Haplotypes at the dystrobrevin binding protein 1 (DTNBP1) gene locus mediate risk for schizophrenia through reduced DTNBP1 expression

The DTNBP1 gene, encoding dysbindin, is now generally considered to be a susceptibility gene for schizophrenia. However, the confidence with which this hypothesis can be held has to be tempered by the poor reproducibility between studies in terms of the exact nature of the associated haplotypes, by the failure so far to identify any specific susceptibility variants and by the absence of any demonstrated function associated with any of the risk haplotypes. In the present study, we show that a defined schizophrenia risk haplotype tags one or more cis-acting variants that results in a relative reduction in DTNBP1 mRNA expression in human cerebral cortex. Subsidiary analyses suggest that risk haplotypes identified in other sample groups of white European ancestry also index lower DTNBP1 expression, whereas putative 'protective' haplotypes index high DTNBP1 expression. Our data indicate that variation in the DTNBP1 gene confers susceptibility to schizophrenia through reduced expression, and that this, therefore, represents a primary aetiological mechanism in the disorder.     

Association study of the dysbindin (DTNBP1) gene in schizophrenia from the Japanese population

Dysbindin (DTNBP1: dystrobrevin binding protein 1), located on 6p22.3, is a candidate susceptibility gene for schizophrenia. Several studies, mostly in Caucasians, have provided evidence for an association between schizophrenia and the gene, although no common polymorphism or haploytpe has been established. In Asian populations, two studies investigated a limited number of single nucleotide polymorphisms (SNPs) of dysbindin and observed support for the association. In the present study, we investigated 12 SNPs of dysbindin, including those examined in previous Asian studies, and the corresponding haplotypes in a Japanese people with schizophrenia. As a result, no significant difference was observed between patients and controls in allelic frequencies or genotypic distributions of the 12 SNPs. Permutation test however showed significant differences in frequencies of the estimated 10-marker haplotypes between patients and controls (global p = 0.006). The present study may provide further support for an association between dysbindin and schizophrenia in Asian populations. The results might be similar to a previous Asian study, but specific haplotypes suggested for the association differed between the studies. Studies with more markers and subjects may be required before firm conclusions can be reached.     

Cis- and trans- mutations in genetic diseases

Whereas a great number of mutations located in the coding regions of genes have been described, genetic defects involving regulatory elements (cis-) or diffusible effectors controlling gene expression (trans-) are poorly known. Moreover, it appears that the structural defects of transcribed regions of genes have already delivered their "conceptual" message, whereas few studies of the consequences of one single gene defect on the expression of other genes and on in vivo functions are available. In the present communication, we wish to address the following issue: can we take advantage of Nature's experiments, ie. diseases, to extend our knowledge of the coordinate regulation of gene expression, via an original pathway, ie. the pathophysiological pathway? Can we select a few inborn or acquired metabolic diseases as models which could provide insight into as yet unknown factors involved in trans- regulation of gene expression?     

The dysbindin gene (DTNBP1) and schizophrenia: no support for an association in the Korean population

The dysbindin gene (DTNBP1) is located in chromosome 6p22.3, one of the regions of positive linkage for schizophrenia. A strong genetic association between DTNBP1 and schizophrenia has been replicated through many recent studies. In particular, dysbindin protein has been found to play a role in the glutamate neural transmission in the brain. In this study, we attempted to replicate the previously reported positive association between DTNBP1 and schizophrenia in the Korean population. Our sample included 194 patients with schizophrenia based on DSM-IV and 351 normal controls. We genotyped five SNPs including SNP A in promoter region of DTNBP1. The allele and genotype association were analyzed and the simulated haplotype was investigated as well. As the result, we could not find a significant association of DTNBP1 with schizophrenia in this Korean sample. Additional analysis of the subgroup of schizophrenia having familial loading of major psychiatric disorders did not show association, either. In summary, DTNBP1 is not likely to be a major susceptibility gene for schizophrenia in this Korean population. This result of no association also implies possible genetic heterogeneity of schizophrenia. Further studies with more dense SNPs of the whole gene sequence for various populations will be necessary to understand the genetic contribution of DTNBP1 for the development of schizophrenia.     

