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Open Access

Peer-reviewed

Research Article

Association of the DNMT3B -579G>T Polymorphism with Risk of Thymomas in Patients with Myasthenia Gravis

  • Fabio Coppedè ,

    fabio.coppede@med.unipi.it

    Affiliation Department of Translational Research and New Technologies in Medicine and Surgery, University of Pisa, Pisa, Italy

  • Roberta Ricciardi,

    Affiliations Division of Neurology, Department of Neuroscience, University of Pisa, Pisa, Italy, Division of Thoracic Surgery, Cardiac and Thoracic Department, University of Pisa, Pisa, Italy

  • Maria Denaro,

    Affiliation Department of Translational Research and New Technologies in Medicine and Surgery, University of Pisa, Pisa, Italy

  • Anna De Rosa,

    Affiliation Division of Neurology, Department of Neuroscience, University of Pisa, Pisa, Italy

  • Carlo Provenzano,

    Affiliation Institute of General Pathology, Catholic University of Rome, Rome, Italy

  • Emanuela Bartoccioni,

    Affiliation Institute of General Pathology, Catholic University of Rome, Rome, Italy

  • Angelo Baggiani,

    Affiliation Department of Translational Research and New Technologies in Medicine and Surgery, University of Pisa, Pisa, Italy

  • Marco Lucchi,

    Affiliation Division of Thoracic Surgery, Cardiac and Thoracic Department, University of Pisa, Pisa, Italy

  • Alfredo Mussi,

    Affiliation Division of Thoracic Surgery, Cardiac and Thoracic Department, University of Pisa, Pisa, Italy

  • Lucia Migliore

    Affiliation Department of Translational Research and New Technologies in Medicine and Surgery, University of Pisa, Pisa, Italy

Abstract

Increasing evidence suggests a contribution of epigenetic processes in promoting cancer and autoimmunity. Myasthenia gravis (MG) is an autoimmune disease mediated, in approximately 80% of the patients, by antibodies against the nicotinic acetylcholine receptor (AChR+). Moreover, epithelial tumours (thymomas) are present in about 10-20% of the patients, and there is indication that changes in DNA methylation might contribute to the risk and progression of thymomas. However, the role of epigenetics in MG is still not completely clarified. In the present study we investigated if a common polymorphism (-579G>T: rs1569686) in the promoter of the DNMT3B gene coding for the DNA methyltransferase 3B, an enzyme that mediates DNA methylation, increases the risk to develop MG or MG-associated thymomas. The study polymorphism was selected based on recent reports and a literature meta-analysis suggesting association with increased risk of various types of cancer. We screened 324 AChR+ MG patients (140 males and 184 females, mean age 56.0 ± 16.5 years) and 735 healthy matched controls (294 males and 441 females, mean age 57.3 ± 15.6 years). 94 of the total MG patients had a thymoma. While there was no association with the whole cohort of MG patients, we found a statistically significant association of the DNMT3B -579T allele (OR = 1.51; 95% CI=1.1-2.1, P = 0.01) and the TT homozygous genotype (OR = 2.59; 95% CI=1.4-4.9, P = 0.006) with the risk of thymoma. No association was observed in MG patients without thymoma, even after stratification into clinical subtypes. Present results suggest that the DNMT3B -579T allele might contribute to the risk of developing thymoma in MG patients, particularly in homozygous TT subjects.

Citation: Coppedè F, Ricciardi R, Denaro M, De Rosa A, Provenzano C, Bartoccioni E, et al. (2013) Association of the DNMT3B -579G>T Polymorphism with Risk of Thymomas in Patients with Myasthenia Gravis. PLoS ONE 8(11): e80846. https://doi.org/10.1371/journal.pone.0080846

Editor: Lorenzo Chiariotti, Università di Napoli Federico II, Italy

Received: August 2, 2013; Accepted: October 12, 2013; Published: November 19, 2013

Copyright: © 2013 Coppedè 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: Publication costs were covered by "Associazione Italiana Miastenia Onlus". No additional external funding received for this study. 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.

