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Polymorphisms XRCC1-R399Q and XRCC3-T241M and the Risk of Breast Cancer at the Ontario Site of the Breast Cancer Family Registry

¹ Fred A. Litwin Centre for Cancer Genetics, ² Division of Epidemiology and Biostatistics, ³ Department of Pathology and Laboratory Medicine, Samuel Lunenfeld Research Institute, Mount Sinai Hospital, Toronto, ON, Canada and Departments of ⁴ Public Health Sciences and ⁵ Laboratory Medicine and Pathobiology, University of Toronto, Toronto, ON, Canada

Requests for reprints: Hilmi Ozcelik, Fred A. Litwin Centre for Cancer Genetics, Samuel Lunenfeld Research Institute, Mount Sinai Hospital, Room 992A, 600 University Avenue, Toronto, ON M5G 1X5. Phone: (416) 586-4996; Fax: (416) 586-8869. E-mail: ozcelik{at}mshri.on.ca

	Abstract

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This study investigates the role of two nonsynonymous single nucleotide polymorphisms in DNA repair genes, X-ray repair cross-complementing group 1 (XRCC1)-R399Q and X-ray repair cross-complementing group 3 (XRCC3)-T241M, in breast cancer. Incident cases of invasive breast cancer in Caucasian women [n = 402, mean age = 45.7 (SD = 6.2) years] and female Caucasian controls [n = 402, mean age = 45.2 (6.5) years] frequency matched on 5-year age intervals were identified from the Ontario Familial Breast Cancer Registry. No evidence for a main effect of the XRCC1-R399Q genotype on breast cancer risk was observed. Estimates of risk for a family history (FH) of breast cancer compared with no FH differed by XRCC1-R399Q genotype (P value for interaction = 0.001). Homozygote XRCC1-399 R/R individuals and FH+ were at a 2.92-fold [95% confidence interval (95% CI) = 1.47–5.79] increased risk of disease compared with FH– individuals; the estimate of risk increased for R/Q heterozygotes with FH+ [odds ratio (OR) = 3.85, 95% CI = 1.94–7.65] but not for Q/Q homozygotes with FH+ (OR = 0.54, 95% CI = 0.20–1.47) compared with homozygous R/R and FH– individuals. A marginal positive association for XRCC3-241 M/M compared with T/T genotype was found (OR = 1.44, 95% CI = 0.94–2.19), but the heterozygous T/M was not associated with an increase in risk (OR = 0.96, 95% CI = 0.71–1.32). There was also some evidence for a combined effect of body mass index and XRCC3-T241M on estimates of risk. Our results suggest that these polymorphisms may influence breast cancer risk by modifying the effect of risk factors such as FH. There is a need for further study into the role of these polymorphisms as effect modifiers.

	Introduction

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Identifying genes associated with breast cancer continues to be a major goal of current research. Among unanswered questions are the number of genetic variants that may be involved in predisposition to the disease and their role in modifying the effect of environmental and life-style factors. Several studies have reported low penetrant variants, single nucleotide polymorphisms (SNPs), as potential cancer susceptibility factors including two variants involved in DNA repair: X-ray repair cross-complementing group 1 (XRCC1)-R399Q (arginine glutamine, amino acid position 399; G A, nucleotide position 28152) and X-ray repair cross-complementing group 3 (XRCC3)-T241M (threonine methionine, amino acid position 241; C T, nucleotide position 18067; Refs. 1–31). These SNPs occur within functional domains of essential DNA repair proteins and result in nonsynonymous amino acid substitutions differing in volume, charge, and/or polarity at positions that are highly conserved within the Mammalia class.² How these SNPs relate to DNA damage phenotypes in human cells and tissues remains uncertain, but at least a few studies (12, 32, 33) have implied that the XRCC1-Q399 and XRCC3-T241 alleles have an important, potentially harmful phenotype.

The association between these polymorphic alleles and breast cancer has been reported in the peer-reviewed literature by a few case-control studies (6, 7, 21, 29, 34). Duell et al. (6) published the first results using a population-based case-control study design. This study did not show evidence of a main effect for the XRCC1-R399Q polymorphism among Caucasian women but did find a potential interaction between genotype and ionizing radiation (IR). The second study by Smith et al. (21) oversampled controls with a family history (FH) of breast cancer to investigate the combined effect of genotype (XRCC1-R399Q and XRCC3-T241M) and FH on risk estimates for the disease. Data stratified by FH were, however, limited in sample size and no significant association between breast cancer risk and genotype was observed. Kim et al. (7) reported results from a hospital-based case-control study of Korean women, which, unlike the other studies, found that homozygosity of the XRCC1-Q399 allele placed women at a 2.4-fold risk [95% confidence interval (95% CI) = 1.20–4.72] for this disease and premenopausal women at a 3.8-fold risk (95% CI = 1.44–10.30). The authors of this study further report a synergistic interaction in breast cancer between XRCC1-R399Q polymorphism and alcohol consumption (data not shown). The Kuschel et al. (29) study was the only large population-based case-control study of the XRCC3-T241M polymorphism. The results showed that homozygous carriers of the XRCC3-M241 allele were associated with an increased risk of 1.3-fold (95% CI = 1.1–1.6), but neither adjusted estimates nor gene exposure effects were reported. The most recent study to be published on the XRCC3-T241M polymorphism and the risk of breast cancer, by Jacobsen et al. (34), did not find evidence for an association. In summary, results are not consistent and studies vary significantly in methodology and analyses. As a result, what has been understood about the role of these alleles in the etiology of breast cancer is still unclear, and there is a need to resolve these inconsistencies.

