Statistical computer model analysis of the reciprocal and recurrent inhibitions of the Ia-EPSP in α-motoneurons.

We simulate the inhibition of Ia-glutamatergic excitatory postsynaptic potential (EPSP) by preceding it with glycinergic recurrent (REN) and reciprocal (REC) inhibitory postsynaptic potentials (IPSPs). The inhibition is evaluated in the presence of voltage-dependent conductances of sodium, delayed rectifier potassium, and slow potassium in five α-motoneurons (MNs). We distribute the channels along the neuronal dendrites using, alternatively, a density function of exponential rise (ER), exponential decay (ED), or a step function (ST). We examine the change in EPSP amplitude, the rate of rise (RR), and the time integral (TI) due to inhibition. The results yield six major conclusions. First, the EPSP peak and the kinetics depending on the time interval are either amplified or depressed by the REC and REN shunting inhibitions. Second, the mean EPSP peak, its TI, and RR inhibition of ST, ER, and ED distributions turn out to be similar for analogous ranges of G. Third, for identical G, the large variations in the parameters' values can be attributed to the sodium conductance step (g(Na_step)) and the active dendritic area. We find that small g(Na_step) on a few dendrites maintains the EPSP peak, its TI, and RR inhibition similar to the passive state, but high g(Na_step) on many dendrites decrease the inhibition and sometimes generates even an excitatory effect. Fourth, the MN's input resistance does not alter the efficacy of EPSP inhibition. Fifth, the REC and REN inhibitions slightly change the EPSP peak and its RR. However, EPSP TI is depressed by the REN inhibition more than the REC inhibition. Finally, only an inhibitory effect shows up during the EPSP TI inhibition, while there are both inhibitory and excitatory impacts on the EPSP peak and its RR.

The efficacy of physiological and pharmacological N-methyl-D-aspartate receptor block is greatly reduced under hyperbaric conditions.

Human divers exposed to hyperbaric pressure may suffer from cognitive and motor impairments thought to be related to high pressure effects per ce. These effects, termed high pressure neurological syndrome (HPNS), appear at pressure above 1.1 MPa. HPNS involves CNS hyperexcitability that is partially attributed to augmented responses of the glutamatergic N-methyl-d-aspartate receptor (NMDAR). NMDAR is blocked by Mg(2+) (physiologically) and by dl-2-Amino-5-phosphonopentanoic acid (AP5, pharmacologically). We have recently reported that hyperbaric pressure augments rat hippocampus NMDAR synaptic response and generates hyperexcitability. We now test pressure effects on the blockade efficacy of Mg(2+)and AP5. Under high pressure conditions more than double [Mg(2+)](o) and [AP5](o) were needed to achieve similar effects on NMDAR synaptic response's amplitude, decay time, and time integral comparable to control conditions. [Mg(2+)](o) and [AP5](o) concentration-response curves and the concentration for 50% responses' inhibition (IC(50)s) showed similar normalized pattern at control and pressure for each parameter. We conclude that hyperbaric pressure reduces the efficacy of these NMDAR blockers that may be associated with the receptor conformational change(s). This provides additional mechanism for pressure over activation of NMDAR. Taken together with our previous reports, high pressure modification of NMDAR activity significantly contributes to CNS hyperexcitability and possibly for long term vulnerability.

Statistical computer model analysis of the reciprocal and recurrent inhibitory postsynaptic potentials in alpha-motoneurons.

We simulate reconstructed alpha-motoneurons (MNs) under physiological and morphological realistic parameters and compare the modeled reciprocal (REC) and recurrent (REN) inhibitory postsynaptic potentials (IPSPs) containing voltage-dependent channels on the dendrites with the IPSPs of a passive MN model. Three distribution functions of the voltage-dependent channels on the dendrites are applied: a step function (ST) with uniform spatial dispersion; an exponential decay (ED) function, with channels with high density located proximal to the soma; and an exponential rise (ER) with a higher density of channels located distally. The excitatory and REN inhibitory inputs are located as a gaussian function on the dendrites, while the REC inhibitory synapses are located proximal to the soma. Our simulations generate four key results. (1) The distribution pattern of the voltage-dependent channels does not affect the IPSP peak, its time integral (TI), or its rate of rise (RR). However, the IPSP peak decreased in the presence of the active dendrites, while the EPSP peak increased. (2) Proximally located IPSP conductance produces greater IPSP peak, RR, and TI. (3) Increased duration of the IPSP produces greater RR and moderately increased TI and has a small effect on the peak amplitude. (4) The IPSP of both REC and REN models is specific to each MN: its amplitude is proportional to the MNs' input resistance, R(N); the increase of IPSP at the proximal location of the IPSP synapses is inversely related to R(N); and the effect of the IPSP conductance duration is insensitive to R(N).