Introduction

Increasing evidence suggests a contribution of epigenetic modifications in complex diseases such as cancer and autoimmune disorders [1-3]. The term epigenetics refers to heritable and reversible modifications that alter gene expression without resulting in direct changes of the primary DNA sequence. Several epigenetic mechanisms are known, including DNA methylation, covalent modifications of histone tails, and nucleosome positioning, all interacting to determine chromatin folding and the relative accessibility of a given genetic locus to activating and suppressing transcription factors [4], and non coding RNAs affecting gene expression levels [5].

DNA methylation represents one of the most studied epigenetic marks for gene regulation; it consists of the addition of a methyl group to the 5’ position of the cytosine pyrimidine ring (5-methylcytosine) mediated by DNA methyltransferase enzymes (DNMTs) using S-adenosylmethionine (SAM) as the methyl donor compound [6]. Methylation of CpG rich regions (CpG islands) in the promoter of a given gene is commonly associated with gene silencing [6]. Most of the studies performed so far in autoimmune diseases have focused on DNA methylation impairments in systemic lupus erythematosus and rheumatoid arthritis [3]. There is however increasing evidence of methylation changes and/or impaired DNMTs activity in other autoimmune disorders such as Sjögren’s syndrome, multiple sclerosis, systemic sclerosis, psoriasis, and autoimmune thyroid diseases [3,7,8].

Myasthenia Gravis (MG) is a prototypic antibody-mediated autoimmune disease. In approximately 80% of the patients the disease is mediated by auto-antibodies against the nicotinic acetylcholine receptor (AChR) [9]. Despite emerging evidence of epigenetic changes in promoting autoimmunity, the role of epigenetics in MG is still scarcely investigated [10]. Moreover, MG is often associated with pathological changes of the thymus: thymic epithelial tumours are present in about 10-20% of MG patients, while up to 80% of the patients with early onset of disease have thymic hyperplasia [11]. Thymoma is an uncommon neoplasm derived from thymus epithelial cells, and studies aimed at analyzing DNA methylation of tumour-related genes showed altered methylation patterns of many of them, including among others MGMT, hMLH1, p16/INK4, and RASSF1A, whose increased methylation significantly correlated with tumour severity [12,13].

The goal of the present study was to investigate if a common polymorphism (-579G>T: rs1569686) in the promoter of the DNMT3B gene coding for the DNA methyltransferase 3B, one of the key de novo enzymes mediating DNA methylation, increases the risk to develop MG or MG-associated thymomas. The selected polymorphism has been suggested to impair DNA methylation of tumor suppressor genes, therefore impairing their expression levels, and for this reason it was investigated as a susceptibility factor for several cancer types [16-21]. A meta-analysis of published studies revealed that the mutant allele (T) is associated with increased risk of cancer compared to the wild type one (G) [22]. Moreover, DNMT3B promoter polymorphisms have been associated with global DNA methylation and are increasingly investigated in other complex diseases than cancer [23-27]. Indeed, clinical studies showed association with wide-spread DNA methylation and suicide attempts in psychiatric patients [23], with increased risk of early-onset schizophrenia [24], with risk of giving birth to a child with Down syndrome [25], as well as with increased risk of the autoimmune disease oral lichen planus [26], and with the progression of joint destruction in rheumatoid arthritis [27].

