1 Department of Epidemiology, Roswell Park Cancer Institute, Buffalo, NY
2 Division of Nutritional Sciences, Cornell University, Ithaca, NY
3 Department of Epidemiology, School of Public Health, University of North Carolina, Chapel Hill, NC
4 Department of Environmental Health Sciences, Mailman School of Public Health, Columbia University, New York, NY
5 Department of Community and Preventive Medicine, Mount Sinai School of Medicine, New York, NY
6 Department of Epidemiology, Mailman School of Public Health, Columbia University, New York, NY
7 Division of Cancer Prevention and Population Sciences, Roswell Park Cancer Institute, Buffalo, NY
8 Department of Medicine, College of Physicians and Surgeons, Columbia University, New York, NY
Correspondence to Dr. Christine B. Ambrosone, Department of Epidemiology, Roswell Park Cancer Institute, Elm and Carlton Streets, Buffalo, NY 14263 (e-mail: christine.ambrosone{at}roswellpark.org).
Received for publication March 10, 2005. Accepted for publication June 14, 2005.
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ABSTRACT |
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breast neoplasms; catalase; fruit; oxidative stress; vegetables; vitamins
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INTRODUCTION |
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Oxidative stress clearly has a role in carcinogenesis (4). Reactive oxygen species can cause oxidative damage to biomolecules (e.g., DNA), and multiple antioxidant defenses can neutralize reactive oxygen species (5
8
). Variability in exposure to factors that could affect the levels of reactive oxygen species, through endogenous processes or exogenous routes, will ultimately impact levels of oxidative stress. Oxidative damage has been reported to be higher in women with breast cancer, compared with controls (9
, 10
), and, as reviewed by Ambrosone (11
), could be involved in breast cancer etiology.
The catalase enzyme is an endogenous antioxidant enzyme that neutralizes reactive oxygen species by converting H2O2 into H2O and O2. Together with other antioxidant enzymes, including superoxide dismutase and glutathione peroxidase, catalase is a primary defense against oxidative stress. Acatalasemic mice, with approximately one tenth of the catalase blood and tissue levels of normal mice, are more susceptible to mammary carcinoma than their counterparts with normal levels are (12). A common catalase-262 C
T polymorphism has been identified in the promoter region of the human catalase gene (CAT), and it is plausible that the endogenous variability associated with this polymorphism plays a role in the host response to oxidative stress.
Because of the support for the role of oxidative stress in breast cancer etiology (11) and the importance of catalase in neutralizing reactive oxygen species, it is plausible to hypothesize that CAT polymorphisms (reference single nucleotide polymorphism (rs#) 1001179) may influence breast cancer risk. Because data on the functional effects of the catalase-262 C
T polymorphism are limited, we first evaluated associations between this genotype and catalase activity in red blood cells from a small sample of volunteers. We also evaluated the association between the CAT polymorphism and the risk of breast cancer and assessed potential modifying influences of fruit and vegetable intakes and specific antioxidant supplement use on risk relations in the Long Island Breast Cancer Study Project (LIBCSP).
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MATERIALS AND METHODS |
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Upon receipt of physician and participant consents, 1,508 cases (82.1 percent) and 1,556 controls (62.8 percent) were interviewed in their homes by a trained interviewer. Among case and control respondents who completed the interviewer-administered questionnaire, 98.2 and 97.6 percent self-completed the food frequency questionnaire, and 73.0 and 73.3 percent donated a blood sample (13), respectively. As published previously (13
), the relations between breast cancer risk and traditional risk factors, including lower parity, late age at first birth, little or no breastfeeding, family history of breast cancer, and increasing income and education, were observed. Results were similar when the analyses were restricted to respondents who donated blood (13
) or to those with DNA available for these analyses (data not shown). Case-control status and fruit and vegetable consumption were not predictors of blood donation. Among those for whom DNA was available, 94 percent of cases and 93 percent of controls were Caucasian. The age ranges of cases and controls were 25.198.1 (mean: 58.6) years and 20.395.5 (mean: 56.1) years, respectively.
Measurements
Catalase activity by genotype among 18 volunteers.
Subjects.
