Birthweight is associated with DNA promoter methylation of the glucocorticoid receptor in human placenta

Birthweight has been associated with a number of health outcomes throughout life. Crucial to proper infant growth and development is the placenta, and alterations to placental gene function may reflect differences in the intrauterine environment which functionally contribute to infant growth and may ultimately affect the child’s health. To examine if epigenetic alteration to the glucocorticoid receptor (GR) gene was linked to infant growth, we analyzed 480 human placentas for differential methylation of the GR gene exon 1F and examined how this variation in methylation extent was associated with fetal growth. Multivariable linear regression revealed a significant association (p < 0.0001) between differential methylation of the GR gene and large for gestational age (LGA) status. Our work is one of the first to link infant growth as a measure of the intrauterine environment and epigenetic alterations to the GR and suggests that DNA methylation may be a critical determinant of placental function.     

Magnesium deficiency in pregnant rats alters methylation of specific cytosines in the hepatic hydroxysteroid dehydrogenase-2 promoter of the offspring

Prenatal under-nutrition involves changes in the epigenetic regulation of specific genes. Maternal magnesium (Mg) deficiency affects maternal glucocorticoid metabolism, but the mechanisms underlying changes in glucocorticoid homeostasis of offspring are not well understood. In this study, we investigated the effects of feeding pregnant rats a Mg-deficient diet (0.003% magnesium) on the methylation of cytosine-guanine (CpG) dinucleotides in hepatic glucocorticoid genes of neonatal offspring, compared with controls (0.082% magnesium). Methylation of CpG dinucleotides in the peroxisome proliferator-activated receptor α (Ppara), glucocorticoid receptor (Nr3c1) and 11β-hydroxysteroid dehydrogenase-2 (Hsd11b2) promoters in the liver were measured by pyrosequencing. Quantitative real-time PCR was used to assess hepatic mRNA expression of each gene. Mean methylation of the Hsd11b2 promoter in the Mg-deficient offspring (33.2%) was higher than in controls (10.4%). This was due to a specific increase at CpG dinucleotides 1 (20.0% vs. control 10.1%), 2 (58.8% vs. 17.0%), 3 (29.7% vs. 6.2%) and 4 (38.7% vs. 8.8%) (p < 0.05). Ppara and Nr3c1 methylation status and expression did not differ between the groups. No significant difference was noted between male and female pups, which were equally represented. Therefore, a Mg-deficient diet alters glucocorticoid metabolism, predicting higher hepatic intracellular glucocorticoid concentrations, and is possibly a key mechanism that induces the metabolic complications of Mg deficiency.     

Significant differences in global genomic DNA methylation by gender and race/ethnicity in peripheral blood

Reduced levels of global DNA methylation are associated with genomic instability and are independent predictors of cancer risk. Little is known about the environmental determinants of global DNA methylation in peripheral blood. We examined the association between demographic and lifestyle factors and levels of global leukocyte DNA methylation in 161 cancer-free subjects enrolled in the North Texas Healthy Heart Study aged 45–75 years in 2008. We used in-person interviews for demographics and lifestyle factors, a self-administrated Block food frequency questionnaire for diet, and bioelectrical impedance analysis and CT-scan for body composition. We measured genomic DNA methylation using bisulfite conversion of DNA and pyrosequencing for LINE-1. Body composition measures including body mass index, waist circumference, areas of subcutaneous fat and visceral fat, percent of fat mass and fat-free mass were not associated with global genomic DNA methylation after controlling the effect of age, gender and race/ethnicity. Instead, female gender was significantly associated with a reduced level of global methylation (β = -2.77, 95% CI: -4.33, -1.22). Compared to non-Hispanic whites, non-Hispanic blacks (β = -2.02, 95% CI: -3.55, -0.50) had significantly lower levels of global methylation. No association was found with age, cigarette smoking, alcohol drinking and dietary intake of nutrients in one-carbon metabolism. Global leukocyte DNA methylation differs by gender and race/ethnicity, suggesting these variables need to be taken into consideration in studies of global DNA methylation as an epigenetic marker for cancer.     

