The effect of halothane on mice selectively bred for differential sensitivity to alcohol

General Genetic Strategies

It is difficult to study the genetics and molecular mechanisms of anesthesia in humans. Fortunately, the genetic approaches in model organisms can, and have, led to profound insights as to the targets of anesthetics. In turn, the organization of these putative targets into meaningful pathways has begun to elucidate the mechanisms of action of these agents. However, it is important to first appreciate the strengths, and limitations, of genetic approaches to understand the anesthetic action. Here we compare the commonly used genetic model organisms, various anesthetic endpoints, and different modes of genetic screens. Coupled with the more specific data presented in subsequent chapters, this chapter places those results in a framework with which to analyze the discoveries across organisms and eventually extend the resulting models to humans.

Reduced limbic metabolism and fronto-cortical volume in rats vulnerable to alcohol addiction

Alcohol abuse is associated with long-term reductions in fronto-cortical volume and limbic metabolism. However, an unanswered question in alcohol research is whether these alterations are the sole consequence of chronic alcohol use, or contain heritable contributions reflecting biological propensity toward ethanol addiction. Animal models of genetic predisposition to alcohol dependence can be used to investigate the role of inborn brain abnormalities in the aetiology of alcoholism. Here we used magnetic resonance imaging (MRI) in the Marchigian-Sardinian (msP) alcohol-preferring rats to assess the presence of inherited structural or functional brain alterations. Alcohol-naïve msP (N=22) and control rats (N=26) were subjected to basal cerebral blood volume (bCBV) mapping followed by voxel-based morphometry (VBM) of grey matter and tract-based spatial statistics mapping of white matter fractional anisotropy. msP rats exhibited significantly reduced bCBV, an established marker of resting brain function, in focal cortico-limbic and thalamic areas, together with reduced grey matter volume in the thalamus, ventral tegmental area, insular and cingulate cortex. No statistically significant differences in fractional anisotropy were observed between groups. These findings highlight the presence of inborn grey matter and metabolic abnormalities in alcohol-naïve msP rats, the localization and sign of which are remarkably similar to those mapped in abstinent alcoholics and subjects at high risk for alcohol dependence. Collectively, these results point for a significant role of heritable neurofunctional brain alterations in biological propensity toward ethanol addiction, and support the translational use of advanced imaging methods to describe the circuital determinants of vulnerability to drug addiction.

A stomatin and a degenerin interact to control anesthetic sensitivity in Caenorhabditis elegans

The mechanism of action of volatile anesthetics is unknown. In Caenorhabditis elegans, mutations in the gene unc-1 alter anesthetic sensitivity. The protein UNC-1 is a close homologue of the mammalian protein stomatin. Mammalian stomatin is thought to interact with an as-yet-unknown ion channel to control sodium flux. Using both reporter constructs and translational fusion constructs for UNC-1 and green fluorescent protein (GFP), we have shown that UNC-1 is expressed primarily within the nervous system. The expression pattern of UNC-1 is similar to that of UNC-8, a sodium channel homologue. We examined the interaction of multiple alleles of unc-1 and unc-8 with each other and with other genes affecting anesthetic sensitivity. The data indicate that the protein products of these genes interact, and that an UNC-1/UNC-8 complex is a possible anesthetic target. We propose that membrane-associated protein complexes may represent a general target for volatile anesthetics.

Quantitative trait loci controlling halothane sensitivity in Caenorhabditis elegans

Genetic analysis is an essential tool for defining the molecular mechanisms whereby volatile anesthetics (VA) disrupt nervous system function. However, the degree of natural variation of the genetic determinants of VA sensitivity has not been determined nor have mutagenesis approaches been very successful at isolating significantly resistant mutant strains. Thus, a quantitative genetic approach was taken toward these goals. Recombinant-inbred strains derived from two evolutionarily distinct lineages of the nematode Caenorhabditis elegans were tested for sensitivity to clinically relevant concentrations (0.3-0.5 mM) of the VA halothane. The halothane sensitivities of coordinated movement and male mating behavior were highly variant among the recombinant-inbred strains with a range of EC50 values of 13- and 4-fold, respectively. Both traits were highly heritable (H2 = 0.82, 0.87, respectively). Several strains were found to be significantly resistant to halothane when compared with the wild-type strain N2. A major locus or loci mapping to the middle of chromosome V accounted for more than 40% of the phenotypic variance for both traits. Five weaker loci, four of which interact, explained most of the remaining variance. None of the halothane-sensitivity quantitative trait loci significantly affected behavior in the absence of halothane or halothane's potency for C. elegans immobilization, which requires 5-fold higher drug concentrations. Thus, the quantitative trait loci are unlikely to result from differences in halothane-independent (native) behavior or differences in halothane metabolism or permeability. Rather, these loci may code for targets and/or downstream effectors of halothane in the C. elegans nervous system or for modifiers of such gene products.

