Figures
Abstract
Myeloperoxidase (MPO) is a metabolic/oxidative lysosomal enzyme secreted by reactive neutrophils at the sites of inflamed organs and tissues during phagocytosis. MPO has been either directly or indirectly linked to neoplasia, which is a well-established risk factor for many types of cancer. A large number of studies have reported the role of MPO G-463A polymorphism regarding breast-cancer risk. However, the published findings are inconsistent. Therefore, we conducted a meta-analysis to determine more precise estimations for the relationship. Eligible studies were identified by searching several electronic databases for relevant reports published before June 2012. According to the inclusion criteria and exclusion criteria, a total of five eligible studies were included in the pooled analyses. When the five eligible studies concerning MPO G-463A polymorphism were pooled into this meta-analysis, there was no evidence found for a significant association between MPO G-463A polymorphism and breast-cancer risk in any genetic model. We also categorized by ethnicity (Caucasian or Asian) for subgroup analysis; according to this subgroup analysis, we found no significant association between MPO G-463A polymorphism and breast-cancer risk in any genetic model. However, in the stratified analysis for the premenopausal group, women carrying the AA genotype were found to have a significantly reduced risk (ORβ=β0.56, 95% CI 0.34β0.94, pβ=β0.027). Under the recessive model, there was a significant association between MPO G-463A polymorphism and breast-cancer risk (ORβ=β0.57, 95% CI 0.34β0.93, pβ=β0.025). We conclude that MPO-G463A polymorphism might not be a good predictor of breast-cancer risk, though menopausal status modified womenβs risk of developing breast cancer.
Citation: Qin X, Deng Y, Zeng Z-Y, Peng Q-L, Huang X-L, Mo C-J, et al. (2013) Myeloperoxidase Polymorphism, Menopausal Status, and Breast Cancer Risk: An Update Meta-Analysis. PLoS ONE 8(8): e72583. https://doi.org/10.1371/journal.pone.0072583
Editor: Hans A. Kestler, University of Ulm, Germany
Received: July 21, 2012; Accepted: July 11, 2013; Published: August 21, 2013
Copyright: Β© 2013 Qin 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: No current external funding sources for this study.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Breast cancer is the most common type of malignant neoplasm in women worldwide, and its incidence is increasing in both developed and developing countries [1]. Multiple genetic and environmental factors are known to be risk factors for breast cancer. Chemicals with carcinogenic potential, such as polycyclic aromatic hydrocarbons (PAHs) or aromatic amines, are common in the ambient environment, and certain PAHs have been identified as known or suspected human carcinogens [2]. Although genotoxicity occurs following a complex process of metabolic biotransformation, ultimate reactive species will form DNA adducts, which, if not repaired, lead to modifications of the genetic material [3].
Myeloperoxidase (MPO) is a metabolic/oxidative lysosomal enzyme secreted by reactive neutrophils at the sites of inflamed organs and tissues during phagocytosis [4]. MPO has been found in breast secretions as an antimicrobial enzyme, which is involved in DNA adduct formation through the activation of xenobiotics, such as PAHs and aromatic amines. These form chemically reactive oxygen species (ROS) in mammary epithelial cells [5]. A single nucleotide polymorphism (SNP) G-463A (rs2333227) is the most extensively studied polymorphism in MPOs and is located in the promoter region of the MPO gene. MPO A allele carriers are reported to confer lower mRNA expression and transcriptional activation than the 463 G common allele in vitro [6], while the G allele has been associated with increased MPO mRNA and protein levels in human monocyte-macrophages [7], [8]. Dally et al. [9] reported that MPO G-463A (G/A+A/A) genotypes were a protective factor in lung cancer patients; the same results were found for hepatoblastoma patients [10]. However, the GG genotype has been associated with high levels of MPO expression, which is correlated with acute promyelocytic leukemia [11]. These studies indicate that MPO-mediated oxidation exists in a wide variety of cancers, especially those involving chronic inflammation and/or prolonged neutrophil invasion.
