Etomidate blocks LTP and impairs learning but does not enhance tonic inhibition in mice carrying the N265M point mutation in the beta3 subunit of the GABA(A) receptor

Enhancement of tonic inhibition mediated by extrasynaptic α5-subunit containing GABAA receptors (GABAARs) has been proposed as the mechanism by which a variety of anesthetics, including the general anesthetic etomidate, impair learning and memory. Since α5 subunits preferentially partner with β3 subunits, we tested the hypothesis that etomidate acts through β3-subunit containing GABAARs to enhance tonic inhibition, block LTP, and impair memory. We measured the effects of etomidate in wild type mice and in mice carrying a point mutation in the GABAAR β3-subunit (β3-N265M) that renders these receptors insensitive to etomidate. Etomidate enhanced tonic inhibition in CA1 pyramidal cells of the hippocampus in wild type but not in mutant mice, demonstrating that tonic inhibition is mediated by β3-subunit containing GABAARs. However, despite its inability to enhance tonic inhibition, etomidate did block LTP in brain slices from mutant mice as well as in those from wild type mice. Etomidate also impaired fear conditioning to context, with no differences between genotypes. In studies of recombinant receptors expressed in HEK293 cells, α5β1γ2L GABAARs were insensitive to amnestic concentrations of etomidate (1 μM and below), whereas α5β2γ2L and α5β3γ2L GABAARs were enhanced. We conclude that etomidate enhances tonic inhibition in pyramidal cells through its action on α5β3-containing GABAA receptors, but blocks LTP and impairs learning by other means - most likely by modulating α5β2-containing GABAA receptors. The critical anesthetic targets underlying amnesia might include other forms of inhibition imposed on pyramidal neurons (e.g. slow phasic inhibition), or inhibitory processes on non-pyramidal cells (e.g. interneurons).

Isoflurane impairs odour discrimination learning in rats: differential effects on short- and long-term memory

BACKGROUND

Anaesthetics suppress the formation of lasting memories at concentrations that do not suppress perception, but it is unclear which elements of the complex cascade leading from a conscious experience to a lasting memory trace are disrupted. Experiments in conscious humans suggest that subhypnotic concentrations of anaesthetics impair consolidation or maintenance rather than acquisition of a representation (long-term more than short-term memory). We sought to test whether these agents similarly impair learning in rats.

METHODS

We used operant conditioning in rats to examine the effect of isoflurane on acquisition compared with long-term (24 h) memory of non-aversive olfactory memories using two different odour discrimination tasks. Rats learned the 'valences' of odour pairs presented either separately (task A) or simultaneously (task B), under control conditions and under isoflurane inhalation. In a separate set of experiments, we tested the ability of the animals to recall a learning set that had been acquired 24 h previously.

RESULTS

Under 0.4% isoflurane inhalation, the average number of trials required to reach criterion performance (18 correct responses in 20 successive trials) increased from 21.9 to 43.5 (P<0.05) and 24.2 to 54.4 (P<0.05) for tasks A and B, respectively. Under 0.3% isoflurane inhalation, only task B was impaired (from 24.2 to 31.5 trials, P<0.05). Recall at 24 h was dose-dependently impaired or prevented by isoflurane for both tasks.

CONCLUSIONS

Isoflurane interfered with long-term memory of odour valence without preventing its acquisition. This paradigm may serve as a non-aversive animal model of conscious amnesia.

An isoflurane- and alcohol-insensitive mutant GABA(A) receptor alpha(1) subunit with near-normal apparent affinity for GABA: characterization in heterologous systems and production of knockin mice

Volatile anesthetics and alcohols enhance transmission mediated by gamma-aminobutyric acid type A receptors (GABA(A)Rs) in the central nervous system, an effect that may underlie some of the behavioral actions of these agents. Substituting a critical serine residue within the GABA(A)R alpha(1) subunit at position 270 with the larger residue histidine eliminated receptor modulation by isoflurane, but it also affected receptor gating (increased GABA sensitivity). To correct the shift in GABA sensitivity of this mutant, we mutated a second residue, leucine at position 277 to alanine. The double mutant alpha(1)(S270H,L277A)beta(2)gamma(2S) GABA(A)R was expressed in Xenopus laevis oocytes and human embryonic kidney (HEK)293 cells, and it had near-normal GABA sensitivity. However, rapid application of a brief GABA pulse to receptors expressed in HEK293 cells revealed that the deactivation was faster in double mutant than in wild-type receptors. In all heterologous systems, the enhancing effect of isoflurane and ethanol was greatly decreased in the double mutant receptor. Homozygous knockin mice harboring the double mutation were viable and presented no overt abnormality, except hyperactivity. This knockin mouse line should be useful in determining which behavioral actions of volatile anesthetics and ethanol are mediated by the GABA(A)Rs containing the alpha(1) subunit.

Distribution of airborne microorganisms in commercial pork slaughter processes

The objective of this research was to determine the prevalence and distribution of airborne bacterial contamination, with particular reference to Escherichia coli and Salmonella, at a number of stages in a pork slaughtering plant. Air samples (impaction and sedimentation) were recovered from seven locations before and during operations in a commercial pork processing plant. Aerobic mesophilic bacteria, E. coli counts and the incidence of Salmonella in the air were determined. Most sample locations which provided high impaction counts also provided high sedimentation counts. Before commencement of operations, there were no significant differences in aerobic mesophilic bacteria obtained from the sample locations. However, within 2 h of the commencement of operations, aerobic mesophilic bacteria in the wet room (3.14 log10 cfu/m3) were significantly higher (P < 0.05) than those in the clean room (2.66 log10 cfu/m3) and chiller (2.34 log10 cfu/m3). By the afternoon, similar aerobic mesophilic bacteria counts were recovered in the wet and clean rooms, although counts in both of these areas were significantly higher (P > 0.05) than in the chiller. In general there were no significant differences in E. coli counts between rooms (wet room, clean room and chiller) and these did not increase during the production day. Salmonella were detected at the locations of the dehairing and evisceration operations. Aerobic mesophilic bacteria in the air within the abattoir increased as production proceeded. In addition the air within the abattoir contained organisms such as Salmonella and E. coli. Positive correlations (P < 0.05-P < 0.001) between impaction and sedimentation samples were found suggesting that air may be an important source of carcass contamination.

