Gap junctions between the supporting cells in some acoustico-vestibular receptors

Summary Extensive gap junctions are found between the supporting cells in acoustico-vestibular receptors (saccular macula of the goldfish; ampullar crista, utricular macula and organ of Corti of the guinea pig). The fine structural details of these gap junctions were examined using lanthanum hydroxide staining and freeze-fracture replicas, as well as conventional thin sections. It was found in the lanthanum treated saccular macula of the goldfish that the gap junction globules consist of five or six subunits surrounding a central 2 nm hole. Similar subunits of the gap junction globule are also found in freeze-fracture replicas of the saccular macula of the goldfish and the ampullar crista of the guinea pig. Possible functions of the extensive gap junctions between supporting cells of these receptors are discussed.     

Commissural effects in the otolith system

We examined whether otolith-activated second- and third-order vestibular nucleus neurons received commissural inhibition from the contralateral otolithic macula oriented in the same geometric plane. For this purpose we performed intracellular recording in vestibular nucleus neurons after stimulation of the ipsi- and contralateral utricular and saccular nerves. More than half (41/72) of the utricular-activated second-order vestibular nucleus neurons received commissural inhibition from the contralateral utricular nerve. The remaining neurons (31/72) showed no visible response to contralateral utricular nerve stimulation. About half (17/36) of utricular-activated third-order neurons also received commissural inhibition from the contralateral utricular nerve. Approximately 10% (7/67) of saccular-activated second-order vestibular neurons received polysynaptic commissural inhibition, whereas 16% (11/67) received commissural facilitation. The majority (49/67) of saccular second-order vestibular neurons, and almost all (22/23) third-order neurons, showed no visible response to stimulation of the contralateral saccular nerve. The present findings suggest that many utricular-activated vestibular nucleus neurons receive commissural inhibition, which may provide a mechanism for increasing the sensitivity of vestibular neurons to horizontal linear acceleration and lateral tilt of the head. Commissural inhibition in the saccular system was less prominent than in the utricular system.     

Neuronal organization of the utricular macula concerned with innervation of single vestibular neurons in the cat

We investigated whether cross-striolar inhibition, which may increase sensitivity to linear acceleration, contributed to utricular (UT) afferent innervation of single vestibular neurons (VNs). Excitatory and inhibitory postsynaptic potentials (EPSPs, IPSPs, respectively) were recorded from VNs after focal stimulation of the UT macula (M). From a total of 83 VNs, 25 (30%) neurons received inputs from both sides of the UTM, and the response patterns were opposite, i.e. cross-striolar inhibition was observed. In roughly 2/3 of these neurons, stimulation of the medial side of the UTM evoked EPSPs, while stimulation of the lateral side evoked IPSPs. In the remaining 1/3 neurons, the response patterns were opposite. Thirty-two (39%) of the 83 neurons received the identical pattern of inputs from both sides of the UTM: EPSPs in 26 neurons and IPSPs in six neurons. Twenty-six (31%) of the 83 neurons received inputs from either the medial or the lateral side of the UTM. These findings suggest that cross-striolar inhibition existed in the UT system, although it was not a dominant circuit that increased the sensitivity as in the saccular system [15].     

Identification of vestibular sense organs responsible for maculo-ocular reflexes in the frog

Summary Eye movements evoked by longitudinal and transverse sinusoidal linear accelerations in the horizontal plane were studied in frogs after selective bilateral section of the anterior division (including the utricular, but not the saccular branch), the utricular branch, the posterior division, the lagenar branch or the saccular branch of the VIIIth nerve and compared to responses obtained from intact animals. In frogs with bilateral section of the anterior division of the VIIIth nerve or its utricular branch no eye movements could be evoked in the dark. The maculo-ocular response dynamics in terms of frequency response in animals with selective bilateral saccular or lagenar deafferentation was within the limits of control animals. Our lesion experiments suggest that the utricule and not the lagena or the saccule is mainly responsible for the generation of maculo-ocular eye movements.Supported by the Swiss National Science Foundation (grant nos. 3.228.82 and 3.403.83), and by the Dr. E. Slack-Gyr Foundation     

