Ethanol dependence and the pituitary-adrenal axis in mice. I. Genotypic differences in hormone levels

Social transfer of pain in mice

A complex relationship exists between the psychosocial environment and the perception and experience of pain, and the mechanisms of the social communication of pain have yet to be elucidated. The present study examined the social communication of pain and demonstrates that "bystander" mice housed and tested in the same room as mice subjected to inflammatory pain or withdrawal from morphine or alcohol develop corresponding hyperalgesia. Olfactory cues mediate the transfer of hyperalgesia to the bystander mice, which can be measured using mechanical, thermal, and chemical tests. Hyperalgesia in bystanders does not co-occur with anxiety or changes in corticosterone and cannot be explained by visually dependent emotional contagion or stress-induced hyperalgesia. These experiments reveal the multifaceted relationship between the social environment and pain behavior and support the use of mice as a model system for investigating these factors. In addition, these experiments highlight the need for proper consideration of how experimental animals are housed and tested.

Human and laboratory rodent low response to alcohol: is better consilience possible?

If people are brought into the laboratory and given alcohol, there are pronounced differences among individuals in many responses to the drug. Some participants in alcohol challenge protocols show a cluster of 'low level of responses to alcohol' determined by observing post-drinking-related changes in subjective, motor and physiological effects at a given dose level. Those individuals characterized as having low level of response (LR) to alcohol have been shown to be at increased risk for a lifetime diagnosis of alcohol dependence (AD), and this relationship between low LR and AD appears to be in part genetic. LR to alcohol is an area where achieving greater consilience between the human and the rodent phenotypes would seem to be highly likely. However, despite extensive data from both human and rodent studies, few attempts have been made to evaluate the human and animal data systematically in order to understand which aspects of LR appear to be most directly comparable across species and thus the most promising for further study. We review four general aspects of LR that could be compared between humans and laboratory animals: (1) behavioral measures of subjective intoxication; (2) body sway; (3) endocrine responses; and (4) stimulant, autonomic and electrophysiological responses. None of these aspects of LR provide completely face-valid direct comparisons across species. Nevertheless, one of the most replicated findings in humans is the low subjective response, but, as it may reflect either aversively valenced and/or positively valenced responses to alcohol as usually assessed, it is unclear which rodent responses are analogous. Stimulated heart rate appears to be consistent in animal and human studies, although at-risk subjects appear to be more rather than less sensitive to alcohol using this measure. The hormone and electrophysiological data offer strong possibilities of understanding the neurobiological mechanisms, but the rodent data in particular are rather sparse and unsystematic. Therefore, we suggest that more effort is still needed to collect data using refined measures designed to be more directly comparable in humans and animals. Additionally, the genetically mediated mechanisms underlying this endophenotype need to be characterized further across species.

Metabotropic glutamate receptor 5 (mGluR5) regulation of ethanol sedation, dependence and consumption: relationship to acamprosate actions

Recent studies have demonstrated that metabotropic glutamate receptor 5 (mGluR5) antagonists decrease alcohol self-administration and suggest that the anti-craving medication, acamprosate, may also act to decrease mGluR5 function. To address the role of mGluR5 in behavioural actions of ethanol and acamprosate, we compared mutant mice with deletion of the mGluR5 gene and mice treated with a mGluR5 antagonist (MPEP) or acamprosate. Lack of mGluR5 or administration of MPEP reduced the severity of alcohol-induced withdrawal (AW), increased the sedative effect of alcohol (duration of loss of righting reflex; LORR), and increased basal motor activity. The motor stimulation produced by ethanol was blocked by deletion of mGluR5, but not by injection of MPEP. Both acamprosate and MPEP increased ethanol-induced LORR and reduced AW. Importantly, the protective effects of both MPEP and acamprosate on AW were found when the drugs were injected before, but not after, injection of ethanol. This indicates that the drugs prevented development of dependence rather than merely producing an anticonvulsant action. No effects of acamprosate or MPEP on ethanol-induced LORR and AW were found in mGluR5 knockout mice, demonstrating that mGluR5 is required for these actions. mGluR5 null mutant mice showed decreased alcohol consumption in some, but not all, tests. These data show the importance of mGluR5 for several actions of alcohol and support the hypothesis that some effects of acamprosate require mGluR5 signalling.

