Selective breeding for alcohol withdrawal severity

Risk Locus Identification Ties Alcohol Withdrawal Symptoms to SORCS2

BACKGROUND

Efforts to promote the cessation of harmful alcohol use are hindered by the affective and physiological components of alcohol withdrawal (AW), which can include life-threatening seizures. Although previous studies of AW and relapse have highlighted the detrimental role of stress, little is known about genetic risk factors.

METHODS

We conducted a genome-wide association study of AW symptom count in uniformly assessed subjects with histories of serious AW, followed by additional genotyping in independent AW subjects.

RESULTS

The top association signal for AW severity was in sortilin family neurotrophin receptor gene SORCS2 on chromosome 4 (European American meta-analysis n = 1,478, p = 4.3 × 10-9 ). There were no genome-wide significant findings in African Americans (n = 1,231). Bioinformatic analyses were conducted using publicly available high-throughput transcriptomic and epigenomic data sets, showing that in humans SORCS2 is most highly expressed in the nervous system. The identified SORCS2 risk haplotype is predicted to disrupt a stress hormone-modulated regulatory element that has tissue-specific activity in human hippocampus. We used human neural lineage cells to demonstrate in vitro a causal relationship between stress hormone levels and SORCS2 expression, and show that SORCS2 levels in culture are increased upon ethanol exposure and withdrawal.

CONCLUSIONS

Taken together, these findings indicate that the pathophysiology of withdrawal may involve the effects of stress hormones on neurotrophic factor signaling. Further investigation of these pathways could produce new approaches to managing the aversive consequences of abrupt alcohol cessation.

Chronobiology of ethanol: animal models

Clinical and epidemiological observations have revealed that alcohol abuse and alcoholism are associated with widespread disruptions in sleep and other circadian biological rhythms. As with other psychiatric disorders, animal models have been very useful in efforts to better understand the cause and effect relationships underlying the largely correlative human data. This review summarizes the experimental findings indicating bidirectional interactions between alcohol (ethanol) consumption and the circadian timing system, emphasizing behavioral studies conducted in the author's laboratory. Together with convergent evidence from multiple laboratories, the work summarized here establishes that ethanol intake (or administration) alters fundamental properties of the underlying circadian pacemaker. In turn, circadian disruption induced by either environmental or genetic manipulations can alter voluntary ethanol intake. These reciprocal interactions may create a vicious cycle that contributes to the downward spiral of alcohol and drug addiction. In the future, such studies may lead to the development of chronobiologically based interventions to prevent relapse and effectively mitigate some of the societal burden associated with such disorders.

Circadian rhythms and addiction: mechanistic insights and future directions

Circadian rhythms are prominent in many physiological and behavioral functions. Circadian disruptions either by environmental or molecular perturbation can have profound health consequences, including the development and progression of addiction. Both animal and humans studies indicate extensive bidirectional relationships between the circadian system and drugs of abuse. Addicted individuals display disrupted rhythms, and chronic disruption or particular chronotypes may increase the risk for substance abuse and relapse. Moreover, polymorphisms in circadian genes and an evening chronotype have been linked to mood and addiction disorders, and recent efforts suggest an association with the function of reward neurocircuitry. Animal studies are beginning to determine how altered circadian gene function results in drug-induced neuroplasticity and behaviors. Many studies suggest a critical role for circadian rhythms in reward-related pathways in the brain and indicate that drugs of abuse directly affect the central circadian pacemaker. In this review, we highlight key findings demonstrating the importance of circadian rhythms in addiction and how future studies will reveal important mechanistic insights into the involvement of circadian rhythms in drug addiction.

Use of animal models of alcohol-related behavior

Alcoholism (alcohol dependence and alcohol use disorder, AUD) is quintessentially behavioral in nature. AUD is behaviorally and genetically complex. This review discusses behavioral assessment of alcohol sensitivity, tolerance, dependence, withdrawal, and reinforcement. The focus is on using laboratory animal models to explore genetic contributions to individual differences in alcohol responses. Rodent genetic animal models based on selective breeding for high vs low alcohol response, and those based on the use of inbred strains, are reviewed. Genetic strategies have revealed the complexity of alcohol responses where genetic influences on multiple alcohol-related behaviors are mostly discrete. They have also identified areas where genetic influences are consistent across behavioral assays and have been used to model genetic differences among humans at different risk for AUD.