Propofol produces differences in behavior but not chloride channel function between selected lines of mice

We report differential central nervous system (CNS) sensitivity to propofol between Long Sleep (LS) and Short Sleep (SS) mice, selectively bred for their differential CNS sensitivity to ethanol. Intravenous propofol requirements for loss of righting reflex, or sleep time, were measured to define the extent of this sensitivity. LS mice slept approximately two times longer than SS mice at equal doses. Awakening plasma and brain levels of the SS line were, respectively, two and three times that of the LS line (P < 0.0001). This suggests that the LS and SS sleep time difference is CNS mediated, and that propofol and ethanol may share common genes that determine anesthetic sensitivities. The ethanol effect may be at least partially mediated by gamma-aminobutyric acid-A (GABAA) receptor function. Propofol had no differential effect on GABAA receptor function, as measured by chloride flux in LS and SS brain microsac preparations. Either the GABAA receptor does not mediate propofol sleep time, or qualitative differences cannot be demonstrated using 36Cl- uptake in brain membranes.

Genetic models in the study of anesthetic drug action

This chapter reviews the use of genetic models in the study of anesthetic drug action. Genetic model systems provide a novel approach to understanding mechanisms of anesthetic drug action. Many models have been derived using selection processes that emphasize differential drug sensitivity, producing animal lines that differ in their CNS drug response. Studies of vertebrate (rodent) and invertebrate (Drosophila, Caenorhabditis elegans) animal model systems are covered. The review discusses studies employing lines derived from spontaneous and induced mutagenic processes, selectively bred lines, and inbred lines possessing inherent differential drug sensitivities. The primary focus of included studies is the general anesthetic drugs that are commonly used in the clinical setting. These are drugs such as the inhalational agents (halothane, enflurane, isoflurane, nitrous oxide) and the intravenous induction agents (propofol and diazepam). Rodent lines with differential sensitivity to opiates are also discussed. Finally, an approach to identifying and isolating the genes that control anesthetic sensitivity is discussed in a section on mapping quantitative trait loci (QTL) in recombinant inbred lines.

Mutations affecting sensitivity to ethanol in the nematode, Caenorhabditis elegans

Mutations in nine genes have been identified in the nematode, Caenorhabditis elegans, which control sensitivity to ethanol. The interaction of these genes has been examined and used to determine a genetic pathway controlling sensitivity to ethanol. The nature of this pathway indicates that ethanol exerts its anesthetic actions at more than one site of action. These results also indicate that ethanol is similar in its effects to the volatile anesthetics, enflurane and isoflurane.

Development of neurochemical and behavioral sensitivity to ethanol in long-sleep and short-sleep mice

The postnatal development of certain neurochemical correlates of CNS ethanol sensitivity was examined in the long-sleep (LS) and short-sleep (SS) mice. The differences in sensitivity to the motor-incoordinating and hypothermic effects of ethanol emerged during the second and third weeks of life. Prior studies have shown the sleep time differences between LS and SS mice became significant at 8-10 days of age whereas the present results established that the differences in ethanol-induced hypothermia became prominent at 12-16 days of age. Previous results from our laboratory suggested that the greater CNS ethanol behavioral sensitivity (sleep time and hypothermia) of LS mice is related to the greater ethanol-induced depression of brain monoamine synthesis in the LS line. The timing of the developmental changes in neurochemical ethanol sensitivity in LS and SS mice was found to parallel that found in the development of behavioral ethanol sensitivity as follows. Ethanol-induced decreases in in vivo tyrosine hydroxylase activity in the cerebellum, hypothalamus, and brain stem did not differ between LS and SS mice at postnatal day 8, but became substantially greater in LS mice between postnatal days 8 and 12, coincident with the appearance of the greater sleep times of LS mice. Likewise, ethanol-induced decreases in in vivo tryptophan hydroxylase activity in the dorsal raphe and hypothalamus, which were similar in LS and SS mice at postnatal days 8 and 12, became significantly greater in LS mice by postnatal day 16, the age at which their increased sensitivity to ethanol-induced hypothermia appeared.(ABSTRACT TRUNCATED AT 250 WORDS)

