Ethanol-induced hypothermia in mice: Influence of genotype on development of tolerance

Male mice of BALB/c, C57BL, DBA/2 strains and two lines of mice selectively bred for sensitivity to ethanol, Long-Sleep (LS) and Short-Sleep (SS), were tested for ethanol-induced hypothermia following varied doses of ethanol. The results show that the genotype as well as the dose of the drug determines the intensity and the duration of the effect. Repeated injection of ethanol results in the decrease of hypothermia in BALB/c mice and in C57BL, but not in DBA/2 mice, indicating that tolerance as measured in this study may not develop in certain genotypes of mice. The blood ethanol elimination data after repeated injections of ethanol indicate that the metabolic factors do not explain the changes observed in the hypothermic effects of repeated injections of ethanol.     

Neurophysiological mechanisms in the genetics of ethanol sensitivity

Abstract

Cerebellar Purkinje neurons of long‐sleep (LS) mice express a higher sensitivity than do those of short‐sleep (SS) mice to the depressant effects of ethanol in situ, in vitro, and in intraocular cerebellar brain grafts. The ethanol sensitivity of Purkinje neurons is intrinsic to the cerebellum, may be associated with only certain brain areas, and shows a high genetic correlation with the behavioral sensitivity of mice to ethanol‐induced ataxia. Tolerance develops to the depressant effects of ethanol on cerebellar neurons in both lines of mice. However, ethanol‐tolerant LS mice are more sensitive to the electrophysiological effects of ethanol on Purkinje neurons than are ethanol‐tolerant SS mice. In addition, the behavioral sensitivity to this drug probably also involves noncerebellar neurons since neonatally cerebellectomized LS and SS mice retain a different sensitivity to the ataxic effects of ethanol.     

Biochemical genetic variants in mice selectively bred for sensitivity or resistance to ethanol-induced sedation

The distribution of biochemical genetic variants was examined among eight inbred strains of mice, which served as contributors to a heterogeneous stock of mice (HS), and in short-sleep (SS) and long-sleep (LS) mice, selectively bred from the HS stock for differential ethanol sensitivity. Fifteen loci for enzymes of alcohol and aldehyde metabolism, as well as 12 other biochemical loci, were investigated. Thirteen of these loci exhibited allelic variation between strains, of which six were separately fixed in the SS and LS mice. Comparisons of genetic similarity coefficients, based upon the distributions of allelic variants for the loci examined, with behavioural sensitivities (sleep-time) to an acute dose of ethanol for the inbred and selected strains of mice, indicated no correlations between these data. This suggests that this collective group of loci are not useful indicators of the genes selectively bred in the SS and LS strains, which are responsible for the differential sensitivities to acute doses of ethanol.     

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.     

Differential sensitivity to neurotensin-induced hypothermia, but not analgesia, in Fischer and Lewis rats

Neurotensin (NT) produces behavioral and physiological effects, including analgesia and hypotheria, when administered into the CNS. Fischer and Lewis rats exhibit differential behavioral responses to central NT receptor activation. To further characterize these differences, we assessed central NT-induced analgesia and hypothermia in independent groups of rats from each strain. Fischer and Lewis rats showed a similar dose-orderly analgesic response in a hot-plate test. Such an isosensitivity was not observed for NT-induced hypothermia. Although NT produced a dose-orderly decrease in mean rectal temperature in both strains, the magnitude of the hypothermic response was significantly smaller in Fischer than in Lewis rats. These findings provide further evidence of genetic differences in central neurotensinergeric neurotransmission in these two strains.     

