Hostname: page-component-7bb8b95d7b-dvmhs Total loading time: 0 Render date: 2024-09-11T22:58:50.690Z Has data issue: false hasContentIssue false
  • English
  • Français

Oestrogen replacement therapy reduces total plasma homocysteine and enhances genomic DNA methylation in postmenopausal women

Published online by Cambridge University Press:  09 March 2007

Simonetta Friso ,
Stefania Lamon-Fava ,
Hyeran Jang ,
Ernst J. Schaefer ,
Roberto Corrocher  and
Sang-Woon Choi
Simonetta Friso*
Affiliation:
Department of Clinical and Experimental Medicine, University of Verona School of Medicine, Policlinico ‘G.B. Rossi’, P.le L.A. Scuro 10, 37134 Verona, Italy
Stefania Lamon-Fava
Affiliation:
Lipid Metabolism Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, Massachusetts, USA
Hyeran Jang
Affiliation:
Vitamins and Carcinogenesis Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, Massachusetts, USA
Ernst J. Schaefer
Affiliation:
Lipid Metabolism Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, Massachusetts, USA
Roberto Corrocher
Affiliation:
Department of Clinical and Experimental Medicine, University of Verona School of Medicine, Policlinico ‘G.B. Rossi’, P.le L.A. Scuro 10, 37134 Verona, Italy
Sang-Woon Choi
Affiliation:
Vitamins and Carcinogenesis Laboratory, Jean Mayer USDA Human Nutrition Research Center on Aging at Tufts University, Boston, Massachusetts, USA
*
*Corresponding author: Dr Simonetta Friso, fax +39 045 580111, email simonetta.friso@univr.it
Rights & Permissions [Opens in a new window]

Abstract

Although oestrogen replacement therapy (ERT), which can affect the risk of major cancers, has been known to reduce total plasma homocysteine concentrations in postmenopausal women, the mechanisms and subsequent molecular changes have not yet been defined. To investigate the effect of ERT on homocysteine metabolism, thirteen healthy postmenopausal women were enrolled in a double-blind, placebo-controlled, randomized, cross-over study consisting of two 8-week long phases, placebo and conjugated equine oestrogen (CEE; 0·625 mg/d). Concentrations of total plasma homocysteine, vitamin B6 and serum folate and vitamin B12 were measured by conventional methods. Genomic DNA methylation was measured by a new liquid chromatography/MS method and promoter methylation status of the oestrogen receptor (ER)α, ERβ and p16 genes was analysed by methylation-specific PCR after bisulfite treatment. The CEE phase demonstrated a significantly decreased mean of total plasma homocysteine concentrations compared with the placebo phase (8·08 μmol/l (6·82–9·39) v. 9·29 (7·53–11·35), P < 0·05) but there was no difference in the blood concentrations of the three B vitamins. The CEE phase also showed a significantly increased genomic DNA methylation in peripheral mononuclear cells compared with the placebo phase (2·85 (SD 0·12) ng methylcytosine/μg DNA v. 2·40 ± (SD 0·15) P < 0·05). However, there was no difference in promoter methylation in the ERα, ERβ and p16 genes. This study demonstrates that decreased homocysteinaemia by CEE therapy parallels with increased genomic DNA methylation, suggesting a potential new candidate mechanism by which ERT affects the risk of cancers and a possible new candidate biomarker for the oestrogen-related carcinogenesis through folate-related one-carbon metabolism.

Keywords

Oestrogen replacement therapyDNA methylationHomocysteineCancer riskFolateVitamin B12Vitamin B6
Type
Full Papers
Information
British Journal of Nutrition , Volume 97 , Issue 4 , April 2007 , pp. 617 - 621
Copyright
Copyright © The Authors 2007

Oestrogen hormones have been regarded as major players in carcinogenesis and, particularly, oestrogen replacement therapy (ERT) has been considered to affect, through various mechanisms, the risk of cancers originated from breast, ovary, endometrium and colon (Beral et al. Reference Beral, Banks and Reeves2002). To date, however, the precise mechanism(s) by which oestrogen affects carcinogenesis remains unclear.

