Undetectable levels of N6-methyl adenine in mouse DNA: Cloning and analysis of PRED28, a gene coding for a putative mammalian DNA adenine methyltransferase

Three methylated bases, 5-methylcytosine, N4-methylcytosine and N6-methyladenine (m6A), can be found in DNA. However, to date, only 5-methylcytosine has been detected in mammalian genomes. To reinvestigate the presence of m6A in mammalian DNA, we used a highly sensitive method capable of detecting one N6-methyldeoxyadenosine per million nucleosides. Our results suggest that the total mouse genome contains, if any, less than 10(3) m6A. Experiments were next performed on PRED28, a putative mammalian N6-DNA methyltransferase. The murine PRED28 encodes two alternatively spliced RNA. However, although recombinant PRED28 proteins are found in the nucleus, no evidence for an adenine-methyltransferase activity was detected.     

DNA methylation in thermophilic bacteria: N4-methylcytosine, 5-methylcytosine, and N6-methyladenine.

While determining the minor and major base composition of the DNA from 17 types of thermophilic bacteria by high performance liquid chromatography (HPLC) of enzymatic digests, we have discovered a novel base, N4-methylcytosine (m4C). Its structure was proven by comparison of the DNA-derived nucleoside to the analogous authentic compound by HPLC, UV spectroscopy, and mass spectroscopy. Eight of the bacterial DNAs contained m4C. Only two contained the common minor base, 5-methylcytosine (m5C), and neither of these was from an extreme thermophile. The other prevalent modified base of bacterial DNA, N6-methyladenine (m6A), was found in nine of the DNAs. Restriction analysis revealed that four of the DNAs had dam-type (Gm6ATC) methylation patterns. Due to the propensity of m5C residues to be deaminated by heat to thymine residues and to inefficient repair of the resulting mismatched base pairs, thermophiles with optimal growth temperatures of greater than or equal to 60 degrees C generally may avoid having m5C in their genomes. Instead, some of them have deamination-resistant m4C residues.     

Bacterial DNA methylation and gene transfer efficiency

The necessary amplification step in bacteria of any plasmid currently used in DNA immunization or gene therapy introduces modification in the nucleotide sequence of plasmid DNA used in gene transfer. These changes affect the adenine and the internal cytosine in respectively all of the GATC and CC(A/T)GG sequences. These modifications which introduce 6-methyladenine and 5-methylcytosine in plasmidic DNA are the consequence of the existence of the bacterial modification systems Dam and Dcm. In eucaryotes, the presence of 5-methylcytosine at dinucleotides -CG- is involved in silencing gene expression, but the possible consequences of the presence of the bacterial G(m)ATC and C(m)C(A/T)GG sequences in the plasmids used in gene transfer experiments are presently unknown. Since the possibility exists to obtain plasmid DNA lacking this specific bacterial pattern of methylation by using (dam(-), dcm(-)) bacteria we performed experiments to compare in vitro and in vivo gene transfer efficiency of a pCMV-luc reporter plasmid amplified either in the JM109 (dam(+), dcm(+)) or JM110 (dam(-), dcm(-)) bacteria. Data obtained demonstrated that the presence of 6-methyladenine in GATC sequences and 5-methylcytosine in the second C of CC(A/T)GG motifs does not reduce the levels of luciferase activity detected following in vitro or in vivo gene transfer. On the contrary, gene transfer with a pCMV-luc amplified in JM109 (dam(+), dcm(+)) bacteria gives greater amounts of luciferase than the same transfection performed with a plasmid amplified in the mutated JM110 (dam(-), dcm(-)) counterpart. Therefore, these data do not suggest that the use of (dam(-), dcm(-)) bacteria to amplify plasmid DNA may increase gene transfer efficiency. However, the persistence of the use of (dam(+), dcm(+)) bacteria in order to amplify plasmid DNA raises the question of the possible biological consequences of the introduction of the bacterial G(m)ATC and C(m)C(A/T)GG sequences in eukaryotic cells or organisms.     

Analysis of products of DNA modification by methylases: a procedure for the determination of 5- and N4-methylcytosines in DNA

Although many different methods are used for the identification of methylated heterocyclic bases in DNA not all of them possess the ability to discriminate N4-methylcytosine (m4C) and 5-methylcytosine (m5C). Therefore, some of the methods need additional reexamination. This paper reinvestigates some chromatographic systems (thin-layer chromatography, paper chromatography, electrophoresis) most widely used in the analysis of minor bases occurring in nucleic acids according to their ability to separate m4C and m5C. A simple procedure for the preparation of the sample and a chromatographic system for its analysis was developed. The recommended chromatographic systems may be used for the simultaneous separation of not only of m4C and m5C but also both methylated cytosines together with N6-methyladenine and 7-methylguanine.     

