Spontaneous Bursts Of Action Potentials Research Articles

Astrocytes mediate cell non-autonomous correction of aberrant firing in human FXS neurons

Pre-clinical studies of fragile X syndrome (FXS) have focused on neurons, with the role of glia remaining largely underexplored. We examined the astrocytic regulation of aberrant firing of FXS neurons derived from human pluripotent stem cells. Human FXS cortical neurons, co-cultured with human FXS astrocytes, fired frequent short-duration spontaneous bursts of action potentials compared with less frequent, longer-duration bursts of control neurons co-cultured with control astrocytes. Intriguingly, bursts fired by FXS neurons co-cultured with control astrocytes are indistinguishable from control neurons. Conversely, control neurons exhibit aberrant firing in the presence of FXS astrocytes. Thus, the astrocyte genotype determines the neuronal firing phenotype. Strikingly, astrocytic-conditioned medium, and not the physical presence of astrocytes, is capable of determining the firing phenotype. The mechanistic basis of this effect indicates that the astroglial-derived protein, S100β, restores normal firing by reversing the suppression of a persistent sodium current in FXS neurons.

MicroRNA miR-133a-3p Facilitates Adrenergic Proarrhythmic Ectopy in Rat Pulmonary Vein Myocardium by Increasing cAMP Content.

Cardiac-specific microRNA miR-133a-3p modulates adrenergic signaling. Adrenergic receptors and their intracellular pathways are the key players in proarrhythmic ectopy derived from the myocardial sleeves of the pulmonary veins. We studied the effect of miR-133a-3p on ectopy induced by norepinephrine in myocardial tissue of rat pulmonary veins. Using microelectrode technique, we revealed facilitation of proarrhythmic pattern of spontaneous bursts of action potentials induced by norepinephrine in tissue preparations of the pulmonary veins isolated from rats in 24 h after injection of a transfection mixture containing miR-133a-3p (1 mg/kg) in vivo. According to ELISA data, the cAMP level in the pulmonary vein myocardium of rats receiving miR-133a-3p was 2-fold higher than in control animals. Bioinformatic analysis showed that mRNA of protein phosphatases and some phosphodiesterases are most probable targets of miR-133a-3p. The proarrhythmic effect of miR-133a-3p can be related to inhibition of the expression of phosphodiesterases accompanied by cAMP accumulation and increased intracellular β-adrenergic signaling.

The unusual action of essential oil component, menthol, in potentiating the effect of the carbamate insecticide, bendiocarb

Standard chemical insecticides present mainly neurotoxic effects and are becoming less and less effective due to insects developing resistance to them. One of the innovative strategies to control insects pests is to find a way to increase the sensitivity of the target sites in the insect nervous system to the applied insecticides. In the presented research, we proposed menthol, a component of essential oils, as a factor increasing the effectiveness of bendiocarb, a carbamate insecticide. The aim of our study was to evaluate the potentiation of the bendiocarb effect by menthol. In toxicity tests performed on Periplaneta americana, menthol (0.1 μM) accelerated the lethal effect of bendiocarb, primarily in its low concentrations (lower than 0.05 mM). In the presence of menthol (1 and 0.1 μM), the ability of insects to turn back from its dorsal to the normal ventral side was significantly lower than with bendiocarb (1 μM) alone. We also evaluated the effectiveness of chemicals on the activity of the ventral nerve cord of the cockroach. In this preparation, bendiocarb (1 μM and higher concentrations) caused an irregular, spontaneous bursts of action potentials. The total nerve activity (including the response to stimulation and spontaneous firing) was much higher when bendiocarb was applied in the presence of menthol (1 μM). The effect of menthol was similar to the octopamine effect and was abolished by phentolamine, the octopamine receptor antagonist. Our results clearly indicated a strengthening effect of menthol on bendiocarb effectiveness; potentiation occurred through octopamine receptors activation.

