Reinterpretation of the literature indicates differential sensitivities of long-sleep and short-sleep mice are not specific to alcohol

The genetic basis of the pharmacological effects of anxiolytics: a review based on rodent models

Anxiolytic drugs exert their pharmacological actions by binding to molecular targets, such as benzodiazepine receptors or 5-hydroxytryptamine (5-HT) receptors. Specific genes encode these receptors, or the subunits of which they are formed. Therefore, genetic factors may influence strongly the ability of anti-anxiety agents to produce their behavioural effects. The literature on this subject is reviewed here, with emphasis on data derived from studies with rodents. We present in a critical way the animal models used in the studies aimed at investigating the genetic basis of the action of anxiolytic compounds, including inbred mice, selected lines, linkage strains or mice generated by targeted mutation. Data show that increased anxiety-like behaviour is not a predictive factor for increased sensitivity to anxiolytic treatment, and it is possible that gene deletion might not be isomorphic to pharmacological antagonism. It is suggested that the strain differences in anxiety-like behaviour may be used as a tool in assaying anxiolytic activity of new drugs.

Brain GABA metabolism after chronic ethanol consumption and withdrawal in rats

We have studied the activities of the GABA metabolizing enzymes-GABA aminotransferase (GABA-AT), succinic semialdehyde dehydrogenase (SSA-DH) and SSA reductase (SSA-R) and the levels of GABA, glutamine and glutamate in rats preferring water (WP) or ethanol (EP) after 6 months of ethanol consumption and 12 hours to 7 days after withdrawal. We showed decreased GABA levels in the brain stem, decreased GABA-AT activity in the hemispheres and brain stem, and enhanced GABA-AT activity in the striatum of EP rats compared with the control or WP animals following chronic consumption of ethanol. We found decreased activity of SSA-R and SSA-DH in the hemispheres and brain stems of alcohol-treated rats compared to the control rats. Withdrawal (0.5-7 days) induced numerous profound changes in GABA metabolism.

Behavioral effects and pharmacokinetics of propofol in rats selected for differential ethanol sensitivity

High- and low-alcohol sensitivity (HAS and LAS) rats have been selected for their differences in ethanol-induced sleep time. The rats also differ in sensitivity to pentobarbital, halothane, isoflurane, and enflurane. To determine if this sensitivity extended to propofol, the anesthetic requirements were measured. In this study, the sleep time and the tissue levels of propofol at awakening, as well as the pharmacokinetics, were evaluated. Propofol was administered intravenously. For one group of rats, sleep times were measured; blood and brain samples were taken at awakening. Blood samples were collected in another group of rats at frequent intervals from 0 to 90 min after injection. Propofol concentration of the samples was determined by gas chromatography. The pharmacokinetic analysis was performed using a nonlinear least-squares regression program. Sleep time was not different; however, blood and brain propofol levels at awakening showed a small, but significant difference between HAS and LAS rats. Propofol blood concentration-time curve data were fitted to a three-compartment model. Pharmacokinetic parameters were also not different between the rat lines. However, sleep time was 50% longer in female rats than male rats in both strains (p < 0.0001). The rates of propofol clearance were slower in female rats, because of different rates of disappearance from the second compartment. The observations suggest that the genetic selection for ethanol sensitivity selection for propofol sensitivity was not nearly as intense and presumably involves some different genes. These two central nervous system depressants would seem to differ significantly in their mechanism of action.(ABSTRACT TRUNCATED AT 250 WORDS)

Genetic influences on locomotor activating effects of ethanol and sodium pentobarbital

The paradoxical capability of sedative-hypnotics to produce behavioral disinhibition varies among genotypes. In DBA/2 mice ethanol (ETOH) produced strong locomotor stimulation with the peak of the biphasic curve at 1.5 g/kg IP. C57BL/6 mice showed no activation, and F1S were intermediate. These characterizations held for a variety of behavioral indices derived from 15 min tests, such as distance, speed, and rest time, at doses in the 0-2.0 g/kg range. Analogous studies with sodium pentobarbital (0-40 mg/kg) yielded a similar pattern of strain differences in locomotor stimulation. In contrast, loss of righting reflex durations (60 mg/kg PENTO, IP) were similar in the two strains, indicating dissociation of activating and sedative effects. In complementary studies, long- and short-sleep mice, which were bred for differences in soporific effects of ETOH, showed similar activation profiles at ETOH doses up to 1.5 g/kg and PENTO doses up to 30 mg/kg. These studies provide support for an hypothesis of common genetic control of the activation effect for ETOH and PENTO.

