Diminished stress responses in the alcohol-sensitive ANT rat line

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.

Does ethanol act preferentially via selected brain GABAA receptor subtypes? the current evidence is ambiguous

In rodent models, gamma-aminobutyric acid A (GABAA) receptors with the alpha6 and delta subunits, expressed in the cerebellar and cochlear nucleus granule cells, have been linked to ethanol sensitivity and voluntary ethanol drinking. Here, we review the findings. When considering both in vivo contributions and data on cloned receptors, the evidence for direct participation of the alpha6-containing receptors to increased ethanol sensitivity is poor. The alpha6 subunit-knockout mouse lines do not have any changed sensitivity to ethanol, although these mice do display increased benzodiazepine sensitivity. However, in general the compensations occurring in knockout mice (regardless of which particular gene is knocked out) tend to fog interpretations of drug actions at the systems level. For example, the alpha6 knockout mice have increased TASK-1 channel expression in their cerebellar granule cells, which could influence sensitivity to ethanol in the opposite direction to that obtained with the alpha6 knockouts. Indeed, TASK-1 knockout mice are more impaired than wild types in motor skills when given ethanol; this might explain why GABAA receptor alpha6 knockout mice have unchanged ethanol sensitivities. As an alternative to studying knockout mice, we examined the claimed delta subunit-dependent/gamma2 subunit-independent ethanol/[3H]Ro 15-4513 binding sites on GABAA receptors. We looked at [3H]Ro 15-4513 binding in HEK 293 cell membrane homogenates containing rat recombinant alpha6/4beta3delta receptors and in mouse brain sections. Specific high-affinity [3H]Ro 15-4513 binding could not be detected under any conditions to the recombinant receptors or to the cerebellar sections of gamma2(F77I) knockin mice, nor was this binding to brain sections of wild-type C57BL/6 inhibited by 1-100 mM ethanol. Since ethanol may act on many receptor and channel protein targets in neuronal membranes, we consider the alpha6 (and alpha4) subunit-containing GABAA receptors unlikely to be directly responsible for any major part of ethanol's actions. Therefore, we finish the review by discussing more generally alcohol and GABAA receptors and by suggesting potential future directions for this research.

Brain regional pharmacology of GABA(A) receptors in alcohol-preferring AA and alcohol-avoiding ANA rats

Compounds interacting with the GABA(A) receptor system modulate voluntary alcohol consumption in alcohol-preferring AA (Alko, Alcohol) rats. Therefore, we compared the central GABA(A) receptor pharmacology of the AA rats to that of their counterpart, alcohol-avoiding ANA (Alko, Non-Alcohol) rats with receptor autoradiography. Total flumazenil-sensitive [(3)H]Ro 15-4513 binding to the benzodiazepine site of GABA(A) receptor was slightly lower in the hippocampus, striate cortex and lateral hypothalamus of the AA than ANA rats. The proportions of zolpidem- and diazepam-sensitive components were similar in both rat lines. Basal picrotoxin-sensitive [(35)S]TBPS binding to the convulsant site of GABA(A) receptor was similar in most regions between the rat lines, but the up-modulation of the binding by 10 microM diazepam in the hippocampal, amygdaloid and entorhinal cortical areas was greater in the AA than ANA rats. These results do not reveal any general genetic defect in the GABA(A) receptors of AA or ANA rats, but the regional profile of the ligand binding differences between the lines, especially in the coupling of the benzodiazepine and chloride channel sites, suggests receptor subtype-specific changes in brain regions implicated in behavioural reward and anxiolysis.