Monocular enucleation alters retinal waves in the surviving eye

BackgroundActivity in neurons drives afferent competition that is critical for the refinement of nascent neural circuits. In ferrets, when an eye is lost in early development, surviving retinogeniculate afferents from the spared eye spread across the thalamus in a manner that is dependent on spontaneous retinal activity. However, how this spontaneous activity, also known as retinal waves, might dynamically regulate afferent terminal targeting remains unknown.MethodsWe recorded retinal waves from retinae ex vivo using multi-electrode arrays. Retinae came from ferrets who were binocular or who had one eye surgically removed at birth. Linear mixed effects models were used to investigate the effects of early monocular enucleation on retinal wave activity.ResultsWhen an eye is removed at birth, spontaneous bursts of action potentials by retinal ganglion cells (RGCs) in the surviving eye are shorter in duration. The shortening of RGC burst duration results in decreased pairwise RGC correlations across the retina and is associated with the retinal wave-dependent spread of retinogeniculate afferents previously reported in enucleates.ConclusionOur findings show that removal of the competing eye modulates retinal waves and could underlie the dynamic regulation of competition-based refinement during retinogeniculate development.

Sodium channel NaV1.3 is important for enterochromaffin cell excitability and serotonin release

In the gastrointestinal (GI) epithelium, enterochromaffin (EC) cells are enteroendocrine cells responsible for producing >90% of the body’s serotonin (5-hydroxytryptamine, 5-HT). However, the molecular mechanisms of EC cell function are poorly understood. Here, we found that EC cells in mouse primary cultures fired spontaneous bursts of action potentials. We examined the repertoire of voltage-gated sodium channels (NaV) in fluorescence-sorted mouse EC cells and found that Scn3a was highly expressed. Scn3a-encoded NaV1.3 was specifically and densely expressed at the basal side of both human and mouse EC cells. Using electrophysiology, we found that EC cells expressed robust NaV1.3 currents, as determined by their biophysical and pharmacologic properties. NaV1.3 was not only critical for generating action potentials in EC cells, but it was also important for regulating 5-HT release by these cells. Therefore, EC cells use Scn3a-encoded voltage-gated sodium channel NaV1.3 for electrical excitability and 5-HT release. NaV1.3-dependent electrical excitability and its contribution to 5-HT release is a novel mechanism of EC cell function.

Characterization of spontaneous electric activity of the myometrial rhythmogenic areas in rats

Spontaneous bursts of action potentials in the myometrial rhythmogenic areas (ovarian and cervical horn regions, uterine corpus) of nonpregnant rats were investigated. The basic spike parameters (frequency, amplitude, peak rise rate, peak rise time and peak half width) registered simultaneously from these active areas under normal conditions were analyzed using a complex elecrophysiological and morphohistochemical approach. The ovarian horn region generates high-amplitude spikes far exceeding in magnitude those in the other two regions. While there are small differences between peak frequencies in all three rhythmogenic areas, the peak rise rate is also the greatest in the ovarian horn region. In contrast, the peak rise time and peak half width are the smallest in this region. It is concluded that there is a significant difference between the rhythmogenic activity parameters of the ovarian horn region as compared to more congenerous parameters of the other two pacemaker areas. Morphohistochemical analysis revealed the largest aggregation of the functionally active cells in the ovarian horn region at the border between the myometrium and serous membrane. In the cervical horn region, no similar cell aggregations were found. Thus, our electrophysiological data correlate with the morphological findings.

Spatiotemporal pattern of action potential firing in developing inner hair cells of the mouse cochlea

Inner hair cells (IHCs) are the primary transducer for sound encoding in the cochlea. In contrast to the graded receptor potential of adult IHCs, immature hair cells fire spontaneous calcium action potentials during the first postnatal week. This spiking activity has been proposed to shape the tonotopic map along the ascending auditory pathway. Using perforated patch-clamp recordings, we show that developing IHCs fire spontaneous bursts of action potentials and that this pattern is indistinguishable along the basoapical gradient of the developing cochlea. In both apical and basal IHCs, the spiking behavior undergoes developmental changes, where the bursts of action potential tend to occur at a regular time interval and have a similar length toward the end of the first postnatal week. Although disruption of purinergic signaling does not interfere with the action potential firing pattern, pharmacological ablation of the α9α10 nicotinic receptor elicits an increase in the discharge rate. We therefore suggest that in addition to carrying place information to the ascending auditory nuclei, the IHCs firing pattern controlled by the α9α10 receptor conveys a temporal signature of the cochlear development.

