Genetic components of ethanol responses

Prenatal ethanol exposure modifies locomotor activity and induces selective changes in Met-enk expression in adolescent rats

Several studies suggest that prenatal ethanol exposure (PEE) facilitates ethanol intake. Opioid peptides play a main role in ethanol reinforcement during infancy and adulthood. However, PEE effects upon motor responsiveness elicited by an ethanol challenge and the participation of opioids in these actions remain to be understood. This work assessed the susceptibility of adolescent rats to prenatal and/or postnatal ethanol exposure in terms of behavioral responses, as well as alcohol effects on Met-enk expression in brain areas related to drug reinforcement. Motor parameters (horizontal locomotion, rearings and stereotyped behaviors) in pre- and postnatally ethanol-challenged adolescents were evaluated. Pregnant rats received ethanol (2g/kg) or water during gestational days 17-20. Adolescents at postnatal day 30 (PD30) were tested in a three-trial activity paradigm (habituation, vehicle and drug sessions). Met-enk content was quantitated by radioimmunoassay in several regions: ventral tegmental area [VTA], nucleus accumbens [NAcc], prefrontal cortex [PFC], substantia nigra [SN], caudate-putamen [CP], amygdala, hypothalamus and hippocampus. PEE significantly reduced rearing responses. Ethanol challenge at PD30 decreased horizontal locomotion and showed a tendency to reduce rearings and stereotyped behaviors. PEE increased Met-enk content in the PFC, CP, hypothalamus and hippocampus, but did not alter peptide levels in the amygdala, VTA and NAcc. These findings suggest that PEE selectively modifies behavioral parameters at PD30 and induces specific changes in Met-enk content in regions of the mesocortical and nigrostriatal pathways, the hypothalamus and hippocampus. Prenatal and postnatal ethanol actions on motor activity in adolescents could involve activation of specific neural enkephalinergic pathways.

Prenatal ethanol exposure alters met-enkephalin expression in brain regions related with reinforcement: possible mechanism for ethanol consumption in offspring

The endogenous opioid system is involved in ethanol reinforcement. Ethanol-induced changes in opioidergic transmission have been extensively studied in adult organisms. However, the impact of ethanol exposure at low or moderate doses during early ontogeny has been barely explored. We investigated the effect of prenatal ethanol exposure on alcohol intake and Methionine-enkephalin (Met-enk) content in rat offspring. Met-enk content was assessed in the ventral tegmental area [VTA], nucleus accumbens [NAcc], prefrontal cortex [PFC], substantia nigra [SN], caudate-putamen [CP], amygdala, hypothalamus and hippocampus. Pregnant rats were treated with ethanol (2g/kg) or water during GDs 17-20. At PDs 14 and 15, preweanlings were evaluated in an intake test (5% and 10% ethanol, or water). Met-enk content in brain regions of infants prenatally exposed to ethanol was quantitated by radioimmunoassay. Ethanol consumption was facilitated by prenatal experience with the drug, particularly in females. Met-enk content in mesocorticolimbic regions - PFC and NAcc - was increased as a consequence of prenatal exposure to ethanol. Conversely, Met-enk levels in the VTA were reduced by prenatal ethanol manipulation. Prenatal ethanol also increased peptide levels in the medial-posterior zone of the CP, and strongly augmented Met-enk content in the hippocampus and hypothalamus. These findings show that prenatal ethanol exposure stimulates consumption of the drug in infant rats, and induces selective changes in Met-enk levels in regions of the mesocorticolimbic and nigrostriatal systems, the hypothalamus and hippocampus. Our results support the role of mesocorticolimbic enkephalins in ethanol reinforcement in offspring, as has been reported in adults.