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)

Effect of pentobarbital and gaseous anesthetics on rats selectively bred for ethanol sensitivity

Rats have been genetically selected to have a differential hypnotic response to an acute injection of ethanol. These high alcohol sensitive (HAS) and low alcohol sensitive (LAS) rats were used to investigate commonalities of the mechanism of action of several gaseous anesthetics, pentobarbital and ethanol. Similar studies have been carried out extensively with mouse lines also differentially sensitive to ethanol (short- and long-sleep mice). Like the mice, the rats are also differentially sensitive to the two gaseous anesthetics, enflurane and isoflurane. However, in contrast to results with these mice, we find that the HAS and LAS rats are differentially sensitive to halothane and pentobarbital in the same direction as their sensitivity to ethanol. In other studies, the rats also have been found to be differentially sensitive to phenobarbital as are SS and LS mice. These results show that, by the use of these anesthetics in combination with selectively bred rodent lines, many new opportunities for dissecting the molecular mechanisms of anesthetic agents present themselves.

Selective breeding for initial sensitivity to ethanol

Selective breeding for initial sensitivity to ethanol has been carried out by a number of investigators in order to investigate the mechanisms by which ethanol brings about a myriad of effects on the mammalian central nervous system. In addition the availability of these selectively bred animals provides clues to the causes of the genetic predisposition of humans to alcoholism. Eventually it is envisioned that the synteny between the mouse and human genomes will allow identification of specific genes responsible for acute effects of ethanol in both species as well as clues as to how alcoholism in humans can be better identified, prevented, and treated.

Regional catecholamine levels in brains of normal and ethanol-tolerant long-sleep and short-sleep mice

The objective of this study was to further investigate neurochemicals which might modulate congenital differences in sensitivity to the acute and chronic effects of ethanol. Catecholamine levels were measured in the cortex, hippocampus, midbrain and cerebellum of long-sleep (LS) and short-sleep (SS) mice. These measurements revealed that norepinephrine (NE) levels were equivalent in all these brain regions of both strains except for a significantly greater concentration in the midbrain of LS mice. The hippocampus, cortex and cerebellum of SS mice contained more epinephrine (E) than for LS mice. Likewise, the hippocampus and cerebellum of SS mice had higher levels of dopamine (DA), while in the midbrain this amine was more abundant in LS mice. Following 7-10 days of ethanol ingestion, both LS and SS mice exhibited a significant reduction in the duration of ethanol-induced loss of righting reflex. This tolerant state was associated with a depletion of NE in the hippocampus and cortex of both strains. NE was also significantly reduced in the midbrain of LS and the cerebellum of SS mice. On the other hand, E levels were unaltered except for a reduction in the hippocampus of tolerant SS mice. DA levels declined in all brain regions of tolerant mice except for the cerebellum of LS mice and the midbrain of SS mice where a significant increase and no change in DA concentration was detected, respectively. Interestingly, the brain levels of 3-methoxy-4-hydroxyphenylglycol were uniformly increased during the tolerant state for both strains.(ABSTRACT TRUNCATED AT 250 WORDS)

Investigations of the role of protein kinase C in the acute sedative effects of ethanol