Effects of ethanol and toluene on fixed-ratio performance in short sleep and long sleep mice

This study examined the effects of ethanol (EtOH) and toluene on fixed-ratio (FR) responding in mice selectively bred for sensitivity to the effects of EtOH on sleep time. Although the more sensitive long sleep (LS) mice showed greater EtOH-induced impairment in a motor performance task than did the less sensitive short sleep (SS) mice, changes in FR performance in the two lines did not differ in response to EtOH, regardless of route (oral or intraperitoneal) or time (40 vs. 60 min pre-session) of administration. These results emphasize the importance of considering task variables in determination of the behavior of different genotypes. In contrast to results with EtOH, the volatile inhalant toluene produced different effects on FR responding in the selected lines, with SS mice being more sensitive than LS mice.

gamma-Aminobutyric acid-activated chloride channels in rats selectively bred for differential acute sensitivity to alcohol

Effects of various sedative hypnotic agents on GABA-mediated chloride flux were evaluated in whole brain membrane vesicles (microsacs) prepared from rats selectively bred for high (HAS) and low sensitivity (LAS) to an acute hypnotic dose of alcohol. The HAS rats were more sensitive to the effects of pentobarbital, phenobarbital, flunitrazepam, and ethanol on GABA-mediated chloride flux compared with the LAS rats. No differences between the lines in GABA-stimulated chloride flux were observed. Modulation of 1-[3H]-phenyl-4-butyl-2,6,7-trioxabicyclo(2.2.2)octane ([3H]-TBOB) and [3H]-diazepam binding also was measured. The lines did not differ in inhibition of [3H]-TBOB binding by pentobarbital, phenobarbital, muscimol or picrotoxin. Although the lines displayed almost identical KD and Bmax for [3H]-diazepam binding, the GABA agonist, muscimol, was a more potent stimulator of [3H]-diazepam binding in membranes prepared from HAS rats than from LAS rats. These findings are discussed in light of previous work using other selected lines.

t-[35S]butylbicyclophosphorothionate binding under equilibrium and nonequilibrium conditions: differential effects of barbiturates and gamma-aminobutyric acid in the long-sleep and short-sleep selected mouse lines

Significant differences were demonstrated between the long-sleep (LS) and short-sleep (SS) selected mouse lines in the abilities of barbiturates and gamma-aminobutyric acid (GABA) to inhibit t-[35S]butylbicyclophosphorothionate [( 35S]TBPS) binding to well-washed cerebral cortical membranes. Thus, using phenobarbital to initiate the dissociation of [35S]TBPS, the extent of inhibition was significantly greater in LS mice (but not SS mice) than would be predicted using equilibrium conditions. Pentobarbital had the opposite effect, causing [35S]TBPS to dissociate to a greater extent in SS than LS membranes. [35S]TBPS binding was dissociated from LS and SS membranes by GABA to a greater and lesser extent, respectively, than would be predicted from equilibrium studies. Because no line differences in the potencies of these drugs to inhibit [35S]TBPS binding were found using equilibrium conditions, these results indicate that the association rates of barbiturates and GABA may be different between these lines. These findings are consistent with neurochemical studies indicating differences in the benzodiazepine/GABA receptor-chloride channel complex in these selected lines and may explain their differential sensitivities to certain agents acting through this supramolecular complex.

Plus-maze behavior and susceptibility to 3-mercaptopropionate-induced seizures in rat lines selected for high and low alcohol sensitivity

Selective outbreeding for high and low acute alcohol sensitivity has produced two rat lines (alcohol-sensitive ANT and alcohol-insensitive AT lines) that also differ in their sensitivity to GABAergic drugs, benzodiazepines and barbiturates. These rats were now compared in two behavioral tests believed to involve central GABAergic mechanisms, in elevated plus-maze test and in 3-mercaptopropionate-induced seizure test. The AT animals spent more time in the open arms of the plus-maze than the ANT rats, suggesting that the AT's behave less anxiously. The ANT's were more susceptible to seizures induced by 3-mercaptopropionate (50 mg/kg, IP) than the AT's, suggesting the ANT's having greater sensitivity to a decrease in brain GABA concentration. At the time of the first seizure signs, there was a tendency, though a nonsignificant one, to greater decreases in brain GABA in the ANT's than AT's. These results suggest that there are differences in GABA-related behaviors between ethanol-naive rats of the lines produced by selective outbreeding for differences in alcohol sensitivity. In theory, these behavioral line differences might physiologically counteract alcohol effects in the ANT's and enhance them in the AT's. In elevated plus-maze test, however, an acute dose of ethanol (1 g/kg, IP) significantly changed the behavior of the ANT animals, but only up to level of the AT rats. The apparent sensitivity to ethanol may thus be dependent on the naive behavior of the alcohol-insensitive AT and alcohol-sensitive ANT rats.

