Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Association Study of N-Methyl-D-Aspartate Receptor Subunit 2B (GRIN2B) Polymorphisms and Schizophrenia Symptoms in the Han Chinese Population

  • Yongfeng Yang ,

    Contributed equally to this work with: Yongfeng Yang, Wenqiang Li

    Affiliations Key Laboratory for NeuroInformation of Ministry of Education, School of Life Science and Technology, University of Electronic Science and Technology of China, Chengdu, China, Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

  • Wenqiang Li ,

    Contributed equally to this work with: Yongfeng Yang, Wenqiang Li

    Affiliations Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

  • Hongxing Zhang,

    Affiliations Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

  • Ge Yang,

    Affiliation Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China

  • Xiujuan Wang,

    Affiliations Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

  • Minli Ding,

    Affiliations Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

  • Tianzi Jiang ,

    lvx928@126.com (LXL); jiangtz@nlpr.ia.ac.cn (TZJ)

    Affiliation Key Laboratory for NeuroInformation of Ministry of Education, School of Life Science and Technology, University of Electronic Science and Technology of China, Chengdu, China

  • Luxian Lv

    lvx928@126.com (LXL); jiangtz@nlpr.ia.ac.cn (TZJ)

    Affiliations Department of Psychiatry, Henan Mental Hospital, The Second Affiliated Hospital of Xinxiang Medical University, Xinxiang, China, Henan Key Lab of Biological Psychiatry, Xinxiang Medical University, Xinxiang, China

Abstract

Schizophrenia (SZ) is a common and complex psychiatric disorder that has a significant genetic component. The glutamatergic system is the major excitatory neurotransmitter system in the central nervous system, and is mediated by N-methyl-D-aspartate (NMDA) receptors. Disturbances in this system have been hypothesized to play a major role in SZ pathogenesis. Several studies have revealed that the NMDA receptor subunit 2B (GRIN2B) potentially associates with SZ and its psychiatric symptoms. In this study, we performed a case–control study to identify polymorphisms of the GRIN2B gene that may confer susceptibility to SZ in the Han Chinese population. Thirty-four single nucleotide polymorphisms (SNPs) were genotyped in 528 paranoid SZ patients and 528 control subjects. A significant association was observed in allele and genotype between SZ and controls at rs2098469 (χ2 = 8.425 and 4.994; p = 0.025 and 0.014, respectively). Significant associations were found in the allele at rs12319804 (χ2 = 4.436; p = 0.035), as well as in the genotype at rs12820037 and rs7298664 between SZ and controls (χ2 = 11.162 and 38.204; p = 0.003 and 4.27×10-8, respectively). After applying the Bonferroni correction, rs7298664 still had significant genotype associations with SZ (p = 1.71×10-7). In addition, rs2098469 genotype and allele frequencies, and 12820037 allele frequencies were nominally associated with SZ. Three haplotypes, CGA (rs10845849—rs12319804—rs10845851), CC (rs12582848—rs7952915), and AAGAC (rs2041986—rs11055665—rs7314376—rs7297101—rs2098469), had significant differences between SZ and controls (χ2 = 4.324, 4.582, and 4.492; p = 0.037, 0.032, and 0.034, respectively). In addition, three SNPs, rs2098469, rs12820037, and rs7298664, were significantly associated with cognition factors PANSS subscores in SZ (F = 16.799, 7.112, and 13.357; p = 0.000, 0.017, and 0.000, respectively). In conclusion, our study provides novel evidence for an association between GRIN2B polymorphisms and SZ susceptibility and symptoms in the Han Chinese population.

Introduction

Schizophrenia (SZ) is a common, chronic, and complex psychiatric disorder that includes delusions and hallucinations, reduced interest and drive, altered emotional reactivity, and disorganized behavior [1]. SZ affects 1.0% of the worldwide population [2]. Family studies, including twin and adoption studies, provide evidence that SZ is predominantly a genetic disorder, and heritability estimates for SZ range from 60% to 80% [35]. Traditionally, SZ genetic research focused on identifying linkage regions, candidate genes, and polymorphisms. Data indicated susceptibility genes contributed to SZ [69]. Some results suggest that multiple, individual mutations that alter genes in neurotransmitter pathways contribute to SZ [1012].