Saccular and utricular inputs to single vestibular neurons in cats

Saccular and utricular organs are essential for postural stability and gaze control. Although saccular and utricular inputs are known to terminate on vestibular neurons, few previous studies have precisely elucidated the origin of these inputs. We investigated the saccular and utricular inputs to single vestibular neurons in whole vestibular nuclei of decerebrated cats. Postsynaptic potentials were recorded from vestibular neurons after electrical stimulation of the saccular and utricular nerves. Ascending and descending axonal projections were examined by stimulating the oculomotor/trochlear nuclei and the cervical segment of the spinal cord, respectively. After each experiment, locations of recorded neurons were identified. The recorded neurons (140) were classified into vestibulo-spinal (79), vestibulo-oculo-spinal (9), and vestibulo-ocular (3) neurons based on antidromic responses; 49 other vestibular neurons were unidentified. The majority of recorded neurons were mainly located in the lateral vestibular nucleus. Most of the otolith-activated vestibular nuclei neurons seemed to participate in vestibulospinal reflexes. Of the total 140 neurons recorded, approximately one third (51) received saccular and utricular inputs (convergent neurons). The properties of these 51 convergent neurons were further investigated. Most (33/51) received excitatory postsynaptic potentials (EPSPs) after saccular and utricular nerve stimulation. These results implied that most of the convergent neurons in this study additively coded mixed information for vertical and horizontal linear acceleration. Based on the latencies of convergent neurons, we found that an early integration process for vertical and horizontal linear acceleration existed at the second-order level.     

Inhibitory role of dentate hilus neurons in guinea pig hippocampal slice

1. Current and voltage-clamp recording of CA3/CA4 pyramidal neurons, hilar neurons, and granule cells or pairs of these neurons were used to study the generation of Cl-dependent and K-dependent inhibitory postsynaptic potentials (IPSPs) in the guinea pig hippocampal slice preparation. 2. A sequence of an early Cl-dependent and a late K-dependent IPSP was evoked in CA3 neurons by electrical stimulation from the stratum moleculare of the dentate gyrus, the hilus, and the stratum oriens/alveus. Blockade of glutamatergic excitation by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM) and D(-)-2-amino-5-phosphonovaleric acid (APV, 30 microM) abolished IPSPs evoked from the stratum moleculare of the dentate gyrus, but IPSPs could still be evoked from the hilus and the stratum oriens/alveus. 3. Repetitive giant IPSPs, which consisted of Cl-dependent and K-dependent components, were evoked by bath application of 4-aminopyridine (4-AP, 10-50 microM) in CA3 neurons and in granule cells. Giant IPSPs were blocked by bath-applied tetrodotoxin (TTX). In addition, 4-AP hyperpolarized CA3 neurons in a Cl-dependent and picrotoxin-sensitive way. 4. Focal application of TTX to the dentate gyrus or the hilus considerably reduced the amplitude of giant IPSPs evoked by 4-AP in CA3 neurons. In hilar neurons, 4-AP evoked repetitive bursts, eventually, but not necessarily intermingled with giant IPSPs. Bursts were observed in hilar neurons in presence as well as absence of CNQX and APV. 5. In paired recordings, bursts in hilar neurons induced by 4-AP occurred simultaneously to giant IPSPs in granule cells and CA3 neurons, and giant IPSPs in granule cells occurred simultaneously to giant IPSPs in CA3 neurons. Blockade of glutamatergic excitation by CNQX and APV did not abolish this synchrony. 6. 4-AP-evoked Cl- and K-dependent IPSPs were, unlike electrically evoked IPSPs, not strictly coupled: some 20% of large IPSPs and up to 90% of small IPSPs were either Cl or K dependent. In granule cells K-dependent components either preceded or followed Cl-dependent components. 7. K-dependent IPSPs only could be evoked in CA3 neurons by focal application of 4-AP (1 mM) to the hilus, the stratum lacunosum moleculare or the stratum pyramidale. Wash out of Ca for 15-20 min blocked the Cl-dependent but not the K-dependent component of giant IPSPs evoked by bath-applied 4-AP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Vestibular primary afferent responses to sound and vibration in the guinea pig

This study tested whether air-conducted sound and bone-conducted vibration activated primary vestibular afferent neurons and whether, at low levels, such stimuli are specific to particular vestibular sense organs. In response to 500 Hz bone-conducted vibration or 500 Hz air-conducted sound, primary vestibular afferent neurons in the guinea pig fall into one of two categories--some neurons show no measurable change in firing up to 2 g peak-to-peak or 140 dB SPL. These are semicircular canal neurons (regular or irregular) and regular otolith neurons. In sharp contrast, otolith irregular neurons show high sensitivity: a steep increase in firing as stimulus intensity is increased. These sensitive neurons typically, but not invariably, were activated by both bone-conducted vibration and air-conducted sound, they originate from both the utricular and saccular maculae, and their sensitivity underpins new clinical tests of otolith function.     