Genetics of responses to drugs of abuse

Genetic differences in drug metabolism, in the number of drug receptors in the brain, and in drug-seeking behavior may contribute to the variability of individual responses to drugs of abuse. Genetic models include inbred strains, mutants, sublines, and selectively bred mice and rats. They have been used to examine acute and chronic effects of narcotics, stimulants, and alcohol as well as drug-seeking behavior, withdrawal syndromes, and the stress-induced release of endogenous opioids. These genetic models should prove helpful in defining individual differences in susceptibility to addiction.

[35S]TBPS binding sites are decreased in the colliculi of mice with a genetic predisposition to bicuculline-induced seizures

Several differences have been found in GABAergic function between the long sleep (LS) and short sleep (SS) mice which were genetically selected for different ethanol-induced sleeptimes, and it has been suggested that these differences may explain their differential ethanol sensitivity. However, these lines also differ in seizure susceptibility, a behavior which may also be mediated by GABAergic pathways. Thus, it is difficult to associate differences in GABA neurochemistry with either of these behaviors, particularly when only two selected lines are used. We measured differences in the density and affinity of the [35S]TBPS binding site on the GABAA receptor/Cl- ionophore complex in discrete brain areas; and in order to determine the relationship between receptor binding and behavioral differences, we included mice from 5 of the LS and SS recombinant inbred strains (LS x SS RI) in addition to mice from the LS and SS lines. [35S]TBPS binding in sagittal brain sections was analyzed by quantitative autoradiography, and the amount of binding differed depending on whether bicuculline was added to inhibit endogenous GABA binding. In the presence of bicuculline, the number of [35S]TBPS sites in SS mice was highest in the colliculi (4.5 +/- 0.5 pmol/mg protein), cerebellum (4.8 +/- 0.6 pmol/mg), hippocampus (3.2 +/- 0.7 pmol/mg) and cortex (2.9 +/- 0.3 pmol/mg). The Bmax was two-fold lower in both superior and inferior colliculi (IC) of LS mice. There were no differences between lines in Bmax in any other area and in Kd values in any area (58 +/- 4.0 nM).(ABSTRACT TRUNCATED AT 250 WORDS)

Patterns of convulsive susceptibility in the long-sleep and short-sleep selected mouse lines

It has been hypothesized that the Long-Sleep and Short-Sleep mouse lines were bidirectionally selected for high and low brain excitability, and further, that these differences are mediated by the benzodiazepine/gamma-aminobutyric acid (GABA) receptor-chloride channel complex. Hence, mice from both lines were administered seven convulsants (bicuculline, pentylenetetrazol, 3-carbomethoxy-beta-carboline, picrotoxin, caffeine, flurothyl and strychnine) and myoclonic and clonic seizure latencies recorded. Supporting the original hypothesis, the results show that the two lines were differentiated by all of the convulsants and that in response to the drugs, three distinct convulsive patterns were found. Nevertheless, a simple genetic model accounting for these results was not evident. To further clarify these susceptibility patterns, a convulsant representing each of these patterns (bicuculline, pentylenetetrazol or caffeine) was administered in conjunction with the anticonvulsant-barbiturate phenobarbital or the benzodiazepine antagonist Ro 15-1788. Irrespective of the convulsant given, phenobarbital attenuated both myoclonus and clonus subsequent to all convulsants, while Ro 15-1788 had a more discrete anticonvulsant profile.

