Association of the Glutamate Transporter Gene SLC1A1 With Atypical Antipsychotics-Induced Obsessive-compulsive Symptoms

doi:10.1001/archgenpsychiatry.2009.155

You are seeing this message because your Web browser does not support basic Web standards. Find out more about why this message is appearing and what you can do to make your experience on this site better.

Vol. 66 No. 11, November 2009

Online Only
	•	Online First Table of Contents

Original Article

•	Online Features

This Article
•	Abstract
•	PDF
•	Reply to article
•	Send to a friend
•	Save in My Folder
•	Save to citation manager
•	Permissions

Citing Articles
•	Citation map
•	Citing articles on Web of Science (12)
•	Contact me when this article is cited

Related Content
•	Related article
•	Similar articles in this journal

Topic Collections
•	Psychiatry
•	Obsessive-Compulsive Disorder
•	Psychopharmacology
•	Schizophrenia
•	Drug Therapy
•	Adverse Effects
•	Drug Therapy, Other
•	Genetics
•	Genetic Disorders
•	Alert me on articles by topic

Social Bookmarking
	What's this?

Association of the Glutamate Transporter Gene SLC1A1 With Atypical Antipsychotics–Induced Obsessive-compulsive Symptoms

Jun Soo Kwon, MD, PhD; Yeon Ho Joo, MD, PhD; Hee Jung Nam, MD; Meerae Lim, MD; Eun-Young Cho, MS; Myung Hun Jung, MD; Jung-Seok Choi, MD; Byungsu Kim, MD, PhD; Do-Hyung Kang, MD; Sohee Oh, MS; Taesung Park, PhD; Kyung Sue Hong, MD, PhD

Arch Gen Psychiatry. 2009;66(11):1233-1241.

ABSTRACT

Context Several studies have indicated that atypical antipsychotics(AAP) induce obsessive-compulsive (OC) symptoms. Research exploringthe mechanism of this phenomenon, however, has been extremelylimited. Considering the indirect evidence of genetic controland difficulties in developing animal models and performinggene expression studies, genetic association studies could bean important approach to understanding the molecular mechanismof AAP-induced OC symptoms. The glutamate transporter gene SLC1A1,which was recently reported to be associated with obsessive-compulsivedisorder (OCD), is a promising candidate gene for susceptibilityto AAP-induced OC symptoms.

Objective To determine whether polymorphisms in SLC1A1are associated with AAP-induced OC symptoms in patients withschizophrenia.

Design A pharmacogenetic case-control association study.

Setting Outpatient schizophrenia clinics.

Patients Clinically stable patients with schizophreniawho were receiving AAP treatment (n = 94; OC group).The OC group consisted of 40 patients with AAP-induced OC symptoms,and the non-OC group consisted of 54 patients who had receivedAAP for more than 24 months without developing OC symptoms.

Main Outcome Measures Allele, genotype, and haplotypefrequencies. The association was tested with a logistic regressionmodel using age, sex, and medication type as covariates.

Results Trends of association were observed in rs2228622and rs3780412 (nominal P = .01; adjusted permutationP = .07) for the dominant model that was the inheritancemodel that best fit our data. In the haplotype -based analysis,the A/C/G haplotype at rs2228622-rs3780413-rs3780412 showeda significant association with AAP-induced OC symptoms; thisassociation withstood multiple test correction (nominal P = .01;adjusted permutation P = .04; odds ratio, 3.955;95% confidence interval, 1.366-11.452, for dominant model).

Conclusions These results suggest that sequence variationsin SLC1A1 are associated with susceptibility to AAP-inducedOC symptoms. This is the first published pharmacogenetic studyon this phenomenon and provides preliminary evidence of theinvolvement of glutamatergic neurotransmission in the pathogenesisof AAP-induced OC symptoms.

INTRODUCTION

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

Since the introduction of atypical antipsychotics (AAP), bothcase reports^1-6 and clinical studies^7-9 have described the denovo onset of obsessive-compulsive (OC) symptoms during treatmentwith these drugs. In a previous investigation, we screened 209clinically stable outpatients with schizophrenia who were receivingAAP and found that 12.4% showed AAP-induced OC symptoms.¹⁰

It is widely accepted that genetic factors play an importantrole in an individual's susceptibility to various AAP adverseeffects,^11-12 and this assumption is the theoretical basis ofpharmacogenetic studies. Nonetheless, heritability data forantipsychotic drug responses are extremely limited because ofdifficulties recruiting twin pairs who have received the sameAAP treatment. We recently described clozapine-induced OC symptomsthat emerged concordantly in a pair of monozygotic twins, whichsuggests the influence of genetic factors on this adverse effect.¹³Strong evidence of heritability has been shown by family andtwin studies of obsessive-compulsive disorder (OCD).^14-17 Consideringthe indirect evidence of genetic control on AAP-induced OC symptomsand difficulties in developing animal models and performinggene expression studies, genetic association studies with candidategenes could play a pivotal role in exploring the molecular mechanismof AAP-induced OC symptoms.