Several studies have shown the possible involvement of MPO in the pathogenesis of breast cancer; however, the conclusions are inconsistent. To our knowledge, G-463A is the most extensively studied polymorphism in the MPO gene with respect to breast cancer susceptibility. We therefore undertook a meta-analysis to evaluate the association between MPO G-463A polymorphism and breast cancer risk.
Materials and Methods
Publication search
Eligible studies were identified by means of an electronic search of PubMed, Elsevier ScienceDirect, EMBASE, and EBSCO for relevant reports published before June 2012 with the following search terms: ββmyeloperoxidaseββ or ββMPOββ combined with ββbreast cancer.ββ All eligible studies were examined carefully. Review articles and references cited in the retrieved articles were manually obtained to find additional eligible studies.
Inclusion and exclusion criteria
The following criteria were used for the study selection: the study (1) evaluated the association between MPO G-463A polymorphism and the risk of breast cancer; (2) used a case-control design; (3) included a full-text article; (4) offered the size of the sample and sufficient data (genotype distributions of both cases and controls were available) for estimating an odds ratio (OR) with a 95% confidence interval (CI) or information for helping infer the results in the papers; and (5) used the English language. Exclusion criteria were as follows: the study (1) used only case-group data, (2) included no available genotype frequency, and (3) used overlapping data published by the same first author.
Data extraction
Based on the inclusion and exclusion criteria, the following data were extracted for each study: the first authorβs surname, year of publication, ethnicity of the subjects, enrollment criteria of case and control, genotyping methods, study size, and genotype distribution in cases and controls (GG, GA, and AA genotypes for MPO G-463A polymorphism). Two authors from the present study (Qin and Deng) independently and carefully collected the data. For conflicting evaluation, these two authors carried out discussions until a consensus was reached. If they could not reach a consensus, disagreement was adjusted by a third author (Zeng).
Methodological quality assessment
Three reviewers (Qin, Deng, and Zeng) independently evaluated the quality of selected studies by scoring according to a set of predetermined criteria (Table 1), which were modified from a previous meta-analysis of molecular association studies [12]β[15]. Scores ranged from 0 to 12, with higher scores indicating better quality. Disagreements were resolved by discussion.
Statistical analysis
The strength of association between MPOs and breast cancer risk was measured by ORs with 95% CIs. The pooled ORs were calculated, including (1) the GA genotype versus the GG genotype, (2) the AA genotype versus the GG genotype, (3) GG+GA genotypes versus the AA genotype (the dominant model), and (4) the GG genotype versus GA+AA genotypes (the recessive model). Heterogeneity between and within groups was checked by using the Q statistic. A value of pβ₯0.10 for the Q-test indicated there was no heterogeneity among studies, so the pooled OR estimate from each study was calculated by the fixed-effects model; otherwise, the random-effects model was used [16], [17]. A funnel plot was carried out in order to estimate potential publication bias. Funnel-plot asymmetry was assessed using Eggerβs linear-regression test, a linear-regression approach for measuring funnel-plot asymmetry on the natural logarithmic scale of the OR. In the control populations, HardyβWeinberg equilibrium (HWE) was evaluated using the goodness-of-fit chi-square test. A value of p<0.01 signified a departure from HWE. Sensitivity analysis was performed to evaluate the stability of the results by removing the studies not in HardyβWeinberg equilibrium. All the statistical tests were performed with STATA version 10.0 (Stata Corporation, College Station, TX).
Results
Characteristics of studies
Five eligible studies were included in the pooled analyses (Figure 1) [18]β[22], and their characteristics are summarized in Table 2. We also included one study that investigated the T-764C (rs2243828) polymorphism, given its 100% genotype concordance with G-463A polymorphism in Caucasians (http://snp500cancer.nci.nih.gov). Four clinical treatment studies were excluded [23]β[26]. In two studies [20], [27] that used the same study participants, we selected the most recent study [20]. There were three studies of Caucasian populations [18], [20], [21] and two of Asian populations [19], [22]. Three studies reported the effects of MPO-G463A polymorphism in premenopausal and postmenopausal women [18], [20], [21], and we analyzed the premenopausal and postmenopausal subgroups separately (Table 3).