Methylation Modifications in Eukaryotic Messenger RNA

RNA methylation modifications have been found for decades of years, which occur at different RNA types of numerous species, and their distribution is species-specific. However, people rarely know their biological functions. There are several identified methylation modifications in eukaryotic messenger RNA （mRNA）, such as NT-methylguanosine （mVG） at the cap, Nr-methyl-2＇-O-methyladenosine （m6Am）, 2＇-O-methylation （Nm） within the cap and the internal positions, and internal N6-methyladenosine （m6A） and 5-methylcytosine （mSC）. Among them, mTG cap was studied more clearly and found to have vital roles in several important mRNA processes like mRNA translation, stability and nuclear export, m6A as the most abundant modification in mRNA was found in the 1970s and has been proposed to function in mRNA splicing, translation, stability, transport and so on. mrA has been discovered as the first RNA reversible modification which is demethylated directly by human fat mass and obesity associated protein （FRO） and its homolog protein, alkylation repair ho- molog 5 （ALKBH5）. b-TO has a special demethylation mechanism that demethylases m6A to A through two over-oxidative intermediate states： N6-hydroxymethyladenosine （hm6A） and Nr-formyladenosine （frA）. The two newly discovered m6A demethylases, bTO and ALKBH5, significantly control energy homeostasis and spermatogenesis, respectively, indicating that the dynamic and reversible mrA, analogous to DNA and histone modifications, plays broad roles in biological kingdoms and brings us an emerging field ＂RNA Epige- netics＂. 5-methylcytosine （5mC） as an epigenetic mark in DNA has been studied widely, but mSC in mRNA is seldom explored. The bisulfide sequencing showed mSC is another abundant modification in mRNA, suggesting that it might be another RNA epigenetic mark. This review focuses on the main methylation modifications in mRNA to describe their formation, distribution, function and demethylation from the current knowledge and to provide future 19erspectives on functional studies.     

Limited accessibility of DNA methylation sites for bacterial methylases M. Eco RII and M.Eco dam in chromatin at different levels of organization

The bacterial methylases M. Eco RII and M. Eco dam can methylate DNA in rat liver chromatin to form the 5-methylcytosine (m5C) and N6-methyladenine (m6A) residues, respectively. The CH3-accepting capacity of DNA in chromatin (mono- and dinucleosomes, mono- and dinucleomers) is 15 - 30 times less than that of free total DNA in rat liver. Such a low level of DNA methylation in chromatin in vitro suggests that the accessibility and recognition of methylation sites by DNA-methylases are decreased in comparison with free DNA both in the core-particle DNA and in the internucleosomal DNA. The degree of DNA methylation in chromatin particles depends on the ionic strength and Mg2+; when the former is decreased from 0.515 down to 0.176, the DNA methylation by both enzymes is increased 2-fold. An addition of Mg2+ (1 - 2 mM) decreases the CH3-accepting capacity of nucleomeric DNA, that of nucleosomal DNA remains unchanged. Thus, the accessibility of DNA for methylases is variable depending on the conformational changes of chromatin. The values of the m6A to m5C ratio for free and nucleosomal DNAs formed by methylation with a methylation of nucleomeric DNA, i. e. 1.01, 0.92 and 0.51, respectively. As Mg/4 concentration rises, the m6A/m5C ratio for nucleosomal and nucleomeric DNA is increased. It seems therefore that at different levels of organization and upon certain conformation changes the number and, probably, the nature of exposed DNA methylation sites in chromatin are different. Bacterial DNA-methylases can be used as an effective probe for a fine analysis of chromatin ultrastructure, in particular at its different functional states.     

Development of Escherichia coli virus T1: escape from host restriction.

The bacterial virus T1 grows interchangeably on different Escherichia coli strains (C, B, and K). This implies that T1 has an efficient mechanism to overcome the host restriction barrier. The DNA of T1 was found to be methylated independently of the hosts. The percentage of N6-methyladenine varied from 1.6 to 1.8, and the 5-methylcytosine content varied from 0.1 to 0.4%. In contrast, the range in percentage of N6-methyladenine and 5-methylcytosine found in the hosts was 0.7 to 2.4 and 0.0 to 1.1, respectively.     

N4-methylcytosine as a minor base in bacterial DNA.

The DNA base composition, including the minor base content, of 26 strains of bacteria was determined. The studied bacteria are sources of widely used restriction endonucleases. Approximately 35% of the bacterial DNAs contained N4-methylcytosine, about 60% contained 5-methylcytosine, and about 90% had N6-methyladenine.     