Materials and Methods

Study population

A total of 324 AChR+ MG patients and 735 healthy matched unrelated controls were recruited at the Myasthenia Clinic (Department of Neuroscience and Cardiac and Thoracic Department) of the Pisa University Hospital, at the Institute of General Pathology of the Catholic University of Rome, and at the Department of Translational Research and New Technologies in Medicine and Surgery of the University of Pisa. Disease diagnosis was based on characteristic signs and symptoms of MG coupled with an anti-AChR antibody positive test; patients with an anti-AChR antibody negative test were excluded from the present study. The main clinical characteristics of MG patients are listed in Table 1. The mean age (±S.D.) of the patients was 56.0 (± 16.5) years. According to disease onset age, patients were divided into early onset (≤45 years) and late onset (>45 years). According to the Osserman classification, they could be divided into pure ocular (class I) and generalized MG (class IIA, IIB, III, IV). MG was associated with different autoimmune disorders (AID) in 51 (15.7 %) out of 324 patients (see Table 1 for details). All patients had computed tomography (CT) scans of the chest and thymectomy was performed in 179 out of 324 patients according to the CT scan findings. Overall 94 patients (29.0%) had a thymoma. Thymic hyperplasia was found in 95 cases (29.3%), and a normal (involuted) thymus in 135 cases (41.7%). The control group includes 735 healthy volunteer subjects with no history of cancer or autoimmune diseases matched for age and gender with the patients (Table 1). All individuals were white Caucasians of Italian descent as determined by grandparents origin; each subject gave an informed written consent for genotype analysis before blood drawing. The study was performed in accordance to the Declaration of Helsinki, and was approved by the Ethics Committees of the Pisa University Hospital and of the Catholic University of Rome.

CharacteristicsMG patients, Total No. = 324Controls, Total No. = 735
Gendera: Females (%) / Males (%)184 (56.8) / 140 (43.2)441 (60.0) / 294 (40.0)
Ageb (years): Mean ± S.D.56.0 ± 16.557.3 ± 15.6
Age at onset (years): ≤ 45 (%) / > 45 (%)170 (52.5) / 154 (47.5)
Antibodies anti-AchR+324 (100%)
Osserman classification: Grade I56 (17.3%)
Osserman classification: Grade IIA78 (24.1%)
Osserman classification: Grade IIB182 (56.2%)
Osserman classification: Grade III3 (0.9%)
Osserman classification: Grade IV5 (1.5%)
Associated autoimmune diseases (AID)c51 (15.8%)
Thymic histology: normal thymus135 (41.7%)
Thymic histology: thymoma94 (29.0 %)
Thymic histology: hyperplasia95 (29.3 %)

Table 1. Demographic characteristics of Myasthenia Gravis patients and Controls.

aGender: no significant difference between MG patients and controls
bAge: no significant difference between MG patients and controls
cAssociated autoimmune diseases (AID): Hashimoto’s thyroiditis: 16 cases; Graves-Basedow disease: 14 cases; Type 1 Diabetes: 7 cases; Others: 14 cases.
CSV
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Genotyping procedures

Genomic DNA was extracted from peripheral blood lymphocytes by means of the QIAamp® Blood Mini Kit (Quiagen, Milan, Italy) according to the manufacturer’s protocol. Genotyping analysis was performed by means of PCR-RFLP techniques following the protocol of Lee et al. [28] with minor modifications [29]. Briefly, a 225 bp product was amplified using 1.25 Units of Taq DNA polymerase (Invitrogen, Milan, Italy), 10 pmol of each primer (forward: 5’-GAG GTC TCA TTA TGC CTA GG-3’ and reverse: 5’-GGG AGC TCA CCT TCT AGA AA-3’), 0.15mM of each dNTPs, 1.5mM MgCl2, and 40 ng of genomic DNA in a total volume of 25µl. PCR conditions were 35 cycles of 30s at 95°C, 45s at 56°C, and 45s at 72°C, preceded by an initial denaturation step of 5 min at 95°C and followed by a final elongation step of 10 min at 72°C. Overnight digestion at 37°C with Pvu II (Fermentas, Milan, Italy) resulted in an undigested 225-bp product for the wild type allele (G), and in 132- and 93-bp products for the mutant allele (T). Digestion products were visualized after electrophoresis on a 2% agarose gel containing ethidium bromide. Samples with previously confirmed wild-type, heterozygous and mutant genotypes [29] have been used as internal quality controls during PCR-RFLP reactions.

