Characterization of an early afterhyperpolarization after a brief train of action potentials in rat hippocampal neurons in vitro

Sex-dependent differences in ethanol inhibition of mouse lateral orbitofrontal cortex neurons

Biological differences between males and females likely influence responses to alcohol and the propensity to engage in excessive drinking. In both humans and rodents, females escalate alcohol use and develop addiction-like behaviors faster than males, while males exhibit more severe withdrawal symptoms during abstinence. The mechanisms underlying these differences are not yet known but may reflect fundamental differences in the ethanol sensitivity of neurons in reward and control areas of the brain. To address this question, we recorded current-evoked spiking of lateral orbitofrontal cortex (lOFC) neurons in male and female C57BL/6J mice following acute and chronic exposure to ethanol. Ethanol (11-66 mM) reduced firing of lOFC neurons but produced less inhibition in neurons from female mice. As previously reported for male mice, the glycine receptor blocker strychnine blocked ethanol inhibition of spiking of lOFC neurons from female mice and prevented the ethanol-induced increase in tonic current. Following chronic intermittent ethanol (CIE) exposure, current-evoked spiking of lOFC neurons was significantly enhanced with a greater effect observed in males. After CIE treatment, acute ethanol had no effect on spiking in neurons from male mice, while it produced a slight but significant decrease in firing in females. Finally, like male mice, the inhibitory effect of the glycine transport inhibitor sarcosine was blunted in CIE-exposed female mice. Together, these results suggest that while lOFC neurons in male and female mice are similarly affected by ethanol, there are significant differences in sensitivity that may contribute to differences in alcohol actions between males and females.

Transient Hypoxemia Disrupts Anatomical and Functional Maturation of Preterm Fetal Ovine CA1 Pyramidal Neurons

Children who survive premature birth often exhibit reductions in hippocampal volumes and deficits in working memory. However, it is unclear whether synaptic plasticity and cellular mechanisms of learning and memory can be elicited or disrupted in the preterm fetal hippocampus. CA1 hippocampal neurons were exposed to two common insults to preterm brain: transient hypoxia-ischemia (HI) and hypoxia (Hx). We used a preterm fetal sheep model using both sexes in twin 0.65 gestation fetuses that reproduces the spectrum of injury and abnormal growth in preterm infants. Using Cavalieri measurements, hippocampal volumes were reduced in both Hx and HI fetuses compared with controls. This volume loss was not the result of neuronal cell death. Instead, morphometrics revealed alterations in both basal and apical dendritic arborization that were significantly associated with the level of systemic hypoxemia and metabolic stress regardless of etiology. Anatomical alterations of CA1 neurons were accompanied by reductions in probability of presynaptic glutamate release, long-term synaptic plasticity and intrinsic excitability. The reduction in intrinsic excitability was in part due to increased activity of the channels underlying the fast and slow component of the afterhyperpolarization in Hx and HI. Our studies suggest that even a single brief episode of hypoxemia can markedly disrupt hippocampal maturation. Hypoxemia may contribute to long-term working memory disturbances in preterm survivors by disrupting neuronal maturation with resultant functional disturbances in hippocampal action potential throughput. Strategies directed at limiting the duration or severity of hypoxemia during brain development may mitigate disturbances in hippocampal maturation.SIGNIFICANCE STATEMENT Premature infants commonly sustain hypoxia-ischemia, which results in reduced hippocampal growth and life-long disturbances in learning and memory. We demonstrate that the circuitry related to synaptic plasticity and cellular mechanisms of learning and memory (LTP) are already functional in the fetal hippocampus. Unlike adults, the fetal hippocampus is surprisingly resistant to cell death from hypoxia-ischemia. However, the hippocampus sustains robust structural and functional disturbances in the dendritic maturation of CA1 neurons that are significantly associated with the magnitude of a brief hypoxic stress. Since transient hypoxic episodes occur commonly in preterm survivors, our findings suggest that the learning problems that ensue may be related to the unique susceptibility of the hippocampus to brief episodes of hypoxemia.

Complementary functions of SK and Kv7/M potassium channels in excitability control and synaptic integration in rat hippocampal dentate granule cells

The dentate granule cells (DGCs) form the most numerous neuron population of the hippocampal memory system, and its gateway for cortical input. Yet, we have only limited knowledge of the intrinsic membrane properties that shape their responses. Since SK and Kv7/M potassium channels are key mechanisms of neuronal spiking and excitability control, afterhyperpolarizations (AHPs) and synaptic integration, we studied their functions in DGCs. The specific SK channel blockers apamin or scyllatoxin increased spike frequency (excitability), reduced early spike frequency adaptation, fully blocked the medium-duration AHP (mAHP) after a single spike or spike train, and increased postsynaptic EPSP summation after spiking, but had no effect on input resistance (Rinput) or spike threshold. In contrast, blockade of Kv7/M channels by XE991 increased Rinput, lowered the spike threshold, and increased excitability, postsynaptic EPSP summation, and EPSP-spike coupling, but only slightly reduced mAHP after spike trains (and not after single spikes). The SK and Kv7/M channel openers 1-EBIO and retigabine, respectively, had effects opposite to the blockers. Computational modelling reproduced many of these effects. We conclude that SK and Kv7/M channels have complementary roles in DGCs. These mechanisms may be important for the dentate network function, as CA3 neurons can be activated or inhibition recruited depending on DGC firing rate.

Characteristics of single large-conductance Ca2+-activated K+ channels and their regulation of action potentials and excitability in parasympathetic cardiac motoneurons in the nucleus ambiguus

Large-conductance Ca2(+)-activated K+ channels (BK) regulate action potential (AP) properties and excitability in many central neurons. However, the properties and functional roles of BK channels in parasympathetic cardiac motoneurons (PCMNs) in the nucleus ambiguus (NA) have not yet been well characterized. In this study, the tracer X-rhodamine-5 (and 6)-isothiocyanate (XRITC) was injected into the pericardial sac to retrogradely label PCMNs in FVB mice at postnatal 7-9 days. Two days later, XRITC-labeled PCMNs in brain stem slices were identified. Using excised patch single-channel recordings, we identified voltage-gated and Ca(2+)-dependent BK channels in PCMNs. The majority of BK channels exhibited persistent channel opening during voltage holding. These BK channels had a conductance of 237 pS and a 50% opening probability at +27.9 mV, the channel open time constant was 3.37 ms at +20 mV, and dwell time increased exponentially as the membrane potential depolarized. At the +20-mV holding potential, the [Ca2+]50 was 15.2 μM with a P0.5 of 0.4. Occasionally, some BK channels showed a transient channel opening and fast inactivation. Using whole cell voltage clamp, we found that BK channel mediated outward currents and afterhyperpolarization currents (IAHP). Using whole cell current clamp, we found that application of BK channel blocker iberiotoxin (IBTX) increased spike half-width and suppressed fast afterhyperpolarization (fAHP) amplitude following single APs. In addition, IBTX application increased spike half-width and reduced the spike frequency-dependent AP broadening in trains and spike frequency adaption (SFA). Furthermore, BK channel blockade decreased spike frequency. Collectively, these results demonstrate that PCMNs have BK channels that significantly regulate AP repolarization, fAHP, SFA, and spike frequency. We conclude that activation of BK channels underlies one of the mechanisms for facilitation of PCMN excitability.

Bidirectional pattern-specific plasticity of the slow afterhyperpolarization in rats: role for high-voltage activated Ca2+ channels and I h

A burst of action potentials in hippocampal neurons is followed by a slow afterhyperpolarization (sAHP) that serves to limit subsequent firing. A reduction in the sAHP accompanies acquisition of several types of learning, whereas increases in the sAHP are correlated with cognitive impairment. The present study demonstrates in vitro that activity-dependent bidirectional plasticity of the sAHP does not require synaptic activation, and depends on the pattern of action potential firing. Whole-cell current-clamp recordings from CA1 pyramidal neurons in hippocampal slices from young rats (postnatal days 14-24) were performed in blockers of synaptic transmission. The sAHP was evoked by action potential firing at gamma-related (50 Hz, gamma-AHP) or theta frequencies (5 Hz, theta-AHP), two firing frequencies implicated in attention and memory. Interestingly, when the gamma-AHP and theta-AHP were evoked in the same cell, a gradual potentiation of the gamma-AHP (186 ± 31%) was observed that was blocked using Ca(2+) channel blockers nimodipine (10 μm) or ω-conotoxin MVIIC (1 μm). In experiments that exclusively evoked the sAHP with 50 Hz firing, the gamma-AHP was similarly potentiated (198 ± 44%). However, theta-burst firing pattern alone resulted in a decrease (65 ± 19%) of the sAHP. In these experiments, application of the h-channel blocker ZD7288 (25 μm) selectively prevented enhancement of the gamma-AHP. These data demonstrate that induction requirements for bidirectional AHP plasticity depend on the pattern of action potential firing, and result from distinct mechanisms. The identification of novel mechanisms underlying AHP plasticity in vitro provides additional insight into the dynamic processes that may regulate neuronal excitability during learning in vivo.