Excision vs sponge swabbing - a comparison of methods for the microbiological sampling of beef, pork and lamb carcasses

AIMS

The aim of this research was to compare excision sampling with polyurethane and cellulose acetate sponge swabbing for the recovery of total viable counts and Enterobacteriaceae on meat carcasses.

METHODS AND RESULTS

Two sample types were used to compare the methods: (i) individual samples, taken from four sites on each carcass and (ii) composite samples, created by pooling the samples from four sites from an additional set of carcasses. When the polyurethane sponge and excision method were compared for individual sites, there were no significant differences in bacterial recovery on beef and pork carcasses and on two of four sites on lamb carcasses. However, when samples from each site were pooled, the excision method was more efficient than either swabbing method across the three animal species.

CONCLUSIONS

Sampling using the polyurethane sponge represents an equivalent alternative method to excision for the bacteriological sampling of carcass surfaces which is nondestructive and less labour intensive.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study provides the scientific basis for using sponge swabbing instead of excision in compliance with 2001/471/EC.

Determination of diffusion and partition coefficients of propofol in rat brain tissue: implications for studies of drug action in vitro

BACKGROUND

Propofol (2,6-diisopropylphenol) is a widely used general anaesthetic that modulates gamma-aminobutyric acid type A (GABA(A)) receptors, the major inhibitory neurotransmitter receptor in the brain. Previous studies have found that the concentration of propofol that is required to affect synaptic inhibition in brain slices is much higher than the free concentration that is achieved clinically and that modulates isolated receptors. We tested whether this is accounted for by slow equilibration in brain tissue, and determined the concentration that must be applied to achieve appropriate brain levels.

METHODS

Rat brain slices 300-microm thick were placed in a solution of 100 microM propofol in artificial cerebrospinal fluid for times ranging from 7.5 to 480 min. Concentrations in these slices were measured by HPLC to determine diffusion and partition coefficients. Electrophysiological measurements of the rate at which effects of 5 microM propofol developed were compared with the calculated rate of increase in tissue concentration.

RESULTS

The diffusion coefficient was approximately 0.02x10(-6) cm2 s(-1), and the brain:artificial cerebrospinal fluid partition coefficient was 36. Diffusion times in brain slices agreed well with time course measurements of propofol-induced depression of synaptic responses, which continued to increase over 5 h. This depression was reversed by blocking GABA inhibition with picrotoxin (100 microM).

CONCLUSIONS

Propofol does enhance inhibition in brain slices at a concentration of 0.63 microM in the superfusate, which produces brain concentrations corresponding with those achieved in vivo, but equilibration requires several hours. It is likely that slow diffusion to GABA receptors accounts for the high concentrations (>10 microM) that were needed to depress evoked responses in previous investigations.

Studies to determine the critical control points in pork slaughter hazard analysis and critical control point systems

Aerobic mesophilic counts (AMC), coliform (CC) and coliform resuscitation counts (CRCs) were obtained by swabbing 50 cm(2) areas at three sites (ham, belly and neck) on pig carcasses, after each of seven stages of the slaughter/dressing process (bleeding, scalding, dehairing, singeing, polishing, evisceration and chilling). In most cases, there were no statistical differences (P>0.05) among the counts derived by these three methods. Reductions in counts at individual sites were observed after scalding (3.5 log(10) cfu cm(-2)), and singeing (2.5 log(10) cfu cm(-2)). Increases in counts at individual sites were observed after dehairing (2.0 log(10) cfu cm(-2)) and polishing (1.5 log(10) cfu cm(-2)). The incidence of Salmonella on pig carcasses was also obtained by swabbing the outside surfaces of 100 half carcasses. Information on the incidence of Salmonella in scald tank water (108 samples) was also investigated. Carcass swabs and scald tank water were examined for the presence of Salmonella using standard enrichment methods. Salmonella were detected on 31% of carcasses immediately after bleeding, 7% of carcasses immediately after dehairing and evisceration, and 1% of carcasses immediately after scalding. Serovars included Salmonella Typhimurium, Salmonella Hadar, Salmonella Infantis and Salmonella Derby. No Salmonella were recovered from samples of scald tank water. The impact of pig slaughter/dressing processes on carcass microbiology and their potential use as critical control points (CCPs) during pork production are discussed.

Prevalence of Campylobacter within a swine slaughter and processing facility

In this work, the occurrence of Campylobacter in a swine slaughter and processing facility was studied. Thirty composite carcass samples, representing 360 swine carcasses, were taken immediately after exsanguination, immediately after polishing, after the final wash, and after overnight chilling at 2 degrees C. Thirty matching composite rectal samples were also taken immediately after exsanguination, and 60 nonmatching individual colon samples were collected from the same lot of swine during evisceration. Also, 72 environmental samples were collected from equipment used in the slaughter operation (42 samples) and the processing operation (30 samples). Campylobacter was isolated by direct plating on Campy-Line agar (CLA) or Campy-Cefex agar (CCA), as well as by Bolton broth enrichment and subsequent inoculation onto CLA or CCA. For all four recovery methods combined, Campylobacter was detected on 33% (10 of 30) of the composite carcasses immediately after exsanguination, 0% (0 of 30) after polishing, 7% (2 of 30) immediately before chilling, and 0% (0 of 30) after overnight chilling. The pathogen was recovered from 100% (30 of 30) of the composite rectal samples and 80% (48 of 60) of the individual colon samples. Campylobacter was detected in 4.8% (2 of 42) and 3.3% (1 of 30) of the slaughter and processing equipment samples, respectively. The recovery rate achieved with direct plating on CLA was significantly higher (P < 0.05) than those achieved with the other three recovery methods. For the 202 isolates recovered from all of the various samples tested, Campylobacter coli was the predominant species (75%) and was followed by Campylobacter spp. (24%) and Campylobacter jejuni (1%). These results indicate that although Campylobacter is highly prevalent in the intestinal tracts of swine arriving at the slaughter facility, this microorganism does not progress through the slaughtering operation and is not detectable on carcasses after overnight chilling.

