Low dietary folate intake is associated with several neoplasias, but reports are inconsistent for breast cancer. Additionally, the association of folate with breast cancer estrogen receptor (ER) status is not well established.
To determine if dietary intakes of folate, B-vitamins (B2, B6, B12) and methionine are associated with breast cancer risk and ER status in Hispanic, and non-Hispanic White women in the southwestern US.
Materials and Methods
Primary breast cancer cases (n = 2,325) in the 4-Corners region (Arizona, Colorado, New Mexico and Utah), diagnosed between October 1999 and May 2004, were identified through state cancer registries. Controls (n = 2,525) were frequency-matched by ethnicity and age (±5 years). Dietary intake, physical activity and other exposures were assessed using in-person interviews. Risk was assessed through multivariable and multinomial logistic regression with adjustment for relevant covariates.
While there was no overall association with breast cancer, the highest quartile of folate intake was marginally inversely associated with ER− breast cancer (Odds Ratio (OR) = 0.50, 95%CI 0.25–1.00, p for trend = 0.07). Vitamin B12 intake was inversely associated with breast cancer also (OR = 0.73, 95%CI 0.53–1.00, p for trend = 0.06), particularly for the highest quartile of ER+ breast cancer (OR = 0.67, 95%CI 0.46–0.99, p for trend = 0.06), among NHW women (OR = 0.49, 95%CI 0.29–0.81, p for trend = 0.01) and invasive breast cancer (OR = 0.63; 95%CI: 0.42, 0.93, Ptrend = 0.01). Methionine intake was also inversely associated with ER+ breast cancer (OR for 4th quartile = 0.83, 95%CI 0.66–1.03, p for trend = 0.04), primarily among Hispanic women (OR = 0.71, 95%CI 0.47–1.06, and P for trend = 0.02).
Higher intake of folate is marginally associated with a lower risk for ER− breast cancer, and higher intakes of vitamin B-12 and methionine are marginally associated with a lower risk of ER+ breast cancer.
Citation: Yang D, Baumgartner RN, Slattery ML, Wang C, Giuliano AR, et al. (2013) Dietary Intake of Folate, B-Vitamins and Methionine and Breast Cancer Risk among Hispanic and Non-Hispanic White Women. PLoS ONE 8(2): e54495. doi:10.1371/journal.pone.0054495
Editor: Todd W. Miller, Dartmouth, United States of America
Received: July 26, 2012; Accepted: December 12, 2012; Published: February 11, 2013
Copyright: © 2013 Yang et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This research was supported by the grants from the National Cancer Institute (CA 078682, CA 078762, CA078552, and CA078802). This research also was supported by the Utah Cancer Registry, which is funded by Contract #N01-PC-67000 from the National Cancer Institute, and with additional support from the State of Utah Department of Health. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Dietary folate, methionine, vitamins B6 and B12 participate in one-carbon metabolism, which is essential for DNA methylation, synthesis and repair . Low dietary folate intake has been associated with several neoplasias , , , , , . A meta-analysis of 13 case-control studies  reported a significant, protective summary effect of folate intake on breast cancer risk (odds ratio (OR) = 0.73; 95% confidence interval (CI): 0.64, 0.83). Evidence from cohort studies, however, is neither consistent nor conclusive. Two recent cohort studies reported an inverse association , , and some studies have indicated that the reduced risk may be more apparent in certain populations, e.g. women with high levels of alcohol intake , , ,  or premenopausal Chinese women. . Reported associations with methionine or vitamins B6 and B12 generally have been null .
The majority of women have estrogen receptor (ER) positive tumors and respond to hormone therapy , , , but approximately one-third of women have ER− tumors that are refractory to hormonal treatment and associated with a poor outcome. Hispanic and African American women are more likely to develop ER− tumors , , . Whether folate intake affects ER expression status is not well established. Maruti et al.  reported that long-term, average folate intake had a significant, protective association with ER−, but not ER+, breast cancer; current intake, however, showed no association. Another recent cohort study reported a non-significant trend towards a protective association with ER− breast cancer . Theoretically, the association of ER− status with folate intake and other B vitamins could be due to methylation of the CpG island promoter region for the ER gene  and several studies have detected this association , , .
We investigated the association of dietary intake of folate, B-vitamins (B2, B6, B12), and methionine with breast cancer risk and ER status among Hispanic and non-Hispanic White (NHW) women using data from the 4-Corners Breast Cancer Study (4-CBCS), a multi-centered, population-based case-control study , . Our primary hypothesis was that folate intake is inversely associated with breast cancer risk, specifically the ER− phenotype, and that inverse associations would be present for the other B-vitamins (B2, B6, B12) and methionine. Additionally, we evaluated the potential modification of these associations by menopausal status, ethnicity, and alcohol intake.