Glutamate (Glu) is the primary excitatory neurotransmitter involved in various neural processes, including neuronal development, synaptic plasticity, and neuronal toxicity in the brain system [13]. In the late 1980s, the Glu hypofunction model of SZ was first suggested, and was based upon the observation that phencyclidine, ketamine, and similarly-acting psychotomimetic compounds induced their unique behavioral effects by blocking neurotransmission at N-methyl-D-aspartate-type glutamate receptors (NMDAR) [10]. Moreover, the glutamate system consists of interconnecting pathways of the cerebral cortex and limbic system, which are brain regions implicated in SZ pathophysiology [11]. As glutamate receptors, NMDARs are ligand- and voltage-gated ion channels that play crucial roles in excitatory synaptic transmission, plasticity, and excitoxicity. They are composed of an N-methyl-D-aspartate-type glutamate (NMDA) receptor NR1 subunit (GRIN1) and one of the four NMDA receptor NR2 subunits (GRIN2A-D) [1416]. Among the proposed mechanisms, disturbances in NMDAR-mediated neuronal transmission offer a logical hypothesis for SZ development.

The NR2B subunit is encoded by the NMDA receptor 2B subunit gene (GRIN2B; MIN_138252), which is located at chromosome 12p12 and consists of 13 exons. Moreover, variations in GRIN2B have been linked to SZ [17,18]. The NMDA subunit NR2B, encoded by GRIN2B, has been implicated in cases of mental retardation [19]. Many recent studies have focused on insertion/deletion polymorphisms and explored potential associations between GRIN2B and SZ. Excessive rare missense GRIN2B mutations have also been reported in people with both SZ and autism [20]. However, other studies had inconsistent results [18,2024]. SZ is highly heterogeneous in both clinical expression and genotype, and it is believed that variations in genotype are related to different clinical subtypes. In the present study, we performed a case–control analysis to investigate the potential association between GRIN2B SNPs and SZ symptoms in the Han Chinese population.

Materials and Methods

Subjects

The Ethical Committee of the Second Affiliated Hospital of Xinxiang Medical University (China) approved the study protocol. Written informed consent was obtained from all participants after the objectives and procedures of the study were fully explained.

The patient population was recruited from inpatients at the Second Affiliated Hospital of Xinxiang Medical University from March 2005 to December 2008. The population consisted of 528 SZ patients (264 males and 264 females; mean age: 27.32 ± 8.03 years old) and 528 healthy controls (264 males and 264 females; mean age: 27.73 ± 8.01 years old). Patients were unrelated Han Chinese born and living in the North Henan province, and all of their biological grandparents were of Han Chinese ancestry. Consensus diagnoses were made by at least two experienced psychiatrists according to the Diagnostic and Statistical Manual of Mental Disorders-Fourth Edition IV (DSM-IV) (1994) diagnostic criteria for SZ. Only paranoid SZ patients were selected. Individuals with a history of severe medical complications, organic brain disease, other major psychiatric disorders, or substance dependence were excluded.

The age of SZ onset was the age at first manifestation of positive symptoms [25], and was derived from the Comprehensive Assessment of Symptoms and History (CASH) [26]. A “family mental health history” was defined as at least one first- or second-degree relative of the proband who met the DSM-IV criteria for SZ or schizoaffective disorder, and was obtained from the patient or a family member during the initial interview. The raters involved in this study were trained psychiatrists experienced in the administration of psychopathological tests such as the CASH and Positive and Negative Symptom Scale (PANSS). To ensure inter-rater consistency, all participating psychiatrists underwent training every 6 months wherein diagnoses and test results were compared using videotaped demonstration interviews. Agreement among the raters was high for the DSM-IV, CASH, and PANSS, with kappa values ranging from 0.762 to 0.843 and intraclass correlation coefficients (r values) ranging from 0.827 to 0.933.

Two hundred and twenty-nine patients (116 males and 113 females, mean age 27.53 ± 6.01 years, part of the total sample of 528 patients) were evaluated for psychotic syndromes using the PANSS [27] when not taking any antipsychotic medications. Raters were trained to administer the PANSS using the Structured Clinical Interview for the PANSS and achieved an inter-rater reliability of 0.80 or greater. Five factors were derived from PANSS [28]: positive (items P1, P3, P6, G6), negative (N1, N2, N3, N4, N6, G7, G13, G16, P5), expression/anxiety (G1, G2, G3, G4, G6, G12), cognition (P2, N5, N7, G5, G10, G11, G15), and excitement/hostility (P4, P7, G8, G14).

Healthy controls were recruited volunteers from communities and colleges within the same region and matched to the patient group for gender ratio (1:1 for both groups), age (F = 0.699, p = 0.403), and Han ethnicity, and with simple non-structured interviews performed by psychiatrists. Any individual with a personal or family history of mental or neurological diseases was excluded. All participants were unrelated Han Chinese who were born and living in the North Henan province. Their biological grandparents were of Han Chinese ancestry.

Peripheral blood samples from each subject were collected into vacutainer tubes containing the anticoagulant ethylene-diaminetetracetic acid. Genomic DNA was extracted from leukocytes using the RelaxGene Blood DNA System (Tiangen Biotech, Beijing, China).

