A major QTL for acute ethanol sensitivity in the alcohol tolerant and non-tolerant selected rat lines.

The Alcohol Tolerant and Alcohol Non-Tolerant rats (AT, ANT) were selectively bred for ethanol-induced ataxia as measured on the inclined plane. Here we report on a quantitative trait locus (QTL) study in an F(2) intercross population derived from inbred AT and ANT (IAT, IANT) and a follow-up study of congenics that were bred to examine one of the mapped QTLs. Over 1200 F(2) offspring were tested for inclined plane sensitivity, acute tolerance on the inclined plane, duration of the loss of righting reflex (LORR) and blood ethanol at regain of the righting reflex (BECRR). F(2) rats that were in the upper and lower 20% for inclined plane sensitivity were genotyped with 78 SSLP markers. Significant QTLs for inclined plane sensitivity were mapped on chromosomes 8 and 20; suggestive QTLs were mapped on chromosomes 1, 2 and 3. Highly significant QTLs for LORR duration (LOD = 12.4) and BECRR (LOD = 5.7) were mapped to the same locus on chromosome 1. Breeding and testing of reciprocal congenic lines confirmed the chromosome 1 LORR/BECRR QTL. A series of recombinant congenic sub-lines were bred to fine-map this QTL. Current results have narrowed the QTL to an interval of between 5 and 20 Mb. We expect to be able to narrow the interval to less than 5 Mb with additional genotyping and continued breeding of recombinant sub-congenic lines.

Neurotensin levels in specific brain regions and hypnotic sensitivity to ethanol and pentobarbital as a function of time after haloperidol administration in selectively bred rat lines.

Evidence indicates that sensitivity to ethanol is a good predictor of the development of alcoholism. Thus, identification of neuronal processes that regulate ethanol sensitivity has been the subject of much recent research. The present studies were designed to further test the hypothesis that neurotensinergic processes mediate, in part, hypnotic sensitivity to ethanol. Single doses of haloperidol were administered to lines of rats [selectively bred for high and low sensitivity (HAS and LAS, respectively) to hypnotic effects of ethanol] to produce increases in neurotensin (NT) levels in brain regions. At 20 h after administration, haloperidol produced dose-dependent increases in NT immunoreactivity levels in nucleus accumbens (NA) and caudate putamen (CP) in both HAS and LAS lines. Levels of NT in NA and CP returned to control values at 48 h after 4 mg/kg haloperidol. These studies used two measures of hypnotic sensitivity to ethanol: duration of loss of righting reflex (sleep time) and blood ethanol concentration at regain of righting reflex (BECRR). At 20 h, but not 48 h, after haloperidol treatment, both HAS and LAS rats displayed increases in ethanol-induced sleep time with concomitant decreases in BECRR. Pentobarbital-induced sleep time was not increased 20 h after administration of 4 mg/kg haloperidol; however, hypnotic sensitivity to both pentobarbital and ethanol was increased by acute (30-min) pretreatment with 1 mg/kg. These results suggest that NT levels in NA, acting via NT receptors, enhance hypnotic sensitivity to ethanol, but not pentobarbital.

Sensitivity and tolerance to ethanol-induced incoordination and hypothermia in HAFT and LAFT mice.

Acute functional tolerance (AFT) manifests as rapid adaptation during a single ethanol exposure, leading to a decrease in the behavioral response to ethanol. In order to investigate the genetic and environmental components of the development of AFT, mice were selectively bred in replicate from HS/Ibg mice. High (HAFT) and low (LAFT) acute functional tolerance selected lines were bred to differ in the rate of development and magnitude of AFT to ethanol's intoxicating effects using a static dowel-balancing task. In the present set of experiments, HAFT and LAFT mice were tested for development of AFT on a fixed-speed rotarod using a protocol similar to that for which they were selected. HAFT mice developed greater AFT to ethanol than did LAFT mice. In a separate experiment, other mice from these lines were tested for initial sensitivity and the development of chronic tolerance to ethanol-induced hypothermia, and ethanol-induced incoordination in the grid test. Previous research has detected possible common genetic control of these phenotypes. No differences between lines were found in initial sensitivity to ethanol or in the development or magnitude of chronic tolerance in either test. These experiments show that genetic factors influencing the development of acute tolerance to ethanol-induced intoxication are at least partially distinct from those influencing initial sensitivity and the development of chronic tolerance to ethanol-induced hypothermia and incoordination. Furthermore, these experiments show that AFT measured by the stationary dowel generalizes to AFT measured by the fixed-speed rotarod.

