Quantitative Trait Loci Affecting Methamphetamine Responses in BXD Recombinant Inbred Mouse Strains

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (39)

Citing Articles via Google Scholar

Google Scholar

Articles by Grisel, J. E.

Articles by Crabbe, J. C.

Search for Related Content

PubMed

PubMed Citation

Articles by Grisel, J. E.

Articles by Crabbe, J. C.

Pubmed/NCBI databases
Gene GEO Profiles
HomoloGene Protein
UniGene
Compound via MeSH
Substance via MeSH
Hazardous Substances DB
d-METHAMPHETAMINE
Medline Plus Health Information
Methamphetamine

Previous Article  |  Next Article

Volume 17, Number 2, Issue of January 15, 1997 pp. 745-754
Copyright ©1997 Society for Neuroscience

Quantitative Trait Loci Affecting Methamphetamine Responses in BXD Recombinant Inbred Mouse Strains

Judith E. Grisel, John K. Belknap, L. A. O'Toole, M. L. Helms, Charlotte D. Wenger, and John C. Crabbe
Research Service, Veterans Affairs Medical Center, and Department of Behavioral Neuroscience, Oregon Health Sciences University, Portland, Oregon 97201

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Individual differences in most behavioral and pharmacological responses to abused drugs are dependent on both genetic andenvironmental factors. The genetic influences on the complex phenotypesrelated to drug abuse have been difficult to study using classicalgenetic analyses. Quantitative trait locus (QTL) mapping is amethod that has been used successfully to examine genetic contributionsto some of these traits by correlating allelic variation in polymorphicgenetic markers of known chromosomal location with variation indrug-response phenotypes. We evaluated several behavioral responsesto multiple doses of methamphetamine (METH) in C57BL/6J (B6),DBA/2J (D2), and 25 of their recombinant inbred (BXD RI) strains.Stereotyped chewing, horizontal home cage activity, and changesin body temperature after 0, 4, 8, or 16 mg/kg METH, as well asstereotyped climbing behavior after 16 mg/kg METH, were examined.Associations (p < 0.01) between METH sensitivity and allelic statusat multiple microsatellite genetic markers were subsequently determinedfor each response. QTLs were provisionally identified for eachphenotype, some unique to a particular behavior and others thatappeared to influence multiple phenotypes. Candidate genes suggestedby these analyses included several that mapped near genes relevantfor the neurotransmitters acetylcholine and glutamate. The locationsof QTLs provisionally identified by this analysis were comparedwith QTLs hypothesized in other studies to influence methamphetamine-and cocaine-related phenotypes. In several instances, QTLs appearedto overlap, which is consistent with idea that common neural substratesunderlie some responses to psychostimulants.
Key words: methamphetamine; QTL; quantitative trait locus; recombinant inbred strain; mouse; gene mapping; stereotypy; locomotor activity; body temperature pharmacogenetics

INTRODUCTION

Most responses to drugs of abuse reflect both genetic and environmental influences (Crabbe and Harris, 1991). Furthermore,the genetic influence on drug responses generally results fromthe collective influences of many genes, each of which may contributea relatively small amount to the genotypic variance. These quantitativetraits have been effectively studied in recombinant inbred (RI)strains of mice. The BXD RI strains [derived by inbreeding novelinbred strains from the F₂ cross between C57BL/6J (B6) and DBA/2J(D2) mice] have been the most commonly used in drug abuse research.Under controlled laboratory conditions, phenotypic differencesamong RI strains largely reflect their genotypic differences:the pattern of B6 and D2 alleles captured in each RI strain isunique because of distinct recombinations of these alleles. Phenotypicstrain means can be correlated with allelic status at known geneticmarkers: a significant relationship indicates a putative quantitativetrait locus (QTL) in the same chromosome region as the marker.Each such QTL contains one or more genes that may influence thetrait. This approach enables the provisional identification ofcandidate genes that may influence a particular behavior or phenotypein the absence of any prior hypotheses about the mechanisms bywhich such phenotypes are expressed. Furthermore, it is not necessaryfor the progenitor strains to differ phenotypically; as long asthe trait is polygenic (influenced by multiple genes) and variablewithin the RI panel, QTL analysis can be performed successfully.This might be the case, for instance, if both progenitor strainspossess genes for high and low response. Another major strengthof this technique is that because inbred strains are geneticallystable, all information obtained in these studies is both cumulativeand comparable to earlier data, thus providing a rich resourceand incentive for collaborative efforts, because genetic correlationscan be determined for different measures across different laboratories.Perhaps most important, genes identified in these murine analysescan usually be readily mapped to particular human chromosomalregions because of the high degree of synteny (Copeland et al.,1993). A description of the strategy for QTL mapping has beenpublished previously (Crabbe and Belknap, 1993; Belknap et al.,1996a,b).

Variability in the response to amphetamine in mice is known to depend in part on genetic differences (Kitahama and Valatx,1979; Crabbe, 1986; DeWit et al., 1986) (for review, see Seale,1991). Seale et al. (1985) were the first to attempt a systematicgenetic analysis of amphetamine sensitivity. Body temperaturewas measured before and several times after d-amphetamine administrationin B6, D2, and 10 of their RI derivatives. Later, Gora-Maslaket al. (1991) subjected the Seale et al. (1985) data to QTL analysisand found several promising associations. Although the power ofthis early experiment to map the responsible genes was limitedbecause only 10 of the RI strains were studied and there wereonly 173 polymorphic loci available at the time, it demonstratedthe feasibility of locating drug-response genes. Several studieshave since used the QTL mapping strategy to locate genes influencingother abused drugs, including those affecting morphine preference(Berettini et al., 1994), alcohol preference (Phillips et al.,1994; Rodriguez et al., 1995; Melo et al., 1996), and alcoholwithdrawal (K. Buck, P. Metten, J. Belknap, and J. Crabbe, unpublishedobservations).

The purpose of the present experiments was to investigate further the genetic substrates of amphetamine-induced responsesin mice. Behavioral and physiological responses (stereotyped chewingand climbing, alterations in thermoregulation, and home cage locomotoractivity) after administration of 0, 4, 8, or 16 mg/kg methamphetamine(METH) were evaluated using B6, D2, and 25 of their RI strains.Genetic correlations were calculated between these measures. QTLanalysis was performed on these strain means, and QTLs suggestedby these experiments were then compared with QTLs hypothesizedto influence psychostimulant-related phenotypes from other studies,including other measures of locomotor activation and stereotypyto amphetamine and cocaine.

MATERIALS AND METHODS
Animals and drugs. Mice were bred at the Portland VA Veterinary Medical Unit from stock originally obtained from The JacksonLaboratory (Bar Harbor, ME). They were group housed (2-5 animalsper cage) at the time of weaning and maintained with ad libitumfood and water in a 12 hr light/dark cycle (6:00 A.M. to 6:00P.M.) at 21 ± 2°C. Adult (10-14 week old) mice were used in allstudies, and testing was conducted between 8:00 A.M. and 12:00P.M. (see below). Animals in each experiment were tested overseveral weeks, with strains roughly counterbalanced across theexperimental period. Each mouse was tested once, but each strainwas tested at multiple times. On test days, cages of mice weretransported to the testing room and mice were weighed 45-60 minbefore the start of the test session and then randomly assignedto either the METH or the saline (SAL) group, with multiple dosesrepresented in each cage. Animals were given either SAL or METH(4, 8, or 16 mg/kg, i.p.; 0.8, 1.2, or 1.6 mg/ml in a volume of0.01 ml/gm body weight; Sigma, St. Louis MO) and tested as describedbelow.