Statistical analyses

Differences in mean age and gender between groups were evaluated by means of the Student’s T-test, and Fisher’s exact test, respectively. To verify that genotype frequencies were in Hardy-Weinberg equilibrium in controls we used Chi-square (χ2) analysis. Differences in allele and genotype distributions between groups have been evaluated by means of Fisher’s exact test. Odds ratios (ORs) have been calculated by means of unconditional logistic regression and given with 95% confidence intervals (CIs). All individual values were analyzed with the SPSS 16.0 statistical package for Windows. The statistical power of the study was evaluated by means of the statistical package QUANTO 1.2.4.exe. Given a case-control cohort of at least 300 cases and 700 controls, and a minor allele frequency (MAF) of 31% in Controls, the study had an a priory power of 82% to detect differences in allele frequencies.

Results

Allele and genotype frequencies generated by the DNMT3B -579G>T polymorphism in patients and controls are shown in Tables 2 and 3, respectively . Genotype distributions in controls conformed to Hardy-Weinberg equilibrium (P = 0.18). No difference in allele and genotype frequencies was observed between patients and controls when MG patients were considered as a whole (Tables 2 and 3). After stratification of MG patients into three subgroups according to thymic pathology (normal thymus, thymic hyperplasia and thymoma), the comparison of each of the three subgroups with controls revealed a significant association of the DNMT3B -579T allele with increased thymoma risk (OR = 1.5; 95% CI = 1.1-2.1, P = 0.01). Moreover, the homozygous TT genotype was associated with an increased thymoma risk compared to the homozygous GG one (OR = 2.59; 95% CI = 1.4-4.9, P = 0.0059). Both associations remained significant even after Bonferroni’s correction for multiple comparisons (Tables 2 and 3). Given the number of thymoma cases (94) and controls (735), a post-hoc power analysis revealed that the study had >90% power to detect differences in allele frequencies. No difference in allele or genotype distributions was observed between MG patients with thymic hyperplasia and controls, or between MG patients with normal thymus and controls.

AllelesControls, No. (%)MG (Total), No. (%)MG (Thymomas), No. (%)MG (Hyperplasia), No. (%)MG (Normal Thymus), No. (%)
Allele G1007 (68.5) 426 (65.7)111 (59.0)127 (66.8)188 (69.6)
Allele T463 (31.5) 222 (34.3)77 (41.0)63 (33.2)82 (30.4)
OR (95%CI) T vs G--1.13 (.93-1.4) a1.51 (1.1-2.1) a1.08 (.78-1.5) a0.95(.72-1.3) a
P-value--0.2260.010b0.6790.775

Table 2. DNMT3B -579G>T allele frequencies in Myasthenia Gravis patients and Controls.

aCompared to the control group
bFisher’s exact test P-value = 0.01; Bonferroni’s corrected P-value = 0.04
CSV
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GenotypesControls, No. (%)MG (Total), No. (%)MG (Thymomas), No. (%)MG (Hyperplasia), No. (%)MG (Normal Thymus), No. (%)
GG337 (45.8) 148 (45.7)34 (36.2)46 (48.4)68 (50.4)
GT333 (45.3) 130 (40.1)43 (45.7)35 (36.8)52 (38.5)
TT65 (8.9)46 (14.2)17 (18.1)14 (14.8)15 (11.1)
OR: GT vs. GG --0.89 (.67-1.2) a1.28 (.80-2.1) a0.77 (.48-1.2) a0.77 (.52-1.1) a
OR : TT vs. GG--1.61 (1.1-2.5) a2.59 (1.4-4.9)a,b1.58 (.82-3.0) a1.14 (.62-2.1) a

Table 3. DNMT3B -579G>T genotype frequencies in Myasthenia Gravis patients and Controls.

aOR and (95%CI) compared to the control group
bFisher exact Test P-value = 0.0059; Bonferroni’s corrected P-value = 0.04
CSV
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We also compared allele and genotype frequencies generated by the DNMT3B -579G>T polymorphism in MG patients stratified according to disease age at onset (≤45 years vs. > 45 years), to disease severity (less severe forms: Grade I + IIA vs. more severe forms: Grade IIB + III + IV), or to the presence/absence of associated autoimmune diseases (associated AID vs. no associated AID). No difference in allele and genotype frequencies was observed in young onset vs. late onset MG patients, in less severe vs. more severe MG, or in patients with associated AID with respect to those with no associated AID (data not shown).

