Cocaine reward and MPTP toxicity: alteration by regional variant dopamine transporter overexpression.

Polygenic factors play important roles in animal models of substance abuse and susceptibility to dopaminergic neurodegeneration. Genetic factors are also likely to contribute to the etiology of human drug abuse disorders, and may alter human vulnerabilities to Parkinsonian neurodegeneration. The dopamine transporter (DAT; SLC6A3) is densely expressed by the dopaminergic midbrain neurons that play central roles in drug reward and is believed to be a primary site of action for cocaine reward. This transporter is necessary for the action of selective dopaminergic neurotoxins, and is uniquely expressed on neurons that are the primary targets of Parkinsonian neurodegeneration. To study possible influences of variant DAT expression on these processes, we have constructed transgenic mice (THDAT) in which tyrosine hydroxylase (TH) promoter sequences drive expression of a rat DAT cDNA variant, increase striatal DAT expression by 20-30%, and provide modest alterations in striatal levels of dopamine and its metabolites. THDAT mice habituate more rapidly to a novel environment than wildtype littermates. These animals display enhanced reward conferred by cocaine, as measured by conditioned place preference. However, locomotor responses to cocaine administration are similar to those of wildtype mice, except at high cocaine doses. THDAT mice display more than 50% greater losses of dopaminergic neurons following a course of MPTP treatment than do wildtype control mice. These results document a model for allelic variation at a gene locus that can exert significant effects in murine models of human substance abuse vulnerability and dopaminergic neurodegeneration.

Sensitivity to cocaine and amphetamine among mice selectively bred for differential cocaine sensitivity.

Selective breeding of mice for differences in response to a drug offers a powerful means for testing hypotheses regarding underlying mechanisms and relationships between drug-induced behaviors. Starting from a heterogeneous stock of mice, we have selectively bred lines of mice for extreme differences in their locomotor response to 10 mg/kg cocaine HCl. Selection pressure has been maintained for 12 generations and has resulted in two cocaine sensitive (CAHI) and two cocaine insensitive (CALO) lines. Across the generations of selection, the CAHI lines showed progressively greater amounts of cocaine-induced locomotion, with mice from the S12 generation traveling over 21,000 cm/30 min. following 10 mg/kg cocaine. The CALO lines, in contrast, did not substantially diverge from control values until the S8 generation. By generation 12, however, the LO lines traveled no further following 10 mg/kg cocaine (7000 cm/30 min), than they did following an initial saline injection. Cocaine and amphetamine dose-response analyses were conducted on drug-naive mice from the tenth generation. The CAHI lines were extremely sensitive to the locomotor activating effects of all doses of cocaine, displaying from 2- to 6-fold greater amounts of cocaine-induced locomotion than the CALO lines. The CALO lines, in contrast, were completely insensitive to the psychomotor stimulant effects of cocaine. The CAHI lines were also more sensitive to the locomotor activating effects of amphetamine. Both lines showed dose-dependent amphetamine-induced locomotion that peaked at 3 mg/kg. However, at all doses, the CAHI lines showed a 2- to 4-fold greater amount of locomotion than CALO lines. Thus, the sensitivity to cocaine developed through selection using a single dose of cocaine has generalized to a range of doses of cocaine and to at least one other psychostimulant.

VMAT2 knockout mice: heterozygotes display reduced amphetamine-conditioned reward, enhanced amphetamine locomotion, and enhanced MPTP toxicity.