Two Types of Burst Firing in Gonadotrophin‐Releasing Hormone Neurones

Gonadotrophin-releasing hormone (GnRH) neurones fire spontaneous bursts of action potentials, although little is understood about the underlying mechanisms. In the present study, we report evidence for two types of bursting/oscillation driven by different mechanisms. Properties of these different types are clarified using mathematical modelling and a recently developed active-phase/silent-phase correlation technique. The first type of GnRH neurone (1-2%) exhibits slow (∼0.05 Hz) spontaneous oscillations in membrane potential. Action potential bursts are often observed during oscillation depolarisation, although some oscillations were entirely subthreshold. Oscillations persist after blockade of fast sodium channels with tetrodotoxin (TTX) and blocking receptors for ionotropic fast synaptic transmission, indicating that they are intrinsically generated. In the second type of GnRH neurone, bursts were irregular and TTX caused a stable membrane potential. The two types of bursting cells exhibited distinct active-phase/silent-phase correlation patterns, which is suggestive of distinct mechanisms underlying the rhythms. Further studies of type 1 oscillating cells revealed that the oscillation period was not affected by current or voltage steps, although amplitude was sometimes damped. Oestradiol, an important feedback regulator of GnRH neuronal activity, acutely and markedly altered oscillations, specifically depolarising the oscillation nadir and initiating or increasing firing. Blocking calcium-activated potassium channels, which are rapidly reduced by oestradiol, had a similar effect on oscillations. Kisspeptin, a potent activator of GnRH neurones, translated the oscillation to more depolarised potentials, without altering period or amplitude. These data show that there are at least two distinct types of GnRH neurone bursting patterns with different underlying mechanisms.

Effects of Random External Background Stimulation on Network Synaptic Stability After Tetanization: A Modeling Study

We constructed a simulated spiking neural network model to investigate the effects of random background stimulation on the dynamics of network activity patterns and tetanus induced network plasticity. The simulated model was a "leaky integrate-and-fire" (LIF) neural model with spike-timing-dependent plasticity (STDP) and frequency-dependent synaptic depression. Spontaneous and evoked activity patterns were compared with those of living neuronal networks cultured on multi-electrode arrays. To help visualize activity patterns and plasticity in our simulated model, we introduced new population measures called Center of Activity (CA) and Center of Weights (CW) to describe the spatio-temporal dynamics of network-wide firing activity and network-wide synaptic strength, respectively. Without random background stimulation, the network synaptic weights were unstable and often drifted after tetanization. In contrast, with random background stimulation, the network synaptic weights remained close to their values immediately after tetanization. The simulation suggests that the effects of tetanization on network synaptic weights were difficult to control because of ongoing synchronized spontaneous bursts of action potentials, or "barrages." Random background stimulation helped maintain network synaptic stability after tetanization by reducing the number and thus the influence of spontaneous barrages. We used our simulated network to model the interaction between ongoing neural activity, external stimulation and plasticity, and to guide our choice of sensory-motor mappings for adaptive behavior in hybrid neural-robotic systems or "hybrots."

The role of early neural activity in the maturation of turtle retinal function.

In the developing vertebrate retina, ganglion cells fire spontaneous bursts of action potentials long before the eye becomes exposed to sensory experience at birth. These early bursts are synchronised between neighbouring retinal ganglion cells (RGCs), yielding unique spatiotemporal patterns: 'waves' of activity sweep across large retinal areas every few minutes. Both at retinal and extraretinal levels, these embryonic retinal waves are believed to guide the wiring of the visual system using hebbian mechanisms of synaptic strengthening. In the first part of this review, we recapitulate the evidence for a role of these embryonic spontaneous bursts of activity in shaping developing complex receptive field properties of RGCs in the turtle embryonic retina. We also discuss the role of visual experience in establishing RGC visual functions, and how spontaneous activity and visual experience interact to bring developing receptive fields to maturation. We have hypothesised that the physiological changes associated with development reflect modifications in the dendritic arbours of RGCs, the anatomical substrate of their receptive fields. We demonstrate that there is a temporal correlation between the period of receptive field expansion and that of dendritic growth. Moreover, the immature spontaneous activity contributes to dendritic growth in developing RGCs. Intracellular staining of RGCs reveals, however, that immature receptive fields only rarely show direct correlation with the layout of the corresponding dendritic tree. To investigate the possibility that not only the presence of the spontaneous activity, but even the precise spatiotemporal patterns encoded in retinal waves might contribute to the refinement of retinal neural circuitry, first we must clarify the mechanisms mediating the generation and propagation of these waves across development. In the second part of this review, we present evidence that turtle retinal waves, visualised using calcium imaging, exhibit profound changes in their spatiotemporal patterns during development. From fast waves sweeping across large retinal areas and recruiting many cells on their trajectory at early stages, waves become slower and eventually stop propagating towards hatching, when they become stationary patches of neighbouring coactive RGCs. A developmental switch from excitatory to inhibitory GABAA responses appears to mediate the modification in spontaneous activity patterns while the retina develops. Future chronic studies using specific spatiotemporal alterations of the waves will shed a new light on how the wave dynamics help in sculpting retinal receptive fields.