Discussion

In order to shed some light on the role of epigenetics in both MG and MG-associated diseases, we analyzed the DNMT3B -579G>T polymorphism in a large population of MG patients of Italian descent. Overall, no association of the studied polymorphism with MG was observed, even after stratification of the patients according to different clinical parameters like age at onset, disease severity according to Osserman classification, or presence/absence of other autoimmune diseases. However, when we stratified MG patients according to thymus pathology, we found a statistically significant association of the T allele with the presence of thymoma, particularly among carriers of the homozygous TT genotype.

Present data are in agreement with a literature meta-analysis suggesting an increased risk of cancer associated with the presence of the DNMT3B -579T allele [22]. That meta-analysis included ten studies performed in Asian populations, and one single study performed in Caucasians. After stratification into ethnic groups, the authors observed association with cancer risk in Asians, likely because almost all the available studies had been performed in that ethnic group [22]. Interestingly, the frequency of the DNMT3B -579G allele in Asians is much lower than that of the DNMT3B -579T one [22]. However, to the best of our knowledge, previous studies have assessed the role of this polymorphism in many different cancers, including those of the gastro-intestinal and respiratory apparatuses, head and neck carcinomas, and nasopharyngeal carcinomas [14-21], but never in thymoma, either alone or associated to MG.

Hirose and coworkers [12] investigated DNA methylation in 26 thymomas and 6 thymic carcinomas to clarify the association between aberrant DNA methylation and the clinico-pathological features of thymic neoplasms. They observed that almost 50% of thymic epithelial tumours showed aberrant methylation, and that the frequency of tumour methylation was correlated with their malignant behaviour. Moreover, also the number of hypermethylated genes increased with increasing malignant behaviour, suggesting that promoter hypermethylation, and the consequent down-regulation of specific tumour suppressor genes, may play an important role in the development of aggressive and invasive thymic epithelial tumours [12]. Their results were in accordance with Chen and coworkers, who found that tumor suppressor genes and DNA repair genes, including hMLH1, RASSF1A, MGMT, p16/INK4, DAPK, FHIT, RAR2, CDH1, and APC, are frequently hypermethylated in thymic epithelial tumours, all found to be methylated in almost 20 to 40% of the cases [13,30]. Several studies reported that DNMTs are upregulated in thoracic neoplasms, and that those cancers are characterized by global DNA hypomethylation and gene specific hypermethylation (reviewed in 30), and an inverse correlation between DNMT3B levels and global DNA methylation was observed in thymic epithelial tumours [13].

The functional role of the DNMT3B -579G>T polymorphism is not yet completely elucidated. Some authors suggest that it can directly impair promoter activity and gene expression levels, and others observed a linkage disequilibrium between rs1569686 and other DNMT3B promoter polymorphisms, namely −149C>T (rs2424913) and -283T>C (rs6058870), which have been functionally associated with promoter activity and gene expression levels [22,25,28,31]. Taken overall, results from those studies coupled with the evidence of an association of the DNMT3B -579G>T polymorphism with various types of cancer, suggest that this polymorphism might either have a functional role on gene expression levels, or be a tag SNP of functional haplotypes [22,28,31]. In this regard, several investigators observed a correlation between DNMT3B promoter polymorphisms, DNMT3B protein levels, and DNA methylation levels, suggesting that the increased risk of cancer observed in carriers of those polymorphisms might be due to impairments of DNA methylation in cancer cells [22,32].