Maternal diabetes increases large conductance Ca2+-activated K+ outward currents that alter action potential properties but do not contribute to attenuated excitability of parasympathetic cardiac motoneurons in the nucleus ambiguus of neonatal mice

Previously, we demonstrated that maternal diabetes reduced the excitability and increased small-conductance Ca(2+)-activated K(+) (SK) currents of parasympathetic cardiac motoneurons (PCMNs) in the nucleus ambiguus (NA). In addition, blockade of SK channels with apamin completely abolished this reduction. In the present study, we examined whether maternal diabetes affects large-conductance Ca(2+)-activated K(+) (BK) channels and whether BK channels contribute to the attenuation of PCMN excitability observed in neonates of diabetic mothers. Neonatal mice from OVE26 diabetic mothers (NMDM) and normal FVB mothers (control) were used. The pericardial sac of neonatal mice at postnatal days 7-9 was injected with the tracer X-rhodamine-5 (and 6)-isothiocyanate 2 days prior to the experiment to retrogradely label PCMNs in the NA. Whole cell current- and voltage-clamps were used to measure spike frequency, action potential (AP) repolarization (half-width), afterhyperpolarization potential (AHP), transient outward currents, and afterhyperpolarization currents (I(AHP)). In whole cell voltage clamp mode, we confirmed that maternal diabetes increased transient outward currents and I(AHP) compared with normal cells. Using BK channel blockers charybdotoxin (CTx) and paxilline, we found that maternal diabetes increased CTx- and paxilline-sensitive transient outward currents but did not change CTx- and paxilline-sensitive I(AHP). In whole cell current-clamp mode, we confirmed that maternal diabetes increased AP half-width and AHP, and reduced excitability of PCMNs. Furthermore, we found that after blockade of BK channels with CTx or paxilline, maternal diabetes induced a greater increase of AP half-width but similarly decreased fast AHP without affecting medium AHP. Finally, blockade of BK channels decreased spike frequency in response to current injection in both control and NMDM without reducing the difference of spike frequency between the two groups. Therefore, we conclude that although BK transient outward currents, which may alter AP repolarization, are increased in NMDM, BK channels do not directly contribute to maternal diabetes-induced attenuation of PCMN excitability. In contrast, based on evidence from our previous and present studies, reduction of PCMN excitability in neonates of diabetic mothers is largely dependent on altered SK current associated with maternal diabetes.

Functions and modulation of neuronal SK channels

Small conductance (SK) channels are calcium-activated potassium channels that, when cloned in 1996, were thought solely to contribute to the afterhyperpolarisation that follows action potentials, and to control repetitive firing patterns of neurons. However, discoveries over the past few years have identified novel roles for SK channels in controlling dendritic excitability, synaptic transmission and synaptic plasticity. More recently, modulation of SK channel calcium sensitivity by casein kinase 2, and of SK channel trafficking by protein kinase A, have been demonstrated. This article will discuss recent findings regarding the function and modulation of SK channels in central neurons.

SK (KCa2) channels do not control somatic excitability in CA1 pyramidal neurons but can be activated by dendritic excitatory synapses and regulate their impact

Calcium-activated K(+) channels of the K(Ca)2 type (SK channels) are prominently expressed in the mammalian brain, including hippocampus. These channels are thought to underlie neuronal excitability control and have been implicated in plasticity, memory, and neural disease. Contrary to previous reports, we found that somatic spike-evoked medium afterhyperpolarizations (mAHPs) and corresponding excitability control were not caused by SK channels but mainly by Kv7/KCNQ/M channels in CA1 hippocampal pyramidal neurons. Thus apparently, these SK channels are hardly activated by somatic Na(+) spikes. To further test this conclusion, we used sharp electrode, whole cell, and perforated-patch recordings from rat CA1 pyramidal neurons. We found that SK channel blockers consistently failed to suppress mAHPs under a range of experimental conditions: mAHPs following single spikes or spike trains, at -60 or -80 mV, at 20-30 degrees C, in low or elevated extracellular [K(+)], or spike trains triggered by synaptic stimulation after blocking N-methyl-d-aspartic acid receptors (NMDARs). Nevertheless, we found that SK channels in these cells were readily activated by artificially enhanced Ca(2+) spikes, and an SK channel opener (1-ethyl-2-benzimidazolinone) enhanced somatic AHPs following Na(+) spikes, thus reducing excitability. In contrast to CA1 pyramidal cells, bursting pyramidal cells in the subiculum showed a Na(+) spike-evoked mAHP that was reduced by apamin, indicating cell-type-dependent differences in mAHP mechanisms. Testing for other SK channel functions in CA1, we found that field excitatory postsynaptic potentials mediated by NMDARs were enhanced by apamin, supporting the idea that dendritic SK channels are activated by NMDAR-dependent calcium influx. We conclude that SK channels in rat CA1 pyramidal cells can be activated by NMDAR-mediated synaptic input and cause feedback regulation of synaptic efficacy but are normally not appreciably activated by somatic Na(+) spikes in this cell type.

Action potential throughput in aged rat hippocampal neurons: regulation by selective forms of hyperpolarization

At hippocampal synapses, repetitive synaptic stimulation (RSS) in the theta frequency range (3-12Hz) is associated with robust EPSP frequency facilitation (FF) and consequently, enhanced action potential (spike) generation and throughput. A complex, synaptically induced hyperpolarization (SIHP) is also triggered by synaptic activation, and a Ca(2+)-dependent afterhyperpolarization (AHP) is triggered above spike threshold. With aging, the AHP is increased and impairs intracellular spike generation, at least in accommodation protocols. However, little is known about how these aging changes interact to affect spike generation at physiological frequencies of RSS, or if the SIHP also is modified in aging. Here we performed the first tests of the net impact of these excitatory and inhibitory aging changes on spike generation during RSS. We report that during RSS at spike threshold (1) spike throughput is well sustained at theta frequencies in young and aged neurons; (2) an interposed AHP dampens spike generation, particularly in aged neurons and at higher frequencies; (3) compared to the AHP, the SIHP does not exert an equivalent inhibitory effect on spike throughput; and (4) in contrast to the AHP, the SIHP is reduced with aging. Together, these results are consistent with a model in which the source of the hyperpolarization is important in determining hippocampal spike throughput within the theta frequency range.

Serotonergic Modulation of Afterhyperpolarization in a Neuron That Contributes to Learning in the Leech

Modulation of afterhyperpolarization (AHP) represents an important mechanism by which excitability of a neuron can be regulated. In the leech brain, sensitization enhances excitability of the S-cell, an interneuron thought to play an important role in this form of nonassociative learning. This increase in excitability is serotonin (5-HT) dependent, but it is not known whether changes in AHP contribute to 5-HT–mediated enhancement of excitability. Therefore electrophysiological recordings and computational modeling were used to determine whether 5-HT enhances excitability via modulation of AHP. 5-HT reduced S-cell AHP and this decrease in the AHP corresponded with an increase in excitability. Little or no AHP is observed in the presence of Ca2+-free saline, suggesting the involvement of Ca2+-dependent K+channels. Furthermore, AHP amplitude decreased following treatment with drugs (tubocurare and charybdotoxin) that block Ca2+-dependent K+channel activity. The S-cell also exhibits an afterdepolarization (ADP), which is usually masked by the AHP, and was inhibited by the Na+channel blocker saxitoxin. A model of the S-cell AHP was constructed using two Ca2+-dependent K+currents and a Na+-driven ADP current. Reduction of the model conductances underlying the AHP to mimic the effects of 5-HT was sufficient to enhance excitability. These findings were confirmed in occlusion experiments in which pretreatment with tubocurare was able to block 5-HT–mediated decreases in mAHP levels and increases in excitability. These data show that modulation of S-cell AHP can contribute to 5-HT–mediated increases in excitability and that the S-cell afterpotential is due to the combined effects of AHP- and ADP-producing currents.

Enhanced neuronal excitability in rat CA1 pyramidal neurons following trace eyeblink conditioning acquisition is not due to alterations in I M

Previous work done by our laboratory has demonstrated a reduction of the post-burst afterhyperpolarization (AHP) and accommodation following trace eyeblink conditioning in rabbit CA1 pyramidal neurons. Our laboratory has also demonstrated a reduction in the AHP in rat CA1 pyramidal neurons following spatial learning. In the current study we have extended our findings in rabbits by showing a reduction in both the AHP and accommodation in F344 X BN rat CA1 pyramidal neurons following acquisition of trace eyeblink conditioning. A component current of the AHP, I(M), was evaluated with a specific blocker of this current, and showed no apparent contribution to the learning-related increase in neuronal excitability. Rather, a reduction in an isoproterenol-sensitive component of the AHP, presumably sI(AHP), was observed to underlie the learning-specific change.

Functions of SK channels in central neurons

1. SK channels are small-conductance calcium-activated potassium channels that are widely expressed in neurons. The traditional view of the functional role of SK channels is in mediating one component of the after-hyperpolarization that follows action potentials. Calcium influx via voltage-gated calcium channels active during action potentials opens SK channels and the resultant hyperpolarization lowers the firing frequency of action potentials in many neurons. 2. Recent advances have shown that, in addition to controlling action potential firing frequency, SK channels are also important in regulating dendritic excitability, synaptic transmission and synaptic plasticity. 3. In accordance with their role in modulating synaptic plasticity, SK channels are also important in regulating several learning and memory tasks and may also play a role in a number of neurological disorders. 4. The present review discusses recent findings on the role of SK channels in central neurons.