Implications of the glutamatergic system in the developmentof OC symptoms were suggested by a few biological studies ofpatients with OCD, including magnetic resonance spectroscopystudies.^18-20 The glutamate transporter gene SLC1A1 (OMIM 133550),which is located on chromosome 9p24, is regarded as a positionaland functional candidate gene for vulnerability to OCD.²¹ Recently,polymorphisms in the SLC1A1 gene were reported to be associatedwith OCD by 3 independent studies.^22-24 SLC1A1 codes for theglutamate transporter excitatory amino acid carrier 1 (EAAC1),which maintains extracellular glutamate concentrations by reuptakeof synaptically released glutamate.²⁵ Excitatory amino acidcarrier 1 is highly expressed in the cerebral cortex, striatum,and thalamus, regions that might be involved in the pathogenesisof OC symptoms. Regarding the relationship between EAAC1 andAAP, significant downregulation of EAAC1 by chronic treatmentwith clozapine was observed in the cingulate cortex of the ratbrain.²⁶ Changes in transcript expression of excitatory aminoacid transporter–interacting protein, which modulatessubcellular localization and activity of the excitatory aminoacid transporters, including EAAC1, were also described in clozapine-treatedrats.²⁷ In animal studies that investigated the effects of AAPon the glutamatergic system, clozapine treatment enhanced K⁺-stimulatedglutamate release²⁸ and upregulated N-methyl-D-aspartate receptorbinding²⁹ in the nucleus accumbens of rat brain. Increased expressionof vesicular glutamate transporter mRNA³⁰ and decreased N-methyl-D-aspartatebinding³¹ by risperidone treatment were also reported. Consideringthe evidence of a biological relationship between the glutamatergicsystem and both OC symptoms and AAP, SLC1A1 is a promising candidategene for susceptibility to AAP-induced OC symptoms.

This study aimed to determine whether polymorphisms in SLC1A1are associated with AAP-induced OC symptoms in patients withschizophrenia. Genotype and haplotype frequencies were investigatedin the OC and non-OC groups for 10 single-nucleotide polymorphisms(SNPs) in the 3' region of SLC1A1 including SNPs that showedsignificant association with OCD in previous studies.^22-24 AsAAP-induced OC symptoms are most frequently observed in clozapine-treatedpatients,^{1, 8, 10} we performed a subgroup analysis for clozapine-inducedOC symptoms. To the best of our knowledge, this is the firstpharmacogenetic study investigating AAP-induced OC symptoms.

METHODS

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

SUBJECTS

Subjects consisted of an OC group (patients with schizophreniawith AAP-induced OC symptoms) and a non-OC group (patients withschizophrenia without OC symptoms). Subject recruitment wasperformed at the schizophrenia clinics of Samsung Medical Center,Seoul National University Hospital, and Asan Medical Center.Clinically stable patients with DSM-IV–diagnosed schizophreniawho were receiving AAP and were capable of providing reliableinformation regarding their symptoms were included in the screeningof OC symptoms. At each center, 2 trained psychiatrists (ofJ.S.K., Y.H.J., M.L., M.H.J., J.-S.C., B.K., and K.S.H.) performedclinical interviews, and the assessment processes were standardizedacross sites. To screen for the presence of OC symptoms, directinterviews using the Korean version of the Structured ClinicalInterview Schedule for DSM-IV Axis I Disorder³² and assessmentusing the Korean version of the Yale-Brown Obsessive CompulsiveScale^33-35 were performed for each patient by 2 psychiatristsindependently. In addition, collateral information from availablefamily members of the patients and hospital records were usedto identify whether OC symptoms emerged de novo on AAP. Thefinal decision on AAP-induced OC symptoms was made by consensusbetween the 2 raters and required the following criteria: (1)OC symptoms developed de novo while receiving AAP, (2) all ofthe criteria for DSM-IV-diagnosed OCD except for criteria C(description of severity) and E (exclusion of drug-induced cases)were met, and (3) OC symptoms were not the direct result ofdelusions, and their contents were clearly different from residualpsychotic symptoms. Forty patients were included in the OC group.The non-OC group included 54 patients matched by sex and medicine(type of AAP) who had been receiving AAP for more than 24 monthsand had not developed any OC symptoms. One hundred controlswere also included in this study to obtain data on Hardy-Weinbergequilibrium and haplotype structures of SNP markers. All ofthe subjects (OC and non-OC patient groups and controls) wereethnically Korean, which was ascertained by asking the ethnicityof both parents.

This study was approved by the institutional review boards ofSamsung Medical Center, Seoul National University Hospital,and Asan Medical Center, and written informed consent was obtainedfrom all subjects.