Mechanical activity of frog esophagus muscle in response to electrical stimulation of intramural nerves.

Microscopic observation of intramural nerves in the frog esophagus, fixed and stained with OsO(4) and ZnI(2), revealed that nerve cell bodies and bundles connecting the nerve cell bodies formed loose and irregular networks. The nerve cell bodies were mostly lying singly in the nerve bundles, with occasional observations of two closely linked nerve cell bodies. Isolated circular and longitudinal segments of esophageal muscle were spontaneously rhythmically contractile, with a frequency of 2.2-3.0 per min. This was not altered by tetrodotoxin (TTX). In longitudinal muscle segments, transmurally applied electrical stimulation produced contractile responses which were not inhibited by atropine or guanethidine, but were reduced in amplitude by TTX, suggesting a nonadrenergic-noncholinergic (NANC) excitatory innervation in the esophagus muscle. In circular muscle segments, transmural application of brief electrical stimulation evoked two types of mechanical response: a biphasic response consisting of an initial relaxation and a following contraction (type I) and a contraction alone (type II). These mechanical responses were not modulated by either atropine or guanethidine. In the type I response, TTX abolished the relaxation component, suggesting that this was produced by non-adrenergic non-cholinergic (NANC) inhibitory nerve excitation. In about half of the type II responses, the amplitude of the contraction was significantly reduced by TTX, suggesting that a part of the contraction was produced by activation of NANC excitatory nerves. Thus, the esophageal smooth muscle of the frog demonstrates myogenic activity, and is innervated by both excitatory and inhibitory NANC nerves.     

Zebrafish pax5 regulates development of the utricular macula and vestibular function.

The zebrafish otic vesicle initially forms with only two sensory epithelia, the utricular and saccular maculae, which primarily mediate vestibular and auditory function, respectively. Here, we test the role of pax5, which is preferentially expressed in the utricular macula. Morpholino knockdown of pax5 disrupts vestibular function but not hearing. Neurons of the statoacoustic ganglion (SAG) develop normally. Utricular hair cells appear to form normally but a variable number subsequently undergo apoptosis and are extruded from the otic vesicle. Dendrites of the SAG persist in the utricle but become disorganized after hair cell loss. Hair cells in the saccule develop and survive normally. Otic expression of pax5 requires pax2a and fgf3, mutations in which cause vestibular defects, albeit by distinct mechanisms. Thus, pax5 works in conjunction with fgf3 and pax2a to establish and/or maintain the utricular macula and is essential for vestibular function.     

Bone conducted vibration selectively activates irregular primary otolithic vestibular neurons in the guinea pig

