Connections of the second auditory cortical area with the medial geniculate body and the first auditory area

Extra — and intracellular unit responses in area AII to stimulation of geniculocortical fibers and of area AI were studied in cat immobilized with D-tubocurarine. In response to stimulation of geniculocortical fibers, antidromic mono-, di-, and polysynaptic spikes were generated by neurons in area AII. The number of antidromic responses in area AII was about half that found in area AI under the same conditions of stimulation. Most of the orthodromic responses were di- and polysynaptic. Intracellular responses also were recorded in the form of EPSPs, EPSP-IPSPs, and primary IPSPs. Stimulation of area AI evoked responses in the neurons of area AII with latent periods of 0.75–6.0, 6.1–16.0, 18.0–23.0, and 60–100 msec. Removal of the medial geniculate body led to a marked decrease in the number of responses with latent periods of 6.1–16.0 msec. Some neurons of area AII responded by spikes to stimulation of both the geniculocortical fibers and area AI. Comparison of the latent periods of responses to these two types of stimulation showed that impulses from area AI to area AII are directed both to input neurons for impulses from the medial geniculate body and to neurons at subsequent stages of the intracortical neuronal change. In response to stimulation of cortical area AI, disynaptic IPSPs appeared in many neurons of area AII. Only one IPSP with a latent period of 1.0 msec, regardable as monosynaptic, was recorded.     

Opioids activate both an inward rectifier and a novel voltage-gated potassium conductance in the hippocampal formation

Opioid receptors were found to activate two different types of membrane potassium conductance in acutely dissociated neurons from the CA1/subiculum regions of the adult rat hippocampal formation. Opioid-responsive neurons were distinguished based on their morphology and electrophysiological responses. In one population of neurons having a multipolar, nonpyramidal cell shape, mu-selective opioid agonists increased an inward rectifying potassium current. Opioid activation of the inward rectifying conductance resulted in small outward potassium currents at resting membrane potentials and increased inward currents at hyperpolarized potentials. In a second population of nonpyramidal neurons, mu opioid agonists increased a novel voltage-gated potassium current. This current was blocked by internal CsCl2, unaffected by external BaCl2 or CdCl2, irreversibly activated by intracellular GTP-gamma-S, and inactivated by sustained depolarization. In contrast to the inward rectifying conductance, the voltage-gated conductance was not activated at resting membrane potentials or hyperpolarized potentials. The opioid-activated, voltage-gated conductance represents a new class of G protein-regulated potassium current in the brain.     

An odorant-suppressed Cl– conductance in lobster olfactory receptor cells

Odorants evoke an outward current in cultured lobster olfactory receptor neurons voltage clamped at -60 mV. The reversal potential of the outward current is independent of the reversal potential of potassium, but shifts with imposed changes in the reversal potential of chloride. The slope of the current-voltage relationship is negative, suggesting that the current is mediated by the odorant suppressing a steady-state conductance. Anthracene-9-carboxylic acid, a specific chloride channel blocker, reversibly inhibits the steady-state conductance. Local application of odorants to the outer dendrites evokes a hyperpolarizing receptor potential in lobster olfactory receptor neurons current-clamped at -70 mV in situ. Consistent with the current characterized in the cultured cells, hyperpolarizing receptor potentials in some cells are voltage sensitive, blocked by anthracene-9-carboxylic acid and associated with a decrease in membrane conductance. These results support the hypothesis that odorants suppress a steady-state chloride conductance in lobster olfactory receptor neurons. Evidence that the chloride conductance can coexist with a 4-aminopyridine-blockable potassium conductance reported earlier in these cells suggests that two distinct mechanisms can mediate odorant-evoked inhibition in lobster olfactory receptor neurons.     