The development of the BXD RI strains has been described previously (Taylor, 1978). Briefly, inbreeding from the F₂ generationof B6 × D2 crosses has resulted in 26 viable strains that showunique recombinations of B6 and D2 alleles: on average, threeto four crossovers per chromosome have been preserved in eachRI strain. All members of each RI strain are homozygous for eitherthe B6 or the D2 allele at each locus. Twenty-five RI strainswere available in sufficient number for testing in Experiment1, and 24 strains for Experiment 2. All procedures were approvedby the VA Institutional Animal Care and Use Committee and performedin accordance with National Institutes of Health guidelines forthe care and use of animals in research.
Experiment 1 Assessment of stereotyped chewing, home cage locomotor activity, and temperature changes induced by METH. One of the primaryaims of this study was to characterize the alterations in thermoregulationafter METH administration in the BXD mice. Pilot studies had determinedthat repeated temperature assessment in B6 and D2 mice (usinga rectal probe) resulted in lower temperatures than a single temperaturedetermination at a comparable time point. Further, this effectwas largely strain-dependent. To circumvent any confounds causedby repeated testing, we used only a single temperature measurementper mouse. We also chose to use behavioral measures that involvedneither handling of animals nor novel environments and, thus,they were unlikely to affect body temperature determinations.These observational measures were exophthalmos (eye protrusion),chewing, and home cage horizontal activity. The analyses of thesebehaviors were conducted in 862 male mice of 25 RI strains andboth progenitor strains. The N per strain per dose was 8 in almostall cases. The measurement of exophthalmos proved to be unreliable(reflected in a nonsignificant split-half reliability estimateof r = 0.36) and, thus, genetic influences on this phenotype couldnot be evaluated. Therefore, the observation of exophthalmos inthese mice was excluded from our analysis and will be omittedfrom the following discussion.

Each animal was taken from its home cage, weighed, injected with either SAL or METH (4, 8, or 16 mg/kg), and returned to itshome cage with its normal cagemates. Only one mouse at a timein each cage was injected per experimental session, with foursessions per day. Starting 17 min after injection, activity wasassessed for 1 min as the number of quadrant crossings in thehome cage (each time an injected mouse entered a different quarterof the cage, 1 activity count was scored). Thirty-three minutesafter injection, the injected subjects were again assessed forthe number of chewing or gnawing occurrences for the next minute.Repetitive chewing involved paw-to-mouth movements most oftendirected at the corn cob bedding material, although frequently(~25% of the time) it did not involve any object. Although foodwas present, it was never seen to be the object of chewing. Forty-eightminutes after injection, body temperature was determined witha rectal probe inserted 2 cm using an analog thermometer.

Measurement of brain METH concentration. Brain METH levels were determined by gas chromatography from samples taken immediatelyafter the test for mice given either 4 or 8 mg/kg METH. Brainswere excised and homogenized in 0.1 M potassium phosphate buffer,pH 6.0. A 550 ml aliquot was centrifuged at 13,000 rpm for 10min, and 400 ml of the supernatant was transferred to a new tube.Internal standard and 600 ml of fresh buffer were added. The sampleprep columns (Bond-Elut, 3 cc) were washed through the column,and the column was aspirated for 5 min. Next, 5 ml of methanolwas washed through and the column was dried for 3 min. Finally,1.5 ml of freshly prepared 2% ammonium hydroxide in ethyl acetatewas slowly passed through the column and collected. A 500 ml portionof this material was placed in a glass vial along with 50 ml of1% HCl in methanol, and the solution was dried. This was continueduntil all of the sample was dried. Next, 60 ml of heptafluorobutylanhydride was added and the vial was sealed and heated at 70°Cfor 20 min. The vial was then cooled and dried, and 400 ml ofethyl acetate was added. The sample was sealed and vortexed, and1 ml was injected in the GC/MS for analysis following the methodsof Foltz et al. (1990).
Experiment 2 Assessment of stereotyped climbing induced by METH. In rodents, low doses of amphetamine (0.25-1.0 mg/kg) produce hypothermiaand a general activation comprised of sniffing, locomotion, andrearing. Higher doses result in hyperthermia and a decreasingincidence of competing behaviors, as stereotyped behaviors beginto emerge (Randrup and Munkvad, 1967; Jellinek, 1971). Stereotypymay take many forms that depend in part on the animal species,dose of amphetamine, and time after injection, as well as environmentalfactors such as stress or previous pharmacological history withpsychostimulants (Randrup et al., 1975). Rapid and repetitiouspaw-to-mouth movements (chewing) have been the most frequentlystudied behavior in rodents.

Protais et al. (1976) initially characterized and standardized climbing behavior as a stereotypy elicited by dopamine agonistsin mice. After apomorphine administration, mice show increasedlocomotor activity and, if placed in a cage with mesh walls, enhancedclimbing behavior (see, for example, Marcais et al., 1978; Balsaraet al., 1981; Joshi et al., 1981; Cabib et al., 1995). A pilotstudy assessing the effects of several doses of METH determinedthat 16 mg/kg produced the most robust climbing response in bothB6 and D2 mice. Therefore, 715 adult female mice from 24 of theBXD/Ty RI set $---$ in addition to B6 and D2 mice $---$ were tested on theclimbing apparatus after intraperitoneal injection of either equivolumeSAL or 16 mg/kg METH. Immediately after the injection, mice wereplaced in a single cage on corncob bedding surrounded by a 12-cm-diameterwire mesh chimney 24 cm high, constructed from 0.5 inch hardwarecloth. The top of each chimney was covered to prevent escape.Animals were scored during a single 2 sec inspection each 5 minthroughout a 60 min test period as follows (Protais, 1976): 4paws on the floor (0), forefeet on the wall or grooming [i.e.,2 feet on floor (1)], 4 paws on the wall [climbing (2)].

Data analysis. Mean SAL strain values were subtracted from individual post-METH scores to obtain a measure of the METH-inducedchange in each behavior for Experiment 1. The effects of strainon METH sensitivity were then analyzed by one-way ANOVA at eachdose for Experiment I. A single-factor (strain) ANOVA was alsoused to examine climbing in the RIs and their progenitors after16 mg/kg METH in Experiment 2. Climbing scores were averaged over15 min time periods to create four epochs. Because strains alsodiffered in climbing behavior after SAL, METH sensitivity wasagain determined by subtracting each strain's mean saline scorefor the corresponding time period from the individual post-METHscores within a strain. To determine the reliability of the measuresassessed in these studies, split-half correlations were obtainedfor each trait and corrected using the Spearman-Brown method.Genetic correlations (i.e., among strain means) were estimatedamong the dependent measures examined in this study (Hegmann andPossidente, 1981).