The Third National Health and Nutrition Examination Survey (Morris et al. Reference Morris, Jacques, Selhub and Rosenberg2000) suggested that higher oestrogen status is associated with decreased serum total homocysteine (tHcy) concentration and a series of trials evaluating the effect of oestrogen have subsequently demonstrated that oestrogen can reduce tHcy in postmenopausal women (Tutuncu et al. Reference Tutuncu, Ergur, Mungen, Gun, Ertekin and Yergok2005). Since Wu & Wu (Reference Wu and Wu2002) proposed that elevated tHcy can be a risk factor for cancer as well as an important tumour marker, it is, however, not clear what role the oestrogen-related decrease in tHcy plays in the risk of disease.

DNA methylation is a major epigenetic mechanism of DNA known to be modulated by nutrients involved in the folate-mediated pathway (Choi & Friso, Reference Choi, Friso, Friso and Choi2006; Ulrich, Reference Ulrich, Friso and Choi2006). Therefore, we ought to investigate a potential mechanism by which oestrogen may reduce tHcy, in view of the evidence that this lowering effect on tHcy is similar to that observed by supplementation with folic acid and/or other B-vitamins, which are regarded as putative chemopreventive agents (Kim, Reference Kim2003; Biasco & Di Marco, Reference Biasco and Di Marco2005; Kane, Reference Kane2005). We also investigated the subsequent molecular effects of reduced tHcy induced by ERT, considering that a reduction of tHcy affects DNA methylation, which is a well-described mechanism for carcinogenesis, and tHcy concentration reflects the coordinate regulation of one-carbon metabolism (Selhub & Miller, Reference Selhub and Miller1992), which has two critical pathways for carcinogenesis, DNA methylation and nucleotide synthesis (Choi & Mason, Reference Choi and Mason2000).

In the present study we evaluate the effect of ERT on one-carbon metabolism biomarkers, including DNA methylation, in order to establish a potential candidate mechanism by which ERT exerts its role in carcinogenesis.

Experimental methods

Study subjects

The study protocol was approved by the Institutional Review Board of Tufts-New England Medical Center, Boston, MA, USA. Study candidates provided written informed consent and underwent a screening visit consisting of an interview including past and present medical history, physical examination, registration of vital signs, electrocardiogram and laboratory tests. Postmenopausal status was determined as absence of menstrual periods for more than 1 year. Exclusion criteria were a positive history of CHD and/or thromboembolism, liver or kidney disease, diabetes mellitus, thyroid dysfunction, history of cancer of the breast, uterus or cervix. In addition, women who smoked or drank more than two alcoholic drinks per week were excluded from the study. Subjects were also instructed to stop their daily regimen of multivitamins and nutritional supplements, where applicable. Women who had previously been on an ERT regimen were asked to stop their treatment for at least 3 months before entering into the study.

The present study was designed as a placebo-controlled, double-blind, randomized, cross-over study consisting of two different phases, placebo and conjugated equine oestrogen (CEE; 0·625 mg/d; Lamon-Fava et al. Reference Lamon-Fava, Posfai and Schaefer2003). Oestrogen replacement was provided as oral tablets containing 0·625 mg CEE while placebo consisted of a tablet identical to the active CEE tablet, but without the active compound. The study compliance was assessed by tablet counting at the end of each phase: greater than 80 % compliance was observed in all subjects.

Thirteen healthy postmenopausal women (age 57((sd 6) years; weight 69·9 (sd 12·3 kg)) were enrolled into the study.