The activity of protein kinase C (PKC) in whole brain and brain areas of mice selectively bred for resistance (short sleep, SS) or sensitivity (long sleep, LS) to the acute ataxic effect of ethanol has been investigated. The cytosolic and membrane fractions of whole brain PKC activities are significantly less in LS mice than in SS mice. There are significant differences in PKC activity between brain areas in both the SS and LS lines. Ethanol given in ataxic doses results in significantly increased amounts in PKC activity in whole brain cytosolic fractions and in some brain areas but equally in both SS and LS mice. Ethanol added in vitro reduced enzyme activity slightly in SS brain membranes, suggesting that the mechanism of the increase in PKC activity seen after in vivo administration is indirect. These results indicate that PKC is not involved in the mechanism whereby LS and SS mice differ in alcohol sensitivity. Direct intracerebroventricular (ICV) injection of phorbol myristate acetate (PMA), an activator of PKC, resulted in increased sleep times in both SS and LS mice. ICV injection of PMA also caused a more marked decrease in body temperature in LS than in SS mice. The half-life of PMA in brain was determined to be 9.6 hr and no metabolites could be detected. At limiting calcium concentrations, PMA added in vitro activated PKC equally well in both lines. However, PMA given ICV did not alter the level of PKC as determined in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)

Selected mouse lines, alcohol and behavior

The technique of selective breeding has been employed to develop a number of mouse lines differing in genetic sensitivity to specific effects of ethanol. Genetic animal models for sensitivity to the hypnotic, thermoregulatory, excitatory, and dependence-producing effects of alcohol have been developed. These genetic animal models have been utilized in numerous studies to assess the bases for those genetic differences, and to determine the specific neurochemical and neurophysiological bases for ethanol's actions. Work with these lines has challenged some long-held beliefs about ethanol's mechanisms of action. For example, lines genetically sensitive to one effect of ethanol are not necessarily sensitive to others, which demonstrates that no single set of genes modulates all ethanol effects. LS mice, selected for sensitivity to ethanol anesthesia, are not similarly sensitive to all anesthetic drugs, which demonstrates that all such drugs cannot have a common mechanism of action. On the other hand, WSP mice, genetically susceptible to the development of severe ethanol withdrawal, show a similar predisposition to diazepam and phenobarbital withdrawal, which suggests that there may be a common set of genes underlying drug dependencies. Studies with these models have also revealed important new directions for future mechanism-oriented research. Several studies implicate brain gamma-aminobutyric acid and dopamine systems as potentially important mediators of susceptibility to alcohol intoxication. The stability of the genetic animal models across laboratories and generations will continue to increase their power as analytic tools.

Effects of ethanol and calcium on lipid order of membranes from mice selected for genetic differences in ethanol intoxication

Fluorescent probes were used to compare the physical properties of membranes from mice selected for sensitivity (LS) and insensitivity (SS) to the hypnotic action of ethanol. Brain synaptic plasma membranes (SPM) from LS mice were more sensitive to the disordering action of ethanol than those from LS mice when probes were located near the membrane surface. However, the membrane core of membranes from the two lines was equally sensitive to ethanol. The genetic differences in ethanol sensitivity of the membrane surface were eliminated when fluorescence measurements were carried out in the presence of 2-3 mM CaCl2. Consistent with behavioral data, differential genetic sensitivity to the disordering action was not obtained with longer chain alcohols. The genetic difference in ethanol sensitivity was not detected with erythrocyte membranes or lipids extracted from SPM. These results indicate that there is a structural difference in the surface of brain membranes of LS and SS mice than may influence their sensitivity to ethanol.

Effect of chronic ethanol treatment and selective breeding for hypnotic sensitivity to ethanol on intracellular ionized calcium concentrations in synaptosomes

The effect of chronic ethanol treatment and of selective breeding for hypnotic sensitivity to ethanol on intracellular ionized calcium concentrations (Cai) were examined in mouse whole brain synaptosomes. Following treatment with a liquid diet for 7 days, resting Cai and KCl-stimulated increases in Cai were measured in synaptosomes isolated from chronic ethanol-treated and pair-fed animals. Ethanol (350-700 mM) increased resting Cai and reduced KCl-stimulated increases in Cai in synaptosomes isolated from pair-fed animals. Ethanol-induced changes in Cai were reduced in synaptosomes isolated from chronic ethanol-treated animals. The effect of ethanol on synaptosomal Cai in long-sleep (LS) and short-sleep (SS) mice, selectively bred for differential sensitivity to the hypnotic actions of acute ethanol, was also investigated. In the absence of ethanol, resting values of Cai and KCl-stimulated increases in Cai did not differ between the two lines of mice. Ethanol (200-600 mM) increased resting Cai and reduced depolarization-stimulated increases in Cai in both long-sleep and short-sleep mice to the same degree. Similarly, KCl-stimulated increases in Ca uptake did not differ in synaptosomes isolated from whole brains and cortices of LS and SS mice, in the absence of presence of ethanol. These findings demonstrate that tolerance develops to the effect of ethanol on neuronal Cai following chronic treatment. However, sensitivity to the hypnotic action of ethanol is not related to changes in neuronal Cai in LS and SS mice.