SNP SELECTION AND GENOTYPING

Thirteen SNPs spanning 25 kB toward the 3' end of the SLC1A1gene were selected for genotyping. Nine showed significant associationwith OCD in previous studies^22-24 (Figure 1). Four SNPs wereadditionally selected in this region considering minor allelefrequencies (http://www.hapmap.org/, Release 22/Phase II, April2007, on National Center for Biotechnology Information B36 Assembly)and intermarker distances between markers (http://genome.ucsc.edu/,March 2006 Assembly). Genomic DNA was extracted from peripheralblood using a Wizard Genomic DNA purification kit (Promega,Madison, Wisconsin) following the manufacturer's protocol. ThreeSNPs (rs10974625, rs3780412, and rs301430) were genotyped bysingle-base primer extension assay using the ABI PRISM SNaPshotMultiplex kit (Applied Biosystems, Foster City, California),and the other SNPs were genotyped by sequencing reaction usingABI PRISM BigDye Terminator v3.1 Cycle Sequencing Kits (AppliedBiosystems). In both analyses, electrophoresis was done usingthe ABI PRISM 3100 Genetic Analyzer (Applied Biosystems). Genotypeswere measured using Gene Scan analysis software (Applied Biosystems)for single-base primer extension assays, and Sequencher v4.1.4software (Gene Codes, Ann Arbor, Michigan) for sequencing reactions.All markers were typed successfully in all subjects.

View larger version (30K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 1. SLC1A1 organization and single-nucleotide polymorphism (SNP) locations (from the University of California at Santa Cruz Genome Browser, March 2006 Assembly). The horizontal line represents the genomic sequence and vertical bars represent exons. Plus signs and circles denote SNPs significantly associated with obsessive-compulsive disorder in single-marker and haplotype analyses of previous studies,^22-24 respectively, with asterisks representing SNPs included in the current association study of atypical antipsychotics–induced obsessive-compulsive symptoms.

STATISTICAL ANALYSIS

Differences in demographic and clinical variables between OCand non-OC groups were tested using a t test or ${chi}$ ² test. We evaluatedthe Hardy-Weinberg equilibrium of 13 SNPs using genotype datafrom controls. Because linkage disequilibrium (LD) analysisshowed that 3 pairs of SNPs were in perfect linkage equilibrium,1 from each pair (rs7871691, rs7042333, and rs301435) was excludedfrom the analysis. Ten SNPs were used in the final statisticalanalysis (Table 1; Figure 1).

View this table:
[in this window]
[in a new window]
[as a PowerPoint slide]

Table 1. Characteristics of SNP Markers on SLC1A1

The allelic and genotypic association between SNPs and AAP-inducedOC symptoms was initially tested using Pearson ${chi}$ ² test or Fisherexact test (depending on the sample sizes of individual cells).Our main analysis used to test for association was logisticregression, which controls for possible confounding effects.In this analysis, sex, age, and medicine (type of antipsychoticdrug) were used as model covariates. For the genetic model,we considered 4 types— additive, codominant, dominant,and recessive—based on the minor allele of each SNP. Theinheritance model with the least Akaike Information Criterion³⁶was accepted as the best-fitting model.

Haploview v4.0 (http://www.broadinstitute.org/haploview/haploview)³⁷was used to estimate pairwise LD of SNP markers. The defaultconfidence interval algorithm of the Haploview program identified1 haplotype block consisting of SNP7 (rs301430) and SNP8 (rs301979)from the OC and non-OC patient group data (Figure 2). Anotherhaplotype block consisting of SNP2 (rs2228622), SNP3 (rs3780413),and SNP4 (rs3780412) was added in the analysis, consideringstrong pairwise LD between markers (D' $≥$ 0.88) and results ofsingle-marker analysis. In each of the 3 subject groups (OC,non-OC, and control), SNPs within the same haplotype block showedstrong pairwise LD (D' $≥$ 0.79 for SNP2/SNP3/SNP4 block and D' $≥$ 0.84 for SNP7/SNP8 block) with a low LD gap between these 2haplotype blocks. Haplotypes of individual subjects were estimatedusing SAS/Genetics haplotype procedure (SAS Institute Inc, Cary,North Carolina). Logistic regression was applied to test theassociation between haplotypes and AAP-induced OC symptoms.To use this regression model with haplotype data, ambiguityof haplotypes was additionally adjusted using each subject'sprobability of having a particular haplotype pair. The mostfrequent haplotype was automatically selected as the referencecategory, and rare haplotypes (haplotype frequency $≤$ 0.05) werepooled together in a group.

View larger version (37K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 2. Linkage disequilibrium (LD) structure of the single-nucleotide polymorphisms and haplotype blocks analyzed in the current study. The number, in each LD indicates the value of D' (D' = 1 not shown) calculated from patient (both obsessive-compulsive [OC] and non-OC groups) data. Block 2 is determined using the default confidence interval algorithm of Haploview 4.0. Block 1 is an additional block including SNPs that show significant association with atypical antipsychotics–induced OC symptoms in single-marker analysis, and having high intermarker LD (D' $≥$ 0.88).