This study reports risk estimates for breast cancer using systematically collected data from the Ontario (Canada) site of the Breast Cancer Family Registry and population controls. Potential biologically plausible interactions between genotypes and exposures related to DNA repair capacity, including those examined previously by other studies, are evaluated. This study specifically looks at exposures during adolescence, a time where the breast tissue is more susceptible to DNA damage caused by exposure to tobacco carcinogens and low-dose IR. Furthermore, this study focuses on a younger population (under age 55) than the other studies, where the occurrence of breast cancer would more likely signify underlying genetic causes.

	Methodology

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Design/Population
Incident cases of breast cancer were identified from the Ontario Familial Breast Cancer Registry (OFBCR). The OFBCR is a population-based registry in Ontario, Canada that comprises one of six international sites of the NIH-funded Breast Cancer Family Registry. The OFBCR identified potential participants from the Ontario Cancer Registry (OCR), which registers virtually all cases of breast cancer in the province (97.5%; Ref. 35), and included all women aged 20–54 years, a 35% random sample of women aged 55–69 years, and all men diagnosed with invasive breast cancer aged 20–74 years. The majority of cases are reported to the OCR within 6 months of diagnosis. All cases were pathologically confirmed and diagnosed between 1996 and 1998. Pathology reports were reviewed to determine a physician involved in the care of each patient. Information about the OFBCR and a FH questionnaire were mailed to those patients once physician permission could be obtained. Questionnaires that were received were classified by whether they met criteria for "genetic" risk that had been established previously by the OFBCR (36, 37). Those individuals who qualified as "genetic" cases and a 25% random sample of "nongenetic" cases that were interested in further participating in the registry were telephoned to review their FHs. Epidemiological and diet questionnaires were mailed to these individuals. They were also asked for permission to contact relatives and about suitable arrangements for providing a blood sample.

In this study, we included only cases under age 55 at the time of diagnosis. Recruitment rates and other characteristics are described briefly in this report. There were 6219 individuals registered in the OCR that were diagnosed under age 55. Ninety-one percent of individuals (n = 5649) could be approached for possible participation in this study. FH questionnaires were completed and returned by 3609 (63.9%) individuals. All "genetic" cases (n = 1396) and a randomly selected sample of "nongenetic" cases (n = 529) were invited to complete an epidemiological questionnaire and provide a blood sample. Of the total cases, 1431 (74.3%) cases returned epidemiological questionnaires and 1212 (63.0%) provided a blood sample. About 2% of the population died at the various stages of recruitment. This study included all "nongenetic" (n = 315) and a 25% random sample of those who were "genetic" cases (n = 224) who had provided a blood sample to obtain a more representative sample of the breast cancer population under age 55. Out of a total of 539 individuals, cases of male breast cancers and those that did not identify themselves as Caucasians were excluded (n = 80; 14.8%). In addition, sufficient DNA could not be extracted from blood samples of 49 individuals (10.7%), and 8 individuals (1.7%) could not be genotyped.

Female population controls were recruited by calling randomly selected residential telephone numbers throughout the province of Ontario. Eligible controls were women with no history of breast cancer. They were frequency matched on 5-year age groups based on the age distribution of the entire OFBCR population. The total number of households contacted by telephone was 14,653. Sixteen percent (n = 2366) of households had an eligible participant willing to participate in the study. The majority (n = 7829; 53.4%) of households did not have an eligible participant. Among households not participating, 322 (2.2%) had an eligible participant. Eligibility could not be determined in the remaining 2194 (15.0%) households. Seventy-three percent (n = 1726) of individuals completed and returned questionnaires, and 52.4% (n = 1290) consented to providing a blood sample. Only a proportion, randomly selected from those under age 55 and agreeing to donate blood, were asked to do so (n = 676), and 62.3% (n = 421) in fact did. Ten (2.4%) samples were insufficient to extract DNA and 1 (0.2%) sample could not be genotyped.

