Peri-adolescent Alcohol Consumption Enhances the Reinforcing and Stimulatory Properties of Ethanol within the Adult Mesolimbic Dopamine System in Alcohol Preferring P Rats

Toalston, Jamie E.

07 August 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Research in the alcohol preferring (P) rat has indicated that peri-adolescent alcohol (EtOH) consumption enhances the acquisition of oral operant EtOH self-administration, inhibits the extinction of responding for EtOH, augments EtOH-seeking behaviors, and increases relative reward value of EtOH during adulthood. Experiment 1 was conducted to determine if these adult effects of peri-adolescent EtOH intake could be observed using an Intracranial Self-Administration (ICSA) model. It was hypothesized that an increased sensitivity to the rewarding actions of EtOH would be manifested in peri-adolescent-EtOH-exposed subjects compared to naive subjects when the opportunity to self-administer EtOH to the posterior ventral tegmental area (pVTA) is available in adulthood. The pVTA is a primary site for EtOH’s reinforcing and rewarding properties in the mesolimbic dopamine (DA) system. Experiment 2 was a dose-response examination of the effects of EtOH administered to the pVTA on downstream DA efflux in the nucleus accumbens shell (AcbSh) via a joint Microinjection-Microdialysis (MicroMicro) procedure. Male P rats were given 24-h free-choice exposure to 15% volume/volume EtOH from postnatal day (PD) 30 to PD 60, or remained experimentally naive, with ad lib food and water. By the end of the periadolescent exposure period, average consumption was 7.3 g/kg/day of EtOH. After PD 75, periadolescent-EtOH-exposed and naïve rats were either implanted with an injector guide cannula aimed at the right pVTA for ICSA (Experiment 1), or two cannulae, one aimed at the right pVTA (injector) and one at the ipsilateral AcbSh (microdialysis) for MicroMicro (Experiment 2). Following one week of recovery from surgery, ICSA subjects were placed in standard two-lever (active and inactive) operant chambers. Test sessions were 60 min in duration and occurred every other day for a total of 7 sessions. Rats were randomly assigned to one of 5 groups (n=4-9/group) that self-infused (FR1 schedule) either aCSF (vehicle, 0 mg%), 50, 75, 100, or 150 mg% EtOH during 4 sessions, aCSF only for sessions 5 and 6 (extinction), and the initial concentration again for session 7 (reinstatement). MicroMicro subjects received six days of recovery from surgery, probe implantation the day before testing, and then continuous microdialysis for DA with 15 min microdialysis samples collected before, during, and then two hrs after 10-min pulse microinjection of either aCSF (vehicle, 0 mg%), 50, 75, 100, or 150 mg% EtOH. Neither EtOH-exposed nor naive groups of P rats self-infused the aCSF or 50 mg% EtOH concentration. While the naive group did not self-infuse the 75 or 100 mg% EtOH concentrations, the peri-adolescent EtOH-exposed group of P rats did readily discriminate the active lever from the inactive lever at these concentrations. Both groups self-infused the 150 mg% EtOH concentration. Pulse microinjections of EtOH during the MicroMicro procedure revealed that 75 and 100 mg% concentrations of EtOH increased downstream DA in the AcbSh of EtOH-exposed, but not naïve, subjects. 150 mg% EtOH increased downstream DA in both adolescent treatment groups. Overall, the results indicate that consumption of EtOH by P rats during peri-adolescence increases the reinforcing properties of EtOH in the pVTA in adulthood. The results also indicate that there were differential effects of peri-adolescent EtOH exposure on DA efflux in the AcbSh. This provides evidence that peri-adolescent EtOH-exposure produces long-lasting alterations in neural circuitry involved in EtOH-reinforcement, during adulthood.

Alcohol -- Physiological effect

Alcoholism -- Pathophysiology

Youth -- Alcohol use

Teenagers -- Alcohol use

Neuropsychology

Addiction

Brain microdialysis

Neurotoxicology

Neurotransmitter receptors

Dopamine -- Receptors -- Pathophysiology

Substance abuse -- Etiology

Drinking Rhythms in Alcohol Preferring Mice

Matson, Liana M.