QTL analysis. Over 1500 genetic markers (Mammalian Genome, 1996) have been genotyped in the BXD RI strains, mostly comprisingmicrosatellite simple sequence repeat polymorphisms determinedby PCR, so that the location and the B6- or D2-like repeat lengthof each of these alleles is known for each strain. By convention,D2 alleles are coded with values of 1, and B6 alleles with valuesof 0 in our database. Therefore, to identify the putative locationof relevant QTLs, the strain mean values for chewing, body temperature,home cage activity, and climbing were correlated with the value(0 or 1) at each of the polymorphic loci in our data set. Forbody temperature changes and activity, each of the three doseswas considered as a separate trait for QTL analysis. Thus, a totalof eight behavioral traits were analyzed. A statistically significantcorrelation at p $<=$ 0.01 between the phenotype and the allelicstate at a particular marker indicates that a gene in this regionof the genome may influence the response to METH. A significantclustering of markers showing similar correlations on a particularregion of the genome is more likely to point to a true locus ofinfluence. Even so, primarily because of the large number of correlationscalculated, there is a high probability of false positives. However,making the criteria more stringent would increase the likelihoodof type II errors or false negatives (missing actual influentialloci). Our strategy, therefore, is to use this analysis as aninitial screen, suggesting provisional regions of influence thatawait confirmation or rejection in subsequent analyses. Our generalapproach for subsequent verification of the QTLs provisionallyreported here has been discussed previously (Belknap et al., 1993,1996a,b; Crabbe et al., 1994) (K. Buck, P. Metten, J. Belknap,and J. Crabbe, unpublished observations). We plan to examine otherpopulations to follow up the results reported here with the goalof attaining aggregate levels of statistical significance requiredto accept linkage that have been proposed by Lander and Kruglyak(1995).

RESULTS

Dose-effect analysis in several METH-induced behaviors
Significant dose-related effects of METH on all responses assessed were evident (data not shown). Repetitive chewing showeda roughly linear dose-response function; the 16 mg/kg dose resultedin near 100% frequency for chewing for almost all strains. Incontrast, body temperature and home cage activity responses evidencedbiphasic curves. The lowest dose of METH, 4 mg/kg, caused statisticallysignificant hypothermia, whereas the highest dose, 16 mg/kg, causedsignificant hyperthermia. Similarly, 4 mg/kg METH resulted inpeak locomotor activation, whereas higher doses showed progressivedecreases in home cage activity.

Strains differed widely with respect to METH-induced effects. For instance, B6 mice showed no effect of METH on body temperatureat any dose, whereas others (such as BXD-1) showed consistenthyperthermia at all doses (consistent with Seale et al., 1986).Figure 1 shows the METH-induced (METH $-$ mean SAL) body temperaturechanges in all 27 strains at each of the three doses. At the 4mg/kg dose (top panel), there was wide variation in body temperaturechanges (F_(26,185) = 5.31, p < 0.0001). Eight strains showed significanthypothermia, and two were hyperthermic relative to saline controlvalues. At the highest dose (16 mg/kg; bottom panel), there werealso differences among strains (F_(26,188) = 3.55, p < 0.0001):none of the strains were hypothermic, and ~75% showed significanthyperthermia. The 8 mg/kg dose (middle panel) was intermediatebut also variable (F_(26,190) = 6.25, p < 0.0001). Overall, METH-inducedbody temperature changes were quite heritable, with genotype (strain)accounting for 43, 46, and 33% of the total observed variance(R²) at the 4, 8, and 16 mg/kg doses, respectively.
Fig. 1. Changes in body temperature in 25 BXD RI strains and the two progenitor strains after 4 mg/kg (top), 8 mg/kg (middle), or16 mg/kg (bottom) intraperitoneal METH injection. The strainsare plotted in order from the most negative response (hypothermia)on the left to the most positive response (hyperthermia) on theright. Each bar shows the mean ± SEM for each dose. The strainsalong the x-axis refer to the BXD strain number; B6 and D2 miceare also labeled.
[View Larger Version of this Image (27K GIF file)]

The typical dose-response curve with respect to home cage activity is an inverted U-shaped function. The individual strainmeans for home cage horizontal activity after the three dosesof METH are shown in Figure 2. The 4 mg/kg dose (top panel) inducedmore activation than the other doses and varied significantlyamong strains (F_(26,186) = 4.37, p < 0.0001). All strains weresignificantly activated by this dose of METH except for BXD-8mice. Increases in home cage locomotor activity were also commonlyobserved after 8 mg/kg METH and, again, they differed significantlyamong strains (F_(26,190) = 6.73, p < 0.0001; middle panel). Incontrast, the 16 mg/kg dose (bottom panel) produced significantreductions in activity in nine strains and enhanced activity inonly two strains (F_(26,188) = 34.98, p < 0.0001). Again, METH-inducedhome cage activity was quite heritable, with genotype accountingfor 38, 48, and 41% of the total variance for the 4, 8, and 16mg/kg doses, respectively.
Fig. 2. Mean ± SEM number of quadrant crossings/min (home cage activity) for B6, D2, and 25 BXD RI strains after 4 mg/kg (top), 8mg/kg (middle), or 16 mg/kg (bottom) intraperitoneal METH. Seelegend to Figure 1.
[View Larger Version of this Image (31K GIF file)]

Repetitive chewing was almost never seen in animals treated with the 4 mg/kg dose of METH, whereas chewing was near maximalin most strains after the 16 mg/kg dose (data not shown). Thus,only the 8 mg/kg dose was particularly useful in assessing straindifferences in sensitivity to this behavior (Fig. 3). As in theother behaviors, repetitive chewing showed large strain differences,from no response in three strains to continuous chewing throughoutthe observation period in three other strains (F_(26,190) = 3.51,p < 0.0001). Genotype accounted for 33% of the total observedvariance at this dose. Stereotypy was also measured by examiningthe climbing response in Experiment 2.
Fig. 3. BXD RI strain chewing responses (mean ± SEM) after 8 mg/kg METH. See legend to Figure 1.
[View Larger Version of this Image (25K GIF file)]

Spearman-Brown-corrected split-half reliability estimates indicated that all of these measures were reliable. For the temperaturechanges r_SB = 0.81, 0.76, and 0.78 after 4, 8, and 16 mg/kg, respectively.Activity changes were also reliable: r_SB = 0.75, 0.87, and 0.86at the same doses. Finally, the corrected reliability estimatefor chewing was r_SB = 0.85.

Brain METH concentrations
Although brain METH levels did vary significantly among strains at the 4 mg/kg dose (F_26,183 = 1.724, p < 0.05), no significantdifferences in brain METH levels were evident after 8 mg/kg METH(p > 0.10) (Fig. 4). The correlation between the strain meansfor brain METH concentrations after these two doses was 0.61 (p< 0.001). However, brain concentrations of METH were not significantlycorrelated with any of the METH sensitivity measures taken inthese same animals. Thus, because pharmacokinetic differencesdid not account for genotypic differences in drug response, wedid not correct for brain METH concentrations when evaluatingthe effects of METH.
Fig. 4. Brain METH levels (µg/gm) after 4 mg/kg (hatched bars) or 8 mg/kg (solid bars) METH in B6, D2, and 25 BXD RI strains. Seelegend to Figure 1.
[View Larger Version of this Image (39K GIF file)]

Effect of 16 mg/kg METH on stereotyped climbing in BXD RIs
As with D2 mice, in many of the RI strains there was little evidence of stimulation during the initial 15 min period afterinjection. That is, for most RI strains, METH-treated groups didnot differ initially from the SAL group and, therefore, data fromthe first epoch were excluded from further analysis. An initialanalysis considered strain differences in SAL treatment acrossthe latter three epochs using a two-way ANOVA. Baseline (SAL)scores were significantly variable across strains (F_25,328 = 4.66,p < 0.0001), although SAL climbing did not vary across epochs(F_2,656 = 0.449, p = 0.64) and the effect of strain did not dependon the time epoch examined (F_50,656 = 0.92, p = 0.63). Therefore,data at each time point were indexed as the mean difference scoreof all the individual METH scores within a strain from the meanSAL score.