Effects of gamma2S subunit incorporation on GABAA receptor macroscopic kinetics

GABA(A) receptors, the major inhibitory neurotransmitter receptors in the mammalian central nervous system, are heteropentameric proteins. We are interested in understanding the contribution of the gamma subunit to the kinetic properties of GABA(A) receptors. Studies in Xenopus oocytes have suggested that co-expression of alpha1, beta2, and gamma 2S subunits results in the formation of both alpha beta and alpha betagamma receptors (Boileau et al. 2002a; Boileau et al., 1998). Here, we have used an excess of the gamma 2S subunit in transfections of HEK293 cells to bias expression toward alpha beta gamma-containing receptors. Using rapid application and whole cell patch clamp techniques, we found that incorporation of the gamma subunit eliminated the rapid phases of desensitization and accelerated deactivation, consistent with a proposed role of desensitization in slowing deactivation. In addition, alpha betagamma receptors had an increased GABA EC(50), reduced sensitivity to block by Zn(2+), and did not display outward rectification as compared to alpha beta receptors.

Washing and chilling as critical control points in pork slaughter hazard analysis and critical control point (HACCP) systems

AIMS

The aim of this research was to examine the effects of preslaughter washing, pre-evisceration washing, final carcass washing and chilling on final carcass quality and to evaluate these operations as possible critical control points (CCPs) within a pork slaughter hazard analysis and critical control point (HACCP) system.

METHODS AND RESULTS

This study estimated bacterial numbers (total viable counts) and the incidence of Salmonella at three surface locations (ham, belly and neck) on 60 animals/carcasses processed through a small commercial pork abattoir (80 pigs d(-1)). Significant reductions (P < 0.05) in bacterial numbers were noted at some stages of the slaughter/dressing process, i.e. the process of hair removal (scalding-dehairing and singeing) resulted in an approx. 4.5 log10 cfu cm(-2) decrease in bacterial numbers. A significant increase (P < 0.05) in bacterial numbers was observed after pre-evisceration washing. Final washing increased the bacterial counts to between 3.6 and 3.8 log10 cfu cm(-2) while chilling effected a small but statistically significant (P < 0.05) increase to between 4.5 and 4.7 log10 cfu cm(-2). The incidence of Salmonella on pigs at the farm was 27%, decreasing to 10% after preslaughter washing. However, stunning and bleeding effected a considerable increase in Salmonella contamination and the incidence after these operations was 50%, which was reduced to 0% during the scalding-dehairing process.

CONCLUSIONS

Washing the live animals and subsequent carcasses with cold water is not an effective control measure but chilling may be used as a CCP.

SIGNIFICANCE AND IMPACT OF THE STUDY

Recent changes in European Union legislation legally mandate HACCP in pork slaughter plants. This research will provide a sound scientific basis on which to develop and implement effective HACCP in pork abattoirs.

Is anesthesia caused by potentiation of synaptic or intrinsic inhibition? Recent insights into the mechanisms of volatile anesthetics

Volatile anesthetics modulate synaptic (GABAA receptor-mediated) and intrinsic (K+ channel-controlled) neuronal inhibition. GABAA receptor activity is enhanced, leading to increased charge transfer and prolonged synaptic inhibition, and members of the two pore domain family of potassium channels are activated, leading to neuronal hyperpolarization and reduced excitability. These effects may underlie different components of the complex anesthetic state.

Networks of interneurons with fast and slow gamma-aminobutyric acid type A (GABAA) kinetics provide substrate for mixed gamma-theta rhythm

During active exploration, hippocampal neurons exhibit nested rhythmic activity at theta ( approximately 8 Hz) and gamma ( approximately 40 Hz) frequencies. Gamma rhythms may be generated locally by interactions within a class of interneurons mediating fast GABA(A) (GABA(A,fast)) inhibitory postsynaptic currents (IPSCs), whereas theta rhythms traditionally are thought to be imposed extrinsically. However, the hippocampus contains slow biophysical mechanisms that may contribute to the theta rhythm, either as a resonance activated by extrinsic input or as a purely local phenomenon. For example, region CA1 of the hippocampus contains a slower class of GABA(A) (GABA(A,slow)) synapses, believed to be generated by a distinct group of interneurons. Recent evidence indicates that these GABA(A,slow) interneurons project to the GABA(A, fast) interneurons that contribute to hippocampal gamma rhythms. Here, we use biophysically based simulations to explore the possible ramifications of interneuronal circuits containing separate classes of GABA(A,fast) and GABA(A,slow) interneurons. Simulated interneuronal networks with fast and slow synaptic kinetics can generate mixed theta-gamma rhythmicity under restricted conditions, including strong connections among each population, weaker connections between the two populations, and homogeneity of cellular properties and drive. Under a broader range of conditions, including heterogeneity, the networks can amplify and resynchronize phasic responses to weak phase-dispersed external drive at theta frequencies to either GABA(A,slow) or GABA(A,fast) cells. GABA(A, slow) synapses are necessary for this process of amplification and resynchronization.

Rapid and direct modulation of GABAA receptors by halothane

BACKGROUND

Hypotheses regarding the nature of channel modulation by volatile anesthetics have focused primarily on "membrane actions" of anesthetics and more recently on direct actions of volatile agents on receptor proteins themselves. With the recognition that many channels are subject to modulation by intracellular enzymes, such as protein kinases and phosphatases, and recent demonstrations that the activity of these modulators themselves may be altered by anesthetic agents, a third possibility has been suggested:-anesthetic actions on channels may be indirect, produced, for example, via direct effects on intracellular enzyme systems.

METHODS

To determine the contribution of indirect versus direct modulation, the authors compared effects of the volatile anesthetic halothane on gamma-aminobutyric acid A receptors under two conditions: in the whole cell configuration with intact intracellular regulatory systems, and in the excised patch configuration, in which intracellular signaling systems have been disrupted. They also evaluated the effects of rapid application and withdrawal of anesthetic to determine the time course of onset and offset of the anesthetic actions on these channels.