Materials and Methods
Participants in the 4-CBCS were women between 25 and 79 years of age residing in Arizona, Colorado, New Mexico and Utah. Subject selection methods, participation rates, data collection, and quality control procedures are described elsewhere , , , . Cases diagnosed with a new primary breast cancer, in situ or invasive disease, with a histological confirmation between 10/1999–05/2004 were ascertained through state cancer registries. All Hispanic and non-reservation American Indian cases were included. A five-year age-matched sample of non-Hispanic white cases was selected randomly on a 1:1 ratio to the distribution of Hispanic/American Indian cases in Arizona and Colorado and at a 4:1 ratio in Utah. In New Mexico, all Hispanic/American Indian and non-Hispanic white cases under age 50 were included with a 1:1 ratio for women over 50 years. Controls <65 were selected randomly from commercial mailing lists (Arizona, Colorado) or driver’s license lists (New Mexico, Utah) and from Center for Medicare Services lists if > = 65 years, during the same time-period as cases, and were frequency-matched to cases by ethnicity and age within five years. The computer program, Generally Useful Ethnic Search System ,  and the Census Spanish Surname List  were used to identify Hispanic women when ethnicity was unknown. Eligibility and ethnicity were confirmed at the time of the screening telephone contact. Contact was made with 71 percent of Hispanic/American Indian women (75% cases; 66% controls) and with 80 percent of non-Hispanic whites (85% cases; 75% controls). Participation rates for cases and controls based on all subjects contacted were 62 percent and 42 percent, respectively . Twenty-four percent of participants were Hispanic/American Indian. All participants signed an informed written consent prior to participation. The study was approved by the Institutional Review Board for Human Subjects Research at each institution.
All participants were asked to complete an in-person interviewer-administered computerized questionnaire in English or Spanish, based on the participant’s preference, blood draw, and anthropometric measurements. Data on demographic characteristics and breast cancer risk factors prior to the referent year (year prior to diagnosis date for cases; selection date for controls) were collected, including reproductive, medical and medication history, height, weight history, diet, physical activity, education, cigarette smoking, and alcohol consumption. There were few American Indian participants (0.85%) and their data were combined with Hispanic women in analyses. Findings based on analyses by genetic admixture supports this combined grouping .
A diet history questionnaire , adapted from the Coronary Artery Risk Development in Young Adults questionnaire  to include the current food supply and ethnic foods commonly consumed in the southwestern United States , was used to collect data for frequency (daily, weekly, monthly), serving amount, type of preparation, usual serving size, and type of fat used for food preparation. Intake of energy and over 120 nutrients was calculated using the Nutrition Data System for Research (Database Version, 4.02_30_ Regents of the University of Minnesota). Folate intake was calculated with and without multivitamin supplementation as well as intake pre- and post-fortification.
Physical activity was measured using a modified version of the Cross Cultural Activity Participation Survey  and expressed as total metabolic equivalent (MET) values for moderate and vigorous activities during the referent year . Body mass index was calculated as weight in kilograms (kg)/height in square meters (m2) for the referent year. Menopausal status was determined by an algorithm based on age (<57 vs. > = 57 years) at referent date and responses to eight questions regarding menstrual status, hormone replacement use, and surgical or medical menopause . The peri-menopausal category which included 561 (12%) women was combined with the pre-menopausal group for analysis. Cigarette smoking status was categorized as never, former, or current smoker. Alcohol consumption for referent year was categorized as low (0 − <10g/day) vs. moderate (> = 10g/day) consumption. Parity was categorized as: nulliparous; 1–2 live births; 3–4 live births; and 5 or more live births. Family history of breast cancer was based on report for first degree relatives. Recent oral contraceptive use was defined as self-reported use within five years prior to referent date. Education was defined as high school or less vs. some college. Data on clinical and tumor characteristics, including ER status, were obtained from cancer registry data.
Separate calculations were made for dietary folate based on pre- and post-fortification, which was initiated in 1998 . Mean intakes of nutrients of vitamins B2, B6, B12, and methionine were also calculated. Cases and controls were compared by ethnicity, as well as the two ethnicities. All the differences were evaluated by least-squares regression analysis of variance, adjusting for age, center and total energy intake. Groups were compared for covariates using t tests for continuous variables and chi-square tests for categorical variables. Unconditional logistic regression models were used to estimate the odds ratios, and 95% confidence intervals for associations between folate, vitamins B2, B6, B12 and methionine with breast cancer risk. Nutrient intakes were log-transformed and adjusted for total energy intake using the residual method , , and then categorized based on the quartile distribution of the residuals in controls, consistent with previous studies , ,  The lowest quartile was the referent category in all models and the order of each category was used as a continuous term to test for linear trend across categories using the Wald statistic to test the resulting coefficient . Analyses were conducted based on diet only, and on total intake (dietary nutrient plus supplement); however, results are provided for only total intake as there were no meaningful differences between the analyses. Although we evaluated both pre and post-fortification, only pre-fortification analyses are reported since relevant exposure occurred prior to the introduction of fortification.