Ethanol drinking in withdrawal seizure-prone and -resistant selected mouse lines

Withdrawal Seizure-Prone (WSP) and Withdrawal Seizure-Resistant (WSR) mouse lines were bidirectionally selectively bred, respectively, to have severe or mild ethanol withdrawal handling-induced convulsions (HICs) after cessation of 3 days of ethanol vapor inhalation. Murine genotypes with severe withdrawal have been found to show low ethanol consumption, and high consumers show low withdrawal. An early drinking study with WSP and WSR mice showed modest evidence consistent with this genetic correlation, but there were several limitations to that experiment. We therefore conducted a thorough assessment of two bottle ethanol preference drinking in both replicate pairs of WSP/WSR selected lines in mice of both sexes. Greater preference drinking of WSR-2 than WSP-2 female mice confirmed the earlier report. However, in the parallel set of selected lines, the WSP-1 mice drank more than the WSR-1s. Naive mice tested for preference for sucrose, saccharin and quinine did not differ markedly for any tastant. Finally, in a test of binge-like drinking, Drinking in the Dark (DID), WSP mice drank more than WSR mice and attained significantly higher (but still modest) blood ethanol concentrations. Tests of acute withdrawal after DID showed a mild, but significant elevation in handling-induced convulsions in the WSP line. These results provide further evidence that 2-bottle ethanol preference and DID are genetically distinguishable traits.

Escalation of intake under intermittent ethanol access in diverse mouse genotypes

Experimental animals offered continuous 24-hour free choice access to ethanol rarely display voluntary ethanol consumption at levels sufficient to induce intoxication or to engender dependence. One of the simplest ways to increase voluntary ethanol intake is to impose temporal limitations on ethanol availability. Escalation of ethanol intake has been observed in both rats and mice under a variety of different schedules of alternating ethanol access and deprivation. Although such effects have been observed in a variety of rat and mouse genotypes, little is known concerning possible genetic correlations between responses to intermittent ethanol access and other ethanol-related phenotypes. In the present study, we examined the effects of intermittent ethanol access in mouse genotypes characterized by divergent responses to ethanol in other domains, including ethanol preference (C57BL/6J and C3H/HeJ mice), binge-like ethanol drinking (High Drinking in the Dark and HS/Npt mice) and ethanol withdrawal severity (Withdrawal Seizure-Prone and Withdrawal Seizure-Resistant mice). Although intermittent ethanol access resulted in escalated ethanol intake in all tested genotypes, the robustness of the effect varied across genotypes. On the other hand, we saw no evidence that the effects of intermittent access are correlated with either binge-like drinking or withdrawal severity, and only weak evidence for a genetic correlation with baseline ethanol preference. Thus, these different ethanol-related traits appear to depend on largely unique sets of genetic mediators.

Selective breeding for ethanol-related traits alters circadian phenotype

Previous studies in mice and rats have shown that selective breeding for high and low ethanol preference results in divergence of circadian phenotype in the selected lines. These results indicate that some alleles influencing ethanol preference also contribute to circadian rhythm regulation. Selective breeding has also been used to produce lines of mice differing in a number of other ethanol-related traits, while studies of phenotypic and genetic correlation indicate that diverse ethanol-related traits are influenced by both shared and unshared genetics. In the present study, we examined several features of circadian activity rhythms in a mouse line selected for binge-like drinking and in mouse lines selected for high and low severity of ethanol withdrawal convulsions. Specifically, Experiment 1 compared High Drinking in the Dark (HDID-1) mice to their genetically heterogeneous progenitor line (HS/Npt), and Experiment 2 compared Withdrawal Seizure-Prone (WSP-2) and Withdrawal Seizure-Resistant (WSR-2) mice. Both line pairs displayed differences in their daily activity patterns under light-dark conditions. In addition, HDID-1 mice showed shorter free-running periods in constant light and less coherent activity rhythms across lighting conditions relative to HS/Npt controls, while WSP-2 mice showed longer free-running periods in constant darkness relative to WSR-2 mice. These results strengthen the evidence for genetic linkages between responsiveness to ethanol and circadian regulation, and extend this evidence to include ethanol-related phenotypes other than preference drinking. However, the present results also indicate that the nature of genetic correlations between and within phenotypic domains is highly complex.

