MethDB--a public database for DNA methylation data

Methylation of cytosine in the 5 position of the pyrimidine ring is a major modification of the DNA in most organisms. In eukaryotes, the distribution and number of 5-methylcytosines (5mC) along the DNA is heritable but can also change with the developmental state of the cell and as a response to modifications of the environment. While DNA methylation probably has a number of functions, scientific interest has recently focused on the gene silencing effect methylation can have in eukaryotic cells. In particular, the discovery of changes in the methylation level during cancer development has increased the interest in this field. In the past, a vast amount of data has been generated with different levels of resolution ranging from 5mC content of total DNA to the methylation status of single nucleotides. We present here a database for DNA methylation data that attempts to unify these results in a common resource. The database is accessible via WWW (http://www.methdb.de). It stores information about the origin of the investigated sample and the experimental procedure, and contains the DNA methylation data. Query masks allow for searching for 5mC content, species, tissue, gene, sex, phenotype, sequence ID and DNA type. The output lists all available information including the relative gene expression level. DNA methylation patterns and methylation profiles are shown both as a graphical representation and as G/A/T/C/5mC-sequences or tables with sequence positions and methylation levels, respectively.     

Profiles of DNA methylation in normal and cancer cells

In eukaryotes, the epigenetic mark DNA methylation is found exclusively at cytosine residues in the CpG islands of genes, transposons and intergenic DNA. Among functional roles, DNA methylation is essential for mammalian embryonic development, and is classically thought to function by stably silencing promoter activity. However, until recently, understanding of the distribution of cytosine methylation in the whole genome - and hence, identification of its targets - was very limited. High-throughput methodologies, including methylated DNA immunoprecipitation, have recently revealed genome-wide mapping of DNA methylation, and provided new and unexpected data. Clearly DNA methylation is selectively associated with some key promoters- and is not a prerequisite for promoter inactivation, since strong CpG island promoters are mostly unmethylated, even when inactive. Most germline-specific genes are methylated and permanently silenced in somatic cells, suggesting a role of this mark in maintaining somatic cellular identity. These large scale studies will also help understanding the deregulation of DNA methylation associated with cancer, among which unmethylation of germinal cells genes, and recent observtion of large hypomethylated regions in tumoral specimens. The next challenge will be to understand if these methylation changes occur randomly, or more likely are specified by oncogenes or linked to environmental pressure.     

DNA methylation in the termite <Emphasis Type="Italic">Coptotermes lacteus</Emphasis>

Social insects are key examples of organisms that display polyphenism. Their genomes encode instructions for the development of multiple phenotypes, known as castes, which typically have highly divergent morphology, physiology and behaviour. DNA methylation, an epigenetic mechanism associated with modulation of gene expression in various eukaryotes, has recently been shown to provide a key link between environmental cues and caste-specific gene expression in honey bees (Hymenoptera). In termites—a major social insect group phylogenetically distant from Hymenoptera—the existence of DNA methylation has not, to our knowledge, been reported to date. Since genes encoding key DNA methylation enzymes are known to be absent in the genomes of a number of insect species, we sought to test whether termites are able to methylate their DNA, and, if so, whether caste-specific patterns of DNA methylation exist. We performed methylation-specific amplified fragment length polymorphism on the termite Coptotermes lacteus, and found evidence for DNA methylation. However, a comparison of methylation levels in different castes did not reveal any significant differences in methylation levels. The demonstration of DNA methylation in termites sets the stage for future epigenetic studies in these important social insects.     