Each phase lasted 8 weeks and phases were separated by at least a 4-week wash-out period, which was defined by previous studies as an appropriate time frame for the disappearance of oestrogen-induced biological effects (Koh et al. Reference Koh, Mincemoyer, Bui, Csako, Pucino, Guetta, Waclawiw and Cannon1997). At week 8 of each phase, blood was drawn after a 12-h fast to measure plasma tHcy, plasma pyridoxal-5′-phosphate (the active form of vitamin B6), serum folate and vitamin B12 concentrations. DNA was extracted from peripheral blood mononuclear cells to measure genomic and promoter DNA methylation.

Biochemical analyses

Total plasma homocysteine was determined by HPLC with a fluorometric detection method (Vester & Rasmussen, Reference Vester and Rasmussen1991). Plasma vitamin B6 (as its active form pyridoxal 5′-phosphate) was determined enzymatically using tyrosine decarboxylase (Camp et al. Reference Camp, Chipponi and Faraj1983). Serum folate and vitamin B12 concentrations were determined by a radioassay method using a commercially available kit (Quantaphase II B12/folate radioassay; Bio-Rad, Hercules, CA, USA).

Genomic DNA methylation measurement

Genomic DNA methylation was determined by liquid chromatography/MS (Friso et al. Reference Friso, Choi, Dolnikowski and Selhub2002).

Briefly, 1 μg DNA was hydrolysed by sequential digestion with three enzymes, nuclease P1 (Fisher Scientific, Pittsburgh, PA, USA), phosphodiesterase I (Sigma, St Louis, MO, USA) and alkaline phosphatase (Sigma). The hydrolysed DNA solution was delivered onto the analytical column (Supelco, Bellefonte, PA, USA) in isocratic mode. Electrospray ionization MS was performed in positive ion mode (Agilent, Billerica, MA, USA). Identification of 5-methylcytosine was obtained by MS analysis of chromatographic peaks. The isotopomer, methyl-D3, ring-6-D1 5-methyl-2′-deoxycytidine (Cambridge Isotope Laboratories, Andover, MA, USA), was used as an internal standard allowing the quantification of absolute amounts of the methylated cytosine residues in genomic DNA (ng 5-methylcytosine/μg DNA).

Promoter DNA methylation measurement

Promoter DNA methylation of the oestrogen receptor (ER)α, ERβ and p16 genes was analysed by a methylation specific-PCR technique as described in previous reports (Sasaki et al. Reference Sasaki, Tanaka, Perinchery, Dharia, Kotcherguina, Fujimoto and Dahiya2002).

Statistical analysis

The statistical computations were performed with SPSS statistical software package version 13.0 (SPSS Inc, Chicago, IL, USA). Distribution of variables was assessed for normality. Distributions of continuous variables such as DNA methylation data were expressed as mean values and standard deviations. Logarithmic transformation was performed on all the skewed variables to normalize their distribution. Therefore, geometric means (antilogarithms of the transformed means) are presented for tHcy, folate, vitamin B6 and vitamin B12. All variables were compared between CEE and placebo phases by Student's paired samples t test. All P values were two-tailed, and values of P < 0·05 were considered to indicate statistical significance. All CI were calculated at the 95 % level.

Results

Plasma tHcy concentrations were significantly decreased during the CEE phase compared with the placebo phase (P = 0·032, by paired samples Student's t test) (Table 1). Mean tHcy concentration during the placebo phase, 9·29 (7·53–11·35) μmol/l, was within the range considered as normal (Stabler & Allen, Reference Stabler, Allen, Goldman and Ausiello2004) and the CEE treatment reduced the value of tHcy to 8·08 (6·82–9·39) μmol/l. A significantly increased level of genomic DNA methylation in peripheral mononuclear cells was observed after the CEE phase compared with the placebo phase (2·85 (SD 0·12) ng methylcytosine/μg DNA v. 2·40 (SD 0·15), P = 0·042, by paired samples Student's t test) (Fig. 1).

