SUMMARY1. The mechanisms involved in the lability of inhibition at higher frequencies of stimulation were investigated in the guinea-pig in vitro neocortical slice preparation by intracellular recording techniques. We attempted to test the possibility of a feedback depression of GABA on subsequent release.2. At resting membrane potential (Em, -75-8 + 5-2 mV) stimulation of either the pial surface or subcortical white matter evoked a sequence of depolarizing and hyperpolarizing synaptic components in most neurones. An early hyperpolarizing component (IPSPA) was usually only obvious as a pronounced termination of the EPSP. followed by a later hyperpolarizing event (IPSPB). Current-voltage relationships revealed two different conductances of about 200 and 20 nS and reversal potentials of -73-0+444 and -88-6+6 1 mV for the early and late component. respectively.3. The conductances of IPSPA and IPSPB were fairly stable at a stimulus frequency of 0-1 Hz. At frequencies between 0-5 and 2 Hz both IPSPs were attenuated with the second stimulus and after about five stimuli a steady state was reached. Concomitantly IPSPs were shortened. The average decrease in synaptic conductance between 0-1 and 1 Hz was 80% for the IPSPA and 60% for the IPSPB. At these frequencies the reversal potentials decreased by 5 and 2 mV, respectively; Em and input resistance (Rin) were not consistently affected.4. The amplitudes of field potentials, action potentials and EPSPs of pyramidal cells were attenuated less than 10% at stimulus frequencies up to 1 Hz, suggesting that alterations in local circuits between the stimulation site and excitatory input onto inhibitory interneurones may play only a minor role in the frequency-dependent decav of IPSPs.5. Localized application of GABA produced multiphasic responses. With low concentrations and application near the soma an early hyperpolarization prevailed followed by a depolarizing late component. Brief application of GABA at low frequencies induced constant responses; at higher frequencies, the responses sometimes declined. were similar to each other and to the early IPSP. An apparently fivefold higher conductance was estimated at lower Ems, suggesting that the GABA response had a voltage sensitivity. The slope conductance of IPSPs was decreased by up to 50 % for tens of seconds after postsynaptically detectable effects of GABA had dissipated. 6. Application of the GABA uptake inhibitor nipecotic acid (50-500 JLM) reduced the conductance of both components of orthodromically evoked inhibition and shortened the IPSP at low frequencies, but had no additional effects at higher stimulation rates. Em and Rin were not consistently affected. Application of nipecotic acid usually decreased the latency and increased the slope conductance of GABA responses. Depression of IPSPs by nipecotic acid at low frequencies, in the face of enhanced GABA responses, is probably presynaptically mediated. The prolonged time course of synaptically liberated GABA by nipecotic acid may cause extended presynaptic effects.7. ...
Hippocampal inhibitory postsynaptic potentials are depolarizing in granule cells but hyperpolarizing in CA3 neurons because the reversal potentials and membrane potentials of these cells differ. Here the hippocampal slice preparation was used to investigate the role of chloride transport in these inhibitory responses. In both cell types, increasing the intracellular chloride concentration by injection shifted the reversal potential of these responses in a positive direction, and blocking the outward transport of chloride with furosemide slowed their recovery from the injection. In addition, hyperpolarizing and depolarizing inhibitory responses and the hyperpolarizing and depolarizing responses to the inhibitory neurotransmitter gamma-aminobutyric acid decreased in the presence of furosemide. These effects of furosemide suggest that the internal chloride activity of an individual hippocampal neuron is regulated by two transport processes, one that accumulates chloride and one that extrudes chloride.