Chronic voluntary alcohol consumption results in tolerance to sedative/hypnotic and hypothermic effects of alcohol in hybrid mice

The continuous two-bottle choice test is the most common measure of alcohol consumption but there is remarkably little information about the development of tolerance or dependence with this procedure. We showed that C57BL/6J × FVB/NJ and FVB/NJ×C57BL/6JF1 hybrid mice demonstrate greater preference for and consumption of alcohol than either parental strain. In order to test the ability of this genetic model of high alcohol consumption to produce neuroadaptation, we examined development of alcohol tolerance and dependence after chronic self-administration using a continuous access two-bottle choice paradigm. Ethanol-experienced mice stably consumed about 16-18 g/kg/day of ethanol. Ethanol-induced withdrawal severity was assessed (after 59 days of drinking) by scoring handling-induced convulsions; withdrawal severity was minimal and did not differ between ethanol-experienced and -naïve mice. After 71 days of drinking, the rate of ethanol clearance was similar for ethanol-experienced and -naïve mice. After 77 days of drinking, ethanol-induced loss of righting reflex (LORR) was tested daily for 5 days. Ethanol-experienced mice had a shorter duration of LORR. For both ethanol-experienced and -naïve mice, blood ethanol concentrations taken at gain of righting reflex were greater on day 5 than on day 1, indicative of tolerance. After 98 days of drinking, ethanol-induced hypothermia was assessed daily for 3 days. Both ethanol-experienced and -naïve mice developed rapid and chronic tolerance to ethanol-induced hypothermia, with significant group differences on the first day of testing. In summary, chronic, high levels of alcohol consumption in F1 hybrid mice produced rapid and chronic tolerance to both the sedative/hypnotic and hypothermic effects of ethanol; additionally, a small degree of metabolic tolerance developed. The development of tolerance supports the validity of using this model of high alcohol consumption in genetic studies of alcoholism.

Disrupted thalamic T-type Ca2+ channel expression and function during ethanol exposure and withdrawal

Chronic ethanol exposure produces profound disruptions in both brain rhythms and diurnal behaviors. The thalamus has been identified as a neural pacemaker of both normal and abnormal rhythms with low-threshold, transient (T-type) Ca(2+) channels participating in this activity. We therefore examined T-type channel gene expression and physiology in the thalamus of C57Bl/6 mice during a 4-wk schedule of chronic intermittent ethanol exposures in a vapor chamber. We found that chronic ethanol disrupts the normal daily variations of both thalamic T-type channel mRNA levels and alters thalamic T-type channel gating properties. The changes measured in channel expression and function were associated with an increase in low-threshold bursts of action potentials during acute withdrawal periods. Additionally, the observed molecular and physiological alterations in the channel properties in wild-type mice occurred in parallel with a progressive disruption in the normal daily variations in theta (4-9 Hz) power recorded in the cortical electroencephalogram. Theta rhythms remained disrupted during a subsequent week of withdrawal but were restored with the T-type channel blocker ethosuximide. Our results demonstrate that a key ion channel underlying the generation of thalamic rhythms is altered during chronic ethanol exposure and withdrawal and may be a novel target in the management of abnormal network activity due to chronic alcoholism.

Selective breeding for intravenous drug self-administration in rats: a pilot study

Although the role of genetic factors in the response to drugs of abuse has been emphasized, no earlier studies have applied selective breeding to intravenous drug self-administration. Here we report the effects of six generations of selective breeding for rat lines with low or high levels of intravenous drug self-administration (LS and HS lines, respectively). Rats from the outbred founder population and the first selected generation were evaluated for intravenous self-administration of either morphine or cocaine. All subsequent generations were assessed for self-administration of cocaine, using a multifactorial score based on how rapidly self-administration behavior was acquired, levels of self-administration during acquisition, and the response to different doses of cocaine. All changes in cocaine self-administration that occurred in generations three through six were consistent with effects of selection, with most measures differing in sixth-generation LS and HS animals. Sixth-generation HS rats self-administered approximately five times more injections of low-dose cocaine than LS animals under fixed-ratio-5 (a schedule in which an injection is delivered after five lever presses). These findings support a role of genetic factors in influencing cocaine-reinforced behavior. Establishment of the LS and HS lines will allow future studies to evaluate the role of specific genetic factors that underlie these differences and may contribute to substance abuse disorders in humans.