Neurotensin selectively alters ethanol-induced anesthesia in LS/Ibg and SS/Ibg lines of mice

Neurotensin (NT) differentially altered ethanol-induced anesthesia as measured by duration of loss of righting response or by blood ethanol levels producing loss of righting response in mice (LS and SS) which were selectively bred for differences in response to ethanol. At doses of 5-500 ng i.c.v., NT increased ethanol sensitivity in SS mice, but not in LS mice, as measured by blood ethanol concentrations at loss of righting response. At higher doses, 0.5-10 micrograms i.c.v., NT enhanced the sensitivity of both SS and LS mice to ethanol-induced anesthesia. The hypothermic effect of ethanol determined at loss of righting response was not altered in either LS or SS mice at low doses of NT, but at higher doses NT enhanced ethanol-induced hypothermia in both lines of mice. The altered anesthetic sensitivity was specific for ethanol in that NT did not alter pentobarbital-induced sleep time in either LS or SS mice and halothane anesthesia was altered slightly only in LS mice. NT analogues, N-acetyl-NT8-13, and [D-Trp11]-NT but not NT1-8 enhanced the anesthetic action of ethanol in SS mice. Bombesin, cholecystokinin sulfate, substance P, [D-Trp8, D-Cys14]-somatostatin and corticotropin releasing hormone (CRF) were not effective in enhancing ethanol-induced anesthesia in LS or SS mice. CRF appeared to decrease ethanol sensitivity in LS but not in SS mice. Beta-Endorphin (beta-END) markedly increased the ethanol sensitivity of SS and to a lesser extent of LS mice at relatively high doses, e.g. 0.5-1.0 micrograms i.c.v. The results of the present study indicate that differences in brain sensitivity of LS and SS mice to ethanol may be mediated by genetic differences in NT systems. Likewise, NT, and probably beta-endorphin, may interact with other neurochemical processes that are involved in the mechanism of ethanol-induced anesthesia and that differ genetically in LS and SS mice.

Effects of 6-hydroxydopamine on brain catecholamines and on acute actions of ethanol in LS/Ibg and SS/Ibg mice

LS/Ibg (LS) and SS/Ibg (SS) mice differ in ethanol-induced duration of loss of righting response or sleep time, hypothermia, hyperglycemia, and blood ethanol concentrations at regaining righting response. These differences in response to ethanol are a result of differences in central nervous system sensitivity and are mediated by polygenic systems. Studies have indicated that catecholaminergic systems may be involved in the differential effects of ethanol in LS and SS lines of mice (Masserano JM, Weiner N: Investigations into the neurochemical mechanisms mediating differences in ethanol sensitivity in two lines of mice. J Pharmacol Exp Ther 221:404-408, 1982). In this study the neurotoxin, 6-hydroxydopamine (6-OHDA), intracerebroventricular, was used to test this hypothesis. Administration of 6-OHDA markedly altered thermoregulation in LS mice but produced little effect in SS mice, and ethanol-induced hyperglycemia was attenuated in both LS and SS mice by 6-OHDA. Ethanol-induced sleep time was increased in SS mice pretreated with 100 micrograms of 6-OHDA, intracerebroventricular, whereas this response in LS mice was unaffected by 6-OHDA administration. Changes in sleep time were not related to changes in blood ethanol concentrations, indicating that 6-OHDA alters ethanol-induced sleep time by mechanisms other than brain sensitivity. Levels of norepinephrine and dopamine were determined in three brain regions, and the altered capacities for thermoregulation and glucoregulation were associated with changes in hypothalamic catecholamine levels.