CNS manifestations of HPNS: revisited.

Exposure to high pressures (HP) has been associated with the development of the high pressure neurological syndrome (HPNS) in deep-divers and experimental animals. In contrast, many diving mammals are naturally able to withstand very high pressures. Although at a certain pressure range humans are also able to perform to some extent, the severe signs of HPNS at higher pressures motivated the research on the pathophysiology underlying this syndrome rather than on possible adaptive mechanisms. Thermodynamically, high pressure resembles cooling. Both conditions usually involve reduction in the entropy and slowing down of kinetic rates. We have observed in rat corticohippocampal brain slices that high pressure slows and reduces excitatory synaptic activity. However, this was associated with increased gain of the system, allowing the depressed inputs to elicit regular firing in their target cells. This increased gain was partially mediated by elevated excitability of their dendrites and reduction in the background inhibition. This compensation is efficient at low-medium frequencies. However, it induces abnormal spike reverberation at the high frequency band (> 50 Hz). Synaptic depression that requires less vesicles/transmitter turn over may serve as an energy-saving mechanism when enzymes and membrane pumps activity are slowed down at pressure. It is even more efficient if a similar reduction is induced in inhibitory synaptic activity. Unfortunately, the frequency response characteristics at this mode of operation may make the system vulnerable to external signals (noise, auditory, visual, etc) at frequencies that elicit 'resonance' responses. Therefore, it is expected that humans exposed to pressures above 1.5 MPa display lethargy and fatigue, certain reduction in cognitive and memory functions when the system is working in an 'economic' mode. The more serious signs of HPNS such as nausea, vomiting, severe tremor, disturbance of motor coordination, and seizures, may be the consequence of an interaction between the 'economic' mode of operation and resonance-inducing environmental disturbances.

Highly 4-aminopyridine sensitive delayed rectifier current modulates the excitability of guinea pig cerebellar Purkinje cells.

The effects of low concentrations of 4-aminopyridine (4-AP) on the membrane properties of guinea pig cerebellar Purkinje cells were investigated in slice preparation using intracellular recordings. It was found that 1-10 microM 4-AP did not affect the resting potential or the input resistance of the cells, but reduced markedly the duration of the slowly depolarizing potential (SDP), and thus the latency to the firing of Ca2+ spikes in response to intracellular current pulses. Intradendritic recordings in the presence of tetrodotoxin, Cd2+, and low [Ca2+]o, which blocked all the regenerative responses, exhibited prominent membrane outward rectification in response to depolarizing current pulses. Under these conditions, the SDP was abolished and, in contrast, a slowly developing hyperpolarization was consistently observed. Application of 10 microM 4-AP reduced the outward membrane rectification in a reversible manner, but did not affect the transient hyperpolarization, which is usually attributed to the activation of potassium "A" current. These results demonstrate, for the first time, the presence of a highly 4-AP sensitive delayed rectifier in guinea pig cerebellar Purkinje cells, which prominently affects their excitability. The results also indicate that the slowly depolarizing potential of guinea pig Purkinje cells does not involve inactivation of transient potassium currents, which has been suggested previously as an underlying mechanism for this phenomenon in turtle Purkinje cells.

Period doubling of calcium spike firing in a model of a Purkinje cell dendrite.

