PAGE separation of hemi-methylated or unmethylated oligonucleotide substrates to distinguish between maintenance and de novo DNA methyltranferase activity

DNA methyltransferase (DNMT) enzymes catalyze the addition of a methyl group to cytosine residues in DNA. Appropriate cytosine methylation of CpG dinucleotides is required for normal mammalian development and homeostasis, and quantitative methods are necessary to assess DNMT activity in various cell extracts. The method described in this report utilizes incorporation of S-[methyl-(3)H]-adenosyl-L-methionine into hemi-methylated or unmethylated oligonucleotides to distinguish between maintenance and de novo DNMT activity, respectively. However, unlike previously described methods, this protocol uses native polyacrylamide gel electrophoresis to detect the incorporation of radioactivity into substrate oligonucleotides. This approach distinguishes between incorporation of radioactivity into target substrate oligonucleotides and incorporation into non-specific cellular DNA that often contaminates nuclear extracts, and permits the reproducible quantitation and comparison of de novo and maintenance DNMT activities in various cell lines. Electrophoretic separation of the methylated substrates is a cost-effective, specific, and reproducible approach to quantitate DNMT activities in nuclear extracts.     

Specificity of methylation of cytosine risidues in DNA of Bacillus brevis var. G-B]

On growing the cells of Bacillus brevis S methionine-auxotroph mutant in the presence of (methyl-3H)-methionine practically the total radioactivity included into DNA is found to exist in 5-methylcytosine (MC) and 6N-methyladenine (MA). The analysis of pyrimidine isopliths isolated from DNA shows that radioactivity only exists in mono- and dinucleotides and the content of MC in Pur-MC-Pur and Pur-MC-T-Pur oligonucleotides is equal. The analysis of dinucleotides isolated from DNA by means of pancreatic DNAase hydrolysis allows the nature of purine residues neighbouring with MC to be revealed and shows that MC localizes in G-MC-A and G-MC-T-Pu fragments. Bac. brevis S DNA-methylase modifying cytosine residues recognizes the GCAT GC degenerative nucleotide sequence which is a part of the following complementary structure with rotational symmetry: (5') ... N'--G--MC--T--G--C--N ... (3') (3') ... N--C--G--A--MC--G--N' ... (5') Cytosine modifying DNA-methylase activity is isolated from Bac. brevis cells; it is capable of methylating in vitro homologous and heterologous DNA. Hence, DNA in bacterial cells can be partially undermethylated. This enzyme methylates cytosine residues in native and deneaturated DNA in the same nucleotide sequences. As compared to the native DNA, the denaturated DNA is indicative of a decrease in the level of methylation of adenine, rather than cytosine residues. Specificity of methylation of cytosine residues in vitro and in vivo does not depend on the nature of substrate DNA (calf thymus, Pseudomonas aeruginosa etc.). DNA-methylases of different variants of Bac. brevis (R, S, P+, P-) methylate cytosine residues in the same nucleotide sequences. It means that specificity of methylation of DNA cytosine residues in the cells of different variants of Bac. brevis is the same.     

Immunospecific retention of oligonucleotides possessing N6-methyladenosine and 7-methylguanosine.

Antibodies specific for N6-methyladenosine (m6A) and for 7-methylguanosine (m7G) were immobilized on Sepharose and the resulting immunoadsorbents tested for their ability to retain specific oligonucleotides possessing the corresponding antigenic haptens (i.e. m6A and m7G). Results obtained with oligonucleotides derived from ribonuclease T1 digests of Escherichia coli tRNA (previously labeled with [methyl-3H]methionine) indicated that each immunoadsorbent quantitatively and exclusively retained those methyl-3H-labeled oligonucleotides possessing [methyl-3H]m6A and [methyl-3H]m7G. Elution and subsequent characterization of the retained methyl-3H-labeled oligonucleotides via DEAE-cellulose chromatography revealed the presence of several small oligonucleotides containing m7G and a single, larger oligonucleotide containing m6A. These findings are in accord with previously sequenced structures which indicate that numerous bacterial tRNA species possess m7G while only tRNAVal contains m6A.     

The molecular basis for biological inactivation of nucleic acids. The action of methylating agents on the ribonucleic acid-containing bacteriophage R17

1. The inactivation of an RNA-containing bacteriophage after reaction with four methylating agents was studied. Measurements of the extent of methylation of the RNA and of the nature and amounts of the various reaction products were made. In experiments with dimethyl sulphate and methyl methanesulphonate inactivation can be quantitatively accounted for by methylation at two of the positions involved in hydrogen bonding: N-1 of adenine and N-3 of cytosine. In experiments with N-methyl-N-nitrosourea and N-methyl-N'-nitro-N-nitrosoguanidine methylation at N-1 of adenine and N-3 of cytosine accounts for only about one-half of the observed inactivation. Scission of the RNA chain during reaction accounts for a further 20% of the inactivation. To account for the remainder it seems necessary to postulate that formation of O(6)-methylguanine constitutes a lethal lesion. 2. Breaks in the RNA chain formed on reaction with the nitroso derivatives presumably result from methylation of the phosphate diester group followed by hydrolysis of the unstable triester thus formed.     