Except the presence of thymoma, no other investigated MG clinical characteristic was associated with this polymorphism in our population. Interestingly, others evaluated the contribution of this polymorphism to the onset and progression of autoimmune thyroid disease, and found no association [33]. The observed lack of association of the study polymorphism with MG risk or age at onset does not exclude that other epigenetic biomarkers might be linked to the disease. Unfortunately, little is still known concerning epigenetic modifications in MG, as the few available studies are focused on DNA methylation in thymoma specimens [30]. Therefore, due to the absence of available genome-wide data, the role of DNA methylation in MG is still to be clarified. By contrast, several studies revealed global or gene specific hypomethylation, impaired activities of enzymes such as DNMTs or methyl CpG binding proteins, histone tail modifications, and/or changes in non coding RNAs, in autoimmune diseases such as systemic lupus erythematosus, rheumatoid arthritis, Sjögren’s syndrome, psoriasis, multiple sclerosis, and systemic sclerosis, among others [3,7,8], suggesting that further studies are needed to elucidate the possible contribution of epigenetics to the pathogenesis of MG.

Conclusions

The thymus plays distinct roles in the pathogenesis of the different AChR+ MG subtypes. Inflammatory, neoplastic and age-related alterations of the thymus are of pivotal relevance for the initiation of anti AChR autoimmunity in early onset MG, thymoma-associated MG and, likely, late onset MG, respectively [34]. At best of our knowledge the present is the first investigation of DNMT3B promoter polymorphisms in MG patients. Our study suggests that the presence of the DNMT3B -579T allele might represent a risk factor for the development of MG-associated thymomas, particularly in carriers of the homozygous TT genotype, while it probably does not have effect on other MG subtypes. Therefore, the analysis of this polymorphism could help to identify those AChR+ MG individuals at increased risk to develop a thymoma.

Acknowledgments

This research was not supported by research grants, and was totally sponsored by the authors. The authors acknowledge all MG patients and control individuals whose participation made possible the present study.

Author Contributions

Conceived and designed the experiments: FC LM. Performed the experiments: FC MD. Analyzed the data: FC MD ADR AB. Contributed reagents/materials/analysis tools: FC RR CP EB ML AM LM. Wrote the manuscript: FC.