RESULTS

Characteristic changes in gamma-aminobutyric acid A receptor function occurred in excised patches as in whole cells, did not require alteration of receptor phosphorylation, and were rapid (onset and offset of anesthetic action occurred within milliseconds).

CONCLUSIONS

These results are not consistent with indirect modulation but rather indicate that volatile agents modulate gamma-aminobutyric acid A receptors by direct action on the channel complex or surrounding lipid membrane.

Kinetic differences between synaptic and extrasynaptic GABA(A) receptors in CA1 pyramidal cells

GABA(A)-mediated IPSCs typically decay more rapidly than receptors in excised patches in response to brief pulses of applied GABA. We have investigated the source of this discrepancy in CA1 pyramidal neurons. IPSCs in these cells decayed rapidly, with a weighted time constant tau(Decay) of approximately 18 msec (24 degrees C), whereas excised and nucleated patch responses to brief pulses of GABA (2 msec, 1 mM) decayed more than three times as slowly (tau(Decay), approximately 63 msec). This discrepancy was not caused by differences between synaptic and exogenous transmitter transients because (1) there was no dependence of tau(Decay) on pulse duration for pulses of 0.6-4 msec, (2) responses to GABA at concentrations as low as 10 microM were still slower to decay (tau(Decay), approximately 41 msec) than IPSCs, and (3) responses of excised patches to synaptically released GABA had decay times similar to brief pulse responses. These data indicate that the receptors mediating synaptic versus brief pulse responses have different intrinsic properties. However, synaptic receptors were not altered by the patch excision process, because fast, spontaneous IPSCs could still be recorded in nucleated patches. Elevated calcium selectively modulated patch responses to GABA pulses, with no effect on IPSCs recorded in nucleated patches, demonstrating the presence of two receptor populations that are differentially regulated by intracellular second messengers. We conclude that two receptor populations with distinct kinetics coexist in CA1 pyramidal cells: slow extrasynaptic receptors that dominate the responses of excised patches to exogenous GABA applications and fast synaptic receptors that generate rapid IPSCs.

Effects of halothane on GABA(A) receptor kinetics: evidence for slowed agonist unbinding

Many anesthetics, including the volatile agent halothane, prolong the decay of GABA(A) receptor-mediated IPSCs at central synapses. This effect is thought to be a major factor in the production of anesthesia. A variety of different kinetic mechanisms have been proposed for several intravenous agents, but for volatile agents the kinetic mechanisms underlying this change remain unknown. To address this question, we used rapid solution exchange techniques to apply GABA to recombinant GABA(A) receptors (alpha(1)beta(2)gamma(2s)) expressed in HEK 293 cells, in the absence and presence of halothane. To differentiate between different microscopic kinetic steps that may be altered by the anesthetic, we studied a variety of measures, including peak concentration-response characteristics, macroscopic desensitization, recovery from desensitization, maximal current activation rates, and responses to the low-affinity agonist taurine. Experimentally observed alterations were compared with predictions based on a kinetic scheme that incorporated two agonist binding steps, and open and desensitized states. We found that, in addition to slowing deactivation after a brief pulse of GABA, halothane increased agonist sensitivity and slowed recovery from desensitization but did not alter macroscopic desensitization or maximal activation rate and only slightly slowed rapid deactivation after taurine application. This pattern of responses was found to be consistent with a reduction in the microscopic agonist unbinding rate (k(off)) but not with changes in channel gating steps, such as the channel opening rate (beta), closing rate (alpha), or microscopic desensitization. We conclude that halothane slows IPSC decay by slowing dissociation of agonist from the receptor.

Interactions between distinct GABA(A) circuits in hippocampus

Synchronous activity among synaptically connected interneurons is thought to organize temporal patterns such as gamma and theta rhythms in cortical circuits. Interactions between distinct interneuron circuits may underlie more complex patterns, such as nested rhythms. Here, we demonstrate such an interaction between two groups of CA1 interneurons, GABA(A,slow) and GABA(A,fast) cells, that may contribute to theta and gamma rhythms, respectively. Stratum lacunosum-moleculare (SL-M) stimuli that activate GABA(A,slow) inhibitory postsynaptic currents (IPSCs) in pyramidal cells simultaneously depress the rate and amplitude of spontaneous GABA(A,fast) IPSCs for several hundred milliseconds. This suppression has a similar pharmacological profile to GABA(A,slow) IPSCs, and SL-M stimuli elicit GABA(A,slow) IPSCs in interneurons. We conclude that GABA(A,slow) cells inhibit both pyramidal cells and GABA(A,fast) interneurons and postulate that this interaction contributes to nested theta/gamma rhythms in hippocampus.

Dual actions of volatile anesthetics on GABA(A) IPSCs: dissociation of blocking and prolonging effects

BACKGROUND

Volatile agents alter inhibitory postsynaptic currents (IPSCs) at clinically relevant concentrations, an action that is thought to make an important contribution to their behavioral effects. The authors investigated the mechanisms underlying these effects by evaluating the concentration dependence of modulation by enflurane, isoflurane, and halothane of IPSCs in rat hippocampal slices.

METHODS

Action potential-independent gamma-aminobutyric acid(A) IPSCs (miniature IPSCs [mIPSCs]) were recorded from CA1 pyramidal neurons. The effects on mIPSC amplitude were used to distinguish between presynaptic (altered release) and postsynaptic (altered receptor response) actions of volatile agents. The concentration dependence of blocking and prolonging actions was compared among the volatile agents to determine whether a single modulatory process could account for both effects.

RESULTS

The application of volatile anesthetics prolonged the decay and reduced the amplitude of mIPSCs in a dose-dependent manner. The effects on decay time for isoflurane and enflurane could not be distinguished. However, the blocking effect of enflurane was significantly greater than that of isoflurane at all concentrations. Despite the blocking effect, the net action of these agents was enhanced inhibition, because charge transfer was always significantly greater than control. Isoflurane, and to a lesser extent enflurane and halothane, caused a picrotoxin-sensitive increase in baseline noise. Moderate increases in mIPSC frequency were also observed for all agents.