Meta-analysis
In the five studies of MPO G-463A polymorphism, we identified 2996 cases and 3738 controls. Overall, the results showed no significant association between MPO G-463A polymorphism and breast cancer risk (GA versus GG: ORβ=β0.97, 95% CI 0.87β1.08; AA versus GG: ORβ=β0.87, 95% CI 0.68β1.10; dominant model: ORβ=β0.96, 95% CI 0.87β1.06; recessive model: ORβ=β0.88, 95% CI 0.69β1.11) (Table 4). In the subgroup analysis by ethnicity, we found no significant association in any of the genetic models (Table 4).
The premenopausal (573 cases, 661 controls) and postmenopausal (1925 cases, 2304 controls) groups came from three and two studies, respectively. In the premenopausal group, women carrying the AA genotype were found to have a significantly reduced risk of breast cancer (ORβ=β0.56, 95% CI 0.34β0.94, pβ=β0.027), and we found a significant association between MPO G-463A polymorphism and breast cancer risk with the recessive model (ORβ=β0.57, 95% CI 0.34β0.93, pβ=β0.025) (Table 5, Figure 2). In the postmenopausal group, no significant association was observed in any of the genetic models (Table 6, Figure 3).
Sensitivity analysis
A single study involved in the meta-analysis was deleted each time to reflect the influence of the individual data set to the pooled ORs. The results suggested that no individual study significantly affected the pooled ORs. Sensitivity analysis was performed after excluding HWE-violating studies, and the corresponding pooled ORs were not materially altered, indicating that our results are statistically robust (Figure 4).
Publication bias
Both Beggβs funnel plot and Eggerβs test were performed in order to assess the publication bias of the literature. As shown in Figure 5, Beggβs funnel plots did not reveal any evidence of obvious asymmetry in any of the comparison models in the overall meta-analysis. The results of the Eggerβs test also did not show any evidence of publication bias (Table 7). However, based on the recommendations of the Cochrane Handbook for Systematic Reviews of Interventions (www.cochranehandbook.org), which states that the test for publication bias yields unreliable results when less than 10 studies are included in a meta-analysis, the negative results in our meta-analysis are possibly because the number of publications we assessed were too few to determine statistical significance.
Each point represents a separate study for the indicated association. Log[OR] natural logarithm of odds ratio.
Discussion
MPO is a member of the mammalian heme peroxidase enzyme family and is a key component of the phagocyte oxygen-dependent intracellular microbicidal system, playing an important role in innate immune responses [28]. MPO has been directly and indirectly linked to neoplasia and is involved not only in the production of oxidative hypochlorous acid from H2O2 during infection but also in the metabolic activation of a number of procarcinogens [9], which are known to be risk factors for many types of cancer. Feyler et al. [29] reported that carriers of the G/A genotype with a reduced risk of bladder cancer compared with the subjects with the MPO G/G genotype, (ORβ=β 0.5, 95% CI 0.29β0.88). Hung et al. [30] found that the MPO G-463A homozygous variant was associated with a reduced risk of bladder cancer (ORβ=β0.31, 95% CI 0.12β0.80). The A allele has been show to be associated with a 50% reduced risk of hepatoblastoma (ORβ=β0.51, 95% CI 0.27β0.93), and the G/A or A/A genotype reduced the risk of hepatoblastoma by 56% (ORβ=β0.44, 95% CI 0.21β0.90) [10]. Numerous studies have reported the role of MPO G-463A polymorphism in affecting the risk of breast cancer, but results differ and the genetic linkages have not always been replicated. Hence, we conducted a meta-analysis to explore the association between MPO G-463A polymorphism and breast cancer risk.