Methylation of adenine residues in DNA of eukaryotes

Like in bacteria, DNA in these organisms is subjected to enzymatic modification (methylation) both at adenine and cytosine residues. There is an indirect evidence that adenine DNA methylation takes place also in animals. In plants m6A was detected in total, mitochondrial and nuclear DNAs; in plants one and the same gene (DRM2) can be methylated both at adenine and cytosine residues. ORF homologous to bacterial adenine DNA-methyltransferases are present in nuclear DNA of protozoa, yeasts, insects, nematodes, higher plants, vertebrates and other eukaryotes. Thus, adenine DNA-methyltransferases can be found in the various evolutionary distant eukaryotes. First N6-adenine DNA-methyltransferase (wadmtase) of higher eukaryotes was isolated from vacuolar fraction of vesicles obtained from aging wheat coleoptiles; in the presence of S-adenosyl-L-methionine this Mg2+ -, Ca2+ -dependent enzyme de novo methylates first adenine residue in TGATCA sequence in single- and double-stranded DNA but it prefers single-stranded DNA structures. Adenine DNA methylation in eukaryotes seems to be involved in regulation of both gene expression and DNA replication including replication of mitochondrial DNA. It can control persistence of foreign DNA in a cell and seems to be an element of R-M system in plants. Thus, in eukaryotic cell there are, at least, two different systems of the enzymatic DNA methylations (adenine and cytosine ones) and a special type of regulation of gene functioning based on the combinatory hierarchy of these interdependent genome modifications.     

DNA methylation with a sting: an active DNA methylation system in the honeybee

The existence of DNA methylation in insects has been a controversial subject over a long period of time. The recently completed genome sequence of the honeybee Apis mellifera has revealed the first insect with a full complement of DNA methyltransferases. A parallel study demonstrated that these enzymes are catalytically active and that Apis genes can be methylated in specific patterns. These findings establish bees as a model to analyze the function of DNA methylation systems in invertebrate organisms and might also be important to understand evolutionary aspects of DNA methylation in higher eukaryotes.     

DNA methylation and chromatin structure: a view from below

An understanding of the function and control of DNA methylation in eukaryotes has been elusive. Studies of Neurospora crassa have led to a model that accounts for the chromosomal distribution of methylation and suggests a basic function for DNA methylation in eukaryotes.     

Developmentally regulated DNA methylation in Dictyostelium discoideum

Methylation of cytosine residues in DNA plays a critical role in the silencing of gene expression, organization of chromatin structure, and cellular differentiation of eukaryotes. Previous studies failed to detect 5-methylcytosine in Dictyostelium genomic DNA, but the recent sequencing of the Dictyostelium genome revealed a candidate DNA methyltransferase gene (dnmA). The genome sequence also uncovered an unusual distribution of potential methylation sites, CpG islands, throughout the genome. DnmA belongs to the Dnmt2 subfamily and contains all the catalytic motifs necessary for cytosine methyltransferases. Dnmt2 activity is typically weak in Drosophila melanogaster, mouse, and human cells and the gene function in these systems is unknown. We have investigated the methylation status of Dictyostelium genomic DNA with antibodies raised against 5-methylcytosine and detected low levels of the modified nucleotide. We also found that DNA methylation increased during development. We searched the genome for potential methylation sites and found them in retrotransposable elements and in several other genes. Using Southern blot analysis with methylation-sensitive and -insensitive restriction endonucleases, we found that the DIRS retrotransposon and the guaB gene were indeed methylated. We then mutated the dnmA gene and found that DNA methylation was reduced to about 50% of the wild-type level. The mutant cells exhibited morphological defects in late development, indicating that DNA methylation has a regulatory role in Dictyostelium development. Our findings establish a role for a Dnmt2 methyltransferase in eukaryotic development.     

A view of an elemental naturalist at the DNA world (Base composition,sequences, methylation)

The pioneering data on base composition and pyrimidine sequences in DNA of pro-and eukaryotes are considered, and their significance for the origin of genosystematics is discussed. The modern views on specificity and functional role of enzymatic DNA methylation in eukaryotes are described. DNA methylation controls all genetic functions and is a mechanism of cellular differentiation and gene silencing. A model of regulation of DNA replication by methylation is suggested. Adenine DNA methylation in higher eukaryotes (higher plants) was first observed, and it was established that one and the same gene can be methylated at both cytosine and adenine moieties. Thus, there are at least two different and seemingly interdependent DNA methylation systems present in eukaryotic cells. The first eukaryotic adenine DNA-methyltransferase is isolated from wheat seedlings and described: the enzyme methylates DNA with formation of N⁶-methyladenine in the sequence TGATCA → TGm⁶ATCA. It is found that higher plants have endonucleases that are dependent on S-adenosyl-L-methionine (SAM) and sensitive to DNA methylation status. Therefore, as in bacteria, plants seem to have a restriction-modification (R-M) system. A system of conjugated up-and down-regulation of SAM-dependent endonucleases by SAM modulations is found in plants. Revelation of an essential role of DNA methylation in regulation of genetic processes is a fundament of materialization of epigenetics and epigenomics. Published in Russian in Biokhimiya, 2007, Vol. 72, No. 12, pp. 1583–1593.     