Recordings from cerebellar Purkinje cell dendrites have revealed that in response to sustained current injection, the cell firing pattern can move from tonic firing of Ca(2+) spikes to doublet firing and even to quadruplet firing or more complex firing. These firing patterns are not modified substantially if Na(+) currents are blocked. We show that the experimental results can be viewed as a slow transition of the neuronal dynamics through a period-doubling bifurcation. To further support this conclusion and to understand the underlying mechanism that leads to doublet firing, we develop and study a simple, one-compartment model of Purkinje cell dendrite. The neuron can also exhibit quadruplet and chaotic firing patterns that are similar to the firing patterns that some of the Purkinje cells exhibit experimentally. The effects of parameters such as temperature, applied current, and potassium reversal potential in the model resemble their effects in experiments. The model dynamics involve three time scales. Ca(2+)- dependent K(+) currents, with intermediate time scales, are responsible for the appearance of doublet firing, whereas a very slow hyperpolarizing current transfers the neuron from tonic to doublet firing. We use the fast-slow analysis to separate the effects of the three time scales. Fast-slow analysis of the neuronal dynamics, with the activation variable of the very slow, hyperpolarizing current considered as a parameter, reveals that the transitions occurs via a cascade of period-doubling bifurcations of the fast and intermediate subsystem as this slow variable increases. We carry out another analysis, with the Ca(2+) concentration considered as a parameter, to investigate the conditions for the generation of doublet firing in systems with one effective variable with intermediate time scale, in which the rest state of the fast subsystem is terminated by a saddle-node bifurcation. We find that the scenario of period doubling in these systems can occur only if (1) the time scale of the intermediate variable (here, the decay rate of the calcium concentration) is slow enough in comparison with the interspike interval of the tonic firing at the transition but is not too slow and (2) there is a biostability of the fast subsystem of the spike-generating variables.

Olfactory learning modifies predisposition for long-term potentiation and long-term depression induction in the rat piriform (olfactory) cortex.

Learning-related modifications in predisposition for long-term potentiation (LTP) and long-term depression (LTD) were studied in brain slices of the rat piriform cortex following olfactory learning. Rats were trained to discriminate between pairs of odors until they demonstrated rule learning. We have previously shown that such training is accompanied by enhanced neuronal excitability and increased synaptic transmission in the intrinsic synaptic pathway. Here we show that the susceptibility for further enhancing synaptic connectivity by inducing LTP in slices from trained rats is markedly reduced after training, compared with slices from pseudo-trained and naive rats. Accordingly, while 900 stimuli at 1 Hz did not induce LTD in slices from control rats, it induced significant LTD in slices from trained rats. Post-tetanic potentiation (PTP) was also reduced after training, indicating that synaptic release is enhanced after odor learning, as previously suggested. We suggest that learning-related cellular modifications and activity-dependent synaptic plasticity share a common mechanism in the primary olfactory cortex. Our data also support the prediction generated according to the sliding modification threshold theory that learning should be accompanied by reduced capability of inducing LTP and increased susceptibility for LTD induction.

Long-lasting cholinergic modulation underlies rule learning in rats.

We studied the role of acetylcholine (ACh) in creating learning-related long-lasting modifications in the rat cortex. Rats were trained to discriminate positive and negative cues in pairs of odors, until they demonstrated rule learning and entered a mode of high capability for learning of additional odors. We have previously reported that pyramidal neurons in olfactory (piriform) cortex from trained rats had reduced spike afterhyperpolarization (AHP) for 3 d after rule learning. In the present study we examined the mechanism underlying this long-lasting modification. The cholinergic agonist carbachol reduced both slow AHP and firing adaptation in neurons from pseudotrained rats, but had no effect on neurons from trained rats, suggesting pre-existing cholinergic effect. Intracellular application of the calcium chelator BAPTA abolished the difference in slow AHP and in adaptation between groups, suggesting that the difference resulted from reduction in the ACh-sensitive, Ca(2+)-dependent potassium current, I(AHP). At the behavioral level, application of the muscarinic blocker scopolamine before each training session delayed rule learning but had no effect on further acquisition of odor memory. We suggest that intense ACh activity during rule learning enhances neuronal excitability in the piriform cortex by reducing I(AHP) and that the effect outlasts the stage of rule learning, so that ACh activity is not crucial for further odor learning.

Olfactory learning is associated with increased spine density along apical dendrites of pyramidal neurons in the rat piriform cortex.