References

  1. 1. Ngalamika O, Zhang Y, Yin H, Zhao M, Gershwin ME et al. (2012) Epigenetics, autoimmunity and hematologic malignancies: a comprehensive review. J Autoimmun 39: 451-465. PubMed: 23084980.
  2. 2. Jiang Y, Liu S, Chen X, Cao Y, Tao Y (2013) Genome-wide distribution of DNA methylation and DNA demethylation and related chromatin regulators in cancer. Biochim Biophys Acta 1835: 155-163. PubMed: 23262191.
  3. 3. Quintero-Ronderos P, Montoya-Ortiz G (2012) Epigenetics and Autoimmune Diseases. Autoimm Dis 2012: 593720.
  4. 4. Martín-Subero JI (2011) How epigenomics brings phenotype into being. Pediatr Endocrinol Rev 9: 506-510. PubMed: 22423506.
  5. 5. Esteller M (2011) Non-coding RNAs in human disease. Nat Rev Genet 12: 861–874. doi:https://doi.org/10.1038/ni.2073. PubMed: 22094949.
  6. 6. Jones PA (2012) Functions of DNA methylation: islands, start sites, gene bodies and beyond. Nat Rev Genet 13: 484–492. doi:https://doi.org/10.1038/nrg3230. PubMed: 22641018.
  7. 7. Meda F, Folci M, Baccarelli A, Selmi C (2011) The epigenetics of autoimmunity. Cell Mol Immunol 8: 226–236. doi:https://doi.org/10.1038/cmi.2010.78. PubMed: 21278766.
  8. 8. Zhang P, Su Y, Lu Q (2012) Epigenetics and psoriasis. J Eur Acad Dermatol Venereol 26: 399–403. doi:https://doi.org/10.1111/j.1468-3083.2011.04261.x. PubMed: 21923658.
  9. 9. Appel SH, Almon RR, Levy N (1975) Acetylcholine receptor antibodies in myasthenia gravis. N Engl J Med 293: 760-761. doi:https://doi.org/10.1056/NEJM197510092931508. PubMed: 1160955.
  10. 10. Renaudineau Y, Youinou P (2011) Epigenetics and autoimmunity, with special emphasis on methylation. Keio J Med 60: 10-16. doi:https://doi.org/10.2302/kjm.60.10. PubMed: 21460598.
  11. 11. Leite MI, Jones M, Ströbel P, Marx A, Gold R et al. (2007) Myasthenia gravis thymus: complement vulnerability of epithelial and myoid cells, complement attack on them, and correlations with autoantibody status. Am J Pathol 171: 893–905. doi:https://doi.org/10.2353/ajpath.2007.070240. PubMed: 17675582.
  12. 12. Hirose Y, Kondo K, Takizawa H, Nagao T, Nakagawa Y et al. (2009) Aberrant methylation of tumour-related genes in thymic epithelial tumours. Lung Cancer 64: 155-159. doi:https://doi.org/10.1016/j.lungcan.2008.07.015. PubMed: 18778870.
  13. 13. Chen C, Yin B, Wei Q, Li D, Hu J et al. (2009) Aberrant DNA methylation in thymic epithelial tumors. Cancer Invest 27: 582-591. doi:https://doi.org/10.1080/07357900802620869. PubMed: 19340654.
  14. 14. Hong YS, Lee HJ, You CH, Roh MS, Kwak JY et al. (2007) DNMT3b 39179GT polymorphism and the risk of adenocarcinoma of the colon in Koreans. Biochem Genet 45: 155–163. doi:https://doi.org/10.1007/s10528-006-9047-9. PubMed: 17318376.
  15. 15. Guo X, Zhang L, Wu M, Wang N, Liu Y et al. (2010) Association of the DNMT3B polymorphism with colorectal adenomatous polyps and adenocarcinoma. Mol Biol Rep 37: 219–225. doi:https://doi.org/10.1007/s11033-009-9626-z. PubMed: 19626461.
  16. 16. Hu J, Fan H, Liu D, Zhang S, Zhang F et al. (2010) DNMT3B promoter polymorphism and risk of gastric cancer. Dig Dis Sci 55: 1011-1016. doi:https://doi.org/10.1007/s10620-009-0831-3. PubMed: 19517237.
  17. 17. Liu H, Jiao Y, Guan Y, Lao Y, Zhao C et al. (2012) The DNMT3B -579 G>T promoter polymorphism and risk of lung cancer. Exp Ther Med 3: 525-529. PubMed: 22969923.
  18. 18. Fan H, Liu DS, Zhang SH, Hu JB, Zhang F et al. (2008) DNMT3B 579 G>T promoter polymorphism and risk of esophagus carcinoma in Chinese. World J Gastroenterol 14: 2230–2234. doi:https://doi.org/10.3748/wjg.14.2230. PubMed: 18407600.
  19. 19. Chen MF, Lu MS, Lin PY, Chen PT, Chen WC et al. (2012) The role of DNA methyltransferase 3b in esophageal squamous cell carcinoma. Cancer 118: 4074-4089. doi:https://doi.org/10.1002/cncr.26736. PubMed: 22213175.