The first high-resolution DNA "methylome"

Cytosine methylation plays a crucial role in the regulation of gene expression and the control of genome stability in higher eukaryotes. Despite its importance for normal development, the degree and genome-wide distribution of DNA methylation has remained largely unknown. In this issue of Cell, fill this gap by presenting a high-resolution map of DNA methylation in the genome of the flowering plant Arabidopsis.     

A diverse epigenetic landscape at human exons with implication for expression

DNA methylation is an important epigenetic marker associated with gene expression regulation in eukaryotes. While promoter methylation is relatively well characterized, the role of intragenic DNA methylation remains unclear. Here, we investigated the relationship of DNA methylation at exons and flanking introns with gene expression and histone modifications generated from a human fibroblast cell-line and primary B cells. Consistent with previous work we found that intragenic methylation is positively correlated with gene expression and that exons are more highly methylated than their neighboring intronic environment. Intriguingly, in this study we identified a unique subset of hypomethylated exons that demonstrate significantly lower methylation levels than their surrounding introns. Furthermore, we observed a negative correlation between exon methylation and the density of the majority of histone modifications. Specifically, we demonstrate that hypo-methylated exons at highly expressed genes are associated with open chromatin and have a characteristic histone code comprised of significantly high levels of histone markings. Overall, our comprehensive analysis of the human exome supports the presence of regulatory hypomethylated exons in protein coding genes. In particular our results reveal a previously unrecognized diverse and complex role of the epigenetic landscape within the gene body.     

DNA methylation: evolution of a bacterial immune function into a regulator of gene expression and genome structure in higher eukaryotes

The amino acid sequence of mammalian DNA methyltransferase has been deduced from the nucleotide sequence of a cloned cDNA. It appears that the mammalian enzyme arose during evolution via fusion of a prokaryotic restriction methyltransferase gene and a second gene of unknown function. Mammalian DNA methyltransferase currently comprises an N-terminal domain of about 1000 amino acids that may have a regulatory role and a C-terminal 570 amino acid domain that retains similarities to bacterial restriction methyltransferases. The sequence similarities among mammalian and bacterial DNA cytosine methyltransferases suggest a common evolutionary origin. DNA methylation is uncommon among those eukaryotes having genomes of less than 10(8) base pairs, but nearly universal among large-genome eukaryotes. This and other considerations make it likely that sequence inactivation by DNA methylation has evolved to compensate for the expansion of the genome that has accompanied the development of higher plants and animals. As methylated sequences are usually propagated in the repressed, nuclease-insensitive state, it is likely that DNA methylation compartmentalizes the genome to facilitate gene regulation by reducing the total amount of DNA sequence that must be scanned by DNA-binding regulatory proteins. DNA methylation is involved in immune recognition in bacteria but appears to regulate the structure and expression of the genome in complex higher eukaryotes. I suggest that the DNA-methylating system of mammals was derived from that of bacteria by way of a hypothetical intermediate that carried out selective de novo methylation of exogenous DNA and propagated the methylated DNA in the repressed state within its own genome.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA-[Adenine] Methylation in Lower Eukaryotes

DNA methylation in lower eukaryotes, in contrast to vertebrates, can involve modification of adenine to N6-methyladenine (m6A). While DNA-[cytosine] methylation in higher eukaryotes has been implicated in many important cellular processes, the function(s) of DNA-[adenine] methylation in lower eukaryotes remains unknown. I have chosen to study the ciliate Tetrahymena thermophila as a model system, since this organism is known to contain m6A, but not m5C, in its macronuclear DNA. A BLAST analysis revealed an open reading frame (ORF) that appears to encode for the Tetrahymena DNA-[adenine] methyltransferase (MTase), based on the presence of motifs characteristic of the enzymes in prokaryotes. Possible biological roles for DNA-[adenine] methylation in Tetrahymena are discussed. Experiments to test these hypotheses have begun with the cloning of the gene. Orthologous ORFs are also present in three species of the malarial parasite Plasmodium. They are compared to one another and to the putative Tetrahymena DNA-[adenine] MTase. The gene from the human parasite P. falciparum has been cloned.     