Confirmation of correlations and common quantitative trait loci between neurotensin receptor density and hypnotic sensitivity to ethanol.

BACKGROUND: In previous studies, genetic correlations were observed between hypnotic sensitivity to ethanol and high-affinity neurotensin receptor (NTS1) binding. Provisional quantitative trait loci (QTLs) were identified for these traits, and some of these QTLs were found on common chromosomal regions. In continued efforts to examine the relationship between NTS1 binding capacity and hypnotic sensitivity to ethanol, studies were designed to confirm correlations between NTS1 densities in the brain, duration of ethanol-induced loss of righting reflex (LORR), and blood ethanol concentrations at regain of righting reflex (BECRR). Another purpose of the study was to confirm QTLs for these traits. METHODS: ILS X ISS F2 mice and HAS X LAS F2 rats as well as the progenitors were tested for LORR, BECRR, and NTS1 densities. Phenotypic correlations were calculated between LORR and BECRR and between these measures and NTS1 densities in striatum from both mice and rats. The F2 mice were genotyped by using polymorphic markers for five previously reported QTLs for LORR to confirm QTLs for BECRR and NTS1 densities in striatum, ventral midbrain, and frontal cortex. RESULTS: Phenotypic correlations were found between LORR and BECRR (r = -0.66 to -0.74, p < 10(-9)) and between these measures and NTS1 densities in striatum (r = 0.28-0.38, p < 10(-2)) from both mice and rats. QTLs for LORR and BECRR (lod score = 2-6) were found in common regions of chromosomes 1, 2, and 15. By using the combined results from a previous LSXSS RI study and the current results, a suggestive QTL (lod score = 3.1) for striatal NTS1 receptor densities was found on chromosome 15 at approximately 60 cM, in the same region as the chromosome 15 LORR/BECRR QTL. CONCLUSIONS: The results are in agreement with previously reported correlations and QTLs for NTS1 receptor densities and measures of hypnotic sensitivity to ethanol in mice and extend those correlations to another species, the rat. These findings support a role for NTS1 in genetically mediated differences in hypnotic sensitivity to ethanol.

The genetics of acute functional tolerance and initial sensitivity to ethanol for an ataxia test in the LSxSS RI strains.

BACKGROUND: It has been proposed that development of tolerance to the behavioral effects of ethanol depends on the degree of impairment produced by the drug; that is, more sensitive individuals should develop greater tolerance. Tests of this hypothesis with respect to acute functional tolerance have produced contradictory results. We tested the hypothesis by examining the genetic relationship between initial sensitivity and acute functional tolerance in the LSXSS recombinant inbred mice. METHODS: We tested mice for initial sensitivity to the ataxic effects of 1.75 g/kg of ethanol in a stationary dowel balance test by determining blood and brain ethanol concentrations at fall. Acute tolerance to the ataxic effects of ethanol was determined by measuring blood ethanol concentration (BEC) at regain of dowel balance ability after the first injection (BEC1RB) and after a second ethanol injection of 2.0 g/kg (BEC2RB). Acute tolerance was quantified by the difference in ethanol concentration at the two regains of balance (BEC2RB - BEC1RB) or by the difference between the second regain and one of the initial sensitivity measures (BEC2RB - initial sensitivity). RESULTS: Four different measures of initial sensitivity were taken: two that used BEC values and two that used forebrain or hindbrain ethanol concentrations. We calculated acute tolerance values by using each of these initial sensitivity measures plus BEC2RB. No evidence of a genetic relationship between initial sensitivity and acute tolerance was found, which suggests that these are two independent phenomena with respect to stationary dowel balance. CONCLUSIONS: Three conclusions can be drawn from this work: (1) Orbital sinus BEC at early time points (<5 min postinjection) may or may not accurately reflect brain EC in mice, dependent on genotype; (2) there is no genetic relationship between initial sensitivity and acute tolerance to stationary dowel ataxia in the LSXSS RIs; and (3) sex-specific factors affect low-dose ethanol responses on the stationary dowel.