Comprehensive DNA methylation analysis of human peripheral blood leukocytes and lymphoblastoid cell lines

DNA methylation is involved in development and in human diseases. Genomic DNA derived from lymphoblastoid cell lines (LCLs) is commonly used to study DNA methylation. There are potential confounding factors regarding the use of LCL-derived DNA, however, such as Epstein-Barr (EB) viral infection and artifacts induced during cell culture. Recently, several groups compared the DNA methylation status of peripheral blood leukocytes (PBLs) and LCLs and concluded that the DNA methylation profiles between them might be consistent. To confirm and extend theses results, we performed a comprehensive DNA methylation analysis using both PBLs and LCLs derived from the same individuals. Using the luminometric methylation assay, we revealed that the global DNA methylation level was different between PBLs and LCLs. Furthermore, the direction of change was not consistent. Comparisons of genome-wide DNA methylation patterns of promoter regions revealed that methylation profiles were largely conserved between PBLs and LCLs. A preliminary analysis in a small number of samples suggested that the methylation status of an LCL may be better correlated with PBLs from the same individual than with LCLs from other individuals. Expectedly, DNA methylation in promoter regions overlapping with CpG islands was associated with gene silencing in both PBLs and LCLs. With regard to methylation differences, we found that hypermethylation was more predominant than hypomethylation in LCLs compared with PBLs. These findings suggest that LCLs should be used for DNA methylation studies with caution as the methylation patterns of promoter regions in LCLs are not always the same as those in PBLs.     

DNA methylation analyses of the connexin gene family reveal silencing of GJC1 (Connexin45) by promoter hypermethylation in colorectal cancer

Gap junctions are specialized plasma membrane domains consisting of channels formed by members of the connexin protein family. Gap junctional intercellular communication is often lost in cancers due to aberrant localization or downregulation of connexins, and connexins are therefore suggested to act as tumor suppressor genes in various tissues. The aim of this study was to investigate the expression pattern and DNA promoter methylation status of connexins in colorectal cancer. Expression of six (GJA1, GJA9, GJB1, GJB2, GJC1 and GJD3) connexin genes was detected in normal colonic tissue samples. GJC1 expression was reduced in colorectal carcinomas compared to normal tissue samples. All analyzed connexins were hypermethylated in colon cancer cell lines, although at various frequencies. GJA4, GJB6 and GJD2 were hypermethylated in 60% (29/48), 25% (12/48) and 96% (46/48) of primary colorectal carcinomas, respectively. However, the methylation status was not associated with gene expression. GJC1 has two alternative promoters, which were methylated in 42% (32/76) and 38% (25/65) of colorectal tumors, and in none of the normal mucosa samples. Expression of GJC1 was significantly lower in methylated compared with unmethylated samples (p < 0.01) and was restored in cell lines treated with the demethylating drug 5-aza-2'deoxycytidine. Taken together, DNA hypermethylation of the promoter region of GJC1, encoding connexin45, is an important mechanism in silencing gene expression in colorectal cancer.     

Epigenetic DNA methylation in the promoters of the Igf1 receptor and insulin receptor genes in db/db mice

We have investigated promoter methylation of the Insr, Igf1 and Igf1r genes in skeletal and cardiac muscles of normal and diabetic db/db mice. No differences in Insr promoter methylation were found in the heart and skeletal muscles and no methylation was detected in the Igf1 promoter in skeletal muscle. In skeletal muscle, db/db males exhibited a 7.4-fold increase in Igf1r promoter methylation, which was accompanied by a 1.8-fold decrease in Igf1r mRNA levels, compared with controls. More than 50% of the detected methylation events were concentrated within an 18 bp sequence that includes one of the Sp1 binding sites. We conclude that the methylation level and pattern of the Igf1r promoter in skeletal muscle is related to gender and the diabetic state.     