CAMP modulates the excitability of immortalized H=hypothalamic (GT1) neurons via a cyclic nucleotide gated channel.

GT1 cells are immortalized hypothalamic neurons that show spontaneous bursts of action potentials and oscillations in intracellular calcium concentration [Ca(2+)](i), as well as pulsatile release of GNRH: We investigated the role of cyclic nucleotide gated (CNG) channels in the activity of GT1 neurons using patch clamp and calcium imaging techniques. Excised patches from GT1 cells revealed single channels and macroscopic currents that were activated by either cAMP or cGMP. CNG channels from GT1 cells showed rapid transitions from open to closed states typical of heteromeric CNG channels, were selective for cations, and had an estimated single channel conductance of 60 picosiemens (pS). Ca(2+) inhibited the conductance of macroscopic currents and caused rectification of currents at increasingly positive and negative potentials. The membrane permeant cAMP analog Sp-cAMP-monophosphorothioate (Sp-cAMPS) increased the frequency of spontaneous Ca(2+) oscillations in GT1 cells, whereas the Rp-cAMPS isomer had only a slight stimulatory effect on Ca(2+) signaling. Forskolin, norepinephrine, and dopamine, all of which stimulate cAMP production in GT1 cells, each increased the frequency of Ca(2+) oscillations. The effects of Sp-cAMPS or NE on Ca(2+) signaling did not appear to be mediated by protein kinase A, since treatment with either H9 or Rp-cAMPS did not inhibit the response. The CNG channel inhibitor L-cis-diltiazem inhibited cAMP-activated channels in GT1 cells. Both L-cis-diltiazem and elevated extracellular Ca(2+) reversibly inhibited the stimulatory effects of cAMP-generating ligands or Sp-cAMP on Ca(2+) oscillations. These results indicate that CNG channels play a primary role in mediating the effects of cAMP on excitability in GT1 cells, and thereby may be important in the modulation of GnRH release.

Patterns of spontaneous activity and morphology of interneuron types in organotypic cortex and thalamus–cortex cultures

The physiological and morphological properties of interneurons in infragranular layers of rat visual cortex have been studied in organotypic cortex monocultures and thalamus–cortex co-cultures using intracellular recordings and biocytin injections. Cultures were prepared at the day of birth and maintained for up to 20 weeks. Twenty-nine interneurons of different types were characterized, in addition to 170 pyramidal neurons. The cultures developed a considerable degree of synaptically driven “spontaneous” bioelectric activity without epileptiform activity. Interneurons in cortex monocultures and thalamus–cortex co-cultures had the same physiological and morphological properties, and also pyramidal cell properties were not different in the two culture conditions. All interneurons and the majority of pyramidal cells displayed synaptically driven action potentials. The physiological group of fast-spiking interneurons included large basket cells, columnar basket cells (two cells with an arcade axon) and horizontally bitufted cells. The physiological group of slow-spiking interneurons included Martinotti cells and a “long-axon” cell. Analyses of the temporal patterns of activity revealed that fast-spiking interneurons have higher rates of spontaneous activity than slow-spiking interneurons and pyramidal cells. Furthermore, fast-spiking interneurons fired spontaneous bursts of action potentials in the gamma frequency range. We conclude from these findings that physiological and morphological properties of interneurons in organotypic mono- and co-cultures match those of interneurons characterized in vivo or in acute slice preparations, and they maintain in long-term cultures a well-balanced state of excitation and inhibition. This suggests that cortex-intrinsic or cell-autonomous mechanisms are sufficient for the expression of cell type-specific electrophysiological properties in the absence of afferents or sensory input.

The first-order giant neurons of the giant fiber system in the squid: electrophysiological and ultrastructural observations.