Phenotypic and genotypic relationships between ethanol tolerance and sensitivity in mice selectively bred for initial sensitivity to ethanol (SS and LS) or development of acute tolerance (HAFT and LAFT).

BACKGROUND: Genetically based risk for development of alcoholism in humans seems to be related to initial sensitivity and/or acute tolerance to ethanol. The genetic basis for the development of tolerance has received less attention than other ethanol-related behaviors. We have selected lines of mice, according to genetics, which are differentially sensitive to the initial hypnotic effect of ethanol (Short Sleep and Long Sleep, SS and LS) and other lines that differentially develop acute functional tolerance to ethanol (High and Low Acute Functional Tolerance, HAFT and LAFT). We review reports of the relationship between initial sensitivity and two forms of tolerance as measured using different behavioral measures and different time scales. The goal of the study was to investigate alcohol tolerance as measured by different behavioral tests conducted over different time periods and relate these variables to hypnotic sensitivity. METHODS: We investigated the phenotypic and genotypic relationships between different measures of tolerance to ethanol in the SS and LS mice. We used two measures of tolerance: (a) The time an animal can remain on a stationary dowel or roto-rod at 5-min intervals up to 30 minutes after a single low dose of ethanol (Acute Single Dose Tolerance, ASDT-dowel or ASDT-roto-rod); and (b) The difference in blood ethanol levels taken when a mouse could repeatedly regain balance on a stationary dowel or roto-rod after successive doses of ethanol (Acute Functional tolerance, AFT-dowel or AFT-roto-rod). The time course in AFT was much longer, up to 2 hours. We carried out the same studies on the High and Low Acute Functional Tolerance (HAFT and LAFT) mice. RESULTS: SS and LS mice differ in hypnotic sensitivity as measured by sleep time, and they differ in all forms of acute tolerance that were measured except in AFT-dowel. Although there were phenotypic correlations between AFT-dowel and ASDT-roto-rod in the Heterogeneous Stock (HS) of mice, provisional Quantitative Trait Loci (determined with Recombinant Inbred mice from a SS X LS cross) for the two phenotypes did not overlap, which indicated that there was little or no genetic correlation between the measures. HAFT and LAFT mice do not differ in hypnotic sensitivity as measured by sleep time measurements nor in ataxic sensitivity as measured on the dowel. The HAFT and LAFT mice both developed tolerance when tested in the 30-minute time frame, but the differences between the lines was largely in the rate of development of tolerance and not the amount developed. On the other hand, when tolerance was measured over 2 hr on the dowel or roto-rod, the HAFT and LAFT animals developed different levels of tolerance. CONCLUSIONS: We concluded that measures of tolerance depended on both the time of ethanol's action and the behavioral task used. It seemed that the measures of tolerance used in this study had different genetic bases in mice. Presumably, tolerance will also vary in humans depending on the behavioral measure, and tolerance will also have different genetic bases for the different behavioral measures in humans.

Selectively bred lines of mice show response and drug specificity for genetic regulation of acute functional tolerance to ethanol and pentobarbital.

Genetic regulation of acute tolerance to ethanol may be associated with ethanol consumption and other ethanol-related behaviors in rodents. We have used lines of mice, selectively bred for high and low acute functional tolerance (HAFT and LAFT, respectively) to ethanol-induced loss of balance to test this hypothesis. Replicate HAFT and LAFT lines differ in AFT to ethanol-induced loss of balance by 4.4- and 5-fold, respectively. Frequency distributions and mean AFT scores for those lines, F(1), and backcrosses show a dominance for the HAFT phenotype. Time courses for acquisition and decay showed that AFT to ethanol-induced loss of balance developed rapidly, could be maintained up to 6 h with repeated doses, and decayed 6 h after peak tolerance and discontinuance of ethanol administration. The lines did not differ in initial sensitivity as measured by brain ethanol concentration at loss of balance, indicating that initial sensitivity and AFT to loss of balance were not coselected traits. Surprisingly, HAFT versus LAFT lines did not differ in development of AFT to loss of righting response, or hypothermia, indicating different mechanisms or neuronal systems mediate genetic influences on these measures. Voluntary ethanol consumption was low in both of the replicate lines, but HAFT lines consumed greater amounts of ethanol than LAFT lines. The HAFT and LAFT lines developed AFT to pentobarbital-induced loss of balance, however, there were no line differences in rates or extent of the AFT development. These results show that genetic regulation of AFT development is drug- as well as response-specific.