Acute ethanol administration differentially alters enkephalinase and aminopeptidase N activity and mRNA levels in regions of the nigrostriatal pathway

Opioid peptides play a key role in ethanol reinforcement and may also represent important determinants in brain sensitivity to ethanol through modulation of nigrostriatal dopaminergic activity. Regulation of opioid levels by peptidase-degrading enzymes could be relevant in ethanol's actions. The aim of this work was to study the acute ethanol (2.5 g/kg) effects on the activity and mRNA expression of enkephalinase (NEP) and aminopeptidase N (APN) in the rat substantia nigra (SN) and the anterior-medial (amCP) and medial-posterior (mpCP) regions of the caudate-putamen (CP). Enzymatic activities were measured by fluorometric assays and mRNA expression by reverse transcriptase polymerase chain reaction. Acute ethanol administration differentially altered peptidase activities and mRNA expression with different kinetics. Ethanol increased and decreased NEP mRNA levels in the SN and amCP, respectively, but produced biphasic effects in the mpCP. APN mRNA levels were increased by ethanol in all brain regions. Ethanol induced a transient and long-lasting increase in NEP (mpCP) and APN (amCP) activities, respectively. Peptidase activities were not changed by ethanol in the SN. Our results indicate that striatal NEP and APN are important ethanol targets. Ethanol-induced changes in these neuropeptidases in the CP could contribute to the mechanisms involved in brain sensitivity to ethanol.

Ethanol-induced changes in proenkephalin mRNA expression in the rat nigrostriatal pathway

Endogenous opioid systems have been suggested to play a key role in ethanol reinforcement mechanisms and alcohol-drinking behavior. Ethanol induces differential alterations in opioid peptide expression in brain areas of the reward circuits, which may be linked to the reinforcing effects of ethanol. In addition, ethanol-induced alterations in opioidergic nigrostriatal transmission could be involved in brain sensitivity to ethanol and play a role in addictive processes. The aim of this work was to study the effects of acute ethanol administration on proenkephalin (proenk) mRNA expression in the rat substantia nigra and caudate-putamen (CP) for up to 24 h post treatment. Male Wistar rats received ethanol (2.5 g/kg) or distilled water by intragastric administration, and proenk mRNA expression was studied by in situ hybridization and densitometry. Ethanol transiently increased proenk mRNA expression in the CP 1 h after drug administration. Proenk mRNA levels remained elevated 2 h post treatment in the anterior-medial and medial-posterior regions of the CP. In contrast, ethanol decreased proenk mRNA expression in the substantia nigra pars compacta and pars reticulata 2 h after drug exposure. Alterations in enkephalin expression in the substantia nigra and CP in response to ethanol exposure could be involved in the mechanisms underlying brain sensitivity to the drug.

Anticonvulsive effects of kappa-opioid receptor modulation in an animal model of ethanol withdrawal

Although the neurochemical mechanisms contributing to alcohol withdrawal seizures are poorly understood, withdrawal seizures probably reflect neuronal hyperexcitability resulting from adaptation to chronic alcohol. Altered kappa-Opioid receptor (KOP-R) signaling has been observed in multiple seizure types; however, a role for this system in ethanol withdrawal seizures has not been systematically characterized. We hypothesized that pharmacological manipulations of the KOP-R would alter withdrawal in mice selectively bred for differences in ethanol withdrawal severity. Withdrawal Seizure-Prone (WSP) and Withdrawal Seizure-Resistant (WSR) mice were made physically dependent using chronic ethanol vapor inhalation, and the effects of the KOP-R antagonist nor-binaltorphimine or agonist U-50,488H on withdrawal severity were examined. Pretreatment with nor-binaltorphimine significantly increased handling-induced convulsion (HIC) severity in withdrawing WSR mice, with no observable effects in withdrawing WSP mice. In contrast, U-50,488H significantly decreased HIC severity in WSP mice, with no effects in WSR mice. During extended withdrawal (i.e. hours 12+), a rebound hyperexcitability was observed in WSP mice given agonist. Thus, administration of a KOP-R antagonist increased withdrawal severity in mice normally resistant to withdrawal seizures, while a KOP-R agonist reduced convulsion severity in animals susceptible to withdrawal seizures. These observations are consistent with differences in the KOP-R system observed in these lines at the molecular level, and suggest the KOP-R system may be a promising therapeutic target for management of ethanol withdrawal seizures. Finally, these findings underscore the importance of determining the potential for rebound increases in withdrawal severity during later withdrawal episodes.