Effect of 5-haplotype of dysbindin gene (DTNBP1) polymorphisms for the susceptibility to bipolar I disorder.

We investigated a possible association between dysbindin gene (DTNBP1) variants and bipolar I disorder (BID). Five SNPs within DTNBP1 (rs3213207, rs1011313, rs2005976, rs760761, and rs2619522) were genotyped for 151 patients with BID and 478 controls. We observed a significant protective association of the haplotype A-C-G-T-A (all SNPs, P = 0.00016) and particularly G-T-A (the last three SNP, P = 0.00007) within DTNBP1 variants investigated. Single marker and subgroup (e.g., psychotic features, age at onset, family history, etc.) analyses showed no significant association. Although the association was due to a small number of subjects, specific DTNBP1 haplotypes, previously associated with schizophrenia, may be also associated with BID. Adequately powered studies from different ethnicities will be necessary to confirm our findings.     

No association of CNR1 gene variations with susceptibility to schizophrenia

Schizophrenia is one of the most common psychiatric disorders. There is a growing body of evidence associating dysregulation of the endogenous cannabinoid system with the pathogenesis of schizophrenia. In order to test the hypothesis that mutations in the central cannabinoid receptor-1 (CNR1) gene confer susceptibility to the development of schizophrenia, we performed an association study in a group of 104 German patients with schizophrenia and 140 healthy controls, using three polymorphisms within and flanking the coding exon of CNR1 (rs6454674, rs1049353, AL136096). In addition, we analyzed the whole coding region of the CNR1 gene of 50 of the patients by capillary sequencing to detect rare mutations. Our adequately powered study failed to reveal a statistically significant segregation of CNR1 polymorphisms to the diseased or control group. Furthermore, capillary sequencing of CNR1 in a subgroup of study subjects did not show any non-synonymous mutations predicting malfunction of CNR1 in patients with schizophrenia. In conclusion, we could not detect a statistically significant association between mutations in the CNR1 gene and the predisposition to develop schizophrenia. However, further studies are necessary to unravel the relationship between mutations in the CNR1 gene and the genetic susceptibility for the manifestation of certain subtypes or schizophrenia i.e. the predominance of negative or positive symptoms or as predictors of the clinical course.     

DTNBP1基因rs4715986位点多态性与中国汉族人群偏执型精神分裂症相关

目的通过两步法研究中国汉族人群DTNBP1基因的多态性与偏执型精神分裂症的相关性。方法发现阶段:在532例偏执型精神分裂症患者及488名健康对照中使用Sanger测序方法检测DTNBP1的11个SNP位点。验证阶段:在1 111例偏执型精神分裂症患者及1 435名健康对照中使用Taqman探针分型的方法对发现阶段检出阳性的rs4715986位点进行验证。结果发现DTNBP1中的rs4715986位点与偏执型精神分裂症的高患病风险相关(χ~2=11.02,P0.01)。在验证人群中重复出rs4715986与偏执型精神分裂症的相关性(χ~2=9.29,P=0.01)。结论DTNBP1基因rs4715986位点的多态性与偏执型精神分裂症的高患病风险相关。DTNBP1可能是中国汉族人群偏执型精神分裂症的易感基因。     

Association of genetic variations in DTNBP1 with cognitive function in schizophrenia patients and healthy subjects