Table 1 Biochemical characteristics of the study group at the end of the placebo and oestrogen replacement therapy phases (Mean values and 95 % CI)

Statistical difference was evaluated by paired samples Student's t test (n 13). Serum folate and vitamin B12 and plasma vitamin B6 and tHcy data are presented as geometric means (antilogarithms of the transformed means) and 95 % CI are reported with two-tailed P values. CEE, conjugated equine oestrogen. For details of subjects and procedures, see p. 618.

Fig. 1 Effects of oestrogen replacement therapy on genomic DNA methylation. A significant difference in genomic DNA methylation of peripheral mononuclear cells is observed between the placebo and conjugated equine oestrogen (CEE) phases; *P = 0·042. Genomic DNA methylation is represented by an absolute amount of 5-methylcytosine (mCyt) in genomic DNA (ng mCyt/μg DNA). Values are expressed as means and standard deviations. Statistical difference was evaluated by Student's paired samples t test. For details of subjects and procedures, see p. 618.

In spite of changes in genomic DNA methylation, there was no significant difference in the promoter DNA methylation of the ERα, ERβ and p16 genes between the CEE and placebo phases. Serum folic acid, vitamin B12 and plasma vitamin B6 concentrations (Table 1) also showed no significant difference between the two phases.

Discussion

ERT has been observed to be associated with the risk of major cancers (Beral et al. Reference Beral, Banks and Reeves2002). However, past studies have not been able to explain the mechanism(s) that can support such association. Interestingly, most, but not all (Farag et al. Reference Farag, Barshop and Mills2003) studies have demonstrated that ERT reduces plasma tHcy concentrations (Tutuncu et al. Reference Tutuncu, Ergur, Mungen, Gun, Ertekin and Yergok2005). Since B-vitamin status is a major determinant of plasma tHcy, whose levels reflect those of intracellular S-adenosylhomocysteine (SAdoHcy), a compound that can affect cellular DNA methylation (Yi et al. Reference Yi, Melnyk, Pogribna, Pogribny, Hine and James2000), we investigated whether the homocysteine-reducing effect of ERT is related to B-vitamin status and whether reduced tHcy levels induced by ERT affect DNA methylation status, either genomic or gene-specific, both of which are well-described mechanisms for carcinogenesis.

The remethylation pathway in one-carbon metabolism converts homocysteine to methionine using a folate- and vitamin B12- dependent methionine synthase reaction (Selhub & Miller, Reference Selhub and Miller1992). The transsulfuration pathway also condenses homocysteine with serine to form cystathionine in an irreversible reaction catalysed by the vitamin B6-dependent cystathionine-β-synthase reaction. Thus, these three B-vitamins are major determinants of the two main pathways of homocysteine metabolism. In a randomized, double-blind, placebo-controlled study, a 3-month treatment with oestrogen decreased fasting tHcy, accompanied by a decrease in plasma vitamin B6 but not folate and vitamin B12 (Smolders et al. Reference Smolders, de Meer, Kenemans, Jakobs, Kulik and van der Mooren2005). In another randomized placebo-controlled trial, 12-weeks of ERT also induced a 25 % decrease in plasma vitamin B6 but no changes in serum folate and vitamin B12 concentrations (Smolders et al. Reference Smolders, de Meer, Kenemans, Teerlink, Jakobs and van der Mooren2004). In the latter study, fasting tHcy concentration was decreased by 12 % but, interestingly, post-methionine loading tHcy concentration was significantly increased (Smolders et al. Reference Smolders, de Meer, Kenemans, Teerlink, Jakobs and van der Mooren2004). Compared with these two studies, we found a significant decrease in tHcy concentrations and non-significant changes in vitamin B6 during the ERT phase, as compared with the placebo phase. It is possible that a treatment period of 8 weeks, such as that of the present study, is not sufficient to induce vitamin B6 depletion as compared with the 3-months length of the previous studies (Smolders et al. Reference Smolders, de Meer, Kenemans, Teerlink, Jakobs and van der Mooren2004, Reference Smolders, de Meer, Kenemans, Jakobs, Kulik and van der Mooren2005). Dimitrova et al. (Reference Dimitrova, DeGroot, Myers and Kim2002), furthermore, reported that oestrogen increases plasma concentration of glutathione, an end-product of the transsulfuration pathway, by enhancing cysthationine β-synthase activity.