SNP selection

In this study, GRIN2B SNPs were selected for study according to the following criteria: (1) All SNPs covering the genomic region chr12: 13605448−14022988 were included in functional analyses using the FASTSNP online service (http://fastsnp.ibms.sinica.edu.tw.) [29]. Only those SNPs with highly ranked risk and a minor allele frequency (MAF) ≥0.05 in the Chinese Beijing population according to the HapMap database were selected; (2) Tag SNPs were chosen based on the aggressive tagging algorithm (Carlson et al., 2004) (r2 0.80, MAF ≥0.05) using genotype data from the HapMap database as implemented in Haploview v4.1 (http://www.broad.mit.edu/mpg/haploview/) [30]; and, (3) All SNPs selected using these two criteria were assessed using Illumina design scores, and all SNPs with scores below 0.6 were excluded.

Genotyping

Genotyping was performed using Illumina GoldenGate assays on a BeadStation 500G Genotyping System (Illumina, Inc., San Diego, CA, USA). DNA samples (250 ng) were genotyped according to the Illumina protocol. DNA samples from cases and controls were randomly sorted, including 96 duplicated DNA samples for genotyping quality control. Genotype calls were made using the Genotyping module of the BeadStudio 2.0 software (Illumina, Inc.). All genotype data were examined for cluster separation using Illumina quality scores generated by the software. Poorly performing SNPs were excluded, designated by a GenTrain score <0.4 or a cluster separation score <0.6. SNPs were further excluded from controls not in Hardy–Weinberg equilibrium (HWE). As a genotyping quality control, four SNPs were genotyped in duplicate (100 samples) by DNA sequencing.

Statistical analyses

Genotypes and alleles were compared between patients and controls using the Golden Helix SVS7.2 program with 10,000 random permutations (Golden Helix, Inc. Bozeman, MT, USA; http://www.goldenhelix.com/). HWE was also calculated using this software. The standardized measure of linkage disequilibrium (LD), coefficients (D′), haplotype frequency, haplotype block, and haplotype association was assessed using the Haploview V4.1 program [30].

Single-SNP analyses for individual genotyping data were performed using Pearson’s chi-square tests on allele and genotype counts. Correlations between alleles and SZ were performed using Armitage trend tests. Odds ratio (OR) and 95% confidence intervals (95% CI) were calculated to evaluate the effect of different alleles and haplotypes. HWE was assessed using chi-square tests with one degree of freedom. Haplotype frequencies were estimated using the expectation maximization (EM) algorithm. To evaluate interactions between genes and sex, global test for interaction was performed. p<0.05 was considered statistically significant for tests with expected HWE. Power analyses were performed using the Genetic Power Calculator for this study [31]. Genotyping data were analyzed using Structure 2.3 (http://pritchardlab.stanford.edu/structure_software/release_versions/v2.3.4/html/structure.html) to generate population stratification assignments for all individuals using the Markov chain Monte Carlo (MCMC) algorithm [32].

Genotype differences between SZ patients and healthy controls were compared using chi-square tests (1 df). Associations between age-at-onset subgroups and different genotype carriers were tested using one-way analysis of variance (ANOVA) tests (SPSS version 13.0, SPSS, Inc. Chicago, IL, USA). Differences between GRIN2B genotypes in the SZ group and scores of five factors from the PANSS were examined using ANOVA with age, age at onset and illness duration as covariables. Fisher’s least significant difference (LSD) tests were used for pair-wise comparisons of the three genotypes following one-way ANOVA tests. The Bonferroni correction for multiple pair-wise comparisons was conducted for the (X × phenotype) interaction to reduce the probability of false positives, as the probability of at least one chance rejection of the null hypothesis (the product of α and the number of possible comparisons) was p = 0.25. The corrected α′ (p = 0.01) is α (p = 0.05) divided by the number of possible comparisons. Bonferroni corrections for multiple tests were performed to exclude type I errors.