Unlike studies that have noted an association between the MPO A/A genotype and a reduced risk of breast cancer, we did not find an association between MPO G-463A polymorphism and breast cancer risk; however, consistent with the findings of Lin et al. [19], we did find a significantly reduced risk (ORβ=β0.56) in premenopausal women carrying the AA genotype. Reynolds et al. [31] showed that the MPO GG genotype is associated with an increased incidence of Alzheimer's disease in females and decreased incidence in males, which could be attributed to the effects of sex hormones on MPO gene expression. In addition, BΓ©kΓ©si documented that intracellular myeloperoxidase activity in neutrophils was lower in postmenopausal women than in premenopausal women [32]. Our meta-analysis findings supported the potential role of estrogen in the regulation of MPO activity.
We have read with great interest the recent meta-analysis reported by Pabalan et al [33]. The data reported by Pabalan et al. [33] regarding the study of Li et al.[20] do not seem in line with the data provided by Li et al [20] in their original publication. The numbers reported by Li et al. [20] under age-adjusted model, in cases and controls, are 477 and 462. While, under fully adjusted model, in cases and controls, are 417 and 403. Interestingly enough, after carefully studying the data presented by Pabalan et al. [33], the numbers in cases and controls, are 894 and 865..In our opinion, it was inappropriate to combinate the results since different models were used and combination resulted in misrepresentation of the original data. Therefore, when we extracted the data from Li et al. [20] for our meta-analysis, we only adopted the data using the fully adjusted model (417 cases and 403 controls) in order to ensure that the ethnicity of the participants was Caucasian. Chu et al. [34] reported in another meta-analysis that there was no association between MPO-G463A polymorphism and breast cancer, regardless of the menopausal status and ethnic background. Although our results are not fully accord with previous meta-analysis regarding the positive association for MPO-G463A polymorphism polymorphism, we have made much more powerful and detailed analysis to support our findings, which made our results much more reliable compared with previous meta-analysis: (1) we included more studies; (2) our analysis involved further subgroup analysis stratified according to Asian and Caucasian ethnicity, which contribute to decrease the geographical heterogeneity of the included studies, but the previous meta-analysis did not do; (3) we considered the association between menopausal status and breast cancer which previous meta-analysis also did not do; (4) we were more rigorous than previous meta-analysis in extracting data especially from the study by Li et al..[20],
However, there were also several limitations to our study. First, our meta-analysis had a limited statistical power for subgroup analysis, and the precision of our estimates needs to be assessed in consideration of the small numbers. Our analysis of premenopausal women only included two studies, both of which were of Caucasian women. Clarifying whether ethnicity has a biological influence on cancer susceptibility, therefore, requires more subjects and different ethnicities. Second, as positive associations have a greater chance of publication than true negatives, many studies remain unpublished and were therefore not included in this meta-analysis. Finally, due to a lack of original data, such as age, alcohol consumption, and other factors, we could not perform a more precise calculation of adjusted ORs, which limited our analysis of potential gene-environment interactions.
Conclusions
In summary, our results indicated that MPO-G463A polymorphism might not be a good predictor of breast cancer risk, while menopausal status modifies a womanβs risk of breast cancer. Premenopausal women carrying the AA genotype were found to have a decreased risk of breast cancer. However, given the limited data, more studies are needed to clarify the role of MPO in breast carcinogenesis.
Author Contributions
Conceived and designed the experiments: XQ SL JMZ. Performed the experiments: XQ YD ZYZ. Analyzed the data: QLP XLH. Wrote the paper: YD CJM.
References
- 1. Kamangar F, Dores GM, Anderson WF (2006) Patterns of cancer incidence, mortality, and prevalence across five continents: defining priorities to reduce cancer disparities in different geographic regions of the world. J Clin Oncol 24: 2137β2150.
- 2. Jedrychowski W, Whyatt RM, Camann DE, Bawle UV, Peki K, et al. (2003) Effect of prenatal PAH exposure on birth outcomes and neurocognitive development in a cohort of newborns in Poland. Study design and preliminary ambient data. Int J Occup Med Environ Health 16: 21β29.