BK potassium channels facilitate high-frequency firing and cause early spike frequency adaptation in rat CA1 hippocampal pyramidal cells

Neuronal potassium (K(+)) channels are usually regarded as largely inhibitory, i.e. reducing excitability. Here we show that BK-type calcium-activated K(+) channels enhance high-frequency firing and cause early spike frequency adaptation in neurons. By combining slice electrophysiology and computational modelling, we investigated functions of BK channels in regulation of high-frequency firing in rat CA1 pyramidal cells. Blockade of BK channels by iberiotoxin (IbTX) selectively reduced the initial discharge frequency in response to strong depolarizing current injections, thus reducing the early spike frequency adaptation. IbTX also blocked the fast afterhyperpolarization (fAHP), slowed spike rise and decay, and elevated the spike threshold. Simulations with a computational model of a CA1 pyramidal cell confirmed that the BK channel-mediated rapid spike repolarization and fAHP limits activation of slower K(+) channels (in particular the delayed rectifier potassium current (I(DR))) and Na(+) channel inactivation, whereas M-, sAHP- or SK-channels seem not to be important for the early facilitating effect. Since the BK current rapidly inactivates, its facilitating effect diminishes during the initial discharge, thus producing early spike frequency adaptation by an unconventional mechanism. This mechanism is highly frequency dependent. Thus, IbTX had virtually no effect at spike frequencies < 40 Hz. Furthermore, extracellular field recordings demonstrated (and model simulations supported) that BK channels contribute importantly to high-frequency burst firing in response to excitatory synaptic input to distal dendrites. These results strongly support the idea that BK channels play an important role for early high-frequency, rapidly adapting firing in hippocampal pyramidal neurons, thus promoting the type of bursting that is characteristic of these cells in vivo, during behaviour.

Firing pattern and calbindin-D28k content of human epileptic granule cells

In the hippocampus of chronic temporal lobe epilepsy, many abnormalities in structure and function have been described but their pathophysiological relevance often is poorly understood. In this study, we asked whether there may be a link between changes in the firing pattern and the loss of the calcium binding protein calbindin-D28k in epileptic hippocampal granule cells. Using the perforated patch-clamp technique, we investigated granule cells in slices prepared from human hippocampi removed for the treatment of pharmacoresistant temporal lobe epilepsy. Granule cells in hippocampi without significant signs of structural damage (lesion group) displayed a firing pattern indistinguishable from that of rodent granule cells and were strongly labeled with anti-calbindin-D28k antibodies. In contrast, half of granule cells in sclerotic hippocampi (HS group) showed an altered firing pattern and a severe loss of calbindin-D28k. While these cells show passive membrane properties comparable to cells of the rodent and lesion group, they lack the medium afterhyperpolarization and display only a weak spike frequency adaptation. On the other hand, granule cells in the HS group have an increased action potential threshold and an enlarged fast afterhyperpolarization. Applying post-recording immunohistochemistry to individual electrophysiologically characterized granule cells, we show that the loss of calbindin-D28k is not causally related to any of the changes in firing pattern. Both alterations seem to occur during the course of temporal lobe epilepsy, with the firing pattern being affected earlier than the calbindin-D28k content. In conclusion, we propose that it is the combination of the altered intrinsic excitability of granule cells with the amplified and prolonged synaptic input from perforant path fibers previously described in the epileptic dentate area which promotes tonic, non-adapting, high frequency firing of granule cells and thereby strongly augments the excitability of the hippocampus.

On the Origin of the Extracellular Action Potential Waveform: A Modeling Study

Although extracellular unit recording is typically used for the detection of spike occurrences, it also has the theoretical ability to report about what are typically considered intracellular features of the action potential. We address this theoretical ability by developing a model system that captures features of experimentally recorded simultaneous intracellular and extracellular recordings of CA1 pyramidal neurons. We use the line source approximation method of Holt and Koch to model the extracellular action potential (EAP) voltage resulting from the spiking activity of individual neurons. We compare the simultaneous intracellular and extracellular recordings of CA1 pyramidal neurons recorded in vivo with model predictions for the same cells reconstructed and simulated with compartmental models. The model accurately reproduces both the waveform and the amplitude of the EAPs, although it was difficult to achieve simultaneous good matches on both the intracellular and extracellular waveforms. This suggests that accounting for the EAP waveform provides a considerable constraint on the overall model. The developed model explains how and why the waveform varies with electrode position relative to the recorded cell. Interestingly, each cell's dendritic morphology had very little impact on the EAP waveform. The model also demonstrates that the varied composition of ionic currents in different cells is reflected in the features of the EAP.

Early and simultaneous emergence of multiple hippocampal biomarkers of aging is mediated by Ca2+-induced Ca2+ release

Age-dependent changes in multiple Ca2+-related electrophysiological processes in the hippocampus appear to be consistent biomarkers of aging, and several also correlate with cognitive decline. These findings have led to the hypothesis that a common mechanism of Ca2+ dyshomeostasis underlies aspects of aging-dependent brain impairment. However, some key predictions of this view remain untested, including that multiple Ca2+-related biomarkers should emerge concurrently during aging and their onset should also precede/coincide with initial signs of cognitive decline. Moreover, blocking a putative common source of dysregulated Ca2+ should eliminate aging differences. Here, we tested these predictions using combined electrophysiological, imaging, and pharmacological approaches in CA1 neurons to determine the ages of onset (across 4-, 10-, 12-, 14-, and 23-month-old F344 rats) of several established biomarkers, including the increases in the slow afterhyperpolarization, spike accommodation, and [Ca2+]i rise during repetitive synaptic stimulation. In addition, we tested the hypothesis that altered Ca2+-induced Ca2+ release (CICR) from ryanodine receptors, which can be triggered by L-type Ca2+ channels, provides a common source of dysregulated Ca2+ in aging. Results showed that multiple aging biomarkers were first detectable at about the same age (12 months of age; approximately midlife), sufficiently early to influence initial cognitive decline. Furthermore, selectively blocking CICR with ryanodine slowed the Ca2+ rise during synaptic stimulation more in aged rat neurons and, notably, reduced or eliminated aging differences in the biomarkers. Thus, this study provides the first evidence that altered CICR plays a role in driving the early and simultaneous emergence in hippocampus of multiple Ca2+-related biomarkers of aging.

Distinct properties of two major excitatory inputs to hippocampal pyramidal cells: a computational study

The two main sources of excitatory input to CA1 pyramidal cells, the Schaffer collaterals (SC) and the perforant path (PP), target different regions of the dendritic tree. This spatial segregation may have important consequences for the way in which different inputs affect the activity of principal neurons. We constructed detailed biophysical models of CA1 pyramidal cells, incorporating a variety of active conductances, and investigated the ability of synapses located in different dendritic segments to elicit a somatic voltage response. Synaptic efficacy as seen by the soma was strongly dependent on the site of the synapse, with PP inputs being more severely attenuated than SC inputs. Variability within SC inputs, but not between SC inputs and PP inputs, could be eliminated by appropriate scaling of synaptic efficacy. The spatial and temporal summation of multiple synaptic inputs was also investigated. While summation of SC inputs was linear up to the somatic spike threshold, PP inputs summed in a strongly sublinear fashion, with the somatic response remaining subthreshold even following the simultaneous activation of a large number of synapses and during stimulation with high-frequency trains. Finally, the relative impact of different pathways on somatic activity could be effectively altered by modulating the kinetic properties of dendritic transient K+ channels, corresponding to the activation of ascending modulatory neurotransmitter systems. In this case, the efficacy of the PP was enhanced by the dendritic generation and limited spread of action potentials. Strong PP activation could also evoke dendritic Ca++ spikes, which often triggered a somatic burst.

Kv7/KCNQ/M and HCN/h, but not KCa2/SK channels, contribute to the somatic medium after-hyperpolarization and excitability control in CA1 hippocampal pyramidal cells

In hippocampal pyramidal cells, a single action potential (AP) or a burst of APs is followed by a medium afterhyperpolarization (mAHP, lasting approximately 0.1 s). The currents underlying the mAHP are considered to regulate excitability and cause early spike frequency adaptation, thus dampening the response to sustained excitatory input relative to responses to abrupt excitation. The mAHP was originally suggested to be primarily caused by M-channels (at depolarized potentials) and h-channels (at more negative potentials), but not SK channels. In recent reports, however, the mAHP was suggested to be generated mainly by SK channels or only by h-channels. We have now re-examined the mechanisms underlying the mAHP and early spike frequency adaptation in CA1 pyramidal cells by using sharp electrode and whole-cell recording in rat hippocampal slices. The specific M-channel blocker XE991 (10 microm) suppressed the mAHP following 1-5 APs evoked by current injection at -60 mV. XE991 also enhanced the excitability of the cell, i.e. increased the number of APs evoked by a constant depolarizing current pulse, reduced their rate of adaptation, enhanced the after depolarization and promoted bursting. Conversely, the M-channel opener retigabine reduced excitability. The h-channel blocker ZD7288 (4-ethylphenylamino-1,2-dimethyl-6-methylaminopyrimidinium chloride; 10 microm) fully suppressed the mAHP at -80 mV, but had little effect at -60 mV, whereas XE991 did not measurably affect the mAHP at -80 mV. Likewise, ZD7288 had little or no effect on excitability or adaptation during current pulses injected from -60 mV, but changed the initial discharge during depolarizing pulses injected from -80 mV. In contrast to previous reports, we found that blockade of Ca2+-activated K+ channels of the SK/KCa type by apamin (100-400 nm) failed to affect the mAHP or adaptation. A computational model of a CA1 pyramidal cell predicted that M- and h-channels will generate mAHPs in a voltage-dependent manner, as indicated by the experiments. We conclude that M- and h-channels generate the somatic mAHP in hippocampal pyramidal cells, with little or no net contribution from SK channels.

Conditional transgenic suppression of M channels in mouse brain reveals functions in neuronal excitability, resonance and behavior

In humans, mutations in the KCNQ2 or KCNQ3 potassium-channel genes are associated with an inherited epilepsy syndrome. We have studied the contribution of KCNQ/M-channels to the control of neuronal excitability by using transgenic mice that conditionally express dominant-negative KCNQ2 subunits in brain. We show that suppression of the neuronal M current in mice is associated with spontaneous seizures, behavioral hyperactivity and morphological changes in the hippocampus. Restriction of transgene expression to defined developmental periods revealed that M-channel activity is critical to the development of normal hippocampal morphology during the first postnatal weeks. Suppression of the M current after this critical period resulted in mice with signs of increased neuronal excitability and deficits in hippocampus-dependent spatial memory. M-current-deficient hippocampal CA1 pyramidal neurons showed increased excitability, reduced spike-frequency adaptation, attenuated medium afterhyperpolarization and reduced intrinsic subthreshold theta resonance. M channels are thus critical determinants of cellular and neuronal network excitability, postnatal brain development and cognitive performance.