Molecular Analysis
DNA was extracted from peripheral blood lymphocytes. SNP genotyping was performed using matrix-assisted laser desorption ionization time of flight (MALDI-TOF) mass spectrometry (MS; Ref. 38). PCR primers [XRCC1: 5'-CCCAAGTACAGCCAGGTC-3' (forward) and 5'-CCGCTCCTCTCAGTAGTC-3' (reverse); XRCC3: 5'-GCTCGCCTGGTGGTCATC-3' (forward) and 5'-GCTTCCGCATCCTGGCTAA-3' (reverse)] were designed using the Oligo Primer Analysis Software (National Biosciences, Inc., Plymouth, MN). Multiplexed PCR reactions (10 µl) contained 10 ng genomic DNA, 1x reaction buffer, 0.20 unit Platinum Taq polymerase (Invitrogen Life Technologies, Burlington, Ontario, Canada), 0.40 µl deoxynucleotides (dNTPs), and 0.18 µM of each primer. Cycling conditions for PCR amplification consisted of 39 cycles (30 s at 94°C, 15 s at 58°C, and 10 s at 72°C). Products were purified using shrimp alkaline phosphatase (0.1 unit/µl; Amersham Biosciences, Bail d Urfe, Quebec, Canada) and exonuclease I (0.5 unit/µl; Amersham Biosciences). Other primers (XRCC1: 5'-CGGCGGCTGCCCTCCC-3' and XRCC3: 5'-ACTGCTCAGCTCACGAGC-3') were designed to anneal to the targeted DNA immediately upstream of the SNP site to be extended by one or more nucleotides in the presence of dNTPs and dideoxynucleotides using the very short primer extension strategy (39). Multiplexed reactions (10 µl) contained 3.0 µl PCR products, 1x ThermoSequenase buffer, 1 unit ThermoSequenase (Amersham Biosciences), 8 µM dNTPs + dideoxynucleotides, and 0.12 µM of each primer. The extension products were purified using a cation exchange resin (DOWEX 50W8-200; Aldrich Chemical Co., Milwaukee, WI). About 1–2 µg of resin were added to each reaction tube and shaken for 10 s. A DNA MALDI-TOF MS matrix (3-hydoxypicolinic acid; Chemika, Seelze, Germany) was spotted (0.5 µl) on each of the 386-well plate (AnchorChip 400/384; Bruker Daltonics, Billerca, MA) for MS. The same amount of each sample was spotted on dried matrix. Samples were analyzed using the Reflex IV MALDI-TOF MS (Bruker Daltonics). The results were acquired by AutoXecute and analyzed by Genotools (Bruker Daltonics; Ref. 40). Inconclusive results were repeated by MS and/or using direct sequencing. Seventy-five percent of the population was also genotyped using the 5' nuclease (Taqman) assay (ABI Prism 7700 system; PE Applied Biosystems, Foster City) for the XRCC1-R399Q polymorphism. The two assays, MS and Taqman, yielded a 95% agreement; discordant results were genotyped using direct sequencing.

Exposure Information
Information about FH of cancer was obtained by self-report using a structured questionnaire. A separate questionnaire elicited information on age (cases, age at diagnosis less 1 year; controls, age at time the risk factor questionnaire was completed), ethnicity, height and weight, education, alcohol and tobacco use, medical and reproductive history, and radiation exposure. Participants were defined as adolescent smokers if they began smoking at least 1 cigarette/day for a 3-month period before age 20. Drinkers were defined as participants who consumed alcoholic beverages (beer, wine, or spirits) at least once a week for a 6-month period in their lifetime. Individuals who reported receiving X-rays to the breast/chest area under age 20 were classified as adolescents exposed to IR.

Statistical Analysis
² tests or Fisher's exact tests were used to examine the differences in the proportions of categorical variables between cases and controls. For continuous variables, Student's t test was performed. Tests for Hardy-Weinberg equilibrium among controls were conducted using observed genotype frequencies and a ² test with 1 df. Both crude and adjusted odds ratios (ORs) and the 95% CI measuring the association between breast cancer and risk factors were estimated using unconditional logistic regression. P < 0.05 was used as the criterion of significance. Variables to be used in building multivariable models were selected a priori. The genotype of XRCC1-R399Q and XRCC3-T241M were variables of main interest; other risk factors for breast cancer related to DNA repair capacity [i.e., age, body mass index (BMI), smoking status, alcohol status, IR exposure, and FH of breast cancer] were included in multivariable models. Entry of a confounding variable into the model was defined using Rothman and Greenland's (41) definition of confounding as a change of at least 10% in the ß parameter estimates. Other potential risk factors evaluated but not included in the final models were menopausal status, parity, and age at first birth. Premenopausal women were defined as individuals not taking hormone replacement therapy whose last menses was within a year of the reference age. Postmenopausal women were individuals whose time since their last menses was more than 1 year from the reference age, and the reason for cessation was not because of a surgical procedure other than complete oophorectomy. None of these latter factors were identified as confounders in this study population. Only gene-environment interactions that were biologically reasonable were tested. Interaction effects were modeled by assuming a multiplicative effect on the logit scale and tests for interaction were performed using the likelihood ratio test. Individuals with missing data for nongenetic risk factors were excluded in multivariable analyses. All statistical analyses were performed using the Statistical Analysis System software (version 8; SAS Institute, Cary, NC).

Ethics
Approval for this study was obtained from the Research Ethics Board of Mount Sinai Hospital, Toronto, ON, Canada and the Advisory and Steering Committees of the NIH-funded Breast Cancer Family Registry.