Collectively, from these observations we can speculate that oestrogen enhances the transsulfuration pathway, which needs vitamin B6 as a cofactor. Sustained increase of this pathway activity by ERT might induce vitamin B6 depletion, which can cause a positive post-methionine loading test. In 1962, Finkelstein reported that treatment with oestradiol significantly increased the activities of methionine-activating enzymes (Finkelstein, Reference Finkelstein1962), suggesting an effect of oestrogen on the remethylation pathway. In the present study, however, no changes in serum folate and vitamin B12 were observed, consistent with other previous studies (Smolders et al. Reference Smolders, de Meer, Kenemans, Teerlink, Jakobs and van der Mooren2004, Reference Smolders, de Meer, Kenemans, Jakobs, Kulik and van der Mooren2005).

The regenerated methionine from homocysteine converts to S-adenosylmethionine, which transfers its methyl group to the 5′ position of cytosine for DNA methylation reaction and is converted to SAdoHcy.

DNA methyltransferases bind SAdoHcy with higher affinity than S-adenosylmethionine and they are, therefore, subject to potent product inhibition by SAdoHcy. Under normal conditions, SAdoHcy is hydrolysed by SAdoHcy hydrolase to adenosine and homocysteine. However, this reaction is readily reversible with equilibrium dynamics that favour SAdoHcy synthesis rather than its hydrolysis. Thus, a chronic elevation in plasma homocysteine levels usually has an indirect and negative effect on cellular methylation reactions through a concomitant increase in intracellular SAdoHcy levels (Yi et al. Reference Yi, Melnyk, Pogribna, Pogribny, Hine and James2000). Therefore, we hypothesize that a decreased plasma tHcy concentration induced by oestrogen therapy may diminish, indirectly, the intracellular SAdoHcy concentrations, thereby reducing the inhibitory effect of SAdoHcy on DNA methylation and increasing cellular genomic DNA methylation. To the best of our knowledge, this is the first observation demonstrating that decreased tHcy by ERT increases genomic DNA methylation.

DNA methylation, more specifically the transfer of a methyl group at the carbon-5′ position of cytosine at 5′-CpG-3′ dinucleotides residues, is an epigenetic phenomenon, which is involved in gene expression and genome integrity. While methylation within gene regulatory elements, such as promoters, generally suppresses the gene function, methylation within gene-deficient regions such as pericentromeric heterochromatin maintains the conformation and integrity of the chromosome. Thus, the evaluation of DNA methylation status is important for the study of carcinogenesis (Friso & Choi, Reference Friso and Choi2002). A decreased level of genomic DNA methylation is a nearly universal finding in tumorigenesis and appears early in carcinogenesis and generally precedes the mutation and deletion events that occur later in the evolution of cancer (Goelz et al. Reference Goelz, Vogelstein, Hamilton and Feinberg1985). Although rodent studies have suggested that genomic DNA hypomethylation by itself can induce cancer (Gaudet et al. Reference Gaudet, Hodgson, Eden, Jackson-Grusby, Dausman, Gray, Leonhardt and Joenisch2003), we do not know whether the mechanism that mediates the ERT-related increases in genomic DNA methylation in peripheral mononuclear cells is related to reduced risk of colon cancer or enhanced risk of breast cancer. Since the effect of tHcy on DNA methylation is highly tissue-specific (Choumenkovitch et al. Reference Choumenkovitch, Selhub, Bagley, Maeda, Nadeau, Smith and Choi2002), we also cannot entirely explicate whether our observation is specific for peripheral mononuclear cells. Nevertheless, the observation that ERT alters genomic DNA methylation status is very meaningful because it suggests a candidate mechanism as well as a new biomarker for the study of oestrogen-related carcinogenesis.

