Edward J. Gallaher

Genetic determinants of sensitivity to diazepam in inbred mice

Mice from 15 standard inbred strains were tested for sensitivity to several effects of acute diazepam (DZ). Strains differed in sensitivity to DZ-induced: low-dose stimulation and high-dose depression of locomotor activity, hypothermia, and ataxia assessed on a rotarod. Correlations among strain means indicated that sensitivity to a particular effect of DZ generalized well across doses. Sensitivities to some of the different behavioral responses also were significantly correlated. For example, strains sensitive to DZ-induced increases in activity were significantly less sensitive to the drugs hypothermic effects. These results suggest that there are multiple genetic determinants of behavioral sensitivity to DZ effects. That is, genetically influenced sensitivity to DZ is not monolithic but is somewhat specific to the particular response variable studied, a result that also characterizes genetic control of responses to other drugs.

Genetic selection for benzodiazepine ataxia produces functional changes in the γ-aminobutyric acid receptor chloride channel complex

The gamma-aminobutyric acid (GABA) receptor-operated chloride channel complex was evaluated in mice selected for differential sensitivity to the ataxic effects of diazepam (diazepam-sensitive (DS) and diazepam-resistant (DR) lines). The ataxic effects of several drugs purported to produce some of their actions through the benzodiazepine-GABA receptor complex were examined using the rotarod test. The duration of impairment produced by diazepam, ethanol, 4,5,6,7-tetrahydroisoxazol[5,4-C]pyridine-3-ol (THIP) and phenobarbital was greater in the diazepam-sensitive than in the diazepam-resistant mice. In contrast, pentobarbital produced an equivalent duration of ataxia in the two lines. Muscimol-stimulated 36Cl- influx and the binding of [35S]t-butylbicyclophosphorothionate (TBPS) and [3H]flunitrazepam were measured using isolated brain membrane vesicles (microsacs). Depolarization-dependent 45Ca2+ uptake was measured in whole brain synaptosomes. Muscimol was a more potent stimulator of 36Cl- flux in the DS compared to the DR mice, although no difference between the lines was found in muscimol-stimulation of [3H]flunitrazepam binding. Flunitrazepam augmented the muscimol-stimulated 36Cl- uptake in the DS but not in the DR mice. However, no differences between the lines of mice were found in either density or affinity of [3H]flunitrazepam binding sites. Similarly, no differences in either the density or affinity of [35S]TBPS binding sites was found. Ethanol (10-45 mM) potentiated the muscimol-stimulation of 36Cl- in DS, with no effect in DR mice. However, ethanol inhibition of [35S]TBPS binding was equivalent in the two lines of mice. Pentobarbital produced an equal potentiation of the muscimol-stimulated 36Cl- flux in the two lines, but phenobarbital potentiated the muscimol-induced 36Cl- influx slightly more in DS mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Volatile anesthetic requirements differ in mice selectively bred for sensitivity or resistance to diazepam : implications for the site of anesthesia

&NA; One approach to elucidating the general anesthetic target has used genetic selection procedures, wherein animals are bred for sensitivity or resistance to general anesthetics and correlations are sought with a specific neuronal structural or functional defect. For example, murine strains have been developed that are either sensitive or resistant to the obtunding effects of diazepam, as assessed by their ability to maintain balance on a rotating rod. The present study explored whether diazepam‐sensitive (DS) and diazepam‐resistant (DR) mice might also be similarly divergent in the obtunding response to general anesthetics, by testing the requirements for halothane and enflurane in these strains. Using a carousel enclosed in a chamber, the end‐point of loss‐of‐righting reflex was defined. For both anesthetics, the DS group had a lower median effective dose (ED50, %atm) than did the DR group, and the reductions paralleled diazepam susceptibility. For example, with halothane, the ED50 for the DS group was 0.72 ± 0.022 (SE); the ED50 for the DR group was 0.87 ± 0.030 (P < 0.0001). Similar results were obtained with enflurane. Such findings associate an inbred difference in response to diazepam with altered volatile anesthetic requirement, suggesting that these two phenotypes are mediated by a common underlying mechanism. (Anesth Analg 1993;76:1313‐7)