	Results

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Selected characteristics of the case and control populations are listed in Table 1. A few individuals identified themselves as Caucasian as well as another ethnic group (Caucasian-Native: n = 15, Caucasian-Asian: n = 3, Caucasian-Black: n = 2). Cases and controls ranged in age from 25 to 54 years, with a third of the population past menopause. Fifteen (3.7%) cases had multiple diagnoses of breast cancer and 19 (4.7%) were known to be deceased to date. There were no significant differences between cases and controls in alcohol consumption or cigarette smoking and IR exposure before age 20 (data not shown); however, a significantly larger proportion of controls were overweight or obese (BMI > 25) compared with cases (40.6% versus 53.5%).

	Discussion

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Studies investigating cancer risk by XRCC1-R399Q genotype have not consistently shown evidence of an association. Among Caucasians, there is some evidence that this SNP may decrease risk for nonmelanoma skin cancer (19) and therapy-related acute myeloblastic leukemia (23) and increase risk for melanoma skin cancer (19). Inconsistent results have been found for lung cancer (2, 4, 8, 25, 26) and cancers of the head and neck (13, 14), and there appears to be no effect for bladder cancer (11, 12), prostate cancer (22), or breast cancer (6, 7, 21). The latter study by Duell et al. (6) concluded that the relationship between XRCC1-R399Q genotype and breast cancer risk might be complicated by other factors. The authors of this study suggest that potential XRCC1 codon 399-dependent risk effects should account for biologically plausible interactions with other genetic and environmental factors because the mechanism by which this SNP functions is unknown at this time and unlikely to be independent of such factors. However, evaluation of the significance of gene-gene and gene-environment interactions in our study as in preceding studies needs to be interpreted with caution but is an important starting point meant to encourage the design of other studies with a larger sample size for relevant subgroups.

Our findings suggest that the effect of the XRCC1-R399Q polymorphism on breast cancer risk differs by FH of the disease. The possibility of an interaction between XRCC1-R399Q and FH was also explored by Smith et al. (21). This study specifically targeted controls with a positive FH and their analyses showed that controls with a FH had a very similar genotype distribution as cases, further supporting the hypothesis that these SNPs may contribute to FH-related susceptibility to breast cancer. A possible interpretation for the presence of such an association in the subgroup with FH may be that FH, particularly first-degree, broadly represents shared genes and environmental factors, and the presence of a single polymorphism, with likely weak effects on the individual's phenotype, may not be measurable except in the context of these supporting factors. Among individuals without a familial predisposition, the effect may be hidden by sum effects of other unidentified genetic and environmental factors.

There were several reasons to investigate other potential gene-environment interactions. Cigarette smoking, alcohol consumption, and IR exposure are associated with the production of free radical intermediates, including hydroxyethyl free radicals and reactive oxygen species that induce base damage and single- and double-strand breaks (42–46), which are corrected in part by the involvement of XRCC1 and XRCC3. Several reports suggest that free radicals and oxidative stress play an important role in the pathogenesis of breast cancer (47). Furthermore, alcohol consumption and IR exposure are known risk factors for the disease and there is some evidence that adolescent smoking could increase risk (48–50). Although this study was unable to show evidence for these gene-environment interactions, other studies agree that these are important hypotheses to examine (51–53) and should be a subject of further research.

This study also investigated a potential interaction between genotypes and BMI. A recently published study showed improved DNA repair capacity in marginally undernourished individuals (low BMI), which the authors suggest may improve longevity by postponing the age-dependent damage to DNA (54). Therefore, we reasoned that there might be a difference when comparing normal weight and overweight individuals by DNA repair genotypes. Our hypothesis was that if either SNP is functional and contributes to a deficient DNA repair phenotype then among individuals with less efficient repair DNA damage (i.e., overweight individuals), the effect of a single SNP may be stronger than among normal weight individuals. Our results provide preliminary evidence for a potential interaction between XRCC3-T241M polymorphism and BMI. However, contrary to expectation, normal weight individuals were at an increased risk if they were XRCC3-241 M/M carriers compared with XRCC3-241 T/T or T/M carriers (OR = 2.68, 95% CI = 1.45–4.94), but among overweight or obese individuals, the risk of the disease did not appear to depend on the genotype of this polymorphism.

Our last objective was to investigate a possible joint effect of the SNPs on breast cancer risk considering that base excision repair and double-strand break repair are thought to be involved in coordinated activities. A potential partnership has been supported by evidence showing that base excision repair activity in human and murine cell extracts closely parallels their levels of endogenous p53 (55). Evidence for an interaction has also been found in studies of Schizosaccharomyces pombe (56). Furthermore, these particular genes, XRCC1 and XRCC3, are both associated with RAD51 (57–59), which is itself associated with the high penetrant breast cancer susceptibility genes, BRCA1 and BRCA2; therefore, there is reason to speculate possible additive effects of these SNPs on disease risk estimates. Indeed, at least one study of breast cancer risk has shown a statistically significant interaction between XRCC1 polymorphism: -R194W and XRCC3-T241M (21).