Dopamine and serotonin release in dorsal striatum and nucleus accumbens is differentially modulated by morphine in DBA/2J and C57BL/6J mice

Numerous studies have demonstrated that genetic factors significantly influence opioid ability to induce behavioral modification in mice. This differential sensitivity has been extensively studied, particularly in the DBA/2J and C57BL/6J strains. In the present study, using the "in vivo" microdialysis technique in these strains, we investigated the effect of morphine administration on the extracellular levels of dopamine (DA), serotonin (5-HT), and their metabolites in the nucleus accumbens and dorsal striatum--areas thought to be involved in morphine-induced locomotor hyperactivity. In the nucleus accumbens, morphine (20 mg/kg) significantly increased extracellular levels of DA in both strains. However, in dorsal striatum the morphine-induced increase of extracellular DA was lower in DBA/2J mice than in C57BL/6J. Moreover, morphine significantly stimulated 5-HT and 5-hydroxyindolacetic acid (5-HIAA) release both in nucleus accumbens and dorsal striatum of C57BL/6J mice, whereas it decreased 5-HT release without modifying 5-HIAA levels in DBA/2J mice. These results suggest that the different behavioral and biochemical responses to acute morphine described in these two strains could be mediated by different sensitivity of both the dopaminergic and the serotonergic systems.

Opioids and alcoholism

Although far from conclusive, evidence implicating the endogenous opioid system in the development and maintenance of alcoholism is growing. Currently available data suggest that ethanol increases opioid neurotransmission and that this activation is part of the mechanism responsible for its reinforcing effects. Findings from preclinical research indicate that ethanol consumption and ethanol-induced dopamine (DA) release are both reduced by opioid antagonists. Individual differences in endogenous opioid activity have been linked to inherited risks for alcoholism in studies comparing ethanol-preferring and nonpreferring rats, as well as in studies using targeted gene mutation (knockout) strategies. To a large extent, findings from human studies have paralleled those from the preclinical work. Persons who differ in family history of alcoholism have been shown to also differ in basal beta-endorphin activity, beta-endorphin response to alcohol, and subjective and HPA axis hormonal response to opioid antagonists. Findings from clinical trials indicate that opioid antagonists may reduce ethanol consumption in alcoholics, particularly in persons who have resumed drinking. Nevertheless, many questions remain unanswered about the use of opioid antagonists in alcoholism treatment and about the exact role of the opioid system in ethanol preference and reward. The progression of knowledge in this field suggests that many of these questions are imminently answerable, as our ability to characterize relationships between opioid activity and human behavior continues to develop. This paper summarizes both the progress that has been made and the gaps that remain in our understanding of the interactions between the endogenous opioid system and risk for alcoholism.

Genetics of alcoholism: role of the endogenous opioid system

At the present time alcoholism is recognized as a metabolic disease exhibiting the clinical features of craving for alcohol, loss of control over drinking, tolerance and physical dependence on alcohol, while both epidemiological and experimental studies have demonstrated that genetic factors may be important in determining whether an individual has a high or low vulnerability to develop alcoholism. Evidence also indicates that alcoholism is not characterized by a single gene single allele inheritance. Instead it seems that multiple genes and environmental factors interact to increase or decrease an individual's vulnerability to become an alcoholic. Current research is aimed at investigating whether certain behavioral, physiological and biochemical markers are highly associated with the incidence of alcoholism. Among the biochemical markers currently under investigation is the endogenous opioid system and its implication in mediating the reinforcing effects of ethanol. It is the objective of this manuscript to review current research on: (a) the interactions of ethanol with the endogenous opioid system at the molecular level; (b) the existence of genetically determined differences in the response of the endogenous opioid system to ethanol between subjects at high and low risk for excessive ethanol consumption, as well as between lines of animals showing preference or aversion for ethanol solutions; (c) the decrease of alcohol consumption following pretreatment with opioid antagonists; and (d) the possible use of specific opioid receptor antagonists together with behavioral therapy to modify drinking behavior, to control craving and to prevent relapse.