Because the strain-specific response to METH was highly correlated across epochs, a total climbing score was calculated. Figure5 shows that there was also wide variation within the BXD panelfor the combined METH-induced difference scores (F_25,334 = 13.52,p < 0.0001). Twelve strains responded with stimulated climbing,whereas six others showed decreased climbing and the remainingeight strains did not significantly alter their climbing activityafter METH administration. The Spearman-Brown-corrected reliabilityestimate for the climbing change after 16 mg/kg METH was 0.79.
Fig. 5. Total METH-induced climbing scores (±SEM) for all BXD RI strains for the period from 15 to 60 min after 16 mg/kg METH. Seelegend to Figure 1.
[View Larger Version of this Image (26K GIF file)]

Genetic correlations among responses to METH
Table 1 shows correlations among strain responses to METH. Because they were based on strain means, they are predominantlygenetic in origin (Hegmann and Possidente, 1981). Within the temperatureand home cage activity measures, there was evidence for a highdegree of genetic control in common across doses. For activity,the 4 and 8 mg/kg doses correlated r = 0.77, and the 8 and 16mg/kg doses correlated r = 0.49. Similarly, temperature correlationsacross doses ranged from 0.49 to 0.84. The strains most activatedby 4 or 8 mg/kg METH had greater increases (or lesser decreases)in METH-induced body temperature induced by all three doses. Thissuggests that some genes affect both thermal and locomotor responsesto METH. The other behavioral responses were not generally correlatedwith each other, indicating that they are largely subserved bydifferent mechanisms and/or neural substrates. An exception tothis generalization was the significant genetic correlation betweenhyperthermia and climbing (r = $-$ 0.44) at the 16 mg/kg dose. Interestingly,the two measures thought to index forms of stereotyped behavior,chewing and climbing, tended to correlate negatively (r = $-$ 0.32,not significant), suggesting that chewing and climbing may becompetitive behaviors.

Table 1. Genetic correlations (among strain means) for behavioral measures taken in Experiments 1 and 2

Activity (4) Activity (8) Activity (16) Temp change (4) Temp change (8) Temp change (16) Chewing (8)

Activity (4 mg/kg)

Activity (8) +0.77^**

Activity (16) +0.08 +0.49^**

Temp change (4) +0.51^** +0.54^** +0.11

Temp change (8) +0.57^** +0.53^** +0.16 +0.84^**

Temp change (16) +0.45^* +0.13 $-$ 0.17 +0.49^* +0.67^**

Chewing (8) $-$ 0.03 $-$ 0.16 $-$ 0.34 $-$ 0.13 +0.05 +0.12

Climbing (16) $-$ 0.29 $-$ 0.11 +0.13 +0.15 $-$ 0.30 $-$ 0.44^* $-$ 0.31

There were 27 strains for the measures in Experiment 1 and 26 strains evaluated for climbing in Experiment 2. Numbers in parenthesesindicate dose of METH (mg/kg) (

^* p < 0.05,

^** p < 0.01, vs value r = 0).

In contrast to all other measures, climbing was evaluated in female mice (both genders were not evaluated for all phenotypesbecause of the limited availability of these strains). It is possible,therefore, that some of the putative common loci may in fact begender-specific and that these correlations would change if onesex were examined for all measures. Combining data from mice ofboth sexes is perhaps most likely to result in an underestimationof common genetic etiology; furthermore, in pilot studies examiningMETH-induced climbing in both female and male B6 and D2 mice,strain differences did not depend on gender. Therefore, althoughit is certainly important to note this difference between themeasures in Table 1, gender effects are unlikely to have a largeimpact on our interpretation of the data.

QTL analysis of METH sensitivity
To identify the putative location of relevant QTLs, the strain mean values for chewing, home cage activity, body temperature,and climbing were correlated with the value (0 or 1) at each ofthe polymorphic loci in our database. Multiple QTLs were provisionallyidentified (p $<=$ 0.01; Table 2) for each measure of drug sensitivity.In several instances, possible candidate genes map to nearby locations.For each chromosome region, only the marker showing the highestcorrelation with each drug sensitivity measure is shown, but alist of all significant associations is available from the authors.The locations of provisionally mapped QTLs are shown schematicallyin Figure 6.

Table 2. Genetic markers, chromosome number, distance from centromere in cM (e.g., 1:8.7), and associations with METH responses forhome cage activity, body temperature, chewing, and climbing

Marker Location HC activity (dose) T° change (dose) Chewing (8 mg/kg) Climbing (16 mg/kg) Candidate

D1Mit1 1:8.7 $-$ 0.66[16]

D1Ncvs75 1:41 $-$ 0.52[16]

D1Ncvs41 1:48.4 $-$ 0.68[4] $-$ 0.68[8] +0.65 Acrg/Acrd (52.3)

D1Ncvs12 1:74.5 +0.68

D1Ncvs59 1:107 $-$ 0.54[4]

Brp13 2:25 +0.67

Hoxd 2:35 $-$ 0.55

D2Mc1 2:83 $-$ 0.62

Evi1 3:14.4 +0.52[4]

Il2 3:19.2 +0.52[8]

Gnat2 3:49 $-$ 0.56[16]

P40-rs4 3:79.6 +0.53[4]

Mltr3 4:16.8 +0.50

Lyb4 4:24.8 $-$ 0.55

D4Nds8 4:20.7 $-$ 0.50[16]

Ms6hm 4:40.3 +0.52

Sac 4:83 +0.66

D5Ncvs56 5:14 +0.55[8]

D5Rik85 5:26 +0.51

D5Mit10 5:54 $-$ 0.76

D5Byu4 5:68 +0.59

Ache 5:81 +0.55 Ache (81.0)

Met 6:6 $-$ 0.66[4]

D6Ncvs34 6:27 $-$ 0.51[8]

D6Nds3 6:31 $-$ 0.66[4]

D6MIt16 6:31 $-$ 0.59[16]

D6Nds2 6:40 +0.52[8]

II5ra 6:47 +0.57[8]

Nmdar2b 6:65 +0.57[4]/+0.53[8]

D7Mit12 7:66 +0.68[4]/+0.59[8]

Xmv76 7:73 +0.58[4]/+0.56[8]/+0.58[16] Drd4 (70.3)

D8Bir2 8:13 0.55[4] +0.59 Adrb3 (10.0)

D8Ncvs43 8:45 $-$ 0.52[16]

Fli-1 9:16 $-$ 0.68[8]

Gst2-3 9:47.5 $-$ 0.58[16]

D9Mit12 9:55 $-$ 0.61[16] Acra3 (51.0)

D9Ncvs17 9:65 $-$ 0.54[8]

Cck 9:71 $-$ 0.67[8]

D9Byu6 9:71 $-$ 0.67[4]

Tel9q 9:74 $-$ 0.58

D10Mit144 10:54 $-$ 0.55[16]

Kcnc2 10:62 $-$ 0.51[4]

Mox2 12:20 +0.54[16]

Xmmv50 12:55 +0.59[4] +0.58[4]/+0.56[8]/+0.58[16]

D14Mit54 14:12.5 $-$ 0.67

Glud 14:15.5 +0.61[16] Glud (15.5)

Mtv11 14:16 $-$ 0.58[16]

Ms15-7 14:16.5 $-$ 0.57[8]

Gnrh 14:39.5 $-$ 0.61[8]/ $-$ 0.62[16] Gnrh (39.5)

Es10 14:41 $-$ 0.64

D15Mit7 15:14.5 +0.61[16]

D15Mit1 15:47.5 +0.52[16]

Spt1 15:58.1 +0.56[8]

Comt 16:13 +0.52[8] Comt/Drd3 (13.0/23.0)

D16Mit70 16:57 +0.51[16]

Zfp40 17:10.05 $-$ 0.67[16]

D17Mit3 17:41.5 +0.58[16]

Hprt-ps1 17:47.6 $-$ 0.53 +0.52 Hprt-ps1 (47.6)

Gnblps1 19:0 $-$ 0.54[16] Adra2a (50.0)

Lybp2 19:2 $-$ 0.62[4] Adrb1 (51.0)

Pomc-2 19:9 $-$ 0.65[8]

Lpc1 19:18 $-$ 0.50[16]

DXNcvs10 20:38.3 +0.66

The dose for activity and body temperature measures is indicated in brackets. Chewing associations after the 8 mg/kg doseof METH only are presented. All associations reported are significantat p $<=$ 0.01; boldface correlations are associated with p $<=$ 0.001.Possible candidate genes, along with their predicted locations,which map within ~10 cM of the QTL, are also given.