- 3. Brockstedt U, Krajinovic M, Richer C, Mathonnet G, Sinnett D, et al. (2002) Analyses of bulky DNA adduct levels in human breast tissue and genetic polymorphisms of cytochromes P450 (CYPs), myeloperoxidase (MPO), quinone oxidoreductase (NQO1), and glutathione S-transferases (GSTs). Mutat Res 516: 41β47.
- 4. Klebanoff SJ (1999) Myeloperoxidase. Proc Assoc Am Physicians 111: 383β389.
- 5. Williams JA, Stone EM, Millar BC, Hewer A, Phillips DH (2000) Pathways of heterocyclic amine activation in the breast: DNA adducts of 2-amino-3-methylimidazo[4,5-f]quinoline (IQ) formed by peroxidases and in human mammary epithelial cells and fibroblasts. Mutagenesis 15: 149β154.
- 6. Piedrafita FJ, Molander RB, Vansant G, Orlova EA, Pfahl M, et al. (1996) An Alu element in the myeloperoxidase promoter contains a composite SP1-thyroid hormone-retinoic acid response element. J Biol Chem 271: 14412β14420.
- 7. Kumar AP, Piedrafita FJ, Reynolds WF (2004) Peroxisome proliferator-activated receptor gamma ligands regulate myeloperoxidase expression in macrophages by an estrogen-dependent mechanism involving the -463GA promoter polymorphism. J Biol Chem 279: 8300β8315.
- 8. Winterbourn CC, Vissers MC, Kettle AJ (2000) Myeloperoxidase. Curr Opin Hematol 7: 53β58.
- 9. Dally H, Gassner K, Jager B, Schmezer P, Spiegelhalder B, et al. (2002) Myeloperoxidase (MPO) genotype and lung cancer histologic types: the MPO -463 A allele is associated with reduced risk for small cell lung cancer in smokers. Int J Cancer 102: 530β535.
- 10. Pakakasama S, Chen TT, Frawley W, Muller C, Douglass EC, et al. (2003) Myeloperoxidase promotor polymorphism and risk of hepatoblastoma. Int J Cancer 106: 205β207.
- 11. Reynolds WF, Chang E, Douer D, Ball ED, Kanda V (1997) An allelic association implicates myeloperoxidase in the etiology of acute promyelocytic leukemia. Blood 90: 2730β2737.
- 12. Thakkinstian A, McEvoy M, Minelli C, Gibson P, Hancox B, et al. (2005) Systematic review and meta-analysis of the association between {beta}2-adrenoceptor polymorphisms and asthma: a HuGE review. Am J Epidemiol 162: 201β211.
- 13. Guo J, Jin M, Zhang M, Chen K (2012) A genetic variant in miR-196a2 increased digestive system cancer risks: a meta-analysis of 15 case-control studies. PLoS One 7: e30585.
- 14. Gao LB, Pan XM, Li LJ, Liang WB, Zhu Y, et al. (2011) RAD51 135G/C polymorphism and breast cancer risk: a meta-analysis from 21 studies. Breast Cancer Res Treat 125: 827β835.
- 15. Camargo MC, Mera R, Correa P, Peek RM Jr, Fontham ET, et al. (2006) Interleukin-1beta and interleukin-1 receptor antagonist gene polymorphisms and gastric cancer: a meta-analysis. Cancer Epidemiol Biomarkers Prev 15: 1674β1687.
- 16. Mantel N, Haenszel W (1959) Statistical aspects of the analysis of data from retrospective studies of disease. J Natl Cancer Inst 22: 719β748.
- 17. DerSimonian R, Laird N (1986) Meta-analysis in clinical trials. Control Clin Trials 7: 177β188.
- 18. Ahn J, Gammon MD, Santella RM, Gaudet MM, Britton JA, et al. (2004) Myeloperoxidase genotype, fruit and vegetable consumption, and breast cancer risk. Cancer Res 64: 7634β7639.
- 19. Lin SC, Chou YC, Wu MH, Wu CC, Lin WY, et al. (2005) Genetic variants of myeloperoxidase and catechol-O-methyltransferase and breast cancer risk. Eur J Cancer Prev 14: 257β261.