The brain vesicular monoamine transporter (VMAT2) pumps monoamine neurotransmitters and Parkinsonism-inducing dopamine neurotoxins such as 1-methyl-4-phenyl-phenypyridinium (MPP+) from neuronal cytoplasm into synaptic vesicles, from which amphetamines cause their release. Amphetamines and MPP+ each also act at nonvesicular sites, providing current uncertainties about the contributions of vesicular actions to their in vivo effects. To assess vesicular contributions to amphetamine-induced locomotion, amphetamine-induced reward, and sequestration and resistance to dopaminergic neurotoxins, we have constructed transgenic VMAT2 knockout mice. Heterozygous VMAT2 knockouts are viable into adult life and display VMAT2 levels one-half that of wild-type values, accompanied by smaller changes in monoaminergic markers, heart rate, and blood pressure. Weight gain, fertility, habituation, passive avoidance, and locomotor activities are similar to wild-type littermates. In these heterozygotes, amphetamine produces enhanced locomotion but diminished behavioral reward, as measured by conditioned place preference. Administration of the MPP+ precursor N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine to heterozygotes produces more than twice the dopamine cell losses found in wild-type mice. These mice provide novel information about the contributions of synaptic vesicular actions of monoaminergic drugs and neurotoxins and suggest that intact synaptic vesicle function may contribute more to amphetamine-conditioned reward than to amphetamine-induced locomotion.

Cocaine reward and locomotor activity in C57BL/6J and 129/SvJ inbred mice and their F1 cross.

Large individual differences exist among mice in their behavioral responses to drugs of abuse, and many of these differences have a substantial genetic basis. The creation of new animal models using recombinant DNA technology has provided new genetic tools for assessing the role of specific candidate genes in drug response. This study presents a characterization of cocaine activation and reward in the two strains used most commonly for production of knockout mice, C57BL/6J and 129/SvJ, and their outcrossed F1 offspring. Using conditioned place preference, the study demonstrates that there are large strain differences in spontaneous locomotor activity and in the rewarding effects of cocaine. The 129/SvJ strain is hypoactive and is very sensitive to the locomotor activating effects of cocaine but does not develop cocaine-conditioned place preference under conditions that yield significant place preference in C57BL/6J mice. These phenotypes are not inherited in a simple additive manner, but rather the F1 generation resembles the C57BL/6J progenitor strain for a number of the behaviors examined.

Behavioral phenotypes of inbred mouse strains: implications and recommendations for molecular studies.

Choosing the best genetic strains of mice for developing a new knockout or transgenic mouse requires extensive knowledge of the endogenous traits of inbred strains. Background genes from the parental strains may interact with the mutated gene, in a manner which could severely compromise the interpretation of the mutant phenotype. The present overview summarizes the literature on a wide variety of behavioral traits for the 129, C57BL/6, DBA/2, and many other inbred strains of mice. Strain distributions are described for open field activity, learning and memory tasks, aggression, sexual and parental behaviors, acoustic startle and prepulse inhibition, and the behavioral actions of ethanol, nicotine, cocaine, opiates, antipsychotics, and anxiolytics. Using the referenced information, molecular geneticists can choose optimal parental strains of mice, and perhaps develop new embryonic stem cell progenitors, for new knockouts and transgenics to investigate gene function, and to serve as animal models in the development of novel therapeutics for human genetic diseases.

Differential cocaine sensitivity between two closely related substrains of C57BL mice.

While there is evidence that individual differences in response to cocaine are mediated, in part, by genetic factors, no single gene has been identified that can account for differential responsivity to cocaine. Recent studies in our laboratory may have moved us closer to identification of the gene(s) underlying cocaine sensitivity. We have identified several cocaine-related phenotypes on which two substrains of C57BL mice (6J and ByJ) differ. The genealogy of these two substrains leads to the expectation that they should be genetically very similar, differing at only a few loci. The large differences between the two substrains in cocaine sensitivity may be influenced by allelic differences at a major gene mediating the actions of cocaine. Naive ByJ mice are more resistant to cocaine-induced seizures than are 6J mice. Furthermore, among 6J mice repeated exposure to cocaine results in a decreased susceptibility to cocaine-induced seizure, while among ByJ mice, the same treatment gives rise to an increased susceptibility to seizures. In contrast to their lower sensitivity to cocaine-induced seizures, ByJ mice show a greater sensitivity to cocaine's locomotor stimulant effects. Furthermore, the repeated pairing of cocaine and the test environment results in the development of conditioned locomotion during subsequent exposure to that environment among 6J, but not ByJ, mice. Similarly, a greater degree of conditioned sensitization to the locomotor stimulant effects of cocaine develops in 6J mice.