The dystrobrevin-binding protein 1 gene (DTNBP1) has been regarded as a susceptibility gene for schizophrenia. Recent studies have investigated its role on cognitive function that is frequently impaired in schizophrenia patients, and generated inconsistent results. The present study was performed to elucidate effects of genetic variations in DTNBP1 on various cognitive domains in both schizophrenia patients and healthy subjects. Comprehensive neuropsychological tests were administered to 122 clinically stable schizophrenia patients and 119 healthy subjects. Based on positive findings reported in previous association studies, six SNPs were selected and genotyped. Compared to healthy subjects, schizophrenia patients showed expected lower performance for all of the cognitive domains. After adjusting for age, gender, and educational level, four SNPs showed a nominally significant association with cognitive domains. The association of rs760761 and rs1018381 with the attention and vigilance domain remained significant after applying the correction for multiple testing (P?相似文献   

偏执型与未分化型精神分裂症家系两个靶染色体易感位点的连锁分析

目的 探讨中国人群中精神分裂症亚型与1号染色体长臂1q21-25和6号染色体短臂6p21-25易感基因位点的相关性.方法 在染色体1q21-25区域中选择5个微卫星标记和6p21-25区域中选择8个微卫星标记对36个来自中国河南省的精神分裂症家系(19个偏执型和17个未分化型)中的242个个体进行基因分型及参数和非参数连锁分析.结果 36个精神分裂症家系的1号染色体参数分析时,在显性遗传模式下,D1S484得到多点异质性对数优势记分法(heterogeneity Log of odds score method,HLOD)值为1.33 (α=0.38).非参数分析时,在D1S484得到多点非参数连锁(nonparametric linkage,NPL)值为1.89(P=0.0188);D1S2878单点NPL值为2.11(P=0.0111),多点NPL值为2.41(P=0.0053);D1S196多点NPL值为1.59(P=0.0383).提示以上3个位点存在连锁.在17个未分化型家系中,D1S484多点NPL值为1.60(P=0.0367);D1S2878单点 NPL值为1.95(P=0.0145),多点NPL值为2.39(P=0.0041); D1S196多点NPL值为 1.74(P=0.0255).这与以上36个家系提示连锁的位点相同.在19个偏执型家系中,5个微卫星标记位点均未提示连锁.36个精神分裂症家系的6号染色体分析发现,除19个偏执型精神分裂症家系参数连锁分析在隐性模式下D6S289位点单点HLOD值为1.26(α=0.40),多点HLOD值为1.12(α=0.38)和非参数连锁分析在D6S289位点单点NPL值为1.52(P=0.0402),多点NPL值为1.92(P=0.0206)之外,36个精神分裂症家系总体分析和其中17个未分化型家系分型分析的结果显示8个微卫星标记位点均未提示有连锁.结论 在染色体1q23.3 和1q24.2区域可能存在与中国河南省未分化型精神分裂症相关的易感基因;在6p23区域可能存在与偏执型精神分裂症相关的易感基因.

Abstract：

Objective To investigate the relationship of susceptibility loci in chromosomes 1q21-25 and 6p21-25 and schizophrenia subtypes in Chinese population. Methods A genomic scan and parametric and non-parametric analyses were performed on 242 individuals from 36 schizophrenia pedigrees, including 19 paranoid schizophrenia and 17 undifferentiated schizophrenia pedigrees, from Henan province of China using 5 microsatellite markers in the chromosome region 1q21-25 and 8 microsatellite markers in the chromosome region 6p21-25, which were the candidates of previous studies. All affected subjects were diagnosed and typed according to the criteria of the Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revised (DSM-Ⅳ-TR; American Psychiatric Association, 2000). All subjects signed informed consent. Results In chromosome 1, parametric analysis under the dominant inheritance mode of all 36 pedigrees showed that the maximum multi-point heterogeneity Log of odds score method (HLOD) score was 1.33 (α=0.38). The non-parametric analysis and the single point and multi-point nonparametric linkage (NPL) scores suggested linkage at D1S484, D1S2878, and D1S196. In the 19 paranoid schizophrenias pedigrees, linkage was not observed for any of the 5 markers. In the 17 undifferentiated schizophrenia pedigrees, the multi-point NPL score was 1.60 (P=0.0367) at D1S484. The single point NPL score was 1.95 (P=0.0145) and the multi-point NPL score was 2.39 (P=0.0041) at D1S2878. Additionally, the multi-point NPL score was 1.74 (P=0.0255) at D1S196. These same three loci showed suggestive linkage during the integrative analysis of all 36 pedigrees. In chromosome 6, parametric linkage analysis under the dominant and recessive inheritance and the non-parametric linkage analysis of all 36 pedigrees and the 17 undifferentiated schizophrenia pedigrees, linkage was not observed for any of the 8 markers. In the 19 paranoid schizophrenias pedigrees, parametric analysis showed that under recessive inheritance mode the maximum single-point HLOD score was 1.26 (α=0.40) and the multi-point HLOD was 1.12 (α=0.38) at D6S289 in the chromosome 6p23. In nonparametric analysis, the single-point NPL score was 1.52 (P=0.0402) and the multi-point NPL score was 1.92 (P=0.0206) at D6S289. Conclusion Susceptibility genes correlated with undifferentiated schizophrenia pedigrees from D1S484, D1S2878, D1S196 loci, and those correlated with paranoid schizophrenia pedigrees from D6S289 locus are likely present in chromosome regions 1q23.3 and 1q24.2, and chromosome region 6p23, respectively.     

