Four hundred sixty nine Iranian participants, including 276 unrelated participants with schizophrenia and 193 healthy matched controls were evaluated. Schizophrenia patients recruited from the Roozbeh Psychiatry Hospital, Tehran University of Medical Sciences, Tehran, Iran. In the case group, the inclusion criteria were the schizophrenia diagnostic criteria based on the fourth edition of diagnostic and statistical manual of mental disorders-text revised (DSM-IV-TR) using the schedule for affective disorders and schizophrenia, and no other mental disorder, the use of the lifetime version of the Schizophrenia, and Affective Disorders Schedule. Healthy controls were recruited from the same geographical area. In this group, the inclusion criteria were not suffering from any mental disorders based on DSM-IV-TR criteria and not having first-degree relatives with any mental disorder, doing clinical interviews, pedigree, past medical and psychiatric history evaluations by two expert psychiatrists, the researchers assessed the presence of all types of mental disorders. The exclusion criteria for the both groups of case and control were WAIS IQ score below 70, history of any other medical conditions, because of possibility to mimic the symptoms of schizophrenia, substance addiction or use in the past one year to abuse/dependence, and severe head trauma. Demographic features are shown in supplementary Table 1.

The clinical diagnosis of schizophrenia was made independently by two expert psychiatrists according to the DSM-IV-TR criteria. We assessed the psychopathology, including positive and negative symptoms, general psychopathology and total score, using the positive and negative syndrome scale (PANSS) in patients.

Cognitive impairments, the IQ and executive functions were assessed in both groups of cases and controls using the Wechsler adult intelligence scale (WAIS-III) and the WCST, respectively.

All blood samples were taken by vacuum tube pre-filled with the anticoagulant EDTA. High molecular weight genomic DNA was prepared from venous blood using the salting out procedure.33 Two SNPs (rs2439272 and rs6988339) were selected by using the related literature. Genotyping was performed blind to status by using polymerase chain reaction (PCR), restriction fragment length polymorphism-PCR (RFLP-PCR), and DNA sequencing. Primers were designed using the Primer3; http://biotools.umassmed.edu/bioapps/primer3_www.cgi. Primers sequences, PCR product sizes, corresponding restriction fragment enzyme and digested sizes for each SNP are shown in supplementary Table 2. Annealing temperatures were 56 °C to 57 C. 100% of the genotypes were callable, and minor allele frequency was greater than 2 %. The digested fragments were fractionated on 2 % agarose gel. In addition, in order to eliminate the genotyping errors, all raw genotyping data were independently read by two experts and the suspect genotypes were retyped. Furthermore, for each SNP, a random group of samples were also re-genotyped by direct sequencing to confirm the genotyping results of restriction fragment enzyme method.

The Hardy–Weinberg equilibrium for genotypic distributions in two populations was tested using the χ2 goodness-of-fit test. Odds ratio and 95 % confidence interval (CI) was calculated to evaluate the effect of different genotypes. The allelic association and linkage disequilibrium (LD) were estimated using the COCAPHASED (UNPHASED) program.34 The genotype frequencies between cases and controls were compared using the CLUMP22 software35 by running 1000 Monte Carlo permutation. Genotypic association was tested by the χ2, or by Fisher’s exact test to assess the significance of the results. The independent-samples t-test procedure was used to compare the means of the quantitative test scores for two groups of case and control. A general linear regression model (Univariate) was used to assess the relation between a categorical grouping (carriers or not of the risk alleles) vs. quantitative outcomes, including the IQ and WCST scores. Means and standard deviations of WAIS and WCST scores were calculated based on the genotypes. Cohen's d was used as an effect size to indicate the standardized difference between each two means.

The significance level for all statistical tests was P < 0.05. The power analysis for rs2439272 and rs6988339 were %60 and %80 respectively.

All of the patients had the diagnosis of chronic schizophrenia with more than 8 years, and had a drug regimen of 4–6 mg of Risperidone (Chlorpromazine equivalents treatment). Each subscales of PANSS scores [Positive Symptoms (F = 57.05), Negative Symptoms (F = 46.69), General Psychopathology Symptoms (F = 13.75), and Total score (F = 30.99)] in patients were significantly higher compared the healthy controls (p < 0.001*).

All scores of WAIS (including verbal IQ, performance IQ and total IQ) were decreased significantly in all, male and female patients with schizophrenia vs. healthy controls (P < 0.001). In all participants, in patients with schizophrenia vs. healthy controls, the verbal IQ scores (Mean ± SD) (74.35 ± 11.07 and 105.19 ± 7.25 respectively) were decreased significantly (P < 0.001). The performance IQ scores (Mean±SD) (74.19±8.72 vs. 108.48 ± 5.66) were also decreased significantly (P < 0.001). Furthermore, the total IQ scores (Mean±SD) (74.35±11.07 vs. 105.19 ± 7.25) were decreased significantly as well (P < 0.001). In male participants, in patients with schizophrenia vs. healthy controls, the verbal IQ scores (Mean ± SD) (74.16 ± 11.59 and 104.40 ± 7.26 respectively) were decreased significantly (P < 0.001). The performance IQ scores (Mean±SD) (74.31±10.14 vs. 107.92 ± 5.78) were also decreased significantly (P < 0.001). In addition, the total IQ scores (Mean±SD) (74.15±11.07 vs. 112.97 ± 6.39) were decreased significantly as well (P < 0.001). In female participants, in patients with schizophrenia vs. healthy controls, the verbal IQ scores (Mean ± SD) (74.64 ± 10.29 and 106.55 ± 7.06 respectively) were decreased significantly (P < 0.001). The performance IQ scores (Mean±SD) (74.01±6.00 vs. 109.45 ± 5.36) were also decreased significantly (P < 0.001). And the total IQ scores (Mean±SD) (73.84±9.63 vs. 114.21 ± 6.10) were decreased significantly as well (P < 0.001).

