Mapping quantitative trait loci that regulate sensitivity and tolerance to quinpirole, a dopamine mimetic selective for D(2)/D(3) receptors.

Acute sensitivity and tolerance to quinpirole (a dopamine mimetic with selectivity for D(2)/D(3) dopamine receptors) were evaluated in the C57BL/6J and DBA/2J inbred strains of mice, 24 of their BXD recombinant inbred strains, and 233 F(2) mice. Baseline locomotor activity, locomotor activity following 0.03 mg/kg quinpirole (and 0. 01 mg/kg in BXD mice), body temperature following 1 mg/kg quinpirole, and hypothermic tolerance following 2 or 3 days of quinpirole administration were evaluated. Quantitative trait locus (QTL) analysis was employed to identify genetic determinants of baseline locomotor activity and five behavioral responses to quinpirole. We examined correlated allelic variation in genetic markers of known chromosomal location with variation in each of these phenotypes. We definitively mapped a QTL on Chromosome (Chr) 9 linked to the D(2) dopamine receptor gene, Drd2, for hypothermic sensitivity to quinpirole, and identify a suggestive QTL in the same chromosomal region for tolerance to quinpirole after repeated treatments. Suggestive QTLs were also identified on Chr 19 for sensitivity and tolerance to quinpirole-induced hypothermia and for baseline locomotor activity; on Chr 15 for locomotor sensitivity to quinpirole; and on Chr 13 and 5 for baseline locomotor activity. Our results indicate that genetic differences in quinpirole sensitivity and tolerance are associated with QTLs near Drd2, and that baseline locomotor activity is associated with a suggestive QTL in proximity to the dopamine transporter gene Dat1. These data suggest that the genes influencing locomotor activity, dopamine mimetic sensitivity, and tolerance do not overlap completely.

Seizure sensitivity and GABAergic modulation of ethanol sensitivity in selectively bred FAST and SLOW mouse lines.

FAST and SLOW selected mouse lines were bred for differences in locomotor response to low-dose ethanol. FAST mice exhibit an extreme stimulant response and SLOW mice exhibit locomotor depression at the same ethanol dose. We tested the hypothesis that gamma-aminobutyric acid (GABA) systems modulate ethanol's stimulant effects by examining convulsant responses to GABAA receptor ligands, and by assessing the effects of GABAA and GABAB ligands on locomotor activity in the presence and absence of EtOH. FAST mice were more sensitive to the convulsant effects of GABAA drugs, and to one of two non-GABAergic drugs also tested. FAST and SLOW mice differed in locomotor responses to two benzodiazepines, but not to other GABAA receptor ligands. Ethanol's stimulant effects were not selectively altered by bicuculline or picrotoxin. The selected lines differed in sensitivity to the locomotor depressant effects of the GABAB agonist, baclofen. Ethanol-stimulated activity of FAST mice was inhibited by baclofen, and this effect was reversed by administration of the GABAB antagonist, CGP-35348. These GABAB receptor mediated effects were replicated in DBA/2J inbred mice that exhibit extreme sensitivity to ethanol's stimulant effects. In summary, we found moderate to strong evidence that some sites on the GABAA receptor complex were altered as a consequence of selection of FAST and SLOW mice, but found little support for GABAA mediation of EtOH-stimulated activity. In contrast, we found moderate evidence for differential alteration of GABAB receptor function; however, GABAB receptor involvement in ethanol-stimulated activity was strongly supported by results in the selected lines and an inbred strain.

Naltrexone effects on ethanol drinking acquisition and on established ethanol consumption in C57BL/6J mice.

Naltrexone's success as a treatment agent for alcoholism seems to be due to its ability to reduce craving in abstinent, dependent individuals and to reduce the pleasure associated with subsequent intake. However, more study is needed to establish the optimal amount of time that naltrexone treatment should be continued. Little information seems to have been collected regarding the most effective dosing regimen for reducing alcohol craving and consumption, and the usefulness of opiate antagonists in the prevention of alcohol dependence in nonaddicts, rather than just as a treatment agent in addicted individuals, also deserves further study. The alcohol-preferring C57BL/6J (B6) mice were used to: (1) study naltrexone effects on consumption in established drinkers using an increasing dosing regimen, (2) study naltrexone effects on the acquisition of ethanol drinking, and (3) study the effects of chronic naltrexone from timed-release pellets on drinking in alcohol-naive mice. Naltrexone reduced ethanol preference in established drinkers, but its effects waned at increasing doses. Naltrexone slowed the acquisition of ethanol drinking, but was ineffective when readministered after a phase when ethanol was offered in the absence of naltrexone. Mice with chronic naltrexone pellets consumed greater amounts of ethanol and showed higher ethanol preference than did placebo-pelleted animals. The observed reduced efficacy of naltrexone with increasing dosage and chronic treatment may have been due to naltrexone-induced opiate receptor changes. Such changes are presumably more likely to occur when naltrexone doses remain high or perhaps accumulate. Thus, dose and frequency of administration may be important factors in determining naltrexone's effectiveness in treating alcohol dependence.

Correlated responses to selection in FAST and SLOW mice: effects of ethanol on ataxia, temperature, sedation, and withdrawal.