Results

To reveal allelic variants of the GRIN2B gene that are associated with SZ, we analyzed the allele and genotype frequencies of thirty-four common SNPs in 528 SZ patients and 528 controls of Han Chinese descent. For power test, we set the parameters as follows: SNP site = rs2098469, high risk allele frequency (A) = 0.16, prevalence = 0.1 (prevalence of SZ), genotype relative risk Aa = 1.12, genotype relative risk AA = 2.96 (1.12 and 2.96 were used the online software to analyzed. http://bioinfo.iconcologia.net/snpstats/start.ht), number of cases = 528. For a power above 80%, 392 cases are needed according to Genetic Power Calculator, so for genotype analyses, the sample size (n = 528) had sufficient power (0.70–0.80) to detect effects. Power analyses revealed that the total sample size (n = 1056) had a power of 0.86 to detect a small effect (r = 0.1–0.23), and a power of 1.00 to detect both medium (r = 0.24–0.36) and large (r>0.37) effects on genotype distributions. For allele frequency, the sample size (n = 2112) had the power (0.91–1.00) to detect small, medium, and large effects. The sampling success rate for all subjects and SNPs was 99.75%, and the genotype concordance between the BeadStation 500G Genotyping System and DNA sequencing was 99.25%. Evaluation of population structure using 10,000 iterations for the burn-in period and 10,000 repeats after burn-in revealed no evidence of population stratification in the control group (K = 1, p = 1).

None of the genotype distributions of these thirty-four SNPs significantly deviated from HWM. There was a significant association in allele at rs2098469 and rs12319804 between SZ and controls (p = 0.025 and 0.035, respectively, Table 1). Significant associations were found in the genotypes between SZ and controls at rs2098469, rs12820037, and rs7298664 (p = 0.014, 0.003, and 4.27×10-8, respectively, Table 1). After applying the Bonferroni correction, rs7298664 still had significant genotype associations with SZ (p = 1.71×10-7). In addition, significant differences were found in the genotypes of males (rs7298664) and females (rs2098469, rs12820037, and rs1806201) between SZ and controls when the two groups were subdivided by gender (p = 8.43×10-18, 0.036, 9.5×10-5, and 0.018, respectively; S1 Table). After applying the Bonferroni correction, rs7298664 and rs12820037 still had significant genotype associations with SZ in male and female respectively (p = 3.37×10-17 and 3.7×10-4, respectively; S1 Table).

thumbnail
Table 1. Genotype and allele frequencies of thirty-four SNPs in the GRIN2B gene in SZ patients and controls.

https://doi.org/10.1371/journal.pone.0125925.t001

To further analyze the haplotype structure in our sample, we evaluated pair-wise LD of thirty-four SNPs in the SZ patient and control group using the standardized D′ and r2 values. The position of these SNPs in GRIN2B, the LD structure, and the D′ values for all variants are shown in Fig 1. The LD maps for SZ patient and control samples were presented in S1 Fig and S2 Fig respectively. Thirty-four SNPs formed seven LD blocks. Within these blocks, twenty-seven haplotypes were formed, but only three haplotypes, CGA, CC, and AAGA in block 3, 4, and 5, had significantly differed between SZ and controls (p = 0.037, 0.032, and 0.034, respectively). Table 2 shows the three significantly associated haplotypes.

thumbnail
Fig 1. Haplotype block structure of the GRIN2B gene in both SZ patients and health controls.

Thirty-four SNPs formed seven LD blocks. The index association SNP is represented by a diamond. The color of the remaining SNPs (circles) indicates LD with the index SNP based on pairwise r2 values from our data.

https://doi.org/10.1371/journal.pone.0125925.g001

thumbnail
Table 2. Frequencies of three schizophrenia associated haplotypes in SZ patients and controls.

https://doi.org/10.1371/journal.pone.0125925.t002

To investigate the association between GRIN2B variations and symptoms, 228 SZ patients with complete PANSS scores were selected. As shown in Table 3, three SNPs positively associated with SZ, and also significantly associated with total PANSS and other five factor scores. Other SNPs from these samples were not found to have these associations. Furthermore, there were significant associations between rs2098469 and total PANSS and five factor subscores with age, age at onset, and illness duration as covariables (p = 0.000, S2 Table). Two SNPs, rs12319804 and rs12820037, were significantly associated with positive and cognition factor subscores (p = 0.000, 0.000 and p = 0.025, 0.003, respectively).

thumbnail
Table 3. Association analyses between five factors of PANSS and three GRIN2B SNPs in patients with SZ.

https://doi.org/10.1371/journal.pone.0125925.t003

Discussion

This study aimed to investigate the GRIN2B mutations associated with SZ and psychotic symptoms in the Han Chinese population. Significant differences were observed in genotype frequencies of three SNPs, rs2098469, rs12820037, and rs7298664, between patients and controls. In addition, the allele frequencies of the rs12319804 and rs2098469 SNPs were significantly associated with SZ in this population. Furthermore, the rs7298664 genotype association remained after Bonferroni correction. In addition, the rs2098469 genotype and allele frequencies, and the 12820037 allele frequencies were nominally associated with SZ. Our results found novel variants can influence SZ risk in the Han Chinese population.