Calcium influence on neuronal sensitivity to ethanol in selectively bred mouse lines

Sensitivity to ethanol, as measured by blood ethanol concentration at loss of righting reflex, was increased significantly in SS but not LS mice following intracerebroventricular (ICV) administration of calcium chloride or A23187, a calcium ionophore. Magnesium chloride or lanthanum chloride, ICV, did not alter sensitivity to ethanol in either SS or LS mice, further indicating a specificity for calcium cation. Calcium was without effect on sensitivity to halothane narcosis in LS or SS mice. Endogenous brain calcium content was similar in these mouse lines, and ethanol administration either in vivo or in vitro did not alter brain calcium concentration. These results indicate that differences in brain sensitivity to ethanol are mediated, in part, by genetic differences in calcium-related processes and support the hypothesis that ethanol-induced narcosis may be due to alterations in calcium metabolism in the CNS.

Alpha-methyl-para-tyrosine effects in mice selectively bred for differences in sensitivity to ethanol

The responses of catecholamine systems in long sleep (LS) and short sleep (SS) mice to alpha-methyl-p-tyrosine (AMPT) have been examined. Marked differences were found between LS and SS mice in the dose necessary for maximal brain catecholamine depletion and in the time-course of the catecholamine depletion. Brain catecholamines in the LS mice were depleted by lower doses of AMPT and the levels remained depressed for longer periods of time in this line of mice. These differences may be explained only partially by an increased susceptibility of the LS mice to the hypothermia and toxic effects caused by AMPT administration, as they persist with non-toxic AMPT dosage regimens and under conditions where the degree of hypothermia is comparable in both lines of mice. In addition, there were no differences between the Ki values for the effect of AMPT on the tyrosine hydroxylase from striata of these mouse lines. The primary cause of the heightened response to AMPT in LS mice would appear to be pharmacokinetic in nature, as brain and plasma peak levels of AMPT in LS mice were greater and the levels remained higher for a longer time. The depletion of brain tyrosine by AMPT combined with the lower affinity of the LS striatal tyrosine hydroxylase for the substrate tyrosine may also contribute to the heightened response in LS mice.

Differential CNS sensitivity to PIA and theophylline in long-sleep and short-sleep mice

Long sleep (LS) and short sleep (SS) mice have a differential sensitivity to the behavioral actions of an adenosine agonist, R-phenylisopropyl-adenosine (PIA) that parallels their differential sensitivity to the soporific effects of ethanol. In addition to being more sensitive to the sedative effects of PIA, LS mice also show a greater excitatory response to an adenosine antagonist, theophylline (1,3-dimethylxanthine). The brain concentrations of both PIA and theophylline following drug administration do not differ in LS and SS mice, suggesting that the central nervous system of the LS mouse is more sensitive to both adenosine receptor agonists and antagonists. However, LS and SS mice made tolerant to ethanol did not show cross-tolerance to PIA. These results suggest that genetic selection for ethanol sensitivity has resulted in a parallel CNS sensitivity to purinergic drugs, but that acute alterations in sensitivity due to the development of ethanol tolerance do not involve changes in purinergic systems.

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

This paper reviews the findings and conclusions of the literature pertinent to the Long-Sleep and Short-Sleep selectively-bred lines of mice and challenges the widely-held notion that the selective breeding program was successful in separating alleles for specific sensitivities to just alcohol. Rather, it is argued that these lines of mice were selected for differing activity of a more general process. Recent evidence, as well as reevaluated previous evidence, indicates that Long-Sleep mice are more sensitive to the soporific effects of three major classes of CNS depressants (alcohols, barbiturates, and benzodiazepines), as well as many other anesthesia-inducing compounds (adenosine, chloral hydrate, trichloroethanol, paraldehyde, nitrous oxide, enflurane, and isoflurane). Further, much evidence also supports the conclusion that most of these hypnotic-depressants and anesthetics could exert their soporific influence by a potentiation of GABA activity. The other characteristic of interest in this regard is susceptibility to convulsions. Short-Sleep mice have significantly lower thresholds to both flurothyl-induced and bicuculline-induced convulsions, as well as being more likely to suffer from paroxysms during ethanol withdrawal.