The functional differences between alleles has not be entirely understood; consequently, although variants leading to diminished XRCC1 or XRCC3 function may be predicted to confer an increased risk of cancer due to accumulated levels of DNA damage, it is also plausible that these cells may be more likely to undergo apoptosis rendering them potentially protective alleles. Considering that many genes are involved in repair of DNA damage, there is also the possibility that these polymorphisms might be in linkage disequilibrium with other causative factors. Evidence for linkage disequilibrium has been suggested by Duell et al. (6). This study found a positive association for XRCC1-399 Q/Q and breast cancer only among African American women, pointing to unmeasured genetic and environmental factors as potentially responsible for the observed effect. Another possibility is that the risk associated with specific genotypes analyzed in this study may have been obscured by other factors that could not be accounted for in this study such as those influencing the expression and function of the corresponding DNA repair enzymes. However, for these two SNPs, XRCC1-R399Q and XRCC3-T241M, there is reason to believe that they may be at least partially related to overall DNA repair functioning as measured by various in vitro and in vivo assays (32, 33, 51, 52, 60, 61). Other studies have not agreed (62–66), and further studies on the potential functional role of these SNPs in tissue-specific cells are required.

The main concern about our results is the representativeness of the cases and controls. The representativeness of the OFBCR as a population-based registry has been evaluated in two studies (37, 67). The former study by Knight et al. (37) examined characteristics such as age, sex, ethnicity, and FH of breast or ovarian cancer in association with response at different stages of the recruitment process for cases diagnosed in 1996. Results showed that women whose ethnicity was not white and men were less likely to participate compared with white women. Furthermore, the response rate at the FH questionnaire stage was lower than expected, but there was no evidence of systematic differences in response according to age and sex. The second study by Mancuso et al. (67) investigated potential biases of FH and ethnicity at this stage (i.e., FH questionnaire) among individuals diagnosed in 2001. Similarly, their results showed that those who do not respond to the OFBCR mailed FH questionnaire do not have substantially different genetic or FH profiles than those who do respond but are more likely to be white. Therefore, there is no evidence to suggest that cases are nonrepresentative of Caucasians in spite of losses at each stage of the OFBCR. Furthermore, results from the crude analysis of nongenetic variables were in agreement with the published literature, and genotypes are in Hardy-Weinberg equilibrium and similar to other studies in Caucasians. Another concern may be loses due to death, but survivorship for breast cancer is relatively high and the OFBCR has estimated that only 2% of potential cases were lost during various recruitment stages. It should also be noted that nongenetic exposures might be misclassified because of recall bias. Reporting factors, such as adolescent smoking and X-ray exposure, alcohol use, and BMI because there is public knowledge of their role in healthy life-style and disease risk, may be influenced by disease status. However, studies that have investigated differential recall between cases and controls have found minimal bias (68).

This study represents an addition to previous published work on XRCC1-R399Q and XRCC3-T241M and breast cancer. Our findings support the hypothesis that XRCC3-T241M may be related to breast cancer susceptibility and suggest that the effect of the XRCC1-R399Q polymorphism differs by FH of the disease. In comparison with the other two population-based case-control studies of breast cancer by Duell et al. (6) and Kuschel et al. (29), our results are in complete agreement. This study provides further support for the role of SNPs in modifying the effects of other factors such as FH and possibly BMI. We suggest that improving our measurements of relevant exposures to account for interactions so that future studies can better assess gene-exposure effects may be an important goal.

	Acknowledgments

 
We thank the Ontario Familial Breast Cancer Registry of Cancer Care Ontario for support, Ellen Shi for help in data extraction, and Pavel Metalnikov, Sean Wells, and Li Hong for assistance in genotyping.

	Footnotes

 
Grant support: National Cancer Institute (RFA CA-96-003) through a cooperative agreement with Cancer Care Ontario, Canadian Breast Cancer Research Initiative (9181), and Susan G. Komen Breast Cancer Foundation (BCTR0100627).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

² J. C. Figueiredo et al. XRCC1-R399Q and XRCC3-T241M: a systematic review of biological important and role in cancer, manuscript in preparation.

Received 7/ 5/03; revised 10/22/03; accepted 11/21/03.

	References

Top Abstract Introduction Methodology Results Discussion References

 

