Functional Analysis of Upstream Common Polymorphisms of the Dopamine Transporter Gene

The human dopamine transporter (DAT, SLC6A3) has been extensively investigated because of its potential involvement in neuropsychiatric disorders. The core elements responsible for its transcription have been identified. A regulatory role for certain genomic variants upstream to the core promoter is known. Recently, other single-nucleotide polymorphisms (SNPs) have been identified in this region and are thought to be associated with schizophrenia and bipolar I disorder. Hence, we have investigated the impact of common SNPs in a 2.8-kilobase region flanking the core promoter region (−2.7 to +63 base pair) in the neuroblastoma cell line SH-SY5Y. Haplotypes generated by site-directed mutagenesis revealed varying impact of individual SNPs on promoter activity using dual luciferase assays. In silico analyses also predicted allele-specific binding of transcription factors for some of these SNPs. Though electrophoretic mobility shift assays indicated several factors that appeared to bind to specific sites within this region, allele-specific binding was not detected for any SNP apart from rs3756450. We have thus identified novel putative regulatory domains flanking the core promoter of DAT that merit further investigation

Systematic Association Studies of Mitochondrial DNA Variations in Schizophrenia: Focus on the ND5 Gene

Postmortem studies, as well as genetic association studies, have implicated mitochondrial dysfunction in schizophrenia (SZ). We conducted multistaged analysis to assess the involvement of mitochondrial DNA (mtDNA) variations in SZ. Initially, the entire mtDNA genome was sequenced in pools of DNA from SZ cases and controls (n = 180 in each group, set 1). Two polymorphisms localized to the NADH dehydrogenase subunit 5 (ND5) gene demonstrated suggestive case control allele frequency differences (mtDNA 13368 G/A, p = .019 and mtDNA 13708G/A, p = .043). Hence, the ND5 gene was sequenced in individual samples from the initial panel of cases and controls. Additional subjects from another independent set of cases and controls (set 2, cases, n = 244, controls n = 508) were also sequenced individually. No significant differences in allele frequencies for mtDNA 13368 G/A, and mtDNA 13708G/A were observed. However, we identified 216 other rare variants, 53 of which were reported earlier in association studies of other mitochondrial disorders. We compared the distribution of polymorphisms in both sets of cases and controls. No significant case-control differences were observed in the smaller, first set. In the second set, cases had more variants overall (p = 0.014), as well as synonymous variants (p = 0.02), but the difference for nonsynonymous variants was not significant (p = 0.19). Screening available first-degree relatives (n = 10) revealed 10 maternally inherited variations, suggesting that not all the variants are somatic mutations. Further investigations are warranted

Rare coding variants in the phospholipase D3 gene confer risk for Alzheimer's disease

Genome-wide association studies (GWAS) have identified several risk variants for late-onset Alzheimer's disease (LOAD)(1,2). These common variants have replicable but small effects on LOAD risk and generally do not have obvious functional effects. Low-frequency coding variants, not detected by GWAS, are predicted to include functional variants with larger effects on risk. To identify low frequency coding variants with large effects on LOAD risk, we performed whole exome-sequencing (WES) in 14 large LOAD families and follow-up analyses of the candidate variants in several large case-control datasets. A rare variant in PLD3 (phospholipase-D family, member 3, rs145999145; V232M) segregated with disease status in two independent families and doubled risk for AD in seven independent case-control series (V232M meta-analysis; OR= 2.10, CI=1.47-2.99; p= 2.93×10(-5), 11,354 cases and controls of European-descent). Gene-based burden analyses in 4,387 cases and controls of European-descent and 302 African American cases and controls, with complete sequence data for PLD3, indicate that several variants in this gene increase risk for AD in both populations (EA: OR= 2.75, CI=2.05-3.68; p=1.44×10(-11), AA: OR= 5.48, CI=1.77-16.92; p=1.40×10(-3)). PLD3 is highly expressed in brain regions vulnerable to AD pathology, including hippocampus and cortex, and is expressed at lower levels in neurons from AD brains compared to control brains (p=8.10×10(-10)). Over-expression of PLD3 leads to a significant decrease in intracellular APP and extracellular Aβ42 and Aβ40, while knock-down of PLD3 leads to a significant increase in extracellular Aβ42 and Aβ40. Together, our genetic and functional data indicate that carriers of PLD3 coding variants have a two-fold increased risk for LOAD and that PLD3 influences APP processing. This study provides an example of how densely affected families may be used to identify rare variants with large effects on risk for disease or other complex traits