In both reproductive and non-reproductive tissues, oestrogen regulates cell growth and differentiation through ER, which have a critical role in breast and colorectal carcinogenesis (Fiorelli et al. Reference Fiorelli, Picariello, Martineti, Tonelli and Brandi1999). There are two types of ER, α and β, which show differential expression in various tissues. Studies have suggested that the chemopreventive effect of ERT in colonic carcinogenesis is associated with an increase in ERβ and a decrease in ERα expression (Weyant et al. Reference Weyant, Carothers, Mahmoud, Bradlow, Remotti, Bilinski and Bertagnolli2001). Issa et al. (Reference Issa, Ottaviano, Celano, Hamilton, Davidson and Baylin1994) reported that one of the earliest events that predisposes to sporadic colorectal carcinogenesis is the inactivation of ER genes by promoter methylation. Other cancers originated from breast, endometrium and prostate also showed a relationship between the promoter methylation and loss of expression in ER genes (Sasaki et al. Reference Sasaki, Tanaka, Perinchery, Dharia, Kotcherguina, Fujimoto and Dahiya2002). We, therefore, evaluated the promoter methylation status of ERα and ERβ along with p16, a tumour suppressor gene frequently found to be hypermethylated in those cancers, but no significant difference between the two phases was observed. This negative observation suggests that: 1) in contrast to genomic DNA hypomethylation, which can induce a compensatory promoter hypermethylation, increased genomic DNA methylation by ERT might not necessarily affect promoter methylation; 2) 8-week treatment with ERT in the present study might not be long enough to change the promoter methylation; 3) significant changes in promoter methylation of these genes might be hardly found before cancer conversion; 4) response of promoter methylation also might be tissue-specific.

One limitation of the study is the restricted number of subjects and some of the endpoints, such as plasma vitamin B6 concentrations, likely due to this reason could not show statistically significant differences between the placebo and ERT groups.

Yet in the present study, ERT indeed reduced tHcy concentration in plasma with a concurrent increase in DNA methylation. Since DNA methylation is critical to carcinogenesis, the altered DNA methylation may be a mechanism by which ERT modulates the risk of cancer. The present study also suggests that DNA methylation can be a good biomarker for the study of oestrogen-related carcinogenesis.

Acknowledgements

This work has been supported by grants from the Regione Veneto, the Cariverona Foundation (S.F.) and the National Institutes of Health Clinical Investigator Development Award HL 03 209 (S.L-F.), and the National Institute of Health Grants R21AA016681-01 (S-W.C). Any opinions, findings, conclusion or recommendations expressed in this publication are those of the author(s) and do not necessarily reflect the view of the U.S. Dept of Agriculture.