The role of calcium and potassium conductance in electrogenesis of smooth-muscle cells of the basilar artery

The role of calcium and potassium conductances in electrogenesis of smooth muscle cells of the bovine basilar artery has been investigated using blocking agents of calcium and potassium channels both in the normal Krebs solution and in hyperpotassium solution under anelectrotonic repolarization of the cell membrane. It is shown that both voltage-operated calcium and potassium conductances participate in generation of gradual action potentials evoked by electrical stimulation. A higher contribution of potassium conductance into the total membrane conductance during depolarization is found to be the main factor interfered with development of full-size action potential.     

Temperature dependent membrane potential changes in snail neurons and their relation to active ion transport.

The mechanisms underlying the temperature response of the resting membrane potential (RMP) were investigated in 3 identified neurons of the buccal ganglion of Helix pomatia. Lowering the temperature evoked a decrease of the RMP and an increase in membrane resistance, and vice versa. The temperature response of the RMP had an equilibrium potential of ca, -60 mV. It is essentially evoked by changes in the potassium conductance. Indications of an electrogenic sodium transport were not detected.     

Conditioning prepulses and kinetics of potassium conductance in the frog node

Summary The kinetics of potassium conductance were analyzed in response to voltage-clamp steps with holding potential (–75 mV) as initial condition and after a positive prepulse to-wards +45 mV of 10-msec duration. As the potassium reversal potentialE _K altered during potassium current flow, a method to obtain the conductance independent ofE _K was used. Conductance kinetics at 15°C were analyzed according to the Hodgkin-Huxley (HH) model. The time constant of potassium activation, with holding potential as initial condition, is a monotonous decreasing function of membrane potential. Its value ofca. 9 msec at –50 mV decreases to 1 msec at +30 mV. Changes inE _K did not affect the voltage dependency of this time constant. The time constant of potassium deactivation, i.e. the off-response following a 10-msec prepulse towards +45 mV, shows a completely different voltage dependency. At a membrane potential of –90 mV it is approximately 2 msec and gradually increases for more positive voltages towards a maximum value of about 6 msec, that is reached between –5 and 0 mV. At still larger values of membrane voltage this time constant starts to fall again. It is concluded that a HH-model, as applied for a single population of potassium channels, has to be rejected. Computer simulations indicate that an extension to two populations of independent potassium channels, each with HH-kinetics, is also inconsistent with the observed results.     

Neuropharmacology of supraoptic nucleus neurons: norepinephrine and gamma-aminobutyric acid receptors

The neurosecretory neurons in the mammalian hypothalamic supraoptic nucleus receive prominent GABAergic and noradrenergic projections arising from local interneurons and the A1 cells in the ventrolateral medulla, respectively. Intracellular recordings in in vitro perfused hypothalamic explants reveal an abundance of spontaneous inhibitory postsynaptic potentials (IPSPs) and a compound IPSP after electrical stimulation in the diagonal band of Broca area. The sensitivity of both spontaneous and evoked IPSPs to intracellular chloride injection, bicuculline, and pentobarbital is consistent with a GABA-activated, chloride-mediated inhibitory synaptic input. Parallel changes in membrane voltage and conductance are present during applications of GABA and muscimol, with similar sensitivity to ionic manipulation, bicuculline, and pentobarbital. These observations contrast with the consistently excitatory effects that follow either the stimulation of A1 cells or the application of norepinephrine and alpha 1-adrenergic agonists. Norepinephrine induces membrane depolarizations and bursting activity patterns that are blocked by the selective alpha 1 antagonist prazosin. Membrane response to norepinephrine is voltage dependent and is associated with little change in conductance. GABA and norepinephrine are proposed as transmitters in the final central pathways that mediate information to supraoptic vasopressinergic neurons from peripheral baroreceptors and chemoreceptors, respectively.     