Mapping quantitative trait loci mediating sensitivity to etomidate

Long- and Short-Sleep (LS and SS) mice were selectively bred for differences in ethanol-induced loss of the righting reflex (LORR) and have been found to differ in LORR induced by various anesthetic agents. We used a two-stage mapping strategy to identify quantitative trait loci (QTLs) affecting duration of LORR caused by the general anesthetic etomidate and brain levels of etomidate (BEL) following regain of the righting reflex. Analysis of recombinant-inbred strains derived from a cross between LS and SS mice (LSXSS) yielded a heritability estimate of 0.23 for etomidate-induced LORR and identified one marker that showed suggestive linkage for a QTL, on mouse Chromosome (chr) 12. Mapping in an F(2) population derived from a cross between inbred LS and SS (ILS and ISS) revealed a significant QTL for etomidate-induced LORR on Chr 12, and two significant QTLs mediating BEL on Chrs 6 and 12. Several QTLs showing suggestive linkage for etomidate-induced LORR and BEL were also identified in the F(2) population. Brain levels of etomidate in the RI and F(2) mice suggested that differences in LORR were due to differential central nervous system sensitivity, rather than differential etomidate metabolism. Interestingly, the region on Chr 7 has also been identified as a region influencing ethanol-induced LORR, suggesting the possibility of a common genetic mechanism mediating etomidate and ethanol sensitivity. These QTL regions need to be further narrowed before the testing of candidate genes is feasible.     

Adrenocortical function in mice selectively bred for different sensitivity to ethanol

The adrenocortical response to ethanol, histamine and electric shock was studied in the Short-Sleep (SS) and Long-Sleep (LS) mice. The plasma corticosterone levels measured at 60 min following ethanol injection were consistently higher in LS mice (males and females) than in SS mice. The corticosterone levels determined 60 min after histamine injection (50 mg/kg) or electric foot shock were not statistically different in these two lines of mice. The initial rise of the corticosteroid after ethanol injection was identical in SS and LS mice, whereas the costicosteroid response to mild stress of saline injection was different: SS mice showed higher levels of corticosterone than LS mice at 20 and 30 min after the injection. Corticosterone increment attributable to alcohol stress clearly seemed greater in LS than in SS mice, even though the adrenals of the SS mice were 20–30% heavier than those of LS. The possible significance of these endocrine differences with respect to sensitivity to ethanol and behavioral arousal level was discussed.     

Balance of glutamate and dopamine in the nucleus accumbens modulates self-stimulation behavior after injection of cholecystokinin and neurotensin in the rat brain.

Subpopulations of dopamine (DA) neurons in the ventral mesencephalon have been reported to contain cholecystokinin (CCK) and neurotensin (NT), giving rise to DA, DA/NT, NT/CCK and DA/CCK/NT projections. More precisely, colocalized DA/CCK neurons project mainly to the caudal part of the medial nucleus accumbens, whereas its rostral portion receives CCK and DA nerve terminal networks that are structurally independent. We investigated the respective effects of both CCK and NT on the intracranial self-stimulation behavior (ICSS) from the posterolateral hypothalamus after their direct administration into the lateral ventricle (ICV), into both portions of the nucleus accumbens, into the ventral tegmental area (VTA), and into the subiculum of the hippocampal formation (SUB). The ICV injection of 150 pmol CCK8 induced a decrease in the rate of ICSS. By contrast, the direct administration of 150 pmol CCK8 into the mediocaudal part of the nucleus accumbens induced an enhanced rate of ICSS while a similar injection into its rostral portion gave rise to a slight transient decrease of ICSS. When injected into the SUB, both CCK8 and glutamate produced decreased rates of ICSS at femtomolar doses one thousand-fold under the picomolar concentrations used for ICV injections. Neurotensin induced similar behavioral profiles to that observed after the ICV injection of CCK8 or into both portions of the nucleus accumbens. Neurotensin and CCK8 displayed opposite effects on ICSS when administered into the SUB or into the VTA, suggesting they may regulate ICSS most probably through different synaptic mechanisms and through different anatomical pathways.     

Gamma aminobutyric acid in different strains of mice effect of ethanol

Four strains of mice (C57BL/6J, DBA/2J, LS and SS), which differ in their voluntary intake and/or neural sensitivity to ethanol, were examined for the contents of γ-aminobutyric acid (GABA) in various brain regions. The effect of an acute dose of ethanol (4 g/kg) on the contents of this amino acid neurotransmitter in these mice were studied. The objective is to determine if the differences in sensitivity to ethanol may be reflected in differences in brain GABA contents in these animals.Results indicate that a previously documented ethanol-induced elevation of GABA in the whole mouse brain is a phenomenon observed in a variety of brain regions. No correlation was observed between GABA contents in the brain and neural sensitivity to ethanol.     