Analyses were based upon two models: (1) folate, vitamins B2, B6, B12 and methionine adjusted for center, age, and ethnicity; and (2) additional adjustment for education, BMI, energy intake/day, fiber intake/day, total weekly MET hours of physical activity, cigarette smoking status, recent alcohol consumption, parity, family history and oral contraceptive use five years prior to referent date. Although the impact of any one covariate was minimal (<15% for the 4th folate quartile), all variables were retained in the final models for consistency with previous studies. Multinomial logistic regression was used to estimate risk by ER tumor status. Effect modification of folate (continuous) by menopausal status, ethnicity, and alcohol consumption was evaluated by comparing models with and without interaction terms using likelihood ratio test . Stratified analyses by ethnicity and menopausal status were also performed. All p values were two-sided. SAS statistical software (version 9.13, SAS Institute, Cary, NC) was used to perform analyses.
All participants signed an informed written consent prior to participation. The study was approved by the following Institutional Review Boards: The Human Research Protections Office of University of New Mexico; University of Utah Institutional Review Board; Human Subjects Research and Institutional Review Board of University of Arizona and Human Research and the Institutional Review Board of University of Colorado.
A total of 2,325 cases (H = 798; NHW = 1,527) and 2,525 controls (H = 924; NHW = 1,601) participated in the study. Of these, 152 subjects with extreme values for BMI (<16 kg/m2 or >50 kg/m2) or caloric intake (<600 kcal/day or >6500 kcal/day) were excluded, leaving a total of 2,262 cases (H = 765; NHW = 1,497) and 2,436 controls (H = 877; NHW = 1,559). ER status was present for 65% of all cases; 17% for women diagnosed with in situ vs. 82% for women with invasive cancer. Analyses based on ER status therefore included a total of 1,480 cases. Hispanic cases were significantly more likely to have ER− tumors than non-Hispanic white cases (27% vs. 20%, p = 0.003). The average age of the participants was 55 (±12) y.
There were statistically significant differences between ethnic groups for all covariates, regardless of case-control status, with the exception of oral contraceptive use (Table 1), many of which have been previously reported , , , , , , , , , , , , . Hispanic women reported more live births, a higher total energy intake, a lower number of MET hours per week, a higher prevalence of overweight and obesity, a lower prevalence of cigarette smoking, and lower levels of alcohol consumption compared to NHW women. Hispanic women were diagnosed more frequently with regional breast cancer compared with NHW women.
Table 1. Characteristics of breast cancer cases and controls, stratified by ethnicity, 4-Corners Breast Cancer Study, 1999–2004.doi:10.1371/journal.pone.0054495.t001
Sixty three percent of participants reported supplement intake during the referent year (71% NHW, 29% H). Intake did not differ by case-control status within each ethnic group (NHW: 47% cases vs. 53% controls; Hispanic: 45% cases vs. 55% controls, P = 0.25). Hispanic and non-Hispanic white women differed significantly for most nutrients (Table 2). Although Hispanic women reported higher dietary folate and vitamin B intakes than non-Hispanic white women, these differences were reversed when supplements were included. There were significant differences between Hispanic cases and controls for B2 and B12, but these differences disappeared with the inclusion of supplement intake. Among non-Hispanic white women, folate intake was significantly higher for cases at only supplemented pre-fortified levels, and intake of vitamins B2, B6 and B12 was higher among controls compared to cases when total intake was considered (Table 2).
Table 2. Mean dietary intake and total intakea of folate, vitamin B2, vitamin B6, vitamin B12 and methionine for cases and controls, stratified by ethnicity, 4-Corners Breast Cancer Study, 1999–2004.doi:10.1371/journal.pone.0054495.t002
Odds ratios for the highest quartile of folate were less than 1.0, although not statistically significant (model 1, OR = 0.84; 95%CI: 0.61, 1.15; model 2, OR = 0.90; 95%CI: 0.64, 1.26) (Table 3). Vitamin B12 intake was associated inversely with breast cancer risk also (model 2, OR = 0.73; 95%CI: 0.53, 1.00). Results for vitamins B2, B6, and methionine were non-significant. No statistically significant interactions were observed between folate and alcohol consumption (P = 0.30), menopausal status (P = 0.30) or ethnicity (P = 0.08). We also analyzed the joint effect of folate by vitamin B12. Each variable was categorized as low (Q1), moderate (Q2–Q3) and high (Q4) based on quartile distributions. The results showed that moderate folate-high vitamin B12 intake (OR = 0.71; 95%CI: 0.54, 0.92) and high folate-high vitamin B12 intake (OR = 0.76; 95%CI: 0.61, 0.93) had significant protective associations with breast cancer risk compared to low folate-low vitamin B12 intake. All other results were non-significant (data not shown).