Opiate receptor knockout mice define mu receptor roles in endogenous nociceptive responses and morphine-induced analgesia.

Morphine produces analgesia at opiate receptors expressed in nociceptive circuits. mu, delta, and kappa opiate receptor subtypes are expressed in circuits that can modulate nociception and receive inputs from endogenous opioid neuropeptide ligands. The roles played by each receptor subtype in nociceptive processing in drug-free and morphine-treated states have not been clear, however. We produced homologous, recombinant mu, opiate receptor, heterozygous and homozygous knockout animals that displayed approximately 54% and 0% of wild-type levels of mu receptor expression, respectively. These mice expressed kappa receptors and delta receptors at near wild-type levels. Untreated knockout mice displayed shorter latencies on tail flick and hot plate tests for spinal and supraspinal nociceptive responses than wild-type mice. These findings support a significant role for endogenous opioid-peptide interactions with mu opiate receptors in normal nociceptive processing. Morphine failed to significantly reduce nociceptive responses in hot plate or tail flick tests of homozygous mu receptor knockout mice, and heterozygote mice displayed right and downward shifts in morphine analgesia dose-effect relationships. These results implicate endogenous opioid-peptide actions at mu opiate receptors in several tests of nociceptive responsiveness and support mu receptor mediation of morphine-induced analgesia in tests of spinal and supraspinal analgesia.

Knockout mice and dirty drugs. Drug addiction.

Recent studies with knockout mice implicate the dopamine transporter as the target of the locomotor effects of the addictive psychomotor drugs cocaine and amphetamine; studies of reward in these animals are eagerly awaited.

Chromosomal mapping of the psychomotor stimulant effects of cocaine in BXD recombinant inbred mice.

To elucidate genes associated with cocaine's locomotor stimulant effects, we used recombinant inbred-quantitative trait loci (RI-QTL) analyses to identify chromosomal loci associated with locomotor activity before (baseline) and after cocaine treatment. RI-QTL analyses seek to identify associations between a quantitative measure of a phenotype and one or more previously mapped marker loci across a panel of RI strains. In the present study, 11 BXD RI strains were used to identify several putative QTLs for each phenotype. Both baseline locomotor activity and cocaine's locomotor stimulant effects are polygenic, with both unique and overlapping genetic influences. The largest associations for baseline activity were observed on chromosomes 5 and 9 and the largest associations for cocaine's psychomotor stimulant effects on chromosomes 3 and 17.

Retained cocaine conditioned place preference in D1 receptor deficient mice.

The role of the D1 dopamine receptor subtype in mediating cocaine effects was examined in mice in which the D1 receptor gene had been ablated by homologous recombination. Cocaine reward was assessed by conditioned place preference experiments using mice which had either one allele (+/-) or both alleles (-/-) of the D1 dopamine receptor gene disrupted and in their wild type (+/+) littermates. Cocaine conditioning resulted in similar increases in preference for drug-paired environments in mice of each of the three genotypes. Cocaine did not alter locomotor activity levels in homozygous, D1 knockout mice -/-, whereas increased activity was noted in both +/+ and +/- animals. These results are consistent with the idea that the D1 receptor is involved in the locomotor stimulant effects of cocaine, but has little role in a major test of the rewarding and reinforcing effects of the drug.

Chromosomal mapping of loci influencing sensitivity to cocaine-induced seizures in BXD recombinant inbred strains of mice.