Fig. 6. Schematic representation of genomic locations for putative QTLs underlying response to METH in the BXD RI strains and theirprogenitors. The 19 mouse chromosomes and the X chromosome aredepicted proportionately; scale gives centimorgans (cM) from thecentromere. For home cage activity (squares) and temperature changes(triangles), dose (mg/kg) is indicated by number inside the symbol.Markers from Silver et al. (1994).
[View Larger Version of this Image (27K GIF file)]

DISCUSSION
Genetic factors mediate some of the variability between individuals in response to psychostimulants (c.f. Broadhurst, 1978;Seale, 1991). We have analyzed several responses to METH in theBXD RIs and their progenitors in order to identify putative geneticloci contributing to METH sensitivity. A comparison of the patternof METH-induced strain mean effects with polymorphic genetic markersresulted in the identification of >70 provisional loci over alleight traits, or about eight to nine per trait. These can be usedto generate hypotheses about candidate genes as well as to focusfuture testing in other genetic models. The next phase of theanalysis will be to determine which of these provisional locirepresent actual associations with high probability (Lander andKruglyak, 1995). Computer simulations (Belknap et al., 1996a,b)and our experience (K. J. Buck, P. Metten, J. K. Belknap, andJ. C. Crabbe, unpublished observations) suggest that approximatelyhalf of these loci will prove to represent true associations.

Candidate neurotransmitter modulation
Extensive pharmacological and neuroanatomical evidence that has been accumulating since the 1970s makes a strong case forthe role of dopamine in psychostimulant-produced behaviors (see,for example, Groves and Rebec, 1976; Kuczenski, 1986; Hernandezet al., 1987). Congruent with these hypotheses, both temperatureand activity changes induced by METH were associated with a regionon chromosome 7 near the dopamine D4 receptor gene (Drd4). Locomotoractivation in response to 4 mg/kg METH was also associated witha region on chromosome 16 that contains the gene for both theD3 receptor and the enzyme catechol-O-methlyltransferase (Comt),which is important for the catabolism of catecholamines. Eventhough genes for several dopamine receptor subtypes and the dopaminetransporter have been mapped in mice, it is perhaps noteworthythat no QTLs suggested by analyses of either stereotyped behaviorwere found in the vicinity of these or other known dopamine-relatedgenes. This finding does not necessarily imply that dopamine neurotransmissionis not involved in METH-induced stereotypy but, rather, that geneticvariability in dopamine activity in the BXD RIs may not underliegenetic differences in METH-induced stereotypy (as measured inthe present studies). There is a dissociation between dopamineactivation in the striatum induced by psychostimulants, and behavioralstereotypy, because there does not appear to be a strict temporalcorrelation between the amount of dopamine release in either thecaudate nucleus or the nucleus accumbens with the stereotypicstimulation observed (Kuczenski et al., 1989, 1990, 1991). Ourdata are congruent with this interpretation and go further tosuggest that the genetic variability in the chewing and climbingstereotypical responses depend more on other neural substrateswhich may, in turn, interact with dopamine mechanisms.

For instance, there is compelling evidence for modulation of METH-stimulated behaviors by acetylcholine and glutamate, neurotransmittersfor which loci associated with relevant genes were identifiedin our analysis. Some of these areas are particularly attractiveloci for attempts at verification because they overlap betweenstudies of related phenotypes. For example, QTLs on mid-chromosome1, associated with climbing, home cage activity, and temperaturechanges, are in a region where QTLs were provisionally mappedfor open-field locomotor stimulation (horizontal movement) after1 and 2 mg/kg METH and its sensitization (T. J. Phillips, M. Huson,C. Gwiazdon, and C. McKinnon, unpublished observations); thisregion contains genes coding for both the $delta$ and the $gamma$ subunitsof the nicotinic acetylcholine receptor. Moreover, a region onchromosome 9 that appears to be associated with the activity andtemperature changes after METH in the present studies $---$ also identifiedby the Phillips group as associated with cocaine-induced locomotorstimulation and METH sensitization $---$ contains the gene for the a₃subunit of the acetylcholine receptor. The gene coding for thea₂ subunit is in a region on proximal chromosome 14 with markersassociated with a cluster of METH-related phenotypes (discussedbelow). There is also substantial biochemical and histochemicalevidence suggesting that B6 and D2 mice differ with respect tocholinergic activity (Ebel et al., 1973; Durkin et al., 1977)and cell density (Albanese et al., 1985; Iacopino et al., 1986;Schwab et al., 1990). Furthermore, the genetic variability incholinergic cell number in the striatum was shown by Dains (1995)to be correlated with neuroleptic-induced catalepsy in the mouse,suggesting an interaction between acetylcholine and dopamine inthe production of striatally mediated motor behavior. Althoughthe relationship between striatal dopamine and acetylcholine hasbeen well documented (Graybiel, 1990; Florin et al., 1992; Groveset al., 1995), the joint dopamine/acetylcholine responses to amphetaminedo not appear to be sufficient to explain the behavioral changesobserved, implying likely interactions with still other neurotransmittersystems (Kuczenski et al., 1977).

It is clear also that both glutamate and GABA are also involved in the locomotor activation resulting from dopamine agonistadministration (Balsara et al., 1981; Liljequist and Karcz-Kubicha,1993; Karler et al., 1995). For example, Karler et al. (1994,1995) found that pharmacological blockade of dopamine, glutamate,or GABA receptors in the ventral lateral striatum could preventthe stereotypy induced by amphetamine or cocaine. The dopaminergicprojections from the substantia nigra pars compacta are knownto involve both of these other transmitters in the striatal-thalamic-corticalloop thought to underlie the locomotor activating effects of psychostimulants.Our data suggest that glutamate modulation by the enzyme glutamatedehydrogenase may play a role in determining individual differencesin genetic sensitivity to activation by amphetamine, because variationin a marker near the Glud locus (and the acetylcholine a₂ subunit)on chromosome 14 was correlated with genetic variability in fourobserved traits (climbing and body temperature changes after 16mg/kg METH and home cage activity after either 8 or 16 mg/kg METH).Given the consensus among genetic studies and the behavioral datasuggesting a role for glutamate in responsivity to psychostimulants,further testing of this locus in an F₂ intercross might be a fruitfulendeavor.