Table 3. Multivariate-adjusted associations of selected energy-adjusted total nutrients with risk of breast cancer, 4-Corners Breast Cancer Study, 1999–2004.adoi:10.1371/journal.pone.0054495.t003
Total folate intake was marginally inversely associated with ER− breast cancer (OR = 0.50; 95%CI: 0.25, 1.00, Ptrend = 0.07), particularly in post-menopausal women (OR = 0.28; 95%CI: 0.11, 0.71, Ptrend = 0.01), while there was no association with ER+ cancer or in pre-menopausal women (Table 4). The protective effect of folate intake with ER− breast cancer was not modified by stage of breast cancer. There were no ethnic differences in these associations (data not shown). In contrast, the highest quartile of B12 had an inverse association with ER+ tumors (OR = 0.67; 95%CI: 0.46, 0.99, Ptrend = 0.06) (Table 4), particularly in NHW women (OR = 0.49; 95%CI: 0.29, 0.81, Ptrend = 0.01) and among invasive breast cancer women (OR = 0.63; 95%CI: 0.42, 0.93, Ptrend = 0.01) (data not shown). Methionine was also inversely associated with risk for ER+ tumors (OR = 0.83; 95%CI: 0.66, 1.03; Ptrend = 0.04), particularly in Hispanic women (OR = 0.71; 95%CI: 0.47, 1.06, P for trend = 0.02) (data not shown), but not with ER− cancer. The association was not modified by stage of cancer.
Table 4. Multivariate adjusted a,b associations of selected energy-adjusted nutrients with risk of breast cancer estrogen receptor status, 4-Corners Women’s Health Study, 1999–2004.c,ddoi:10.1371/journal.pone.0054495.t004
Because alcohol intake can influence the biological effects of folate and Methionine , we also stratified analyses by low/high alcohol consumption for all women combined and by tumor phenotype (ER−, ER+). A protective association was observed for risk of breast cancer (OR = 0.53; 95%CI: 0.37, 0.73) among women diagnosed with an ER− tumor who reported a low alcohol intake (<10 g/day) and higher folate intake (>893 mcg/day). There was no suggestion of an interaction between folate and alcohol intake among women diagnosed with ER+ tumors.
This case-control study provides weak evidence that dietary folate and vitamin B intake is protective for breast cancer. Several other case-control studies also have reported protective associations , , , but findings from cohort studies are less consistent , , , . We also detected a protective association for vitamin B12, in keeping with two previous case-control studies , . Our results, however, suggest that these associations may differ according to ER phenotype. Thus, the confounding between folate and vitamin B12 intake for total breast cancer risk maybe due to differential effects on ER phenotypes. We also found a protective association of methionine intake for ER+ breast cancer (P for trend = 0.04), but no evidence for associations with vitamins B2 or B6, in keeping with previous studies , .
A few studies to date have examined associations of dietary folate and B-vitamins with breast cancer according to ER status , , , . Our study suggests that folate intake is marginally protective for ER− breast cancer, which is consistent with results for the Nurses’ Health Study  and the VITamin D and OmegA-3 TriaL (VITAL) study . However, the IOWA Women’s Health Study did not find any relationship between folate intake and ER− or ER+ breast cancer . The association of folate with ER− cancer is consistent with the hypothesis that low levels of folate result in global DNA hypomethylation with aberrant methylation of CpG island promotors for the ER gene, resulting in silencing of receptor expression , . The protective associations for B12 and methionine with ER+ breast cancer agree with the hypothesized role of one-carbon metabolism in carcinogenesis but suggest a different pathway . Vitamin B12 and methionine are established enzymatic cofactors in one-carbon metabolism , . Deficiencies in these vitamins dysregulate one-carbon metabolism and impair DNA synthesis and repair, which may increase the risk of carcinogenesis . Taken together, our results suggest that folate deficiency may be more important than B12 or methionine for alteration of DNA methylation, resulting in silencing of ER expression and the manifestation of the ER− breast cancer phenotype. In contrast, deficiency of B12 and methionine may influence the risk for the more common ER+ phenotype by a more general impairment of DNA synthesis and repair (29).
We used pre-fortification values for folate intake in our study because this was the relevant exposure before the introduction of fortification. In more recent studies conducted post-fortification, the protective association of increased folate intake on breast cancer risk may be nullified or even reversed , , . Choumenkovitch et al.  estimated that the 1998 folate fortification increased average folate intake for women in the U.S. by approximately 100 mcg/day. As a result, compared to the recommended dietary allowance of 400 mcg/day of dietary folate equivalents (DFE) for adults , the current folate intake of the U.S. population may be more than adequate to saturate metabolic systems: 665 mcg DFE/day on average for women without supplemental intake and 1,013 mcg DFE/day for women with supplemental intake . DFE’s are commonly used folate intake units calculated from natural folate from food and synthetic folic acid from dietary supplements or fortified foods.  A recent report from the Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial (PLOC) suggests that excess folate intake due to fortification and supplementation may actually increase breast cancer risk in post-menopausal women . Animal studies also provide evidence for an increased risk with excessive intake, with timing and dose of exposure being the key factors . Thus, the timing and dose-effect relationship of folate with breast cancer risk may actually be U-shaped . The levels at which risk decreases or increases remain to be determined, and could be highly variable depending upon diet composition and genetic susceptibility. In our study, mean total folate intake was similar to that reported for the PLOC study, but lower than the levels reported by Sellers et al. ,  and Zhang et al. , . Additionally, the difference between pre- and post-fortification intake for women in our study was smaller than the average increase reported by Choumenkovitch et al. . Women living in the 4-Corners area of the Southwest, particularly Hispanics, appear to have a higher intake of folate from diet, but a lower intake of folic acid from fortification and supplementation, resulting in an overall lower folate status compared with the general US population. It is therefore possible that the protective association of folate on breast cancer is less masked and especially not reversed in our study by folate supplementation and fortification.