Low brain histamine content affects ethanol-induced motor impairment

The effect of ethanol on motor performance in humans is well established but how neural mechanisms are affected by ethanol action remains largely unknown. To investigate whether the brain histaminergic system is important in it, we used a genetic model consisting of rat lines selectively outbred for differential ethanol sensitivity. Ethanol-sensitive rats had lower levels of brain histamine and lower densities of histamine-immunoreactive fibers than ethanol-insensitive rats, although both rat lines showed no changes in histamine synthesizing neurons. Lowering the high brain histamine content of the ethanol-insensitive rats with alpha-fluoromethylhistidine before ethanol administration increased their ethanol sensitivity in a behavioral motor function test. Higher H3 receptor ligand binding and histamine-induced G-protein activation was detected in several brain regions of ethanol-naive ethanol-sensitive rats. Brain histamine levels and possibly signaling via H3 receptors may thus correlate with genetic differences in ethanol-induced motor impairment.

Increased behavioral neurosteroid sensitivity in a rat line selectively bred for high alcohol sensitivity

Acute administration of a neurosteroid 5beta-pregnan-3alpha-ol-20-one induced a greater impairment in motor performance of the selectively bred alcohol-sensitive (ANT) than alcohol-insensitive (AT) rats. This difference was not associated with the sensitivity of gamma-aminobutyrate type A (GABA(A)) receptors, as 5alpha-pregnan-3alpha-ol-20-one (allopregnanolone) decreased the autoradiographic signals of t-butylbicyclophosphoro[35S]thionate binding to GABA(A) receptor-associated ionophores more in the brain sections of AT than ANT rats. Nor was the difference associated with baseline levels of neuroactive progesterone metabolites, as 5alpha-pregnan-3,20-dione (5alpha-DHP) and 5alpha-pregnan-3alpha-ol-20-one were lower in the ANT rats. After ethanol (2 g/kg, i.p.) administration and the subsequent motor performance test, the increased brain concentrations of these metabolites were still lower in the ANT than AT rats, although especially in the cerebellum the relative increases were greater in the ANT than AT rats. The present data suggest that the mechanisms mediating neurosteroid-induced motor impairment are susceptible to genetic variation in rat lines selected for differences in ethanol intoxication.

An update on GABAA receptors

Recent advances in molecular biology and complementary information derived from neuropharmacology, biochemistry and behavior have dramatically increased our understanding of various aspects of GABAA receptors. These studies have revealed that the GABAA receptor is derived from various subunits such as alpha1-alpha6, beta1-beta3, gamma1-gamma3, delta, epsilon, pi, and rho1-3. Furthermore, two additional subunits (beta4, gamma4) of GABAA receptors in chick brain, and five isoforms of the rho-subunit in the retina of white perch (Roccus americana) have been identified. Various techniques such as mutation, gene knockout and inhibition of GABAA receptor subunits by antisense oligodeoxynucleotides have been used to establish the physiological/pharmacological significance of the GABAA receptor subunits and their native receptor assemblies in vivo. Radioligand binding to the immunoprecipitated receptors, co-localization studies using immunoaffinity chromatography and immunocytochemistry techniques have been utilized to establish the composition and pharmacology of native GABAA receptor assemblies. Partial agonists of GABAA receptors are being developed as anxiolytics which have fewer and less severe side effects as compared to conventional benzodiazepines because of their lower efficacy and better selectivity for the GABAA receptor subtypes. The subunit requirement of various drugs such as anxiolytics, anticonvulsants, general anesthetics, barbiturates, ethanol and neurosteroids, which are known to elicit at least some of their pharmacological effects via the GABAA receptors, have been investigated during the last few years so as to understand their exact mechanism of action. Furthermore, the molecular determinants of clinically important drug-targets have been investigated. These aspects of GABAA receptors have been discussed in detail in this review article.