- 20. Li Y, Ambrosone CB, McCullough MJ, Ahn J, Stevens VL, et al. (2009) Oxidative stress-related genotypes, fruit and vegetable consumption and breast cancer risk. Carcinogenesis 30: 777β784.
- 21. He C, Tamimi RM, Hankinson SE, Hunter DJ, Han J (2009) A prospective study of genetic polymorphism in MPO, antioxidant status, and breast cancer risk. Breast Cancer Res Treat 113: 585β594.
- 22. Tsai SM, Wu SH, Hou MF, Chen YL, Ma H, et al. (2012) Oxidative stress-related enzyme gene polymorphisms and susceptibility to breast cancer in non-smoking, non-alcohol-consuming Taiwanese women: a case-control study. Ann Clin Biochem 49: 152β158.
- 23. Ambrosone CB, Barlow WE, Reynolds W, Livingston RB, Yeh IT, et al. (2009) Myeloperoxidase genotypes and enhanced efficacy of chemotherapy for early-stage breast cancer in SWOG-8897. J Clin Oncol 27: 4973β4979.
- 24. Ahn J, Ambrosone CB, Kanetsky PA, Tian C, Lehman TA, et al. (2006) Polymorphisms in genes related to oxidative stress (CAT, MnSOD, MPO, and eNOS) and acute toxicities from radiation therapy following lumpectomy for breast cancer. Clin Cancer Res 12: 7063β7070.
- 25. Ambrosone CB, Ahn J, Singh KK, Rezaishiraz H, Furberg H, et al. (2005) Polymorphisms in genes related to oxidative stress (MPO, MnSOD, CAT) and survival after treatment for breast cancer. Cancer Res 65: 1105β1111.
- 26. Bewick MA, Conlon MS, Lafrenie RM (2008) Polymorphisms in manganese superoxide dismutase, myeloperoxidase and glutathione-S-transferase and survival after treatment for metastatic breast cancer. Breast Cancer Res Treat 111: 93β101.
- 27. Yang J, Ambrosone CB, Hong CC, Ahn J, Rodriguez C, et al. (2007) Relationships between polymorphisms in NOS3 and MPO genes, cigarette smoking and risk of post-menopausal breast cancer. Carcinogenesis 28: 1247β1253.
- 28. Klebanoff SJ (1967) Iodination of bacteria: a bactericidal mechanism. J Exp Med 126: 1063β1078.
- 29. Feyler A, Voho A, Bouchardy C, Kuokkanen K, Dayer P, et al. (2002) Point: myeloperoxidase -463G β> a polymorphism and lung cancer risk. Cancer Epidemiol Biomarkers Prev 11: 1550β1554.
- 30. Hung RJ, Boffetta P, Brennan P, Malaveille C, Gelatti U, et al. (2004) Genetic polymorphisms of MPO, COMT, MnSOD, NQO1, interactions with environmental exposures and bladder cancer risk. Carcinogenesis 25: 973β978.
- 31. Reynolds WF, Rhees J, Maciejewski D, Paladino T, Sieburg H, et al. (1999) Myeloperoxidase polymorphism is associated with gender specific risk for Alzheimer's disease. Exp Neurol 155: 31β41.
- 32. Bekesi G, Kakucs R, Varbiro S, Feher J, Pazmany T, et al. (2001) Induced myeloperoxidase activity and related superoxide inhibition during hormone replacement therapy. BJOG 108: 474β481.
- 33. Pabalan N, Jarjanazi H, Sung L, Li H, Ozcelik H (2012) Menopausal status modifies breast cancer risk associated with the myeloperoxidase (MPO) G463A polymorphism in Caucasian women: a meta-analysis. PLoS One 7: e32389.
- 34. Chu H, Wang M, Gu D, Wu D, Zhang Z, et al. (2010) The MPO -463G>A polymorphism and cancer risk: a meta-analysis based on 43 case-control studies. Mutagenesis 25: 389β395.