Considering multiple comparisons, we performed 10 000 permutationsand obtained an adjusted P value for each analysis. We adoptedthe step-down minP multiple testing procedure proposed by Westfalland Young³⁸ and Ge et al.³⁹

Identical association tests were applied for a subgroup of patientsreceiving clozapine (32 in the OC group and 43 in the non-OCgroup).

Statistical analyses were performed using SAS version 9.1 (SASInstitute Inc). P values of less than .05 were considered statisticallysignificant.

RESULTS

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

Demographic and clinical characteristics of the 2 patient groupsare presented in Table 2. Patients in the OC group were youngerthan those in the non-OC group. There was no difference in durationof illness, clinical subtype, type of AAP, and mean maximumdaily dose of each drug that has ever been reached between theOC and non-OC groups. The mean (SD) score of Yale-Brown ObsessiveCompulsive Scale for the OC group was 14.89 (6.65).

View this table:
[in this window]
[in a new window]
[as a PowerPoint slide]

Table 2. Demographic and Clinical Characteristics of Subjects

For all 10 SNPs used in the analysis, no significant deviationfrom Hardy-Weinberg equilibrium was observed in the controls(Table 1). Table 3 shows results of allelic and genotypic associationanalyses using a simple ${chi}$ ² (or Fisher exact) test without controllingfor possible confounding effects of demographic or clinicalvariables. Single nucleotide polymorphisms 2 (rs2228622) and4 (rs3780412) showed an association with AAP-induced OC symptoms.However, no marker reached the level of significance after applyingmultiple test correction in the permutation tests.

View this table:
[in this window]
[in a new window]
[as a PowerPoint slide]

Table 3. Genotypic and Allelic Association Analysis

In the logistic regression that controlled for confounding effectsof age, sex, and medicine (Table 4), trends of association wereobserved in SNP2 (nominal P = .01; adjusted permutationP = .07) for dominant and codominant models (nominalP = .007; adjusted permutation P = .06)and SNP4 for dominant models (nominal P = .02; adjustedpermutation P = .09). As represented in the AkaikeInformation Criterion values, the dominant model was acceptedas the best inheritance model fitting our data for both SNP2and SNP4. Other SNPs did not show any trend of association withAAP-induced OC symptoms.

View this table:
[in this window]
[in a new window]
[as a PowerPoint slide]

Table 4. Association Analysis of AAP-Induced OC Symptoms With SNP2 and SNP4 on SLC1A1 Using Logistic Regression Model Adjusted for Age, Sex, and Type of Medicine

In the haplotype-based logistic regression analysis, an associationwith nominal P < .05 was observed for the A/C/Ghaplotype of the SNP2/SNP3/SNP4 block in additive, codominant,and dominant models (nominal P = .04, P = .006,and P = .01, respectively) (Table 5). The dominantmodel showed the lowest Akaike Information Criterion value andwas accepted as the best inheritance model. The other haplotypeblock (SNP7/SNP8) did not show any association with AAP-inducedOC symptoms. In permutation tests adjusting for multiple comparisons,the association between A/C/G haplotype of SNP2/SNP3/SNP4 andAAP-induced OC symptoms remained significant for dominant andcodominant models.

View this table:
[in this window]
[in a new window]
[as a PowerPoint slide]

Table 5. Association Analysis of AAP-Induced OC Symptoms With Haplotype (SNP2/SNP3/SNP4) Block on SLC1A1 Using Logistic Regression Model Adjusted for Age, Sex, and Type of Medicine

In the subgroup of patients receiving clozapine treatment, allelicand genotypic association was observed in SNP2 ( ${chi}$ ² = 4.906,P = .03 for allelic association; ${chi}$ ² = 7.074,P = .02 for genotypic association) and SNP4 ( ${chi}$ ² = 5.900,P = .02 for allelic association; ${chi}$ ² = 6.214,P = .04 for genotypic association). However, no markerreached statistical significance after applying multiple testcorrection. Regression analysis showed trends of associationin SNP2 for dominant (nominal P = .01; adjusted permutationP = .07) and codominant (nominal P = .01;adjusted permutation P = .07) models (Table 4). Inthe haplotype-based analysis, association of the A/C/G haplotypeof SNP2/SNP3/SNP4 block and clozapine-induced OC symptoms wasobserved in the additive, codominant, and dominant models (nominalP = .02, P = .008, and P = .02,respectively) (Table 5). After adjusting for multiple comparisonsin the permutation test, significant association remained forthe codominant model.