5-Methylcytosine in Chlorelle pyrenoidosa DNAs.

The presence of 5-methylcytosine in Chlorella pyrenoidosa (strain 211/8b) DNA's has been investigated by means of paper chromatography and thermal chromatography on hydroxyapatite. It has been shown that nuclear DNA contains 3.5 mol% 5-methylcytosine whereas no significant amount of this base can be detected in chloroplast DNA. The thermal chromatography of nuclear DNA labelled from [6-3H]- or [Me-14C] methionine lead us to conclude that the 5-methylcytosine content is directly proportional to the G + C content of the various DNA fractions. The existence of methylated sequences in DNA is postulated and the biological function of the 5-methylcytosine is discussed.     

Differential binding of Escherichia coli McrA protein to DNA sequences that contain the dinucleotide m5CpG

The Escherichia coli McrA protein, a putative C⁵-methylcytosine/C⁵-hydroxyl methylcytosine-specific nuclease, binds DNA with symmetrically methylated HpaII sequences (Cm5CGG), but its precise recognition sequence remains undefined. To determine McrA’s binding specificity, we cloned and expressed recombinant McrA with a C-terminal StrepII tag (rMcrA-S) to facilitate protein purification and affinity capture of human DNA fragments with m5C residues. Sequence analysis of a subset of these fragments and electrophoretic mobility shift assays with model methylated and unmethylated oligonucleotides suggest that N(Y > R) m5CGR is the canonical binding site for rMcrA-S. In addition to binding HpaII-methylated double-stranded DNA, rMcrA-S binds DNA containing a single, hemimethylated HpaII site; however, it does not bind if A, C, T or U is placed across from the m5C residue, but does if I is opposite the m5C. These results provide the first systematic analysis of McrA’s in vitro binding specificity.     

Human placental DNA methyltransferase: DNA substrate and DNA binding specificity

We have partially purified a DNA methyltransferase from human placenta using a novel substrate for a highly sensitive assay of methylation of hemimethylated DNA. This substrate was prepared by extensive nick translation of bacteriophage XP12 DNA, which normally has virtually all of its cytosine residues replaced by 5-methylcytosine (m5C). Micrococcus luteus DNA was just as good a substrate if it was first similarly nick translated with m5dCTP instead of dCTP in the polymerization mixture. At different stages in purification and under various conditions (including in the presence or absence of high mobility group proteins), the methylation of m5C-deficient DNA and that of hemimethylated DNA were compared. Although hemimethylated , m5C-rich DNAs were much better substrates than were m5C-deficient DNAs and normal XP12 DNA could not be methylated, all of these DNAs were bound equally well by the enzyme. In contrast, from the same placental extract, a DNA-binding protein of unknown function was isolated which binds to m5C-rich DNA in preference to the analogous m5C-poor DNA.     

The stability of oligodeoxyribonucleotide duplexes containing degenerate bases.

Oligodeoxyribonucleotides containing N4-methoxycytosine (mo4C), N4-methoxy-5-methylcytosine (mo4m5C) and other base-analogues were synthesised and used to compare the stabilities of duplexes containing mo4C.A and mo4C.G base pairs with those containing normal and mismatch pairs. The Tm values and other thermodynamic parameters are recorded. The otherwise identical duplexes containing a mo4C.A and a mo4C.G base pair have closely similar stabilities to each other and to the corresponding duplexes containing normal base pairs, considerably greater than the stabilities of those containing mismatch pairs. Corresponding observations are recorded in dot-blot experiments using M13 cloned DNA carrying an insert complementary to the oligonucleotides; approximate Td values are given.     

蓬勃发展的表观转录组学

迄今为止,研究者们在RNA上已经发现了百余种不同种类的化学修饰,这些修饰大都分布在丰度较高的非编码RNA中,并对非编码RNA功能的维持具有重要作用.近年来,得益于高分辨率质谱的应用以及全转录组测序技术的开发,越来越多的mRNA上的修饰被发现、精确定量和定位,包括N6-甲基腺嘌呤(m6A)、N6,2-O-二甲基腺嘌呤(m...     