Changes in membrane potential and postsynaptic potentials evoked by strychnine in neocortical neurons

Intracellular responses of neurons of the suprasylvian fissure to intracortical stimulation before and during topical cortical strychnine application was studied in experiments on immobilized, unanesthetized cats (a local anesthetic was used). Untreated cortical neurons responded to intracortical stimulation with a monosynaptic excitatory postsynaptic potential (EPSP) followed by an inhibitory postsynaptic potential (IPSP). Application of strychnine evoked epileptiform population activity and paroxysmal depolarizations of neuronal membrane potentials (MPs), followed by hyperpolarization. Increased hyperpolarizations, and the prolonged duration of their summation were responsible for an increased MP and reduced or abolished tonic spike activity. Intracellular application (as a result of diffusion from the microelectrode) of ethyleneglycoltetraacetate (EGTA) that blocked the calcium-dependent potassium membrane conductance (gK(Ca)) abolished the hyperpolarization. The development of epileptiform activity was accompanied by reduction of the IPSP, and an increase in the monosynaptic EPSP. The role of gK(Ca) and postsynaptic inhibition in epileptogenesis is discussed.I. I. Mechnikov State University, Odessa. Translated from Neirofiziologiya, Vol. 24, No. 6, pp. 684–691, November–December, 1992.     

Unit responses in area 5b of the suprasylvian gyrus to stimulation of the posterior lateral thalmamic nucleus

In response to stimulation of the posterior lateral nucleus in unanesthetized cats immobilized with D-tubocurarine an evoked potential consisting of three components with a latent period of 3–5 msec appeared in area 5b of the suprasylvian gyrus. All three components were reversed at about the same depth in the cortex (1500–1600 µ). Reversal of the potential shows that it is generated in that area by neurons evidently located in deeper layers of the cortex and is not conducted to it physically from other regions. Responses of 53 spontaneously active neurons in the same area of the cortex to stimulation of the posterior lateral nucleus were investigated. A characteristic feature of these reponses was that inhibition occurred nearly all of them. In 22 neurons the responses began with inhibition, which lasted from 30 to 400 msec. In 30 neurons inhibition appeared immediately after excitation while one neuron responded by excitation alone. The latent periods of the excitatory responses varied from 3 to 28 msec. The short latent period of the evoked potentials and of some single units responses (3–6 msec) confirms morphological evidence of direct connections between the posterior lateral nucleus and area 5b of the suprasylvian gyrus. Repetitive stimulation of that nucleus led to strengthening of both excitation and inhibition. Influences of the posterior lateral nucleus were opposite to those of the specific nuclei: the posterior ventrolateral nucleus and the lateral and medial geniculate bodies. Stimulation of the nonspecific reticular nucleus, however, evoked discharges from neurons like those produced by stimulation of the posterior lateral nucleus.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 5, No. 5, pp. 502–509, September–October, 1973.     

体外培养新生大鼠大脑皮层星形神经元钾通道的特性及膜外钾离子浓度对其影响

用膜片钳技术中的细胞贴附方式和内面向外方式,首次在新生大鼠大脑皮层星形神经元胞体膜上记录到一类电压依赖性钾通道。此通道可被２０ｍｍｏｌ／ＬＴＥＡ,５ｍｍｏｌ／ＬＢａ２＋,１４０ｍｍｏｌ／ＬＣｓ＋阻断,不受２０ｍｍｏｌ／Ｌ４—ＡＰ影响,其激活不依赖Ｃａ２＋。膜外钾离子浓度对通道的特性有显著的影响,逆转电位随［Ｋ＋］０的增大而增大,并表现出一定的饱和现象,两者的对数呈线性关系;同一驱动电位下,平均开放时间和开放概率随［Ｋ＋］０的增大而增大,平均关闭时间的变化则相反。     

体外培养新生大鼠大脑皮层星形神经元钾通道的特性及膜外钾离子浓度对其影响

用膜片钳技术中的细胞贴附方式和内面向外方式,首次在新生大鼠大脑皮层星形神经元胞体膜上记录到一类电压依赖性钾通道。此通道可被２０ｍｍｏｌ／Ｌ ＴＥＡ,５ｍｍｏｌ／Ｌ Ｂａ＾２＋,１４０ｍｍｏｌ／Ｌ Ｃｓ＾＋阻断,不受２０ｍｍｏｌ／Ｌ４－ＡＰ影响,其激活不依赖Ｃａ＾２＋。膜外钾离子浓度对通道的特性有显著的影响,逆转电位随Ｋ＾＋的增大而增大,并表现出一定的饱和现象,两者的对数呈线性关系;同一驱动电位下,     