Neuronal subthreshold excitability and firing behaviour are markedly influenced by the activation and deactivation of the somato-dendritic hyperpolarization-activated cation current (Ih). Here, we evaluated possible contributions of Ih to hyperexcitability in an animal model of absence seizures (WAG/Rij rats). We investigated pyramidal neurons of the somatosensory neocortex, the site of generation of spike-wave discharges. Ih-mediated functions in neurons from WAG/Rij rats, Wistar rats (sharing the same genetic background with WAG/Rij, but less epilepsy-prone) and ACI rats (an inbred strain, virtually free of seizures) were compared. We complemented whole-cell recordings from layer 2-3 pyramidal neurons with immunohistochemistry, Western blot and RT-PCR analysis of the h-channel subunits HCN1-4. The fast component of Ih activation in WAG/Rij neurons was significantly reduced (50% reduction in the h-current density) and four times slower than in neurons from nonepileptic Wistar or ACI rats. The results showing decreases in currents corresponded to a 34% reduction in HCN1 protein in the WAG/Rij compared to the Wistar neocortex, but HCN1 mRNA showed stable expression. The other three Ih subunit mRNAs and proteins (HCN2-4) were not affected. The alterations in Ih magnitude and kinetics of gating in WAG/Rij neurons may contribute to augmented excitatory postsynaptic potentials, the increase in their temporal summation and the facilitation of burst firing of these neurons because each of these effects could be mimicked by the selective Ih antagonist ZD 7288. We suggest that the deficit in Ih-mediated functions may contribute to the development and onset of spontaneously occurring hyperexcitability in a rat model of absence seizures.
SUMMARY1. The ionic mechanism underlying the fast, GABAA receptor-mediated inhibitory postsynaptic potential (IPSPA) was examined in rat neocortical neurones using intracellular recording techniques. Synaptic responses were evoked by orthodromic stimulation applied to the subcortical white matter or to the pial surface. All experiments were carried out at a constant extracellular Cl-concentration.2. The resting membrane potential was -76-2 + 1I0 mV (mean+s. E. M., n = 32) and in most cells IPSPA was depolarizing. The reversal potential of IPSPA (EIPSP-A) was -70-2 + 0 9 mV (n = 32) and that of a more slowly developing hyperpolarizing response (IPSPB) was -91 4 + 1 3 mV (n = 28).3. An examination of the temporal relationships between excitatory postsynaptic potentials (EPSPs) and IPSPAS in different cells suggested that, despite partial overlap of these responses, EPSPs had little influence on the measured values of DEIPSP-A, 4. Application of 20 mm trimethylamine (TriMA), a membrane-permeant weak base which is expected to produce a rise in pHi (and hence in intracellular HC03-), induced a reversible positive shift in EIPSP-A of up to + 9-0 mV (mean + 4-2 mV) at an extracellular pH (pH.) of 7 4. In some experiments, the shift in reversal potential was associated with a change in the polarity of IPSPA from hyperpolarizing to depolarizing.5. Application of 20 mm lactate (a membrane-permeant weak acid which is expected to produce a fall in pHi and hence in intracellular HCO3 ) at pH. 7 0 produced a hyperpolarizing shift in EIPSP-A of up to -75 mV (mean -56 mV). In some experiments, exposure to lactate changed the polarity of IPSPA from depolarizing to hyperpolarizing.6. Changes in pH. from 7-4 to 7-0 reduced the effect of TriMA and augmented that of lactate on EIPSP-A' as could be expected on the basis of the pHo-dependent change in the fraction of membrane permeable non-charged weak base or acid.