The giant fiber system controlling mantle contraction used for jet propulsion in squid consists of two sets of three giant neurons organized in tandem. The somata of the 1st- and 2nd-order giant cells are located in the brain, while the perikarya of the 3rd-order giant cells are encountered in the stellate ganglia of the mantle. The somata and dendrites of one fused pair of 1st-order giant cells are thought to receive synaptic input from the eye, statocyst, skin proprioceptors, and supraesophageal lobes. To define the cellular properties for integration of such an extensive synaptic load, especially given its diversity, intracellular recordings and electron microscopic observations were performed on 1st-order giant cells in an isolated head preparation. Spontaneous bursts of action potentials and spikes evoked by extracellular stimulation of the brachial lobe were sensitive to the Na+ channel blocker TTX. Action potentials were also abolished by recording with microelectrodes containing the membrane impermeant, use dependent Na+ channel blocker QX-314. The small action potential amplitude and the abundant synaptic input imply that the spike initiation zone is remotely located from the recording site. The high spontaneous activity in the isolated head preparation, as well as the presence of synaptic junctions resembling inhibitory synapses, suggest; that afferent synapses on 1st-order giant neurons might represent the inhibitory control of the giant fiber system. The characterization of the electroresponsive properties of the 1st-order giant neurons will provide a description of the single cell integrative properties that trigger the rapid jet propulsion necessary for escape behavior in squid.

Effects of temperature on neuronal bursting in guinea-pig hippocampal slices

In guinea-pig hippocampal slices, activity of CA1 and CA3 neurons (pyramidal layer) during temperature changes was extracellularly recorded. A sharp increase in the rate of spontaneous bursts of action potentials as well as in the number of spikes in a burst during low-amplitude warming in a functional temperature range (36–40°C) was found. Cessation of warming was followed by a recovery of these parameters to the initial values irrespective of the temperature (between 32 and 40°C) at which stabilization occurred. In a functional temperature range (36–40°C), continuous slow cooling inhibited neuronal bursting activity. It is suggested that temporal extension of neuronal bursting in response to continuous temperature rise may play a role in the generation of febrile of febrile seizures.

CAMP-dependent protein kinase modulates expiratory neurons in vivo.

The adenosine 3',5'-cyclic monophosphate (cAMP)-dependent protein kinase (PKA) second-messenger system influences neuronal excitability by modulating voltage-regulated and transmitter-activated channels. In this study we investigated the influence of the cAMP-PKA system on the excitability of expiratory (E) neurons in the caudal medulla of anesthetized, paralyzed, and artificially ventilated adult cats. We intracellularly injected the PKA inhibitors cAMP-dependent PKA inhibitor 5-22 amide (Walsh inhibitory peptide) and Rp-adenosine 3',5'-cyclic monophosphothioate triethylamine (Rp-cAMPS), the PKA activator Sp-adenosine 3',5'-cyclic monophosphothioate triethylamine (Sp-cAMPS), and the adenylyl cyclase activator forskolin and measured membrane potential, neuronal input resistance, and synaptic membrane currents. Inhibition of cAMP-PKA activity by Walsh inhibitory peptide or Rp-cAMPS injections hyperpolarized neurons, decreased input resistance, and depressed spontaneous bursts of action potentials. Action potential duration was shortened and afterhyperpolarizations were increased. Inhibitory synaptic currents increased significantly. Stimulation of cAMP-PKA activity by Sp-cAMPS or forskolin depolarization neurons and increased input resistance. Spontaneous inhibitory synaptic currents were reduced and excitatory synaptic currents were increased. Rp-cAMPs depressed stimulus-evoked excitatory postsynaptic potentials and currents, whereas Sp-cAMPS increased them. Sp-cAMPS also blocked postsynaptic inhibition of E neurons by 8-hydroxy-dipropylaminotetralin, a serotonin-1A (5-HT-1A) receptor agonist that depresses neuronal cAMP-PKA activity. To determine the predominant effect of G protein-mediated neuromodulation of E neurons, we injected guanosine-5'-O-(3-thiotriphosphate) tetralithium salt (GTP-gamma-S), an activator of both stimulatory and inhibitory G proteins. GTP-gamma-S hyperpolarized E neurons, reduced input resistance, and increased action potential afterhyperpolarization. We conclude that the intracellular cAMP-PKA messenger system play an important role in the activity-dependent modulation of excitability in E neurons of the caudal medulla. In addition, the cAMP-PKA pathway itself is downregulated during activation of 5-HT-1A receptors.