Specific and nonspecific effects of ethanol vapor on plasma corticosterone in mice

The intent of this study was to determine whether chronic ethanol (EtOH) vapor inhalation, with or without adjunct pyrazole (PYR) administration, was stressful in mice, as defined by increases in plasma corticosterone (CORT) concentration. Mice were randomly assigned to groups differentiated both on the basis of EtOH vapor exposure and the presence or absence of PYR administration. Blood samples for blood EtOH concentration (BEC) and plasma CORT concentration were obtained from mice after 72-96 hours of treatment. Mice were sacrificed after 96 hours of treatment and body and adrenal weight determined. BEC was significantly higher in PYR-treated animals and animals treated with the higher EtOH vapor concentration. Plasma CORT was elevated in proportion to BEC; however, other nonspecific stresses, in particular that of PYR administration, also elevated plasma CORT. Nonspecific stresses associated with this protocol may reduce the generality of these observations. Nevertheless, the high correlation between BEC and plasma CORT concentration in the PYR groups indicates that, with suitable control groups, the PYR-EtOH vapor inhalation approach is viable for studies concerned with EtOH effects on hypothalamic-anterior pituitary-adrenocortical function.

Differences in the brain and pituitary beta-endorphin system between the alcohol-preferring AA and alcohol-avoiding ANA rats

The content of pro-opiomelanocortin (POMC) mRNA was determined in the hypothalamus, as well as in the anterior and intermediate lobes of the pituitary gland of the alcohol-preferring AA and alcohol-avoiding ANA rats under basal conditions. In addition the content of beta-endorphin-like immunoreactivity (beta-EPLIR) was measured in nine brain regions, the anterior and intermediate lobes of the pituitary gland and the serum. The content of beta-EPLIR was significantly higher in the septum and significantly lower in the amygdala, and periaqueductal gray matter of the AA rats, while there was no significant difference between the AA and ANA rats in the arcuate nucleus plus median eminence, nucleus accumbens, caudate, hippocampus, and cortex. HPLC analysis indicated no significant differences in the relative proportions of non-acetyl and acetyl forms of beta-endorphin peptides in the hypothalamus, distinct brain regions, and anterior and neurointermediate lobes of the pituitary gland, between the AA and ANA rats. The content of POMC mRNA but not of beta-EPLIR was significantly higher in the hypothalamus and neurointermediate lobe of the AA rats, while the content of both beta-EPLIR and POMC mRNA were significantly higher in the anterior pituitary of the AA than of the ANA rats. Thus, there are genetically determined differences in the pituitary and brain beta-endorphin system between the AA and ANA rats, which may be important in controlling the differences in the voluntary ethanol consumption exhibited by these animals.

Genetic differences in hypothalamic-pituitary-adrenal axis responsiveness to acute ethanol and acute ethanol withdrawal

There is a growing body of evidence suggesting that corticosteroids contribute to the increased neural excitability observed during ethanol withdrawal. In the present study, this was further investigated using mouse strains which differ in ethanol withdrawal severity. DBA/2 (DBA) mice were found to display more severe acute ethanol withdrawal seizures than C57BL/6 (C57) mice. Additionally, DBA mice showed a greater stress response than C57 mice, as measured by higher plasma concentrations of adrenocorticotropic hormone (ACTH) and corticosterone, to an acute dose of ethanol. Mimicking withdrawal plasma corticosterone levels by administering corticosterone to ethanol-naive mice resulted in increases in handling-induced convulsions in the range observed during withdrawal. There did not appear to be a strain difference in sensitivity to the excitatory effects of corticosterone. In summary, the greater stress response to ethanol by DBA mice may account, in part, for the more severe ethanol withdrawal syndrome of this strain.