Immunoglobulin E mediated membrane conductance changes in rat basophilic leukemia cells

Electrophysiological effects of anaphylactic stimulation of rat basophilic leukemia cells (RBL-2H3) were studied using conventional microelectrodes. Stimulation of passively sensitized cells by anti-immunoglobulin E resulted in hyperpolarization followed by depolarization. These changes in membrane polarization were associated with a decrease in input membrane resistance. No effect of anaphylactic stimulation was seen in Ca2+-free solution or when Ca2+ influx was blocked by Co2+, but it was mimicked by the Ca2+ ionophore A-23187. This suggests that the changes in ionic conductances were associated with calcium influx. These results support the hypothesis that membrane conductance changes are involved in the stimulus-secretion process of the RBL-2H3 cells.     

Properties of membrane ion conductances evoked by hormonal stimulation of guinea-pig and rabbit isolated hepatocytes

Membrane conductance changes evoked in isolated guinea-pig or rabbit hepatocytes by hormonal stimulation were studied with the whole-cell patch clamp technique. In Cl-containing solutions, noradrenaline (NA), ATP or angiotensin II (AII) evoked an increase of conductance to both K (GK) and Cl (GCl) ions. Activation of GK occurred after a delay of several seconds and was sustained in the presence of hormone. Activation of GCl was transient, lasting several seconds, and arose either at the same time or shortly after the increase in GK. Conductances showed an initial rapid rise and slow oscillatory changes during maintained hormone application. The NA-induced current reversed at -19 mV in Cl solutions, between the equilibrium potentials for chloride (ECl = 0 mV) and potassium ions (EK = -85 mV), and at -75 mV, near EK, in Cl-free solution. In both conditions whole-cell current-voltage curves were linear in the range -100 mV to +40 mV. The conductance increase produced by NA to Cl- ions was about 50 nS, that to K+ ions was 6 nS. The potassium conductance increase was abolished by the polypeptide toxin apamin (50 nM). An increase in membrane current noise was associated with NA-evoked outward K+ current and blocked by apamin. Spectral analysis gave estimates of the elementary K channel conductance of 1.7 pS. Power spectra were fitted by two Lorentzian components, with average half-power frequencies of 2 and 190 Hz. These results are discussed in relation to the single-channel properties and indicate that the open probability of K channels during the NA response is high. In Cl solutions, with apamin to block the K conductance, no increase in current noise was detected during the large Cl conductance evoked by NA. This suggests either that Cl channels are of very low unitary conductance (less than 1 pS) or that Cl transport is due to a membrane carrier. The complex time-course of hormonally evoked conductances is not due to the properties of ion conductances per se but probably to underlying changes of intracellular second-messenger concentration.     

Interleukin-1beta depolarizes magnocellular neurons in the paraventricular nucleus of the hypothalamus through prostaglandin-mediated activation of a non selective cationic conductance