Among inbred mice, genetic factors mediate differences in sensitivity to the convulsant properties of cocaine; however, the gene(s) underlying cocaine's effects have not been identified. To help elucidate the gene(s) responsible for cocaine seizure susceptibility, we used recombinant inbred-quantitative trait loci (RI-QTL) analyses to identify chromosomal loci associated with cocaine-induced seizures. RI-QTL analyses seek to identify associations between a quantitative measure of a particular phenotype and one or more previously mapped marker genes across a panel of RI strains. This report describes an RI-QTL analysis of cocaine seizure susceptibility among 26 BXD RI strains. These strains showed a skewed, bimodal range of seizure susceptibility which could be the result of one or more modifying genes acting in concert with a major gene to influence cocaine sensitivity. Correlating the percent seizures displayed by each strain following 60 mg/kg cocaine with chromosomal marker data for these strains revealed a number of significant correlations clustered in two regions on chromosomes 12 and 6. This is the first identification of putative chromosomal loci associated with a cocaine-related phenotype and should facilitate identification of the gene(s) underlying cocaine toxicity and other cocaine-related phenotypes.

Cold-induced increases in phenylethanolamine N-methyltransferase (PNMT) mRNA are mediated by non-cholinergic mechanisms in the rat adrenal gland.

Previously, we reported that cold stress induces a rapid increase in adrenomedullary PNMT mRNA levels, followed by concomitant increases in PNMT immunoreactivity (10). In the present study, the extracellular signals mediating this adaptive response to stress were investigated using northern analysis and RNA slot-blot hybridization. Although adrenal denervation significantly diminished cold-induced increments in adrenomedullary PNMT mRNA levels, it did not completely abolish the cold stress response. In contrast to these results, splanchnectomy completely inhibited cold-induced increments in TH mRNAs in the same tissue samples. These findings indicate that the effects of cold exposure on PNMT mRNA levels are mediated by both neural and non-neural mechanisms, and that adrenal PNMT and TH are differentially regulated in response to cold stress. Surprisingly, the neural component of the PNMT stress response could not be attenuated by peripheral administration of chlorisondamine, a powerful nicotinic ganglionic blocking agent. In contrast, chlorisondamine was effective in inhibiting sympathetic neural activity, as judged by the drug's ability to completely block increases in blood pressure, heart rate, and plasma catecholamines resulting from spinal cord stimulation in pithed rats. The administration of atropine, a muscarinic receptor antagonist, also failed to inhibit cold-induced alterations in adrenal PNMT mRNA. These results suggest that the trans-synaptic induction of adrenal PNMT mRNA involves a non-cholinergic component, and that cold-induced increases in PNMT mRNA are not coupled to acetylcholine-mediated adrenal catecholamine release.

Pharmacogenetic approaches to drug dependence.

The aim of this volume is to bring together information about both the neurochemical mechanisms associated with the actions of drugs of abuse and the psychopharmacological and behavioural effects of these drugs. One approach that is proving to be quite useful for bringing together these two very diverse fields is the use of classical pharmacogenetic techniques. Pharmacogenetics is defined as the study of genetic and environmental factors underlying individual differences in response to pharmacological or toxicological agents. Much of the early work in this field dealt with genetic differences in drug metabolism and other pharmacokinetic parameters [1]. More recently, however, attention has been directed towards understanding the implications of genetic differences associated with pharmacodynamic parameters mediating the actions of drugs. This paper discusses the use of pharmacogenetic techniques in drug abuse research. It presents an overview of some of the more common genetic techniques available for use in drug research and provides some examples from research projects that have employed these approaches.

Aggression modulates genetic influences on morphine analgesia as assessed using a classical mendelian cross analysis.