DNA甲基化在动植物遗传育种中的研究进展

DNA甲基化是真核生物表观遗传学重要的机制之一,对基因转录水平的表达具有重要的调控作用。近年来,DNA甲基化在动植物遗传育种领域的研究引起了人们广泛的关注。我们从DNA甲基化与基因的表达调控、动植物基因组的甲基化状态、甲基敏感扩增片段多态性方法、DNA甲基化与杂种优势,以及DNA甲基化与分子标记等方面,简要综述了国内外有关DNA甲基化在动植物遗传育种研究中的进展,着重于全基因组DNA甲基化模式在动植物遗传育种中的相关研究和应用。     

叶锈菌胁迫下的小麦基因组MSAP分析

内源DNA甲基化是真核生物表观遗传调控的重要组成部分, 在真核生物的基因表达调控中具有重要的作用。生物胁迫为植物提供一种内在的表观遗传进化动力。研究生物胁迫下DNA甲基化的变异模式, 有助于全面理解DNA甲基化的表观调控生物学功能。小麦近等基因系TcLr19、TcLr41及其感病亲本Thatcher在苗期对叶锈菌生理小种THTT、TKTJ分别表现为小种特异性抗病反应和感病反应。文章利用甲基化敏感扩增多态性(Methylation-sensitive amplified polymorphism, MSAP)技术分析了小麦的甲基化水平, 同时比较了苗期在生物胁迫前后基因组DNA胞嘧啶甲基化模式。用60对MSAP引物对接种前后的小麦DNA进行全基因组筛选, 没有直接分离得到接菌前后的甲基化模式的差异, 结果初步表明, 叶锈菌并没有诱导稳定且特异的植物基因组DNA胞嘧啶位点的甲基化模式变化, 但发现TcLr41及其感病亲本Thatcher之间存在表观遗传学差异。     

综述: 表观遗传学研究的模式生物——粗糙脉孢菌

丝状真菌粗糙脉孢菌是一种作为遗传学研究的经典模式生物．通过对粗糙脉孢菌5S rRNA基因的组成和在染色体上分布的研究,揭示了丝状真菌中存在的一种基因组防御机制——重复序列诱导的DNA点突变(RIP)．通过对发生突变的5S rRNA假基因的研究还发现,粗糙脉孢菌中存在一种重要的表观遗传修饰——DNA甲基化,随后的深入研究使粗糙脉孢菌成为解析DNA甲基化机制的最重要模式生物之一．粗糙脉孢菌基因转化操作引起的营养生长阶段同源基因的沉默(quelling)是由RNAi途径调控的,同时该途径也是调控减数分裂过程中非配对DNA诱发的基因沉默(meiotic silencing)的关键．由于粗糙脉孢菌基因组简单,且存在与高等真核生物相同的DNA甲基化和多种组蛋白的修饰,使其成为今后深入研究组蛋白修饰与染色质重塑等表观遗传现象参与基因表达调控和基因组稳定性维持的重要模式生物之一．     

The Regulation and Function of Histone Methylation

Histones are wrapped around by genomic DNA to form nucleosomes which are the basic units of chromatin. In eukaryotes histones undergo various covalent modifications such as methylation, phosphorylation, acetylation, ubiquitination and ribosylation. Histone modifications play a fundamental role in the epigenetic regulation of gene expression in multicellular eukaryotes. Histone methylation is one of the most important modifications occurring on Lysine (K) and Arginine (R) residues of histones, dynamically regulated by histone methyltransferases and demethylases. Identifications of such histone modification enzymes and to study how they work are the most fundamental questions needs to be answered. Uncovering the regulation and functions of the various histone methylation enzymes will help us to better understand the epigenetic code. This review summarizes the regulation of histone methyltransferases activity, the recruitment of methyltransferases and the distribution patterns and function of histone methylations.