We studied the effect of olfactory learning on the dendritic spine density of pyramidal neurons in the rat piriform (olfactory) cortex. Rats were trained to distinguish between two pairs of odours in an olfactory discrimination task. Three days after training completion, rats were killed and layer II pyramidal neurons identified by Golgi impregnation were examined with a light microscope. Counts of visible spines were performed along the secondary and tertiary branches of both the apical dendrites and the basal dendrites, which are the sites of intracortical synaptic inputs. An estimate of the true spine density was obtained using Feldman and Peters' method (1979, The Journal of Comparative Neurology, 188, 527--542). The estimated true spine density along apical dendrites was higher in neurons from trained rats than those in pseudotrained and naive rats by 15%. As length of spiny dendrites did not change significantly after learning, the learning-related increase in spine density in neurons from trained rats may indicate on an increased number of excitatory synapses interconnecting pyramidal neurons in the piriform cortex, following olfactory learning.

Pressure-induced depression of synaptic transmission in the cerebellar parallel fibre synapse involves suppression of presynaptic N-type Ca2+ channels.

High pressure induces CNS hyperexcitability while markedly depressing synaptic transmitter release. We studied the effect of pressure (up to 10.1 MPa) on the parallel fibre (PF) synaptic response in biplanar cerebellar slices of adult guinea pigs. Pressure mildly reduced the PF volley amplitude and to a greater extent depressed the excitatory field postsynaptic potential (fPSP). The depression of the PF volley was noted even at supramaximal stimulus intensities, indicating an effect of pressure on the amplitude of the action potential in each axon. Low concentrations of TTX mimicked the effects of pressure on the PF volley without affecting the fPSP. Application omega-conotoxin GVIA (omega-CgTx) reduced the synaptic efficacy by 34.3+/-2.7%. However, in the presence of omega-CgTx the synaptic depression at pressure was significantly reduced. Reduced Ca2+ entry by application of Cd2+ or low [Ca2+]o did not have a similar influence on the effects of pressure. Application of omega-AGA IVA, omega-AGA TK and Funnel-web spider toxin did not affect the synaptic response in concentrations that usually block P-type Ca2+ channels, whilst the N/P/Q-type blocker omega-conotoxin MVIIC reduced the response to 52.7+/-5.0% indicating the involvement of Q-type channels and R-type channels in the non-N-type fraction of Ca2+ entry. The results demonstrate that N-type Ca2+ channels play a crucial role in the induction of PF synaptic depression at pressure. This finding suggests a coherent mechanism for the induction of CNS hyperexcitability at pressure.

The clinical effectiveness of implants placed immediately into fresh extraction sites of molar teeth.

BACKGROUND: Studies concerning immediate implantation describe its use in the anterior and premolar regions. However, its clinical effectiveness in immediately replacing molar teeth has rarely been challenged. The purpose of this study was to evaluate the survival rate of implants placed immediately after extraction of molar teeth to support a fixed ceramo-metal prosthesis. METHODS: From 1989 to 1996, 56 immediate implants were placed in 43 patients following extraction of 51 molars; 46 molars were replaced by 1 implant and 5 molars replaced by 2 implants. All implants were restored with fixed prostheses (4 single crowns and 52 splinted). Mean follow-up period was 15 months (range, 4 to 60 months). The influence of the following parameters on implant failure was evaluated: gender, arch, smoking, pre-extraction vertical bone loss, implant length, and severity of complications between the two stages of surgery. RESULTS: The 5-year cumulative survival rate (5-year CSR) was 89%. The 5-year CSR among men was 84% compared to 93.5% among women. The maxillary 5-year CSR was 82% and the mandibular 92%. Among non-smokers (50 implants), the 5-year CSR was 90% compared to 83% among smokers (6 implants). Complications were evident in 8 (6 minor, 2 major) out of 50 non-failing implants compared to 2 (minor) of the 6 failing implants. No differences were evident in the other study variables. CONCLUSIONS: Immediate implantation in the molar region is an alternative, predictable surgical treatment. Immediate implantation in the posterior mandible has a better prognosis than in the posterior maxilla.

Reduced synaptic facilitation between pyramidal neurons in the piriform cortex after odor learning.