Slow afterhyperpolarization governs the development of NMDA receptor-dependent afterdepolarization in CA1 pyramidal neurons during synaptic stimulation

CA1 pyramidal neurons from animals that have acquired a hippocampus-dependent task show a reduced slow postburst afterhyperpolarization (sAHP). To understand the functional significance of this change, we examined and characterized the sAHP activated by different patterns of synaptic stimuli and its impact on postsynaptic signal integration. Whole cell current-clamp recordings were performed on rat CA1 pyramidal neurons, and trains of stratum radiatum stimuli varying in duration, frequency, and intensity were used to activate the AHP. At -68 mV, a short train of subthreshold stimuli (20-150 Hz) generated only the medium AHP. In contrast, just two suprathreshold stimuli >50 Hz triggered a prominent sAHP sensitive to bath-applications of isoproterenol, carbachol, or intracellularly applied BAPTA, suggesting that the underlying current is the Ca2+-activated K+ current, the sIAHP. The sAHP magnitude was positively related to stimulus train duration and frequency, consistent with its dependence on intracellular Ca2+ accumulation for activation. About 20% of neurons recorded did not have a sAHP. In response to high-frequency suprathreshold stimuli, these neurons developed a pronounced afterdepolarization (ADP) and multiple action potential firing. The ADP magnitude increased with successive stimuli and was positively related to stimulus intensity and frequency. It was sensitive to bath-applications of thapsigargin and nitrendipine, and abolished by d-AP5, indicating that it is supported by intracellular Ca2+ release, the L-type Ca2+ influx, and N-methyl-D-aspartate (NMDA) receptor-mediated influx. In the presence of D-AP5, we were unable to trigger an ADP with maximal stimulus intensity. Pharmacologically eliminating the sAHP allowed neurons to develop an ADP with the original stimulus train. We propose that the slow AHP acts to facilitate Mg2+ re-block of the activated NMDA receptors, thereby reducing temporal summation and preventing an NMDA receptor-dependent ADP during intense synaptic events. Neuromodulation of the sAHP may thus affect information throughput and regulate NMDA receptor-mediated plasticity.

pH modulation of currents that contribute to the medium and slow afterhyperpolarizations in rat CA1 pyramidal neurones

We examined the effects of changes in pH(o) and pH(i) on currents contributing to the medium and slow afterhyperpolarizations (mI(AHP) and sI(AHP), respectively) in rat CA1 neurones. Reducing pH(o) from 7.4 to 6.7 inhibited mI(AHP) and sI(AHP) whereas increasing pH(o) to 7.7 augmented mI(AHP) and, to a greater extent, sI(AHP). The ability of changes in pH(o) to modulate mI(AHP) reflected changes in the Ca(2+)-activated K(+) current, I(AHP), and a Co(2+)- and XE991-resistant component of mI(AHP), but not the muscarine-sensitive current, I(M). In the presence of 1 microM TTX and 5 mM TEA, low pH(o)-evoked reductions in sI(AHP) were associated with reductions in Ca(2+)-dependent depolarizing potentials; because neither effect was attenuated when internal H(+) buffering power was raised by including 100 mm tricine in the patch pipette, the actions of reductions in pH(o) to inhibit sI(AHP) and, possibly, I(AHP) in large part appear to reflect a low pH(o)-dependent decrease in Ca(2+) influx. In contrast, the effects of high pH(o) to augment mI(AHP) and sI(AHP) were associated with relatively small increases in Ca(2+) potentials but were significantly attenuated by 100 mM internal tricine, indicating that a rise in pH(i) consequent upon the rise in pH(o) was largely responsible. The possibility that changes in pH(i) could act to modulate mI(AHP) and sI(AHP), independently of changes in Ca(2+) influx, was also suggested by experiments in which pH(i) was lowered at a constant pH(o) by the external application of propionate or by the withdrawal of HCO(-)(3) from the perfusing medium. Lowering pH(i) at a constant pH(o) had little effect on Ca(2+) potentials but inhibited mI(AHP) and, to a greater extent, sI(AHP), effects that were attenuated by 100 mM internal tricine. Together, the results indicate that changes in pH(o) and pH(i) modulate mI(AHP) and sI(AHP) in rat CA1 neurones and suggest that, depending on the direction of the pH(o) change, the sensitivities of the underlying currents to changes in Ca(2+) influx and/or pH(i) may contribute to the effects of changes in pH(o) to modulate mI(AHP) and sI(AHP).

Two forms of electrical resonance at theta frequencies, generated by M-current, h-current and persistent Na+ current in rat hippocampal pyramidal cells

Coherent network oscillations in the brain are correlated with different behavioural states. Intrinsic resonance properties of neurons provide a basis for such oscillations. In the hippocampus, CA1 pyramidal neurons show resonance at theta (theta) frequencies (2-7 Hz). To study the mechanisms underlying theta-resonance, we performed whole-cell recordings from CA1 pyramidal cells (n = 73) in rat hippocampal slices. Oscillating current injections at different frequencies (ZAP protocol), revealed clear resonance with peak impedance at 2-5 Hz at approximately 33 degrees C (increasing to approximately 7 Hz at approximately 38 degrees C). The theta-resonance showed a U-shaped voltage dependence, being strong at subthreshold, depolarized (approximately -60 mV) and hyperpolarized (approximately -80 mV) potentials, but weaker near the resting potential (-72 mV). Voltage clamp experiments revealed three non-inactivating currents operating in the subthreshold voltage range: (1) M-current (I(M)), which activated positive to -65 mV and was blocked by the M/KCNQ channel blocker XE991 (10 microM); (2) h-current (I(h)), which activated negative to -65 mV and was blocked by the h/HCN channel blocker ZD7288 (10 microM); and (3) a persistent Na(+) current (I(NaP)), which activated positive to -65 mV and was blocked by tetrodotoxin (TTX, 1 microM). In current clamp, XE991 or TTX suppressed the resonance at depolarized, but not hyperpolarized membrane potentials, whereas ZD7288 abolished the resonance only at hyperpolarized potentials. We conclude that these cells show two forms of theta-resonance: "M-resonance" generated by the M-current and persistent Na(+) current in depolarized cells, and "H-resonance" generated by the h-current in hyperpolarized cells. Computer simulations supported this interpretation. These results suggest a novel function for M/KCNQ channels in the brain: to facilitate neuronal resonance and network oscillations in cortical neurons, thus providing a basis for an oscillation-based neural code.

Regional differences in distribution and functional expression of small-conductance Ca2+-activated K+ channels in rat brain

Small-conductance Ca2+-activated K+ (SK) channels are important for excitability control and afterhyperpolarizations in vertebrate neurons and have been implicated in regulation of the functional state of the forebrain. We have examined the distribution, functional expression, and subunit composition of SK channels in rat brain. Immunoprecipitation detected solely homotetrameric SK2 and SK3 channels in native tissue and their constitutive association with calmodulin. Immunohistochemistry revealed a restricted distribution of SK1 and SK2 protein with highest densities in subregions of the hippocampus and neocortex. In contrast, SK3 protein was distributed more diffusely in these brain regions and predominantly expressed in phylogenetically older brain regions. Whole-cell recording showed a sharp segregation of apamin-sensitive SK current within the hippocampal formation, in agreement with the SK2 distribution, suggesting that SK2 homotetramers underlie the apamin-sensitive medium afterhyperpolarizations in rat hippocampus.

Cholecystokinin-immunopositive basket and Schaffer collateral-associated interneurones target different domains of pyramidal cells in the CA1 area of the rat hippocampus

Two types of GABAergic interneurone are known to express cholecystokinin-related peptides in the isocortex: basket cells, which preferentially innervate the somata and proximal dendrites of pyramidal cells; and double bouquet cells, which innervate distal dendrites and dendritic spines. In the hippocampus, cholecystokinin immunoreactivity has only been reported in basket cells. However, at least eight distinct GABAergic interneurone types terminate in the dendritic domain of CA1 pyramidal cells, some of them with as yet undetermined neurochemical characteristics. In order to establish whether more than one population of cholecystokinin-expressing interneurone exist in the hippocampus, we have performed whole-cell current clamp recordings from interneurones located in the stratum radiatum of the hippocampal CA1 region of developing rats. Recorded neurones were filled with biocytin to reveal their axonal targets, and were tested for the presence of pro-cholecystokinin immunoreactivity. The results show that two populations of cholecystokinin-immunoreactive interneurones exist in the CA1 area (n=15 positive cells). Cholecystokinin-positive basket cells (53%) preferentially innervate stratum pyramidale and adjacent strata oriens and radiatum. A second population of cholecystokinin-positive cells, previously described as Schaffer collateral-associated interneurones [Vida et al. (1998) J. Physiol. 506, 755-773], have axons that ramify almost exclusively in strata radiatum and oriens, overlapping with the Schaffer collateral/commissural pathway originating from CA3 pyramidal cells. Two of seven of the Schaffer collateral-associated cells were also immunopositive for calbindin. Soma position and orientation in stratum radiatum, the number and orientation of dendrites, and the passive and active membrane properties of the two cell populations are only slightly different. In addition, in stratum radiatum and its border with lacunosum of perfusion-fixed hippocampi, 31.6+/-3.8% (adult) or 26.8+/-2.9% (postnatal day 17-20) of cholecystokinin-positive cells were also immunoreactive for calbindin. Therefore, at least two populations of pro-cholecystokinin-immunopositive interneurones, basket and Schaffer collateral-associated cells, exist in the CA1 area of the hippocampus, and are probably homologous to cholecystokinin-immunopositive basket and double bouquet cells in the isocortex. It is not known if the GABAergic terminals of double bouquet cells are co-aligned with specific glutamatergic inputs. However, in the hippocampal CA1 area, it is clear that the terminals of Schaffer collateral-associated cells are co-stratified with the glutamatergic input from the CA3 area, with as yet unknown functional consequences. The division of the postsynaptic neuronal surface by two classes of GABAergic cell expressing cholecystokinin in both the hippocampus and isocortex provides further evidence for the uniform synaptic organisation of the cerebral cortex.