Pharmacogenetic techniques allow for the examination of genetic and environmental factors underlying phenotypes associated with drug response. Initial studies of mice bred at Jackson Laboratories (JAX) indicated that C57BL/6J mice were more sensitive to morphine-induced analgesia, as measured by latency to paw lick, than SJL/J mice. A classical Mendelian cross breeding program was initiated in which F1, F2 and backcross generations were derived from C57BL/6J and SJL/J breeding pairs purchased from JAX to examine the genetic factors underlying morphine analgesia. Genetic analysis indicated significant dominance or heterosis for a reduced drug response. The F1 generation was less sensitive to morphine-induced analgesia than either parental strain. Mathematical analysis of the generation means revealed that a simple dominance model with no epistatic interaction between genes best described the data. Environmental factors also affected sensitivity to morphine analgesia, in that C57BL and SJL mice raised in our facility did not differ in latency to paw lick. SJL mice from JAX exhibit a high degree of aggression, while SJL mice raised in our facilities show little or no aggression. The levels of aggression among groups of SJL mice were characterized and found to correlate with sensitivity to morphine analgesia. Mice exposed to increasingly greater levels of aggression were the least sensitive to morphine. Thus, the changes observed in sensitivity to morphine-induced analgesia appear to be related to the degree of aggression to which these mice are exposed, possibly resulting from the stress and/or prolonged exposure to painful stimuli associated with aggressive encounters.

Cold-induced alterations in the binding of adrenomedullary nuclear proteins to the promoter region of the tyrosine hydroxylase gene.

It is well documented that cold stress induces a rapid trans-synaptically mediated increase in the relative abundance of rat adrenomedullary tyrosine hydroxylase (TH) mRNA. To investigate the transcriptional mechanisms regulating the cold stress response, we have employed a gel mobility shift assay, using DNA fragments prepared from the proximal 5' flanking region of the bovine TH gene as a heterologous molecular probe. In pilot studies, this region of the bovine TH promoter (nucleotides -246 to +21) was fused to the bacterial reporter gene, chloramphenicol acetyltransferase, and the chimeric construct transfected into human neuroblastoma SK-N-BE(2)-C, hepatoma HepG2, and rat pheochromocytoma PC-12 cells. Results of this analysis indicate that the proximal 5' flanking region of the bovine TH gene contains sufficient information to drive transient reporter gene expression in both human and rat catecholaminergic clonal cell lines. The findings derived from the gel mobility shift studies demonstrate that cold exposure causes rapid and selective alterations in the binding of adrenomedullary nuclear proteins to the proximal 5' flanking region of the TH gene. The most striking cold stress-induced alteration in DNA/nucleoprotein binding occurs in a region of the TH promoter (nucleotides -246 to -189) which contains an element bearing marked sequence similarity to an AP1 binding site and is highly conserved among animal species. This alteration occurs within 1 hr of cold exposure and persists for up to 48 hr after the onset of stress. The results of adrenal denervation experiments indicate that the cold-induced change in DNA/nucleoprotein binding is neurally mediated, requiring intact sympathetic innervation of the gland.(ABSTRACT TRUNCATED AT 250 WORDS)

Classical genetic analyses of responses to sedative-hypnotic drugs in crosses derived from long-sleep and short-sleep mice.

A classical (Mendelian) genetic analysis of responses to eight sedative-hypnotic compounds (ethanol, urethane, trifluoroethanol, chloral hydrate, barbital, paraldehyde, methyprylon, pentobarbital) was conducted in crosses derived from mouse lines that were selectively bred for differential duration of anesthesia following ethanol. The sleep-time responses of these mice, the long-sleep (LS) and short-sleep (SS) mouse lines, as well as the F1, F2 and backcross (F1 x LS, F1 x SS) generations were measured. Generally, differences in responses among the generations were greater for water soluble compounds than were differences for more lipid soluble compounds. Also, the inheritance of responses to water soluble compounds could be explained primarily by additive effects of alleles while the inheritance patterns for more lipid soluble compounds were more complex. Genetic correlation with ethanol response decreased with increasing lipophilicity. These results suggest that the selection of the LS-SS mouse lines was specific for water soluble anesthetic agents. Because several of these agents are known to act at GABA receptors, examination of the interactions of compounds which differ in lipid solubility at GABA receptors from LS and SS mice may prove useful in elucidating the mechanism of the anesthetic actions of ethanol and other drugs.

Effects of cold exposure on rat adrenal tyrosine hydroxylase: an analysis of RNA, protein, enzyme activity, and cofactor levels.