References

Beral, V, Banks, E & Reeves, G (2002) Evidence from randomised trials on the long-term effects of hormone replacement therapy. Lancet 360, 942944.CrossRefGoogle ScholarPubMed
Biasco, G & Di Marco, MC (2005) Folate and prevention of colorectal cancer in ulcerative colitis. Eur J Cancer Prev 14, 395398.CrossRefGoogle ScholarPubMed
Camp, VM, Chipponi, J & Faraj, BA (1983) Radioenzymatic assay for direct measurement of plasma pyridoxal 5′-phosphate. Clin Chem 29, 642644.CrossRefGoogle ScholarPubMed
Choi, SW & Friso, S (2006) Interaction between folate and methylene-tetrahydrofolate reductase gene in cancer. In Nutrient-gene Interactions in Cancer, pp. 5774 [Friso, S and Choi, S-W, editors]. Boca Raton, FL: CRC Press.Google Scholar
Choi, SW & Mason, JB (2000) Folate and carcinogenesis: an integrated scheme. J Nutr 130, 129132.CrossRefGoogle ScholarPubMed
Choumenkovitch, SF, Selhub, J, Bagley, PJ, Maeda, N, Nadeau, MR, Smith, DE & Choi, SW (2002) In the cystathionine beta-synthase knockout mouse, elevations in total plasma homocysteine increase tissue S-adenosylhomocysteine, but responses of S-adenosylmethionine and DNA methylation are tissue specific. J Nutr 132, 21572160.CrossRefGoogle ScholarPubMed
Dimitrova, KR, DeGroot, K, Myers, AK & Kim, YD (2002) Estrogen and homocysteine. Cardiovasc Res 53, 577588.CrossRefGoogle ScholarPubMed
Farag, NH, Barshop, BA & Mills, PJ (2003) Effects of estrogen and psychological stress on plasma homocysteine levels. Fertil Steril 79, 256260.CrossRefGoogle ScholarPubMed
Finkelstein, JD (1962) Methionine metabolism in mammals: effects of age, diet, and hormones on three enzymes of the pathway in rat tissues. Arch Biochem Biophys 122, 583590.CrossRefGoogle Scholar
Fiorelli, G, Picariello, L, Martineti, V, Tonelli, F & Brandi, ML (1999) Functional estrogen receptor beta in colon cancer cells. Biochem Biophys Res Comm 261, 521527.CrossRefGoogle ScholarPubMed
Friso, S & Choi, SW (2002) Gene-nutrient interactions and DNA methylation. J Nutr 132, Suppl., 8, 2382S2387S.CrossRefGoogle ScholarPubMed
Friso, S, Choi, SW, Dolnikowski, GG & Selhub, J (2002) A method to assess genomic DNA methylation using high-performance liquid chromatography/electrospray ionization mass spectrometry. Anal Chem 74, 45264531.CrossRefGoogle ScholarPubMed
Gaudet, F, Hodgson, JG, Eden, A, Jackson-Grusby, L, Dausman, J, Gray, JW, Leonhardt, H & Joenisch, R (2003) Induction of tumors in mice by genomic hypomethylation. Science 300, 489492.CrossRefGoogle ScholarPubMed
Goelz, SE, Vogelstein, B, Hamilton, SR & Feinberg, AP (1985) Hypomethylation of DNA from benign and malignant human colon neoplasms. Science 228, 187190.CrossRefGoogle ScholarPubMed
Issa, JP, Ottaviano, YL, Celano, P, Hamilton, SR, Davidson, NE & Baylin, SB (1994) Methylation of the oestrogen receptor CpG island links ageing and neoplasia in human colon. Nat Genet 7, 536540.CrossRefGoogle ScholarPubMed
Kane, MA (2005) The role of folates in squamous cell carcinoma of the head and neck. Cancer Detect Prev 29, 4653.CrossRefGoogle ScholarPubMed
Kim, YI (2003) Role of folate in colon cancer development and progression. J Nutr 133, 3731S3739S.CrossRefGoogle ScholarPubMed
Koh, KK, Mincemoyer, R, Bui, MN, Csako, G, Pucino, F, Guetta, V, Waclawiw, M & Cannon, RO 3rd (1997) Effects of hormone-replacement therapy on fibrinolysis in postmenopausal women. N Engl J Med 336, 683690.CrossRefGoogle ScholarPubMed
Lamon-Fava, S, Posfai, B & Schaefer, EJ (2003) Effect of hormonal replacement therapy on C-reactive protein and cell-adhesion molecules in postmenopausal women. Am J Cardiol 91, 252254.CrossRefGoogle ScholarPubMed