QTLs affecting multiple phenotypes
There are three other published genetic analyses of psychostimulant responses in the BXD RIs. Data collected by Seale et al.(1985) were subject to QTL analyses by Gora-Maslak et al. in 1991.The hyperthermia induced by 20 mg/kg amphetamine was found tobe associated with markers in four distinct regions of the mousegenome. These were from 10 RI strains and a very limited set ofless than 200 markers, constraints that would imply that any associationsobserved would be likely to reflect fairly large genetic influencesbut would also have a higher probability of being spurious. Infact, all four of these regions overlap with those suggested forsome traits by the current analyses, although we found QTLs forMETH's temperature effects in common with Gora-Maslak et al. (1991)only in the region from 27 to 31 cM on chromosome 6. Recently,Tolliver et al. (1994) and Miner and Marley (1995) mapped QTLscontributing to the locomotor activation in the BXD RIs aftercocaine administration. Tolliver and colleagues evaluated theresponse to 32 mg/kg cocaine in 16 strains, while Miner and Marleyexamined locomotor stimulation to 10 mg/kg cocaine in 11 of theBXDs. Both Tolliver et al. (1994) and Miner and Marley (1995)identified the region of chromosome 9 associated with the locomotorresponse that overlaps with the large cluster of QTLs that wefound associated with several responses to METH on the distalportion of this chromosome (discussed above). All three studiesalso found a common region of influence near the D17 Mit3 andHprt-ps1 loci on chromosome 17. As gene mapping studies of drugeffects begin to accumulate, both discrepancies and commonaltiesbetween studies are potentially informative. The fact that commonregions are found in studies of phenotypes that differ substantially(large dose ranges or different pharmacological agents) can leadto hypotheses about common mechanisms (see, for example, Crabbeet al., 1994). The Hprt-ps1 marker locus on chromosome 17, forinstance, was associated with psychostimulant response in allof these studies. This is a pseudogene for the enzyme hypoxanthine-guaninephosphoribosyltransferase (HPRT) and, therefore, does not appearto translate any functional proteins (Isamat et al., 1988). Itis interesting, however, that an HPRT enzyme deficiency is associatedwith the motor disorder Lesch-Nyhan syndrome in humans and withalterations in dopaminergic activity in motor nuclei and increasedsensitivity to amphetamine-induced locomotion and stereotypy inmice (Jinnah et al., 1991, 1994), suggesting the possibility thatpolymorphisms in the retroposed HPRT pseudogene may differentiallyregulate (as endogenous antisense nucleotides) the HPRT gene itself(see, for example, Zhou et al., 1992; Akagi et al., 1994; Carltonet al., 1994; Manjanatha et al., 1994; Kas et al., 1995; Leedmanet al., 1995).

A lack of concurrence between QTLs for different markers may be indicative of distinct genetic underpinnings for the differentyet related phenotypes, or they may be attributable to other factors.It is possible, for instance, that more pleiotropic QTLs wouldhave been identified in common if the same sex were tested forall phenotypes; as it happens, female mice were analyzed in theclimbing study, whereas male mice were used to evaluate all otherphenotypes. In a recent study by Melo et al. (1996) aimed at mappinggenes associated with alcohol preference, two sex-specific QTLswere identified. Because these are the first gender-specific QTLsproposed for a pharmacological response, the prevalence of suchsex-constrained loci is not yet known. However, many behavioralresponses are known to vary significantly between females andmales and, therefore, attempts at elucidating genetic substratesof such phenotypes should give this possibility serious consideration.

One of the ubiquitous effects of addictive drugs is behavioral stimulation (see Crabbe and Harris, 1991). This increased activityseen in both animals and humans after drug administration mayreflect aspects of the reinforcing or rewarding effects of thesedrugs (Wise, 1978, 1987). The current use of QTL mapping in RIstrains offers promise toward the identification of genes associatedwith locomotor activation in response to psychotropic drugs. Thepresent findings suggest putative QTLs that may contribute todifferences in METH sensitivity between individuals. The nextstep is to attempt to confirm these provisional QTL associationsin an F₂ (or other) population. In this way, offspring from B6and D2 parents are individually phenotyped and then genotypedat areas of the genome suggested to reflect influences of QTLsfrom this RI study. When the correlations between behavior andallelic variation are confirmed in such a genetically segregatingpopulation, the case for a significant influence of these lociis strengthened further. Finally, congenic mice, isogenic at allloci except for a small region bracketing a QTL in question, canbe created, contributing further to our understanding of the influenceof a particular locus or gene product on a complex phenotype.In the interim, pharmacological or anatomical interventions canbe used to test the hypothesis generated by preliminary QTL analysisin RIs (such as the role of glutamate or acetylcholine for geneticsensitivity to psychostimulants). These convergent methods oftesting are likely to further the goal of understanding the precisemolecular products that influence responding to psychostimulantsand, therefore, susceptibility to drug abuse.

FOOTNOTES

Received July 23, 1996; revised Oct. 22, 1996; accepted Oct. 28, 1996.

These studies were supported by Public Health Service Grants POl AA08621 and P50AA10760, National Institutes of Drug AbuseContract 271-90-7405, and two grants from the Department of VeteransAffairs. J.E.G. was supported by Training Grant T32 AA07468. Apreliminary report of this work has been given at the SpecialConference on The Biology and Genetics of Complex Mammalian Traits,1995, Bar Harbor, ME. We thank Dr. Steve R. Mitchell for his helpwith the QTL analyses, Dr. Jeffrey S. Mogil for his suggestionson the preparation of this manuscript, and Dr. Charlie Meshulfor his helpful discussions.

Correspondence should be addressed to Judith E. Grisel, Research Service, 151W, Department of Veterans Affairs Medical Center,3710 SW U.S. Veterans Hospital Road, Portland, OR 97201.