29 August 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Multiple lines of High Alcohol Preferring (HAP) mice were selectively bred for their intake of 10% ethanol (v/v) during 24-h daily access over a four-week period, with the highest drinking lines exhibiting intakes in excess of 20 g/kg/day. Drinking rhythms and corresponding blood ethanol concentrations (BEC) of the highest drinking HAP lines to those of the C57BL/6J (B6) inbred strain. Adult male and female crossed HAP (cHAP), HAP1 and B6 mice had free-choice access to 10% ethanol and water for 3 weeks prior to bi-hourly assessments of intake throughout the dark portion of a reverse 12:12 light dark cycle. In another cohort of cHAP mice, the same procedure was used to assess bi-hourly ethanol intake, and blood samples were taken across the day to look at the pattern of accumulation in these mice. Finally, considering the high level of intake by cHAP mice, we were interested in assessing whether metabolic and functional tolerance develop following chronic free-choice access, which were assessed using 2.0 and 1.75 g/kg challenge doses of 20% ethanol, respectively. cHAP and HAP1 mice maintained an excessive level of intake throughout the dark portion of the cycle, accumulating mean BEC levels of 261.5 + 18.09 and 217.9 + 25.02 mg/dl at 7-8 hours following lights off, respectively. B6 mice drank comparatively modestly, and did not accumulate high BEC levels (53.63 + 8.15 mg/dl). In the cHAP cohort, mean BECs were 112.47 + 19.91 at 2 hours after lights off, 189.00 + 27.40 at 6 hours after lights off, 193.80 + 29.66 at 10 hours after lights off, and 89.68 + 22.19 at 2 hours after lights on. Further, following 3 weeks of ethanol access, cHAP mice had a faster rate of ethanol metabolism and fewer hind slips than water-only exposed mice (ps < .05). In conclusion, the excessive free-choice drinking demonstrated by the HAP1 and cHAP lines, as well as the pattern of sustained high BECs in cHAP mice, challenge the notion that rodents will not reliably and voluntarily sustain ethanol intake at pharmacologically relevant levels. These results suggest that the highest drinking HAP lines may provide a unique opportunity for modeling the excessive intake that has been observed in alcohol-dependent individuals. Further, we observed that cHAP mice develop both metabolic and functional tolerance to the ataxic effects of ethanol following 3 weeks of free-choice access. Together, these findings support HAP mice as translational rodent model of alcoholism, and provide rationale for exploration of the predisposing factors for excessive consumption, as well as the development of physiological, behavioral, and toxicological outcomes following alcohol exposure.

Alcoholism

Rodent Model

Self-administration

Tolerance

Selective Breeding

Alcohol -- Physiological effect

Alcoholism -- Pathophysiology

Substance abuse -- Etiology

Alcoholism -- Animal models

Expectation (Psychology)

Risk-taking (Psychology) -- Testing

Rats -- Genetics

Rats -- Breeding

Neurotoxicology

Rats -- Functional genomics

Ethanol

Developmental differences in hypothermic and behavioral responses to ethanol treatment in Alcohol Preferring and Non-Preferring Rats