COMMENT

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

Several lines of evidence indicate that AAP induces or aggravatesOC symptoms.^1-9 To the best of our knowledge, however, therehas been no pharmacogenetic study that explored candidate genesinvolved in this adverse drug reaction. In the present study,we investigated the relation between AAP-induced OC symptomsand 10 SNPs in the SLC1A1 gene that was recently reported tobe associated with OCDs in 3 independent studies.^22-24

Obsessive-compulsive symptoms can be observed in patients invarious stages of schizophrenia,^40-41 ie, before the onset ofillness, in the active psychotic phase, and after stabilizationby pharmacotherapy. To limit the phenotype of the current studyto drug-associated OC symptoms, we applied strict inclusioncriteria, ie, de novo onset of OC symptoms during AAP treatmentand OC symptoms of an ego-dystonic nature, reported by clinicallystable patients, that could be clearly differentiated from delusionsor other residual psychotic symptoms. According to a summaryof 55 reported cases,¹ the duration of AAP medication at theonset of AAP-induced OC symptoms ranged from a few weeks to15 months. Therefore, we included patients who had been receivingAAP for more than 24 months without development of any OC symptomsin the non-OC group. Because AAP-induced OC symptoms showedpreponderance in men and were most frequently observed in clozapine-treatedpatients,^{1, 8, 10} we tried to match sex and type of AAP betweenthe OC and non-OC groups. We also controlled for these variablesin the logistic regression model used in the analysis. In addition,we analyzed patients receiving clozapine separately.

Trends of association were detected between AAP-induced OC symptomsand SNP2 (rs2228622) and SNP4 (rs3780412). These 2 SNPs aretightly linked within the same haplotype block (SNP2/SNP3/SNP4)of SLC1A1, and the A/C/G haplotype of this block showed significantassociation with AAP-induced OC symptoms, which withstood multipletest correction. The haplotype association indicated that theodds of AAP-induced OC symptoms are 3.96 times higher in patientswho have the A/C/G haplotype than in patients who have the referencehaplotype (G/C/A, most frequent haplotype; frequency, 0.44)(odds ratio, 3.955; 95% confidence interval, 1.366-11.452).The same nature of association was observed in the separateanalysis of the subgroup of patients receiving clozapine treatment.

Interestingly, the associated SNPs (SNP2 and SNP4) in the presentstudy are identical to the SNPs that showed significant associationwith OCD in the investigation of Stewart et al,²⁴ and one ofthem (SNP4) was also associated with OCD in another study.²³Single-nucleotide polymorphism 2 is a synonymous SNP locatedin exon 4, and SNP4 is an intronic SNP. The possible functionaleffects of these SNPs have not yet been investigated. If thepolymorphisms do not directly confer susceptibility to AAP-inducedOC symptoms, they might be in LD with nearby functional SNPs.Genotyping of additional polymorphisms and extensive sequencingin this region are warranted to clarify the causative variants.Given that clozapine showed the strongest potential to induceOC symptoms of the AAP and was reported to downregulate EAAC1in the cingulate cortex of rat brain,²⁶ and given the indirectevidence that other antipsychotic drugs also affect the glutamatergicsystem,^{29, 42-43} the etiologic connection between the SLC1A1gene and molecular mechanisms of AAP-induced OC symptoms needsto be more intensively pursued.

The present study has certain methodological limitations. First,the possibility that patients in the non-OC group (defined aslacking OC symptoms after 24 months of treatment) would laterdevelop OC symptoms could not be ruled out because there hasbeen no systematic evaluation of the duration of medicationbefore the onset of AAP. Delayed onset of phenotypes might bean inevitable confounding factor in genetic studies. Second,considering the small sample size and adoption of multiple testcorrections, this study might be vulnerable to type II error.Replication studies in independent samples are required. Third,we investigated only 1 gene implicated in OCD. There might bea large number of functional candidate genes for AAP-inducedOC symptoms, eg, genes involved in the dopaminergic and serotonergicsystems that are involved in the mechanism of action of AAPs.Association studies for those genes and evaluation of gene-geneinteractions are needed in future studies. Because AAPs areused for the treatment of psychiatric disorders other than schizophrenia,association studies for a broader range of diagnoses are alsowarranted. Fourth, though all subjects in the OC and non-OCgroups were ethnically Korean, population differences betweenthe 2 groups have not been checked at the genetic level. Therefore,the possibility of a false-positive result originating fromundetected population stratification could not be completelyexcluded.

Within the above discussed limitations, the findings in thecurrent study suggest that SLC1A1 is involved in susceptibilityto developing OC symptoms in patients with schizophrenia whoare receiving AAP treatment. It is noteworthy that this is thefirst published pharmacogenetic study on this condition, andit provides preliminary evidence of the involvement of glutamatergicneurotransmission in the pathogenesis of AAP-induced OC symptoms.