Previous studies revealed that dysfunction of the glutamatergic signaling system was a major mechanism in SZ pathogenesis, and genes encoding NMDA receptors are obvious candidates in numerous association studies of SZ [3337]. More studies have focused on the association of GRIN2B with SZ. The original studies reported that some GRIN2B SNPs were significantly associated with SZ [20,22,23,3840]. In addition, the rs1019385 SNP was associated with SZ in several studies and meta-analyses [22,34,35,38]. However, other studies found no such associations [18,21,24]. Our study could not validate the positive association of rs1019385; however, novel variants of GRIN2B, including rs2098469, rs12820037, and rs7298664 had significant association in genotype frequency with SZ. We also found significant association with SZ when the two groups were subdivided by gender. Moreover, our results are consistent with previous studies that reported no association of rs1805247, rs1806191, rs1806201, rs3026160, rs1805522, rs1805482, and rs35025065 with SZ [18,41]. The present study revealed significant association in alleles between SZ and controls at rs12319804 and rs2098469, which differs from data in previous studies [38,40]. Further association analyses of haplotypes consisting of thirty-four SNPs at the GRIN2B gene with SZ were performed. Three haplotypes at GRIN2B significantly associated with SZ. In previous studies, better memory performance was observed in the absence of the T-T haplotype at GRIN2B rs220599 and rs12828473 [42,43]. Our results were inconsistent with these previous studies [18,22,23]. There are several explanations for these disparate findings. First, the small sample size and high phenotypic heterogeneity likely contributed to low statistical power, such as the conclusions of Martucci et al. [22]. Therefore, by including only paranoid SZ patients and enlarging the sample size (528 SZ patients and 528 controls), we potentially improved the power to detect disease associations. In addition, more markers were tested in this study compared to previous reports. Second, differences in population ethnicity and stratification may lead to the high heterogeneity of samples. All of our subjects were living in the North Henan province and belonged to the same population group based on structure analyses. Third, because SZ is a complex genetic disease and genome-wide association studies have revealed multiple susceptibility genes that contribute to SZ pathogenesis [8,9], each gene might exert weak-to-moderate effects.

SZ is characterized by several symptom domains: positive symptoms, negative symptoms, disorganization of thoughts and behaviors, and cognitive deficits [44,45]. Several studies have explored the associated between GRIN2B and cognitive deficit symptoms [21,42,43], differential language lateralization [46], anti-psychotic-induced movement disorders [47], and clozapine-induced obsessive-compulsive symptoms [48]. However, there are few studies regarding positive and negative symptoms of SZ and GRIN2B. Genetic enhancement of GRIN2B may improve learning and memory in mice, and NMDA dysfunction has been related to cognitive impairment associated with SZ [49,50]. Several studies have revealed the association between GRIN2B and clinically-manifested cognitive deficit symptoms, including memory performance [42,43]. Currently, neurocognitive dysfunction is a core feature of SZ and recognized in more SZ patients [51]. Therefore, we investigated this feature in our SZ patients using five factors of PANSS. In our study, three SNPs, rs2098469, rs12820037, and rs7298664, were associated with positive, negative, expression/anxiety, and cognition factor PANSS subscores in SZ patients. These differ with former data regarding rs12828473 and rs220599 [42,43]. The differences may be due to unknown population stratification [18], limited sample size [22], incomplete information, or sample heterogeneity [23]. Thus, all results revealed that genetic variations of GRIN2B influence symptom traits in SZ. Moreover, rs2098469, rs12820037, and rs7298664 were associated with cognition factor subscores in SZ patients with age, age at onset, and illness duration as covariables. Therefore, our study provided novel evidence for the association of GRIN2B with cognition deficit symptoms.

SZ is influenced by glutamatergic neurotransmission and other neurotransmitter networks, including serotonin and dopamine systems. Additionally, we had previously found an association between SLC6A4 in the serotonin system and SZ [52]. Hence, further studies should examine the interaction of different neurotransmission systems, and how candidate genes affect glutamatergic and related signaling pathways and alter SZ symptoms.

This study had some limitations. First, our sample size may not be large enough for complete PANSS scores. Second, we only selected paranoid SZ patients, not included other subtypes (catatonic, collapse, residual and undifferentiated). Third, this study was limited by a lack of independent validation. Therefore, the further research will need improving in this aspects.

Conclusion

In summary, our study provides novel data suggesting an association between GRIN2B and SZ susceptibility and symptoms. Other studies in different ethnic populations, particularly in patients with defined SZ phenotypes, are required to confirm the role of GRIN2B variants in paranoid SZ.

Supporting Information

S1 Fig. Haplotype block structure of the GRIN2B gene in SZ patients.