Assessing combined methylation–sensitive high resolution melting and pyrosequencing for the analysis of heterogeneous DNA methylation

Heterogeneous DNA methylation leads to difficulties in accurate detection and quantification of methylation. Methylation-sensitive high resolution melting (MS-HRM) is unique among regularly used methods for DNA methylation analysis in that heterogeneous methylation can be readily identified, although not quantified, by inspection of the melting curves. Bisulfite pyrosequencing has been used to estimate the level of heterogeneous methylation by quantifying methylation levels present at individual CpG dinucleotides. Sequentially combining the two methodologies using MS-HRM to screen the amplification products prior to bisulfite pyrosequencing would be advantageous. This would not only replace the quality control step using agarose gel analysis prior to the pyrosequencing step but would also provide important qualitative information in its own right. We chose to analyze DAPK1 as it is an important tumor suppressor gene frequently heterogeneously methylated in a number of malignancies, including chronic lymphocytic leukemia (CLL). A region of the DAPK1 promoter was analyzed in ten CLL samples by MS-HRM. By using a biotinylated primer, bisulfite pyrosequencing could be used to directly analyze the samples. MS-HRM revealed the presence of various extents of heterogeneous DAPK1 methylation in all CLL samples. Further analysis of the biotinylated MS-HRM products by bisulfite pyrosequencing provided quantitative information for each CpG dinucleotide analyzed, and confirmed the presence of heterogeneous DNA methylation. Whereas each method could be used individually, MS-HRM and bisulfite pyrosequencing provided complementary information for the assessment of heterogeneous methylation.     

CpG island hypermethylation of BRCA1 and loss of pRb as co-occurring events in basal/triple-negative breast cancer

Triple-negative breast cancer (TNBC) occurs in approximately 15% of all breast cancer patients, and the incidence of TNBC is greatly increased in BRCA1 mutation carriers. This study aimed to assess the impact of BRCA1 promoter methylation with respect to breast cancer subtypes in sporadic disease. Tissue microarrays (TMAs) were constructed representing tumors from 303 patients previously screened for BRCA1 germline mutations, of which a subset of 111 sporadic tumors had previously been analyzed with respect to BRCA1 methylation. Additionally, a set of eight tumors from BRCA1 mutation carriers were included on the TMAs. Expression analysis was performed on TMAs by immunohistochemistry (IHC) for BRCA1, pRb, p16, p53, PTEN, ER, PR, HER2, CK5/6, EGFR, MUC1 and Ki-67. Data on BRCA1 aberrations and IHC expression was examined with respect to breast cancer-specific survival. The results demonstrate that CpG island hypermethylation of BRCA1 significantly associates with the basal/triple-negative subtype. Low expression of pRb, and high/intense p16, were associated with BRCA1 promoter hypermethylation, and the same effects were seen in BRCA1 mutated tumors. The expression patterns of BRCA1, pRb, p16 and PTEN were highly correlated, and define a subgroup of TNBCs characterized by BRCA1 aberrations, high Ki-67 (≥40%) and favorable disease outcome. In conclusion, our findings demonstrate that epigenetic inactivation of the BRCA1 gene associates with RB/p16 dysfunction in promoting TNBCs. The clinical implications relate to the potential use of targeted treatment based on PARP inhibitors in sporadic TNBCs, wherein CpG island hypermethylation of BRCA1 represents a potential marker of therapeutic response.     

Determination of genomic 5-hydroxymethyl-2’-deoxycytidine in human DNA by capillary electrophoresis with laser induced fluorescence

Recent studies reported the presence of 5-hydroxymethylcytosine (5 hmC) as an additional modification in mammalian genomic DNA. To date, 5 hmC has been detected only in mouse DNA isolated from embryonic stem cells, some adult tissues and in DNA from human bone marrow. Understanding its biological function will require the development of sensitive analytical methods that allow the detection and quantification of 5-hydroxymethylcytosine along with 5-methylcytosine and cytosine.