Chromosome 1 loci in Finnish schizophrenia families

We have earlier reported evidence for linkage to two regions on chromosome 1q32--q42 in schizophrenia families collected for two separate studies in Finland. Here we report the results of a fine mapping effort aimed at further definition of the chromosomal region of interest using a large, population-based study sample (221 families, 557 affected individuals). Most affecteds (78%) had a DSM-IV schizophrenia diagnosis and the remaining had schizophrenia spectrum disorders. We genotyped a total of 147 microsatellite markers on a wide 45 cM region of chromosome 1q. The results were analyzed separately for families originating from an internal isolate of Finland and for families from the rest of Finland, as well as for all families jointly. We used traditional two-point linkage analysis, SimWalk2 multipoint analysis and a novel gamete-competition association/linkage method. Evidence for linkage was obtained for one locus in the combined sample (Z(max) = 2.71, D1S2709) and in the nuclear families from outside the internal isolate (Z(max) = 3.21, D1S2709). In the families from the internal isolate the strongest evidence for linkage was obtained with markers located 22 cM centromeric from this marker (Z(max) = 2.30, D1S245). Multipoint analysis also indicated these loci. Some evidence for association with several markers was observed using the gamete-competition method. Interestingly, the strongest evidence for linkage in the combined study sample was obtained for marker D1S2709, which is an intragenic marker of the DISC1 gene, previously suggested as a susceptibility gene for schizophrenia. These results are consistent with the presence of susceptibility gene(s) in this chromosomal region, a result also implied in other recent family studies of schizophrenia.     

Genome-wide search for schizophrenia susceptibility loci: The NIMH genetics initiative and millennium consortium

Schizophrenia has a complex pattern of inheritance, indicative of interactions among multiple genes and environmental factors. The detection and replication of specific susceptibility loci for such complex disorders are facilitated by the availability of large samples of affected sib pairs and their nuclear families, along with standardized assessment and systematic ascertainment procedures. The NIMH Genetics Initiative on Schizophrenia, a multisite collaborative study, was established as a national resource with a centralized clinical data base and cell repository. The Millennium Schizophrenia Consortium has completed a genome-wide scan to detect susceptibility loci for schizophrenia in 244 individuals from the nuclear families of 92 independent pairs of schizophrenic sibs ascertained by the NIMH Genetics Initiative. The 459 marker loci used in the scan were spaced at 10-cM intervals on average. Individuals of African descent were higher than those of European descent in their average heterozygosity (79% vs. 76%, P < .0001) and number of alleles per marker (9.2 vs. 8.4, P < .0001). Also, the allele frequencies of 73% of the marker loci differed significantly (P < .01) between individuals of European and African ancestry. However, regardless of ethnic background, this sample was largely comprised of schizophrenics with more than a decade of psychosis associated with pervasive social and occupational impairment. Am. J. Med. Genet. (Neuropsychiatr. Genet.) 81:275–281, 1998. © 1998 Wiley-Liss, Inc.     