Learning-related cellular modifications were studied in the rat piriform cortex after operand conditioning. Rats were trained to discriminate positive cues in pairs of odors. In one experimental paradigm, rats were trained to memorize 35-50 pairs of odors ("extensive training"). In another paradigm, training was continued only until rats acquired the rule of the task, usually after learning the first two pairs of odors ("short training"). "Pseudotrained" and "naive" rats served as controls. We have previously shown that "rule learning" of this task was accompanied by reduced spike afterhyperpolarization in pyramidal neurons in brain slices of the piriform cortex. In the present study, synaptic inputs to the same cells were examined. Pairs of electrical stimuli applied to the intrinsic fibers that interconnect layer II pyramidal neurons revealed significant reduction in paired-pulse facilitation (PPF) in this pathway even after short training. PPF in shortly trained rats was reduced to the same extent as in extensively trained rats. PPF reduction did not result from modification of membrane properties in the postsynaptic cells, change in postsynaptic inhibition, or impairment of the facilitation mechanism. Extracellular field potential recordings showed enhanced synaptic transmission in these synapses. The reduction in PPF became apparent only 3 d after task acquisition and returned to control value 5 d later. PPF evoked by stimulating the afferent fibers to the same neurons was increased 1 d after training for 2 d. We suggest that the transient enhancement in connectivity in the intrinsic pathway is related to the enhanced learning capability and not to memory for specific odors, which lasts for weeks.

Spontaneous Na+ and Ca2+ spike firing of cerebellar Purkinje neurons at high pressure.

The effects of high pressure (up to 10.1 MPa) on the spontaneous firing of Purkinje neurons in guinea-pig cerebellar slices were studied using the macropatch clamp technique. Pressure did not significantly alter the single somatic Na+ spike parameters or the frequency of regular Na+ spike firing. When Na+ currents were blocked by 0.5-1 microM tetrodotoxin (TTX), a pressure of 10.1 MPa slightly reduced the dendritic Ca2+ spike amplitude to 90.2+/-3.1% of its control value, and slowed its kinetics. The effects of pressure on the single Ca2+ spike were even less prominent when K+ currents were blocked by 5 mM 4-aminopyridine (4-AP). Pressure prolonged the active period of Ca2+ spike firing to 152.2+/-10.4% of the control value. Within the active period pressure increased the inter-spike interval to 164.9+/-8.7% and suppressed the typical firing of doublets. The latter changes were reversed by a high extracellular potassium concentration ([K+]o) and 1 microM 4-AP, whereas in the presence of 5 mM 4-AP the pattern was insensitive to pressure. A high [Ca2+]o reduced the firing frequency and suppressed doublet firing in a manner reminiscent of the pressure effect, but these changes could not be reversed by 4-AP. A low [Ca2+]o slightly increased the firing of doublets. These results show that the single somatic Na+ spike is insensitive and the dendritic Ca2+ spike is only mildly sensitive to pressure. However, alterations in Ca2+ spike firing pattern suggest that modulation of dendritic K+ currents induce depression of dendritic excitability at pressure.

The effect of a high partial pressure of carbon dioxide environment on metabolism and immune functions of human peritoneal cells-relevance to carbon dioxide pneumoperitoneum.

OBJECTIVE: Our purpose was to evaluate in vitro the effect of a high partial pressure of carbon dioxide environment used in laparoscopy on metabolic and immune response of various human peritoneal cells. STUDY DESIGN: Polymorphonuclear leukocytes were obtained from 5 healthy volunteers, peritoneal macrophages were obtained from the effluent of 8 patients undergoing continuous ambulatory peritoneal dialysis, and human peritoneal mesothelial cell cultures were prepared from omentum derived from 5 patients undergoing elective surgery. The cells were exposed to a laparoscopy-like environment (1 atmosphere carbon dioxide and 0.2 atmosphere oxygen), to a control gas mixture (1 atmosphere helium and 0.2 atmosphere oxygen), or air for 3 hours. After exposure to gas mixtures, cell functions were tested at various recovery periods. RESULTS: Three hours of exposure to a high partial pressure of carbon dioxide had no effect on viability of peritoneal macrophages and human peritoneal mesothelial cells, tested by trypan blue dye uptake and lactate dehydrogenase release. A high partial pressure of carbon dioxide decreased the mitochondrial dehydrogenases activity of peritoneal macrophages and human peritoneal macrophage cells by 60%, assayed by 3-(4, 5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide reduction. High partial pressure of carbon dioxide blocked the superoxide release from activated polymorphonuclear leukocytes and the secretion of interleukin 1beta from stimulated peritoneal macrophages, and human peritoneal macrophage cells were decreased by 15% and 30% and the secretion of tumor necrosis factor-alpha from peritoneal macrophages was suppressed by 85%. Mitochondrial activity, polymorphonuclear leukocyte function, and interleukin 1beta and tumor necrosis factor-alpha secretion returned to normal after a recovery period of 12 to 24 hours, 4.5 hours, and 24 hours, respectively. In the control experiments exposure of cells to helium had no suppressive effect. CONCLUSIONS: Exposure of cells to a high partial pressure of carbon dioxide environment suppresses the inflammatory and metabolic responses of peritoneal cells. We suggest that this suppressive effect may contribute to the low postsurgery adhesion formation and the reduction in postoperative pain observed in laparoscopy. Nevertheless, the suppression of the immune response should also be taken into account for operations involving a high risk of bacterial dissemination.