Interleukin-1beta (IL-1beta) is involved in hypothalamic regulation of the neuroimmune response by influencing the synthesis and secretion of corticotropin releasing hormone (CRH), vasopressin (VP) and other stress-related mediators. VP secretion from magnocellular (MNC) neurons of the paraventricular nucleus (PVN) of the hypothalamus at the posterior pituitary and/or median eminence contributes to increasing adrenocorticotropin hormone (ACTH) output and ultimately glucocorticoid release, which then contributes to the stress response. In this study, using whole-cell patch clamp recordings from neurons in a slice preparation of the rat PVN, we show that MNC neurons are also influenced by IL-1beta. In response to 1 nM IL-1beta, 62% of MNC neurons tested depolarized (mean depolarization=10.9+/-1.4 mV); effects which were maintained in the presence of a sodium channel blocker, tetrodotoxin (TTX). The effects of IL-1beta on MNC neurons were blocked in the presence of a specific cyclooxygenase (COX)-2 inhibitor, NS-398, indicating a dependence on prostaglandins (PG) in mediating these effects. In response to direct application of 1 muM PGE2, 57% of MNC neurons depolarized, exhibiting a membrane potential change similar to that induced by IL-1beta (mean depolarization=7.8+/-1.1 mV). Voltage clamp experiments examining the effects of PGE2 on the currents evoked by slow voltage ramps revealed activation of a conductance characteristic of a non-selective cationic conductance (NSCC) (voltage-independent, with a reversal potential of -41.8+/-7.6 mV), suggesting that this prostanoid directly modifies cationic currents in MNC neurons. These data provide evidence that IL-1beta depolarizes MNC neurons in the PVN as a result of prostaglandin-mediated activation of a NSCC.     

Electrical properties of motoneurons in the spinal cord of rat embryos

Electrical properties of immature motoneurons were studied in vitro using isolated segments of spinal cords of rat embryos aged 14-21 days of gestation. Stable resting potentials and evoked synaptic potentials were recorded for more than 9 hr, indicating that motoneurons remain viable for many hours. Motoneurons are electrically excitable at 14 days of gestation and from the onset of excitability the action potentials are Na+-dependent but slow rising long-duration Ca2+-dependent action potentials can be evoked if K+ conductance is reduced. Thus, during embryonic development the regenerative potential inward current is Na+-and Ca2+-dependent. During motoneurons' differentiation there are some changes in their electrical properties: resting membrane potential increases, input resistance decreases, input capacitance increases, threshold for action potential decreases, and maximum rate of rise of action potential increases. Afferent motoneuron contacts are formed at 16-18 days of gestation when excitatory synaptic potentials can first be evoked in response to dorsal root stimulation. The changes in input capacitance and threshold for action potential occur at the onset of functional afferent motoneuron contacts, but it is not known whether these changes are autonomous or are influenced by the newly formed sensory inputs.     

Effects of physostigmine on the voltage dependent ionic conductances of skeletal muscle fibres

The voltage dependent ionic conductances were studied by analysing the phase plane trajectories of action potentials evoked by electrical stimulation of the sartorius muscles of the frog (Rana esculenta). The delayed outward potassium current was measured also under voltage clamp conditions on muscle fibres of either the frog (Rana esculenta) or Xenopus laevis. On analysing the effect of physostigmine decreasing the peak amplitude, the rate of both the rising and falling phases of the action potentials, it was revealed that the alkaloid at a concentration of 1 mmol/l reduced significantly both the delayed potassium conductance and the outward ionic current values during the action potentials. The inhibition of sodium conductance and inward ionic current was less expressed. The maximum value of delayed potassium conductance measured under voltage clamp conditions was decreased by 1 mmol/l physostigmine. The time constant determined from the development of delayed potassium conductance was increased at a given membrane potential. The voltage vs. n relationship describing the membrane potential dependence of the delayed rectifier was not influenced by physostigmine. It has been concluded that physostigmine changes the time course of the action potentials by decreasing the value of both voltage dependent ionic conductances and by slowing down their kinetics. It is discussed that results obtained from the phase plane analysis of complex pharmacological effects can only be accepted with some restrictions.     

Evoked Electrical Activity and Immunocytochemical Peculiarities of Cultured Excitatory and Inhibitory Neurons of the Rat Hippocampus

Experiments were carried out on cultured hippocampal neurons using a patch-clamp technique in the whole-cell configuration. We studied the characteristics of regular series of action potentials (APs), which were generated with a low frequency by inhibitory and excitatory interneurons after their direct stimulation with long-lasting (500 msec) current pulses. Nearly all parameters of the evoked impulse activity (except the frequency of generation and duration of APs) in excitatory and inhibitory neurons were significantly different. According to immunocytochemical analysis, Kv1.2- and Kv4.2-type potassium channels were expressed in the membrane of excitatory neurons (granular cells), and somatostatin was present in all these cells. As to inhibitory interneurons, only a part of such cells (large units) demonstrated immunopositivity with respect to somatostatin. In inhibitory neurons, only Kv1.2-type potassium channels were expressed. Therefore, mechanisms responsible for the ability of hippocampal interneurons to generate impulse activity under conditions of direct stimulation (in our experiments, regular low-frequency series of APs) in inhibitory and excitatory neurons are rather dissimilar. Neirofiziologiya/Neurophysiology, Vol. 37, No. 3, pp. 207–216, May–June, 2005.     