Motor impairment: a new ethanol withdrawal phenotype in mice

Alcoholism is a complex disorder with genetic and environmental risk factors. The presence of withdrawal symptoms is one criterion for alcohol dependence. Genetic animal models have followed a reductionist approach by quantifying various effects of ethanol withdrawal separately. Different ethanol withdrawal symptoms may have distinct genetic etiologies, and therefore differentiating distinct neurobiological mechanisms related to separate signs of withdrawal would increase our understanding of various aspects of the complex phenotype. This study establishes motor incoordination as a new phenotype of alcohol withdrawal in mice. Mice were made physically dependent on ethanol by exposure to ethanol vapor for 72 h. The effects of ethanol withdrawal in mice from different genetic backgrounds were measured on the accelerating rotarod, a simple motor task. Ethanol withdrawal disrupted accelerating rotarod behavior in mice. The disruptive effects of withdrawal suggest a performance rather than a learning deficit. Inbred strain comparisons suggest genetic differences in magnitude of this withdrawal phenotype. The withdrawal-induced deficits were not correlated with the selection response difference in handling convulsion severity in selectively bred Withdrawal Seizure-Prone and Withdrawal Seizure-Resistant lines. The accelerating rotarod seems to be a simple behavioral measure of ethanol withdrawal that is suitable for comparing genotypes.

Seizures, illicit drugs, and ethanol

Recreational substance users are at risk for seizures by indirect mechanisms, including cerebral trauma, central nervous system infection, ischemic and hemorrhagic stroke, and metabolic derangements such as hypoglycemia, hypocalcemia, and renal failure. Drugs and ethanol can also cause seizures more directly, either as a feature of intoxication (eg, psychostimulants) or of withdrawal (eg, sedatives, including ethanol). In any patient with a seizure, clinicians should consider illicit drug or ethanol use. Seizures in known alcoholics or illicit drug users require workup to exclude treatable coexisting conditions.

Genetic Dissociation Between Ethanol Sensitivity and Rapid Tolerance in Mouse and Rat Strains Selectively Bred for Differential Ethanol Sensitivity

BACKGROUND

The Inbred Long- and Short-Sleep mice (ILS and ISS) and the Inbred High- and Low-Alcohol-Sensitive rats (IHAS and ILAS) were selectively bred for differential alcohol sensitivity with use of the duration of loss-of-righting-reflex test (LORR), with the IHAS and ILS animals being much more sensitive than the ILAS and ISS animals, respectively. The current study was undertaken to determine whether acute sensitivity in these strains is genetically correlated to a rapid tolerance to alcohol, a form of tolerance that is evident 24 hr after a single alcohol dose.

METHODS

Separate groups of animals were administered a single pretreatment dose of alcohol (0-6 g/kg for the mice; 0-4 g/kg for the rats). Alcohol sensitivity was tested 24 hr later with the LORR test, and blood ethanol concentration was tested at regain of righting (BECRR). Alcohol-induced hypothermia also was determined in the mice. Independently derived replicate rat strains were used for all experiments (IHAS1, ILAS1; IHAS2, ILAS2); no such replicates exist for the ILS and ISS strains.

RESULTS

Alcohol pretreatment caused a dose-dependent decrease in LORR duration accompanied by an increase in BECRR in the ILS strain, but LORR increased in the ISS strain with no effect on BECRR. Both strains became hypothermic during the LORR test on day two, but the only significant effect of alcohol pretreatment was in the ISS strain, in which alcohol-induced hypothermia was enhanced. Alcohol pretreatment caused a significant dose-dependent decrease in LORR duration accompanied by an increase in BECRR in the IHAS1 but not in the IHAS2 strain. In contrast, ILAS1 and ILAS2 strains both showed a significant increase in LORR duration and also a significant increase in BECRR.

CONCLUSIONS

Alcohol pretreatment caused a dose-dependent decrease in LORR duration and an increase in BECRR in the IHAS1 and ILS strain, suggesting the development of functional rapid tolerance. In contrast, LORR duration increased in the ILAS1, ILAS2, and ISS groups, but BECRR either increased (ILAS1, ILAS2) or did not change (ISS). These observations suggest that central nervous system sensitivity was decreased in the ILAS1 and ILAS2 groups (i.e., rapid functional tolerance) or unchanged in the ISS strain, but that some pharmacokinetic property also was altered in these strains. Overall, the results do not support a genetic relation between alcohol sensitivity and the development of rapid tolerance.