The main objective of this study was to determine whether bone-conducted vibration (BCV) is equally effective in activating both semicircular canal and otolith afferents in the guinea pig or whether there is preferential activation of one of these classes of vestibular afferents. To answer this question a large number (346) of single primary vestibular neurons were recorded extracellularly in anesthetized guinea pigs and were identified by their location in the vestibular nerve and classed as regular or irregular on the basis of the variability of their spontaneous discharge. If a neuron responded to angular acceleration it was classed as a semicircular canal neuron, if it responded to maintained roll or pitch tilts it was classified as an otolith neuron. Each neuron was then tested by BCV stimuli—either clicks, continuous pure tones (200–1,500 Hz) or short tone bursts (500 Hz lasting 7 ms)—delivered by a B-71 clinical bone-conduction oscillator cemented to the guinea pig's skull. All stimulus intensities were referred to that animal's own auditory brainstem response (ABR) threshold to BCV clicks, and the maximum intensity used was within the animal's physiological range and was usually around 70 dB above BCV threshold. In addition two sensitive single axis linear accelerometers cemented to the skull gave absolute values of the stimulus acceleration in the rostro-caudal direction. The criterion for a neuron being classed as activated was an audible, stimulus-locked increase in firing rate (a 10% change was easily detectable) in response to the BCV stimulus. At the stimulus levels used in this study, semicircular canal neurons, both regular and irregular, were insensitive to BCV stimuli and very few responded: only nine of 189 semicircular canal neurons tested (4.7%) showed a detectable increase in firing in response to BCV stimuli up to the maximum 2 V peak-to-peak level we delivered to the B-71 oscillator (which produced a peak-to-peak skull acceleration of around 6–8 g and was usually around 60–70 dB above the animal's own ABR threshold for BCV clicks). Regular otolithic afferents likewise had a poor response; only 14 of 99 tested (14.1%) showed any increase in firing rate up to the maximum BCV stimulus level. However, most irregular otolithic afferents (82.8%) showed a clear increase in firing rate in response to BCV stimuli: of the 58 irregular otolith neurons tested, 48 were activated, with some being activated at very low intensities (only about 10 dB above the animal's ABR threshold to BCV clicks). Most of the activated otolith afferents were in the superior division of the vestibular nerve and were probably utricular afferents. That was confirmed by evidence using juxtacellular injection of neurobiotin near BCV activated neurons to trace their site of origin to the utricular macula. We conclude there is a very clear preference for irregular otolith afferents to be activated selectively by BCV stimuli at low stimulus levels and that BCV stimuli activate some utricular irregular afferent neurons. The BCV generates compressional and shear waves, which travel through the skull and constitute head accelerations, which are sufficient to stimulate the most sensitive otolithic receptor cells.     

Regenerative potentials in rat neostriatal neurons in an in vitro slice preparation

Summary 1. Regenerative potentials in rat neostriatal neurons were studied using the in vitro slice preparation. Some of the recorded neurons were intracellularly labeled with HRP. All had the morphological characteristics of the medium spiny neuron. 2. Application of TTX (10^–5 g/ml) to the superfusing medium abolished fast action potentials generated by intracellularly injected depolarizing current. Application of TEA prolonged the spike duration by decreasing its repolarizing rate without affecting rising phase. After suppression of K-conductance by TEA, depolarizing current elicited both fast and slow all or none action potentials. 3. Combined treatment with TTX and TEA revealed two types of depolarizing potentials, a slowly rising graded depolarizing potential and slow action potential. Substitution of Ca⁺⁺ with Mg⁺⁺ in the medium diminished the amplitude of these potentials. They were also blocked by application of Co⁺⁺ into the superfusion medium. The duration of slow action potentials were increased (1) with increase in the intensity of current pulse, (2) with decrease in the resting membrane potential, and (3) with increase in the concentration of TEA in the bathing medium. 4. In the normal Ringer solution, local stimulation elicited depolarizing postsynaptic responses (DPSPs). Large DPSPs evoked by strong local stimulation triggered one or two fast action potentials. In some neurons, large DPSPs could trigger both fast and slow action potentials. They were consistently triggered after application of TEA (1 mM) to the medium. 5. When a relatively high concentration of TEA (4 mM) was applied to the Ringer solution, locally evoked DPSPs could trigger only slow action potentials. In double stimulation experiments, a large reduction in the amplitude and the duration of test DPSPs was observed up to about 150 ms interstimulus interval.     

Differential spatial organization of otolith signals in frog vestibular nuclei

Activation maps of pre- and postsynaptic field potential components evoked by separate electrical stimulation of utricular, lagenar, and saccular nerve branches in the isolated frog hindbrain were recorded within a stereotactic outline of the vestibular nuclei. Utricular and lagenar nerve-evoked activation maps overlapped strongly in the lateral and descending vestibular nuclei, whereas lagenar amplitudes were greater in the superior vestibular nucleus. In contrast, the saccular nerve-evoked activation map coincided largely with the dorsal nucleus and the adjacent dorsal part of the lateral vestibular nucleus, corroborating a major auditory and lesser vestibular function of the frog saccule. The stereotactic position of individual second-order otolith neurons matched the distribution of the corresponding otolith nerve-evoked activation maps. Furthermore, particular types of second-order utricular and lagenar neurons were clustered with particular types of second-order canal neurons in a topology that anatomically mirrored the preferred convergence pattern of afferent otolith and canal signals in second-order vestibular neurons. Similarities in the spatial organization of functionally equivalent types of second-order otolith and canal neurons between frog and other vertebrates indicated conservation of a common topographical organization principle. However, the absence of a precise afferent sensory topography combined with the presence of spatially segregated groups of particular second-order vestibular neurons suggests that the vestibular circuitry is organized as a premotor map rather than an organotypical sensory map. Moreover, the conserved segmental location of individual vestibular neuronal phenotypes shows linkage of individual components of vestibulomotor pathways with the underlying genetically specified rhombomeric framework.     