Effect of taurine on ethanol-induced sleep time in mice genetically bred for differences in ethanol sensitivity

Long Sleep (LS) and Short Sleep (SS) mice were used in this study to investigate the interaction between ethanol and taurine. Sleep time (hypnosis) was selected as an index of ethanol-induced central nervous system depression. In order to achieve a similar degree of central nervous system depression with ethanol, SS and LS mice received 5.3 and 3.0 g/kg, IP, of ethanol, respectively. When taurine (7.5, 15 and 25 mumol/kg) was administered intracerebroventricularly (ICV) to LS and SS mice immediately after regaining the righting reflex following ethanol injection, a return to sleep time was produced. This effect of taurine was immediate in onset and occurred in a dose-dependent fashion. LS mice exhibited a greater effect from taurine administration than SS mice. In another experiment LS and SS mice were given ICV TAG, a taurine antagonist (6-aminomethyl-3-methyl-4H-1,2,4-benzothiadiazine-1,1-dioxide HCl), which significantly reduced the effect of taurine to produce a return to sleep time in the presence of ethanol. TAG did not affect ethanol-induced sleep time. In control experiments, in the absence of ethanol, neither taurine (25 mumol/kg, ICV) nor TAG (1 mumol/kg, ICV) caused a significant loss of the righting reflex (sleep time). When pentobarbital (50 mg/kg, IP) was injected instead of ethanol in the sleep time experiments, taurine (7.5, 15 and 25 mumol/kg, ICV) produced a return to sleep time in LS and SS mice that resembled the effect of taurine with ethanol in SS mice. These results indicate that taurine (ICV) can enhance the central depressant action of ethanol and pentobarbital and that the greatest effect of taurine occurred with LS mice in the presence of ethanol. It is possible that taurine may have some role in the central nervous system depressant properties of ethanol.

Astrocyte proliferation precedes a decrease in basket cells in the dentate fascia following chronic ethanol treatment in mice

The effect of chronic ethanol administration on the density of basket cells in the dentate gyrus of mice selectively bred for their sensitivity to acute ethanol exposure (long-sleep, LS and short-sleep, SS) was assessed in two experiments. In addition, the effect of chronic ethanol on the density of dentate granule cells and astrocytes was examined. In the first experiment, mice received 3 weeks of a liquid ethanol diet with 35% of their calories derived from ethanol (EDC). In this experiment, LS mice did not demonstrate a change in the density of granule cells or in the density of basket cells. There was, however, a significant increase in the density of astrocytes as a result of this treatment for the LS mice. The SS mice were unaffected on all measures. In the second experiment, portions of which have been reported previously, mice received a diet with 23% EDC for 3 months. As a result of this exposure, LS mice showed a significant decrease in the density of basket cells, but there was no change in the density of granule cells or astrocytes. There was no difference between controls and experimental mice from the SS group on any of these parameters. These results suggest that at least in the dentate gyrus, chronic ethanol treatment selectively reduces the density of basket cells but only in mice that are more sensitive to the hypnotic effects of acute ethanol exposure. Furthermore, this effect seems to be preceded by an apparent increase in the density of astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Differences in the biophysical properties of the benzodiazepine/gamma-aminobutyric acid receptor chloride channel complex in the long-sleep and short-sleep mouse lines

Significant differences in the thermal stability of benzodiazepine receptors were found in cerebral cortical membranes prepared from the long-sleep (LS) and short-sleep (SS) selected mouse lines. Thus, benzodiazepine receptors from LS mice were heat inactivated (55 degrees C) at a significantly faster rate than those from SS mice. Although gamma-aminobutyric acid (GABA) reduced the rate of heat inactivation in both lines, the more rapid rate of inactivation in the LS line was maintained. Furthermore, the potency of GABA to enhance [3H]flunitrazepam binding decreased threefold in membranes from LS mice as the incubation temperature was increased from 0 degrees to 37 degrees C, but was unaltered in membranes from SS mice. These differences in the biophysical properties of the benzodiazepine/GABA receptor chloride channel complex ("supramolecular complex"), together with a higher KD for t-[35S]butylbicyclophosphorothionate in membranes from LS compared to SS mice, suggest that the supramolecular complex may modulate the differential sensitivity to some depressants and convulsants in these lines.