Alteration of kappa-opioid receptor system expression in distinct brain regions of a genetic model of enhanced ethanol withdrawal severity

Abrupt withdrawal from chronic alcohol exposure can produce convulsions that are likely due to ethanol (EtOH) neuroadaptations. While significant efforts have focused on elucidating dependence mechanisms, the alterations contributing to EtOH withdrawal severity are less well characterized. The present studies examined the kappa-opioid receptor (KOP-R) system in Withdrawal Seizure-Prone (WSP) and Withdrawal Seizure-Resistant (WSR) mice, selected lines that display severe and mild convulsions upon removal from chronic EtOH exposure. Previous data demonstrated significant increases in whole brain prodynorphin (Pdyn) mRNA in WSP mice only during EtOH withdrawal. No significant effects of EtOH exposure or withdrawal were observed in WSR mice. The present study characterized Pdyn mRNA and the KOP-R in WSP and WSR mice during EtOH withdrawal using in situ hybridization (ISH) and KOP-R autoradiography. Analyses were performed in brain regions that express Pdyn mRNA and/or KOP-R and that might participate in seizure circuitry: the piriform cortex, olfactory tubercle, nucleus accumbens, caudate-putamen, claustrum, dorsal endopiriform nucleus, and cingulate cortex. ISH analyses confirmed previous findings; EtOH withdrawal increased Pdyn mRNA in multiple brain regions of WSP mice, but not WSR. Basal KOP-R binding was higher in WSR mice than in WSP mice, suggesting an anti-convulsant role for receptor activation. Finally, increased KOP-R density was present during EtOH withdrawal in WSP mice. These data suggest that differences in the KOP-R system among the lines might contribute to their selected difference in EtOH withdrawal severity.

Alcohol and gene expression in the central nervous system

AIMS

To describe recent research focusing on the analysis of gene and protein expression relevant to understanding ethanol consumption, dependence and effects, in order to identify common themes.

METHODS

A selective literature search was used to collate the relevant data.

RESULTS

Over 160 genes have been individually assessed before or after ethanol administration, as well as in genetically selected lines. Techniques for studying gene expression include northern blots, differential display, real time reverse transcriptase-polymerase chain reaction (RT-PCR) and in situ hybridization. More recently, high throughput functional genomic technology, such as DNA microarrays, has been used to examine gene expression. Recent gene expression analyses have dramatically increased the number of candidate genes (nine array papers have illuminated 600 novel gene transcripts that may contribute to alcohol abuse and alcoholism).

CONCLUSIONS

Although functional genomic experiments (transcriptome analysis) have failed to identify a single alcoholism gene, they have illuminated important pathways and gene products that may contribute to the risk of alcohol abuse and alcoholism.

Chromosomal loci influencing chronic alcohol withdrawal severity

Ethanol (alcohol) withdrawal-induced convulsions are a key index of physical dependence on ethanol and a clinically important consequence of alcohol abuse in humans. In rodent models, severity of withdrawal is strongly influenced by genotype. For example, many studies have reported marked differences in withdrawal severity between the WSR (Withdrawal Seizure Resistant) and WSP (Withdrawal Seizure Prone) mouse strains selectively bred for over 25 generations to differ in chronic withdrawal severity. Therefore, we used an F(2) intercross between the inbred WSP and WSR strains for a genome-wide search for quantitative trait loci (QTLs), which are chromosomal sites containing genes influencing the magnitude of withdrawal. We also used the recently developed HW, RHW (high withdrawal) and LW, RLW (low withdrawal) lines selectively bred for the same trait and in the same manner as the WSP, WSR lines. QTL analysis was then used to dissect the continuous trait distribution of withdrawal severity into component loci, and to map them to broad chromosomal regions by using the Pseudomarker 0.9 and Map Manager QT29b programs. This genome-wide search identified five significant QTLs influencing chronic withdrawal severity on Chromosomes (Chrs) 1 (proximal), 4 (mid), 8 (mid), 11 (proximal), and 14 (mid), plus significant interactions (epistasis) between loci on Chr 11 with 13, 4 with 8, and 8 with 14.