CONCLUSIONS

These results show that enflurane, isoflurane, and halothane reduce IPSC amplitude through a direct postsynaptic action. Furthermore, the concentration dependence of the actions of the agents reveals a dissociation between the effects on the amplitude and the time course of IPSCs, suggesting that distinct mechanisms underlie the two actions.

Concentration measures of volatile anesthetics in the aqueous phase using calcium sensitive electrodes

Volatile anesthetic concentrations have been difficult to measure, but are an important experimental parameter for in vitro studies of anesthetic actions. Calcium sensitive electrodes were investigated as a means of continuously monitoring anesthetic concentrations in artificial cerebrospinal fluids (ACSF). Anesthetic-induced Ca2+ electrode signals were compared at room (22 degrees C) and physiological (35 degrees C) temperatures. Electrophysiological measures of anesthetic effects on synaptic potentials provided a bioassay. Halothane and isoflurane produced negative changes in calcium electrode potentials which were linearly related to concentrations over a clinically useful range (0.5-1.5 MAC). Anesthetic-induced voltages persisted in nominally zero Ca2+ ACSF and even in deionized water. A good correlation (r>0.9) was found for calcium electrode measures of anesthetic concentration and synaptic response depression produced by halothane, at both 22 and 35 degrees C. These results support three conclusions: (1) calcium sensitive electrodes provide a useful measure of volatile anesthetic concentrations in aqueous solution. (2) Care must be taken when using these electrodes for Ca2+ concentration measurements, if a volatile anesthetic is also to be used, since the anesthetic could introduce an appreciable error (>50%). (3) A temperature change of 13 degrees C had surprisingly little effect on Ca2+ electrode responses or on synaptic depression produced by anesthetics.

The synaptic basis of GABAA,slow

Although two kinetically distinct evoked GABAA responses (GABAA,fast and GABAA,slow) have been observed in CA1 pyramidal neurons, studies of spontaneous IPSCs (sIPSCs) in these neurons have reported only a single population of events that resemble GABAA,fast in their rise and decay kinetics. The absence of slow sIPSCs calls into question the synaptic basis of GABAA,slow. We present evidence here that both evoked responses are synaptic in origin, because two classes of minimally evoked, spontaneous and miniature IPSCs exist that correspond to GABAA,fast and GABAA,slow. Slow sIPSCs occur infrequently, suggesting that the cells underlying these events have a low spontaneous firing rate, unlike the cells giving rise to fast sIPSCs. Like evoked GABAA,fast and GABAA,slow, fast and slow sIPSCs are modulated differentially by furosemide, a subtype-specific GABAA antagonist. Furosemide blocks fast IPSCs by acting directly on the postsynaptic receptors, because it reduces the amplitude of both miniature IPSCs and the responses of excised patches to applied GABA. Thus, in the hippocampus, parallel inhibitory circuits are composed of separate populations of interneurons that contact anatomically segregated and pharmacologically distinct postsynaptic receptors.

GABAA-mediated IPSCs in piriform cortex have fast and slow components with different properties and locations on pyramidal cells

GABAA-mediated IPSCs in piriform cortex have fast and slow components with different properties and locations on pyramidal cells. J. Neurophysiol. 78: 2531-2545, 1997. A recent study in piriform (olfactory) cortex provided evidence that, as in hippocampus and neocortex, gamma-aminobutyric acid-A (GABAA)-mediated inhibition is generated in dendrites of pyramidal cells, not just in the somatic region as previously believed. This study examines selected properties of GABAA inhibitory postsynaptic currents (IPSCs) in dendritic and somatic regions that could provide insight into their functional roles. Pharmacologically isolated GABAA-mediated IPSCs were studied by whole cell patch recording in slices. To compare properties of IPSCs in distal dendritic and somatic regions, local stimulation was carried out with tungsten microelectrodes, and spatially restricted blockade of GABAA-mediated inhibition was achieved by pressure-ejection of bicuculline from micropipettes. The results revealed that largely independent circuits generate GABAA inhibition in distal apical dendritic and somatic regions. With such independence, a selective decrease in dendritic-region inhibition could enhance integrative or plastic processes in dendrites while allowing feedback inhibition in the somatic region to restrain system excitability. This could allow modulatory fiber systems from the basal forebrain or brain stem, for example, to change the functional state of the cortex by altering the excitability of interneurons that mediate dendritic inhibition without increasing the propensity for regenerative bursting in this highly epileptogenic system. As in hippocampus, GABAA-mediated IPSCs were found to have fast and slow components with time constants of decay on the order of 10 and 40 ms, respectively, at 29 degrees C. Modeling analysis supported physiological evidence that the slow time constant represents a true IPSC component rather than an artifactual slowing of the fast component from voltage clamp of a dendritic current. The results indicated that, whereas both dendritic and somatic-region IPSCs have both fast and slow GABAA components, there is a greater proportion of the slow component in dendrites. In a companion paper, the hypothesis is explored that the resulting slower time course of the dendritic IPSC increases its capacity to regulate the N-methyl--aspartate component of EPSPs. Finally, evidence is presented that the slow GABAA-mediated IPSC component is regulated by presynaptic GABAB inhibition whereas the fast is not. Based on the requirement for presynaptic GABAB-mediated block of inhibition for expression of long-term potentiation, this finding is consistent with participation of the slow GABAA component in regulation of synaptic plasticity. The lack of susceptibility of the fast GABAA component to the long-lasting, activity-induced suppression mediated by presynaptic GABAB receptors is consistent with a protective role for this process in preventing seizure activity.

Targeted deletion in astrocyte intermediate filament (Gfap) alters neuronal physiology

Glial fibrillary acidic protein (GFAP) is a member of the family of intermediate filament structural proteins and is found predominantly in astrocytes of the central nervous system (CNS). To assess the function of GFAP, we created GFAP-null mice using gene targeting in embryonic stem cells. The GFAP-null mice have normal development and fertility, and show no gross alterations in behavior or CNS morphology. Astrocytes are present in the CNS of the mutant mice, but contain a severely reduced number of intermediate filaments. Since astrocyte processes contact synapses and may modulate synaptic function, we examined whether the GFAP-null mice were altered in long-term potentiation in the CA1 region of the hippocampus. The GFAP-null mice displayed enhanced long-term potentiation of both population spike amplitude and excitatory post-synaptic potential slope compared to control mice. These data suggest that GFAP is important for astrocyte-neuronal interactions, and that astrocyte processes play a vital role in modulating synaptic efficacy in the CNS. These mice therefore represent a direct demonstration that a primary defect in astrocytes influences neuronal physiology.