Cortisol and beta-endorphin response in alcoholics and alcohol abusers following a high naloxone dosage

The course of plasma cortisol and beta-endorphin-like immunoreactivity (beta-EP-IR) was determined following a single i.v. administration of 20 mg naloxone. The test subjects included 20 male alcoholics (medication-free), investigated one to three days and four weeks after the onset of abstinence, as well as 10 short-time abstinent alcohol abusers and 10 healthy control subjects. The mean baseline values of cortisol and beta-EP-IR remained within normal limits in all groups. The significant decrease in the plasma cortisol baseline values in the alcoholics after 4 weeks abstinence may indicate a lower level of the regulation of the hypothalamic-pituitary-adrenal axis (HPA) under conditions of abstinence. After naloxone administration an increase in plasma cortisol and beta-EP-IR was observed in all groups. The multivariate trend analysis showed significant differences in the time course of plasma cortisol between the three groups, however not in the course of beta-EP-IR. The changes in the dynamic regulation of the HPA axis, resulting from chronic alcohol consumption, appears to be irrespective of whether the drinking pattern is dependent or abusive. In alcoholics these changes could still be identified following a 4-week abstinence period.

Opioids and behavior: genetic aspects

Three animal models, based on genetic differences in endogenous opioid peptides and opioid receptors, are described. Obese mice and rats, whose pituitary opioid content is elevated, may be used to investigate eating disorders. Recombinant inbred strains of mice, which differ in brain opioid receptors and analgesic responsiveness, can be used for study of opioid- and nonopioid-mediated mechanisms of pain inhibition. Individual reactivity to opioids can be examined in C57BL/6 and DBA/2 inbred strains of mice. A model that combines a variety of opioid effects is offered and suggests the existence of a genetically determined dissociation of opioid effects on locomotor activity and pain inhibition. In addition, stimulatory locomotor responses in the C57BL/6 reaction type are linked to a high risk of drug addiction and facilitatory effects on adaptive processes, while high analgesic potency in the DBA/2 reaction type is accompanied by a low proneness to drug abuse and amnesic properties of opioids.

Regional brain [Met]-enkephalin in alcohol-preferring and non-alcohol-preferring inbred strains of mice

Scrutiny of the data from these studies reveals that the C58/J alcohol-preferring mice have significantly lower baseline methionine-enkephalin levels in both the corpus striatum and hypothalamus compared to C3H/CHRGL/2 non-alcohol-preferring mice. In other brain regions in these two strains, specifically, pituitary, amygdala, midbrain, and hippocampus, analysis of methionine-enkephalin levels did not show any significant differences. This suggests that the hypothalamus may indeed be a specific locus involved in the regulation of alcohol intake, via the molecular interaction between neuroamines, opioid peptides, as they are influenced by genetics and environment.

Inbred strains of mice with variable sensitivity to ethanol exhibit differences in the content and processing of beta-endorphin

The content of beta-endorphin-like immunoreactivity (beta-EPLIR) in the anterior and neurointermediate lobe of the pituitary gland, the hypothalamus and the serum of the c57BL/6, BALB/C and DBA/2 inbred strains of mice was estimated at the resting state as well as 45 min after i.p. injection of either ethanol solution (3.0 g/kg.b.wt.) or saline. At the resting state, the neurointermediate lobe and the serum of the c57BL/6 mice showed the highest content of beta-EPLIR, while no statistically significant difference was noticed in the total beta-EPLIR content in the anterior lobe and hypothalamus. At 45 min post-ethanol treatment the beta-EPLIR content was increased in the serum of all three strains of mice studied and was decreased in the hypothalamus of the c57BL/6 mice only. Further analysis of the beta-endorphin peptides using sephadex G-75 chromatography and reverse phase high performance liquid chromatography indicated strain differences in the relative proportions of the various forms of beta-endorphin in the anterior lobe, neurointermediate lobe and the hypothalamus. These strain specific differences in the content and post-translational processing of beta-endorphin may be involved in some of the genetically determined differences in responses to ethanol by these inbred strains of mice.