Effects of temperature on adenosine A1 receptor activation in guinea pig hippocampus in vitro

The effects of temperature on adenosine A1 receptor activation were studied both by electrophysiological analysis of synaptically evoked responses in CA1 neurons in guinea pig hippocampal slices, and by measuring the binding of adenosine analogues to adenosine A1 receptors in crude synaptosomes from guinea pig hippocampal neurons. Increasing the temperature of the perfusing medium from 30 degrees C to 45 degrees C attenuated the amplitude of the synaptically and the non-synaptically evoked CA1 population spikes. Bath application of 1 microM 8-cyclopentyltheophylline, an adenosine A1 receptor antagonist, did not affect non-synaptically evoked CA1 population spikes, but significantly increased the amplitude of synaptically evoked population spikes in the upper range of hyperthermia (37-43 degrees C). In contrast, application of 5 microM L- N(6)-phenylisopropyladenosine, an adenosine A1 receptor agonist, did not affect non-synaptically evoked CA1 population spikes, but significantly decreased the amplitude of synaptically evoked population spikes in the upper range of hyperthermia. Binding assays using crude hippocampal synaptosomes showed that the affinity of adenosine A1 receptors for a radio-labeled adenosine analogue increased in response to a temperature increase. These results suggest that increased activation of adenosine A1 receptors in response to a temperature increase depresses excitatory synaptic responses in hippocampal CA1 neurons.     

An animal model of ocular vestibular-evoked myogenic potential in guinea pigs

This study aimed to establish an animal model of ocular vestibular-evoked myogenic potential (oVEMP) in guinea pigs. Ten healthy and 10 gentamicin-treated guinea pigs underwent oVEMP test using a hand-held bone-conducted vibrator placed on the animal’s forehead. All 10 healthy animals exhibited bilateral oVEMPs at the stimulus intensity of 139 dB force level (FL), with a mean threshold and latencies of peak nI and pI of 130 ± 4 dBFL, 3.17 ± 0.37 ms and 4.72 ± 0.38 ms, respectively. Similar to response rate, the nI–pI amplitude decreased markedly in magnitude as stimulus intensity decreased. Another 10 animals administered with gentamicin (2 mg) on the left ear 1 week after surgery had 100% clear oVEMPs beneath the left eye (ipsilateral to the lesion side), whereas oVEMPs were absent and reduced beneath the right eye (opposite to the lesion side) in 7 and 3 animals, respectively. Morphological study of animals with absent oVEMPs identified substantial damage to the hair cells of the utricular macula. Quantitative analysis revealed that histological density of intact hair cells of the utricular macula from control and lesion ears were 194 ± 15 and 66 ± 9 per 130 × 130 μm² field, respectively, showing a 68% reduction in the latter. Further, the stereocilia of the residual hair cells were either fused or deformed, and pointed outward randomly. In conclusion, this study establishes the animal model of oVEMP in guinea pigs using bone-conducted vibration stimuli, which sets the stage for investigating the pathophysiology of the utricular disorders.     

Neuronal and glial activity during spreading depression in cerebral cortex of cat.

1. Extra- and intracellular potentials were recorded from neurons and glia during spreading depression (SD) in cerebral cortex of cats. The glial membrane depolarized during SD and the time course of depolarization was concurrent with the surface DC change of SD. The glial depolarization evoked by 20-Hz repetitive cortical stimulation disappeared during the negative DC shift of SD. Simultaneous recording of the extra- and intracellular potentials from a single glial cell with a coaxial microelectrode showed that the extracellular DC potential change was of opposite polarity to the glial intracellular potential, which suggests that the slow glial depolarization concurrent with SD is not the field potential. In contrast to glial cells, the neuronal burst discharges as well as the neuronal membrane depolarization associated with SD did not show a close relationship to SD: the neuronal membrane depolarization and discharge were frequently delayed by 10-3- s from the onset of the SD slow wave. Sometimes SD was observed without accompanying neuronal depolarization. The degree of neuronal depolarization was not always correlated with the amplitude of the negative wave of SD. 2. The effect of tetrodotoxin (TTX) on the negative DC potential of SD was examined. Simultaneous recording of glial membrane potential and the neuronal unit activity as well as extracellular DC potential and surface DC potential during SD was performed and the TTX-treated cortex was compared with the normal state. TTX did not change the DC level of the cerebral cortex. SD could be evoked by KCl when neuronal discharge was completely abolished by TTX application...     