Volatile anaesthetic enhancement of paired-pulse depression investigated in the rat hippocampus in vitro

1. A prominent in vivo effect of general anaesthetics, including volatile anaesthetics such as halothane, is the prolonging of paired-pulse depression of the hippocampal CA1 population spike. The mechanisms by which volatile anaesthetics produce this effect were investigated in the hippocampal brain slice preparation by testing the effect of halothane on several long-lasting inhibitory processes, including the calcium-activated potassium current that underlies the slow after-hyperpolarization (IAHP), the GABAB-mediated potassium current that underlies the late IPSP, and the fast and slow components of the early GABAA-mediated IPSP. 2. Halothane produced a dose-dependent block of IAHP at concentrations between 0.5 and 1.5%. This block was manifested as a reduction in spike frequency adaptation, a reduction in the amplitude of the slow after-hyperpolarization following a train of action potentials, and a reduction in the amplitude of the voltage-clamped current following a calcium spike elicited in the presence of tetraethylammonium and tetrodotoxin. The effect did not appear to be caused by blockade of voltage-sensitive calcium channels, since halothane markedly reduced IAHP at a concentration (1.5%) that had little effect on the depolarization-evoked calcium spike. 3. Halothane reduced the amplitude of the late GABAB-mediated IPSP by approximately 50% at concentrations between 1 and 2%. Similar results were obtained for polysynaptic and monosynaptic responses, and with current-clamp and voltage-clamp recordings. However, halothane, at concentrations up to 3%, had no effect on the presynaptic GABAB response, as indicated by no reduction in paired-pulse depression of the monosynaptic GABAA response. 4. Halothane (2%) and enflurane (4%) prolonged the decay phase of the slow component of the monosynaptic GABAA-mediated IPSC approximately twofold, but did not alter the amplitude of the response. Halothane also prolonged the decay phase of the fast component of the GABAA-mediated IPSC, with no effect on the amplitude. However, enflurane markedly reduced the amplitude of the fast component of the GABAA IPSC, so that only a small slow current remained in response to a selective stimulus. 5. It is concluded that the effects of halothane on IAHP and on GABAB responses cannot account for its effects on paired-pulse depression, but that volatile anaesthetics enhance paired-pulse depression by prolonging the decay of the slow dendritic GABAA response. Furthermore, it is speculated that the proconvulsant property of enflurane is related to its depression of the fast somatic component of GABAA inhibition.

Different mechanisms for use-dependent depression of two GABAA-mediated IPSCs in rat hippocampus

1. The mechanisms involved in the use-dependent depression of GABAA,fast and GABAA,slow, two GABAA-mediated IPSCs in the rat hippocampal slice preparation, were investigated by observing the effects of paired-pulse depression and of baclofen and CGP 35348 on monosynaptic inhibitory currents recorded from CA1 pyramidal neurons. 2. The second of a pair of evoked responses that consisted of both inhibitory components was depressed and decayed more rapidly compared to the first at an interpulse interval (IpI) of 200 ms. This effect was due to a decrease in the amplitude of GABAA,slow, with no effect on the time constant of decay or on the amplitude or time constant of GABAA,fast. 3. The time course of paired-pulse depression of both components at IpIs ranging from 5 to 2560 ms was compared. GABAA,slow was depressed maximally by 55% at IpIs of 80-160 ms. GABAA,fast was depressed maximally by 38% at 5 ms, and recovered exponentially with a time constant of 130 ms. 4. GABAA,slow was more sensitive than GABAA,fast to depression by baclofen. GABAA,slow was susceptible to complete block, with an ED50 of approximately 200 nM for (+/-)-baclofen and 100 nM for the active enantiomer, (R)-(+)-baclofen. GABAA,fast was blocked by only 50% by the highest concentrations of baclofen tested (10-100 microM (R)-(+)-baclofen), with an ED50 of approximately 2 microM for (+/-)-baclofen and 1 microM for (R)-(+)-baclofen. Paired-pulse depression of GABAA,fast was not occluded by 10 or 100 microM (R)-(+)-baclofen. 5. The GABAB antagonist CGP 35348 (0.4-1 mM), prevented paired-pulse depression of GABAA,slow at IpIs of 160 to 200 ms, and reversed the depression of GABAA,fast by baclofen, but had no effect on paired-pulse depression of GABAA,fast at IpIs of 20 to 40 ms. 6. It is concluded that use-dependent depression of GABAA,slow, but not GABAA,fast, is mediated by a presynaptic GABAB receptor. It is speculated that use-dependent depression of GABAA,fast, which occurs only over a much faster time scale, may be due to rapid postsynaptic GABAA receptor desensitization.

Hyperpolarization-activated cation current (Ih) in neurons of the medial nucleus of the trapezoid body: voltage-clamp analysis and enhancement by norepinephrine and cAMP suggest a modulatory mechanism in the auditory brain stem