REFERENCES

Albanese A, Gozzo S, Iacopino C, Altavista MC (1985) Strain-dependent variations in the number of forebrain cholinergic neurons. Brain Res 334:380-384 . [Web of Science][Medline]
Akagi H, Sakamoto M, Shinjyo C, Shimada H, Fujimura T (1994) A unique sequence located downstream from the rice mitochondrial atp6 may cause male sterility. Curr Genet 25:52-58 . [Web of Science][Medline]
Balsara JJ, Muley MP, Vaidya AS, Chandorkar AG (1981) Effects of baclofen on dopamine-dependent behaviors in mice. Psychopharmacology 75:396-399 . [Medline]
Belknap JK, Metten P, Helms ML, O'Toole LA, Angeli-Gade S, Crabbe JC, Phillips TJ (1993) Quantitative trait loci (QTL) applications to substances of abuse: physical dependence studies with nitrous oxide and ethanol in BXD mice. Behav Genet 23:213-222 . [Web of Science][Medline]
Belknap JK, Mitchell SR, O'Toole LA, Helms ML, Crabbe JC (1996a) Type I and type II error rates for quantitative trait loci (QTL) mapping studies using recombinant inbred mouse strains. Behav Genet 26:149-160 . [Web of Science][Medline]
Belknap JK, Dubay C, Crabbe JC, Buck KJ (1996b) Mapping quantitative trait loci for behavioral traits in the mouse. In: Handbook of psychiatric genetics (Blum K, Noble E, eds), Ch 25. Boca Raton, FL: CRC.
Berettini WH, Ferraro TN, Alexander RC, Buchberg AM, Vogel WH (1994) Quantitative trait loci mapping of three loci controlling morphine preference using inbred mouse strains. Nature Genet 7:54-58. [Web of Science][Medline]
Broadhurst PL (1978) In: Drugs and the inheritance of behaviour. New York: Plenum.
Cabib S, Zocchi A, Puglisi-Allegra S (1995) A comparison of the behavioral effects of minaprine, amphetamine and stress. Psychopharmacology 121:73-80 . [Medline]
Carlton MB, Colledge WH, Evans MJ (1995) Generation of a pseudogene during retroviral infection. Mamm Genet 6:90-95.
Copeland NG, Jenkins NA, Gilbert DJ, Eppig JT, Maltais LJ, Miller JC, Dietrich WF, Weaver A, Lincoln SE, Steen RG, Stein LD, Nadeau JH, Lander ES (1993) A genetic linkage map of the mouse: current applications and future prospects. Science 262:57-66 . [Abstract/Free Full Text]
Crabbe JC (1986) Genetic differences in locomotor activation in mice. Pharmacol Biochem Behav 25:289-292 . [Web of Science][Medline]
Crabbe JC, Belknap JK (1993) Behavior genetic analyses of drug withdrawal. Alcohol Alcoholism Suppl 2:477-482 . [Medline]
Crabbe JC Harris RA editors (1991) In: The genetic basis of alcohol and drug actions. New York: Plenum.
Crabbe JC, Belknap JK, Buck KJ (1994) Genetic animal models of alcohol and drug abuse. Science 264:1715-1723 . [Abstract/Free Full Text]
Dains KM (1995) Genetics and the organization of cholinergic neurons in the mouse caudate-putamen. PhD dissertation, SUNY v.
de Wit H, Uhlenhuth EH, Johanson CE (1986) Individual differences in the reinforcing and subjective effects of amphetamine and diazepam. Drug Alcohol Depend 16:341-60 . [Web of Science][Medline]
Durkin T, Ayad G, Ebel A, Mandel P (1977) Regional acetylcholine turnover rates in the brains of three inbred strains of mice: correlation with some interstrain behavioral differences. Brain Res 136:475-486 . [Web of Science][Medline]
Ebel A, Hermetet JC, Mandel P (1973) Comparative study of acetylcholinesterase and choline acetyltransferase enzyme activity in brains of DBA and C57 mice. Nature New Biol 242:56-58 . [Web of Science][Medline]
Florin SM, Kuczenski R, Segal DS (1992) Amphetamine-induced changes in behavior and caudate extracellular acetylcholine. Brain Res 581:53-58 . [Web of Science][Medline]
Gora-Maslak G, McClearn GE, Crabbe JC, Phillips TJ, Belknap JK, Plomin R (1991) Use of recombinant inbred strains to identify quantitative trait loci in psychopharmacology. Psychopharmacology 104:413-424 . [Medline]
Graybiel AM (1990) Neurotransmitters and neuromodulators in the basal ganglia. Trends Neurosci 13:241-244. [Web of Science][Medline]
Groves PM, Rebec GV (1976) Biochemistry and behavior: some central actions of amphetamine and antipsychotic drugs. Annu Rev Psychol 27:91-127 . [Web of Science][Medline]
Groves PM, Garcia-Munoz M, Linder JC, Manley MS, Martone MM, Young SJ (1995) Elements of the intrinsic organization and information processing in the neostriatum. In: Models of information processing in the basal ganglia (Houk JC, Davis JL, Beiser DG, eds), pp 51-96. Cambridge MA: MIT.
Hegmann JP, Possidente B (1981) Estimating genetic correlations from inbred strains. Behav Genet 11:103-114 . [Web of Science][Medline]
Hernandez L, Lee F, Hoebel BG (1987) Simultaneous microdialysis and amphetamine infusion in the nucleus accumbens and striatum of freely moving rats: increase in extracellular dopamine and serotonin. Brain Res Bull 19:623-628 . [Web of Science][Medline]
Iacopino C, Altavista MC, Gozzo S, Albanese A (1986) Qualitative pharmacohistochemistry of acetylcholinesterase in the neostriatum of inbred mouse strains. Brain Res 374:402-408 . [Web of Science][Medline]
Isamat M, Macleod KF, King A, McEwan C, Melton DW (1988) Characterization, evolutionary relationships and chromosome location of processed mouse HPRT pseudogene. Cell Mol Genet 14:359-369.
Jaworska-Feil L, Budziszewska B, Lason W (1995) The effects of repeated amphetamine administration on the thyrotropin-releasing hormone level: its release and receptors in the rat brain. Neuropeptides 29:171-176 . [Web of Science][Medline]
Jellinek P (1971) Dual effect of dexamphetamine on body temperature in the rat. Eur J Pharmacol 15:389-392 . [Web of Science][Medline]
Jinnah HA, Gage FH, Friedmann T (1991) Amphetamine-induced behavioral phenotype in a hyposanthine-guanine phosphoribosyltransferase-deficient mouse model of Lesch-Nyhan syndrome. Behav Neurosci 105:1004-1012 . [Web of Science][Medline]
Joshi VV, Balsara JJ, Jadhav JH, Chandorkar AG (1981) Effect of L-histidine and chlorcyclizine on apomorphine-induced climbing behaviour and methamphetamine stereotypy in mice. Eur J Pharmacol 69:499-502 . [Web of Science][Medline]
Karler R, Calder LD, Thai LH, Bedingfield JB (1994) The dopaminergic-glutamatergic, basis for the action of amphetamine and cocaine. Brain Res 658:8-14 . [Web of Science][Medline]
Karler R, Calder LD, Thai LH, Bedingfield JB (1995) The dopaminergic, glutamatergic, GABAergic bases for the action of amphetamine and cocaine. Brain Res 671:100-104 . [Web of Science][Medline]
Kas K, Stickens D, Merregaert J (1995) Characterization of a processed pseudogene of human FAU1 on chromosome 18. Gene 160:273-276 . [Web of Science][Medline]
Kitahama K, Valatx J-L (1979) Strain differences in amphetamine sensitivity in mice. I. A diallel analysis of open field activity. Psychopharmacology 66:189-194 . [Medline]
Kuczenski R (1986) Dose response for amphetamine-induced changes in dopamine levels in push-pull perfusates of rat striatum. J Neurochem 46:1605-1611 . [Web of Science][Medline]
Kuczenski R, Segal DS (1989) Concomitant characterization of behavioral and striatal neurotransmitter response to amphetamine using in vivo microdialysis. J Neurosci 9:2051-2065 . [Abstract]
Kuczenski R, Segal DS (1990) In vivo measures of monoamines during amphetamine-induced behaviors in rats. Prog Neuropsychopharmacol Biol Psychiatry 14:S37-S50 .
Kuczenski R, Schmidt D, Leith N (1977) Amphetamine-haloperidol interactions in rat striatum: failure to correlate behavioral effects with dopaminergic and cholinergic dynamics. Brain Res 126:117-129 . [Web of Science][Medline]
Kuczenski R, Segal DS, Aizenstein ML (1991) Amphetamine, cocaine and fencamfamine: relationship between locomotor and stereotypy response profiles and caudate and accumbens dopamine dynamics. J Neurosci 11:2703-2712 . [Abstract]
Lander E, Kruglyak L (1995) Genetic dissection of complex traits: guidelines for interpreting and reporting linkage results. Nature Genet 11:241-247 . [Web of Science][Medline]
Leedman PJ, Stein AR, Chin WW (1995) Regulated specific protein binding to a conserved region of the 3 $'$ -untranslated region of thyrotropin $beta$ -subunit mRNA. Mol Endocrinol 9:375-387 . [Abstract/Free Full Text]
Li WH, Graur D (1991) In: Fundamentals of molecular evolution. Sunderland, MA: Sinauer.
Liljequist S, Karcz-Kubicha M (1993) Genetic aspects on the effects of ethanol and central stimulants on locomotor activity and brain dopamine metabolism in mice. Alcohol Alcoholism Suppl 2:457-461 . [Medline]
Manjanatha MG, Lindsey LA, Mittelstaedt RA, Heflich RH (1994) Low hprt mRNA levels and multiple hprt mRNA species in 6-thioguanine-resistant Chinese hamster cell mutants possessing nonsense mutations. Mutation Res 308:65-75 .
Marcais H, Protais P, Costentin J, Schwartz JC (1978) A gradual score to evaluate the climbing behaviour elicited by apomorphine in mice. Psychopharmacology 56:233-234 . [Medline]
Melo JA, Shendure J, Pociask K, Silver LM (1996) Identification of sex-specific quantitative trait loci controlling alcohol preference in C57BL/6 mice. Nature Genet 13:147-153 . [Web of Science][Medline]
Miner LL, Marley RJ (1995) Chromosomal mapping of the psychomotor stimulant effects of cocaine in BXD recombinant inbred mice. Psychopharmacology 122:209-214 . [Medline]
Phillips TJ, Crabbe JC, Metten P, Belknap JK Localization of genes affecting alcohol drinking in mice. Alcohol Clin Exp Res 18:931-941.
Localization Protais P, Costentin J, Schwartz JC (1976) Climbing behavior induced by apomorphine in mice: a simple test for the study of dopamine receptors in striatum. Psychopharmacology 50:1-6. [Medline]
Randrup A, Munkvad I (1967) Stereotyped activities produce by amphetamine in several animal species and man. Psychopharmacologia 11:300-310 .
Randrup A, Munkvad I, Fog R, Ayhan IH (1975) Catecholamines in activation, stereotypy, and level of mood. In: Catecholamines and behavior, Vol 1 (Friedhoff AJ, ed), pp 89-107. New York: Plenum.
Rodriguez LA, Plomin R, Blizard DA, Jones BC, McClearn GE (1995) Alcohol acceptance, preference, and sensitivity in mice. II. Quantitative trait loci mapping analysis using BXD recombinant inbred strains. Alcohol Clin Exp Res 19:367-373 . [Web of Science][Medline]
Schwab C, Bruckner G, Castellano C, Oliverio A, Biesold D (1990) Regional cholinergic differences in the brains of DBA/2 and C57BL/6 mice: a morphological study during ontogeny. Dementia 1:74-78.
Seale TW (1991) Genetic differences in response to cocaine and stimulant drugs. In: The genetic basis of alcohol and drug actions (Crabbe JC, Harris RA, eds), pp 279-321. New York: Plenum.
Seale TW, Carney JM, Johnson P, Rennert OM (1985) Inheritance of amphetamine-induced thermoregulatory responses in inbred mice. Pharmacol Biochem Behav 23:373-377 . [Web of Science][Medline]
Silver LM, Nadeau JH, Goodfellow PN, editors (1994) Mamm Genome 5.
Tolliver BK, Belknap JK, Woods WE, Carney JM (1994) Genetic analysis of sensitization and tolerance to cocaine. J Pharmacol Exp Ther 270:1230-1238 . [Abstract/Free Full Text]
Wise RA (1978) Catecholamine theories of reward: a critical review. Brain Res 152:215-217 . [Web of Science][Medline]
Wise RA (1987) The role of reward pathways in the development of drug dependence. Pharmacol Ther 35:227-263 . [Web of Science][Medline]
Zhou BS, Beidler DR, Cheng YC (1992) Identification of antisense RNA transcripts from a human DNA topoisomerase I pseudogene. Cancer Res 52:4280-4285 . [Abstract/Free Full Text]