1. Abdel-Rahman SZ, Soliman AS, Bondy ML, et al. Inheritance of the 194Trp and the 399Gln variant alleles of the DNA repair gene XRCC1 are associated with increased risk of early-onset colorectal carcinoma in Egypt. Cancer Lett, 2000;159:79–86.[CrossRef][Medline]
2. Butkiewicz D, Rusin M, Enewold L, Shields PG, Chorazy M, Harris CC. Genetic polymorphisms in DNA repair genes and risk of lung cancer. Carcinogenesis, 2001;22:593–7.[Abstract/Free Full Text]
3. Chen S, Tang D, Xue K, et al. DNA repair gene XRCC1 and XPD polymorphisms and risk of lung cancer in a Chinese population. Carcinogenesis, 2002;23:1321–5.[Abstract/Free Full Text]
4. David-Beabes GL, London SJ. Genetic polymorphism of XRCC1 and lung cancer risk among African-Americans and Caucasians. Lung Cancer, 2001;34:333–9.[CrossRef][Medline]
5. Duell EJ, Holly EA, Bracci PM, Wiencke JK, Kelsey KT. A population-based study of the Arg399Gln polymorphism in X-ray repair cross-complementing group 1 (XRCC1) and risk of pancreatic adenocarcinoma. Cancer Res, 2002;62:4630–6.[Abstract/Free Full Text]
6. Duell EJ, Millikan RC, Pittman GS, et al. Polymorphisms in the DNA repair gene XRCC1 and breast cancer. Cancer Epidemiol Biomarkers & Prev, 2001;10:217–22.[Abstract/Free Full Text]
7. Kim SU, Park SK, Yoo KY, et al. XRCC1 genetic polymorphism and breast cancer risk. Pharmacogenetics, 2002;12:335–8.[CrossRef][Medline]
8. Divine KK, Gilliland FD, Crowell RE, et al. The XRCC1 399 glutamine allele is a risk factor for adenocarcinoma of the lung. Mutat Res, 2001;461:273–8.[Medline]
9. Park JY, Lee SY, Jeon HS, et al. Polymorphism of the DNA repair gene XRCC1 and risk of primary lung cancer. Cancer Epidemiol Biomarkers & Prev, 2002;11:23–7.[Abstract/Free Full Text]
10. Ratnasinghe D, Yao SX, Tangrea JA, et al. Polymorphisms of the DNA repair gene XRCC1 and lung cancer risk. Cancer Epidemiol Biomarkers & Prev, 2001;10:119–23.[Abstract/Free Full Text]
11. Stern MC, Umbach DM, van Gils CH, Lunn RM, Taylor JA. DNA repair gene XRCC1 polymorphisms, smoking, and bladder cancer risk. Cancer Epidemiol Biomarkers & Prev, 2001;10:125–31.[Abstract/Free Full Text]
12. Matullo G, Guarrera S, Carturan S, et al. DNA repair gene polymorphisms, bulky DNA adducts in white blood cells and bladder cancer in a case-control study. Int J Cancer, 2001;92:562–7.[CrossRef][Medline]
13. Sturgis EM, Castillo EJ, Li L, et al. Polymorphisms of DNA repair gene XRCC1 in squamous cell carcinoma of the head and neck. Carcinogenesis, 1999;20:2125–9.[Abstract/Free Full Text]
14. Olshan AF, Watson MA, Weissler MC, Bell DA. XRCC1 polymorphisms and head and neck cancer. Cancer Lett, 2002;178:181–6.[CrossRef][Medline]
15. Shen H, Xu Y, Qian Y, et al. Polymorphisms of the DNA repair gene XRCC1 and risk of gastric cancer in a Chinese population. Int J Cancer, 2000;88:601–6.[CrossRef][Medline]
16. Lee SG, Kim B, Choi J, Kim C, Lee I, Song K. Genetic polymorphisms of XRCC1 and risk of gastric cancer. Cancer Lett, 2002;187:53–60.[CrossRef][Medline]
17. Lee JM, Lee YC, Yang SY, et al. Genetic polymorphisms of XRCC1 and risk of the esophageal cancer. Int J Cancer, 2001;95:240–6.[CrossRef][Medline]
18. Xing D, Qi J, Miao X, Lu W, Tan W, Lin D. Polymorphisms of DNA repair genes XRCC1 and XPD and their associations with risk of esophageal squamous cell carcinoma in a Chinese population. Int J Cancer, 2002;100:600–5.[CrossRef][Medline]
19. Nelson HH, Kelsey KT, Mott LA, Karagas MR. The XRCC1 Arg399Gln polymorphism, sunburn, and non-melanoma skin cancer: evidence of gene-environment interaction. Cancer Res, 2002;62:152–5.[Abstract/Free Full Text]
20. Winsey SL, Haldar NA, Marsh HP, et al. A variant within the DNA repair gene XRCC3 is associated with the development of melanoma skin cancer. Cancer Res, 2000;60:5612–6.[Abstract/Free Full Text]
21. Smith TR, Miller MS, Lohman K, et al. Polymorphisms of XRCC1 and XRCC3 genes and susceptibility to breast cancer. Cancer Lett, 2003;190:183–90.[CrossRef][Medline]
22. van Gils CH, Bostick RM, Stern MC, Taylor JA. Differences in base excision repair capacity may modulate the effect of dietary antioxidant intake on prostate cancer risk: an example of polymorphisms in the XRCC1 gene. Cancer Epidemiol Biomarkers & Prev, 2002;11:1279–84.[Abstract/Free Full Text]