1. Principal cells in the medial nucleus of the trapezoid body (MNTB) are part of a circuit in the superior olivary complex (SOC) that processes binaural information important for sound localization. MNTB cells have two voltage-dependent currents active near rest that contribute to these cells' highly nonlinear membrane properties and shape their responses to synaptic input. One of these currents, a low-threshold, 4-aminopyridine (4-AP)-sensitive K+ current, has been studied previously under current clamp. Using the single-electrode voltage-clamp technique, we have investigated the other of these currents, a hyperpolarization-activated, mixed cation current (Ih), in brain slices of the rat SOC. 2. Ih is responsible for a prominent "sag" in the voltage response to a steady hyperpolarizing current recorded under current clamp in MNTB cells. In voltage-clamp recordings, hyperpolarizing voltage steps from the resting potential elicited a large inward current that activated and deactivated with biexponential kinetics. Activation time constants were voltage dependent, with tau 1 and tau 2 = 246 and 1620 ms at -75 mV and 107 and 560 ms at -100 mV. 3. Ih was blocked by 1-5 mM cesium and had a reversal potential of -43 mV. Steady-state activation curves derived from tail currents yielded a half-activation voltage of -75.7 mV and slope factor of 5.7 mV, corresponding to < 10% activation of Ih at rest. 4. Application of norepinephrine (15-20 microM) or 8-bromoadenosine 3',5'-cyclic monophosphate (8-Br-cAMP) (1 mM) caused a depolarizing shift in the steady-state activation curve and decreased the activation time constants. The shift in the activation curve resulted in a large increase in the activation of Ih at rest, an inward shift in the holding current, and an increase in the resting membrane conductance. In current-clamp recordings, this increase in the resting activation level of Ih resulted in membrane depolarization of 2-3 mV in the absence of 4-AP, and 5-10 mV in the presence of 4-AP, an increase in the input conductance, and a reduction in the voltage sag in response to hyperpolarizing currents. 5. The resulting change in the resting point of MNTB cells exposed to norepinephrine or 8-Br-cAMP is likely to alter the responses of these cells to synaptic input, both via the direct effect on the resting membrane conductance and by changing the activation of the low-threshold, 4-AP-sensitive potassium current.(ABSTRACT TRUNCATED AT 400 WORDS)

Physiological evidence for two distinct GABAA responses in rat hippocampus

The gamma-aminobutyric acid(A) (GABAA) receptor is a ligand-gated ionophore involved in synaptic inhibition. Biochemical and molecular biological studies indicate that considerable receptor heterogeneity exists, but physiological differences between inhibitory GABAA synaptic responses have not been identified in the brain. The present report describes two anatomically segregated GABAA-mediated synaptic currents in the hippocampal CA1 region that have distinct physiological, pharmacological, and functional properties. GABAA,fast enters at or near the cell body, decays rapidly (3-8 ms), is blocked by furosemide, and rapidly curtails the excitatory response. GABAA,slow enters far from the cell body, decays slowly (30-70 ms), is not blocked by furosemide, and underlies the conventionally recognized early inhibitory postsynaptic potential. The receptors producing these responses may represent subtypes of the GABAA receptor.

Effect of volatile anesthetics on synaptic transmission in the rat hippocampus

The synaptic effects of halothane, isoflurane, and enflurane were examined in the rat hippocampus in vivo and compared with the effects of ketamine and urethane. Actions of the agents on excitatory amino acid-mediated neurotransmission were studied by observing evoked responses and long-term potentiation in the stratum pyramidale of CA1 with stimulation of the contralateral CA3 region. Long-term potentiation is a long-lasting increase in synaptic efficacy, which follows a brief stimulus train. It has been shown to be established through activation of the NMDA subclass of excitatory amino acid receptors and is thought to be involved in memory processing. Volatile anesthetics had no effect on evoked excitatory responses or on long-term potentiation. Actions of the anesthetics on inhibitory processes in the hippocampus were studied by pairing stimuli at a range of interpulse intervals. The first stimulus activated inhibitory processes that caused the response to the second stimulus to be smaller than the initial response, a phenomenon termed paired pulse depression. Paired pulse depression was significantly prolonged by the volatile anesthetics compared with that under urethane or ketamine. These results indicate that the mechanism of action of the volatile anesthetics at the hippocampal CA1 synapse does not involve amino acid-mediated excitation but does involve enhancement of inhibition.

Retrotrapezoid nucleus in the rat

The retrotrapezoid nucleus (RTN), recently described in the cat, is an anatomically identified cell group of the ventral medulla. It is of interest because of its possible role in the generation or control of breathing. The present investigation confirms the existence in the rat of an analogous cell group, as identified by retrograde transport of rhodamine microbeads from an injection site in the ventral respiratory group of the ventral medulla. Electrophysiological recordings from the region of RTN reveal individual units with respiratory related activity. These results support a possible role for the RTN in the control of breathing.

Neural mechanisms generating the leech swimming rhythm: swim-initiator neurons excite the network of swim oscillator neurons

This paper describes newly identified excitatory connections linking the segmentally iterated swim-initiator interneurons with the network of oscillator neurons that generates the leech swimming rhythm. Apparently monosynaptic excitatory chemical connections are made from one class of swim-initiator neurons (cells 204/205) to several members of the swim oscillator network, including cells 28, 115 and, as described by Weeks (1982c), cell 208. A second class of swim-initiator neurons, cells 21 and 61, also excites this subset of the oscillator neurons. The unpaired swim oscillator neuron, cell 208, also chemically excites cells 28 and 115, apparently directly. Thus, in addition to its role as a member of the swim oscillator, the excitatory output from cell 208 to the swim oscillator adds to that provided by the swim-initiator neurons. The results of this paper enlarge the subset of identified swim oscillator neurons synaptically excited by the swim-initiator neurons. These newly described targets of the swim-initiators strengthen the hypotheses that: 1) the swim-initiator neurons supply much of the tonic excitatory drive responsible for activation and maintenance of the swim central motor program, and 2) the two classes of swim-initiators, cells 204/205 and cells 21/61, act synergistically to initiate and maintain swimming.