Direction-specific differences in the magnitude of abducens nerve responses during off-vertical axis rotation are a basic property of the utriculo-ocular reflex in frogs

Abducens nerve multiunit responses were recorded in darkness from decerebrated frogs during steps of angular velocity about an axis tilted with respect to the earth vertical (off-vertical axis rotation, OVAR). Thereby, a rotating gravity vector activated utricular hair cells and modulated the abducens nerve discharge sinusoidally as a function of head position in space. As expected, a bias velocity response component and nystagmus-related changes in neural activity were absent, since frogs do not possess a functioning velocity storage mechanism. Responses increased as a function of the tilt angle and of the velocity and direction of the platform rotation. OVAR in the direction of the recorded abducens nerve (clockwise for the right and counterclockwise for the left abducens nerve) evoked significantly smaller responses than rotation in the opposite direction. The possible origin of these direction-specific response properties was further studied after lesioning various structures assumed to modify utriculo-ocular reflexes. Each of these lesions (ipsilateral hemilabyrinthectomy, cerebellectomy, contralateral canal nerve sections) had a specific effect on the recorded response properties, but none of them, nor combinations thereof, abolished the direction-specific characteristics of the responses as long as the contralateral utricular nerve branch remained intact. Our results demonstrate that direction-specificity is a property of the basic utriculo-ocular reflex that is independent of the velocity storage mechanism in the brainstem, of the intervestibular commissural system, of the inhibitory control by the cerebellum and of the central convergence of utricular and horizontal canal inputs. A simple, unidirectional interaction between central utricular neurons with adjacent functional polarization vectors is suggested as the basic element for the observed direction specificity.     

Tetrodotoxin block of A-fibre conduction and its effect on reflex responses evoked by electrical stimulation of the sural nerve in the decerebrated rabbit

In the present study, we have investigated the viability of using tetrodotoxin (TTX) to induce selective blockade of myelinated fibre conduction in rabbit sural nerve, and explored some aspects of reflexes evoked by non-myelinated sural nerve afferents before and after application of TTX. In rabbits decerebrated under halothane-nitrous oxide anaesthesia, application of 30 nM TTX to the desheathed sural nerve completely blocked Abeta and Adelta waves of the compound action potential evoked by electrical stimulation of the nerve at 95 times threshold. The amplitude of C-fibre volleys evoked by these stimuli was reduced to a mean of 60 % of pre-treatment values. Reflexes evoked in medial gastrocnemius motoneurones by sural nerve stimulation showed corresponding changes after TTX treatment, with activation latency increasing from 5-7 ms in the control state to > 100 ms after TTX application. Temporal summation (wind up) in long latency reflexes (> 100 ms) was significantly enhanced after application of TTX. These data show that low concentrations of TTX can selectively block conduction in rabbit sural nerve A-fibres, providing a method for studying the central actions of non-myelinated C-fibres in isolation.     