Molecular interactions of ethanol with GABAergic system and potential of RO15-4513 as an ethanol antagonist

The behavioral and biochemical effects of ethanol in man and animals have been investigated for a long time. A role of catecholamines in the central stimulatory action and during withdrawal has been envisaged, but more recent observations have revealed the involvement of inhibitory synaptic transmitter, GABA, in the actions of ethanol. Ethanol-induced motor incoordination, hypnosedation, antianxiety, and anticonvulsant actions are reported to be GABA-mediated. Involvement of the GABA system has been implicated in ethanol withdrawal-induced seizures in animals. More direct evidences using Cl- influx studies in synaptoneurosomes and spinal neuronal culture studies confirm such a mode of action of ethanol, probably influencing the chloride channel modulation at the GABA-benzodiazepine receptor ionophore complex. RO15-4513 (ethyl-8-azido-5,6-dihydro-5-methyl-6-Oxo-4H-imidazo [1,5-alpha], [1,4] benzodiazepine-3-carboxylate), a novel imidazobenzodiazepine, an analogue of the classical benzodiazepine antagonist is reported to possess alcohol antagonistic properties. RO15-4513 reverses both the behavioral and biochemical effects of ethanol, including the action of GABA-induced Cl- fluxes. But its potential clinical application may be restricted due to its inverse agonistic property. The present review focuses on the GABA-linked behavioral and biochemical actions of ethanol and discusses the potential of RO15-4513 as an alcohol antagonist.

Differential modulation of benzodiazepine receptor binding by ethanol in LS and SS mice

The LS and SS lines of mice were initially selected based on sedative responses to ethanol, but have been found to differ in response to a variety of hypnotics and anesthetics. These differences do not appear to be due to pharmacokinetic factors and several lines of evidence suggest involvement of the GABAergic system. To examine an important component of this system, the benzodiazepine receptor, we analyzed benzodiazepine receptor binding in vivo in LS and SS mice, and modulation of receptor binding by three interventions known to increase binding in other strains: pentobarbital, defeat stress, and ethanol. Receptor binding was determined by specific uptake of [3H]-Ro15-1788. Receptor binding was increased in cortex and hippocampus of LS mice compared to SS mice, with the increase in cortex most likely due to increased receptor number rather than a change in apparent affinity. Pentobarbital (30 mg/kg IP) induced similar increases in binding in both lines in several brain regions. Defeat stress caused increased binding in several brain regions of both SS and LS mice, with greater binding in cortex of LS mice. In contrast, ethanol at 3 doses (0.5, 1, and 2 g/kg) led to greater increases in binding in SS mice compared to LS mice in most brain regions. None of the interventions altered nonspecific binding. Ethanol concentrations were slightly greater in plasma and brain of LS mice. These results indicate differences in benzodiazepine receptor binding in LS and SS mice, with differential modulation of binding by ethanol but not by pentobarbital or stress. These differences may contribute to differential pharmacodynamic responses in the two lines of mice.

The effect of ethanol on arachidonic acid metabolism in the murine peritoneal macrophage

Exposure to ethanol in man has been linked to an alteration of the immune surveillance system and reduced ability of the macrophage to undergo phagocytosis. Since ethanol has been suggested to alter membrane function and inhibit the production of calcium ionophore stimulated synthesis of prostaglandins and leukotrienes by the human neutrophil and transformed murine mast cell, the dose response effect of ethanol on the biosynthesis of icosanoids by the peritoneal macrophage during zymosan phagocytosis was studied. Peritoneal macrophages from two inbred strains of mice derived from a common stock (HS) and selected for sensitivity to ethanol (short sleep [SS]/long sleep [LS]) were studied. Zymosan phagocytosis was found to lead to synthesis of LTC4 (70 ng/10(6) cells), 6-keto-PGF1 alpha (5 ng/10(6) cells) and PGE2 (3 ng/10(6) cells). For the HS macrophage, ethanol caused a dose dependent inhibition of these lipid mediators as well as inhibition of phagocytosis and release of beta-hexosaminidase. However, a difference was observed in arachidonate metabolism stimulated by phagocytosis between the LS and SS mice below 100 mM ethanol. The SS mouse had a 50% inhibition of cyclooxygenase products at 86 mM ethanol with no inhibition of lipoxygenase metabolites. The LS mice had a trend suggesting increased lipoxygenase metabolites below 100 mM ethanol. At these levels of ethanol which can be found in man, these results suggest there may be differential production of lipid mediators under genetic control.

Changes in the frequency of basket cells in the dentate fascia following chronic ethanol administration in mice

The frequency of basket cells in the granule cell layer of the dentate fascia of Short Sleep (SS) and Long Sleep (LS) mice was determined following 3 months of ethanol exposure. These mice were bred for their differential susceptibility to the narcotic effects of acute doses of ethanol. The ethanol-insensitive SS mice were unaffected by the treatment while the ethanol-sensitive LS mice that received ethanol showed a significant decrease in basket cell frequency over their control group counterparts. These basket cells are thought to control the tonic level of activity of the granule cells. Thus, a decrease in basket cell frequency might lead to higher granule cell activity following chronic ethanol exposure. This effect could counteract the assumed stronger depressant effect of ethanol in the relatively ethanol-sensitive LS mice.