The strengths of this study include a large population-based study sample including Hispanic and non-Hispanic white women with complete and extensive data for diet, dietary supplements, and numerous non-dietary confounding factors, collected with rigorous quality-control standards . Inclusion of vitamins B2, B6, and B12 as covariates in the analyses helped to clarify the association between these vitamins in relation to breast cancer risk. Additionally, cases were identified through population-based cancer registries.
Several limitations must be considered. We were unable to account for genetic variants that regulate one-carbon metabolism and that have been shown to be associated with increased breast cancer risk , . Several studies have reported that women with a low folate intake and the MTHFR 677TT genotype are at increased risk of breast cancer , , , although Lewis et al.’s  meta-analysis produced a significant summary estimate for MTHFR677. As in all case-control studies using self-report methods, recall bias is possible. Twenty-four percent of cases with invasive cancer were missing ER status, however, this is not out of keeping with other studies utilizing ER status . Additionally, there was little difference for missing ER status between Hispanic (24.7%) and non-Hispanic white (23.0%) women diagnosed with invasive cancer (P = 0.41), and overall, it is unlikely that missing ER status is associated with folate intake. The participation rate was lower in our study than for some previous studies, increasing the potential for selection bias, although obtaining high response rates in minority populations is a universal problem , . To obtain a better understanding of the potential impact of poor response on study findings, we evaluated several factors and showed comparability for participants and non-participants . Also, Larsson et al.  found no association across studies between response rates and risk estimates for folate and breast cancer in their meta-analysis. Lastly, the sample size was not sufficient to detect weak associations. Nonetheless, our study provides a unique insight into the association of folate and vitamin B intake on breast cancer risk in Hispanic women.
In conclusion, our results support the hypothesis that folate and B-vitamin intake influence breast cancer risk, but that folate intake may be related specifically to risk for the ER− phenotype. These risks may be different than those reported in studies conducted after folate fortification.
Conceived and designed the experiments: KBB AG MM BR TB MS. Performed the experiments: KBB AG MM BR TB. Analyzed the data: DY KBB RB CW. Wrote the paper: DY KBB RB CW.
- 1. Ulrich CM (2007) Folate and cancer prevention: a closer look at a complex picture. Am J Clin Nutr 86: 271–273.
- 2. Curtin K, Slattery ML, Ulrich CM, Bigler J, Levin TR, et al. (2007) Genetic polymorphisms in one-carbon metabolism: associations with CpG island methylator phenotype (CIMP) in colon cancer and the modifying effects of diet. Carcinogenesis 28: 1672–1679.
- 3. Giovannucci E, Stampfer MJ, Colditz GA, Rimm EB, Trichopoulos D, et al. (1993) Folate, methionine, and alcohol intake and risk of colorectal adenoma.[see comment]. Journal of the National Cancer Institute 85: 875–884.
- 4. Koutros S, Zhang Y, Zhu Y, Mayne ST, Zahm SH, et al.. (2008) Nutrients contributing to one-carbon metabolism and risk of non-Hodgkin lymphoma subtypes. Am J Epidemiol 167: 287–294. Epub 2007 Nov 2006.
- 5. Murtaugh MA, Curtin K, Sweeney C, Wolff RK, Holubkov R, et al. (2007) Dietary intake of folate and co-factors in folate metabolism, MTHFR polymorphisms, and reduced rectal cancer. Cancer Causes & Control 18: 153–163.
- 6. Prinz-Langenohl R, Fohr I, Pietrzik K (2001) Beneficial role for folate in the prevention of colorectal and breast cancer. Eur J Nutr 40: 98–105.
- 7. Shen H, Wei Q, Pillow PC, Amos CI, Hong WK, et al. (2003) Dietary folate intake and lung cancer risk in former smokers: a case-control analysis. Cancer Epidemiol Biomarkers Prev 12: 980–986.
- 8. Larsson SC, Giovannucci E, Wolk A (2007) Folate and risk of breast cancer: a meta-analysis. J Natl Cancer Inst 99: 64–76.
- 9. Ericson U, Sonestedt E, Gullberg B, Olsson H, Wirfalt E (2007) High folate intake is associated with lower breast cancer incidence in postmenopausal women in the Malmo Diet and Cancer cohort.[see comment]. Am J Clin Nutr 86: 434–443.
- 10. Maruti SS, Ulrich CM, White E (2009) Folate and one-carbon metabolism nutrients from supplements and diet in relation to breast cancer risk. Am J Clin Nutr 89: 624–633.
- 11. Rohan TE, Jain MG, Howe GR, Miller AB (2000) Dietary folate consumption and breast cancer risk. J Natl Cancer Inst 92: 266–269.
- 12. Negri E, LaVecchia C, Franceschi S (2000) Re: dietary folate consumption and breast cancer risk. J Natl Cancer Inst 92: 1270–1271.