A genetic analysis of ethanol, pentobarbital, and methyprylon sleep-time response

The sleep-time responses to ethanol, pentobarbital, and methyprylon were assessed in various generations derived from crossing the long-sleep (LS) and short-sleep (SS) mouse lines in order to assess whether common or different genes regulate response to these agents. The LS and SS mice were selectively bred for differences in duration of ethanol-induced sleep time. Ethanol and pentobarbital responses segregate in a different fashion into F1 and F2 generations derived from the LS and SS lines, indicating different genic control and probably different mechanisms of action for these two agents. Ethanol and methyprylon response segregated similarly but fewer genes seem to influence methyprylon response. These results support the notion that water-soluble depressants have common mechanisms of action.

Behavioral sensitivity to purinergic drugs parallels ethanol sensitivity in selectively bred mice

Behavioral responses to an adenosine receptor agonist and antagonist were examined in mice genetically selected for differential sensitivity to the soporific effects of ethanol. Both ethanol and the adenosine receptor agonist L-phenylisopropyladenosine had greater sedative and hypothermic effects in ethanol-sensitive "long-sleep" mice than in ethanol-insensitive "short-sleep" mice. Long-sleep mice were also more sensitive to the excitatory behavioral effects of theophylline, an adenosine receptor antagonist. These data suggest that adenosine may be an endogenous mediator of responses to ethanol.

Ethanol and temperature effects on five membrane bound enzymes

The effects of ethanol on the activities of five membrane bound enzymes were determined using a crude membrane preparation obtained from cortex of long-sleep (LS) and short-sleep (SS) mice. These two mouse lines were selectively bred for differences in duration of ethanol-induced sleep time. The enzymes studied were two forms of NaK-ATPase, Mg-ATPase, 5'nucleotidase, and acetylcholinesterase. Arrhenius plots of the ethanol-temperature-enzyme activity studies indicate specificity in ethanol's actions. NaK-ATPase activity consists of two enzymes which were distinguished by sensitivity to ouabain. The Arrhenius plot of the high ouabain sensitivity enzyme (low Ki) exhibited a transition temperature which was reduced twice as much by ethanol in LS membranes as in SS membranes. Ethanol did not affect the transition temperature of the high Ki NaK-ATPase but the control (no ethanol) transition temperature was 2.7 degrees higher in SS membranes. Arrhenius plots of Mg-ATPase activity did not exhibit a transition temperature and ethanol did not alter enzyme activity. Ethanol did not alter the transition temperatures of 5'nucleotidase or acetylcholinesterase but the control transition temperature for acetylcholinesterase was 2.3 degrees higher in SS membranes. These results indicate specificity in ethanol's actions on membranes and that inhibition of the lipid-enzyme interactions for the low Ki NaK-ATPase is correlated with the difference in sensitivity to ethanol seen between the LS and SS mice.

Differential response to ethanol, pentobarbital and morphine in mice selectively bred for ethanol sensitivity

Males of two lines of mice, long sleep (LS) and short sleep (SS), that had been selectively bred for their differential sensitivity to ethanol-induced sleep, were examined for their responses to the hypothermic and analgesic effects of ethanol, pentobarbital and morphine, and to the cataleptic effect of morphine. SS mice were found to be less sensitive than the LS animals to ethanol but not pentobarbital-induced analgesia and hypothermia. The SS animals were also less sensitive to morphine-induced hypothermia, but were, by contrast, more sensitive than their LS counterparts to morphine-induced analgesia, while no line differences existed with respect to catalepsy. The rate of morphine disappearance from the blood was somewhat higher in the LS animals but this difference is probably too small to account for the observed differential responses to morphine.

Neonatal cerebellectomy alters ethanol-induced sleep time of short sleep but not long sleep mice

The effects of neonatal cerebellectomy on ethanol-induced sleep times in long sleep (LS) and short sleep (SS) mice were investigated. Cerebellectomy did not alter the ethanol sensitivity of LS animals for loss of righting reflex. In contrast, SS mice became more sensitive to alcohol after cerebellectomy. Even so, large differences were still observed between the alcohol-induced sleep times of cerebellectomized LS and SS mice. The data indicate that, while the cerebellum must have a prominant influence on alcohol sleep time in SS animals, this brain structure is not solely responsible for the observed differences in righting reflex sensitivity to ethanol in these two mouse lines. We postulate the existence of noncerebellar central neurons with differential sensitivities to the depressant effects of ethanol in LS and SS mice.