Quantitative-trait loci analysis of cocaine-related behaviours and neurochemistry.

We recently conducted a dose-response study of the effects of cocaine on several activity measures in the panel of BxD/Ty recombinant inbred mice. Animals were tested in an automated activity chamber over 2 days with i.p. saline on day 1 and i.p. cocaine on day 2, at one of four doses, 5, 15, 30 or 45 mg kg(-1). The monitor recorded total distance traveled, nosepokes in a holeboard, repeated movements and time spent by an individual in proximity to the centre of the apparatus. Dose-response curves for locomotor activation, i.e. the difference between cocaine and saline scores, showed that for all strains tested, scores increased 5-30 mg kg(-1). With few exceptions, locomotor activity at 45 mg kg(-1) was not significantly higher than that at 30 mg kg(-1). Repeated movement scores showed patterns similar to locomotor activity and nosepokes tended to be progressively inhibited by increasing doses of cocaine. Recombinant inbred strain mean distributions for all behaviours and at all doses exhibited continuous, rather than discrete variation, thus providing evidence of multiple-gene effects on cocaine-related behaviours. Quantitative trait loci (QTL) analysis pointed to several chromosomal locations associated with variations in cocaine-related behaviours and some are either identical or close to QTL reported by others. In separate groups of animals, densities of dopamine D1, and D2 receptors and dopamine uptake transporters were measured in the medial prefrontal cortex, caudate-putamen, nucleus accumbens and ventral midbrain. In all areas, all measures showed distributions consistent with polygenic influence and were associated with QTL. Of particular interest was our finding of a large segment on chromosome 15, which is related to dopamine receptor densities and cocaine-related behaviours.

Identification and confirmation of quantitative trait loci regulating alcohol consumption in congenic strains of mice.

BACKGROUND: C57BL/6 inbred mice prefer alcohol whereas DBA/2 mice avoid it. We describe the construction of congenic strains of mice in which DBA/2 alleles for alcohol avoidance were placed on a C57BL/6 background using phenotypic selection. METHODS: Mice were primed to drink 10% v/v ethanol in water for 2 days before a two-bottle choice paradigm. N2 males who demonstrated an alcohol-avoidance phenotype were backcrossed to B6 females to construct 15 independent lines. RESULTS: Eight of these lines were lost due to failure to breed or absence of males with an alcohol-avoidance phenotype. The remaining sublines were split to form a total of 21 sublines. In the N7 and N9 generations, a genome scan located provisional quantitative trait loci (QTLs) on chromosomes 1, 2, 3, 6, and 9. Progeny testing confirmed QTLs on chromosomes 1 and 2. CONCLUSIONS: The QTL on chromosome 2 overlaps the 95% confidence interval of Alcp1 whereas that on chromosome 1 is new and has been called Alcp5. Marker-assisted selection was used in the N9 and subsequent generations to maintain the congenic lines and produce congenic strains.

Allele dose analysis in recombinant inbred strains: a tool for multiple phenotype analysis with implications for quantitative trait loci mapping.

A considerable investment in genetic mapping is necessary to confirm linkages of quantitative trait loci for complex traits such as ethanol sensitivity, a significant predictor of alcoholism. Before embarking on such intensive mapping efforts in large intercrosses, we suggest an approach based on genetic marker data in recombinant strains that yield a rationale for selecting a battery of related phenotypes for confirmation studies of quantitative trait loci action. Using this approach with selected strains of mice, we retrospectively consider the relationship between ethanol sensitivity and neurotensin levels in several mammalian brain regions.

Acute functional tolerance to ethanol and fear conditioning are genetically correlated in mice.