- 13. Levi F, Pasche C, Lucchini F, LaVecchia C (2001) Dietary intake of selected micronutrients and breast cancer risk. Int J Cancer 91: 260–263.
- 14. Zhang S, Hunter DJ, Hankinson SE, Giovannucci EL, Rosner BA, et al. (1999) A prospective study of folate intake and the risk of breast cancer. JAMA 281: 1632–1637.
- 15. Shrubsole MJ, Shu XO, Li HL, Cai H, Yang G, et al. (2011) Dietary B vitamin and methionine intakes and breast cancer risk among Chinese women. Am J Epidemiol 173: 1171–1182.
- 16. Stevens VL, McCullough ML, Sun J, Gapstur SM (2010) Folate and other one-carbon metabolism-related nutrients and risk of postmenopausal breast cancer in the Cancer Prevention Study II Nutrition Cohort. Am J Clin Nutr 91: 1708–1715.
- 17. Elledge RM, Clark GM, Chamness GC, Osborne CK (1994) Tumor biologic factors and breast cancer prognosis among white, Hispanic, and black women in the United States.[comment]. Journal of the National Cancer Institute 86: 705–712.
- 18. Jatoi I, Chen BE, Anderson WF, Rosenberg PS (2007) Breast cancer mortality trends in the United States according to estrogen receptor status and age at diagnosis. Journal of Clinical Oncology 25: 1683–1690.
- 19. Osborne CK (1991) Receptors. In: Harris JR, Hellman S, Henderson IC, Kinne DW, editors. Breast Disease. Philadelphia, PA: JB Lippincott Co. 301–325.
- 20. Stanford JL, Greenberg RS (1989) Breast cancer incidence in young women by estrogen receptor status and race. American Journal of Public Health 79: 71–73.
- 21. Baumgartner KB, Annegers JF, McPherson RS, Frankowski RF, Gilliland FD, et al. (2002) Is alcohol intake associated with breast cancer in Hispanic women? The New Mexico Women’s Health Study. Ethnicity & Disease 12: 460–469.
- 22. Zhu K, Williams SM (1998) Methyl-deficient diets, methylated ER genes and breast cancer: an hypothesized association. Cancer Causes & Control 9: 615–620.
- 23. Sellers TA, Vierkant RA, Cerhan JR, Gapstur SM, Vachon CM, et al. (2002) Interaction of dietary folate intake, alcohol, and risk of hormone receptor-defined breast cancer in a prospective study of postmenopausal women. Cancer Epidemiol Biomarkers Prev 11: 1104–1107.
- 24. Zhang SM, Hankinson SE, Hunter DJ, Giovannucci EL, Colditz GA, et al. (2005) Folate intake and risk of breast cancer characterized by hormone receptor status. Cancer Epidemiol Biomarkers Prev 14: 2004–2008.
- 25. Slattery ML, Baumgartner KB, Byers T, Guiliano A, Sweeney C, et al. (2005) Genetic, anthropometric, and lifestyle factors associated with IGF-1 and IGFBP-3 levels in Hispanic and non-Hispanic white women. Cancer Causes Control 16: 1147–1157.
- 26. Slattery ML, Edwards S, Murtaugh MA, Sweeney C, Herrick J, et al. (2007) Physical activity and breast cancer risk among women in the southwestern United States. Ann Epidemiol 17: 342–353.
- 27. Slattery ML, Sweeney C, Edwards S, Herrick J, Baumgartner K, et al. (2007) Body size, weight change, fat distribution and breast cancer risk in Hispanic and non-Hispanic white women. Breast Cancer Res Treat 102: 85–101.
- 28. Sweeney C, Edwards SL, Baumgartner KB, Herrick JS, Palmer LE, et al. (2007) Recruiting Hispanic women for a population-based study: validity of surname search and characteristics of nonparticipants. Am J Epidemiol 166: 1210–1219.
- 29. Murtaugh MA, Herrick JS, Sweeney C, Baumgartner KB, Guiliano AR, et al. (2007) Diet composition and risk of overweight and obesity in women living in the southwestern United States. J Am Diet Assoc 107: 1311–1321.
- 30. Howard CA, Samet JM, Buechley RW, Schrag SD, Key CR (1983) Survey research in New Mexico Hispanics: some methodological issues. Am J Epidemiol 117: 27–34.
- 31. Buechley RW (1976) Generally Useful Ethnic Search System: GUESS. Albuquerque, New Mexico: Cancer Research and Treatment Center, The University of New Mexico.
- 32. Word DL, Perkins RC (1996) Building a Spanish surname list for the 1990’s- A new approach to an old problem. U.S. Bureau of the Census, Population Division Working Paper No. 13 1–25.
- 33. Sweeney C, Wolff RK, Byers T, Baumgartner KB, Giuliano AR, et al. (2007) Genetic admixture among Hispanics and candidate gene polymorphisms: potential for confounding in a breast cancer study? Cancer Epidemiol Biomarkers Prev 16: 142–150.