Influence of spontaneous activity and visual experience on developing retinal receptive fields

Background The role played by early neural activity in shaping retinal functions has not yet been established. In the developing vertebrate retina, ganglion cells fire spontaneous bursts of action potentials before the onset of visual experience. This spontaneous bursting disappears shortly after birth or eye opening. In the present study, we have investigated whether the outgrowth of receptive fields in turtle retinal ganglion cells is affected by early spontaneous bursting or by early visual experience.Results Ganglion cells normally stop bursting spontaneously 2–4 weeks posthatching, the time when receptive-field areas reach adult size. When turtles are reared in the dark, the spontaneous bursting persists. Concomitantly, receptive-field areas expand to more than twice those observed in normal adults. To test whether chronic blockade of spontaneous bursting inhibits the expansion of developing receptive-field areas, we have exposed the retina to curare, a nicotinic cholinergic antagonist, because spontaneous bursting by ganglion cells requires acetylcholine. Curare was released from Elvax, a slow-release polymer that was implanted in the eye. When spontaneous bursting was chronically blocked with curare in hatchlings, dark-induced expansion of receptive fields was abolished. Moreover, receptive fields of ganglion cells exposed to curare in hatchlings reared in normal light and dark cycles were smaller than normal.Conclusions These results strongly suggest that early, acetylcholine-dependent spontaneous bursts of activity control the outgrowth of receptive-field areas in retinal ganglion cells. The onset of visual experience induces the disappearance of the immature spontaneous bursts, resulting in the stabilization of receptive-field areas to their mature size.

Mechanisms of spontaneous calcium oscillations and action potentials in immortalized hypothalamic (GT1-7) neurons

1. Individual immortalized gonadotropin-releasing hormone (GnRH)-secreting hypothalamic (GT1-7) neurons in semiconfluent cultures showed spontaneous oscillations in intracellular Ca2+ concentration ([Ca2+]i) as measured by video fluorescence microscopy and fura-2. In parallel experiments, GT1-7 neurons also showed spontaneous bursts of action potentials that were recorded as action currents from intact cells. The bursts of action currents occurred in characteristic patterns, suggesting an underlying rhythmic oscillation in membrane potential. 2. Depolarization with increased extracellular K+ evoked a concentration-dependent increase in the frequency of Ca2+ oscillations or a sustained plateau of increased [Ca2+]i in GT1-7 neurons. Increased extracellular K+ (30 mM) caused an initial increase in the frequency of action currents, after which they were reversibly abolished. 3. The Ca2+ channel blockers Ni2+ and nimodipine abolished Ca2+ oscillations, whereas nifedipine, gadolinium, omega-conotoxin and omega-agatoxin had no effect on Ca2+ oscillations. These results indicate that Ca2+ oscillations are generated by influx of Ca2+ through voltage-gated Ca2+ channels that are not sensitive to nifedipine and are not N-type or P-type channels. 4. Thapsigargin caused a small, transient rise in baseline [Ca2+]i but had no effect on Ca2+ oscillations. Caffeine and ryanodine had no effect on baseline [Ca2+]i or Ca2+ oscillations. These results indicate that the release of Ca2+ from inositol 1,4,5-trisphosphate (IP-3)-sensitive or caffeine sensitive intracellular stores does not play a major role in Ca2+ oscillations in GT1-7 neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

Somatostatin activates an inwardly rectifying K+ conductance in freshly dispersed rat somatotrophs.

1. Somatotrophs from enzymatically dispersed anterior pituitary glands of rats, enriched to greater than 94% purity by density gradient centrifugation, were studied within 16 h of isolation using patch clamp recording methods in the conventional whole-cell and the perforated-patch configurations. 2. Rhythmic oscillations of membrane potential gave rise to action potentials in thirty-six of fifty-two cells studied with the perforated-patch technique. Membrane potential oscillated between approximately -70 mV and approximately -25 mV with an average frequency (mean +/- S.D.) of 0.9 +/- 0.9 s-1. 3. The current-voltage (I-V) relationship of cells was linear at negative potentials with outward rectification at potentials positive to -40 mV. Evidence that the outward current was due to K+ channels came from the deactivation tail currents, which reversed direction close to the K+ equilibrium potential (EK). The reversal potential shifted 60 mV per tenfold change of external K+ concentration ([K+]o), as expected for K+ current. 4. Suppression of outward current by tetraethylammonium (TEA) provided additional evidence for K+ current. Cd2+ reduced outward current, suggesting the presence of Ca(2+)-activated K+ conductance. 5. Depolarizing commands elicited transient inward Na+ current and a sustained Ca2+ current (ICa). ICa was recorded in isolation with Cs+ and TEA in the recording pipette and 10 mM-Ba2+ as the charge carrier. Activation of ICa began at approximately -40 mV, with peak inward current at 0 to +10 mV. The half-inactivation potential was approximately -35 mV. In addition, ICa was blocked by nifedipine. These characteristics indicate the presence of L-type Ca2+ channels in somatotrophs. 6. Somatostatin caused hyperpolarization and suppressed the spontaneous bursts of action potentials. Under voltage clamp, somatostatin activated an inwardly rectifying current that reversed direction near EK. When EK was altered by elevation of [K+]o, the reversal potential of the somatostatin-induced current shifted 55 mV per tenfold change of [K+]o, as predicted for a K+ current by the Nernst relation. The somatostatin-induced conductance (gK) was greater at more negative potentials, and the activation range shifted positive with elevation of [K+]o. 7. We conclude that freshly isolated rat somatotrophs possess Na+, Ca2+ and K+ currents. A large proportion of the cells exhibit spontaneous bursts of action potentials. Somatostatin activates an inwardly rectifying K+ conductance, causing hyperpolarization and cessation of spontaneous action potential activity, actions that would contribute to suppression of growth hormone release.