Myers, Mallory Lynn

30 August 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Differences in voluntary consumption of ethanol have been negatively correlated with differences in initial sensitivity and tolerance to ethanol’s pharmacological effects. From this perspective, both adolescent and adult alcohol-nonpreferring (NP) rats would be expected to be initially more sensitive to the sedative and hypothermic effects of ethanol and fail to acquire tolerance to those effects than preferring (P) rats. The first objective of this experiment was to assess alcohol-induced hypothermia and locomotor sedation in adolescent and adult P and NP rats over five consecutive daily administrations (saline, 1.5 g/kg, or 3.0 g/kg ethanol 17%v/v), testing the hypothesis that the P rats would acquire tolerance to the hypothermic response whereas the NP rats would not show changes across days. In addition, it was hypothesized that there would be age-related differences in initial sensitivity to ethanol, evident by adolescent rats displaying less ethanol-induced hypothermia and locomotor sedation than adult rats on Day 1. The second objective was to determine if conditioning was occurring between the administration environment and the hypothermic response and locomotor sedation elicited by ethanol exposure, via a sixth injection of saline. Female rats were surgically implanted with intraperitoneal Mini Mitter telemetry probes on postnatal day 25 or 85 and experimental manipulations began five days later. Data were collected every minute; temperature data were then converted to change from baseline scores and locomotor data were totaled for each session. On Day 1, maximum temperature reduction elicited by the 3.0 g/kg dose was greater in the NP rats than the P rats, regardless of age. That dose also produced greater levels of locomotor sedation in the adult rats compared to the adolescent rats, regardless of line. The 1.5 g/kg dose of ethanol produced a greater hypothermic response in adult rats compared to adolescent rats, locomotor activity was reduced equally across the groups. With repeated administrations, NP adult rats displayed sensitization to the hypothermic response elicited from the 3.0 g/kg dose; in contrast, tolerance to the hypothermic response was found within the 1.5 g/kg dose for the adolescent P, adult P, and the adult NP rats. Repeated saline administrations also resulted in tolerance to the hypothermic response associated with administration in the adult NP and adolescent P rats. On the Day 6 saline administrations, adult rats which had previously been exposed to the 3.0 g/kg dose, maintained their baseline body temperatures better than both of the other exposure groups. Adolescent rats failed to show any signs of conditioning when administered saline on Day 6. Contrary to prediction the P rats failed to acquire tolerance to the 3.0 g/kg dose for either measure; and the line difference in ethanol-induce hypothermia was due to sensitization of the hypothermic response in adult NP rats. These results also provide further support that adolescent rats are less sensitive to the initial aversive effects of ethanol at the 1.5 g/kg dose for ethanol-induced hypothermia and the 3.0 g/kg dose for locomotor activity. The current experiment provides evidence that initial sensitivity as well as the acquisition of tolerance to ethanol-induced hypothermia may be behavioral phenotypes correlated with selection for high and low alcohol drinking preference.

P and NP Rats

Adolescent

Tolerance

Sensitization

Ethanol-induced Hypothermia

Rats -- Behavior -- Experiments

Psychobiology

Hypothermia, Induced

Hypothermia -- Age factors

Ethanol

Conditioned response

Behaviorism (Psychology)

Rats -- Functional genomics

Alcohol -- Physiological effect

Adolescent and Adult Two-Bottle Choice Ethanol Drinking and Adult Impulsivity in Genetically Selected High-Alcohol Preferring Mice

O'Tousa, David Scott

20 September 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Abuse of alcohol during adolescence continues to be a problem, and it has been shown that earlier onset of drinking predicts increased alcohol abuse problems later in life. High levels of impulsivity have been demonstrated to be characteristic of alcoholics, and impulsivity has also been shown to predict later alcohol use in teenage subjects, showing that impulsivity may be an inherent underlying biological process that precedes the development of alcohol use disorders. These experiments examined adolescent drinking in a high-drinking, relatively impulsive mouse population, and assessed its effects on adult drinking and adult impulsivity. Experiment 1: Selectively bred High-Alcohol Preferring (HAP II) mice, which are shown to be highly impulsive, were given either alcohol (free choice access) or water only for two weeks during middle adolescence or adulthood. All mice were given free choice access to alcohol following 30 days without access, in adulthood. Experiment 2: Adolescent HAP II mice drank alcohol and water, or water alone, for two weeks, and were then trained to perform a delay discounting task as adults to measure impulsivity. In each experiment, effects of volitional ethanol consumption on later behavior were assessed. We expected adolescent alcohol exposure to increase subsequent drinking and impulsivity. Adolescent mice consumed significant quantities of ethanol, reaching average blood ethanol concentrations (BECs) of 142 mg/dl in Experiment 1 and 108 mg/dl in Experiment 2. Adult mice reached average BECs of 154 mg/dl in Experiment 2. Mice pre-exposed to alcohol in either adolescence or adulthood showed a transient increase in ethanol consumption, but we observed no differences in impulsivity in adult mice as a function of whether mice drank alcohol during adolescence. These findings indicate that HAP II mice drink intoxicating levels of alcohol during both adolescence and adulthood, and that this volitional intake has long-term effects on subsequent drinking behavior. Nonetheless, this profound exposure to alcohol during adolescence does not increase impulsivity in adulthood, indicating that long-term changes in drinking are mediated by mechanisms other than impulsivity. Importantly, this research demonstrates that the HAP II mouse is a good candidate for a model of heavy adolescent alcohol consumption.