Effect of chronic ethanol consumption on the fine structure of the dentate gyrus in long-sleep and short-sleep mice

The effect of short- and long-term chronic ethanol consumption on the fine structure of the dentate gyrus was examined in two lines of mice selected for their differential sensitivity to acute ethanol administration. Quantitative electron microscopic analysis of dendritic spines, axon terminals, and synaptic appositions revealed significant differences between the long-sleep and short-sleep mice. In control preparations, long-sleep mice were found to have larger spine areas and perimeters, larger axon terminals, and longer synaptic appositions than short-sleep mice. In addition, the shape of dendritic spines in the long-sleep mice was significantly more complex than those of short-sleep mice. Ethanol tended to increase this complexity in long-sleep mice only. Ethanol had only a limited effect on the other anatomical measures. The results provide evidence for ultrastructural differences between the nervous systems of these lines of mice which may have a role in their differential sensitivity to acute ethanol administration.

Differential convulsive susceptibility of high-activity and low-activity selected mice in response to GABA antagonists

Lines of mice selectively-bred for High and Low-Activity in an open-field maze were tested for seizure susceptibility to three analeptics: flurothyl, pentylenetetrazol and bicuculline. The major finding was that two replicate High-Activity lines were more susceptible to myoclonic convulsions but less susceptible to clonic convulsions than their respective replicate Low-Activity lines. The major exception to this finding was that the High and Low-Activity lines did not differ for bicuculline-induced clonus although females tended to conform to the general pattern. These results are interesting because they demonstrate that diametrically opposite susceptibility to myoclonus and clonus is not an isolated phenomenon. Similar seizure susceptibility patterns and activity differences have also been reported for the Long-Sleep and Short-Sleep selectively-bred mouse lines. Further, since the progenitor population of the High-Activity and Low-Activity lines were developed from strains that were also part of the progenitor population of the Long-Sleep and Short-Sleep lines, it is hypothesized that some of the same alleles underwent selection in both selective-breeding programs.

Intoxicating effects of lorazepam and barbital in rat lines selected for differential sensitivity to ethanol

The motor impairing effects and plasma concentrations of barbital and lorazepam were studied in the alcohol tolerant (AT) and alcohol non-tolerant (ANT) rat lines developed for low and high sensitivity to motor impairment from ethanol. The mixed (M) line, from which the AT and ANT rats were derived, was also included in the study. Like ethanol, barbital and lorazepam impaired the performance of the ANT rats more than that of the AT rats. The motor performance of the M rats was relatively more impaired after barbital than after lorazepam administration at the same dose used in the AT and ANT rats. At the two latter time points (2.5 and 3.5 h) the sensitive ANT rats had significantly higher serum barbital concentrations than the AT rats. The serum barbital concentrations of the AT and ANT rats did not differ, however, at the two first time points (0.5 and 1.5 h) of the tilting plane tests, although the ANT rats were significantly more intoxicated. The concentrations of lorazepam in plasma do not explain the differential motor impairment either, since the sensitive ANT rats had lower plasma concentrations than the insensitive AT rats. The results, thus, suggest that the selection involved in the development of the AT and ANT lines has not been specific for ethanol. The results also support the idea that ethanol, barbiturates and benzodiazepines have some modes of action in common.

Gamma-aminobutyric acid and alcohol actions: neurochemical studies of long sleep and short sleep mice

