Biological and functional consequences of polymorphisms in the XPD gene

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Biological and functional consequences of polymorphisms in the XPD gene

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Title: Biological and functional consequences of polymorphisms in the XPD gene
Author: Kevin James Wolfe
Abstract: Epidemiological studies have documented many associations between single nucleotide polymorphisms (SNPs) in the nucleotide excision repair gene XPD (ERCC2) and cancer risk. Little is known, however, about the underlying mechanisms for these associations. I used lymphocytes from healthy subjects to explore novel mechanisms which could explain the reported risk-modifying effects on disease susceptibility of three SNPs in the XPD gene, the synonymous C156A SNP in exon 6 and the nonsynonymous SNPs Asp312Asn in exon 10 and Lys751Gln in exon 23. Baseline and NNK-induced chromosomal aberrations (Ca) were assessed by cytogenetic analysis and then P values were calculated as estimates of sub-population differences for increased frequencies of CAs associated with the three XPD polymorphisms. I found significant elevation in baseline frequencies of CAs among smokers with the variant 312Asn polymorphism (P=0.028). Elevations in NNK-induced aberrations were found among younger subjects (age<39 years) with the 156A or the 751Gln polymorphism, (P=0.025 and P=0.037, respectively) and in females compared to males with a combination of the 312Asn and the 751Gln polymorphisms (P=0.045). Application of real time PCR showed that each SNP, alone and in combination, significantly decreased constitutive XPD mRNA levels (P<0.003) in lymphocytes. Decreases in XPD mRNA levels were significantly higher in older subjects and in smokers. Localized Mfold structure analysis of the mRNA sequence surrounding the studied SNPs were predicted to alter mRNA secondary structure, which indicated that these SNPs potentially affect local folding and mRNA stability. UVC treatment of cells with wild type XPD produced a significant increase (P=0.03) in XPD protein levels by 30 min, which surprisingly coincided with a decrease in XPD mRNA transcript copy number (P=0.0002). Fluorescent confocal microscopy demonstrated that this increase in XPD protein appeared largely due to an increase in nuclear localization of XPD, which was evident at 30 min and persistent at 6 hrs. New observations from this project provide possible mechanistic explanations for the association of polymorphisms in XPD with increased genetic damage (CAs) and cancer risk.
URI: http://hdl.handle.net/2152.3/248
Date: 2006-10-23

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