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

Characterization of Behavioral Profiles for Inbred P and NP and Congenic P.NP and NP.P Rats

Jensen, Meredith

27 August 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Alcoholism inheritance rates have been estimated as high as 60% in a human population. Many significant features of alcohol dependence have been replicated in rodent animal models of alcoholism, however not in totality. These animal models include inbred preferring (iP) and nonpreferring (iNP) rat types. Congenic rats have been engineered from the iP and iNP strains whereby a P congenic rat has in its genome a well-chosen chromosomal portion taken from an NP rat (P.NP) and, reciprocally, an NP congenic rat has acquired the analogous DNA from a P rat (NP.P). In this case, a quantitative trait locus (QTL) from chromosome 4 is the donor genetic material for the congenic rats. It is of great interest to further study this chromosome 4 QTL because it has been found to control a significant portion of ethanol consumption behavior in iP and iNP rats. This study aimed to behaviorally profile the iP, iNP and reciprocal congenic rats. As a result of the behavioral profiling of these genetically related groups, some conclusions could be made regarding which behaviors appear to be controlled by the chromosome 4 donor DNA.This study primarily utilized the Multivariate Concentric Square Field apparatus (MCSF) to characterize behavioral profiles for the inbred and congenic rats. The Open field (OF) and Elevated plus maze (EPM) supported this effort. The MCSF is valuable in that it allows for the animals to interact within an environment that has ethological value. The 12 different zones that make up the field are characterized by some functional quality in terms of type and duration of behavior performed, etc. The behavioral data is aggregated and finally represented in terms of five functional categories, the elements of the behavioral profile: general activity, exploratory activity, risk assessment, risk taking, and shelter seeking. The study hypotheses were shaped by prior research suggesting that iPs should display lower general activity and risk taking strategy than iNPs in the MCSF. Inbred Ps should be more active in the OF and spend more time in the center of the EPM. Generally, it is expected that the iP QTL confer behavioral phenotypes to the iNP strain that deviate toward a "P" behavioral phenotype and reciprocally, the iNP QTL confer behavioral phenotypes to the iP strain that deviate toward an "NP" behavioral phenotype. The results showed that iP rats performed more risk assessment and risk taking behavior and less shelter seeking and anxiety-like behavior than iNP rats. It followed that P.NP congenic rats significantly downgraded their risk assessment and risk taking behavior when compared to iP rats. This decrease can be attributed to the chromosome 4 QTL donated from the iNP breed. All together this study concludes that risk assessment and risk taking behavior in the iP rats is controlled by the same DNA region that, in part, determines voluntary intake of ethanol consumption. Further fine mapping of the QTL region should help in discovering if the same DNA sequences that influence ethanol intake also significantly influence risk behavior.

Congenic rats

Preferring rats

Nonpreferring rats

Alcohol

Multivariate concentric square field

Open field

Elevated plus maze

Alcoholism -- Genetic aspects

Neuropsychology

Neurotoxicology

Rats -- Functional genomics

Rats as laboratory animals

Genomics

Reinforcement (Psychology)

Risk-taking (Psychology) -- Testing

Risk assessment

Cognition in animals

Animal behavior

Rats -- Genetics