Genetic determinants of sensitivity to pentobarbital in inbred mice

Rationale. We postulated that genetic determinants of different responses to pentobarbital (PB) in mice would differ from response to response.Objectives. Mice from 14 standard inbred strains were tested for sensitivity to several effects of acute PB.Methods. Strains were tested for sensitivity to PB-induced low-dose stimulation and high-dose depression of locomotor activity, reduced rearing, hypothermia, and ataxia assessed on a rotarod, using four doses of PB or saline.Results. Strains differed in sensitivity to PB for all responses. Correlations among strain means indicated that strain sensitivity to a particular effect of PB generalized rather well across doses. Sensitivities to some of the different behavioral responses were also significantly correlated. For example, strains less sensitive to PB-induced enhanced locomotor activity were also significantly more sensitive to the drugs hypothermic effects. Some responses were genetically independent. Brain PB concentrations were also determined, and appeared to be unrelated to inbred strain drug sensitivities.Conclusions. Overall, these results suggest that there are multiple genetic determinants of behavioral sensitivity to PB effects. That is, genetically influenced sensitivity to PB is not monolithic, but is somewhat specific to the particular response variable studied, a result that also characterizes genetic control of responses to other drugs.

Dissociation of the Effect of Aminoglutethimide on Corticosterone Biosynthesis from Ataxic and Hypothermic Effects in DBA and C57 Mice

Adrenalectomy is frequently used to deplete adrenocortical hormones in physiological and receptor-binding studies in animals. However, this procedure is irreversible, removes both the cortex and medulla, and produces many negative side effects such as hypotension and hypoglycemia. Aminoglutethimide is a steroid synthesis inhibitor which depletes adrenocortical hormones without these negative effects. However, aminoglutethimide itself has been shown to produce behavioral and physiological deficits. In the present experiments, dose-response relationships were determined for the effects of aminoglutethimide on corticosterone levels, motor coordination, and body temperature in C57 and DBA mice. Aminoglutethimide (5.4-54 mg/kg) inhibited the increase in plasma corticosterone concentrations normally observed in response to restraint stress. Only at higher doses (170-1,000 mg/kg) were rotarod performance and body temperature affected. The corticosterone response to restraint stress recovered fully between 12 and 24 h after aminoglutethimide. In the present study, doses of aminoglutethimide were found that temporarily inhibit stressed corticosterone release without producing motor deficits and temperature decreases. These results indicate that aminoglutethimide is a potential substitute for adrenalectomy in studies on the effects of removal of adrenocortical hormones.

Locomotor responses to benzodiazepines, barbiturates and ethanol in diazepam-sensitive (DS) and -resistant (DR) mice

Diazepam-sensitive (DS) and -resistant (DR) mice were selectively bred for increased and reduced sensitivity to the ataxic effects of diazepam (40 mg/kg). Other response differences between DS and DR mice may reflect pleiotropic effects of the genes fixed during their selection. These mice were tested for their sensitivity to the locomtor stimulant effects of several doses of diazepam, flunitrazepam, pentobarbital, phenobarbital, and ethanol. DR mice were more sensitive than DS mice to the locomotor stimulant effects of all drugs except phenobarbital. These results largely support the hypothesis that a common biological mechanism mediates sensitivity to the stimulant effects of sedative-hypnotic drugs. Receptor mediation of the benzodiazepine effects was examined by administering the benzodiazepine receptor antagonist, RO15-1788. Locomotor depression produced by diazepam and flunitrazepam in DS mice was blocked by RO15-1788. However, while the locomotor stimulation produced by diazepam in DR mice was antagonized, the stimulant effect of flunitrazepam was not. This suggests that binding of flunitrazepam to the GABAA-benzodiazepine receptor is not necessary for production of locomotor stimulation.