Differential effects of long-chain alcohols in long- and short-sleep mice

Observations that the long-sleep (LS) and short-sleep (SS( mouse lines differ in their depressant response to barbiturates, and that the difference between lines becomes greater as lipid solubility increases, prompted this investigation of the effects of alcohols that differ in lipid solubility. Results indicate that LS and SS mice differ significantly in their sleep time responses to propanol, butanol, and 3-methyl butanol, as well as ethanol: their hypothermic responses showed a similar pattern, but only the response to ethanol differed significantly between lines. For both sleep time and hypothermia, the difference between lines decreased with increasing lipid solubility. In all cases, the LS mice were more sensitive than the SS to the depressant effects of the alcohol. Similar ratios of SS:LS waking brain ethanol and butanol levels indicated that CNS sensitivity to long-chain alcohols is similar to that for ethanol. A pharmacokinetic study revealed higher ethanol levels for LS than for SS mice at all time points in blood, fat, and brain body compartments. Blood ethanol elimination curves showed that the SS mice eliminate ethanol at a faster rate than do the LS.

Alcohol and morphine induced hypothermia in mice selected for sensitivity in ethanol

We have used changes in body temperature as an index of responsiveness to alcohol and morphine in mice selectively bred for differential sensitivity to ethanol. In agreement with other laboratories, we found that mice which show longer duration of loss of righting reflex following hypnotic doses of ethanol (long sleep; LS) also showed greater loss in body temperature following subhypnotic doses of ethanol than did the less sensitive short sleep (SS) mice. This effect was dose dependent in both lines. In contrast, SS mice were more sensitive than LS mice to the hypothermic effects of morphine, although the difference was only evident 30 min after morphine administration. Naloxone attenuated morphine induced hypothermia in mice of both genotypes, but attenuated alcohol induced hypothermia only in SS mice. Thus, SS mice may be more sensitive to an opiate agonist and an antagonist, at least as indexed by changes in body temperature, and may prove to be a useful population for evaluating both alcohol-opiate interactions and genetic differences in opiate responsiveness.

Ethanol-induced changes in tyrosine hydroxylase activity in brains of mice selectively bred for differences in sensitivity to ethanol

The effects of ethanol on tyrosine hydroxylase (TH) activity in five brain areas were analyzed in two lines of mice selectively bred for their differences in sensitivity to ethanol. Following a 4.1 g/kg dose of ethanol, intraperitoneally, short sleep (SS) mice lose their righting reflex for a duration of 20 minutes and long sleep (LS) mice fail to regain their righting reflex until 120 minutes. A significant increase in TH activity occurred in the striatum, locus coeruleus and frontal cortex in both lines of mice approximately 25 minutes following ethanol administration. A decrease in TH activity occurred in the substantia nigra of SS mice at 5 minutes following ethanol administration. However, there was no significant differences in TH activity in any of these four brain regions between LS and SS mice at any time following ethanol administration. In contrast, hypothalamic TH activity was significantly increased at 25 minutes in the SS mice and at 125 minutes in the LS mice following the administration of ethanol, times which coincided with the regaining of the righting reflex. These data suggest that activation of TH in the hypothalamus of LS and SS mice in response to ethanol is associated with arousal from ethanol induced narcosis.

Ethanol-induced depressions in cerebellar and hippocampal neurons of mice selectively bred for differences in ethanol sensitivity: an electrophysiological study

The recently discovered profound differential sensitivity of cerebellar Purkinje (P) cells in long-sleep (LS) verus short-sleep (SS) mice to the depressant effects of locally applied ethanol was extended in this study. First, the sensitivity of Purkinje neurons from HS mice (an outbred stock of mice from which the LS and SS lines were derived), was found to be almost exactly intermediate between the values for the long-sleep and short-sleep animals. Second, no differential sensitivity in long-sleep versus short-sleep hippocampal pyramidal neurons was observed. This was true using both spontaneous and evoked activity. Third, no differential sensitivity of P cells was seen in long- versus short-sleep mice with local application of halothane. Taken together with previous reports, these data strongly suggest that whatever genetically determined central nervous alterations result in the differential soporific effects of ethanol in the two (LS and SS) mouse lines, such alterations are brain region- and depressant drug-specific rather than generalized.