- 34. Slattery ML, Caan BJ, Duncan D, Berry TD, Coates A, et al. (1994) A computerized diet history questionnaire for epidemiologic studies. J Am Diet Assoc 94: 761–766.
- 35. Liu K, Slattery M, Jacobs D Jr, Cutter G, McDonald A, et al. (1994) A study of the reliability and comparative validity of the cardia dietary history. Ethn Dis 4: 15–27.
- 36. DuBose KD, Edwards S, Ainsworth BE, Reis JP, Slattery ML (2007) Validation of a historical physical activity questionnaire in middle-aged women. J Phys Act Health 4: 343–355.
- 37. Ainsworth BE, Haskell WL, Whitt MC, IRWIN ML, Swartz AM, et al. (2000) Compendium of physical activities: an update of activity codes and MET intensities. Med Sci Sports Exerc 32: S498–504.
- 38. USFaD (1996) Food standards: amendment of standards of identity for enriched grain products to require addition of folic acid. Final rule. 21 CFR Parts 136, 137, and 139. Fed Regist 61: 8781–8807.
- 39. Willett W, Stampfer M (1986) Total energy intake: implications for epidemiologic analyses. Am J Epidemiol 124: 17–27.
- 40. Willett W (1998) Nutritional epidemiology. New York: Oxford University Press, Inc.
- 41. Moore CE, Murphy MM, Holick MF (2005) Vitamin D intakes by children and adults in the United States differ among ethnic groups. J Nutr 135: 2478–2485.
- 42. Satia-Abouta J, Galanko JA, Martin CF, Potter JD, Ammerman A, et al. (2003) Associations of micronutrients with colon cancer risk in African Americans and whites: results from the North Carolina Colon Cancer Study. Cancer Epidemiol Biomarkers Prev 12: 747–754.
- 43. Jewell NP (2004) Statistics for Epidemiology. Boca Raton: Chapman & Hall/CRC.
- 44. Wang C, Baumgartner RN, Yang D, Slattery ML, Murtaugh MA, et al.. (2008) No evidence of association between breast cancer risk and dietary carotenoids, retinols, vitamin C and tocopherols in Southwestern Hispanic and non-Hispanic White women. Breast Cancer Res Treat.
- 45. Sweeney C, Baumgartner KB, Byers T, Giuliano AR, Herrick JS, et al. (2008) Reproductive history in relation to breast cancer risk among Hispanic and non-Hispanic white women. Cancer Causes Control 19: 391–401.
- 46. Slattery ML, Curtin K, Giuliano AR, Sweeney C, Baumgartner R, et al. (2008) Active and passive smoking, IL6, ESR1, and breast cancer risk. Breast Cancer Res Treat 109: 101–111.
- 47. Slattery ML, Curtin K, Sweeney C, Wolff RK, Baumgartner RN, et al. (2008) Modifying effects of IL-6 polymorphisms on body size-associated breast cancer risk. Obesity (Silver Spring) 16: 339–347.
- 48. Rollison DE, Giuliano AR, Sellers TA, Laronga C, Sweeney C, et al. (2008) Population-based case-control study of diabetes and breast cancer risk in Hispanic and non-Hispanic White women living in US southwestern states. Am J Epidemiol 167: 447–456.
- 49. Risendal B, Hines LM, Sweeney C, Slattery ML, Giuliano AR, et al.. (2008) Family history and age at onset of breast cancer in Hispanic and non-Hispanic white women. Cancer Causes Control.
- 50. Murtaugh MA, Sweeney C, Giuliano AR, Herrick JS, Hines L, et al. (2008) Diet patterns and breast cancer risk in Hispanic and non-Hispanic white women: the Four-Corners Breast Cancer Study. Am J Clin Nutr 87: 978–984.
- 51. Hines LM, Risendal B, Slattery ML, Baumgartner KB, Giuliano AR, et al. (2008) Differences in Estrogen Receptor Subtype According to Family History of Breast Cancer among Hispanic, but not Non-Hispanic White Women. Cancer Epidemiol Biomarkers Prev 17: 2700–2706.
- 52. Slattery ML, Sweeney C, Herrick J, Wolff R, Baumgartner K, et al. (2007) ESR1, AR, body size, and breast cancer risk in Hispanic and non-Hispanic white women living in the Southwestern United States. Breast Cancer Res Treat 105: 327–335.
- 53. Slattery ML, Sweeney C, Wolff R, Herrick J, Baumgartner K, et al. (2007) Genetic variation in IGF1, IGFBP3, IRS1, IRS2 and risk of breast cancer in women living in Southwestern United States. Breast Cancer Res Treat 104: 197–209.
- 54. Slattery ML, Curtin K, Baumgartner R, Sweeney C, Byers T, et al. (2007) IL6, aspirin, nonsteroidal anti-inflammatory drugs, and breast cancer risk in women living in the southwestern United States. Cancer Epidemiol Biomarkers Prev 16: 747–755.
- 55. Giovannucci RE, Ascherio A, Stampfer MJ, Colditz GA, Willett WC (1995) Alcohol, Low-Methionine-Low-Folate Diets, and Risk of Colon Cancer in Men. Journal of the National Cancer Institute 87: 265–273.