1. The properties of excitatory postsynaptic potentials (EPSPs) of rat neocortical neurons were investigated with a fast single-electrode current-voltage clamp in vitro. Typically, apparently pure EPSPs were obtained by selection of electric stimuli of low intensity. 2. The amplitude and time integral of the EPSP increased when the neuron was depolarized. At threshold for generation of action potentials, the amplitude of EPSPs was increased by approximately 30% [from 5.0 +/- 2.1 to 6.3 +/- 1.0 (SD) mV, n = 12]. The integral of EPSPs was maximally about fourfold (3.7 +/- 1.5, n = 16) larger than at resting membrane potential (Em). The mechanisms involved in this augmentation of EPSPs were further investigated. 3. The amplitude and the time integral of excitatory postsynaptic currents (EPSCs) decreased linearly with shifts in command potential from -100 to -60 mV. The decrease of the EPSC integral with depolarization indicates that the enhancement of the EPSP may be brought about by recruitment of a voltage-dependent inward current. 4. Evoking EPSPs at various delays after the onset of small depolarizing current pulses (0.3-0.6 nA, 600 ms) revealed that augmentation decays with time. The integral of EPSPs evoked approximately 80 ms after the onset of the current pulse was 3.7 (+/- 1.5, n = 16) times larger than at Em. The integral of EPSPs evoked at 480 ms. however, were only twofold (+/- 0.7, n = 16) larger. Hence EPSPs evoked after a delay of 80 ms were 1.7-fold (+/- 0.4, n = 24) larger than EPSPs evoked after 480 ms. EPSCs were independent of the delay of stimulation at all potentials. 5. Intracellular application of the lidocaine derivative N-(2,6-dimethyl-phenylcarbamoylmethyl) triethylammonium bromide (QX 314) at 100 mM from pipettes rapidly abolished fast action potentials and inward rectification. During comparable depolarizations the increase in EPSP integrals was much smaller in QX 314-treated neurons than in controls. On average, the integral of EPSPs evoked at 70-90 ms was 1.7 times (+/- 1.0) larger than at Em, and the integral of EPSPs evoked with larger delays was close to the value obtained at resting Em (0.9 +/- 0.3, n = 8). The ratio of EPSP integrals early versus late (1.8 +/- 0.5) is comparable to controls, suggesting that QX 314-sensitive currents are unlikely to be involved in the time-dependent enhancement. 6. Mimicking EPSPs by brief depolarizations atop long depolarizations revealed a time- and voltage-dependent enhancement comparable to that of EPSPs.(ABSTRACT TRUNCATED AT 400 WORDS)
1. Active and passive factors affecting the chloride gradient of cortical neurons were assessed using intracellular recordings from neurons in slices of cingulate cortex maintained in vitro. The chloride equilibrium potential (ECl-) was estimated indirectly from the reversal potentials of responses to perisomatic gamma-aminobutyric acid (GABA) application and the Cl(-)-dependent inhibitory postsynaptic potential (IPSP). Under control conditions the mean resting potential (Vm; -69.7 mV) was not significantly different than the mean IPSP reversal potential (EIPSP; -70.1 mV). 2. Increasing the external potassium concentration ([K+]o) from 1 to 10 mM shifted the mean EIPSP from -80.4 to -61.8 mV. The mean EIPSP was approximately equal to the mean Vm at all [K+]oS. The conditions of Donnan equilibrium are not met in [K+]o less than 10 mM. 3. Polarization of Vm up to 20 mV away from EIPSP for 4 min with maintained current injection had no significant effect on EIPSP. 4. The GABA reversal potential was maintained 37-52 mV less negative than Vm after equilibration in saline in which the external chloride concentration had been reduced from 133 to 5 mM by substitution with isethionate. Vm and input resistance were not significantly different from control values in cells recorded under these conditions. 5. We conclude that Cl- is not passively distributed in cortical neurons, perhaps due to a low resting Cl- permeability. 6. Impalement with electrodes containing 2 M KCl resulted in a rapid 10 mV depolarizing shift in EIPSP that then remained relatively constant. Intracellular iontophoresis of Cl- resulted in a further depolarizing shift of EIPSP of 5-10 mV that returned to control in less than 1 min. The time course of recovery of IPSP amplitude could be fit with a single exponential having a mean time constant of 6.9 +/- 1.5 s and was independent of the amount of Cl- injected or stimulation frequency. 7. Reductions in temperature from 37 to 32 degrees C significantly increased the mean time constant of IPSP recovery from Cl- injection to 11.1 +/- 3.3 s, corresponding to Q10 = 2.6.(ABSTRACT TRUNCATED AT 400 WORDS)
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