Here we report the validation of a fast and sensitive method for the quantification of global 5-hydroxymethyl-2'-deoxycytidine (5 hmdC) in DNA. The method is based on a procedure consisting of fluorescence labeling of deoxyribonucleotides and analysis by capillary electrophoresis with laser-induced fluorescence detection (CE-LIF). A double stranded DNA fragment containing a defined number of 5 hmdC residues was used for peak assignment, to establish separation conditions and to determine the limit of detection (LOD). The method yielded a LOD for 5 hmdC of 0.45 amol, which is equivalent to approximately to one 5 hmdC per 4,000 normal nucleotides (0.025%) using 1 μg of DNA as the matrix.

By applying the calibrated assay to the analysis of various DNAs we show that 5 hmdC is present in human tissue and human cancer cell lines. We demonstrate that by using CE-LIF DNA can be analyzed in one run for both methylation and hydroxymethylation of cytosine with high sensitivity and accuracy.     

Epigenetic reprogramming as a key contributor to melanocyte malignant transformation

Melanoma progression requires deregulation of gene expression by currently uncharacterized epigenetic mechanisms. A mouse model based on changes in cell microenvironment was developed by our group to study melanocyte malignant transformation. Melanoma cell lines (4C11- and 4C11+) were obtained as result of 5 sequential anchorage blockades of non-tumorigenic melan-a melanocytes. Melan-a cells submitted to 4 de-adhesion cycles were also established (4C), are non-tumorigenic and represent an intermediary phase of tumor progression. The aim of this work was to identify factors contributing to epigenetic modifications in early and later phases of malignant transformation induced by anchorage impediment. Epigenetic alterations occur early in tumorigenesis; 4C cell line shows changes in global and gene-specific DNA methylation and histone marks. Many histone modifications differ between melan-a, 4C, 4C11- (non-metastatic melanoma cell line) and 4C11+ (metastatic melanoma cell line) which could be associated with changes in gene and microRNA expression. These epigenetic alterations seem to play a key role in malignant transformation since melanocytes treated with 5-Aza-2'-deoxycytidine before each anchorage blockade do not transform. Some epigenetic changes seem to be also responsible for the maintenance of malignant phenotype, since melanoma cell lines (4C11- and 4C11+) treated in vitro with 5-Aza-2'-deoxycytidine or Trichostatin A showed reduction of tumor growth in vivo. Changes in gene expression reflecting cell adaptation to new environment were also observed. We propose a model in which sustained microenvironmental stress in melanocytes results in epigenetic reprogramming. Thus, after adaptation, cells may acquire epigenetic marks that could contribute to the establishment of a malignant phenotype.     

Assessment of methylation level prediction accuracy in methyl-DNA immunoprecipitation and sodium bisulfite based microarray platforms

In this study, we verified the accuracy of two array methods—methylated DNA immunoprecipitation coupled with CpG island microarrays (MeDIP-CGI-arrays) and sodium bisulfite conversion based microarrays (BC-arrays)—in predicting regional methylation levels as measured by pyrosequencing of bisulfite converted DNA (BC-pyrosequencing). To test the accuracy of these methods we used the Agilent Human CpG island and the Illumina HumanMethylation27 microarrays respectively, and compared microarray outputs to the data from targeted BC-pyrosequencing assays from several genomic regions of corresponding samples. We observed relatively high correlation with BC-pyrosequencing data for both array platforms, R = 0.87 for BC-Array and R = 0.79 for MeDIP-CGI array. However, MeDIP-CGI array were less reliable in predicting intermediate levels of DNA methylation. Several bioinformatics strategies, to ameliorate the performance of the MeDIP-CGI-Arrays did not improve the correlation with BC-pyrosequencing data. The high scalability, low cost and simpler analysis of BC-arrays, together with the recent extended coverage may make them a more versatile methylation analysis tool.     