Moreover, all scores of WCST (including perseveration, non-perseveration and total errors) were increased significantly in all, male and female patients with schizophrenia vs. healthy controls. The exceptions were for non-perseveration errors that were decreased significantly in all and female patients with schizophrenia vs. healthy controls. In all participants, in patients with schizophrenia vs. healthy controls, the perseveration errors (Mean ± SD) (23.12 ± 6.75 and 5.50 ± 0.56 respectively) were increased significantly (P < 0.001). The non-perseveration errors (Mean±SD) (4.61±2.60 vs. 5.50 ± 0.15) were decreased significantly (P < 0.001). And the total errors (Mean±SD) (27.83±5.43 vs. 11.00 ± 0.71) were increased significantly (P < 0.001). In male participants, in patients with schizophrenia vs. healthy controls, the perseveration errors (Mean ± SD) (22.93 ± 6.81 and 5.55 ± 0.50 respectively) were increased significantly (P < 0.001). The non-perseveration errors (Mean±SD) (6.64±2.83 vs. 5.51 ± 0.14) were also increased significantly (P < 0.001). And the total errors (Mean±SD) (27.88±4.80 vs. 11.06 ± 0.63) were increased significantly too (P < 0.001). In female participants, in patients with schizophrenia vs. healthy controls, the perseveration errors (Mean ± SD) (23.40 ± 6.67 and 10.90 ± 0.83 respectively) were increased significantly (P < 0.001). The non-perseveration errors (Mean±SD) (4.56±2.22 vs. 5.48 ± 0.18) were decreased significantly (P = 0.001). And the total errors (Mean±SD) (27.75±6.28 vs. 10.90 ± 0.83) were increased significantly (P < 0.001).

We compared the allele and genotype frequencies in patients with schizophrenia vs. healthy controls. For the SNP rs2439272, we found a significant difference in G allele frequencies between patients with schizophrenia (0.53) and healthy controls (0.44) in all subjects (P = 0.009), and between patients with schizophrenia (0.53) and healthy controls (0.43) in male samples (P = 0.019). For the same SNP, we found significant difference in GG genotype frequencies between patients with schizophrenia (0.26) and healthy controls (0.16) in all subjects (P = 0.025), and between patients with schizophrenia (0.28) vs. healthy controls (0.16) in male samples (P = 0.024).

For the SNP rs6988339, we found significant differences in G allele frequencies between patients with schizophrenia (0.44) and healthy controls (0.33) in all subjects (P = 0.0007), and between patients with schizophrenia (0.45) and healthy controls (0.29) in male samples (P = 0.005). For the same SNP, we found significant differences in GG genotype frequencies between patients with schizophrenia (0.15) and healthy controls (0.09) in all subjects (P = 0.002). These genotype frequencies were significantly different between patients with schizophrenia (0.18) vs. healthy controls (0.07) in male samples (P = 0.006). In female samples, for both of the SNPs, no significant differences in allele and genotype frequencies were detected (Table 1). Because there was no linkage disequilibrium between the two selected variants in our analysis, we did not do haplotype analysis.

For the both SNPs, our findings indicate that there is a significant impact on verbal IQ (P < 0.001), performance IQ (P < 0.001) and total IQ (P < 0.001) in all, male and female subjects. These findings suggest a direct association between the rs2439272 and rs6988339 GG genotype with the verbal, performance and total IQ impairments (Table 2).

Cohen's d showed that for both SNPs, A allele is protective and G allele is associated with poorer WAIS scores. The maximum standard differences were observed between AA and GG genotypes.

For the SNP rs2439272, our findings indicate that there is a significant impact of GG genotype on perseverative (P < 0.001), and total errors (P < 0.001) in all, male and female subjects. But for the non-perseverative errors, we also found significant impact in all (P = 0.019), male (P=0.009) and female (P = 0.001) participants. These findings suggest a direct association between the rs2439272 GG genotype with the perseverative, non-perseverative, and total errors based on the WCST scores in all, male and female participants (Table 3). Regarding the effect of rs6988339, we found significant impact of GG genotype on perseverative (P < 0.001), non-perseverative (P < 0.001) and total errors (P < 0.001) in all, male and female subjects. But for the non-perseverative errors, we also found significant difference in male (P=0.005), and female participants (P<0.001). These findings suggest a direct association between the rs6988339 GG genotype with the perseverative, non-perseverative, and total errors based on the WCST scores in male and female, and perseverative, and total errors in all participants (Table 3). Cohen's d showed that for both SNPs, A allele is protective and G allele is associated with poorer WCST scores. The maximum standard differences were observed between AA and GG genotypes.