Explorative study on the expression of neuregulin-1 gene in peripheral blood of schizophrenia

Neuregulin-1 (Nrg-1)¹ gene has been considered as a schizophrenia susceptibility gene. In order to observe the association of Nrg-1 gene with schizophrenia, the study was designed to investigate the effect of anti-psychotic treatment on the Nrg-1 mRNA expression in peripheral blood lymphocytes of the patients with a diagnosis of schizophrenia. The Nrg-1 mRNA expression in peripheral blood lymphocytes (PBLs) was measured by using semi-quantitative RT-PCR in 31 first-onset schizophrenia patients, 16 sibling controls and 31 no-sibship controls. Results showed that Nrg-1 mRNA expression in PBLs of patients was lower than that in other two control groups (F = 6.722, P = 0.002). However, as follow-up time extended, from the second week, Nrg-1 mRNA expression of PBLs in antipsychotic treated patients gradually increased and has obvious statistical significance compared the efficacy of taking anti-psychotic before and after therapy. These results demonstrated that Nrg-1 gene has association with schizophrenia. It is possible to select Nrg-1 mRNA expression of PBLs in schizophrenia patients as a potential therapeutic marker.     

HLA-A and DPB1 loci confer susceptibility to Graves' disease.

To investigate HLA-linked genetic factors involved in the pathogenesis of Graves' disease, 76 patients and 317 healthy controls in the Japanese population were examined for HLA-A, B, C, DR, and DQ specificities by serologic typing and for HLA-DPB1 alleles by DNA typing by using the PCR-SSOP method. The frequencies of HLA-A2, B46, Cw11, and DPB1*0501 were increased and those of HLA-A24, B7, Bw52, and DR1 were decreased in the patients. The increased frequencies of HLA-A2 and DPB1*0501 in the patients were statistically significant when the corrected p value (pc) was applied (pc < 0.02 and pc < 0.002, respectively). ORs for a risk to develop the disease were calculated among individuals positive for DPB1*0501 and/or HLA-A2, and the highest OR (10.5) was observed in individuals possessed both DPB1*0501 and HLA-A2. This observation suggests a synergic involvement of a HLA class II allele (DPB1*0501) and an HLA class I allele (HLA-A2) in the pathogenesis of Graves' disease.     

Association of rare variation in the glutamate receptor gene SLC1A2 with susceptibility to bipolar disorder and schizophrenia

The SLC1A2 gene encodes the excitatory amino acid transporter 2 (EAAT2). Glutamate is the major mediator of excitatory neurotransmission and EAAT2 is responsible for clearing the neurotransmitter from the synaptic cleft. Genetic variation in SLC1A2 has been implicated in a range of neurological and neuropsychiatric conditions including schizophrenia (SZ), autism and in core phenotypes of bipolar disorder (BD). The coding and putative regulatory regions of SLC1A2 gene were screened for variants using high resolution melting or sequenced in 1099 or in 32 BD subjects. Thirty-two variants were detected in the SLC1A2 gene. Fifteen potentially etiological variants were selected for genotyping in 1099 BD and 1095 control samples. Five amino acid changing variants were also genotyped in 630 participants suffering from SZ. None of the variants were found to be associated with BD or SZ or with the two diseases combined. However, two recurrent missense variants (rs145827578:G>A, p.(G6S); rs199599866:G>A, p.(R31Q)) and one recurrent 5′-untranslated region (UTR) variant (ss825678885:G>T) were detected in cases only. Combined analysis of the recurrent-case-only missense variants and of the case-only missense and 5′-UTR variants showed nominal evidence for association with the combined diseases (Fisher''s P=0.019 and 0.0076). These findings are exploratory in nature and await replication in larger cohorts, however, they provide intriguing evidence that potentially functional rare variants in the SLC1A2 gene may confer susceptibility to psychotic disorders.     