Potassium currents modulation of calcium spike firing in dendrites of cerebellar Purkinje cells.

The pattern of sustained Ca2+ spike firing was investigated, using macropatch clamp and intracellular recordings, in guinea pig cerebellar Purkinje cells. Under our standard experimental conditions (30 degrees C, 5 mM [K+]o, 2 mM [Ca2+]o, 1 microM tetrodotoxin), each firing period started with uniform firing and gradually turned into a doublet pattern with a large spike afterhyperpolarization (AHP) between the doublets. Macropatch clamp recordings from localized dendritic regions revealed that each doublet is composed of two similar inward current deflections. This result indicated, for both peaks, an active process in the recording site and contradicted the possibility that they reflect firing in two completely separated dendritic regions. When [K+]o was increased the transition to a doublet pattern occurred earlier and the doublets became more pronounced. A similar but more prominent effect occurred following application of 1-10 microM 4-aminopyridine, which also reduced the threshold, increased the spike amplitude, and shortened the initial delay of evoked Ca2+ spike firing. In contrast, membrane depolarization, increased [Ca2+]o, and application of quinidine (but not apamine) markedly suppressed the generation of doublet pattern. During uniform initial firing, a short hyperpolarizing pulse that mimicked a large AHP induced a subsequent doublet. A short depolarizing pulse following a single spike induced an artificial doublet followed by a large AHP. These results indicate that the pattern of Ca2+ spike firing in the dendrites of Purkinje cells is dynamically modulated by a highly aminopyridine-sensitive K+ current, and probably also by a Ca2+-activated potassium current.

Reduced after-hyperpolarization in rat piriform cortex pyramidal neurons is associated with increased learning capability during operant conditioning.

Learning-related cellular modifications were studied in the rat piriform cortex. Water-deprived rats were divided to three groups: 'trained' rats were trained in a four-arm maze to discriminate positive cues in pairs of odours, 'control' rats were 'pseudo-trained' by random water rewarding, and 'naive' rats were water-deprived only. In one experimental paradigm, the trained group was exposed to extensive training with rats learning to discriminate between 35 and 50 pairs of odours. Piriform cortex pyramidal neurons from 'trained', 'control' and 'naive' rats did not differ in their passive membrane properties and single spike characteristics. However, the after-hyperpolarizations (AHPs) that follow six-spike trains were reduced after 'extensive training' by 43% and 36% compared with 'control' and 'naive', respectively. This effect was not observed in the piriform cortex of another group of rats, in which hyperexcitability was induced by chemical kindling. In another experimental paradigm rats were trained only until they demonstrated 'rule learning', usually after discriminating between one and two pairs of odours ('mild training'). In this experiment, a smaller, yet significant, reduction (20%) in AHPs was observed. AHP reduction was apparent in most of the sampled neurons. AHP remained reduced up to 3 days after the last training session. 5 days or more after the last training session, AHP amplitude recovered to pre-training value and did not differ between 'trained' rats and the others. Accordingly, training suspension for 5 days or more resulted in slower learning of novel odours. We suggest that increased neuronal excitability, manifested as reduced AHP, is related to the ability of the cortical network to enter a 'learning mode' which creates favourable conditions for enhanced learning capability.

GABA metabolism controls inhibition efficacy in the mammalian CNS.