Morris, MS, Jacques, PF, Selhub, J & Rosenberg, IH (2000) Total homocysteine and estrogen status indicators in the Third National Health and Nutrition Examination Survey. Am J Epidemiol 152, 140148.CrossRefGoogle ScholarPubMed
Sasaki, M, Tanaka, Y, Perinchery, G, Dharia, A, Kotcherguina, I, Fujimoto, S & Dahiya, R (2002) Methylation and inactivation of estrogen, progesterone, and androgen receptors in prostate cancer. J Natl Cancer Inst 94, 384390.CrossRefGoogle ScholarPubMed
Selhub, J & Miller, JW (1992) The pathogenesis of homocysteinemia: interruption of the coordinate regulation by S-adenosylmethionine of the remethylation and transsulfuration of homocysteine. Am J Clin Nutr 55, 131138.CrossRefGoogle ScholarPubMed
Smolders, RG, de Meer, K, Kenemans, P, Jakobs, C, Kulik, W & van der Mooren, MJ (2005) Oral estradiol decreases plasma homocysteine, vitamin B6, and albumin in postmenopausal women but does not change the whole-body homocysteine remethylation and transmethylation flux. J Clin Endocrinol Metab 90, 22182224.CrossRefGoogle Scholar
Smolders, RG, de Meer, K, Kenemans, P, Teerlink, T, Jakobs, C & van der Mooren, MJ (2004) Hormone replacement influences homocysteine levels in the methionine-loading test: a randomized placebo controlled trial in postmenopausal women. Eur J Obstet Gynecol Reprod Biol 117, 5559.CrossRefGoogle Scholar
Stabler, SP & Allen, RH (2004) Megaloblastic anemias. In Textbook of Medicine, 22nd ed. pp. , 10501057 [Goldman, L and Ausiello, D, editors]. Philadelphia: Saunders.Google Scholar
Tutuncu, L, Ergur, AR, Mungen, E, Gun, I, Ertekin, A & Yergok, YZ (2005) The effect of hormone therapy on plasma homocysteine levels: a randomized clinical trial. Menopause 12, 216222.CrossRefGoogle Scholar
Ulrich, C (2006) Genetic variability in folate-mediated one-carbon metabolism and cancer risk. In Nutrient-Gene Interactions in Cancer, pp. 7591 [Friso, S and Choi, S-W, editors]. Boca Raton, FL: CRC Press.Google Scholar
Vester, B & Rasmussen, K (1991) High performance liquid chromatography method for rapid and accurate determination of homocysteine in plasma and serum. Eur J Clin Chem Clin Biochem 29, 549554.Google ScholarPubMed
Weyant, MJ, Carothers, AM, Mahmoud, NN, Bradlow, HL, Remotti, H, Bilinski, RT & Bertagnolli, MM (2001) Reciprocal expression of ERalpha and ERbeta is associated with estrogen-mediated modulation of intestinal tumorigenesis. Cancer Res 61, 25472551.Google ScholarPubMed
Wu, LL & Wu, JT (2002) Hyperhomocysteinemia is a risk factor for cancer and a new potential tumor marker. Clin Chim Acta 322, 2128.CrossRefGoogle Scholar
Yi, P, Melnyk, S, Pogribna, M, Pogribny, IP, Hine, RJ & James, SJ (2000) Increase in plasma homocysteine associated with parallel increases in plasma S-adenosylhomocysteine and lymphocyte DNA hypomethylation. J Biol Chem 275, 2931829323.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Biochemical characteristics of the study group at the end of the placebo and oestrogen replacement therapy phases (Mean values and 95 % CI)

Figure 1

Fig. 1 Effects of oestrogen replacement therapy on genomic DNA methylation. A significant difference in genomic DNA methylation of peripheral mononuclear cells is observed between the placebo and conjugated equine oestrogen (CEE) phases; *P = 0·042. Genomic DNA methylation is represented by an absolute amount of 5-methylcytosine (mCyt) in genomic DNA (ng mCyt/μg DNA). Values are expressed as means and standard deviations. Statistical difference was evaluated by Student's paired samples t test. For details of subjects and procedures, see p. 618.