COMT: a common susceptibility gene in bipolar disorder and schizophrenia.

A variety of psychiatric illnesses, including schizophrenia and bipolar disorder, have been reported in patients with microdeletion on chromosome 22q11-a region which includes the catechol-O-methyltransferase (COMT) gene. The variety of psychiatric manifestations in patients with the 22q11 microdeletion and the role of COMT in the degradation of catecholamine neurotransmitters may thus suggest a general involvement of the COMT gene in psychiatric diseases. We have previously reported on a significant association between a COMT haplotype and schizophrenia. In this study, we attempt to test for association between bipolar disorder and the polymorphisms implicated in schizophrenia. The association between COMT and bipolar disorder was tested by examining the allele and haplotype found to be associated with schizophrenia. A significant association between bipolar disorder and COMT polymorphisms was found. The estimated relative risk is greater in women, a result consistent with our previous findings in schizophrenia. We suggest that polymorphisms in the COMT gene may influence susceptibility to both diseases--and probably also a wider range of behavioral traits.     

A genome-wide scan for schizophrenia and psychosis susceptibility loci in families of Mexican and Central American ancestry.

Schizophrenia is a complex psychiatric disorder, likely to be caused in part by multiple genes. In this study, linkage analyses were performed to identify chromosomal regions most likely to be associated with schizophrenia and psychosis in multiplex families of Mexican and Central American origin. Four hundred and fifty-nine individuals from 99 families, containing at least two siblings with hospital diagnoses of schizophrenia or schizoaffective disorder, were genotyped. Four hundred and four microsatellite markers were genotyped for all individuals and multipoint non-parametric linkage analyses were performed using broad (any psychosis) and narrow (schizophrenia and schizoaffective disorder) models. Under the broad model, three chromosomal regions (1pter-p36, 5q35, and 18p11) exhibited evidence of linkage with non-parametric lod (NPL) scores greater than 2.7 (equivalent to empirical P values of less than 0.001) with the peak multipoint NPL = 3.42 (empirical P value = 0.00003), meeting genomewide evidence for significant linkage in the 1pter-p36 region. Under the narrow model, the same three loci showed (non-significant) evidence of linkage. These linkage findings (1pter-p36, 18p11, and 5q35) highlight where genes for psychosis and schizophrenia are most likely to be found in persons of Mexican and Central American ancestry, and correspond to recent linkages of schizophrenia or psychosis in other populations which were formed in part from emigrants from the Spanish empire of the 15th and 16th centuries.     

Age-related changes in the expression of schizophrenia susceptibility genes in the human prefrontal cortex

The molecular basis of complex neuropsychiatric disorders most likely involves many genes. In recent years, specific genetic variations influencing risk for schizophrenia and other neuropsychiatric disorders have been reported. We have used custom DNA microarrays and qPCR to investigate the expression of putative schizophrenia susceptibility genes and related genes of interest in the normal human brain. Expression of 31 genes was measured in Brodmann's area 10 (BA10) in the prefrontal cortex of 72 postmortem brain samples spanning half a century of human aging (18-67 years), each without history of neuropsychiatric illness, neurological disease, or drug abuse. Examination of expression across age allowed the identification of genes whose expression patterns correlate with age, as well as genes that share common expression patterns and that possibly participate in common cellular mechanisms related to the emergence of schizophrenia in early adult life. The expression of GRM3 and RGS4 decreased across the entire age range surveyed, while that of PRODH and DARPP-32 was shown to increase with age. NRG1, ERBB3, and NGFR show expression changes during the years of greatest risk for the development of schizophrenia. Expression of FEZ1, GAD1, and RGS4 showed especially high correlation with one another, in addition to the strongest mean levels of absolute correlation with all other genes studied here. All microarray data are available at http://www.ncbi.nlm.nih.gov/geo/ (accession #: TBA).