Blood samples were obtained from healthy volunteers (n = 18) at Roswell Park Cancer Institute, Buffalo, New York. All participants for the catalase activity study were Caucasian and primarily female (80 percent), ranging in age from 20 to 64 years.
Activity measurement by CAT genotype.
Erythrocytes were separated by centrifugation, and catalase activity was measured using a commercially available kit (Oxis Research, Portland, Oregon). Briefly, 30 µl of diluted erythrocyte lysate were incubated with 10 mM H2O2 at room temperature for exactly 1 minute. An aliquot was added to horseradish peroxidase/chromagen reagent and allowed to develop for 10 minutes. Absorbance was read at 520 nm, and activity units were assigned on the basis of a calibration curve of known amounts of H2O2. Activity was normalized to erythrocyte counts. The CAT genotype was determined by direct sequencing using the Beckman CEQ genetic analysis system (Beckman Coulter, Inc., Fullerton, California).
CAT genotyping among LIBCSP participants.
Genomic DNA was extracted from mononuclear cells in whole blood separated by Ficoll (Sigma Chemical Co., St. Louis, Missouri). Pelleted cells were frozen at 80°C until DNA isolation by standard phenol, and chloroform isoamyl alcohol extraction and RNase treatment were performed (15). Genotyping was performed by BioServe Biotechnologies (Laurel, Maryland) by use of the high-throughput, matrix-assisted, laser desorption/ionization time-of-flight mass spectrometry of Sequenom, Inc. (San Diego, California), as previously described (16
), using the primers 5'-ACGTTGGATGTCTGGCCCAGCAATTGGAGAG-3' and 5'-CGTTGGATGAGGATGCTGATAACCGGGAG-3'. All genotyping results were reviewed manually for quality control. Controls for genotype and two nontemplate controls were included on each plate. In addition, 170 sets of blinded controls (8 percent) were distributed throughout the DNA samples for quality control purposes. Laboratory personnel were blinded to case/control status. CAT genotype data were available for 1,017 cases and 1,071 controls.
Other exposure assessment among LIBCSP participants.
The questionnaire focused on known and suspected risk factors for breast cancer, including reproductive, hormonal, medical, and lifestyle histories. For assessment of diet for the 12 months prior to the interview, 98 percent of participants completed a self-administered, modified National Cancer InstituteBlock food frequency questionnaire, which was validated previously (17). The food frequency questionnaire included questions related to 13 fruits and fruit juices and 16 vegetables (excluding French fries), in addition to questions about supplement use (multiple vitamins and single supplements of vitamins A, E, and C, as well as ß-carotene). Frequency and portion size data were translated to daily nutrient intakes by use of the National Cancer Institute's DietSys, version 3 (18
). Participants with daily energy intakes above or below 3 standard deviations of the log-transformed mean (cases = 9, controls = 15) were dropped from the analyses (19
).
Statistical analysis
Among the 18 volunteers, levels of catalase activity were compared with CAT genotypes by use of one-way analysis of variance and Student's t tests. The measure of observer agreement of genotype between 8 percent of randomly selected duplicates that were included for quality control purposes was assessed using the kappa statistic. Among the 1,008 cases and 1,056 controls from the LIBCSP, unconditional logistic regression (20) was used to calculate odds ratios and corresponding 95 percent confidence intervals for breast cancer, in relation to genotype. Tests for Hardy-Weinberg equilibrium among the controls were conducted by use of observed genotype frequencies and a
2 test with 1 df. Multivariate models were adjusted simultaneously for age at reference date (defined as the date of diagnosis for cases and the date of identification for controls), family history of breast cancer (first-degree relative), and body mass index at reference date. The other variables assessed did not confound the associations of interest. The final multivariate models shown include only the factors that changed the estimated effect by 10 percent or more, which was developed by starting with a full model and then excluding covariates that did not improve the overall fit, as measured by the 2 log-likelihood ratio test (20
). Total caloric intake was included in the multivariate model to control for confounding by total energy intake (21
).