  20. 20. Liu Z, Wang L, Wang LE, Sturgis EM, Wei Q (2008) Polymorphisms of the DNMT3B gene and risk of squamous cell carcinoma of the head and neck: a case-control study. Cancer Lett 268: 158-165. doi:https://doi.org/10.1016/j.canlet.2008.03.034. PubMed: 18455294.
  21. 21. Chang KP, Hao SP, Tsang NM, Chang YL, Cheng MH et al. (2008) Gene expression and promoter polymorphisms of DNA methyltransferase 3B in nasopharyngeal carcinomas in Taiwanese people: a case–control study. Oncol Rep 19: 217–222. PubMed: 18097598.
  22. 22. Zhu S, Zhang H, Tang Y, Liu P, Wang J (2012) DNMT3B polymorphisms and cancer risk: a meta analysis of 24 case-control studies. Mol Biol Rep 39: 4429-4437. doi:https://doi.org/10.1007/s11033-011-1231-2. PubMed: 21938431.
  23. 23. Murphy TM, Mullins N, Ryan M, Foster T, Kelly C et al. (2013) Genetic variation in DNMT3B and increased global DNA methylation is associated with suicide attempts in psychiatric patients. Genes Brain Behav 12: 125-132. doi:https://doi.org/10.1111/j.1601-183X.2012.00865.x. PubMed: 23025623.
  24. 24. Zhang C, Fang Y, Xie B, Du YS, Cheng WH et al. (2010) Association of DNA methyltransferase 3B gene polymorphism with early-onset schizophrenia. Zhonghua Yi Xue Yi Chuan Xue Za Zhi 27: 697-699. PubMed: 21154337.
  25. 25. Coppedè F, Bosco P, Tannorella P, Romano C, Antonucci I et al. (2013) DNMT3B promoter polymorphisms and maternal risk of birth of a child with Down syndrome. Hum Reprod 28: 545–550. doi:https://doi.org/10.1093/humrep/des376. PubMed: 23081874.
  26. 26. Fonseca-Silva T, Oliveira MV, Fraga CA, Farias LC, Gomes EP et al. (2012) DNMT3B (C46359T) polymorphisms and immunoexpression of DNMT3b and DNMT1 proteins in oral lichen planus. Pathobiology 79: 18–23. doi:https://doi.org/10.1159/000330171. PubMed: 22236544.
  27. 27. Nam EJ, Kim KH, Han SW, Cho CM, Lee J et al. (2010) The -283C/T polymorphism of the DNMT3B gene influences the progression of joint destruction in rheumatoid arthritis. Rheumatol Int 30: 1299-12303. doi:https://doi.org/10.1007/s00296-009-1141-y. PubMed: 19777235.
  28. 28. Lee SJ, Jeon HS, Jang JS, Park SH, Lee GY et al. (2005) DNMT3B polymorphisms and risk of primary lung cancer. Carcinogenesis 26: 403-409. PubMed: 15528220.
  29. 29. Coppedè F, Zitarosa MT, Migheli F, Lo Gerfo A, Bagnoli S et al. (2012) DNMT3B promoter polymorphisms and risk of late onset. Journal of Alzheimer'S Disease - Curr Alzheimer Res 9: 550-554.
  30. 30. Chen C, Yin N, Yin B, Lu Q (2011) DNA methylation in thoracic neoplasms. Cancer Lett 301: 7-16. doi:https://doi.org/10.1016/j.canlet.2010.10.017. PubMed: 21087818.
  31. 31. Huidobro C, Fernandez AF, Fraga MF (2013) The role of genetics in the establishment and maintenance of the epigenome. Cell Mol Life Sci 70: 1543-1573. doi:https://doi.org/10.1007/s00018-013-1296-2. PubMed: 23474979.
  32. 32. Bao Q, He B, Pan Y, Tang Z, Zhang Y et al. (2011) Genetic variation in the promoter of DNMT3B is associated with the risk of colorectal cancer. Int J Colorectal Dis 26: 1107-1112. doi:https://doi.org/10.1007/s00384-011-1199-3. PubMed: 21519807.
  33. 33. Arakawa Y, Watanabe M, Inoue N, Sarumaru M, Hidaka Y et al. (2012) Association of polymorphisms in DNMT1, DNMT3A, DNMT3B, MTHFR and MTRR genes with global DNA methylation levels and prognosis of autoimmune thyroid disease. Clin Exp Immunol 170: 194-201. doi:https://doi.org/10.1111/j.1365-2249.2012.04646.x. PubMed: 23039890.
  34. 34. Marx A, Pfister F, Schalke B, Saruhan-Direskeneli G, Melms A et al. (2013) The different roles of the thymus in the pathogenesis of the various myasthenia gravis subtypes. Autoimmun Rev 12: 875-884. doi:https://doi.org/10.1016/j.autrev.2013.03.007. PubMed: 23535159.