High-voltage-activated Ca2+ currents and the excitability of pyramidal neurons in the hippocampal CA3 subfield in rats depend on corticosterone and time of day

This study tested the time-of-day dependence of the intrinsic postsynaptic properties of hippocampal CA3 pyramidal neurons. High-voltage-activated Ca2+ currents and the Ca(2+)- and voltage-dependent afterhyperpolarizations were examined in slices of rat brains obtained at four distinct time periods. Just after onset of the dark phase, the steady-state amplitude of the Ca2+ current (-1.24+/-0.11 nA) was significantly greater (P<0.03) than that of the light phase (-0.84+/-0.06 nA). Over the entire time range, the amplitude of the Ca2+ current correlated with plasma corticosterone levels in a U-shaped function. Furthermore, depolarization-induced excitability during the dark phase exhibited an increased spike after depolarization (3.1+/-0.1 mV) and a slower adaptation of the firing frequency (146+/-18%). These findings point to a dynamic time-of-day dependence of the CA3 neuronal properties and postsynaptic Ca2+ currents.

Properties of a calcium-activated K(+) current on interneurons in the developing rat hippocampus

Calcium-activated potassium currents have an essential role in regulating excitability in a variety of neurons. Although it is well established that mature CA1 pyramidal neurons possess a Ca(2+)-activated K(+) conductance (I(K(Ca))) with early and late components, modulation by various endogenous neurotransmitters, and sensitivity to K(+) channel toxins, the properties of I(K(Ca)) on hippocampal interneurons (or immature CA1 pyramidal neurons) are relatively unknown. To address this problem, whole-cell voltage-clamp recordings were made from visually identified interneurons in stratum lacunosum-moleculare (L-M) and CA1 pyramidal cells in hippocampal slices from immature rats (P3-P25). A biphasic calcium-activated K(+) tail current was elicited following a brief depolarization from the holding potential (-50 mV). Analysis of the kinetic properties of I(K(Ca)) suggests that an early current component differs between these two cell types. An early I(K(Ca)) with a large peak current amplitude (200.8 +/- 13.2 pA, mean +/- SE), slow time constant of decay (70.9 +/- 3.3 ms), and relatively rapid time to peak (within 15 ms) was observed on L-M interneurons (n = 88), whereas an early I(K(Ca)) with a small peak current amplitude (112.5 +/- 7.3 pA), a fast time constant of decay (39.4 +/- 1.6 ms), and a slower time-to-peak (within 26 ms) was observed on CA1 pyramidal neurons (n = 85). Removal of extracellular calcium or addition of inorganic Ca(2+) channel blockers (cadmium, nickel, or cobalt) was used to demonstrate the calcium dependence of these currents. Addition of norepinephrine, carbachol, and a variety of channel toxins (apamin, iberiotoxin, verruculogen, paxilline, penitrem A, and charybdotoxin) were used to further distinguish between I(K(Ca)) on these two hippocampal cell types. Verruculogen (100 nM), carbachol (100 microM), apamin (100 nM), TEA (1 mM), and iberiotoxin (50 nM) significantly reduced early I(K(Ca)) on CA1 pyramidal neurons; early I(K(Ca)) on L-M interneurons was inhibited by apamin and TEA. Combined with previous work showing that the firing properties of hippocampal interneurons and pyramidal cells differ, our kinetic and pharmacological data provide strong support for the hypothesis that different types of Ca(2+)-activated K(+) current are present on these two cell types.

Current and voltage clamp studies of the spike medium afterhyperpolarization of hypoglossal motoneurons in a rat brain stem slice preparation

Whole-cell patch clamp recordings were performed on hypoglossal motoneurons (HMs) in a brain stem slice preparation from the neonatal rat. The medium afterhyperpolarization (mAHP) was the only afterpotential always present after single or multiple spikes, making it suitable for studying its role in firing behavior. At resting membrane potential (-68.8 +/- 0.7 mV), mAHP (23 +/- 2 ms rise-time and 150 +/- 10 ms decay) had 9.5 +/- 0.7 mV amplitude, was suppressed in Ca(2+)-free medium or by 100 nM apamin, and reversed at -94 mV membrane potential. These observations suggest that mAHP was due to activation of Ca(2+)-dependent, SK-type K(+) channels. Carbachol (10-100 microM) reversibly and dose dependently blocked the mAHP and depolarized HMs (both effects prevented by 10 microM atropine). Similar mAHP block was produced by muscarine (50 microM). In control solution a constant current pulse (1 s) induced HM repetitive firing with small spike frequency adaptation. When the mAHP was blocked by apamin, the same current pulse evoked much higher frequency firing with strong spike frequency adaptation. Carbachol also elicited faster firing and adapting behavior. Voltage clamp experiments demonstrated a slowly deactivating, apamin-sensitive K(+) current (I(AHP)) which could account for the mAHP. I(AHP) reversed at -94 mV membrane potential, was activated by depolarization as short as 1 ms, decayed with a time constant of 154 +/- 9 ms at -50 mV, and was also blocked by 50 microM carbachol. These data suggest that mAHP had an important role in controlling firing behavior as clearly demonstrated after its pharmacological block and was potently modulated by muscarinic receptor activity.

Differential control of three after-hyperpolarizations in rat hippocampal neurones by intracellular calcium buffering

1. The whole-cell recording technique, combined with internal perfusion, was used to study the effects of intracellular Ca2+ buffering on fast, medium and slow after-hyperpolarizations (fAHP, mAHP and sAHP) in hippocampal CA1 pyramidal neurones in rat brain slices at room temperature. 2. The action potentials and the fAHP were unaffected by 100 microM to 3 mM concentrations of the internally applied fast Ca2+ chelator BAPTA. At higher (10-15 mM) concentrations, BAPTA inhibited the fAHP and prolonged the decay of the action potential, suggesting that the corresponding large-conductance Ca2+-activated K+ channels are located close to the sites of Ca2+ entry during an action potential. Addition of Ca2+ to the BAPTA-containing solution (at a ratio of 4.5 [Ca2+] : 10 [BAPTA]) to maintain the control level of [Ca2+]i did not prevent the effects of high concentrations of BAPTA. 3. The mAHP, activated by a train of action potentials, was inhibited by internally applied BAPTA within the range of concentrations used (100 microM to 15 mM), and this effect could not be reversed or prevented by addition of Ca2+ to the BAPTA-containing solution. The inhibition of the mAHP by BAPTA could also be observed after blockade of the hyperpolarization-activated IQ type mixed Na+-K+ current (also known as Ih) component of the mAHP by bath-applied 3-5 mM Cs+, suggesting that the inhibition of the mAHP by BAPTA is due to inhibition of the depolarization-activated IM (muscarinic) type K+ current. 4. The sAHP, activated by a train of action potentials, was potentiated by 100-300 microM internally applied BAPTA, both with and without added Ca2+. At 1-2 mM or higher concentrations, the potentiation of the sAHP by BAPTA without added Ca2+ was transient and was followed by a fast decrease. With added Ca2+, however, BAPTA caused a persistent potentiation of the sAHP with more than a 10-fold increase in duration for periods exceeding 1 h even at concentrations of the buffer as high as 10-15 mM. Earlier reports showing a blockade of the sAHP by BAPTA, based on experiments without added Ca2+, were apparently due to a sharp reduction in intracellular free [Ca2+] and to a high intracellular concentration of the free buffer. 5. Internally applied BAPTA caused a prolongation of the spike discharge during an 800 ms-long depolarizing current step. At 100-300 microM BAPTA, but not at 1-2 mM or higher concentrations, this effect could be reversed by addition of Ca2+. The effects of BAPTA on the spike discharge occurred in parallel with the changes in the sAHP time course, which was more prolonged at higher concentrations of the buffer. 6. The concentration-dependent differential control of the three types of AHP in hippocampal neurones by BAPTA is related to modulation of intracellular Ca2+ diffusion by a fast acting mobile Ca2+ buffer.

Hippocampal slices from prion protein null mice: disrupted Ca(2+)-activated K+ currents

The intrinsic properties of hippocampal CA1 pyramidal cells were examined in mice lacking prion protein (PrP-null). The resting potentials, time constants, amplitude of the medium afterhyperpolarization (AHP) and spike firing accommodation did not differ from the control group. The PrP-null group differed in having lower input resistances, a lack of the late AHP and of a charybdotoxin-sensitive summated AHP. We propose that CA(2+)-activated K+ currents, in particular IAHP, are disrupted in PrP-null mice.