A replicated bidirectional selective breeding program has produced lines of mice that differ in locomotor response to ethanol (EtOH). FAST mice were bred for high locomotor activation, whereas SLOW mice were bred for low or depressed locomotor activity in response to 2.0 g/kg of EtOH. We tested FAST and SLOW mice for differences in sensitivity to the incoordinating (1.5 to 2.5 g/kg), hypothermic (3.0 g/kg), and sedative (4.0 g/kg) effects of EtOH, and for differences in sensitivity to withdrawal after acute and chronic EtOH exposure. SLOW mice were more ataxic in a grid test and developed greater tolerance than FAST mice at 2.0 g/kg of EtOH, were more hypothermic than FAST mice, and were more sensitive to the sedative effects of EtOH than FAST mice, as measured by latency to and duration of loss of righting reflex, and by blood ethanol concentrations at regain of the righting reflex. FAST mice had more severe withdrawal seizures after chronic exposure, but did not differ from SLOW mice in withdrawal severity after an acute injection of EtOH. These data suggest that FAST mice are generally more sensitive to central nervous system excitation, and SLOW mice are generally more sensitive to central nervous system sedation by EtOH, and further suggest genetic overlap with respect to genes that mediate locomotor responses to EtOH and genes determining sensitivity to EtOH-induced ataxia, hypothermia, sedation, and withdrawal severity after chronic exposure. Our current observations are in contrast to observations made earlier in selection, in which few line differences in sensitivity to EtOH effects other than locomotor activity were found. Thus, it seems that continued selection for differences in locomotor response to EtOH has produced genetically correlated differences in other EtOH responses.

Effects of dizocilpine in withdrawal seizure-prone (WSP) and withdrawal seizure-resistant (WSR) mice.

Mice selectively bred to be Withdrawal Seizure-Prone (WSP) or Seizure-Resistant (WSR) after chronic ethanol administration have been reported to be differentially sensitive to the anticonvulsant and proconvulsant effects on alcohol withdrawal of drugs interacting with glutamate receptors. Several behavioral effects of the noncompetitive glutamate receptor antagonist, dizocilpine, were determined in WSP and WSR mice to see whether their differential sensitivity generalized to effects unrelated to seizures, and to see whether it was only apparent during ethanol withdrawal. Dizocilpine potentiated the loss of righting reflex induced by ethanol, and dose-dependently stimulated habituated and nonhabituated open field activity. WSP and WSR mice were equally sensitive to these effects of dizocilpine. Pretreatment with dizocilpine increased the transcorneal amperage necessary to produce maximal electroshock seizures: WSR mice were more sensitive than WSP to this effect. Ethanol withdrawal (i.e., testing 6 h after a 24-h exposure to ethanol vapor) and dizocilpine had several effects on mice tested in the hole-in-wall apparatus. Several differences between WSP and WSR mice were also found, but in no case did dizocilpine differentially affect ethanol-withdrawing WSP and WSR mice. Across these experiments, differences between WSP and WSR mice in response to dizocilpine were rather specific. For some responses, WSP and WSR mice were equally sensitive, but only in the seizure-related measure assessed were naive WSR mice more sensitive than WSP.(ABSTRACT TRUNCATED AT 250 WORDS)

Mu-opiate receptor binding and function in HOT and COLD selected lines of mice.

mu-Opiate receptor binding and function were examined in mice selectively bred for sensitivity (COLD) and resistance (HOT) to ethanol-induced hypothermia. These mice also have differential hypothermic sensitivity to mu-opiates. mu-Opiate receptor density was higher in the frontal cortex of HOT mice compared with COLD mice, but was the same in other brain areas. In addition, there were no line differences in Kd values. Basal adenylate cyclase (AC) activity was similar in both lines, as was the response to forskolin (FS) stimulation. Morphine was more effective at inhibiting FS-AC activity in the hypothalamus of HOT mice compared with COLD mice but was equally effective in the frontal and parietal cortex. There were no differences between lines in basal Ca2+, Mg2+, or Ca2+/Mg(2+)-ATPase activity. Further, 30 min after treatment ATPase activities were not altered in ethanol- or levorphanol-treated mice. These results suggests that mu-opiate biochemical pathways, but not ATPase enzyme systems, may be involved in mediating differential hypothermic sensitivity observed in HOT and COLD mice.

Sensitivity and tolerance to ethanol-induced hypothermia in genetically selected mice.

COLD mice have been genetically selected for pronounced hypothermia (HT) after acute EtOH administration, whereas HOT mice have been selected for attenuated HT. In the current experiments, HOT and COLD mice were found to differ significantly in sensitivity to EtOH-induced HT across a range of doses: the difference was greater at higher doses. After 3 g/kg of EtOH, HOT mice displayed a 1.8 degrees C HT, whereas COLD mice had a 3.6 degrees C HT. Male mice had greater HT responses than female mice regardless of genotype. Nonselected control mice were intermediate to the HOT and COLD mice in responsiveness to EtOH. After an acute EtOH dose, HOT mice were found to have slightly lower brain EtOH concentrations than COLD mice 3 and 4 (but not 1 and 2) hr after administration of EtOH, and may have eliminated EtOH slightly more rapidly than COLD mice. When tested repeatedly in a cool ambient environment (18 degrees C), COLD mice developed tolerance to EtOH hypothermia, whereas HOT mice did not. These results confirm that sensitivity to the hypothermic effects of EtOH is influenced markedly by genotype. Furthermore, selection for neurosensitivity to EtOH has produced a correlated difference in rate or magnitude of tolerance development, which is consistent with an hypothesis of the influence of common genes determining these responses to EtOH. The difference in tolerance could not be accounted for by initial HT sensitivity differences between the lines. The HOT and COLD lines should be useful for studies of the neurobiological mechanisms of EtOH-induced HT.(ABSTRACT TRUNCATED AT 250 WORDS)