It has been speculated that tolerance to alcohol involves some form of neuronal plasticity that is similar to or the same as that mediating learning and memory. To investigate this possibility further, we tested the hypothesis that acute functional tolerance (AFT) to alcohol is genetically correlated to a Pavlovian learning task: fear conditioning. Mice selectively bred for differences in ability to acquire AFT were tested for fear conditioning. Subjects received a mild footshock paired to a broadband clicker and were tested 24 hr later for their freezing response to the conditioning chamber (context), to an altered chamber, and to the clicker. Both the original and replicate lines selected for high AFT (HAFT) were found to freeze significantly more than those selected for low AFT (LAFT) in response to the context and to the clicker. In a second experiment, an F2 population derived from the C57BL/6 (B6) and DBA/2 (D2) mouse strains were tested first for fear conditioning, followed 3 weeks later by AFT testing. AFT was defined as the difference between blood alcohol levels determined at the time of regain balance on a dowel rod first after 1.75 g/kg of ethanol and again after a subsequent dose of 2.0 g/kg. Consistent with results from HAFT and LAFT, freezing to context was found to be significantly positively correlated to AFT (r = 0.38, p = 0.04) in the F2 mice. The results suggest that co-variation in fear conditioning and AFT may be mediated by one or more of the same or at least tightly linked genes. Further dissection of this correlation may reveal neuronal mechanisms common to both AFT and fear conditioning.

Genetic relationship between central beta-endorphin and novelty-induced locomotor activity.

The goal of research presented in this report was to investigate the possibility that differences in beta-ED levels could account for some portion of genetically mediated variation in locomotor activity. Subjects representing six of the LSXSS RI mouse strains were activity tested in a novel environment. Significant effects of strain and time as well as a significant strain by time interaction were detected. Beta-ED levels were estimated from several brain regions and the pituitary of naive and activity-tested mice. Significant strain effects were detected in all brain regions but not in the pituitary. There was no overall effect of exposure to novelty, but some strains showed either a decrease or an increase in beta-ED levels in the septum, amygdala, and midbrain. A significant genetic correlation between adaptation to the novel environment (locomotor activity at 30 min subtracted from locomotor activity at 5 min) and beta-ED levels in the septum was observed. Estimates of hypothalamic mRNA for the beta-ED precursor POMC revealed no effect of strain. Finally, locomotor activity was tested following doses of the mu-opioid antagonist naltrexone. Out of six strains tested (naive to the apparatus), naltrexone dose dependently attenuated locomotor activity in only the strain that showed the highest control level of activity. The results suggest that beta-ED levels influence novelty-induced locomotor activity, but that other important genotype-dependent factors are involved.

Discovery of a new Pomc1 allele in the LS x SS recombinant inbred strains: relationship to locomotor behavior.

Various lines of evidence suggest that a polymorphism in the gene for proopiomelanocortin, Pomc1, might account for some portion of the genetic variance for open-field activity in the LS x SS RI strains. To test this hypothesis, approximately 1600 bp of Pomc1 was sequenced from genomic DNA of seven of the LS x SS strains. Two distinct alleles containing a total of five single-base pair differences were detected. A substitution was found in the coding region causing a Pro-to-Ser conversion, two substitutions occurred in the 3' untranslated region of the mRNA, and a substitution and a deletion were detected in the 3' untranscribed flanking region. The fragment containing the coding region substitution was sequenced in an additional 15 of the LS x SS strains. A total of 12 strains contained one form of the allele, while 10 had the other. The strain distribution pattern of open-field activity scores between the two allels suggests that these alleles do not contribute to the genetic variation of open-field activity in the LS x SS RI strains.

Mapping of provisional quantitative trait loci influencing temporal variation in locomotor activity in the LS x SS recombinant inbred strains.

The finding that stress-induced locomotor activity exhibited a significant strain x time interaction in the LS x SS RI strains prompted examination of QTL influencing this behavior as a function of time. The degree of genetic determination for locomotor activity was 0.26 for the first 5 min and decreased to 0.16 for the last 5 min of a 30-min test but the number of genetic factors stayed relatively constant (three or four) across time. A QTL point analysis revealed a total of 15 QTL, 5-8 per 5-min time block. Few of the QTL were detected across all time points and different combinations of QTL were evident for each time period. Five of the QTL were in common with those reported by other investigators for similar behaviors. The results suggest that locomotor behavior is under a greater degree of genetic control during the initial part of the test but environmental factors become increasingly important as the test progresses. Furthermore, different genetic factors appear to be mediating genetic variation in locomotor behavior at any given time point.