Copyright ©1997 Society for Neuroscience   0270-6474/1997/17745-10$05.00/0

This article has been cited by other articles:

G. Burgio, M. Szatanik, J.-L. Guenet, M.-R. Arnau, J.-J. Panthier, and X. Montagutelli
Interspecific Recombinant Congenic Strains Between C57BL/6 and Mice of the Mus spretus Species: A Powerful Tool to Dissect Genetic Control of Complex Traits
Genetics, December 1, 2007; 177(4): 2321 - 2333.
[Abstract] [Full Text] [PDF]

A. Lionikas, D. A. Blizard, D. J. Vandenbergh, M. G. Glover, J. T. Stout, G. P. Vogler, G. E. McClearn, and L. Larsson
Genetic architecture of fast- and slow-twitch skeletal muscle weight in 200-day-old mice of the C57BL/6J and DBA/2J lineage
Physiol Genomics, December 16, 2003; 16(1): 141 - 152.
[Abstract] [Full Text] [PDF]

I. Nishimura, T. A. Drake, A. J. Lusis, K. M. Lyons, J. H. Nadeau, and J. Zernik
ENU LARGE-SCALE MUTAGENESIS AND QUANTITATIVE TRAIT LINKAGE (QTL) ANALYSIS IN MICE: NOVEL TECHNOLOGIES FOR SEARCHING POLYGENETIC DETERMINANTS OF CRANIOFACIAL ABNORMALITIES
Critical Reviews in Oral Biology & Medicine, September 1, 2003; 14(5): 320 - 330.
[Abstract] [Full Text] [PDF]

M. J. Ryan, S. P. Didion, D. R. Davis, F. M. Faraci, and C. D. Sigmund
Endothelial Dysfunction and Blood Pressure Variability in Selected Inbred Mouse Strains
Arterioscler Thromb Vasc Biol, January 1, 2002; 22(1): 42 - 48.
[Abstract] [Full Text] [PDF]

A. Janowsky, C. Mah, R. A. Johnson, C. L. Cunningham, T. J. Phillips, J. C. Crabbe, A. J. Eshleman, and J. K. Belknap
Mapping Genes That Regulate Density of Dopamine Transporters and Correlated Behaviors in Recombinant Inbred Mice
J. Pharmacol. Exp. Ther., August 1, 2001; 298(2): 634 - 643.
[Abstract] [Full Text] [PDF]

J. P. Wisor, S. Nishino, I. Sora, G. H. Uhl, E. Mignot, and D. M. Edgar
Dopaminergic Role in Stimulant-Induced Wakefulness
J. Neurosci., March 1, 2001; 21(5): 1787 - 1794.
[Abstract] [Full Text] [PDF]

J. C. Crabbe
Provisional Mapping of Quantitative Trait Loci for Chronic Ethanol Withdrawal Severity in BXD Recombinant Inbred Mice
J. Pharmacol. Exp. Ther., July 1, 1998; 286(1): 263 - 271.
[Abstract] [Full Text]

T. J. Phillips, M. G. Huson, and C. S. McKinnon
Localization of Genes Mediating Acute and Sensitized Locomotor Responses to Cocaine in BXD/Ty Recombinant Inbred Mice
J. Neurosci., April 15, 1998; 18(8): 3023 - 3034.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (39)

Citing Articles via Google Scholar

Google Scholar

Articles by Grisel, J. E.

Articles by Crabbe, J. C.

Search for Related Content

PubMed

PubMed Citation

Articles by Grisel, J. E.

Articles by Crabbe, J. C.

Pubmed/NCBI databases
Gene GEO Profiles
HomoloGene Protein
UniGene
Compound via MeSH
Substance via MeSH
Hazardous Substances DB
d-METHAMPHETAMINE
Medline Plus Health Information
Methamphetamine