[3H]DPDPE binding to delta opioid receptors in the rat mesocorticolimbic and nigrostriatal pathways is transiently increased by acute ethanol administration

Dopaminergic transmission in the mesolimbic and nigrostriatal pathways plays a key role in the reinforcement mechanisms and brain sensitivity to ethanol, respectively. Ethanol reinforcement and high alcohol drinking behaviour have been postulated to be partially mediated by a neurobiological mechanism involving the ethanol-induced activation of the endogenous opioid system. Activation of opioid neural pathways by ethanol may include alterations in the processing, release and/or the receptor binding of opioid peptides. The aim of this work was to investigate the effects of acute ethanol administration on delta opioid receptors in the rat mesocortical, meso-accumbens and nigrostriatal pathways by quantitative receptor autoradiography, using [(3)H] (2-D-penicillamine, 5-D-penicillamine)-enkephalin as radioligand. A significant increase in [(3)H] (2-D-penicillamine, 5-D-penicillamine)-enkephalin binding was observed in the substantia nigra pars reticulata 1 h after ethanol treatment. Two hours after drug exposure, ligand binding was significantly increased in the frontal and prefrontal cortices, the core and shell regions of the nucleus accumbens, and in the anterior-medial and medial-posterior regions of the caudate-putamen. In contrast, ligand binding was significantly decreased in the posterior region of the caudate-putamen 30 min after ethanol administration. The observed effects may reflect ethanol-induced changes in ligand binding affinity and/or in receptor density. Our results suggest that transitory changes in delta opioid receptors with different kinetic patterns may be involved in ethanol reinforcement and brain sensitivity to the drug. Ethanol-induced delta receptor up- and down-regulation mechanisms may participate in modulation of dopaminergic transmission in the mesocorticolimbic and nigrostriatal pathways.

Acute ethanol administration transiently decreases [3H]-DAMGO binding to mu opioid receptors in the rat substantia nigra pars reticulata but not in the caudate-putamen

Ethanol's actions in brain have been suggested to be partially mediated by a mechanism involving the ethanol-induced activation of the endogenous opioid system. Opioid systems, which are closely linked with dopamine transmission, are thought to be affected by ethanol through alterations in the processing, release, and/or receptor binding of opioid peptides. We studied the effects of a single acute dose of ethanol on rat nigrostriatal mu opioid receptors by quantitative receptor autoradiography, using [3H] [D-Ala(2),MePhe(4),Gly-ol(5)]-enkephalin ([3H]-DAMGO) as radioligand. [3H]-DAMGO binding was significantly decreased in the pars reticulata of the substantia nigra 1 h after ethanol administration. Ethanol exposure did not affect [3H]-DAMGO binding neither in the pars compacta of the substantia nigra nor in the caudate-putamen at any time tested after drug administration. The observed effects may reflect ethanol-induced changes in ligand binding affinity (Kd) or in receptor density (Bmax). Early and transitory ethanol-induced changes of mu receptors in the substantia nigra pars reticulata may be related to regulation of dopaminergic nigrostriatal transmission and contribute to determine brain sensitivity to the drug.