For dietary factors, fruit and vegetable consumption and specific dietary antioxidants were dichotomized into categories of the lowest three quintiles versus the highest two quintiles, on the basis of the distributions in controls of each factor. This categorization was based on previous findings in the LIBCSP of the similarity of the odds ratios in each of those groups (18). Gene-environment interactions were evaluated by joint categories of CAT genotype, fruit and vegetable intake, and dietary antioxidants (vitamin C, vitamin E, or ß-carotene). We evaluated modification of risk relations with genotype by use of dietary sources of antioxidants only and then by dietary antioxidants plus supplement sources. Variables for combined effects were coded using a common referent group (e.g., CAT TC and TT genotypes combined with lower category of dietary intake).
Because there is concern that use of supplements could modify associations among diet, genotypes, and breast cancer risk, we also stratified by supplement use (any of vitamin C, vitamin E, or ß-carotene supplement). To test multiplicative interactions, we included a cross-product term of the ordinal score for each genotype and dietary antioxidant intake in multivariate models. The log-likelihood statistic for models that included a multiplicative interaction term was compared with that for models that did not. Tests for trend were conducted using the continuous values for dietary antioxidant intakes. All analyses were conducted using SAS, version 8.2, software (SAS Institute, Inc., Cary, North Carolina). All statistical tests were two sided.
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RESULTS |
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Associations between CAT genotypes and breast cancer risk among women in the LIBCSP are shown in table 1. After adjustment for possible confounding factors (age, family history, and body mass index), the CC genotype, reflecting higher red blood cell catalase activity, was associated with a 17 percent reduction in breast cancer risk (multivariate odds ratio (OR) = 0.83, 95 percent confidence interval (CI): 0.69, 1.00; age-only adjusted OR = 0.86, 95 percent CI: 0.72, 1.03), compared with having the TT and TC genotypes combined. Estimates associated with TC genotypes did not differ from those for the TT genotype. Based on these data and the similarity in catalase red blood cell activity for those having any T alleles, further analyses were performed by combining TC and TT genotypes as the referent in the LIBCSP data set and contrasting CC genotypes against that group. The relations were similar between pre- and postmenopausal women (for multiplicative interaction: p = 0.89) and, thus, women were combined for all further analysis.
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Risk associations by supplement use in the LIBCSP
Since antioxidant vitamin supplements may modify risk through an oxidative stress mechanism, we also evaluated the effects of supplement use on modifying risk relations. Gaudet et al. (18) previously reported that antioxidant supplements were not associated with risk of breast cancer in the LIBCSP (OR = 0.93, 95 percent CI: 0.78, 1.11). Although there was no effect of supplement use on the relations between CAT genotypes and breast cancer risk, supplement use did modify the associations among risk, CAT genotype, and fruit and vegetable intake. As shown in table 3, inverse associations among CAT genotypes, high fruit and vegetable consumption, and breast cancer risk appeared to be strongest among women who did not use vitamin supplements. Among non-vitamin supplement users, we observed a statistically significant multiplicative interaction (p = 0.02), with the lowest risk observed for women who were high fruit consumers (>10 servings/week) and who had CC genotypes (OR = 0.59, 95 percent CI: 0.38, 0.89). Among supplement users, however, there was no significant multiplicative interaction between fruit consumption and CAT genotype (p = 0.62). Nonetheless, point estimates of risk were consistently lower among women with CC genotypes regardless of supplement use.
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DISCUSSION |
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Although our study is the first to evaluate the CAT polymorphism in relation to cancer risk, it is plausible that the enzyme could play a role in cancer etiology. Malignant lung tumors have significantly decreased catalase activity (24). The phenotyping data reported here verified that the CC genotype was, indeed, associated with significantly higher enzyme activity in red blood cells. Previously, Forsberg et al. (25
) showed that the T allele was associated with greater transcriptional activation in K-562 and HepG2 cell lines, but not in HeLa cell lines. They also found that the T allele was associated with higher catalase protein levels in blood (n = 29). This finding is in contrast to ours, in which the CC genotype was associated with higher enzyme activity in red blood cells. Differences are possibly due to the measurement of protein versus activity in red blood cells, or they reflect a dependence of the enzyme's stability on sample preparation methods. In both studies, the numbers of samples examined were quite small. Larger genotype-phenotype association studies are required before definitive conclusions can be reached. Nonetheless, several other studies support our observation that activity is reduced in carriers of T alleles. Ahsan et al. (22
) showed that arsenic exposure resulted in hyperkeratosis to a much greater extent (fourfold) among those with TT genotypes than among those with CC genotypes. The TT genotype also was associated with higher blood pressure compared with the CC genotype (26
). Our results, showing that the CC genotype was associated with decreased risk, are consistent with these previous findings, and our findings for CAT also support an oxidative stress mechanism in breast cancer etiology.