Identification of restriction endonucleases sensitive to 5-cytosine methylation at non-CpG sites,including expanded (CAG)n/(CTG)n repeats

Most epigenetic studies assess methylation of 5'-CpG-3' sites but recent evidence indicates that non-CpG cytosine methylation occurs at high levels in humans and other species. This is most prevalent at 5'-CHG-3', where H = A, C or T, and it preferentially occurs at 5'-CpA-3' and 5'-CpT-3' sites. With the goal of facilitating the detection of non-CpG methylation, the restriction endonucleases ApeKI, BbvI, EcoP15I, Fnu4HI, MwoI and TseI were assessed for their sensitivity to 5-methylcytosine at GpCpA, GpCpT, GpCpC or GpCpG sites, where methylation is catalyzed by the DNA 5-cytosine 5'-GpC-3' methyltransferase M.CviPI. We tested a variety of sequences including various plasmid-based sites, a cloned disease-associated (CAG)83?(CTG)83 repeat and in vitro synthesized tracts of only (CAG)500?(CTG)500 or (CAG)800?(CTG)800. The repeat tracts are enriched for the preferred CpA and CpT motifs. We found that none of the tested enzymes can cleave their recognition sequences when they are 5'-GpC-3' methylated. A genomic site known to convert its non-CpG methylation levels upon C2C12 differentiation was confirmed through the use of these enzymes. These enzymes can be useful in rapidly and easily determining the most common non-CpG methylation status in various sequence contexts, as well as at expansions of (CAG)n?(CTG)n repeat tracts associated with diseases like myotonic dystrophy and Huntington disease.     

Methylome analysis reveals Jak-STAT pathway deregulation in putative breast cancer stem cells

Growing evidence supports the existence of a subpopulation of cancer cells with stem cell characteristics within breast tumors. In spite of its potential clinical implications, an understanding of the mechanisms responsible for retaining the stem cell characteristics in these cells is still lacking. Here, we used the mammosphere model combined with DNA methylation bead arrays and quantitative gene expression to characterize the epigenetic mechanisms involved in the regulation of developmental pathways in putative breast cancer stem cells. Our results revealed that MCF7-derived mammospheres exhibit distinct CpG promoter methylation profiles in a specific set of genes, including those involved in Jak-STAT signaling pathway. Hypomethylation of several gene components of the Jak-STAT pathway was correlated with an increased expression in mammospheres relative to parental cells. Remarkably, cell sorting of the cells with a putative cancer stem cell phenotype (CD44⁺/CD24 low) suggests a constitutive activation of Jak-STAT pathway in these cells. These results show that Jak-STAT activation may represent a characteristic of putative breast cancer stem cells. In addition, they favor the concept that the expression of cancer stem-like pathways and the establishment and maintenance of defining properties of cancer stem cells are orchestrated by epigenetic mechanisms.     

MSAP技术及其在植物上的应用

DNA甲基化在植物的很多生命过程中具有重要作用,检测DNA甲基化的技术应运而生。依据对DNA甲基化敏感程度不同的同裂酶,在AFLP技术的基础上发展而来的MSAP技术可以方便的检测全基因组范围内胞嘧啶甲基化模式及程度。该文对MSAP技术的原理、特点、基本程序及应用进行了阐述。     

Expression discordance of monozygotic twins at birth: Effect of intrauterine environment and a possible mechanism for fetal programming

Within-pair comparison of monozygotic (MZ) twins provides an ideal model for studying factors that regulate epigenetic profile, by controlling for genetic variation. Previous reports have demonstrated epigenetic variability within MZ pairs, but the contribution of early life exposures to this variation remains unclear. As epigenetic marks govern gene expression, we have used gene expression discordance as a proxy measure of epigenetic discordance in MZ twins at birth in two cell types. We found strong evidence of expression discordance at birth in both cell types and some evidence for higher discordance in twin pairs with separate placentas. Genes previously defined as being involved in response to the external environment showed the most variable expression within pairs, independent of cell type, supporting the idea that even slight differences in intrauterine environment can influence expression profile. Focusing on birthweight, previously identified as a predisposing factor for cardiovascular, metabolic and other complex diseases, and using a statistical model that estimated association based on within-pair variation of expression and birthweight, we found some association between birthweight and expression of genes involved in metabolism and cardiovascular function. This study is the first to examine expression discordance in newborn twins. It provides evidence of a link between birthweight and activity of specific cellular pathways and, as evidence points to gene expression profiles being maintained through cell division by epigenetic factors, provides a plausible biological mechanism for the previously described link between low birthweight and increased risk of later complex disease.