AUTHOR INFORMATION

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

Correspondence: Kyung Sue Hong, MD, PhD, Department of Psychiatry,Sungkyunkwan University School of Medicine, Samsung MedicalCenter, 50 Irwon-dong, Gangnam-gu, Seoul 135-710, Korea (hongks{at}skku.edu).

Submitted for Publication: October 6, 2008; final revision receivedFebruary 25, 2009; accepted April 3, 2009.

Financial Disclosure: Dr Kwon reports having served as a consultantfor Janssen, and has received research support or honorariafrom Otsuka, Lilly Korea, Lundbeck, Dainippon Sumitomopharma,Janssen, Janssen Korea, AstraZeneca, and Pfizer. Dr Joo reportshaving served as a consultant for AstraZeneca and Pfizer, andhas received research support or honoraria from AstraZeneca,Eli Lilly, SanofiAventis, GlaxoSmithKline, Otsuka, and Pfizer.Dr Hong reports having served as an advisor for AstraZeneca,and has received research support or honoraria from Otsuka,Pfizer, AstraZeneca, Janssen, SanofiAventis, and Eli Lilly.

Funding/Support: This study was supported by grant A030001 fromthe Korea Health 21 R&D Project, Ministry of Health, Welfareand Family Affairs, Republic of Korea; the In-SungFoundationfor Medical Research; grant M10500000126 from the National ResearchLaboratory Program of Korea Science and Engineering Foundation(Dr Park); and the Brain Korea 21 Project of the Ministry ofEducation (Dr Park).

Author Affiliations: Department of Neuropsychiatry, Seoul National University College of Medicine, Seoul National University Hospital (Drs Kwon, Jung, Choi, and Kang); Brain and Cognitive Sciences, WCU Program, College of Natural Sciences, Seoul National University (Dr Kwon); Department of Psychiatry, University of Ulsan College of Medicine, Asan Medical Center (Drs Joo and Kim); Department of Psychiatry, Sungkyunkwan University School of Medicine (Drs Nam, Lim, and Hong) and Samsung Biomedical Research Institute, Samsung Medical Center (Ms Cho and Dr Hong); and Department of Statistics, Seoul National University, Seoul, Korea (Ms Oh and Dr Park).

REFERENCES

Jump to Section
•	Top
•	Introduction
•	Methods
•	Results
•	Comment
•	Author information
•	References

1. Lykouras L, Alevizos B, Michalopoulou P, Rabavilas A. Obsessive-compulsive symptoms induced by atypical antipsychotics: a review of the reported cases. Prog Neuropsychopharmacol Biol Psychiatry. 2003;27(3):333-346. FULL TEXT | PUBMED

2. Alevizos B, Papageorgiou C, Christodoulou GN. Obsessive-compulsive symptoms with olanzapine. Int J Neuropsychopharmacol. 2004;7(3):375-377. FULL TEXT | WEB OF SCIENCE | PUBMED

3. Diler RS, Yolga A, Avci A, Scahill L. Risperidone-induced obsessive-compulsive symptoms in two children. J Child Adolesc Psychopharmacol. 2003;13(suppl 1):S89-S92. FULL TEXT | WEB OF SCIENCE | PUBMED

4. Ke CL, Yen CF, Chen CC, Yang SJ, Chung W, Yang MJ. Obsessive-compulsive symptoms associated with clozapine and risperidone treatment: three case reports and review of the literature. Kaohsiung J Med Sci. 2004;20(6):295-301. FULL TEXT | PUBMED

5. Ozer S, Arsava M, Ertugrul A, Demir B. Obsessive compulsive symptoms associated with quetiapine treatment in a schizophrenic patient: a case report. Prog Neuropsychopharmacol Biol Psychiatry. 2006;30(4):724-727. FULL TEXT | PUBMED

6. Stamouli S, Lykouras L. Quetiapine-induced obsessive-compulsive symptoms: a series of five cases. J Clin Psychopharmacol. 2006;26(4):396-400. FULL TEXT | WEB OF SCIENCE | PUBMED

7. Baker RW, Chengappa KN, Baird JW, Steingard S, Christ MA, Schooler NR. Emergence of obsessive compulsive symptoms during treatment with clozapine. J Clin Psychiatry. 1992;53(12):439-442. WEB OF SCIENCE | PUBMED

8. de Haan L, Linszen DH, Gorsira R. Clozapine and obsessions in patients with recent-onset schizophrenia and other psychotic disorders. J Clin Psychiatry. 1999;60(6):364-365. WEB OF SCIENCE | PUBMED

9. Ertugrul A, Anil Yagcioglu AE, Eni N, Yazici KM. Obsessive-compulsive symptoms in clozapine-treated schizophrenic patients. Psychiatry Clin Neurosci. 2005;59(2):219-222. PUBMED

10. Lim M, Park DY, Kwon JS, Joo YH, Hong KS. Prevalence and clinical characteristics of obsessive-compulsive symptoms associated with atypical antipsychotics. J Clin Psychopharmacol. 2007;27(6):712-713. FULL TEXT | WEB OF SCIENCE | PUBMED

11. Arranz MJ, de Leon J. Pharmacogenetics and pharmacogenomics of schizophrenia: a review of last decade of research. Mol Psychiatry. 2007;12(8):707-747. FULL TEXT | WEB OF SCIENCE | PUBMED

12. Malhotra AK. Pharmacogenetics to pharmacogenomics of psychotropic drug response. In: Lerer B, ed. Pharmacogenetics of Psychotropic Drugs. Cambridge, England: Cambridge University Press; 2002:21-35.