In the LIBCSP, higher fruit and vegetable consumption was associated with decreased breast cancer risk among postmenopausal women, with weaker associations among premenopausal women (18). In this analysis, when intakes of fruits and vegetables and of specific dietary antioxidants were categorized by low and high consumption, risk reduction appeared greatest among women with CC genotypes who consumed higher amounts of vegetables and, particularly, fruits. These findings and the mechanism indicated are consistent with our earlier findings, that the MPO variant related to reduced generation of reactive oxygen species was associated with reduced breast cancer risk, particularly among women who consumed higher amounts of fruits and vegetables and of other specific dietary antioxidants (16
). Similarly, in the Western New York Diet Study (27
), we found that the increased risk associated with a variant form of the gene for manganese superoxide dismutase (MnSOD), an enzyme-neutralizing reactive oxygen species, was reduced among higher consumers of fruits, vegetables, and dietary antioxidants.
The mechanisms whereby CAT effects may be greatest for higher consumers of fruits are unclear. Fruit contains numerous putative anticarcinogenic substances and other nonnutrient antioxidants, such as terpenes, flavonoids (quercetin), and polyphenols, as well as vitamin C. It is possible that those chemopreventive components in fruits enhance the antioxidant capabilities of catalase, an effect that is not observed with antioxidant vitamin supplements alone. An in vitro study showed that the levels of CAT mRNA expression increased about 30 percent in quercetin-treated hepatoma cells, whereas the expression of other antioxidant enzymes (e.g., manganese superoxide dismutase and glutathione peroxidase) remained unchanged (28). Furthermore, treatment of rats with flavonoids prior to the administration of an iron chelate prevented the reduction of catalase enzyme activity and an increase in oxidative stress markers (29
), indicating that the function of endogenous antioxidant systems may be maximized at high levels of the putative anticarcinogenic substances contained in fruits.
The weaker association between vitamin E and risk reduction may, in part, reflect that most dietary vitamin E is obtained from vegetable oils used in cooking, rather than from the consumption of vegetables (30). Intake of such oils is not estimated well by food frequency questionnaires (31
). In addition, ß-carotene consumption, unlike intakes of vitamins C and E, was associated with risk reduction in participants with either T alleles or the CC genotype. However, the biologic basis for this association is unclear. It is possible that the association is independent of the functions of catalase, implying a mechanism other than antioxidant properties for the putative benefits associated with ß-carotene. It is also possible that the effects of dietary ß-carotene are so strong that they are not impacted by CAT genotypes.
We observed a statistically significant interaction between CAT genotypes and fruit intake only among non-supplement users, although there was a modest risk reduction associated with supplement use overall among women with CC genotypes. Supplement users generally have higher dietary intakes of fruits and vegetables than non-supplement users do, and it is possible that intake from supplements overwhelms dietary intake, so that the latter has little impact on risk reduction. Thus, the small functional effect of the genotype could be overcome by a substantially increased intake of antioxidants. Alternatively, because the greatest risk reduction was observed among non-supplement users with high fruit consumption and CC genotypes, and because the additional antioxidants supplied by supplements did not significantly reduce cancer risk, it is also possible that other putative chemopreventive components in fruits, rather than specific vitamins, could account for the interaction between fruit intake and CAT genotype, as discussed above. This observation emphasizes the importance of dietary fruit and vegetable consumption. This is consistent with findings from the Nurses' Health Study showing stronger inverse associations between fruit and vegetable intakes and cancer among non-vitamin users than among multivitamin users (3). Considering the fact that 46 percent of women in the cohort used vitamin supplements (3
), it may at least in part explain the lack of associations between fruit and vegetable consumption and the risk of breast cancer in that study.