Immunocytochemical analysis of glutamate and GABA in selectively bred mice

Withdrawal Seizure Prone (WSP) and Withdrawal Seizure Resistant (WSR) mice have been selectively bred for differential ethanol withdrawal handling-induced convulsions (HICs). In addition, it has been observed that WSP mice exhibit drug-naive HICs. This latter finding suggests that WSP and WSR mice differ in their susceptibility to HICs. Alterations in the glutamate and gamma-aminobutyric acid (GABA) systems have been implicated in convulsive activity and have been proposed to underlie the manifestation of ethanol withdrawal symptoms. It is therefore possible that WSP and WSR mice are genetically different with respect to their glutamatergic and/or GABAergic systems. To test this hypothesis, we have analyzed WSP and WSR mice that are both drug- and HIC-naive for differences in the density of nerve terminal glutamate and GABA immunoreactivity within the CA1 subfield of the hippocampus (CA1) and layer II of the somatosensory cortex (SSC). The major finding of this study is that drug- and HIC-naive WSP mice exhibit a significantly greater density of presynaptic glutamate immunoreactivity associated with asymmetric synapses within the CA1, but not the SSC, when compared to WSR mice. The density of GABA immunoreactivity within nerve terminals associated with symmetric synapses does not differ between the selected lines in either brain region. Since prior drug exposure and HICs cannot account for the observed differences in these naive mice, the results strongly suggest that the density of nerve terminal glutamate immunoreactivity within the CA1 is a reflection of inherent genetic differences between WSP and WSR mice. Furthermore, an elevated density of presynaptic glutamate immunoreactivity may be an underlying neurochemical correlate to increased susceptibility to drug-naive and ethanol withdrawal convulsions.

Altered brain sensitivity to ethanol in mice after MPTP treatment

Previous studies demonstrated the role of the dopaminergic receptors in brain sensitivity to ethanol. The present study was designed to assess the relative contribution of the nigrostriatal component to this brain sensitivity. Adult male C57BL mice were given 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine (MPTP) injections (30 mg/kg daily for 2 consecutive days). The treatment decreased the striatal dopamine level by 35% from the control level, and the number (Bmax) of dopaminergic receptors was increased by 67%. Ethanol-induced sleep time was reduced in the MPTP-treated mice, as compared to controls, and this gap progressively widened during the 3 weeks of testing to 29%. Brain ethanol levels upon awakening increased by 22%. The results suggest that the nigrostriatal dopaminergic pathways play a major role in determining brain sensitivity to ethanol which may represent an important component in the addictive process.

Effects of diltiazem in convulsive states differ from those previously reported for dihydropyridine calcium channel antagonists

Unlike the dihydropyridine calcium channel antagonists studied previously, the benzothiazepine calcium channel antagonist, diltiazem, increased the incidence of convulsions caused by bicuculline, N-methyl-DL-aspartate or 4-aminopyridine. However, the latencies to convulsions were also increased. Diltiazem increased the ratings of convulsive behaviour on handling after intraperitoneal administration of bicuculline, or pentylenetetrazol and after the calcium channel activator, Bay K 8644, administered ICV. When the binding of the dihydropyridine, [3H]-nitrendipine in the CNS was measured in vivo, this was increased by diltiazem. This compound therefore showed a different pattern of interaction with convulsant drugs then that previously demonstrated for other calcium channel antagonists, appearing to possess both pro- and anticonvulsant actions, and a different pattern of interaction with the dihydropyridine receptor complex.

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)

Effect of acute alcohol withdrawal on sensitivity to pro- and anticonvulsant treatments in WSP mice

Through the genetic technique of selective breeding, a mouse line [Withdrawal Seizure Prone (WSP)] has been developed that expresses severe handling-induced convulsions (HIC) after cessation of chronic ethanol exposure. These mice also display rebound elevations in HIC after a single ethanol injection. In the current studies, we tested WSP mice in several paradigms. WSP mice were found to be marginally sensitive to the effects of acute doses of dizocilpine to reduce HIC. However, when tested during acute withdrawal from a single ethanol injection, WSP were more sensitive to this compound. Although N-methyl-D-aspartate significantly elevated HIC in naive WSP mice, it was more effective at low doses when given during acute withdrawal. Withdrawing mice were slightly more sensitive than naive mice to kainic acid. Pentylenetetrazole elevated HIC in naive and withdrawing mice; it was marginally more effective in naive mice. Diazepam inhibited HIC in both naive and withdrawing mice, and was slightly more effective during acute withdrawal. This pattern of results suggests that acute alcohol withdrawal is accompanied by altered sensitivity to convulsants and anticonvulsants. These changes include enhanced sensitivity in at least two excitatory amino acid-gated ion channel binding sites.