Intersegmental coordination of the leech swimming rhythm. I. Roles of cycle period gradient and coupling strength

The isolated leech nervous system generates a metachronally coordinated rhythmic output that is the neuronal correlate of swimming activity. We investigated two factors that contribute to intersegmental coordination: the swim-cycle periods expressed by segmental ganglia and the strength of neuronal coupling between ganglia. To determine the regional variation in swim-cycle periods, we severed both of the lateral intersegmental connectives. We left intact the median connective, which conveys tonic excitation but little phasic information. We obtained a reduction in intersegmental coupling strength by severing a single lateral intersegmental connective. Cycle periods were manipulated by cooling restricted sections of the nerve cord. Our experiments revealed an anterior-posterior gradient of cycle periods in ganglia of the isolated nerve cord; that is, chains of ganglia obtained from the anterior nerve cord exhibited longer cycle periods than those obtained from the posterior end of the cord. This gradient extends posteriorly to approximately ganglion 12 and may reverse posterior to ganglion 13. Increasing local cycle periods by cooling restricted sections of the nerve cord caused delay in activity cycles in the cooled ganglia, relative to the cycles of ganglia at the control temperature. This finding demonstrates that the observed gradient in cycle period provides for smaller intersegmental phase lags than would occur if there were no period gradients. Reduction of coupling strength by severing a lateral connective led to altered phase relationships across the lesion, both at the motor and oscillator levels. For those ganglion chains in which the anterior ganglia had greater periods, the reduced coupling led to reduced or even reversed phase relationships across the lesion but left unchanged the phase lag between the ends of the chain. In contrast, reduced coupling between halves of a chain in which the posterior ganglia had greater cycle periods led to increased phase lags across the lesion and between the ends. These altered phase relationships arise from a relative increase in the contribution of period differences when coupling strength is decreased. We conclude that the anterior-to-posterior progression of neuronal activity in the isolated leech nerve cord during swimming activity is provided by the intersegmental coupling signals. Furthermore, the period gradient expressed in our preparations acts to provide for smaller phase lags than would be generated by these coupling signals in the absence of such a gradient.(ABSTRACT TRUNCATED AT 400 WORDS)

Intersegmental coordination of the leech swimming rhythm. II. Comparison of long and short chains of ganglia

Preparations of the nearly isolated leech nerve cord containing as few as two ganglia are sufficient to generate intersegmentally coordinated swim oscillations, provided that they receive tonic excitation from other segments via the median connective (Faivre's nerve). Due to their greatly reduced complexity, these preparations should provide useful experimental models of neuronal coordination. As a step in the development of such models, we have characterized the intersegmental coordination of nerve-cord chains ranging from 2 to 18 ganglia in length. We found that increases in swim-cycle period give rise to increases in intersegmental delay between homologous motoneuron bursts. Thus the intersegmental phase relationships are nearly independent of period. The relationship between intersegmental delay and period is approximately linear and extrapolates to intersect the period axis at approximately 0.3 s. This value is in close agreement with the analogous measure derived from tension measurements in the intact swimming leech. Chain length (number of connected ganglia in a preparation) has a pronounced influence on the magnitude of intersegmental phase lag. The longest chains (18 ganglia) exhibited phase lags of approximately 8 degrees per segment, whereas for pairs of ganglia the phase lag was approximately 40 degrees per segment. This dependence of phase lags on chain length was apparent at both the motor and oscillator levels. The intersegmental phase lag is not the same in all parts of the nerve cord. Rather, it increases steadily toward the posterior end of the chain, providing a deceleration in the rearward progression of the metachronal activity. The rearward increase in intersegmental phase lag is paralleled by a propensity of chains taken from more posterior sections of the nerve cord to exhibit larger phase lags. That is, there appears to be a phase-lag gradient intrinsic to the nerve cord to account for the deceleration of activity. The anterior and posterior ends of an isolated nerve cord continue to exhibit phase-locked bursting when an intervening section of five ganglia is bathed in elevated Mg2+ saline. Thus, information sufficient to coordinate oscillations in separate ganglia travels at least six segments. The phase lag across the blocked section is reduced but within each unblocked section is increased so that the phase lag between extreme ends is nearly unchanged. This altered burst pattern is due to a combination of synaptic block in segmental ganglia and conduction block in through-fibers.

2,3-Dihydroxybenzoic acid. Effect on mortality rate in a septic rat model

Neutrophil-derived oxygen-free radicals may play a role in organ dysfunction associated with generalized sepsis. A rat model was used to test the effects of two free radical scavengers, dimethyl sulfoxide (DMSO) and 2,3-dihydroxybenzoic acid (2,3-DHB), on mortality from intra-abdominal sepsis produced by cecal ligation and perforation. Being an iron-chelating agent, 2,3-DHB may have an additional bacteriostatic effect. Therapeutic regimens included no treatment; gentamicin sulfate (2 mg given intraperitoneally [IP] every eight hours); DMSO (2 g/24 hr given IP every eight hours in divided doses); 2,3-DHB (35 mg/kg given IP every eight hours); and combinations of gentamicin with each free radical scavenger. No statistically significant improvement in survival was obtained by therapeutic intervention with gentamicin alone, DMSO alone, 2,3-DHB alone, or gentamicin in combination with DMSO. When used in combination with gentamicin, 2,3-DHB yielded a statistically significant improvement in survival when compared with gentamicin alone or with no treatment. These results show that 2,3-DHB when used in combination with gentamicin has a beneficial effect on mortality following intra-abdominal sepsis in this model.

Intersegmental coordination of leech swimming: comparison of in situ and isolated nerve cord activity with body wall movement

Recordings of motoneuron activity during swimming, obtained from leech ventral nerve cords in situ, were compared with films of swimming leeches and with recordings of motoneuron activity from isolated nerve cords. It was found that the intersegmental phase lag in body movement is greater than the phase lag of in situ neuronal activity, which is in turn greater than the phase lag of isolated nerve cord activity. We conclude that peripheral neuronal or mechanical effects, as well as sensory feedback to the central pattern generator, contribute to the movement pattern of the intact swimming leech.

Measurement of rCBF by H2 clearance: theoretical analysis of diffusion effects

Although experimental evidence now indicates that diffusion of hydrogen can influence the measured clearance curves from which local blood flow is inferred, its exact role has not yet been well defined. For this reason we have developed a theoretical treatment of the effects of diffusion near a boundary separating regions of inhomogeneous perfusion (e.g. the gray-matter interface), and reexamined the appropriateness of the currently used bi-exponential model. Using our model, we confirmed empirical estimates of important diffusion effects up to approximately 2 mm from an inhomogeneity, and further refined the concept of spatial resolution. We also showed that fitting data to bi-exponential curves may be incorrect and lead to inaccurate results. We conclude from these studies that diffusion does indeed have an important effect on the clearance curves measured near an inhomogeneity.