Adrenal glucocorticoid function in rats with various ethanol-induced sleeping time following ethanol administration

The effect of single and chronic ethanol (Eth) administration (25 % solution, 3.5 g/kg) on functional activity of the hypophyseal-adrenal system in rats with different sensitivity to the hypnotic action of ethanol (short-sleep - SS; non-sleep--NS, long-sleep--LS, intermediate group--IG), was studied. It has been shown that, after a single Eth administration, the concentration of corticosterone (K) in LS rat plasma was 1.5-fold higher than that in the NS animals although it did not differ from the K level in SS and Ig those. After repeated ethanol load, the corticosterone contents in the NS rat blood plasma was 3.5-fold and 4.9-fold lower compared to the control and LS groups, respectively. The data obtained indicate that the SS and LS animals had initially different basal blood plasma glucocorticoid level. The SS animals showed a decreased blood plasma K, whereas the LS ones--an increased one. The features of the glucocorticoid status are suggested to be a factor determining the sensitivity of rats to the ethanol hypnotic effect.     

Changes in CNS response to neurotensin accompany the postpartum period in mice

Neurotensin (NT) is a highly conserved neuropeptide in mammals. Recent studies suggest that altered NT neurotransmission in postpartum females could promote the emergence of some maternal behaviors, including offspring protection. Here we evaluated how virgin and postpartum brains from mice selected for high maternal defense differ in response to NT. Virgin and postpartum mice were injected with either vehicle or 0.1 μg NT icv and brains were evaluated for c-Fos immunoreactivity, an indirect marker of neuronal activity. Using ANOVA analysis, common significant responses to NT were found in both female groups in four brain regions, including supraoptic nucleus, ventromedial nucleus, bed nucleus of stria terminalis dorsal, and a subregion of lateral septum (LS). For postpartum mice, only one additional region showed a significant response to NT relative to vehicle, whereas for virgin mice seven unique brain regions showed a significant c-Fos response: nucleus accumbens shell, paraventricular nucleus, central amygdala, and substantia nigra. Using a principal components analysis of c-Fos, we identified regions within each group with highly correlated activity. As expected, virgin and postpartum mice (vehicle conditions) showed different activity hubs and in the postpartum group the hubs matched regions linked to maternal care. The response to injected NT was different in the maternal and virgin groups with maternal mice showing a stronger coordinated activity in periaqueductal gray whereas virgin mice showed a stronger septal and amygdala linking of activity. Together, these results indicate neuronal responses of virgin and postpartum mice to NT and highlight pathways by which NT can alter maternal responses.     

Genetically determined differences in ethanol sensitivity influenced by body temperature during intoxication

The present study investigated the importance of body temperature during intoxication in mediating differences between five inbred strains of mice (C57BL/6J; BALB/cJ; DBA/2J; A/HeJ; 129/J) in their acute sensitivity to the hypnotic effects of ethanol. Mice exposed to 22 degrees C after ethanol injection became hypothermic and exhibited statistically significant differences between strains in rectal temperatures at the return of the righting reflex (RORR), duration of loss of the righting reflex (LORR), and blood and brain ethanol concentrations at RORR. Exposure to 34 degrees C after injection offset ethanol-hypothermia and markedly reduced strain-related differences in rectal temperatures and blood and brain ethanol concentrations at RORR. Brain ethanol concentrations at RORR were significantly lower in C57, BALB, DBA and A/He mice exposed to 34 degrees C compared to mice exposed to 22 degrees C during intoxication suggesting that offsetting hypothermia increased ethanol sensitivity in these strains. Taken with previous in vitro studies, these results suggest that genetically determined differences in acute sensitivity to the behavioral effects of ethanol reflect differences in body temperature during intoxication as well as differences in sensitivity to the initial actions of ethanol at the cellular level.     