Effects of ethanol and pentobarbital on the GABA receptorchloride channel complex were evaluated in mice selected for differential sensitivity to the hypnotic effects of ethanol (long sleep and short sleep lines). 36Cl- influx, [35S]tbutylbicyclophosphorothionate (TBPS) and [3H]muscimol binding were measured in a membrane vesicle suspension (microsacs) from cerebellum or forebrain. Muscimol was found to be a more potent stimulator of 36Cl- flux in the LS cerebellum, as compared to the SS cerebellum, but a similar maximal level of uptake was achieved in the two lines. Muscimol displaced [35S]TBPS (a ligand for the convulsant site) from cerebellar microsacs, and LS mice were also more sensitive than SS mice to this action of muscimol. However, the number or affinity of high affinity [3H]muscimol binding sites did not differ between the lines. Physiologically relevant concentrations of ethanol (15-50 mM) potentiated muscimol stimulation of 36Cl- uptake in LS cerebellum but had no effect in SS cerebellum. Ethanol failed to alter stimulated chloride flux hippocampal microsacs from either line. Both the LS and SS lines responded similarly to pentobarbital potentiation of muscimol stimulated chloride uptake regardless of brain region. The demonstrated difference between the LS and SS mice in muscimol stimulated chloride uptake as well as in muscimol displacement of [35S]TBPS binding offers a biochemical explanation for the line differences in behavioral responses to GABAergic agents. Moreover, the findings suggest that genetic differences in ethanol hypnosis are related to differences in the sensitivity of GABA-operated chloride channels to ethanol.

GABAergic drugs can enhance or attenuate chlordiazepoxide-induced sleep time in a heterogeneous strain of mice

Evidence supports the notion that differences between the Long-Sleep and Short-Sleep selectively-bred lines of mice are attributable to differences in brain excitability and that these differences are mediated by activity of the GABAergic system. The general applicability of this hypothesis to other populations of mice was tested by using an outbred strain of mice. Specifically, a heterogeneous strain of mice was administered several doses of the hypnotic chlordiazepoxide. Additionally, the indirect GABA agonist AOAA, and the GABA antagonists bicuculline, picrotoxin and pentylenetetrazol were administered to independent groups in conjunction with chlordiazepoxide. The results clearly demonstrate that chlordiazepoxide dose-dependently increased hypnosis, while AOAA enhanced, and the antagonists attenuated sleep time. These findings can be used to support the contention that GABA mediates the bidirectional response of Long-Sleep and Short-Sleep mice to CNS hypnotic-depressants; and, further, show that GABA mediation of sleep time in mice is a general phenomenon.

Sedative-hypnotic anomalies related to dose of pentobarbital in long-sleep and short-sleep selectively-bred mice

Hypnotic effects following administration of three doses of pentobarbital were evaluated in mice selectively-bred for differential hypnotic sensitivity to ethanol. Although the ethanol-sensitive Long-Sleep (LS) line displays greater sedation to a wide variety of CNS depressants (alcohols, barbiturates, benzodiazepines, general anesthetics), when compared to the ethanol-insensitive Short-Sleep (SS) line, the response pattern to pentobarbital remains equivocal. Thus, to clarify the effect of pentobarbital, certain variables (dose, sex, circadian rhythmicity) believed to be important in the expression of sleep time were evaluated. For all doses examined "sex" and "time of day tested" impacted on sleep time. With these provisos, 40 mg/kg consistently induced shorter sleep time in SS mice. The 60 mg/kg dose either failed to distinguish these two lines, or induced greater sleep times in the SS mice. The 80 mg/kg dose tended to have the same effect as the 60 mg/kg dose, but to a greater degree. Overall, it appears that for each line the dose response curve for pentobarbital is sigmoidal, but that the slope of the curve for the middle range of doses is greater for the SS line. Since pentobarbital has a unique effect on these lines of mice that is dissimilar to those reported for other barbiturates, the implication is that an additional factor, that is unimportant for other barbiturates, is essential for pentobarbital-induced hypnosis. Factors that could be responsible for this effect include differential metabolism of Gabaergic receptor dynamics.

Thiopental, phenobarbital, and chlordiazepoxide induce the same differences in narcotic reaction as ethanol in long-sleep and short-sleep selectively-bred mice

Hypnotic effects following administration of thiopental, phenobarbital or chlordiazepoxide were evaluated in mice selectively-bred for differential hypnotic sensitivity to ethanol. For every dose employed, except one which had no effect, all three agents induced greater sedation in the ethanol-sensitive Long-Sleep (LS) line than in the ethanol-insensitive Short-Sleep (SS) line. Such findings with regard to the LS and SS lines suggest that the differences in sedative response to ethanol, as well as some barbiturates and benzodiazepines, may be mediated, in part, by a common mechanism. The second experiment showed that age of the subjects can be an important variable influencing hypnotic-induced sleep time. For thiopental, significant line differences occurred only with 150 day old mice, whereas chlordiazepoxide produced differences in 50, 75, 100 and 150 day old mice.