23. Seedhouse C, Bainton R, Lewis M, Harding A, Russell N, Das-Gupta E. The genotype distribution of the XRCC1 gene indicates a role for base excision repair in the development of therapy-related acute myeloblastic leukemia. Blood, 2002;100:3761–6.[Abstract/Free Full Text]
24. Hsieh LL, Chien HT, Chen IH, et al. The XRCC1 399Gln polymorphism and the frequency of p53 mutations in Taiwanese oral squamous cell carcinomas. Cancer Epidemiol Biomarkers & Prev, 2003;12:439–43.[Abstract/Free Full Text]
25. Zhou W, Liu G, Miller DP, et al. Polymorphisms in the DNA repair genes XRCC1 and ERCC2, smoking, and lung cancer risk. Cancer Epidemiol Biomarkers & Prev, 2003;12:359–65.[Abstract/Free Full Text]
26. Misra RR, Ratnasinghe D, Tangrea JA, et al. Polymorphisms in the DNA repair genes XPD, XRCC1, XRCC3, and APE/ref-1, and the risk of lung cancer among male smokers in Finland. Cancer Lett, 2003;191:171–8.[CrossRef][Medline]
27. David-Beabes GL, Lunn RM, London SJ. No association between the XPD (Lys751G1n) polymorphism or the XRCC3 (Thr241Met) polymorphism and lung cancer risk. Cancer Epidemiol Biomarkers & Prev, 2001;10:911–2.[Free Full Text]
28. Duan Z, Shen H, Lee JE, et al. DNA repair gene XRCC3 241Met variant is not associated with risk of cutaneous malignant melanoma. Cancer Epidemiol Biomarkers & Prev, 2002;11:1142–3.[Free Full Text]
29. Kuschel B, Auranen A, McBride S, et al. Variants in DNA double-strand break repair genes and breast cancer susceptibility. Hum Mol Genet, 2002;11:1399–407.[Abstract/Free Full Text]
30. Stern MC, Umbach DM, Lunn RM, Taylor JA. DNA repair gene XRCC3 codon 241 polymorphism, its interaction with smoking and XRCC1 polymorphisms, and bladder cancer risk. Cancer Epidemiol Biomarkers & Prev, 2002;11:939–43.[Abstract/Free Full Text]
31. Shen H, Sturgis EM, Dahlstrom KR, Zheng Y, Spitz MR, Wei Q. A variant of the DNA repair gene XRCC3 and risk of squamous cell carcinoma of the head and neck: a case-control analysis. Int J Cancer, 2002;99:869–72.[CrossRef][Medline]
32. Lunn RM, Langlois RG, Hsieh LL, Thompson CL, Bell DA. XRCC1 polymorphisms: effects on aflatoxin B1-DNA adducts and glycophorin A variant frequency. Cancer Res, 1999;59:2557–61.[Abstract/Free Full Text]
33. Abdel-Rahman SZ, El-Zein RA. The 399Gln polymorphism in the DNA repair gene XRCC1 modulates the genotoxic response induced in human lymphocytes by the tobacco-specific nitrosamine NNK. Cancer Lett, 2000;159:63–71.[CrossRef][Medline]
34. Jacobsen NR, Andersen Nexo B, Olsen A, et al. No association between the DNA repair gene XRCC3 T241M polymorphism and risk of skin cancer and breast cancer. Cancer Epidemiol Biomarkers & Prev, 2003;12:584–5.[Free Full Text]
35. Holowaty EJ, Marrett LD, Fehringer G. Cancer incidence in Ontario trends and regional variations. Toronto: Ontario Cancer Treatment and Research Foundation; 1995.
36. Sutherland HJ, Lacroix J, Knight J, Andrulis IL, Boyd NF. The Cooperative Familial Registry for Breast Cancer Studies: design and first year recruitment rates in Ontario. J Clin Epidemiol, 2001;54:93–8.[CrossRef][Medline]
37. Knight JA, Sutherland HJ, Glendon G, Boyd NF, Andrulis IL. Characteristics associated with participation at various stages at the Ontario site of the cooperative family registry for breast cancer studies. Ann Epidemiol, 2002;12:27–33.[CrossRef][Medline]
38. Griffin TJ, Smith LM. Single-nucleotide polymorphism analysis by MALDI-TOF mass spectrometry. Trends Biotechnol, 2000;18:77–84.[CrossRef][Medline]
39. Sun X, Ding H, Hung K, Guo B. A new MALDI-TOF based mini-sequencing assay for genotyping of SNPs. Nucleic Acids Res, 2000;28:E68.
40. Pusch W, Kraeuter KO, Froehlich T, Stalgies Y, Kostrzewa M. Genotools SNP manager: a new software for automated high-throughput MALDI-TOF mass spectrometry SNP genotyping. Biotechniques, 2001;30:210–5.[Medline]
41. Rothman KJ, Greenland S. Modern epidemiology. Philadelphia: Lippincott-Raven Publishers; 1998.
42. Pryor WA, Hales BJ, Premovic PI, Church DF. The radicals in cigarette tar: their nature and suggested physiological implications. Science, 1983;220:425–7.[Abstract/Free Full Text]
43. Borish ET, Cosgrove JP, Church DF, Deutsch WA, Pryor WA. Cigarette tar causes single-strand breaks in DNA. Biochem Biophys Res Commun, 1985;133:780–6.[CrossRef][Medline]
44. Brooks PJ. DNA damage, DNA repair, and alcohol toxicity: a review. Alcohol Clin Exp Res, 1997;21:1073–82.[CrossRef][Medline]
45. Wallace SS. Biological consequences of free radical-damaged DNA bases. Free Radic Biol Med, 2002;33:1–14.[CrossRef][Medline]
