protein (protein purified from the bovine brain and exhibiting some functional properties similar to those of -latrotoxin) on spontaneous GABA-ergic inhibitory currents (IPSC). Latrotoxin-like protein was found to dramatically increase the frequency of spontaneous IPSC recorded in cell cultures of dissociated hippocampal neurons in the presence of tetrodotoxin. Possible mechanisms of the action of latrotoxin-like protein on transmitter release are discussed.     

Voltage- and calcium-activated currents in cultured olfactory receptor neurons of male Mamestra brassicae (Lepidoptera)

Insect olfactory receptor neurons (ORNs) grown in primary cultures were studied using the patch-clamp technique in both conventional and amphotericin B perforated whole-cell configurations under voltage-clamp conditions. After 10-24 days in vitro, ORNs had a mean resting potential of -62 mV and an average input resistance of 3.2 GOmega. Five different voltage-dependent ionic currents were isolated: one Na(+), one Ca(2+) and three K(+) currents. The Na(+) current (35-300 pA) activated between -50 and -30 mV and was sensitive to 1 microM tetrodotoxin (TTX). The sustained Ca(2+) current activated between -30 and -20 mV, reached a maximum amplitude at 0 mV (-4.5 +/- 6.0 pA) that increased when Ba(2+) was added to the bath and was blocked by 1 mM Co(2+). Total outward currents were composed of three K(+) currents: a Ca(2+)-activated K(+) current activated between -40 and -30 mV and reached a maximum amplitude at +40 mV (605 +/- 351 pA); a delayed-rectifier K(+) current activated between -30 and -10 mV, had a mean amplitude of 111 +/- 67 pA at +60 mV and was inhibited by 20 mM tetraethylammonium (TEA); and, finally, more than half of ORNs exhibited an A-like current strongly dependent on the holding potential and inhibited by 5 mM 4-aminopyridine (4-AP). Pheromone stimulation evoked inward current as measured by single channel recordings.     

Synaptic processes in pericruciate cortical neurons evoked by pyramidal tract stimulation in cats

In cats anesthetized with chloralose and pentobarbital and immobilized with D-tubocurarine activity of 423 pericruciate cortical neurons was recorded (342 extra- and 81 intracellularly); 78 neurons had spontaneous activity. Stimulation of the pyramidal tract evoked antidromic action potentials in the pyramidal neurons with a latent period of 0.5–16.0 msec. Recurrent and lateral PSPs also developed both in pyramidal and in unidentified neurons in all layers of the cortex; IPSPs were recorded in 46.7% of neurons, EPSPs in 21.0%, mixed reponses in 26.0%, and no visible changes were found in 6.3%. The latent period of the IPSPs was 1.5–14.0 msec, their amplitude 1.3–17.0 mV, their rise time from 4 to 18 msec, and their duration 18–120 msec (sometimes up to 250–500 msec). In 30% of cases in which IPSPs appeared, their course was divided into two phases: fast (duration 10–20 msec) and slow. EPSPs developed after a latent period of 2.6–29.0 msec; their amplitude was 1.0–7.8 mV and their duration from 10.0 to 50.0 msec. In 51.2% of spontaneously active neurons the antidromic volley inhibited their activity in the course of 200–400 msec, in 19.5% it stimulated their activity, in 7.4% it had a mixed effect, and in 21.9% no visible change took place in their activity. The role and participation of axon collaterals of pyramidal neurons and of the interneuronal system in the formation of these processes are discussed.     

Voltage-dependent Conductance Changes in a Nonvoltage-activated Sodium Current from a Mast Cell Line

Nonexcitable cells do not express voltage-activated Na⁺ channels. Instead, selective Na⁺ influx is accomplished through GTP-activated Na⁺ channels, the best characterized of which are found in renal epithelia. We have described recently a GTP-dependent Na⁺ current in rat basophilic leukemia (RBL) cells that differs from previous reported Na⁺ channels in several ways including selectivity, pharmacology and mechanism of activation. In this report, we have investigated the biophysical properties of the RBL cell Na⁺ current using the whole cell patch-clamp technique. Following activation by 250–500 μm GTPγS, hyperpolarizing steps to a fixed potential (−100 mV) from a holding potential of 0 mV evoked transient inward Na⁺ currents that declined during the pulse. If the holding potential was made more positive (range 0 to +100 mV), then the amplitude of the transient inward current evoked by the hyperpolarization increased steeply, demonstrating that the conductance of the channels was voltage-dependent. Using a paired pulse protocol (500 msec pulses to −100 mV from a holding potential of 0 mV), it was found that the peak amplitude of the current during the second pulse became larger as the interpulse potential became more positive. In addition, increasing the time at which the cells were held at positive potentials also resulted in larger currents, indicating a time-dependent conductance change. With symmetrical Na⁺ solutions, outward currents were recorded at positive potentials and these demonstrated both a time- and voltage-dependent increase in conductance. The results show that a nonvoltage activated Na⁺ channel in an electrically nonexcitable cell undergoes prominent voltage-dependent transitions. Possible mechanisms underlying this voltage dependency are discussed. Received: 12 March 1998/Revised: 5 June 1998     

Postsynaptic potentials of neurons of the cat auditory cortex

The electrical reactions of 294 neurons of the auditory cortex to a click were recorded in experiments on cats immobilized with tubocurarine (174 intra- and 120 extracellularly). The value of the membrane potential varied from 30 to 70 mV with intracellular leads. The following types of reactions were obtained (the number of neurons is given in parentheses): a peak without slow oscillations in the membrane potential (4), EPSP (3), EPSP-peak (6), EPSP-peak-IPSP (17), EPSP-IPSP (9), primary IPSP (114, including 23 with an after-discharge). Twenty one neurons did not react to a click. The amplitude of the sub-threshold EPSP was 1–1.5 mV, the duration of the ascending part was about 10 and of the descending part 20–30 msec. The peak potential on the ascending part of the EPSP developed at the critical level of 3–4 mV. The amplitude of the peaks varied from several millivolts to 50–60. In 17 neurons prolonged hyperpolarization having all the properties of an IPSP, developed after the peak. The amplitude of these IPSP varied in different neurons from 1 to 10 mV and the duration varied from 20 to 80 msec. IPSP without preceding excitation of the given neuron were the predominant types of reaction. The latent period of these primary IPSP varied from 7 to 20 msec and the amplitude from 1 to 15 msec with a duration of 30–200, more frequently 80–100 msec. It is suggested that two types of inhibition develop in neurons of the auditory cortex in response to a click: recurrent and afferent. The functional significance of the first consists in limiting the duration of the discharge in the reacting neurons, the second prevents the development of excitation in adjacent neurons, thereby limiting the area of neuronal activity.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSSR, Kiev. Translated from Neirofiziologiya, Vol. 3, No. 4, pp. 339–349, July–August, 1971.