Common quantitative trait loci for alcohol-related behaviors and CNS neurotensin measures: voluntary ethanol consumption.

The C57BL/6, DBA/2, and recombinant inbred (RI) strains derived from them (BxD RIs) are the most frequently studied mouse strains with regard to genetic regulation of voluntary ethanol consumption (YEC). We have studied VEC in an alternate genetic model provided by the LSxSS RIs. These RI strains exhibit phenotypic extremes in VEC comparable to the C57BL/6 and DBA/2 mice and genotype-dependent sex differences in drinking behavior. A correlational analysis between various ethanol-related behaviors suggests genetic independence of VEC from high-dose neurosensitivity (sleep time), acute ethanol tolerance, hypothermia, and low-dose locomotor activity. A search for quantitative trait loci identified a number of putative quantitative trait loci (QTL), three of which are identical to those previously reported for 10% ethanol drinking in the BxD RIs. We also find a significant correlation between low-affinity neurotensin receptor densities (NTRL) in the frontal cortex and VEC, and more common QTL between these two phenotypes than expected by chance. This suggests a role for frontal cortex NTRL in regulating voluntary ethanol intake.

Ethanol modulates cocaine-induced behavioral change in inbred mice.

We recently conducted a study of the behavioral effects of combined cocaine and ethanol in genetically defined mice. Male and female C57BL/6 (B6) and DBA/2 (D2) were tested in an automated activity monitor on 2 consecutive days. On day 1, all animals received an IP injection of sterile saline and were placed into the activity monitor for 30 min. Behaviors measured were total distance traveled, stereotypy, nosepokes, and wall-seeking. On day 2, all animals were tested again for 15 min following injection of one of the following: saline, 10% v/v ethanol at 2.0 g kg(-1) or 2.0 g kg(-1) ethanol plus 5, 15, or 30 mg kg(-1) cocaine. Cocaine alone at the same doses was injected into separate groups of animals. For the B6 strain, the overall effect of ethanol was to reduce cocaine-induced locomotor stimulation; no consistent effect of ethanol on cocaine-induced locomotion was observed in D2 mice. Cocaine-induced inhibition of nosepokes in both strains and sexes was partially reversed by ethanol. Ethanol also partially reversed cocaine-elevated stereotypy in both strains and both sexes. In B6 mice, cocaine-increased wall seeking tended to be reversed by coadministration of ethanol, whereas no consistent pattern was observed in the D2s. Results from this study suggest that the several measures affected by cocaine (locomotor activity, stereotypy, exploration, thigmotaxis) were, in turn, differentially affected by concurrent treatment with ethanol. Furthermore, our results point to genetic-based differences in ethanol's effects on cocaine-related behaviors. We address the implications for combined ethanol and cocaine use in humans.

Distribution and clearance of cocaine in brain is influenced by genetics.

The purpose of this study was to examine the pharmacokinetics of cocaine in two inbred mouse strains, C57BL/6 (B6) and DBA/2 (D2). Male and female mice were administered 30 mg kg(-1) cocaine IP and killed after 5, 15, 30, or 60 minutes postinjection. Brains were removed quickly and assayed for total brain cocaine concentration. Quantification of cocaine was conducted using gas chromatography and mass spectrometry. The results of this study revealed a strain difference in total brain cocaine kinetics. Specifically, we observed that at 5 min onward, B6 mice cleared cocaine from the brain with a t1/2 estimated at 22.3 min, while distribution in D2 mice appeared to be incomplete until 15 min with a subsequent t1/2 estimated at 11.2 min. These results show that despite faster clearance by D2 mice, the prolonged time to distribution in this strain may help explain why D2 mice show initial greater locomotor activation by cocaine, compared to B6s.

High genetic susceptibility to ethanol withdrawal predicts low ethanol consumption.