46. Hu JJ, Smith TR, Miller MS, Lohman K, Case LD. Genetic regulation of ionizing radiation sensitivity and breast cancer risk. Environ Mol Mutagen, 2002;39:208–15.[CrossRef][Medline]
47. Kang DH. Oxidative stress, DNA damage, and breast cancer. AACN Clin Issues, 2002;13:540–9.[Medline]
48. Aronson K. Alcohol: a recently identified risk factor for breast cancer. Can Med Assoc J, 2003;168:1147–8.[Free Full Text]
49. Russo IH. Cigarette smoking and risk of breast cancer in women. Lancet, 2002;360:1033–4.[CrossRef][Medline]
50. Ron E. Ionizing radiation and cancer risk: evidence from epidemiology. Pediatr Radiol, 2002;32:232–7; discussion 242–4.[CrossRef][Medline]
51. Lei YC, Hwang SJ, Chang CC, et al. Effects on sister chromatid exchange frequency of polymorphisms in DNA repair gene XRCC1 in smokers. Mutat Res, 2002;519:93–101.[Medline]
52. Duell EJ, Wiencke JK, Cheng TJ, et al. Polymorphisms in the DNA repair genes XRCC1 and ERCC2 and biomarkers of DNA damage in human blood mononuclear cells. Carcinogenesis, 2000;21:965–71.[Abstract/Free Full Text]
53. Hu JJ, Smith TR, Miller MS, Mohrenweiser HW, Golden A, Case LD. Amino acid substitution variants of APE1 and XRCC1 genes associated with ionizing radiation sensitivity. Carcinogenesis, 2001;22:917–22.[Abstract/Free Full Text]
54. Raji NS, Surekha A, Rao KS. Improved DNA-repair parameters in PHA-stimulated peripheral blood lymphocytes of human subjects with low body mass index. Mech Ageing Dev, 1998;104:133–48.[Medline]
55. Zhou J, Ahn J, Wilson SH, Prives C. A role for p53 in base excision repair. EMBO J, 2001;20:914–23.[CrossRef][Medline]
56. Memisoglu A, Samson L. Contribution of base excision repair, nucleotide excision repair, and DNA recombination to alkylation resistance of the fission yeast Schizosaccharomyces pombe. J Bacteriol, 2000;182:2104–12.[Abstract/Free Full Text]
57. Taylor RM, Moore DJ, Whitehouse J, Johnson P, Caldecott KW. A cell cycle-specific requirement for the XRCC1 BRCT II domain during mammalian DNA strand break repair. Mol Cell Biol, 2000;20:735–40.[Abstract/Free Full Text]
58. Liu N, Lamerdin JE, Tebbs RS, et al. XRCC2 and XRCC3, new human Rad51-family members, promote chromosome stability and protect against DNA cross-links and other damages. Mol Cell, 1998;1:783–93.[CrossRef][Medline]
59. Yanagisawa T, Urade M, Yamamoto Y, Furuyama J. Increased expression of human DNA repair genes, XRCC1, XRCC3 and RAD51, in radioresistant human KB carcinoma cell line N10. Oral Oncol, 1998;34:524–8.[CrossRef][Medline]
60. Matullo G, Palli D, Peluso M, et al. XRCC1, XRCC3, XPD gene polymorphisms, smoking and (32)P-DNA adducts in a sample of healthy subjects. Carcinogenesis, 2001;22:1437–45.[Abstract/Free Full Text]
61. Palli D, Russo A, Masala G, et al. DNA adduct levels and DNA repair polymorphisms in traffic-exposed workers and a general population sample. Int J Cancer, 2001;94:121–7.[CrossRef][Medline]
62. Relton CL, Daniel CP, Fisher A, Chase DS, Burn J, Tawn EJ. Polymorphisms of the DNA repair gene XRCC1 and the frequency of somatic mutations at the glycophorin A locus in newborns. Mutat Res, 2002;502:61–8.[Medline]
63. Pastorelli R, Cerri A, Mezzetti M, Consonni E, Airoldi L. Effect of DNA repair gene polymorphisms on BPDE-DNA adducts in human lymphocytes. Int J Cancer, 2002;100:9–13.[CrossRef][Medline]
64. Qiao YL, Spitz MR, Shen H, et al. Modulation of repair of ultraviolet damage in the host-cell reactivation assay by polymorphic XPC and XPD/ERCC2 genotypes. Carcinogenesis, 2002;23:295–9.[Abstract/Free Full Text]
65. Tuimala J, Szekely G, Gundy S, Hirvonen A, Norppa H. Genetic polymorphisms of DNA repair and xenobiotic-metabolizing enzymes: role in mutagen sensitivity. Carcinogenesis, 2002;23:1003–8.[Abstract/Free Full Text]
66. Araujo FD, Pierce AJ, Stark JM, Jasin M. Variant XRCC3 implicated in cancer is functional in homology-directed repair of double-strand breaks. Oncogene, 2002;21:4176–80.[CrossRef][Medline]
67. Mancuso C, Glendon G, Anson-Cartwright L, Shi EJ, Andrulis IL, Knight J. Ethnicity, but not cancer family history, is related to response to a population based mailed questionnaire. Ann Epidemiol, 2004;14:36–43.
68. Chouinard E, Walter S. Recall bias in case-control studies: an empirical analysis and theoretical framework. J Clin Epidemiol, 1995;48:245–54.[CrossRef][Medline]

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