Electrical and mechanical responses to inhibition of cell respiration in vascular smooth muscle of the rat portal vein.

Metabolic regulation of contractility in vascular smooth muscle was studied in the spontaneously active rat portal vein using respiratory depression by cyanide (0.2-2.0 mM) as a model for tissue hypoxia. Intracellular recordings of electrical activity were done with concomitant registration of force development. Average membrane potential in the absence of cyanide was -61 +/- 1 mV (n = 27). Addition of cyanide to normal Krebs solution resulted in a reduction of force amplitude and the number of action potentials per burst, with a relatively more pronounced effect on the mechanical activity. At moderate levels of inhibition of force amplitude the frequency of spontaneous bursts of action potentials transiently increased concomitant with a slight depolarization, but after prolonged (15-20 min) exposure to cyanide the membrane repolarized to the level prior to cyanide addition and the burst frequency decreased to be equal to or lower than that in the absence of cyanide. Higher concentrations of cyanide totally inhibited spontaneous mechanical and electrical activity. In contrast to the results with glucose, it was found that when beta-hydroxybutyrate was used as substrate the addition of 2 mM cyanide led to a marked hyperpolarization (13 +/- 1 mV) after total inhibition of spontaneous activity. The hyperpolarization was not prevented by administration of 4-aminopyridine (2.5 mM) or tetraethylammonium (4-6 mM) prior to the addition of cyanide. To investigate the effects of increased metabolic demand on the relation between force and membrane potential in cyanide-treated muscle, high-K+ (40 mM) contractures were studied. Contractures were associated with depolarization of 34 +/- 3 mV (n = 5). 1 mM cyanide reduced the amplitude of the contractures to about 9% of control with a moderate reduction in the amount of depolarization (28 +/- 1 mV, n = 5). It is concluded that the decrease of mechanical activity during respiratory inhibition may partly reflect a reduction in the number of spikes per burst but that other mechanisms, independent of membrane activity, also contribute to the inhibition. The increase of glycolysis during respiratory inhibition seems to prevent more pronounced changes in membrane potential.

Voltage clamp discloses slow inward current in hippocampal burst-firing neurones.

Hippocampal pyramidal cells, among the most-studied cortical neurones, display several interesting properties. In particular, intracellular recordings in both in vivo1 and in vitro2 preparations have shown that the pyramidal neurones of the CA3 region of the hippocampus have, in addition to the more conventional single spike, the capacity to generate spontaneous bursts of action potentials (APs). The burst-firing patterns have been well documented, but their underlying electrophysiological mechanisms are not completely understood. The bursts seem to be an intrinsic response of individual neurones and can be triggered by weak orthodromic stimulation or by direct depolarization of the somatic membrane. In molluscan and spinal systems, voltage-clamp techniques have revealed slow, voltage-sensitive, inward currents underlying this type of firing behaviour3–7. The use of these voltage-clamp techniques to study this phenomenon in hippocampal neurones has previously been precluded by the small size of the neurones and by the difficulty of recording from them in intact preparations. However, the development of methodology for voltage-clamping with a single microelectrode (SEC)8 and for the maintenance of hippocampal slices in vitro9 has made it possible for us to examine the membrane currents in these CA3 neurones. We report here a slow inward current in CA3 neurones and suggest that it is carried by calcium ions.