alcoholism

impulsivity

adolescence

ethanol

animal model

Animal genetics

Mice -- Behavior

Behavior genetics

Mice -- Genetics

Alcoholism -- Research

Alcohol -- Physiological effect

Impulse

Cognitive neuroscience

Ethanol

Youth -- Alcohol use

Adolescent psychology

Teenagers -- Alcohol use

Effects of Prazosin Treatment on Ethanol- and Sucrose-Seeking and Intake in P Rats

Verplaetse, Terril Lee

20 September 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Background: Previous studies show that prazosin, an α1-adrenergic receptor antagonist, decreases alcohol drinking in animal models of alcohol use and dependence and in alcohol-dependent men. These studies extended previous findings by using a paradigm that allows for separate assessment of prazosin on motivation to seek versus consume ethanol or sucrose in selectively bred rats given acute or chronic prazosin treatment. Methods: Alcohol-preferring P rats were trained to complete an operant response that resulted in access to either 2% (Exp. 1) or 1% (Exp.2) sucrose or 10% ethanol. In Experiment 1, a 4-week consummatory testing phase consisted of rats bar-pressing to “pay” a specified amount up front to gain access to unlimited ethanol (or sucrose) for a 20-minute period. A 4-week appetitive testing phase examined how much the rats would bar-press for ethanol in an extinction session when no reinforcer could be obtained. In Experiment 2, during testing, the response requirement was dropped to a 1 and daily session cycles of drug (3 weeks/ 14 sessions from Tues to Fri) or vehicle (2 weeks/ 9 sessions from Tues to Fri) treatment were alternated per drug dose for a total of 3 drug doses (3 cycles) per rat. After each drug cycle, a single non-reinforced extinction session was conducted with no drug ‘on board’ and no reinforcer access. On test days, rats were given IP injections of either vehicle or one of three doses of prazosin (Exp 1: 0.5, 1.0, 1.5 mg/kg; Exp 2: 0.25, 0.5, 1.0 mg/kg; balanced design; -30 min). Results: In Experiment 1, prazosin significantly decreased ethanol-seeking at all doses tested. The highest dose decreased ethanol intake and increased the latency to first lever-press and first lick. Sucrose-seeking and intake were decreased by the same doses of prazosin. In Experiment 2, prazosin significantly decreased reinforcer-seeking at the lowest and highest doses while ethanol intake was not decreased by prazosin. Conversely, sucrose-seeking was decreased at the highest dose of prazosin tested while sucrose consumption was decreased by all doses. Latency to lever-press for sucrose was increased by the lowest dose of prazosin compared to vehicle. Conclusions: These findings extend previous research and indicate that prazosin decreases motivation to seek ethanol and sucrose. The specificity of prazosin on different behaviors and over different reinforcers suggests that these findings are not due to prazosin-induced motor-impairment or malaise. These data suggest that prazosin may work by decreasing the reinforcing properties of reinforcers in general.