- 56. Lajous M, Lazcano-Ponce E, Hernandez-Avila M, Willett W, Romieu I (2006) Folate, vitamin B(6), and vitamin B(12) intake and the risk of breast cancer among Mexican women. Cancer Epidemiol Biomarkers Prev 15: 443–448.
- 57. Chen J, Gammon MD, Chan W, Palomeque C, Wetmur JG, et al. (2005) One-carbon metabolism, MTHFR polymorphisms, and risk of breast cancer. Cancer Res 65: 1606–1614.
- 58. Cho E, Holmes M, Hankinson SE, Willett WC (2007) Nutrients involved in one-carbon metabolism and risk of breast cancer among premenopausal women. Cancer Epidemiology, Biomarkers & Prevention 16: 2787–2790.
- 59. Lajous M, Romieu I, Sabia S, Boutron-Ruault MC, Clavel-Chapelon F (2006) Folate, vitamin B12 and postmenopausal breast cancer in a prospective study of French women. Cancer Causes Control 17: 1209–1213.
- 60. Shrubsole MJ, Jin F, Dai Q, Shu XO, Potter JD, et al.. (2001) Dietary folate intake and breast cancer risk: results from the Shanghai Breast Cancer Study. 7136–7141.
- 61. Lin J, Lee I, Cook NR, Selhub J, Manson JE, et al. (2008) Plasma folate, vitamin B-6, vitamin B-12, and risk of breast cancer in women. Am J Clin Nutr 87: 734–743.
- 62. Selhub J (1999) Homocysteine metabolism. Annu Rev Nutr 19: 217–246.
- 63. Kabat GC, Miller AB, Jain M, Rohan TE (2008) Dietary intake of selected B vitamins in relation to risk of major cancers in women. Br J Cancer 99: 816–821.
- 64. Kim YI (2004) Folate and DNA methylation: a mechanistic link between folate deficiency and colorectal cancer? Cancer Epidemiol Biomarkers Prev 13: 511–519.
- 65. Ulrich CM (2006) Genetic variability in folate-mediated one-carbon metabolism and cancer risk. In: Choi SW, Friso S, editors. Nutrient-Gene Interactions in Cancer. Boca Raton, FL: CRC Press. 75–92.
- 66. Kim YI (2006) Does a high folate intake increase the risk of breast cancer? Nutr Rev 54: 468–475.
- 67. Choumenkovitch SF, Selhub J, Wilson PW, Rader JI, Rosenberg IH, et al. (2002) Folic acid intake from fortification in United States exceeds predictions. J Nutr 132: 2792–2798.
- 68. Institute of Medicine (1998) Dietary Reference Intakes: Thiamin, riboflavin, niacin, vitamin B6, folate, vitamin B12, pantothenic acid, biotin, and choline. Washington, DC: National Academy Press. Section 196, 1.
- 69. Suitor CW, Bailey LB (2000) Dietary folate equivalents: interpretation and application. J Am Diet Assoc 100: 88–94.
- 70. Stolzenberg-Solomon RZ, Chang SC, Leitzmann MF, Johnson KA, Johnson C, et al. (2006) Folate intake, alcohol use, and postmenopausal breast cancer risk in the Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial. Am J Clin Nutr 83: 895–904.
- 71. Dumitrescu RG, Shields PG (2005) The etiology of alcohol-induced breast cancer. Alcohol 35: 213–225.
- 72. Mason JB, Choi S-W (2005) Effects of alcohol on folate metabolism: implications for carcinogenesis. Alcohol 35: 235–241.
- 73. Suzuki T, Matsuo K, Hirose K, Hiraki A, Kawase T, et al. (2008) One-carbon metabolism-related gene polymorphisms and risk of breast cancer. Carcinogenesis 29: 356–362.
- 74. Shrubsole MJ, Gao YT, Cai Q, Shu XO, Dai Q, et al. (2004) MTHFR polymorphisms, dietary folate intake, and breast cancer risk: results from the Shanghai Breast Cancer Study. Cancer Epidemiol Biomarkers Prev 13: 190–196.
- 75. Lewis SJ, Harbord RM, Harris R, Smith GD (2006) Meta-analyses of observational and genetic association studies of folate intakes or levels and breast cancer risk. 1607–1622.
- 76. Althuis MD, Fergenbaum JH, Garcia-Closas M, Brinton LA, Madigan MP, et al. (2004) Etiology of hormone receptor-defined breast cancer: a systematic review of the literature. Cancer Epidemiol Biomarkers Prev 13: 1558–1568.
- 77. Steffen AD, Kolonel LN, Nomura AM, Nagamine FS, Monroe KR, et al. (2008) The effect of multiple mailings on recruitment: the Multiethnic Cohort. Cancer Epidemiol Biomarkers Prev 17: 447–454.
- 78. Rogers A, Murtaugh MA, Edwards S, Slattery ML (2004) Contacting controls: are we working harder for similar response rates, and does it make a difference? Am J Epidemiol 160: 85–90.