13. Hong KS, Nam HJ, Lim M. Emergence of obsessive-compulsive symptoms during clozapine treatment in a pair of monozygotic twins [eLetter]. Br J Psychiatry. 2008;190:81-a. WEB OF SCIENCE

14. do Rosario-Campos MC, Leckman JF, Curi M, Quatrano S, Katsovitch L, Miguel EC, Pauls DL. A family study of early-onset obsessive-compulsive disorder. Am J Med Genet B Neuropsychiatr Genet. 2005;136B(1):92-97. FULL TEXT | WEB OF SCIENCE | PUBMED

15. Hanna GL, Himle JA, Curtis GC, Gillespie BW. A family study of obsessive-compulsive disorder with pediatric probands. Am J Med Genet B Neuropsychiatr Genet. 2005;134B(1):13-19. FULL TEXT | WEB OF SCIENCE | PUBMED

16. Inouye E. Similar and dissimilar manifestations of obsessive-compulsive neuroses in monozygotic twins. Am J Psychiatry. 1965;121:1171-1175. FULL TEXT | WEB OF SCIENCE | PUBMED

17. van Grootheest DS, Cath DC, Beekman AT, Boomsma DI. Twin studies on obsessive-compulsive disorder: a review. Twin Res Hum Genet. 2005;8(5):450-458. WEB OF SCIENCE | PUBMED

18. Chakrabarty K, Bhattacharyya S, Christopher R, Khanna S. Glutamatergic dysfunction in OCD. Neuropsychopharmacology. 2005;30(9):1735-1740. FULL TEXT | WEB OF SCIENCE | PUBMED

19. Starck G, Ljungberg M, Nilsson M, Jonsson L, Lundberg S, Ivarsson T, Ribbelin S, Ekholm S, Carlsson A, Forssell-Aronsson E, Carlsson ML. A 1H magnetic resonance spectroscopy study in adults with obsessive compulsive disorder: relationship between metabolite concentrations and symptom severity. J Neural Transm. 2008;115(7):1051-1062. FULL TEXT | WEB OF SCIENCE | PUBMED

20. Whiteside SP, Port JD, Deacon BJ, Abramowitz JS. A magnetic resonance spectroscopy investigation of obsessive-compulsive disorder and anxiety. Psychiatry Res. 2006;146(2):137-147. FULL TEXT | WEB OF SCIENCE | PUBMED

21. Pauls DL. The genetics of obsessive compulsive disorder: a review of the evidence. Am J Med Genet C Semin Med Genet. 2008;148C(2):133-139. WEB OF SCIENCE | PUBMED

22. Arnold PD, Sicard T, Burroughs E, Richter MA, Kennedy JL. Glutamate transporter gene SLC1A1 associated with obsessive-compulsive disorder. Arch Gen Psychiatry. 2006;63(7):769-776. FREE FULL TEXT

23. Dickel DE, Veenstra-VanderWeele J, Cox NJ, Wu X, Fischer DJ, Van Etten-Lee M, Himle JA, Leventhal BL, Cook EH Jr, Hanna GL. Association testing of the positional and functional candidate gene SLC1A1/EAAC1 in early-onset obsessive-compulsive disorder. Arch Gen Psychiatry. 2006;63(7):778-785. FREE FULL TEXT

24. Stewart SE, Fagerness JA, Platko J, Smoller JW, Scharf JM, Illmann C, Jenike E, Chabane N, Leboyer M, Delorme R, Jenike MA, Pauls DL. Association of the SLC1A1 glutamate transporter gene and obsessive-compulsive disorder. Am J Med Genet B Neuropsychiatr Genet. 2007;144B(8):1027-1033. FULL TEXT | WEB OF SCIENCE | PUBMED

25. Tzingounis AV, Wadiche JI. Glutamate transporters: confining runaway excitation by shaping synaptic transmission. Nat Rev Neurosci. 2007;8(12):935-947. FULL TEXT | WEB OF SCIENCE | PUBMED

26. Schmitt A, Zink M, Petroianu G, May B, Braus DF, Henn FA. Decreased gene expression of glial and neuronal glutamate transporters after chronic antipsychotic treatment in rat brain. Neurosci Lett. 2003;347(2):81-84. FULL TEXT | WEB OF SCIENCE | PUBMED