Reinforcement (Psychology)

Rats as laboratory animals

Alcoholism -- Psychological aspects

Alpha adrenoceptors

Substance abuse -- Etiology

Ethanol

Prazosin

Operant behavior

Operant conditioning

G proteins -- Receptors

Alcoholism -- Molecular aspects

Alcoholism -- Treatment

Achieving pharmacologically relevant IV alcohol self-administration in the rat

Windisch, Kyle Allyson

27 September 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Alcohol consumption produces a complex array of effects that can be divided into two types: the explicit pharmacological effects of ethanol (which can be quite separate temporally from time of intake) and the more temporally “relevant” effects (primarily olfactory and taste) that bridge the time from intake to the onset of the pharmacological effects. Dissociating these effects is essential to untangling the neurologic underpinnings of alcohol abuse and dependence. Intravenous self-administration of ethanol allows for controlled and precise dosing, bypasses first order absorption kinetics allowing for a faster onset of pharmacologic effects, and eliminates the confounding “non-pharmacological” effects associated with oral consumption. Intravenous self-administration of ethanol has been reliably demonstrated in both mouse and human experimental models; however, consistent intravenous self-administration of pharmacologically relevant levels of ethanol remains elusive in the rat. Previous work has demonstrated reliable elevated intravenous ethanol self administration using a compound reinforcer of oral sucrose and intravenous ethanol. The present study sought to elucidate the role of each component of this reinforcer complex using a multiple schedule study design. Male P rats had free access to both food and water during all intravenous self-administration sessions and all testing was performed in conjunction with the onset of the dark cycle. Once animals achieved stable operant responding on both levers for an orally delivered 1% sucrose solution (1S) on a FR4 schedule, surgery was conducted to implant an indwelling jugular catheter. Animals were habituated to the attachment of infusion apparatus and received twice daily sessions for four days to condition each lever to its associated schedule. Animals were then trained to respond on a multiple FR4-FR4 schedule composed of alternating 2.5 minute components. During one component only oral 1S was presented, while in the second component a compound reinforcer of oral 1S + IV 20% ethanol was presented (25 mg/kg/injection). Both levers were extended into the chamber during the session, with the active lever/schedule alternating as the session progressed across components. Average ethanol intake was 0.47 ± 0.04 g/kg. A significant increase in sucrose only reinforcers and sucrose lever error responding was found suggesting that sucrose not ethanol is responsible for driving overall responding. The current findings suggest that the existing intravenous ethanol self-administration methodology remains aversive in the rat.

Neurotoxicology

Rats as laboratory animals

Cognition in animals

Alcoholism -- Research

Ethanol

Alcoholism -- Animal models

Expectation (Psychology)

Pharmacogenomics

Operant behavior

Substance abuse -- Etiology

Drinking of alcoholic beverages

Reinforcement (Psychology)

Sucrose

Rats -- Behavior

Kinetic Analysis of Primate and Ancestral Alcohol Dehydrogenases

Myers, Candace R.

29 November 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Seven human alcohol dehydrogenase genes (which encode the primary enzymes involved in alcohol metabolism) are grouped into classes based on function and sequence identity. While the Class I ADH isoenzymes contribute significantly to ethanol metabolism in the liver, Class IV ADH isoenzymes are involved in the first-pass metabolism of ethanol. It has been suggested that the ability to efficiently oxidize ethanol occurred late in primate evolution. Kinetic data obtained from the Class I ADH isoenzymes of marmoset and brown lemur, in addition to data from resurrected ancestral human Class IV ADH isoenzymes, supports this proposal--suggesting that two major events which occurred during primate evolution resulted in major adaptations toward ethanol metabolism. First, while human Class IV ADH first appeared 520 million years ago, a major adaptation to ethanol occurred very recently (approximately 15 million years ago); which was caused by a single amino acid change (A294V). This change increases the catalytic efficiency of the human Class IV enzymes toward ethanol by over 79-fold. Secondly, the Class I ADH form developed 80 million years ago--when angiosperms first began to produce fleshy fruits whose sugars are fermented to ethanol by yeasts. This was followed by the duplication and divergence of distinct Class I ADH isoforms--which occurred during mammalian radiation. This duplication event was followed by a second duplication/divergence event which occurred around or just before the emergence of prosimians (some 40 million years ago). We examined the multiple Class I isoforms from species with distinct dietary preferences (lemur and marmoset) in an effort to correlate diets rich in fermentable fruits with increased catalytic capacity toward ethanol oxidation. Our kinetic data support this hypothesis in that the species with a high content of fermentable fruit in its diet possess greater catalytic capacity toward ethanol.