Thirty-four SNPs formed seven LD blocks. The index association SNP is represented by a diamond. The color of the remaining SNPs (circles) indicates LD with the index SNP based on pairwise r2 values from our data.

https://doi.org/10.1371/journal.pone.0125925.s001

(TIF)

S2 Fig. Haplotype block structure of the GRIN2B gene in health controls.

Thirty-four SNPs formed six LD blocks. The index association SNP is represented by a diamond. The color of the remaining SNPs (circles) indicates LD with the index SNP based on pairwise r2 values from our data.

https://doi.org/10.1371/journal.pone.0125925.s002

(TIF)

S1 Table. Genotypic and allelic frequencies of thirty-four SNPs from the chi-square test in female and male samples.

https://doi.org/10.1371/journal.pone.0125925.s003

(PDF)

S2 Table. Association analyses between five factors of PANSS and three GRIN2B SNPs with three covariables in patients with SZ.

https://doi.org/10.1371/journal.pone.0125925.s004

(PDF)

Acknowledgments

The authors thank the patients, their families, and the healthy volunteers for their participation, and the physicians who helped us collect clinical data and blood samples in the Second Affiliated Hospital of Xinxiang Medical University.

Author Contributions

Conceived and designed the experiments: LL WL. Performed the experiments: YY GY MD XW. Analyzed the data: WL YY HZ TJ. Contributed reagents/materials/analysis tools: WL HZ TJ. Wrote the paper: YY WL.