Genetic selection for high and low alcohol consumption in a limited-access paradigm

BACKGROUND

Several rat lines have been bred for their differences in alcohol consumption based on a continuous-access paradigm in which alcohol solution is available 24 hr/day. The limited-access paradigm (LAP), in which access to alcohol solution is restricted to a short period per day, however, has been used extensively to investigate the neurochemical mechanisms underlying alcohol consumption. There is evidence of possible differences in genetic determination of alcohol drinking in a continuous- versus limited-access condition. For these reasons, selective breeding for high- and low-alcohol consumption (HARF and LARF, respectively) based on a LAP was conducted.

METHODS

N/Nih rats were used as the breeding stock. A within-family breeding procedure was used to develop HARF and LARF lines with 10 families per line. Access to alcohol solution was restricted to 20 min/day. Alcohol was provided as 3%, 6% and 12% w/v solutions. Average intake of alcohol during the 12% phase was used as the selection criterion. Inbreeding began in the seventh generation.

RESULTS

After the sixth generation of selection, rats from the HARF line consumed an average of 1.2 g/kg, whereas rats from the LARF line consumed an average of 0.6 g/kg of alcohol during the 20-min access period. Alcohol consumption remained stable over the next eight generations of inbreeding. In the continuous-access-drinking paradigm, the HARF and LARF rats consumed an average of 5.5 to 7.0 g/kg and 1.0 to 2.0 g/kg of alcohol per day respectively. An estimated heritability of 0.25 was obtained.

CONCLUSIONS

These findings indicate that alcohol drinking in the LAP is influenced by genetic factors. Differences in alcohol drinking in the LAP also generalize to continuous access drinking. These rat lines will be very useful for investigations into the genetic and neurochemical mechanisms underlying alcohol drinking.

Ethanol-regulated gene expression of neuroendocrine specific protein in mice: brain region and genotype specificity

Neuroendocrine specific protein or reticulon 1 (NSP/RTN1) was identified as a putative ethanol-regulated gene using mRNA differential display in mice genetically selected for severe ethanol withdrawal (withdrawal seizure-prone, WSP). One transcript of RTN1 (3.0 kb) showed a statistically significant increase (13%) in relative abundance in whole brain of ethanol-treated WSP mice but not in mice selected for resistance to ethanol withdrawal convulsions (WSR). We hypothesized that ethanol-induced regulation of gene expression of mRTN1 is specific to mice predisposed to exhibit severe ethanol withdrawal and that the gene might be regulated differentially in specific brain regions. WSP and WSR selected lines and DBA/2J and C57BL/6J inbred strains of mice were exposed to ethanol vapor or air for 72 h. mRNA steady-state expression of RTN1 was assessed in hippocampus, cortex, and cerebellum. Results indicated that the pattern of ethanol-induced changes in gene expression was dependent upon transcript size, brain region, and genotype. Modest increases in the relative abundance of both transcripts of RTN1 were observed in the hippocampus and cortex of all ethanol-treated mice. Results from cerebellum showed a moderate decrease in expression of RTN1 (3.0 kb transcript) in WSP and DBA/2J mice, but not in the mice resistant to ethanol withdrawal (C57BL/6J and WSR). These results suggest a genotype-specific effect of chronic ethanol exposure on steady-state mRNA levels of RTN1 in the cerebellum. Overall, the results indicate a complex pattern of ethanol-induced regulation of the putative mouse homologue of RTN1 and suggest that specific brain regional changes may be involved in the expression of physical dependence.

Withdrawal from alcohol in withdrawal seizure-prone and -resistant mice: evidence for enkephalin resistance