Oxidatively generated damage to DNA at 5-methylcytosine mispairs

Oxidatively generated damage to DNA has been implicated as causing mutations that lead to aging and disease. The one-electron oxidation of normal DNA leads to formation of a nucleobase radical cation that hops through the DNA until it is trapped irreversibly, primarily by reaction at guanine. It has been observed that 5-methylcytosine (C(m)) is a mutational "hot-spot". However, C(m) in a Watson-Crick base pair with G is not especially susceptible to oxidatively induced damage. Radical cation hopping is inhibited in duplexes that contain C-A or C-T mispairs, but no reaction is detected at cytosine. In contrast, we find that the one-electron oxidation of DNA that contains C(m)-A or C(m)-T mispairs results primarily in reaction at C(m) even in the presence of GG steps. The reaction at C(m) is attributed to proton coupled electron transfer, which provides a relatively low activation barrier path for reaction at 5-methylcytosine. This enhanced reactivity of C(m) in mispairs may contribute to the formation of mutational hot spots at C(m).     

Measurement of DNA methylation using stable isotope dilution and gas chromatography-mass spectrometry

A simple, highly selective, and sensitive method has been developed to quantify methylation of DNA extracted from human peripheral blood mononuclear cells. Assay has been performed at nucleobases level. Cytosine and 5-methylcytosine DNA content has been detected by gas chromatography-mass spectrometry using [2-(13)C]cytosine and [2-(13)C]5-methylcytosine as internal standards. The methylation level has been calculated as 5-methylcytosine/total cytosine ratio. The working range selected on calibration curve, obtained by evaluation of standards and matrix-added standards measurements, is suitable for 5 microg DNA analysis. In this range, healthy human DNA methylation percentage is within 5-6%.     

Characterization of DNA methyltransferase specificities using single-molecule, real-time DNA sequencing

DNA methylation is the most common form of DNA modification in prokaryotic and eukaryotic genomes. We have applied the method of single-molecule, real-time (SMRT®) DNA sequencing that is capable of direct detection of modified bases at single-nucleotide resolution to characterize the specificity of several bacterial DNA methyltransferases (MTases). In addition to previously described SMRT sequencing of N6-methyladenine and 5-methylcytosine, we show that N4-methylcytosine also has a specific kinetic signature and is therefore identifiable using this approach. We demonstrate for all three prokaryotic methylation types that SMRT sequencing confirms the identity and position of the methylated base in cases where the MTase specificity was previously established by other methods. We then applied the method to determine the sequence context and methylated base identity for three MTases with unknown specificities. In addition, we also find evidence of unanticipated MTase promiscuity with some enzymes apparently also modifying sequences that are related, but not identical, to the cognate site.     

The methylomes of six bacteria

Six bacterial genomes, Geobacter metallireducens GS-15, Chromohalobacter salexigens, Vibrio breoganii 1C-10, Bacillus cereus ATCC 10987, Campylobacter jejuni subsp. jejuni 81-176 and C. jejuni NCTC 11168, all of which had previously been sequenced using other platforms were re-sequenced using single-molecule, real-time (SMRT) sequencing specifically to analyze their methylomes. In every case a number of new N⁶-methyladenine (^m6A) and N⁴-methylcytosine (^m4C) methylation patterns were discovered and the DNA methyltransferases (MTases) responsible for those methylation patterns were assigned. In 15 cases, it was possible to match MTase genes with MTase recognition sequences without further sub-cloning. Two Type I restriction systems required sub-cloning to differentiate their recognition sequences, while four MTase genes that were not expressed in the native organism were sub-cloned to test for viability and recognition sequences. Two of these proved active. No attempt was made to detect 5-methylcytosine (^m5C) recognition motifs from the SMRT® sequencing data because this modification produces weaker signals using current methods. However, all predicted ^m6A and ^m4C MTases were detected unambiguously. This study shows that the addition of SMRT sequencing to traditional sequencing approaches gives a wealth of useful functional information about a genome showing not only which MTase genes are active but also revealing their recognition sequences.     

Methylation of parental and progeny DNA strands in Physarum polycephalum

Although 5-methylcytosine comprises 4 to 8% of the cytosine residues in the major nuclear DNA of Physarum polycephalum (Evans &; Evans, 1970), only 1 % of the cytosine residues of progeny DNA become methylated during replication. Further methylation occurs during the same and subsequent mitotic cycles, so that 6 to 7 cycles after its synthesis, 5-methylcytosine comprises 5 to 7% of the DNA-cytosine residues of a single generation of DNA. The extent of methylation occurring during the S period has been measured by the determination of the specific activity of the precursor (S-adenosylmethionine) and the product (DNA-5-methylcytosine) and by comparison of the radioactivity in DNA-cytosine and DNA-5-methylcytosine after incorporation of [¹⁴C]deoxycytidine. Continuing methylation of parental DNA has been shown, by density shift experiments and by the conversion of prelabeled DNA-cytosine to DNA-5-methylcytosine. The DNA-5-methylcytosine once formed was found to be stable.