Results from analyses of the LIBCSP data could also be affected by sources of bias that are common to case-control studies (e.g., selection bias or recall bias) (32) or by misclassification bias related to genotyping. However, problems with recalling the details of past exposures would be less likely to affect genotyping status, although diet and other interview data may be susceptible to this bias. Furthermore, the possible nondifferential misclassification bias due to diet and vitamin supplement use likely deflates the estimated odds ratio toward the null and, thus, true odds ratios could be larger than those observed (33
, 34
). Finally, in light of the contradictory data on the functional impact of the variant and the marginally significant odds ratios, the results may also be attributable to chance.
Our findings indicate that consumption of fruits and vegetables modifies endogenous oxidant and antioxidant capabilities and may impact breast cancer risk through gene/diet interactions. It is interesting to note that, although no associations were observed between consumption of fruits and vegetables and breast cancer risk in the Nurses' Health Study, a report evaluating serum antioxidants in that same study showed that carotenoids were inversely associated with breast cancer risk (35).
Fruits and vegetables are rich sources of these and other putative chemopreventive substances that may enhance the effectiveness of endogenous antioxidant enzymes. Although there is support for a role for oxidative stress in breast cancer, the results of epidemiologic studies of fruit and vegetable consumption have been inconsistent (21, 36
38
). Allelic variability in genes that protect from oxidative stress could modify associations between fruits and vegetables and breast cancer risk and explain, in part, inconsistencies in the published literature, although several issues may contribute to the null results, such as dietary measurement error and a short follow-up period in those cohorts (39
, 40
).
In summary, the high-activity CAT CC genotype was associated with a modest reduction in breast cancer risk. More importantly, higher consumption of fruits further decreased the inverse associations between CAT genotype and breast cancer risk. Our data do not support the view that supplements may enhance the inverse associations with high fruit or high fruit and vegetable intakes. We believe that the results could be interpreted to show that foods, rather than vitamins, are likely sources of numerous other risk-reducing properties and should be relied upon, rather than supplements, for health promotion.
To our knowledge, this is the first study to evaluate functional CAT genotypes and breast cancer risk. The study benefits from the large population-based sample with adequate statistical power and in-depth interview assessments. These data provide further support for a link between oxidative stress and breast cancer, and they contribute to a better understanding of the role of fruit intake in breast cancer risk, taking into consideration variability in endogenous antioxidant capabilities. Although the genotype may not be changed, it is encouraging to note that the inverse associations with CAT polymorphisms were observed primarily in women who consumed more fruits, particularly among non-vitamin supplement users. These findings underscore public health recommendations for the consumption of diets rich in fruits as well as vegetables as a means of cancer prevention.
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ACKNOWLEDGMENTS |
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For their valuable contributions to the Long Island Breast Cancer Study Project, the authors thank the following: members of the Long Island Breast Cancer Network; the 31 participating institutions on Long Island and in New York City, New York; their National Institutes of Health collaborators, Dr. Gwen Collman, National Institute of Environmental Health Sciences, and Dr. G. Iris Obrams, formerly of the National Cancer Institute; and members of the External Advisory Committee to the population-based, case-control study: Dr. Leslie Bernstein (Committee Chair), Gerald Akland, Barbara Balaban, Dr. Blake Cady, Dr. Dale Sandler, Dr. Roy Shore, and Dr. Gerald Wogan, as well as other collaborators who assisted with various aspects of the data collection efforts including Gail Garbowski, Dr. Mary S. Wolff, Dr. Steven D. Stellman, Dr. Maureen Hatch, Dr. Geoffrey Kabat, Dr. Jan Beyea, Dr. Bruce Levin, Dr. H. Leon Bradlow, David Camann, Martin Trent, Dr. Ruby Senie, Dr. Carla Maffeo, Pat Montalvan, Dr. Gertrud Berkowitz, Dr. Margaret Kemeny, Dr. Mark Citron, Dr. Freya Schnabel, Dr. Allen Schuss, Dr. Steven Hajdu, and Dr. Vincent Vinceguerra. Finally, the authors thank Dr. James R. Marshall and Dr. Susan E. McCann, Roswell Park Cancer Institute, for their insightful input.
Conflict of interest: none declared.
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References |
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