Silencing-induced metaplasticity in hippocampal cultured neurons

Silencing-induced homeostatic plasticity is usually expressed as a change in the amplitude or the frequency of miniature postsynaptic currents. Here we report that, prolonged (approximately 24 h) silencing of mature (20-22 days in vitro) cultured hippocampal neurons using the voltage-gated sodium channel blocker tetrodotoxin (TTX) produced no effects on the amplitude or frequency of the miniature excitatory postsynaptic currents (mEPSCs). However, the silencing changed the intrinsic membrane properties of the neurons, resulting in an increased excitability and rate of action potentials firing upon TTX washout. Allowing neurons to recover in TTX-free recording solution for a short period of time after the silencing resulted in potentiation of mEPSC amplitudes. This form of activity-dependent potentiation is different from classical long-term potentiation, as similar potentiation was not seen in nonsilenced neurons treated with bicuculline to raise their spiking activity to the same level displayed by the silenced neurons during TTX washout. Also, the potentiation of mEPSC amplitudes after the recovery period was not affected by the N-methyl-d-aspartate receptor blocker d-2-amino-5-phosponopentanoic acid or by the calcium/calmodulin-dependent kinase II (CaMKII) inhibitor KN-62 but was abolished by the L-type calcium channel blocker nifedipine. We thus conclude that the potentiation of mEPSC amplitudes following brief recovery of spiking activity in chronically silenced neurons represents a novel form of metaplasticity that differs from the conventional models of homeostatic synaptic plasticity.     

Non-cholinergic synaptic potentials mediated by lumbar colonic nerve in the guinea-pig inferior mesenteric ganglion in vitro

Non-cholinergic slow synaptic potentials mediated by the lumbar colonic nerve have been investigated using an in vitro preparation of the guinea-pig inferior mesenteric ganglion attached to a distal colonic segment. Non-cholinergic potential responses to colonic nerve stimulation, colonic distension and chemical activation of sensory afferents were recorded intracellularly from neurons in the inferior mesenteric ganglion. Electrical stimulation of the lumbar colonic nerve produced either a slow excitatory postsynaptic potential, or a slow inhibitory postsynaptic potential followed by a slow excitatory postsynaptic potential. The extrapolated reversal potential of the slow excitatory postsynaptic potential was in the range of 0 to -20 mV and that of the slow inhibitory postsynaptic potential was -90 to 110 mV. The slow excitatory postsynaptic potential and the slow inhibitory postsynaptic potential were reversibly abolished by perfusion of the ganglion with tetrodotoxin (1 microM), or perfusion with low calcium (200 microM), high magnesium (12 mM) containing solution. Capsaicin (1 microM) evoked a reversible depolarization of inferior mesenteric ganglion cells after which desensitization occurred and the slow excitatory postsynaptic potential was abolished but the slow inhibitory postsynaptic potential was enhanced in amplitude and prolonged in duration. Bath application of substance P (2 microM) evoked a prolonged depolarization of inferior mesenteric ganglion neurons, during which the slow excitatory postsynaptic potential but not the slow inhibitory postsynaptic potential was abolished. Distensions of the colon to pressures in the range of 2-25 cm of water produced a stimulus graded non-cholinergic slow depolarization which was occasionally followed by a late slow hyperpolarization. Both types of response were abolished by tetrodotoxin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Initiation of epileptiform activity by excitatory amino acid receptors in the disinhibited rat neocortex.

1. Intracellular recordings were obtained from neurons in layer II-III of rat frontal cortex maintained in vitro. The role of excitatory amino acid receptors in generation of picrotoxin (PTX)-induced epileptiform activity was investigated with the use of D-2-amino-5-phosphonovaleric acid (D-APV) and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) as selective antagonists of N-methyl-D-aspartate (NMDA) and non-NMDA receptors, respectively. 2. Bath application of PTX resulted in a decrease in evoked inhibitory postsynaptic potentials (IPSPs) in neocortical neurons and a concomitant increase in a polysynaptic late excitatory postsynaptic potential (IEPSP). Epileptiform burst responses, termed paroxysmal depolarizing shifts (PDSs), subsequently developed. Based on response duration, two types of PDSs were identified. Long PDSs were greater than 100 ms in duration, whereas short PDSs lasted less than 50 ms. An early depolarizing potential preceded both types of epileptiform burst response. 3. The NMDA receptor antagonist D-APV reduced the peak amplitude and duration of the PDS. D-APV-insensitive portions of the PDS were greatly attenuated or abolished by CNQX. The non-NMDA antagonist also increased the latency to PDS onset and reduced its duration without affecting peak amplitude. CNQX-insensitive components of the PDS, when present, were abolished by D-APV. 4. Short-duration PDSs could be blocked by CNQX. In these neurons, increasing the stimulation strength produced epileptiform responses of reduced amplitude. 5. Under control conditions, PDS amplitude was a linear function of membrane potential, increasing with hyperpolarization and diminishing on depolarization.(ABSTRACT TRUNCATED AT 250 WORDS)