The effects of changes in gamma-aminobutyric acid (GABA) metabolism or inhibitory processes was studied in the perforant path-dentate gyrus synapses in rat cortico-hippocampal slices, and in the monosynaptic-reflex circuit in isolated newborn, rat spinal cord. GABA metabolism was modulated by pharmacological block of either the anabolic enzyme glutamate decarboxylase (GAD) or the catabolic enzyme GABA transaminase (GABA-T). The results support the notion that GABA concentration determines the efficacy of inhibition in these regions of the central nervous system (CNS).

Block of glutamate decarboxylase decreases GABAergic inhibition at the crayfish synapses: possible role of presynaptic metabotropic mechanisms.

1. The cytosolic concentration of a neurotransmitter is believed to be an important factor determining its release. The effects of 3-mercaptopropionic acid (MP) and aminooxyacetic acid (AOAA), glutamate decarboxylase (GAD) blockers, on GABAergic postsynaptic and presynaptic inhibitory neurotransmission were examined in the crayfish (Procambarus clarkii) opener neuromuscular synapses. 2. Intracellular recordings of evoked excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs) as well as loose macropatch clamp measurements of excitatory postsynaptic currents (EPSCs) and inhibitory postsynaptic currents (IPSCs) were used to evaluate the effects of the drugs, which were applied exclusively to the nerve bundle. 3. Under normal conditions, a stimulus train to the inhibitor preceding the excitor stimulation elicited a large reduction in EPSP amplitude in a time interval-dependent manner. This inhibition is effected by postsynaptic as well as presynaptic processes. 4. Treatment with MP or AOAA decreased the IPSP amplitude and its altered conductance but had no effect on the IPSP reversal potential or the resting potential of the cell. They did, however, slightly increase the Rin of the fiber. 5. Quantal analysis of single IPSCs revealed that GAD blockers increased the number of failures and thus reduced quantal content (m), diminished the probability of release (p), but did not affect the quantum current (q) or the statistical parameter (n), believed to be the number of available active zones. 6. Quantal analysis of EPSCs, released after interaction with the inhibitor, revealed a reduction in m without any effect on q. GAD blockers greatly reduced the efficacy of this inhibition without affecting the EPSC q. 7. GAD blockers increased the output of the excitor release sites by the following mechanisms: 1) increased EPSC, 2) increased EPSC facilitation, or 3) enhancement of spontaneous activity (miniature EPSCs). 8. Short time incubation with picrotoxin and CGP-35348 eliminated IPSCs and evoked inhibition. However, longer exposure (90 min) increased the excitor responses, similarly to the effects of GAD blockers. 9. Baclofen, a gamma-aminobutyric acid-B (GABAB) agonist, antagonized AOAA effects on evoked inhibition. 10. These results demonstrate that GAD blockers decrease postsynaptic and presynaptic inhibition by reducing both tonic and evoked release, most likely by diminishing p. 11. The reduction in GABA synthesis and release revealed a complex mechanism for GABAergic metabotropic regulation of inhibition efficacy and the release from the excitor glutamatergic terminals.

Pressure exposure unmasks differences in release properties between high and low yield excitatory synapses of a single crustacean axon.

The cellular mechanisms underlying the effect of high pressure on synaptic transmission at two types of synapses were studied in the opener muscle of the lobster walking leg. Excitatory postsynaptic currents (EPSCs) were recorded using a loose macropatch clamp technique at normal pressure and 3.5, 6.9 MPa helium pressure. Responses of the single excitatory axon could be grouped into two types: low yield (L) synapse exhibiting a small mean EPSC with a considerable number of failures, and high yield (H) synapse having a larger mean EPSC with very few failures. The change in several synaptic transmission parameters indicated that high pressure similarly reduced presynaptic evoked release in both L and H synapses. However, some differences in the kinetics and probability of release could be detected. A major difference was the spontaneous miniature EPSCs (mEPSCs) activity. Many of the mEPSC, observed only in L synapses, were 'giant' (size of 2-5 q). High pressure selectively increased the frequency of the giant mEPSCs in the L synapse but had little effect on their amplitude histogram. High pressure depressed evoked synaptic transmission in both synapses by modulating the presynaptic quantal release parameters, but concomitantly enhanced spontaneous quantal release in L synapses by an unknown mechanism.