Methionine enkephalin (Met-enkephalin) functions as an endogenous anticonvulsant. Peptide transport system-1 (PTS-1) is an important regulator of Met-enkephalin levels in brain and transports the peptide from brain to blood. In outbred mice, alcohol dependence is associated with decreased PTS-1 activity and increased levels of Met-enkephalin. In contrast, alcohol withdrawal is associated with recovery of PTS-1 activity, decreased levels of Met-enkephalin, and seizures. In this study, we examined the PTS-1/Met-enkephalin system in two replicates of withdrawal seizure-resistant (WSR) and withdrawal seizure-prone (WSP) mouse lines. We measured levels of preproenkephalin (PPE) mRNA and Met-enkephalin peptide in brain and the activity of PTS-1 during alcohol-naive, -dependent, and -withdrawal states. In alcohol-naive animals, Met-enkephalin levels were higher in WSP than in WSR mice. In alcohol-withdrawal animals, Met-enkephalin levels remained elevated in WSP mice, whereas they increased in WSR mice. Peptide levels were unrelated to levels of PPE mRNA or activity of PTS-1. Factorial analysis showed that proneness to seizures was genetically linked to Met-enkephalin levels in alcohol-naive, -dependent, and -withdrawing mice but not to mRNA levels or PTS-1 activity. Overall, these results may be explained by resistance to enkephalin in WSP mice and suggest that the dysregulation of the PTS-1/Met-enkephalin system contributes to susceptibility to seizures in WSP mice.

Elevated prodynorphin expression associated with ethanol withdrawal convulsions

The hypothesis that kappa-opioid system activity may in part mediate convulsions exhibited during ethanol withdrawal was tested by exposing Withdrawal Seizure-Prone (WSP) and Withdrawal Seizure-Resistant (WSR) mice to chronic ethanol. Whole brain was harvested for RNA isolation and prodynorphin mRNA steady-state levels in whole brain were examined using Northern blot analysis. The data revealed significantly increased levels of prodynorphin mRNA expression in mice susceptible to ethanol withdrawal convulsions after withdrawal, with no corresponding increase in prodynorphin steady-state levels in mice resistant to ethanol withdrawal convulsions. These findings were not due to basal differences in prodynorphin expression between the WSP and WSR mice. To verify that the differences observed were not due to an ethanol-induced global alteration in gene transcription, mRNA levels of the housekeeping gene glyceraldehyde-3-phosphate dehydrogenase were measured. Glyceraldehyde-3-phosphate dehydrogenase expression was unchanged following both chronic exposure to ethanol and chronic exposure followed by withdrawal. These results extend our understanding of prodynorphin's role in generalized seizure activity to include ethanol withdrawal-induced convulsions. Our findings suggest that prodynorphin expression is modulated during ethanol withdrawal convulsions, or alternatively, prodynorphin may mediate the severity of ethanol withdrawal convulsions.

The heritability of alcoholism symptoms: "indicators of genetic and environmental influence in alcohol-dependent individuals" revisited

There is consistent evidence from twin and adoption studies implicating genetic factors in the etiology of alcoholism, yet few studies have examined the role of genetic influences on individual symptoms of alcoholism. In a previous study of 113 male twins, Johnson et al. (1996a) identified 7 alcoholism symptoms that were more "genetic" and 14 that were more "environmental" (that is, non-genetic) in their etiology by examining symptom concordances among monozygotic and dizygotic twin pairs. The present study represents an attempt to replicate the results of this previous study and extend them by estimating the contribution of genetic factors to the variation in liability for different alcoholism symptoms. Subjects were 3356 male twin pairs from the Vietnam Era Twin Registry. Lifetime histories of alcoholism symptoms were assessed by a structured psychiatric telephone interview. The results of the previous study were not replicated. The correlations between symptom classifications as genetic and non-genetic in the present and previous study were nonsignificant and ranged from -0.27 to 0.11. However, within the present study the correlation between symptom classifications as genetic and non-genetic was statistically significant across random split-half subsamples (r = 0.59); nine alcoholism symptoms were consistently classified as genetic and six symptoms as non-genetic in their etiology. Model-fitting analyses applied to different alcoholism symptoms yielded heritability estimates ranging from 0.03 to 0.53 with broad and overlapping confidence intervals around these estimates, ranging from 0.00 to 0.65. The results of this study highlight the difficulty of identifying more or less heritable phenotypes in twin research, and suggest that it may not be possible to identify specific alcoholism symptoms that are more genetic in their etiology than others. Nevertheless, there appears to be potentially important variation in the relative magnitude of genetic influences for individual alcoholism symptoms, and exploring these differences may lead to further insights into the nosology and etiology of alcohol-related problems.