Interaction of neurotensin with prostaglandin E2 and prostaglandin synthesis inhibitors: effects on colonic temperature in mice

Neurotensin (NT) administered intracisternally (i.c.) to adult mice produced a marked hypothermia while prostaglandin E₂, administered by the same route, produced hyperthermia. When administered concurrently the effects of the two substances were neutralized. The prostaglandin synthesis inhibitors, indomethacin and acetylsalicylic acid, were injected subcutaneously 30 min prior to i.c. administered NT and/or thyrotropin-releasing hormone (TRH). Both inhibitors failed to potentiate the hypothermia induced by NT or alter its antagonism by TRH in mice kept at 26°C. When mice were kept at 6°C, pretreatment with indomethacin, but not acetylsalicylic acid, potentiated NT-induced hypothermia and prevented its antagonism by TRH. Because indomethacin inhibits synthesis of prostaglandins within the central nervous system (CNS) as well as in peripheral organs while acetylsalicylic acid acts only in the periphery, it appears that NT-induced hypothermia in a cold environment is enhanced by a reduction of prostaglandins in the CNS.     

A comparison of the effects of alcohol on mice selectively bred for differences in ethanol sleep-time

The activities of liver alcohol dehydrogenase and aldehyde dehydrogenase were virtually identical in two lines of mice selectively bred for differences in “sleep-time” to ethanol. Similarly, the rates of blood ethanol disappearance were identical for these mouse lines. The ED50 values for loss of righting reflex with ethanol were approximately two-fold greater in the short-sleep than in the long-sleep mice. These results suggest that the two lines of mice differ in their central nervous system sensitivity to ethanol.     

Ethanol‐ and cocaine‐induced locomotion are genetically related to increases in accumbal dopamine

Neuroanatomical research suggests that interactions between dopamine and glutamate within the mesolimbic dopamine system are involved in both drug‐induced locomotor stimulation and addiction. Therefore, genetically determined differences in the locomotor responses to ethanol and cocaine may be related to differences in the effects of these drugs on this system. To test this, we measured drug‐induced changes in dopamine and glutamate within the nucleus accumbens (NAcc), a major target of mesolimbic dopamine neurons, using in vivo microdialysis in selectively bred FAST and SLOW mouse lines, which were bred for extreme sensitivity (FAST) and insensitivity (SLOW) to the locomotor stimulant effects of ethanol. These mice also show a genetically correlated difference in stimulant response to cocaine (FAST > SLOW). Single injections of ethanol (2 g/kg) or cocaine (40 mg/kg) resulted in larger increases in dopamine within the NAcc in FAST compared with SLOW mice. There was no effect of either drug on NAcc glutamate levels. These experiments indicate that response of the mesolimbic dopamine system is genetically correlated with sensitivity to ethanol‐ and cocaine‐induced locomotion. Because increased sensitivity to the stimulating effects of ethanol appears to be associated with greater risk for alcohol abuse, genetically determined differences in the mesolimbic dopamine response to ethanol may represent a critical underlying mechanism for increased genetic risk for alcoholism.     

Differences in the urocortin 1 system between long-sleep and short-sleep mice

There is evidence that the peptide urocortin 1 (Ucn1) may be involved in mediating some of the effects of ethanol. The purpose of the present study was to characterize Ucn1 immunoreactivity in mice selectively bred for either high or low sensitivity to ethanol-induced sedation, with additional differences in their response to ethanol-induced hypothermia. The brains of naïve male mice of the inbred long sleep/short sleep (ILS/ISS) selected lines were analyzed by immunohistochemistry. Significant differences were found between lines in the number of Ucn1-containing cells in the non-preganglionic Edinger–Westphal nucleus (npEW, the main source of Ucn1 in the brain); with the ISS mice having more cells. However, significant differences in the optical density of Ucn1 immunoreactivity in individual npEW cells and differences in cell area were also found between lines, with ILS mice having a greater density of Ucn1 per cell and having larger cells in the npEW. Importantly, the ILS mice also had a significantly greater number of Ucn1-positive terminal fibers than ISS mice in the lateral septum and the dorsal raphe nucleus, projection areas of Ucn1-containing neurons. These results suggest that the greater sensitivity of ILS than ISS mice to the hypothermic effects of ethanol could be mediated by stronger innervation of the dorsal raphe by Ucn1-containing fibers. In addition, these results lend further support to previous findings implicating Ucn1-containing projections from npEW to the dorsal raphe in ethanol-induced hypothermia.     