Alcohol -- Physiological effect

Alcoholism -- Nutritional aspects

Cell metabolism

Ethanol -- Metabolism

Alcohol dehydrogenase -- Analysis

Alcohol dehydrogenase -- Regulation

Isoenzymes

Human evolution

Primates -- Genetics

Enzymes

Catalysis

Nutrition

Liver -- Metabolism

Drug-nutrient interactions

Brown lemur -- Behavior

Marmosets -- Behavior

Molecular and Cellular Mechanisms Leading to Similar Phenotypes in Down and Fetal Alcohol Syndromes

Solzak, Jeffrey Peter

22 August 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Down syndrome (DS) and Fetal Alcohol Syndrome (FAS) are two leading causes of birth defects with phenotypes ranging from cognitive impairment to craniofacial abnormalities. While DS originates from the trisomy of human chromosome 21 and FAS from prenatal alcohol consumption, many of the defining characteristics for these two disorders are stunningly similar. A survey of the literature revealed over 20 similar craniofacial and structural deficits in both human and mouse models of DS and FAS. We hypothesized that the similar phenotypes observed are caused by disruptions in common molecular or cellular pathways during development. To test our hypothesis, we examined morphometric, genetic, and cellular phenotypes during development of our DS and FAS mouse models at embryonic days 9.5-10.5. Our preliminary evidence indicates that during early development, dysregulation of Dyrk1a and Rcan1, cardinal genes affecting craniofacial and neurological precursors of DS, are also dysregulated in embryonic FAS models. Furthermore, Caspase 3 was also found to have similar expression in DS and FAS craniofacial neural crest derived tissues such as the first branchial arch (BA1) and regions of the brain. This may explain a developmental deficit by means of apoptosis. We have also investigated the expression of pAkt, a protein shown to be affected in FAS models, in cells located within the craniofacial precursor of Ts65Dn. Recent research shows that Ttc3, a gene that is triplicated and shown to be overexpressed in the BA1 and neural tube of Ts65Dn, targets pAkt in the nucleus affecting important transcription factors regulating cell cycle and cell survival. While Akt has been shown to play a role in neuronal development, we hypothesize that it also affects similar cellular properties in craniofacial precursors during development. By comparing common genotypes and phenotypes of DS and FAS we may provide common mechanisms to target for potential treatments of both disorders. One of the least understood phenotypes of DS is their deficient immune system. Many individuals with DS have varying serious illnesses ranging from coeliac disease to respiratory infections that are a direct result of this immunodeficiency. Proteasomes are an integral part of a competent and efficient immune system. It has been observed that mice lacking immunoproteasomes present deficiencies in providing MHC class I peptides, proteins essential in identifying infections. A gene, Psmg1 (Dscr2), triplicated in both humans and in Ts65Dn mice, is known to act as a proteasome assembly chaperone for the 20S proteasome. We hypothesized that a dysregulation in this gene promotes a proteasome assembly aberration, impacting the efficiency of the DS immune system. To test this hypothesis we performed western blot analysis on specific precursor and processed β-subunits of the 20S proteasome in thymic tissue of adult Ts65Dn. While the β-subunits tested displayed no significant differences between trisomic and euploid mice we have provided further insight to the origins of immunodeficiency in DS.

Down Syndrome

Fetal Alcohol Syndrome

Caspase 3

Dyrk1a

Rcan1

Akt

Fetal alcohol syndrome -- Research

Down syndrome -- Research

Fetal alcohol syndrome -- Animal models

Phenotype -- Research

Cognition disorders

Dual specificity phosphatase 1

Apoptosis

Transcription factors

Immunodeficiency

Dysostosis

Alcohol -- Physiological effect

Developmental neurophysiology

Increased delay discounting tracks with later ethanol seeking but not consumption