References

  1. 1. Owen MJ, Craddock N, O'Donovan MC. Schizophrenia: genes at last? Trends Genet. 2005; 21: 518–525. pmid:16009449
  2. 2. Schultz SK, Andreasen NC. Schizophrenia. Lancet. 1999; 353: 1425–1430. pmid:10227239
  3. 3. <b>Kendler KS, Eaves LJ. Psychiatric Genetics(Review of Psychiatry) American Psychiatric Association.Arlington,VA; 2005.
  4. 4. Gottesman II. Schizophrenia genesis: the origins of madness. New York: Freeman; 1991.
  5. 5. Lichtenstein P, Yip BH, Björk C, Pawitan Y, Cannon TD, Sullivan PF, et al. Common genetic determinants of schizophrenia and bipolar disorder in Swedish families: a population-based study. Lancet. 2009; 373: 234–239. pmid:19150704
  6. 6. O'Donovan MC, Craddock N, Norton N, Williams H, Peirce T, Moskvina V, et al. Molecular genetics of schizophrenia collaboration. Identification of loci associated with schizophrenia by genome-wide association and follow-up. Nat Genet. 2008; 40: 1053–1055. pmid:18677311
  7. 7. Williams HJ, Owen MJ, O'Donovan MC. New findings from genetic association studies of schizophrenia. J Hum Genet. 2009; 54: 9–14. pmid:19158819
  8. 8. Yue WH, Wang HF, Sun LD, Tang FL, Liu ZH, Zhang HX, et al. Genome-wide association study identifies a susceptibility locus for schizophrenia in Han Chinese at 11p11.2. Nat Genet. 2011; 43: 1228–1231. pmid:22037552
  9. 9. Shi YY, Li ZQ, Xu Q, Wang T, Li T, Shen JW, et al. Common variants on 8p12 and 1q24.2 confer risk of schizophrenia. Nat Genet. 2011; 43: 1224–1227. pmid:22037555
  10. 10. Javitt DC. Negative schizophrenic symptomatology and the phencyclidine (PCP) model of schizophrenia. Hillside J. Psychiatry. 1987; 9: 12–35. pmid:2820854
  11. 11. Tsai G, Coyle JT. Glutamatergic mechanisms in schizophrenia. Annu Rev Pharmacol Toxicol. 2002; 42: 165–179. pmid:11807169
  12. 12. Sodhi M, Wood KH, Meador-Woodruff J. Role of glutamate in schizophrenia: integrating excitatory avenues of research. Expert Rev Neurother. 2008; 8: 1389–1406. pmid:18759551
  13. 13. Goff DC, Coyle JT. The emerging role of glutamate in the pathophysiology and treatment of schizophrenia. Am J Psychiatry. 2001; 158: 1367–1377. pmid:11532718
  14. 14. Hollmann M, Heinemann S. Cloned glutamate receptors. Annu Rev Neurosci. 1994; 17: 31–108. pmid:8210177
  15. 15. Nakanishi S, Masu M. Molecular diversity and functions of glutamate receptors. Annu Rev Biophys Biomol Struct. 1994; 23: 319–348. pmid:7919785
  16. 16. Moriyoshi K, Masu M, Ishii T, Shigemoto R, Mizuno N, Nakanishi S. Molecular cloning and characterization of the rat NMDA receptor. Nature. 1991; 354: 31–37. pmid:1834949
  17. 17. Cherlyn SY, Woon PS, Liu JJ, Ong WY, Tsai GC, Sim K. Genetic association studies of glutamate, GABA and related genes in schizophrenia and bipolar disorder: a decade of advance. Neurosci Biobehav Rev. 2010; 34: 958–977. pmid:20060416
  18. 18. Quin SY, Zhao X, Pan YX, Liu JH, Feng GY, Fu JC, et al. An association study of the N-methyl-d-aspartate receptor NR1 subunit gene (GRIN1) and NR2B subunit gene (GRIN2B) in schizophrenia with universal DNA microarray. Eur J Hum Genet. 2005; 13: 807–814. pmid:15841096
  19. 19. Endele S, Rosenberger G, Geider K, Popp B, Tamer C, Stefanova I, et al. Mutations in GRIN2A and GRIN2B encoding regulatory subunits of NMDA receptors cause variable neurodevelopmental phenotypes. Nat Genet. 2010; 42: 1021–1026. pmid:20890276
  20. 20. Myers RA, Casals F, Gauthier J, Hamdan FF, Keebler J, Boyko AR, et al. A population genetic approach to mapping neurological disorder genes using deep resequencing. PLoS Genet. 2011; 7: e1001318. pmid:21383861
  21. 21. Williams HJ, Georgieva L, Dwyer S, Kirov G, Owen MJ, O'Donovan MC. Absence of de novo point mutations in exons of GRIN2B in a large schizophrenia trio sample. Schizophr Res. 2012; 141: 274–276. pmid:22986046
  22. 22. Martucci L, Wong AH, De Luca V, Likhodi O, Wong GW, King N, et al. N-methyl-D-aspartate receptor NR2B subunit gene GRIN2B in schizophrenia and bipolar disorder: Polymorphisms and mRNA levels. Schizophr Res. 2006; 84: 214–221. pmid:16549338
  23. 23. Di Maria E, Gulli R, Begni S, De Luca A, Bignotti S, Pasini A, et al. Variations in the NMDA receptor subunit 2B gene (GRIN2B) and schizophrenia: a case-control study. Am J Med Genet B Neuropsychiatr Genet. 2004; 128B: 27–29. pmid:15211626
  24. 24. Iwayama Y, Hashimoto K, Nakajima M, Toyota T, Yamada K, Shimizu E, et al. Analysis of correlation between serumd-serine levels and functional promoter polymorphisms of GRIN2A and GRIN2B genes. Neuroscience Letters. 2006; 394: 101–104. pmid:16266783
  25. 25. White T, Ho BC, Ward J, O’Leary D, Andreasen NC. Neuropsychological performance in first-episode adolescents with schizophrenia: a comparison with first-episode adults and adolescent control subjects. Biol Psychiatry. 2006; 60: 463–471. pmid:16566898
  26. 26. Andreasen NC, Flaum M, Arndt S. The comprehensive assessment of symptoms and history (CASH). An instrument for assessing diagnosis and psychopathology. Arch Gen Psychiatry. 1992; 49: 615–623. pmid:1637251