C57BL/6J (B6) inbred mice are well known to drink large amounts of alcohol (ethanol) voluntarily and to have only modest ethanol-induced withdrawal under fixed dose conditions. In contrast, DBA/2J (D2) mice are "teetotallers" and exhibit severe ethanol withdrawal. Speculation that an inverse genetic relationship existed between these two traits was substantiated by meta-analysis of existing data collected in multiple genetic models, including large panels of standard and recombinant inbred strains, their crosses, and selectively bred mouse lines. Despite methodological differences among laboratories in measurement of both preference drinking and withdrawal, a nearly universal finding was that genotypes consuming large amounts of 10% ethanol (calculated as g/kg/day) during two-bottle choice preference drinking were genetically predisposed to low withdrawal scores in independent studies after either acute or chronic ethanol treatment. Conversely, low-drinking genotypes had higher withdrawal severity scores. The genetic relationship appears to be strongest in populations derived from B6 and D2, where data from more genotypes (BXD RIs, B6D2F2s, BXD RI F1s, and B6D2F2-derived selectively bred lines) were available for analysis. Gene mapping studies in these populations identified four chromosome regions [on Chromosomes (Chrs) 1, 2, 4, and 15] where genes might potentially influence both traits. Among genotypes with greater genetic diversity (for example, a panel of standard inbred strains or selectively bred lines), the relationship was less pronounced. Thus, reduced susceptibility to the development of high alcohol use may be supported by increased genetic susceptibility to ethanol withdrawal symptoms.

Common quantitative trait loci for alcohol-related behaviors and central nervous system neurotensin measures: hypnotic and hypothermic effects.

Genetic correlations were found between high-affinity neurotensin receptor (NTR(H)) densities and NT-immunoreactivity (NT-ir) levels in specific brain regions and sensitivity to hypnotic and hypothermic effects of ethanol in LSXSS recombinant inbred strains of mice. Simple sequence length polymorphisms were used to identify quantitative trait loci (QTL) influencing hypnotic and hypothermic sensitivity to ethanol, NTR(H) and low-affinity neurotensin receptor densities and NT-ir levels in LSXSS recombinant inbred strains. Common QTL for NTR(H) receptor densities, NT-ir levels and these ethanol actions were identified. One of the QTL (chromosome 2, 80 cM) for NTR(H) density and hypnotic sensitivity is linked to the NTR(H) gene, Ntsr. Also, QTL for NTR(H) density were found in common with confirmed QTL for hypnotic sensitivity on chromosomes 1 (43 cM), 11 (57 cM) and 15 (56 cM) and with an unconfirmed QTL on chromosome 3 (19 cM). Two common QTL for NT-ir levels, but not NTR(H) or low-affinity neurotensin receptor receptors, and ethanol-induced hypothermia were observed on chromosomes 4 (43 cM) and 6 (41 cM). Two common QTL for NT-ir levels and sleep time were identified on chromosomes 3 (19 cM) and 9 (55 cM). Common QTL indicate that genes regulating NT receptor and/or NT-ir expression may be the same as those regulating sensitivity to ethanol.

Common quantitative trait loci for alcohol-related behaviors and central nervous system neurotensin measures: locomotor activation.

We have analyzed LSXSS recumbinant inbred for ethanol-induced activity using 2.0 g/kg ethanol and a new method we call ethanol activation slope. The ethanol activation slope provides a robust dose-response measure of ethanol activation, independent of both activity after saline and the inhibitory effects of ethanol on locomotor activity. These behavioral data were used in a quantitative trait locus analysis to map chromosomal loci involved in ethanol-induced locomotor activity. We tentatively identified seven loci that mediate the low-dose stimulatory effect of ethanol and six loci involved in locomotion after 2.0 g/kg ethanol. Only one of the loci are in common between the two behaviors. We also compared the behavioral quantitative trait locus to those previously identified that are involved in regulating central nervous system neurotensin levels and neurotensin receptor densities. Six chromosomal regions were identified that regulate at least one central nervous system neurotensin measure and an ethanol-induced locomotor behavior. The identification of loci controlling both central nervous system neurotensin levels or neurotensin receptor densities and ethanol-induced locomotor activity strengthens the proposal that neurotensin regulates, in part, ethanol-induced behaviors and central nervous system sensitivity to ethanol.