Ionic basis of spike after-depolarization and burst generation in adult rat hippocampal CA1 pyramidal cells

1. Intracellular recordings in adult rat hippocampal slices were used to identify the ionic conductances underlying active spike after-depolarization (ADP) and intrinsic burst firing in the somata of CA1 pyramidal cells (PCs). To test the 'Ca2+ hypothesis', Ca2+ currents were suppressed by replacing the Ca2+ in the saline with either Mn2+ or Mg2+. Alternatively, the inorganic Ca2+ channel blockers Cd2+ (0.5 mM) or Ni2+ (2 mM) were added to the saline. To test the 'Na+ hypothesis', Na+ currents were blocked with tetrodotoxin (TTX; 0.5 microM). 2. The suppression of Ca2+ currents blocked the fast after-hyperpolarization (AHP) generated by the fast Ca(2+)-gated K+ current Ic, while enhancing the amplitude and duration of active spike ADPS. 3. Evoked and spontaneous burst firing was preserved undiminished following Ca2+ current suppression, while the propensity to fire bursts increased in many cases. The postburst medium AHP (generated primarily by the muscarine-sensitive voltage-gated K+ current, IM) was not affected by this treatment, which blocked the slow AHP (generated by the slow Ca(2+)-gated K+ current, IAHP). 4. TTX strongly suppressed active ADPs and intrinsic bursts before substantially reducing the threshold, rate of rise and amplitude of solitary spikes. 5. In Ca(2+)-free saline, caesium-filled PCs generated large, plateau ADPs following an initial burst of fast spikes. Application of TTX suppressed these ADPs before solitary fast spikes appeared to be reduced. 6. Injection of brief, just subthreshold depolarizing current pulses into bursters evoked slow depolarizing potentials lasting up to 50 ms. These persisted after suppression of Ca2+ currents and were entirely blocked by TTX. 7. We conclude that active spike ADPs and intrinsic bursts in the somata of adult CA1 PCs are generated by a low voltage-gated, persistent Na+ current. Burst termination is mediated by voltage-gated K+ currents activated during the burst (most likely IM), rather than by the Ca(2+)-gated K+ currents Ic and IAHP. The latter currents downregulate the innate tendency of CA1 PCs to burst (Ic) and limit the rate of spontaneous burst firing (IAHP).

Properties of the hyperpolarization-activated cation current Ih in rat midbrain dopaminergic neurons

Intracellular electrophysiological recordings in current- and voltage-clamp mode were obtained from dopaminergic neurons of the rat mesencephalon in an in vitro slice preparation. In current-clamp mode, a time-dependent anomalous rectification (TDR) of the membrane was observed in response to hyperpolarizing current pulses. In single-electrode voltage-clamp mode, a slowly developing inward current (Ih) underlying the TDR was studied by hyperpolarizing voltage commands from a holding potential of -50 to -60 mV. Ih started to be activated at approximately -69 mV, was fully activated at -129 to -141 mV, with half-maximal activation at -87 mV, and showed no inactivation with time. The time course of development of Ih followed a single exponential, and its time constant was voltage-dependent. At -81 mV, Ih activated with a time constant of 379 +/- 47.6 ms, whereas at -129 mV Ih activated with a time constant of 65 +/- 2.2 ms. Its estimated reversal potential was -35 +/- 4 mV. Raising the extracellular concentration of K+ from 2.5 to 6.5 and to 12.5 mM increased the amplitude of Ih while reducing the extracellular concentration of Na+ from 153.2 to 27.2 mM caused a reduction in amplitude of Ih. Bath application of caesium (1-5 mM) reversibly reduced or blocked the TDR/Ih. Perfusion of tetrodotoxin (0.5-1 microM), tetraethylammonium (10-20 mM) or barium (0.3-2 mM) did not significantly affect Ih. Ih was also present in cells impaled with CsCl-filled electrodes.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation of adenylate cyclase attenuates the hyperpolarization following single action potentials in brain noradrenergic neurons independently of protein kinase A

Afterhyperpolarizations that follow action potentials are a prominent mechanism for the control of neuronal excitability. Such afterhyperpolarizations in many neurons are modulated by a variety of second messenger systems. Here, we examined the regulation of afterhyperpolarizations in noradrenergic locus coeruleus neurons by the adenylate cyclase system. Although superfusion of the adenylate cyclase activator, forskolin, had no effect on hyperpolarizations following trains of action potentials, both forskolin and a membrane permeable analog of cyclic AMP, 8-bromo-cyclic AMP, attenuated the amplitude of afterhyperpolarizations which followed single action potentials of locus coeruleus neurons recorded intracellularly in brain slices. In contrast, superfusion of 1,9-dideoxyforskolin, the forskolin analog that does not activate adenylate cyclase, had no effect on these single action potential afterhyperpolarizations. Co-application of a protein kinase inhibitor (H8, KT5720, staurosporin or Rp-cAMPS) with either forskolin or 8-bromo-cyclic AMP failed to block the reduction of afterhyperpolarization amplitude, but blocked the cyclic AMP-dependent enhancement of opiate responses in the same locus coeruleus neurons. Furthermore, application of a membrane permeable analog of 5'-AMP, 8-bromo-5'-AMP, the cyclic AMP metabolite that does not activate a protein kinase, potently reduced the amplitudes of single action potential afterhyperpolarizations. The afterhyperpolarization amplitude was also reduced in locus coeruleus neurons taken from chronically morphine-treated rats, a treatment known to increase adenylate cyclase activity. These results indicate that elevation of intracellular cyclic AMP or 5'-AMP reduces the single action potential afterhyperpolarization in locus coeruleus neurons. This action may be mediated through a mechanism independent of protein kinase activation.

Single-channel activity correlated with medium-duration, Ca-dependent K current in cultured rat hippocampal neurones

Whole-cell voltage- and patch-clamp techniques were used to record the calcium-dependent component of ImAHP and correlated single-channel activity in postnatal cultured rat hippocampal neurons. The Ca-dependent ImAHP was elicited by voltage steps to + 10 mV from a holding potential of -50 mV in the whole-cell mode. In cell-attached patches, single currents of approximately 2 pA were observed following spontaneous action currents. The duration of ensemble-averaged single-channel activity was very similar to that of the whole-cell ImAHP, approximately 100 ms. Both whole-cell current and single-channel activity could be blocked by bath-applied cadmium, 200 microM. Vigorous channel activity was evoked by bursts of action potentials that are known to elicit Ca-dependent AHPs. We conclude that this channel is a candidate for mediating ImAHP.

Comparison between the membrane and synaptic properties of human and rodent dentate granule cells

We have compared the cellular and synaptic properties of rodent dentate granule cells with those of humans. The human tissue was obtained from neurosurgical procedures which necessitated removal of the hippocampus for treatment of extra-hippocampal tumors which presented clinically with seizures. The hippocampi studied here were neuroanatomically similar to autopsy controls. The present studies have demonstrated that there are few differences between rodent and human granule cells as regards either their membrane properties or their synaptic physiology and pharmacology. The differences we noted were (1) less spike frequency adaptation in the human relative to rodent cells; and (2) perforant path stimulation reliably elicited both feedforward and feedback inhibition in the rodent cells, while in the human tissue feedback inhibition appeared to predominate. It is unclear if these changes are due to the seizure experience or if they represent true species differences.

Muscarinic modulation of conductances underlying the afterhyperpolarization in neurons of the rat basolateral amygdala

The excitability level of pyramidal neurons in the basolateral amygdala (BLA) is greatly increased following muscarinic receptor activation, an effect associated with an increased rate of action potential firing and reduction of the afterhyperpolarization (AHP). We impaled BLA pyramidal neurons in slices of rat ventral forebrain with a single microelectrode to examine the currents underlying the AHP and spike frequency accommodation and determine their sensitivities to muscarinic modulation. In voltage-clamp, depolarizing steps were followed by biphasic outward tail currents, consisting of rapidly decaying (IFast) and slowly decaying (ISlow) current components. These corresponded temporally with the medium and slow portions of the AHP, respectively. The reversal potential for the IFast component of the AHP tail current shifted in the depolarizing direction with increases in the extracellular K+ concentration. The amplitude of IFast was reduced during perfusion of 0-Ca2+ medium or by superfusion of TEA (1-5 mM) or carbachol (10-40 microM). It is suggested that IFast was produced by the rapidly decaying Ca(2+)-activated K+ current (IC) and the muscarinic-sensitive M-current (IM). The ISlow tail current component reversed at the estimated values for EK in medium containing either normal or elevated K+ levels. This component was eliminated by perfusion of 0-Ca2+ medium or inclusion of cyclic-AMP in the recording electrode. It was not blocked by TEA (5 mM) or apamin (50-500 nM), but was reduced by carbachol in a dose-dependent manner (IC50 = 0.5 microM). Electrical stimulation of cholinergic afferent pathways to the BLA produced inhibition of ISlow, an effect which was enhanced by eserine and prevented by atropine. Loss of the ISlow component was always accompanied by similar reductions in accommodation and the slow AHP. It was concluded that this tail current component resulted from the slowly decaying Ca(2+)-activated K+ current, IAHP. Thus, the muscarinic inhibition of IAHP contributes to the enhanced excitability exhibited by BLA pyramidal neurons following cholinergic stimulation.