  27. 27. Kay SR, Fiszbein A, Opler LA. The positive and negative syndrome scale (PANSS) for schizophrenia. Schizophr Bull. 1987; 13: 261–276. pmid:3616518
  28. 28. Kim JH, Kim SY, Lee J, Oh KJ, Kim YB, Cho ZH. Evaluation of the factor structure of symptoms in patients with schizophrenia. Psychiatry Res. 2012; 197: 285–289. pmid:22364933
  29. 29. Yuan HY, Chiou JJ, Tseng WH, Liu CH, Liu CK, Lin YJ, et al. FASTSNP: an always up-to-date and extendable service for SNP function analysis and prioritization. Nucleic Acids Res. 2006; 34: W635–641. pmid:16845089
  30. 30. Barrett JC, Fry B, Maller J, Daly MJ. Haploview: analysis and visualization of LD and haplotype maps. Bioinformatics. 2005; 21: 263–265. pmid:15297300
  31. 31. Purcell S, Cherny SS, Sham PC. Genetic Power Calculator: design of linkage and association genetic mapping studies of complex traits. Bioinformatics. 2003; 19: 149–150. pmid:12499305
  32. 32. Pritchard JK, Stephens M, Donnelly P. Inference of population structure using multilocus genotype data. Genetics. 2000; 155: 945–959. pmid:10835412
  33. 33. Gaspar PA, Bustamante ML, Silva H, Aboitiz F. Molecular mechanisms underlying glutamatergic dysfunction in schizophrenia: therapeutic implications. J Neurochem. 2009; 111: 891–900. pmid:19686383
  34. 34. Allen NC, Bagade S, McQueen MB, Ioannidis JP, Kavvoura FK, Khoury MJ, et al. Systematic meta-analyses and field synopsis of genetic association studies in schizophrenia: the szGene database. Nat Genet. 2008; 40: 827–834. pmid:18583979
  35. 35. Li DW, He L. Association study between the NMDA receptor 2B subunit gene (GRIN2B) and schizophrenia: a HuGE review and meta-analysis. Genet Med. 2007; 9: 4–8. pmid:17224684
  36. 36. Lewis DA, Gonzalez-Burgos G. Pathophysiologically based treatment interventions in schizophrenia. Nat Med. 2006; 12: 1016–1022. pmid:16960576
  37. 37. Harrison PJ, Weinberger DR. Schizophrenia genes, gene expression, and neuropathology: on the matter of their convergence. Mol Psychiatry. 2005; 10: 40–68. pmid:15263907
  38. 38. Miyatake R, Furukawa A, Suwaki H. Identification of a novel variant of the human NR2B gene promoter region and its possible association with schizophrenia. Mol Psychiatry. 2002; 7: 1101–1106. pmid:12476325
  39. 39. Hong CJ, Yu YW, Lin CH, Cheng CY, Tsai SJ. Association analysis for NMDA receptor subunit 2B (GRIN2B) genetic variants and psychopathology and clozapine response in schizophrenia. Psychiatr Genet. 2001; 11: 219–222. pmid:11807413
  40. 40. Ohtsuki T, Sakurai K, Dou H, Toru M, Yamakawa-Kobayashi K, Arinami T. Mutation analysis of the NMDAR2B (GRIN2B) gene in schizophrenia. Molecular Psychiatry. 2001; 6: 211–216. pmid:11317224
  41. 41. Ripke S, Sanders AR, Kendler KS, Levinson DF. Genome-wide association study identifies five new schizophrenia loci. Nat Genet. 2011; 43: 969–976. pmid:21926974
  42. 42. de Quervain DJ, Papassotiropoulos A. Identification of a genetic cluster influencing memory performance and hippocampal activity in humans. Proc Natl Acad Sci U S A. 2006; 103: 4270–4274. pmid:16537520
  43. 43. Jablensky A, Morar B, Wiltshire S, Carter K, Dragovic M, Badcock JC, et al. Polymorphisms associated with normal memory variation also affect memory impairment in schizophrenia. Genes Brain Behav. 2011;10: 410–417. pmid:21281445
  44. 44. Austin J. Schizophrenia: an update and review. J Genet Counselling. 2005;14: 329–340. pmid:16195940
  45. 45. Muesser KT, McGurk SR. Schizophrenia. Lancet. 2004; 363: 2063–2072. pmid:15207959
  46. 46. Ocklenburg S, Arning L, Hahn C, Gerding WM, Epplen JT, Güntürkün O, et al. Variation in the NMDA receptor 2B subunit gene GRIN2B is associated with differential language lateralization. Behav Brain Res. 2011; 225: 284–289. pmid:21827795
  47. 47. Bakker PR, Al Hadithy AF, Amin N, van Duijn CM, van Os J, van Harten PN. Antipsychotic-induced movement disorders in long-stay psychiatric patients and 45 TagSNPs in 7 candidate genes: a prospective study. PLoS One. 2012; 7: e50970. pmid:23226551
  48. 48. Cai J, Zhang W, Yi ZH, Lu WH, Wu ZG, Chen J, et al. Influence of polymorphisms in genes SLC1A1, GRIN2B, and GRIK2 on clozapine-induced obsessive-compulsive symptoms. Psychopharmacology (Berl). 2013; 230: 49–55. pmid:23660601
  49. 49. Breier A. Cognitive deficit in schizophrenia and its neurochemical basis. Br J Psychiatry Suppl. 1999; 37: 16–18. pmid:10211135
  50. 50. Tang YP, Shimizu E, Dube GR, Rampon C, Kerchner GA, Zhuo M, et al. Genetic enhancement of learning and memory in mice. Nature. 1999; 401: 63–69. pmid:10485705
  51. 51. Mesholam-Gately RI, Giuliano AJ, Goff KP, Faraone SV, Seidman LJ. Neurocognition in first-episode schizophrenia: a meta-analytic review. Neuropsychology. 2009; 23: 315–336. pmid:19413446
  52. 52. Li WQ, Yang YY, Lin JT, Wang S, Zhao JY, Yang G, et al. Association of serotonin transporter gene (SLC6A4) polymorphisms with schizophrenia susceptibility and symptoms in a Han Chinese population. Prog Neuropsychopharmacol Biol Psychiatry. 2013; 44: 290–295. pmid:23583772