Molecular Mechanisms Associated with Cocaine Effects

Cocaine has been shown to be a highly addictive and toxic drug. It produces these effects and a variety of other physiological and behavioral effects through its interactions with several distinct central nervous system receptor sites. We present the results of a series of studies that utilized multiple site analyses to elucidate which cocaine binding sites influence the reinforcing and toxic effects of cocaine and with what proportion of influence. The nature of cocaine interactions with monoamine transporters is also discussed, especially with the dopamine transporter, which has been shown to be the cocaine binding site that is primarily associated with the reinforcing effects of cocaine. We also provide evidence that vulnerability to both the toxic and addictive effects of cocaine may be significantly influenced by genetic differences in both humans and animals. In view of the fact that cocaine is commonly abused in a polydrug situation, we present the results of both behavioral and biochemical experiments which suggest that common biochemical pathways may mediate the reinforcing or addictive properties of drugs of abuse. Finally, we discuss research on the biochemical mechanisms associated with effects of ethanol, particularly those which may also influence cocaine self-administration and speculate on pharmacotherapeutic strategies for concurrent abuse of cocaine and ethanol.

Diminished stress responses in the alcohol-sensitive ANT rat line

During behavioral tests of alcohol sensitivity, rapid alcohol-opposing reactions may constitute an important mechanism in reducing the acute performance-impairing actions of alcohol. The alcohol-sensitive ANT (alcohol nontolerant) rats achieve lower plasma corticosterone concentrations after a tilting plane test of alcohol sensitivity (2 g ethanol/kg, IP) than the alcohol-insensitive AT (alcohol tolerant) rats, suggesting a dampening of activated stress mechanisms in the ANT rats. We have extended the comparison of these rat lines by examining central and peripheral stress responses to an acute 10-min swimming stress without ethanol administration. After the stress, plasma and adrenal corticosterone concentrations, adrenal dopamine concentrations, binding of [3H]Ro 5-4864 to adrenal membranes, and hypothalamic norepinephrine turnover were lower in the ANT than AT rats. Habituation to daily handling did not affect the stress effects or the differences between the rat lines. These results suggest that the alcohol-sensitive ANT rats have a diminished reaction to general stress, even in the absence of ethanol. This may impair their capacity to overcome the sedative and motor-impairing effects of moderate ethanol doses.

Alcohol dependence and withdrawal: a genetic animal model

Using the techniques of selective breeding, mouse lines have been developed that express severe (Withdrawal Seizure Prone: WSP) or mild (Withdrawal Seizure Resistant: WSR) handling induced convulsions after cessation of chronic ethanol exposure. These lines differ at least ten-fold in severity of withdrawal after identical ethanol treatment. One feature of the genetic model is that other traits which distinguish these lines are presumably influenced by those genes determining ethanol withdrawal severity. WSP and WSR mice do not differ markedly in the metabolism of ethanol. In addition to handling induced convulsions, they also differ in other withdrawal signs: for example, WSP mice show more pronounced tremor. WSP and WSR mice do not differ in sensitivity to ethanol's hypothermic, anesthetic, or locomotor stimulant effects, nor in the magnitude of tolerance development to these responses. This suggests that sensitivity, tolerance and dependence are distinct genetic entities. WSP mice also display more severe withdrawal from diazepam, phenobarbital, and nitrous oxide than WSR mice, suggesting that some genes generally predispose mice to withdrawal from depressants. WSP mice display withdrawal handling induced convulsions after a single dose of ethanol, pentobarbital, or diazepam. The effective dose for producing drug seizures is not markedly different between WSP and WSR mice for a number of compounds with varied mechanisms of action. However, WSP mice are more sensitive than WSR mice to the effects of acute doses of convulsants to elevate handling induced convulsions. WSP mice have more binding sites in hippocampus for the N-methyl-D-aspartate antagonist MK 801. Binding of this ligand is increased during ethanol dependence in both mouse lines.(ABSTRACT TRUNCATED AT 250 WORDS)