Influence of ethanol dependence on regional brain content of beta-endorphin in the mouse

beta-Endorphin-like immunoreactivity (BE-LI) was measured in 7 brain regions of Swiss-Webster mice after 24, 48 and 72 h of exposure to ethanol vapor following a priming injection of ethanol and daily injections of pyrazole HCl to inhibit ethanol metabolism. Control mice in identical chambers received pyrazole injections but breathed air only. Ethanol dependence was confirmed by scoring additional groups of mice for handling-induced convulsions during withdrawal after each exposure duration. Measurement of anterior and neurointermediate (NIL) pituitary BE-LI, alpha-MSH and ACTH and plasma corticosterone confirmed earlier results showing NIL depletion of all 3 peptides at 24 h and increased plasma corticosterone concentrations at 72 h in ethanol-exposed mice. In brain extracts from ethanol-dependent mice, BE-LI was significantly reduced in the hypothalamus and midbrain with the greatest reduction occurring at 24 h. In forebrain, cerebral cortex, septum and hippocampus, pyrazole treatment significantly reduced BE-LI relative to an unhandled control group, and ethanol exposure tended to reverse this effect. HPLC of hypothalamic extracts revealed no differences in proportions of molecular forms of beta-endorphin-like peptides between 24 h control and ethanol-exposed groups. The predominant BE-LI peak in both groups co-eluted with opiate-active unmodified beta-endorphin. Ethanol dependence in mice is associated with regionally selective decreases in brain beta-endorphin concentration.

Neonatal monosodium glutamate lesions alter neurosensitivity to ethanol in adult mice

A number of studies have indicated a relationship between brain peptide activity and sensitivity to the behavioral effects of ethanol. Specifically, it has been suggested that ethanol effects are mediated by changes in the endogenous opioid peptides derived from the proopiomelanocortin (POMC) precursor. Most cell bodies containing brain POMC-derived peptides are found in the arcuate nucleus of the hypothalamus. Neonatal administration of monosodium glutamate (MSG) has been reported to destroy cell bodies of the arcuate nucleus. We treated WSC strain mice on postnatal Day 4 with a single SC injection of 4 mg/g MSG or saline. When adult, MSG and control mice were challenged with an IP injection of ethanol and its effect on body temperature, open field activity, or duration of loss of righting reflex was assessed. Blood ethanol concentration (BEC) was measured and the hypothalamic content of beta-endorphin like immunoreactivity (beta-EP) was determined by radioimmunoassay. beta-EP was markedly reduced in both females and males by MSG treatment. MSG-treated animals of both sexes showed significantly less ethanol-induced hypothermia than controls. BEC was higher in MSG-treated animals of both sexes than in controls, so the differences were not due to ethanol pharmacokinetics. beta-EP was generally lower in males. Duration of righting reflex was prolonged in MSG treated animals, and the reduction in open field activity was potentiated. These latter effects may be in part attributable to the higher BECs achieved in lesioned animals. These data suggest that beta-EP cell bodies in the arcuate nucleus of the hypothalamus mediate neurosensitivity to some effects of ethanol in mice, but further experiments will be necessary to implicate beta-EP specifically.

Endorphins in inbred mice with variable sensitivity to ethanol: effect of acute ethanol treatment

Resting levels of beta-endorphin like immunoreactivity were determined in the hypothalamus, neurointermediate lobe and anterior lobe of the pituitary gland and the serum of inbred mice strains (C57BL/6, BALB/C and DBA/2). C57BL/6 mice showed the highest content of beta-endorphin like immunoreactivity in the neurointermediate lobe, anterior lobe and serum. Animals were injected i.p. with either an ethanol solution (3g ethanol/Kg b. wt.) or saline. 45 minutes post ethanol treatment the beta-endorphin like immunoreactivity content was increased in the serum of all three strains of mice studied and was decreased in the hypothalamus of the C57BL/6 mice. Studies with reverse phace HPLC indicated some differences in the relative proportions of the various forms of beta-endorphin in some tissues among the three strains of mice. These results suggest that genetically determined differences in endorphin levels may be involved in some of the genetically determined differences in responses to ethanol.