Epileptic focus induced in rat by intrahippocampal cholera toxin: neuronal properties in vitro

Injecting 0.5-1.0 microgram of cholera toxin into rat hippocampus induces a chronic epileptic focus which generates interictal discharges and brief epileptic seizures intermittently over the following seven to 10 days. Here we examined the electrophysiological properties of hippocampal slices prepared from these rats three to four days after injection, at the height of the epileptic syndrome. These slices generated epileptic discharges in response to electrical stimulation of afferent pathways. In many cases epileptic discharges occurred spontaneously in the CA3 subregion; these usually lasted < 200 ms, but they could last < 0.6 s. Intracellular recordings from pyramidal layer cells revealed depolarization shifts synchronous with the epileptic field potentials. These depolarization shifts had slow onsets compared with those induced by blocking inhibition with bicuculline (depolarizations started a mean of 57 ms before, and reached 5.2 mV by, the onset of the cholera toxin epileptic field potential, compared with 12 ms and 3.6 mV respectively for 70 microM bicuculline methiodide). Extracellular unit recordings showed that the slow predepolarization seen in the cholera toxin focus was associated with an acceleration of the firing of other pyramidal layer neurons. The epileptic activity in this model cannot be attributed to the loss of synaptic inhibition, because inhibitory postsynaptic potentials could be evoked when the synchronous bursts were blocked by increasing [Ca2+]o from 2 to 8 mM. Observations of monosynaptic inhibitory postsynaptic currents isolated by application of 20 microM 6-cyano-7-nitroquinoxaline-2,3-dione, 50 microM DL-2-amino-5-phosphonovaleric acid and 100-200 microM 3-amino-2-(4-chlorophenyl)-2-hydroxy-propylsulphonic acid showed a small effect of the toxin only on the time course of the inhibitory postsynaptic current. On the other hand, there were significant changes in the intrinsic properties of individual neurons. The membrane potentials of cells in the cholera toxin focus did not differ from those in slices from rats injected with vehicle solution, but their input resistances were significantly increased. Unlike the other cellular changes in this model, the increase in input resistance was not seen in slices exposed acutely to 1 micrograms/ml cholera toxin for 30 min, suggesting there may be morphological changes in the chronic focus. Action potential accommodation and the slow afterhyperpolarization were depressed in both acute and chronic epileptic tissue, indicating impairments of Ca(2+)- and/or voltage-dependent K+ currents, and we conclude that these provide the most likely basis for cholera toxin epileptogenesis.

Ionic mechanisms underlying the depolarizing and hyperpolarizing afterpotentials of single spike in guinea-pig cingulate cortical neurons

Intracellular recordings and hybrid single-microelectrode voltage-clamp techniques were used to study the ionic mechanisms underlying the afterdepolarization and the subsequent slow afterhyperpolarization that followed a single action potential in layers V/VI neurons of the guinea-pig anterior cingulate cortex in in vitro slices. Both the afterdepolarization and afterhyperpolarization were markedly suppressed in size by addition of Co2+ or Cd2+, reduction in extracellular Ca2+, and intracellular EGTA injection. On the other hand, elevation of extracellular Ca2+ concentration augmented the amplitudes of the afterpotentials. The afterdepolarization amplitude was selectively depressed by the stilbene derivatives, 4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonate, disodium 3H2O, and 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid, disodium salt. Reduction in external Cl- and intracellular Cl- injection enhanced the afterdepolarization amplitude without affecting the afterhyperpolarization. The null potentials for the afterdepolarizations recorded with K acetate- and Cs acetate-electrodes were -68 and -63 mV, respectively. The slope of the null potential obtained with K acetate electrodes or Cs acetate electrodes was 49 and 53 mV, respectively, per log unit of the external Cl- concentration. Reduction in external K+ markedly depressed the afterdepolarization and augmented the afterhyperpolarization in size, whereas rise in external K+ markedly augmented the afterdepolarization and depressed the afterhyperpolarization. The null potential for the afterhyperpolarization recorded with K acetate electrodes was -94 mV. The slope of the null potential was 57 mV per log unit of the external K+ concentration. Reduction in extracellular Na+ concentration slightly depressed both the amplitudes of the afterdepolarization and afterhyperpolarization. A hybrid voltage-clamp analysis revealed a slow decaying inward current and a subsequent outward current that followed an action potential. Both the amplitudes of the inward current corresponding to afterdepolarization and the outward current corresponding to afterhyperpolarization were suppressed by addition of Co2+. Reduction in extracellular Cl- concentration augmented the inward current amplitude without significantly affecting the outward current. These results indicate that the afterdepolarization is mainly due to an increase in a Ca(2+)-activated Cl- conductance, while the afterhyperpolarization is mainly generated by an activation of Ca(2+)-mediated K+ conductance.

Different firing patterns generated in dendrites and somata of CA1 pyramidal neurones in guinea-pig hippocampus

1. Intracellular recordings, taken from CA1 pyramidal cells in guinea-pig hippocampal slices, were used to examine the origins of repetitive and burst firing in these cells. Single action potentials were elicited by depolarizing current injection at somatic recording sites. In contrast, current injection during intradendritic recordings initiated burst firing in the dendrites. Burst firing could be elicited in the soma by direct depolarization of distal apical dendrites (> 150 microns from the cell body layer) with large extracellular polarizing electrodes. 2. Intracellular recordings were taken simultaneously from the apical dendrites and pyramidal cell somata with the intention of impaling the same neurone with both electrodes. Paired dendrite-soma recordings confirmed that rhythmic single action potentials were generated at the cell soma, whereas bursts of action potentials were initiated in the distal apical dendrites (> 150 microns from the cell body layer). Fast spikes in the dendrite often triggered fast spikes in the soma, but not all fast spikes in the dendritic burst were 'relayed' to the soma. 3. In paired recordings, when a dendritic action potential failed to elicit a full somatic action potential, a 'd-spike' was commonly recorded in the soma. Somatic d-spikes were uniform all-or-none responses that could be shown, in some cases, to trigger the full somatic action potentials. 4. Attenuated spikes could be recorded in the dendrites, triggered by action potentials initiated at the cell soma. Dendritic responses to somatic stimulation sometimes varied in amplitude, but always showed a direct correspondence with somatic action potentials. 5. Dendritic recordings taken closer to the pyramidal cell bodies (< 150 microns from the cell body layer) showed a 'transitional' region where single action potentials rather than burst discharges could be evoked. After-potentials of these single spikes differed from those associated with somatic spikes in that proximal dendritic spikes had depolarizing after-potentials. The observed shift from after-hyperpolarization to depolarizing after-potentials in intradendritic recordings taken progressively further from the cell body corresponds to the change from repetitive to burst firing. 6. The results indicate that activity of the CA1 pyramidal cell soma, presumably a reflection of its output, can be either burst or repetitive firing. Somatic 'bursts,' unlike the burst discharges seen in the apical dendrites or the burst discharges reported in CA3 cells, are not initiated locally. Rather, they appear to be simply a rapid spike-for-spike response by the soma to the fast spikes that form part of the apical dendritic burst.(ABSTRACT TRUNCATED AT 400 WORDS)

An analysis of the long-lasting after-hyperpolarization of guinea-pig vagal motoneurones

1. The long-lasting after-hyperpolarization which characterizes the neurones of the dorsal motor nucleus of the vagus in the guinea-pig was studied in vitro. 2. Following a train of action potentials, vagal motoneurones develop a long-lasting after-hyperpolarization. Two different shapes of long-lasting after-hyperpolarization were encountered: an after-hyperpolarization which slowly (0.6-1.2 s) and monotonically developed to peak value; and a second type of long-lasting after-hyperpolarization where the onset of the slow component appears to be masked by an early, relatively fast component. Both shapes of long-lasting after-hyperpolarization depend on Ca2+ influx and increase as a function of the number of action potentials in the train. 3. A novel procedure was used to analyse the ionic processes which underlie the long-lasting after-hyperpolarization. The neuronal responses to a series of long (7 s) hyperpolarizing current pulses during the long-lasting after-hyperpolarization were recorded and the voltage-current curves at 600 different time points along the long-lasting after-hyperpolarization were plotted. The conductance and the reversal potential at each time point were calculated from the slope and the intersection of these curves, respectively. 4. Using this procedure it was found that the long-lasting after-hyperpolarization consists of two conductances that differ in kinetic properties and reversal potential: an early conductance which peaks shortly after the end of the train and decays in a few tenths of seconds (EAHP), and a late conductance which develops slowly (time to peak about 1 s) and decays in 3-8 s (LAHP). The reversal potential for the early conductance is 10 mV more positive than the reversal potential for the late conductance (-84 mV); the latter reversal potential is in agreement with the K+ equilibrium potential. The different shapes of long-lasting after-hyperpolarization can be explained by different ratios of these two conductances. 5. Noradrenaline (10 microM) selectively blocks the late conductance, without an observable effect on the Ca2+ action potential. 6. The behaviour of the noradrenaline-sensitive late conductance was analysed. The amplitude of the conductance change increased sigmoidally as a function of the number of spikes in the train. A log-log plot suggests that at least two Ca2+ ions participate in the opening of a K+ channel. 7. A model that accounts for the slow kinetics of the late conductance was constructed.(ABSTRACT TRUNCATED AT 400 WORDS)

A change from HCO3(-)-CO2- to hepes-buffered medium modifies membrane properties of rat CA1 pyramidal neurones in vitro

1. Intracellular recordings were obtained from CA1 pyramidal neurones in rat hippocampal slices. Perfusion with a HCO3(-)-CO2-free, HEPES-buffered medium at pH 7.4 produced a wide variety of reversible effects on neuronal excitability, compared to responses obtained under standard (21 mM-HCO3-, 5% CO2, pH 7.4) conditions. 2. Introduction of HCO3(-)-CO2-free medium most commonly elicited, within 5-20 min, a fall in resting membrane potential (Vm), a rise in threshold for Na(+)-dependent action potential generation, and a reduction in input resistance. Anomalous inward rectification in the hyperpolarizing direction and subthreshold inward rectification were commonly reduced in HEPES-buffered medium. More prolonged exposure (> or = 25 min) to HCO3(-)-CO2-free medium produced, on occasion, Na+ spike inactivation. 3. The amplitudes of the fast and medium after-hyperpolarizations (AHPs) following a single depolarizing current-evoked action potential were attenuated during perfusion with HEPES-buffered medium at pH 7.4, as was the composite AHP following a train of action potentials. 4. Perfusion with HEPES-buffered medium at pH 7.4 reduced the degree of spike frequency adaptation and abolished depolarizing current-evoked burst-firing behaviour when this was present under standard conditions. 5. In tetrodotoxin (TTX)- and tetraethylammonium (TEA)-poisoned neurones, perfusion with HCO3(-)-CO2-free medium at pH 7.4 slightly raised the threshold for activation of Ca(2+)-dependent potentials and slightly reduced their duration, compared to responses obtained in HCO3(-)-CO2-buffered medium at the same pH. The AHP following the Ca2+ spike was, however, markedly attenuated. 6. Perfusion with a low-pH HCO3(-)-CO2-buffered medium (7 mM-HCO3-, 5% CO2, pH 6.9) produced changes qualitatively similar to those observed during perfusion with HEPES-buffered medium at pH 7.4. Raising the pH of the HEPES-buffered medium to 7.8 or 7.9 reversed inconsistently and then only in part the changes noted on the transition from a HCO3(-)-CO2- to a HEPES-buffered medium at the same pH (7.4). 7. The effects noted are unlikely to be due to a direct action of HEPES itself on neuronal membrane conductances. Rather, I suggest that they are likely to be caused by intracellular acidosis consequent upon the omission of HCO3- and CO2 from the extracellular medium.