Halothane's effects on GABA-gated chloride flux in mice selectively bred for sensitivity or resistance to diazepam

The DS (diazepam-sensitive) and DR (diazepam-resistant) lines of mice, selected on the basis of their ataxic response to diazepam, also diverge in the physiologic response of their brain gamma-aminobutyric acidA (GABAA) receptors to benzodiazepines, as indicated by augmentation of GABA-mediated chloride flux. Cross-sensitivity and -resistance to other sedatives known to interact with the GABAA-receptor have also been demonstrated in DS and DR mice. Based on the finding that these mice also show cross-sensitivity and -resistance to obtundation by halothane, we predicted that their GABAA-receptors would also exhibit a differential response to halothane as assayed by an in vitro 36Cl- influx assay using purified brain microvesicles. Consistent with this prediction, therapeutic concentrations of halothane enhanced 1 mumol/l GABA-gated flux with significantly greater potency in DS than in DR mice (halothane EC50 336 +/- 64 mumol/l (S.E.M.) vs. 605 +/- 110 mumol/l, respectively, P = 0.03), but there was no difference in maximal flux enhancement between the two lines (DS 4.7 +/- 0.4 nmol.mg-1 x 3 s-1, vs. DR 4.7 +/- 0.5 nmol.mg-1 x 3 s-1). Halothane (500 mumol/l) also shifted the entire GABA concentration-flux relationship significantly to the left, decreasing the EC50 for GABA in both the DS and DR lines. Importantly, the shift in the GABA concentration-flux response in the presence of halothane was more pronounced in the DS mice (GABA EC50 1.8 +/- 0.4 mumol/l vs. 14.7 +/- 0.9 mumol/l without halothane) than in the DR mice (GABA EC50 4.7 +/- 0.6 mumol/l vs. 14.7 +/- 0.9 mumol/l without halothane).(ABSTRACT TRUNCATED AT 250 WORDS)

Genetics of Benzodiazepines, Barbiturates, and Anesthetics

The behavioral effects of the benzodiazepines (BZs) first attracted attention when chlordiazepoxide was observed to produce a taming effect in previously vicious monkeys. Clinical trials soon followed, and chlordiazepoxide (Librium®) was introduced into clinical practice in 1960, followed closely by diazepam (Valium®) in 1963. Primarily because of their extraordinary safety, these drugs rapidly replaced the barbiturates as anxiolytics of choice. The benzodiazepines soon became the most widely prescribed psychoactive drugs, arid indeed the most-prescribed drugs of any class, until attention was directed to their overuse and potential dependence liability. They continue to be used widely for their sedative-hypnotic, anxiolytic, anticonvulsant, and muscle relaxant effects, and despite the abovementioned dependence liability, they remain among the most useful and safest drugs available.

Halothane sensitivity in replicate mouse lines selected for diazepam sensitivity or resistance.

We have previously shown that mice selected for sensitivity to diazepam are also more sensitive to halothane, and that halothane augments the gamma-aminobutyric acid (GABA)-mediated chloride flux response in brain tissue from diazepam-sensitive (DS) mice to a greater degree than in diazepam-resistant (DR) mice. These findings suggest that the GABAA receptor is an important site of halothane action. To confirm this correlation, halothane requirement was determined in two independently developed replicate lines of DS and DR mice. Association of the traits of diazepam and halothane sensitivity in replicate lines of DS mice diminishes the probability that the original finding was due to a false-positive correlation, and instead suggests that it results from the common action of genes controlling diazepam sensitivity. Halothane median effective concentration (EC50) was determined by using the end-point of loss of righting reflex in two replicate lines of mice selected for diazepam sensitivity (resistant mice = diazepam high performance-1 and -2 [DHP-1 and DHP-2], sensitive mice = diazepam low performance-1 and -2 [DLP-1 and DLP-2]). DLP-1 and DLP-2 mice were sensitive to halothane, whereas DHP-1 and DHP-2 mice were resistant to halothane. Halothane EC50 in the DLP-1 and DHP-1 mice was 0.86 +/- 0.01 (SE) and 1.10 +/- 0.04 atm%, respectively (P < 0.0001), and that in the DLP-2 and DHP-2 mice was 0.88 +/- 0.01 and 0.97 +/- 0.02 atm%, respectively (P < 0.0001).(ABSTRACT TRUNCATED AT 250 WORDS)