Phenotypic characterization of second generation offspring of alcohol-sensitive ANT and alcohol-insensitive AT rat lines

The alcohol-sensitive ANT and the alcohol-insensitive AT rat lines developed by selective breeding for differential sensitivity to motor impairment on the tilting plane by a moderate ethanol dose (2 g/kg, IP), were cross-bred to produce second generation (F2) offspring to study phenotypic correlations between various behavioral and biochemical properties and the degree of initial alcohol sensitivity in the tilting plane test. The F2 population (n = 75) was subjected to alcohol sensitivity tests using a tilting plane test and a sleep time test, and to the elevated plus-maze test of sober activity and anxiety. Finally, the animals were sacrificed and the concentrations of dopamine and its acidic metabolites were analyzed in their striatal tissues. Serum corticosterone was determined to obtain information about the stress responses of the animals after the tilting plane test. The behaviors studied had no significant correlations with each other, suggesting that the various genetic and environmental factors affecting these behavioral phenotypes are different for each behavior. The biochemical measures yielded some correlations with the tilting plane test results that were contrary to the differences between the parent rat lines (dopaminergic indices) or that were confounded by the correlations with the body weight of the animals (corticosterone). Body-weight independent correlational tendency between the alcohol-induced impairment in motor performance and serum corticosterone concentration, however, fitted the differences between the parent lines, suggesting that stress mechanisms cannot be fully excluded as factors contributing to the differential alcohol sensitivity between the ANT and AT rat lines.

Benzodiazepine-induced motor impairment linked to point mutation in cerebellar GABAA receptor

The selectively outbred alcohol-non-tolerant (ANT) rat line is highly susceptible to impairment of postural reflexes by benzodiazepine agonists such as diazepam. ANT cerebella are generally devoid of diazepam-insensitive high-affinity binding of the benzodiazepine [3H]Ro15-4513, whereas in non-selected strains such binding marks a granule-cell-specific GABAA (gamma-aminobutyric acid) receptor containing the alpha 6 subunit. A critical determinant for diazepam insensitivity of this 'wild-type' cerebellar GABAA receptor is an arginine residue in alpha 6 position 100, where other alpha subunits carry a histidine. Here we report that the alpha 6 gene of ANT rats is expressed at wild-type levels but carries a point mutation generating an arginine-to-glutamine substitution at position 100. In consequence, alpha 6(Q100)beta 2 gamma 2 receptors show diazepam-mediated potentiation of GABA-activated currents and diazepam-sensitive binding of [3H]Ro15-4513. Our results suggest that cerebellar motor control may be a distinct behavioural correlate of the alpha 6-subunit-containing GABAA receptor subtype.

Hormone responses to sedative drugs and cold exposure in two rat lines with high and low alcohol sensitivity

Two rat lines bred for differences in motor impairment in the tilting plane test after a moderate dose of ethanol were compared for peripheral hormone responses. The alcohol-sensitive ANT rats had significantly lower plasma corticosterone concentrations than the alcohol-insensitive AT rats 30 min after an IP saline injection. Ethanol (2 g/kg, IP) and lorazepam (3 mg/kg, IP) injections increased the corticosterone concentration in ANT rats. Sodium barbital (160 mg/kg, IP) did not produce any increase in these rats; instead, it prevented any increase caused by a tilting plane test procedure 10 min before decapitation. Three trials on the tilting plane significantly elevated the corticosterone concentration in saline-treated ANT rats, but produced no additional increase in drug-treated ANT rats. In AT rats, drug injections caused no significant corticosterone increase but the tilting plane test procedure after barbital (lorazepam) treatment(s) elevated the corticosterone concentration. Cold exposure (+4 degrees C for 30 min) of the drug-naive animals elevated their concentrations of serum and adrenal corticosterone, thyrotropin, and growth hormone, but not of prolactin and luteinizing hormone. The increase in serum corticosterone was greater in AT than ANT rats, whereas the increase in serum thyrotropin was slightly greater in ANT rats. No differences between the rat lines were found in the growth hormone, prolactin, and luteinizing hormone levels. The results confirm and extend our earlier findings of the inability of ANT rats to produce additional stress responses to behavioral challenges when being intoxicated by sedative drugs, which may at least partly account for their increased sensitivity to sedative drugs.