Muscarinic responses of rat basolateral amygdaloid neurons recorded in vitro

1. Intracellular recordings were obtained from pyramidal-type neurons in the basolateral amygdaloid nucleus (BLA) in slices of rat ventral forebrain and used to compare the actions of exogenously applied cholinomimetics to the effects produced by electrical stimulation of amygdalopetal cholinergic afferents from basal forebrain. 2. Bath application of carbachol depolarized pyramidal cells with an associated increase in input resistance (Ri), reduced the slow after-hyperpolarization (AHP) that followed a series of current-evoked action potentials and blocked spike frequency accommodation. All of these effects were reversed by the muscarinic antagonist atropine but not by the nicotinic antagonist hexamethonium. 3. Electrical stimulation of amygdaloid afferents within the external capsule evoked a series of synaptic potentials consisting of a non-cholinergic fast excitatory postsynaptic potential (EPSP), followed by early and late inhibitory postsynaptic potentials (IPSPs). Each of these synaptic potentials was reduced by carbachol in an atropine-sensitive manner. 4. Local application of carbachol to pyramidal cells produced a short-latency hyperpolarization followed by a prolonged depolarization. The hyperpolarization and depolarization to carbachol were blocked by atropine but not hexamethonium. 5. The carbachol-induced hyperpolarization was associated with a decrease in Ri and had a reversal potential nearly identical to that of the early IPSP. The inhibitory response was blocked by perfusion of medium containing tetrodotoxin (TTX), bicuculline or picrotoxin, while the subsequent depolarization was unaffected. On the basis of these data, it is concluded that the muscarinic hyperpolarization is mediated through the rapid excitation of presynaptic GABAergic interneurons in the slice. 6. The findings that the carbachol-induced depolarization was associated with an increase in Ri, often had a reversal potential below -80 mV, was sensitive to changes in extracellular potassium concentration and was blocked by intracellular ionophoresis of the potassium channel blocker caesium suggest that it resulted from a muscarinic blockade of one or more potassium conductances. 7. Repetitive stimulation of sites within the slice containing cholinergic afferents evoked a series of fast EPSPs followed by IPSPs. These non-cholinergic potentials were followed by a slow EPSP that lasted from 10 s-4 min. The slow EPSP was enhanced by eserine and blocked by atropine. It was also blocked by TTX or cadmium, indicating that it was dependent on spike propagation and calcium-dependent release of acetylcholine (ACh). 8. Stimulation of cholinergic afferents in the slice mimicked other effects produced by carbachol including blockade of the slow AHP and accommodation of action potential discharge and these actions were potentiated by eserine and blocked by atropine.(ABSTRACT TRUNCATED AT 400 WORDS)

Computer simulation of carbachol-driven rhythmic population oscillations in the CA3 region of the in vitro rat hippocampus

1. We used simulations of the in vitro CA3 region of the hippocampus to analyse the 5 Hz population oscillations recorded experimentally in carbachol. 2. A simulation model of the in vitro CA3 region was constructed with 1000 pyramidal neurones and 200 inhibitory neurones (100 producing fast inhibitory postsynaptic potentials (IPSPs) and 100 producing slow IPSPs of delayed onset). Each neurone contained nineteen soma-dendritic compartments. Pyramidal neurones contained six voltage- and/or calcium-dependent ionic currents, whose kinetics were consistent with voltage-clamp data. The connectivity and waveform of unitary synaptic events for excitatory and fast inhibitory synapses were consistent with dual intracellular recordings. This network was shown to generate previously described network oscillations, including synchronized bursts recorded in the presence of GABAA blockers, and synchronized synaptic potentials observed during partial blockade of GABAA inhibition. 3. The model generated 5 Hz oscillations as recorded in carbachol under the following conditions: (a) excitatory synaptic conductance was within a limited range; (b) there was blockade of fast and slow IPSPs (consistent with the experimental lack of effect of bicuculline and phaclofen on carbachol oscillations and the known depression of IPSPs by acetylcholine); (c) the after hyperpolarization (AHP) conductance was reduced (consistent with the known pharmacology of carbachol); (d) the apical dendrites of the pyramidal cells were depolarized, as suggested by the carbachol-induced depolarization of pyramidal neurones. Each oscillation was associated in pyramidal cells with a burst of action potentials riding on a depolarizing wave. The N-methyl-D-aspartate (NMDA) type of excitatory synapse was not necessary for the oscillations to occur. 4. Progressive reduction of excitatory synaptic strength led to an oscillation of the same frequency, with bursts riding on smaller EPSPs (consistent with the experiment). Further reduction of excitatory synaptic strength abolished the population oscillation by uncoupling the neurones. When excitatory synaptic conductance was too large, population oscillations were attenuated as the cells switched from a bursting mode to a repetitively firing mode. 5. Increasing the AHP conductance prolonged the interburst interval as expected. Inclusion of slow IPSPs exerted a similar effect. 6. When fast IPSPs were included, an oscillation with different characteristics emerged: a 10 Hz oscillation that was gated by compound GABAA IPSPs. On any oscillatory wave, few pyramidal neurones fired, and the firing of individual neurones was irregular.(ABSTRACT TRUNCATED AT 400 WORDS)

Cesium potentiates epileptiform activities induced by bicuculline methiodide in rat neocortex maintained in vitro

We report that extracellular application of cesium (Cs+, 3 mM) potentiated the epileptiform discharge evoked by GABAA-receptor antagonist bicuculline methiodide (BMI 50 microM) in rat neocortical slices maintained in vitro. Cs+ changed BMI-induced epileptiform burst of a few hundred milliseconds evoked by extracellular focal stimuli into epileptiform discharge only a few seconds long (1.8-7 s). Moreover, Cs+ induced the appearance of spontaneously occurring epileptiform activities (0.038-0.15 Hz). Simultaneous intracellular/extracellular recordings indicated that each intracellular epileptiform burst was correlated with a field discharge. Variation of the membrane potential modified only the amplitude of the epileptiform burst and did not alter its frequency of occurrence, indicating that each discharge was a synchronous population event. The epileptiform discharges were not blocked by the N-methyl-D-aspartate (NMDA) receptor antagonist 3-((+-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP 5-10 microM). In contrast, the non-NMDA receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX 0.5-5 microM) greatly reduced the duration of each epileptiform discharge by abolishing its afterdischarges in a concentration-dependent manner. This reduction in duration was accompanied by an increase in frequency of occurrence, however. After blockade of non-NMDA receptors with CNQX, a CPP-sensitive spontaneous discharge could be observed. These findings indicate that the inorganic cation Cs+ applied extracellularly can induce spontaneously occurring epileptiform activities in BMI-treated neocortical slices. In addition, receptors of excitatory amino acids play a major role in synchronizing this type of Cs+/BMI-induced spontaneous epileptiform activities.

Electrophysiological responses to muscarinic receptor stimulation in cultured hippocampal neurons

Electrophysiological recordings of responses to muscarinic receptor stimulation in cultured embryonic hippocampal neurons have been largely unsuccessful to date. In this study muscarinic receptor binding was demonstrated in 2-week-old embryonic rat hippocampal cultures. Using whole-cell patch-clamp recording we found that 1-5 microM carbachol produced multiple effects including depolarization, increased action potential firing rate, increased synaptic activity and a reduction in the amplitude of medium-duration afterhyperpolarizations. Voltage-clamp analysis revealed a time-dependent current relaxation with hyperpolarizing steps from a holding potential of about -40 mV which was inhibited by 10 microM muscarine or 50 microM carbachol and had characteristics similar to those of the m-current. Both atropine and pirenzepine inhibited all of these effects indicating that these cholinergic actions were mediated by muscarinic receptors. This study shows that muscarinic responses obtained classically in hippocampal brain slices can also be produced in cultured hippocampus.

Contributions of low-threshold calcium current and anomalous rectifier (Ih) to slow depolarizations underlying burst firing in human neocortical neurons in vitro

The slow depolarization that underlies the voltage-dependent burst-firing behavior of human neocortical neurons is mediated by a low-threshold calcium conductance in concert with the anomalous rectifier current, Ih. The slow depolarization could be elicited by depolarization from negative membrane potentials or as a rebound following hyperpolarization. The rebound depolarization was time- and voltage-dependent. Most of the slow depolarization was blocked by inorganic calcium blockers. The remainder of the depolarization and the 'sag' in the hyperpolarizing voltage responses were blocked by extracellular Cs+.