Five generations of selective breeding for ultrasonic vocalization (USV) responses in N:NIH strain rats

This article reports on early results from an ongoing selective breeding study in which rats were selected for different rates of ultrasonic vocalization (USV) in response to isolation. Using the N:NIH strain, all litters were screened at 10 (+/- 1) days of age in a 2-min isolation test, and those males and females with the highest (or lowest) rates in each litter were selected for later breeding with like breeders from unrelated litters. A Random line (unselected control) was also bred. In the first selected generation (S1), the Low line diverged from Random line controls, and has maintained significantly lower rates over all generations since. In the S3 generation, the High line diverged significantly from Random line controls, and has shown significantly higher USV rates in each succeeding generation. No line differences were found in other behaviors measured in isolation. Data from a small sample of S5 pups tested at postnatal Days 3, 10, 14, and 18 days showed that individual pups' rates of USV from Day 10 predicted those at Day 14, consistent with findings from an unselected generation. Ambient temperature, modulated by body weight, controlled USV at Day 3, whereas at Days 10 and 14 line accounted for most of the variance in USV. This is the first instance of laboratory selection occurring on the basis of an infantile trait.

Cross-generalization of an EtOH "hangover" cue to endogenously and exogenously induced stimuli

Twenty male Sprague-Dawley rats were trained in a two-choice food-reinforced drug discrimination task (10 min sessions) using the state-dependent interoceptive stimulus attributes of ethanol's (EtOH) delayed or rebound effects (EDE) versus "normal" basal homeostasis. Cross-generalization tests were conducted with 0.18 mg/kg naloxone injected after three days of three injections per day of either SAL or 10 mg/kg morphine. Naloxone failed to generalize to the EDE-state after chronic saline; however, the precipitated morphine withdrawal state produced complete generalization to the EDE training cue. Daily tests were conducted after 8 h photoperiod phase-shifts. An 8 h phase-advance, equivalent to a west-to-east intercontinental night-time flight in humans, produced a biphasic, graded, increase in EDE-appropriate responding, which peaked on the second day after the phase-advance and recovered by the fourth day. The 8 h phase-delays failed to engender significant EDE-appropriate responding. These data provide evidence for the subjective similarity between EtOH hangover, opiate withdrawal states, and the physiological disruption induced by circadian phase-advances.

The 1996 RSA Distinguished Research Award Lecture. A genetic animal model of alcohol withdrawal

Work with genetic animal models has a long history in alcohol research. No attempt has been made here to acknowledge the contributions of the many other long-standing projects in the area. Rather, I have tried to give a capsule view of one such project, and to indicate some areas of future direction. It seems clear that the expression of molecular biological tools will greatly expand our capabilities in the immediate future. The field is well-situated to take advantage of this situation, as it has achieved much progress during the "dark ages," where the study of genetic influence was inferential: that is, we were limited to studying genes we could not identify. The future will surely lead us to the identification and study of specific genes of importance.

Genetic animal models of alcohol and drug abuse

Behavioral and pharmacological responses of selectively bred and inbred rodent lines have been analyzed to elucidate many features of drug sensitivity and the adverse effects of drugs, the underlying mechanisms of drug tolerance and dependence, and the motivational states underlying drug reward and aversion. Genetic mapping of quantitative trait loci (QTLs) has been used to identify provisional chromosomal locations of genes influencing such pharmacological responses. Recent advances in transgenic technology, representational difference analysis, and other molecular methods now make feasible the positional cloning of QTLs that influence sensitivity to drugs of abuse. This marks a new period of synthesis in pharmacogenetic research, in which networks of drug-related behaviors, their underlying pharmacological, physiological, and biochemical mechanisms, and particular genomic regions of interest are being identified.

Quantitative trait loci (QTL) applications to substances of abuse: physical dependence studies with nitrous oxide and ethanol in BXD mice

Recombinant inbred (RI) mouse strains were developed primarily as a tool to detect and provisionally map major gene loci--those with effects large enough to cause a bimodal distribution in the trait of interest. This implied that progress toward gene mapping was possible only for gene loci accounting for at least half of the genetic variance. More recently, QTL (quantitative trait loci) approaches have been advanced that do not require bimodal distributions and are thus applicable to a much wider range of phenotypes. They offer the prospect of meaningful progress toward detecting and mapping minor as well as major gene loci affecting any trait of interest, provided there is a significant degree of genetic determination among the RI strains. This paper presents a review of RI gene mapping efforts concerning phenotypes related to drug abuse and presents new data for studies now in progress for nitrous oxide and acute ethanol withdrawal intensity. These two studies exemplify several strengths and limitations of the RI QTL approach.