Long-term cold exposure (5-7 days) is known to induce concomitant increases in the levels of adrenomedullary tyrosine hydroxylase (TH) RNA, protein, and enzyme activity. In this report, we compare the time courses of these changes and investigate the effects of cold exposure on the levels of biopterin, the cofactor required for tyrosine hydroxylation. After only 1 h of cold exposure, TH mRNA abundance increased 71% compared with nonstressed controls. Increases in total cellular TH RNA levels were maximal (threefold over control values) within 3-6 h of cold exposure and remained elevated throughout the duration of the experiment (72 h). TH protein levels increased rapidly after 24 h of cold exposure and reached a maximal value threefold above that of controls at 48-72 h. Despite the relatively rapid and large elevations in TH RNA and protein content, only modest increases in TH activity were detected during the initial 48 h of cold exposure. Adrenomedullary biopterin increased rapidly after the onset of cold exposure, rising to a level approximately twofold that of the nonstressed controls at 24 h, and remained at this level throughout the duration of the stress period. Taken together, the results of this time course study indicate that cold-induced alterations in adrenal TH activity are mediated by multiple cellular control mechanisms, which may include pre- and posttranslational regulation. Our findings also suggest that cold stress-induced increases in the levels of the TH cofactor may represent another key event in the sympathoadrenal system's response to cold stress.

Effect of cold stress on cholinergic receptors in the rat adrenal gland.

The effects of cold exposure on cholinergic binding sites in the rat adrenal gland were assessed by examining the binding of [125I]alpha-bungarotoxin (BTX), a nicotonic receptor antagonist and [3H]quinuclidinyl benzilate (QNB), a muscarinic receptor antagonist, to adrenal tissue homogenates. Cold exposure resulted in significant alterations in both nicotinic and muscarinic binding. Exposure to cold for 4 and 7 days resulted in a significant decrease in QNB binding. Scatchard analysis indicates that this alteration is due to a decrease in binding sites (Bmax) rather than a change in ligand affinity (Kd). In contrast, chronic cold exposure produced a significant increase in BTX binding sites. These results indicate that adrenal cholinergic receptors are altered in reciprocal fashion by chronic cold exposure, and that this change may represent a key event in the sympathoadrenal system's adaptive response to chronic cold stress.

Strain comparison of nicotine-induced seizure sensitivity and nicotinic receptors.

Nicotine-induced seizure sensitivity was assessed in 19 inbred mouse strains. Two routes of drug administration were utilized: acute intravenous (IV) infusion and intraperitoneal (IP) injection. Dose-response curves for sensitivity to IP nicotine-induced seizures were constructed for the 19 inbred strains and a heterogeneous stock (HS/Ibg) of mice. Differences were observed among the strains both in ED50 values and slopes of the dose-response curves following IP injection of nicotine. ST/bJ mice were the most sensitive having an ED50 of 2.34 +/- 0.09 mg/kg nicotine. DBA/1J mice were the most resistant strain with an ED50 value of 6.16 +/- 0.02 m/kg nicotine. Latency to clonic seizure was measured in the 19 inbred mouse strains using the acute IV route of drug administration. Again, ST/bJ mice were the most sensitive and DBA/2Ibg were the most resistant to IV nicotine-induced seizures. Significant correlations were observed between latency to IV nicotine-induced seizures and both ED50 values and the slope of the dose-response curves for IP nicotine-induced seizures. However, the pattern of results differed between the two routes of drug administration. The relationship between seizure sensitivity and nicotinic receptor concentration in three brain regions, cortex, midbrain and hippocampus, was also assessed using alpha-bungarotoxin (BTX) as the ligand. A significant relationship was observed between BTX binding in the three brain regions and sensitivity to IV nicotine-induced seizures such that strains with greater concentrations of BTX binding sites were more sensitive to nicotine-induced seizures than were strains with lower concentrations of BTX binding sites.(ABSTRACT TRUNCATED AT 250 WORDS)