27. Huerta I, McCullumsmith RE, Haroutunian V, Gimenez-Amaya JM, Meador-Woodruff JH. Expression of excitatory amino acid transporter interacting protein transcripts in the thalamus in schizophrenia. Synapse. 2006;59(7):394-402. FULL TEXT | WEB OF SCIENCE | PUBMED

28. Yamamoto BK, Cooperman MA. Differential effects of chronic antipsychotic drug treatment on extracellular glutamate and dopamine concentrations. J Neurosci. 1994;14(7):4159-4166. ABSTRACT

29. Schmitt A, Zink M, Muller B, May B, Herb A, Jatzko A, Braus DF, Henn FA. Effects of long-term antipsychotic treatment on NMDA receptor binding and gene expression of subunits. Neurochem Res. 2003;28(2):235-241. FULL TEXT | PUBMED

30. Moutsimilli L, Farley S, El Khoury MA, Chamot C, Sibarita JB, Racine V, El Mestikawy S, Mathieu F, Dumas S, Giros B, Tzavara ET. Antipsychotics increase vesicular glutamate transporter 2 (VGLUT2) expression in thalamolimbic pathways. Neuropharmacology. 2008;54(3):497-508. FULL TEXT | WEB OF SCIENCE | PUBMED

31. Choi YK, Gardner MP, Tarazi FI. Effects of risperidone on glutamate receptor subtypes in developing rat brain. Eur Neuropsychopharmacol. 2009;19(2):77-84. FULL TEXT | WEB OF SCIENCE | PUBMED

32. Hahn OS, Ahn JH, Song SH, Cho MJ, Kim JK, Bae JN, Cho SJ, Jeong BS, Suh DW, Hahm BJ, Lee DW, Park JI, Hong JP. Development of Korean version of Structured Clinical Interview Schedule for DSM-IV Axis I Disorder: interrater reliability. J Korean Neuropsychiatr Assoc. 2000;39(2):362-372.

33. Goodman WK, Price LH, Rasmussen SA, Mazure C, Delgado P, Heninger GR, Charney DS. The Yale-Brown obsessive compulsive scale II: validity. Arch Gen Psychiatry. 1989;46(11):1012-1016. FREE FULL TEXT

34. Kim SJ, Choi NK, Hong HJ, Hwang YS, Kim YK, Lee HS, Kim CH. Dimensional analyses of the Yale-Brown obsessive-compulsive scale and Yale-Brown obsessive-compulsive scale checklist [in Korean]. Korean J Psychopharmacol. 2004;15(3):339-345.

35. Lim JS, Kim CH. Assessment of obsessive-compulsive symptoms and obsessive-compulsive disorder [in Korean]. Anxiety and Mood. 2008;4(1):11-18.

36. Akaike H. A new look at the statistical model identification. IEEE Trans Automat Contr. 1974;19(6):716-723. FULL TEXT

37. Barrett JC, Fry B, Maller J, Daly MJ. Haploview: analysis and visualization of LD and haplotype maps. Bioinformatics. 2005;21(2):263-265. FREE FULL TEXT

38. Westfall PH, Young SS. Resampling-Based Multiple Testing: Examples and Methods for P-value Adjustment. New York, NY: John Wiley & Sons; 1993.

39. Ge Y, Dudoit S, Speed TP. Resampling-based multiple testing for microarray data analysis. TEST. 2003;12:1-77. FULL TEXT | WEB OF SCIENCE

40. Byerly M, Goodman W, Acholonu W, Bugno R, Rush AJ. Obsessive compulsive symptoms in schizophrenia: frequency and clinical features. Schizophr Res. 2005;76(2-3):309-316. FULL TEXT | WEB OF SCIENCE | PUBMED

41. Ongür D, Goff DC. Obsessive-compulsive symptoms in schizophrenia: associated clinical features, cognitive function and medication status. Schizophr Res. 2005;75(2-3):349-362. FULL TEXT | WEB OF SCIENCE | PUBMED

42. Bespalov A, Jongen-Relo AL, van Gaalen M, Harich S, Schoemaker H, Gross G. Habituation deficits induced by metabotropic glutamate receptors 2/3 receptor blockade in mice: reversal by antipsychotic drugs. J Pharmacol Exp Ther. 2007;320(2):944-950. FREE FULL TEXT

43. De Souza IE, McBean GJ, Meredith GE. Chronic haloperidol treatment impairs glutamate transport in the rat striatum. Eur J Pharmacol. 1999;382(2):139-142. FULL TEXT | WEB OF SCIENCE | PUBMED

CiteULike

Connotea

Delicious

Digg

Facebook

Technorati

Twitter What's this?

RELATED ARTICLE

This Month in Archives of General Psychiatry
Arch Gen Psychiatry. 2009;66(11):1158.
FULL TEXT

| | |