Transformation of the afferent tactile signal into a motor command in the cat motor cortex

Activity of 112 neurons of the precruciate motor cortex in cats was studied during a forelimb placing reaction to tactile stimulation of its distal parts. The latent period of response of the limb to tactile stimulation was: for flexors of the elbow (biceps brachii) 30–40 msec, for the earliest reponses of cortical motor neurons about 20 msec. The biceps response was observed 5–10 msec after the end of stimulation of the cortex with a series of pulses lasting 25 msec. Two types of excitatory responses of the neurons were identified: responses of sensory type observed to each tactile stimulation of the limb and independent of the presence or absence of motion, and responses of motor type, which developed parallel with the motor response of the limb and were not observed in the absence of motion. The minimal latent period of the responses of motor type was equal to the latent period of the sensory responses to tactile stimulation (20±10 msec). Stimulation of the cortex through the recording microelectrode at the site of derivation of unit activity, which increased during active flexion of the forelimb at the elbow (11 stimuli at intervals of 2.5 msec, current not exceeding 25 µA), in 70% of cases evoked an electrical response in the flexor muscle of the elbow.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 9, No. 2, pp. 115–123, March–April, 1977.     

GABA-mediated synaptic inhibition of projection neurons in the antennal lobes of the sphinx moth,Manduca sexta

Responses of neurons in the antennal lobe (AL) of the moth Manduca sexta to stimulation of the ipsilateral antenna by odors consist of excitatory and inhibitory synaptic potentials. Stimulation of primary afferent fibers by electrical shock of the antennal nerve causes a characteristic IPSP-EPSP synaptic response in AL projection neurons. The IPSP in projection neurons reverses below the resting potential, is sensitive to changes in external and internal chloride concentration, and thus is apparently mediated by an increase in chloride conductance. The IPSP is reversibly blocked by 100 microM picrotoxin or bicuculline. Many AL neurons respond to application of GABA with a strong hyperpolarization and an inhibition of spontaneous spiking activity. GABA responses are associated with an increase in neuronal input conductance and a reversal potential below the resting potential. Application of GABA blocks inhibitory synaptic inputs and reduces or blocks excitatory inputs. EPSPs can be protected from depression by application of GABA. Muscimol, a GABA analog that mimics GABA responses at GABAA receptors but not at GABAB receptors in the vertebrate CNS, inhibits many AL neurons in the moth.     

Membrane Potential Measured During Potassium-Evoked Release of Noradrenaline from Rat Brain Neurons: Effects of Normorphine

A single slice of rat pons that contained the locus ceruleus (LC) or two slices of cerebellum were loaded with [3H]noradrenaline; superfusion with high (35 or 60 mM) potassium solutions evoked a release of 3H. In the presence of normorphine, the release of 3H evoked by 35 mM potassium and 60 mM potassium was reduced. In some of those experiments in which the release of 3H from the LC slice was measured, an intracellular microelectrode was used to measure membrane potential. This showed that solutions of increased potassium concentration depolarized the neurons to a potential at which inward calcium currents flowed (calcium action potentials occurred). Normorphine hyperpolarized the neurons; during this hyperpolarization the depolarization caused by 35 mM potassium did not reach the threshold for significant calcium entry. The results suggest that the inhibition by normorphine of transmitter release evoked by solutions of raised potassium concentration could result in part from the membrane hyperpolarization caused by the normorphine.