Neurotensin and pain modulation

Neurotensin (NT) can produce a profound analgesia or enhance pain responses, depending on the circumstances. Recent evidence suggests that this may be due to a dose-dependent recruitment of distinct populations of pain modulatory neurons. NT knockout mice display defects in both basal nociceptive responses and stress-induced analgesia. Stress-induced antinociception is absent in these mice and instead stress induces a hyperalgesic response, suggesting that NT plays a key role in the stress-induced suppression of pain. Cold water swim stress results in increased NT mRNA expression in hypothalamic regions known to project to periaqueductal gray, a key region involved in pain modulation. Thus, stress-induced increases in NT signaling in pain modulatory regions may be responsible for the transition from pain facilitation to analgesia. This review focuses on recent advances that have provided insights into the role of NT in pain modulation.     

Differential effects of pentobarbital and ethanol in mice

The duration of the loss of righting reflex (RR) after ethanol, 4 g/kg, intraperitoneally (i.p.), was significantly longer in “long-sleep” (LS) than in “short-sleep” (SS) mice. This effect was shown to be correlated with differences in brain sensitivities to ethanol. In contrast, pentobarbital sodium (PB), 50 mg/kg, i.p., produced a significantly longer loss of RR in SS than in LS mice. The PB concentrations in the brain were the same in both mouse strains at the time of RR recovery suggesting equal sensitivities of the central nervous systems to PB. The rates of disappearance of PB from the blood were the same in both strains, but the apparent volume of distribution of PB in the LS strain was greater than in SS mice.In addition, C57BL/6J mice were found to be more sensitive than DBA/2J mice to PB, 50 mg/kg. In contrast, C57BL mice are known to be less sensitive than the DBA strain to ethanol. The PB concentration in the brain of DBA mice at the recovery of the RR was significantly greater than in C57BL mice. The apparent volumes of distribution of PB were not different in the two strains, but the rate of disappearance of PB from the blood of C57BL mice was significantly greater than for the DBA strain. In conclusion, factors which govern the brain sensitivities of selected mouse strains to ethanol and pentobarbital may not be equivalent.     

Time course of ethanol's effects on brain prostaglandins in LS and SS mice

Prostaglandin synthesis inhibitors antagonize behavioral responses to alcohols. Recent work has shown that ethanol increases brain prostaglandin (PG) levels. The study reported here examined the time course for ethanol-stimulated brain PGE and PGF production in Long Sleep and Short Sleep mice, animals bred selectively for high vs. low acute response to ethanol. Increases in brain PGE levels correlated highly with the absorption phase but only partially with the elimination phase of ethanol. PGF levels correlated significantly with blood ethanol levels across the entire three hour period. These results, plus sex and genotype interactions, provide further evidence to support the hypothesis that ethanol produces its intoxicating effects to a significant degree through a prostaglandin mediated mechanism.     

Differences in L-[3H]Glutamate Accumulation and Endogenous L-Glutamate Content in Synaptic Vesicles from Mice Selectively Bred for Differences in Ethanol Sensitivity

The ATP-stimulated accumulation of L-[3H]glutamate by whole brain synaptic vesicle preparations from long-sleep and short-sleep mice, lines selectively bred for difference in sleep time response to acute ethanol administration, was examined. L-[3H]Glutamate accumulation in vesicles from short-sleep mice was approximately twice that observed in vesicles from long-sleep mice at three glutamate loading concentrations. The vesicular content of endogenous L-glutamate in crude and enriched vesicle preparations from short-sleep mice was approximately 1.5-fold higher than in vesicles from long-sleep mice. The data suggest that L-glutamate associated with synaptic vesicles may serve a role in glutamate neurosecretion.