Beckwith, Steven Wesley

31 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Assessments of delay discounting in rodent lines bidirectionally selected for home cage intake and preference of alcohol have had mixed findings. The current study sought to examine if delay discounting related differentially to alcohol seeking versus and alcohol drinking, two processes underlying alcohol intake and preference. Three strains of rats were utilized to answer this question Long Evans (LE), high alcohol drinking rats (HAD2), and alcohol preferring P rats. All strains were compared in an adjusting amount delay discounting task. Operant self-administration of alcohol was then assessed in the sipper tube model, and finally home cage drinking was assessed in a 24 hour 2 bottle choice paradigm. In the delay discounting it was found that the P rats were steeper discounters than both the LE and HAD2. In the sipper tube model, P rats displayed higher levels of seeking than both the HAD2s and the LE, but both the P rats and the HAD2s had higher intakes than the LE. During 24 hour home cage access, the P rats and the HAD2s had higher intake and preference for alcohol than the LE, but were not different from each other. These results show that increased discounting of delayed rewards tracks with appetitive processes versus consummatory factors and home cage intake of alcohol. This builds on prior findings using selected line pairs by providing an explanation for discordant results, and supports the hypotheses that increased delay discounting is an intermediate phenotype that predisposes individuals to alcohol use disorders.

Alcohol Seeking

Delay Discounting

Impulsivity

Delay discounting (Psychology)

Control (Psychology)

Rodents -- Behavior -- Experiments

Ethanol

Rodents -- Research

Impulse

Self-control

Choice (Psychology)

Reinforcement (Psychology)

Rodents -- Decision making

Rats -- Effects of drugs on

Rats -- Psychology

Psychobiology

Rodents -- Physiology

Rats as laboratory animals -- Research

Does binge drinking induce PMDD-like dysfunction for female C57BL/6J mice? : implications for sex differences in addiction vulnerability

Melón, Laverne C.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / It has traditionally been posited that women show a "telescoped" development of alcohol use disorders (Kuhn, 2011). In particular, a number of clinical studies support striking sex differences in the progression from initial use of alcohol to dependence on the compound; with women showing a faster progression through landmark events associated with the development of alcohol addiction (Randall et al., 1999). However, recent studies have challenged this tenet (Keyes et al., 2010). The work presented herein was designed to determine whether females are indeed more vulnerable to the development of behavioral maladaptations following binge drinking and whether sex differences in GABA(A) receptor regulation might underlie this vulnerability. Using a mouse model of binge drinking this dissertation established that, compared to males, females escalate their binge drinking at a faster rate and maintain altered responsivity to the locomotor effects of alcohol after extended abstinence from binge drinking. Female mice also displayed significant increases in ethanol preference and intake in a continuous, two-bottle choice protocol following a shorter history of binge drinking than males. The final goal was to determine if binge drinking results in unique patterns of anxiety- or depressive-like symptoms in males and females and whether these behaviors would be associated with the dimorphic regulation of GABAA receptor subunits across the prefrontal cortex and hippocampus. Male binge drinkers displayed anxiety-like behavior during early withdrawal that dissipated after 2 weeks of abstinence. There were no significant changes in the expression of delta or gamma2 GABAA receptor subunit mRNA at this time point in the regions analyzed. Females also showed temporary anxiety-like behavior during early withdrawal from binge drinking. Additionally, females displayed significant depressive-like behavior after 2 weeks of abstinence from binge drinking. In particular, diestrus-phase females displayed significantly greater immobility in the forced-swim test after ethanol exposure and no longer maintained the reduced swim-time behavior associated with this phase of the cycle at baseline (when compared to the estrus-phase). qPCR analysis of hippocampal tissues from diestrus females supported a significant reduction in expression of gamma2 GABA(A) subunit mRNA after binge drinking. This effect was not noted for RNA isolated from hippocampal tissues taken during the estrus phase of bingers. These final data suggest possible interaction of estrous-cycle and binge drinking history that may result in the unique expression of deficits following binge drinking for females. Taken together, this work supports sex and estrous dependent effects of binge drinking on behavior and gene regulation.

Substance abuse -- Sex differences

Alcoholism -- Pathophysiology

Alcohol -- Physiological effect

GABA -- Receptors -- Research

Ethanol -- Physiological effect

Depression, Mental -- Animal models

Anxiety disorders -- Animal models

Mice -- Physiology

Animal models in research