Repair of O(6)-methylguanine is not affected by thymine base pairing and the presence of MMR proteins

Methylation at the O(6)-position of guanine (O(6)-MeG) by alkylating agents is efficiently removed by O(6)-methylguanine-DNA methyltransferase (MGMT), preventing from cytotoxic, mutagenic, clastogenic and carcinogenic effects of O(6)-MeG-inducing agents. If O(6)-MeG is not removed from DNA prior to replication, thymine will be incorporated instead of cytosine opposite the O(6)-MeG lesion. This mismatch is recognized and processed by mismatch repair (MMR) proteins which are known to be involved in triggering the cytotoxic and genotoxic response of cells upon methylation. In this work we addressed three open questions. (1) Is MGMT able to repair O(6)-MeG mispaired with thymine (O(6)-MeG/T)? (2) Do MMR proteins interfere with the repair of O(6)-MeG/T by MGMT? (3) Does MGMT show a protective effect if it is expressed after replication of DNA containing O(6)-MeG? Using an in vitro assay we show that oligonucleotides containing O(6)-MeG/T mismatches are as efficient as oligonucleotides containing O(6)-MeG/C in competing for MGMT repair activity, indicating that O(6)-MeG mispaired with thymine is still subject to repair by MGMT. The addition of MMR proteins from nuclear extracts, or of recombinant MutSalpha, to the in vitro repair assay did not affect the repair of O(6)-MeG/T lesions by MGMT. This indicates that the presence of MutSalpha still allows access of MGMT to O(6)-MeG/T lesions. To elucidate the protective effect of MGMT in the first and second replication cycle after N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) treatment, MGMT transfected CHO cells were synchronized and MGMT was inactivated by pulse-treatment with O(6)-benzylguanine (O(6)-BG). Thereafter, the recovered cells were treated with MNNG and subjected to clonogenic survival assays. Cells which expressed MGMT in the first and second cell cycle were more resistant than cells which expressed MGMT only in the second (post-treatment) cell cycle. Cells which did not express MGMT in both cell cycles were most sensitive. This indicates that repair of O(6)-MeG can occur both in the first and second cell cycle after alkylation protecting cells from the killing effect of the lesion.     

Determination of methylation specificity of DsaV methyltransferase by a simple biochemical method.

We have developed a simple new method that can identify the base methylated by a sequence-specific DNA methyltransferase and have used it to identify the cytosine that is methylated by DsaV methyltransferase (M. DsaV) within its recognition sequence 5'-CCNGG. The method utilizes the fact that exonuclease III of E. coli does not degrade DNA ends with 3' overhangs and cannot hydrolyze a phosphorothioate linkage. DNA duplexes containing phosphorothioate linkages at specific positions were methylated with M. DsaV in the presence of [methyl-3H] S-adenosylmethionine and were subjected to exonuclease III digestion. The pattern of [methyl-3H] dCMP release from the duplexes was consistent with the methylation of the internal cytosine in CCNGG, but not of the outer cytosine. To establish the accuracy of this method, we confirmed the known specificity of EcoRII methyltransferase by the method. We also confirmed the specificity of M. DsaV using an established biochemical method that involves the use of a type IIS restriction enzyme. Methylation of CCWGG (W = A or T) sequences at the internal cytosines is native to E. coli and is not restricted by the modified cytosine restriction (Mcr) systems. Surprisingly, the gene for M. DsaV was significantly restricted by the McrBC system. We interpret this to mean that M. DsaV may occasionally methylate at sequences other than CCNGG or may occasionally methylate the outer cytosine in its recognition sequence.     

Methylation of ribonucleic acid by the carcinogens dimethyl sulphate, N-methyl-N-nitrosourea and N-methyl-N′-nitro-N-nitrosoguanidine. Comparisons of chemical analyses at the nucleoside and base levels

1. The following methods for hydrolysis of methyl-(14)C-labelled RNA, and for chromatographic isolation and determination of the products, were investigated: enzymic digestion to nucleosides at pH6 or 8; alkaline hydrolysis and conversion into nucleosides; hydrolysis by acid to pyrimidine nucleotides and purine bases, or completely to bases; chromatography on Dowex 50 (NH(4) (+) form) at pH6 or 8.9, or on Dowex 50 (H(+) form), or on Sephadex G-10. 2. The suitability of the various methods for determination of methylation products was assessed. The principal product, 7-methylguanosine, was unstable under the conditions used for determinations of nucleosides. 3- and 7-Methyladenine and 3- and 7-methylguanine are best determined as bases; 1-methyladenine and 3-methylcytosine can be isolated as either nucleosides or bases; O(6)-methylguanine is unstable under the acid hydrolysis conditions used and can be determined as the nucleoside; 3-methyluracil was detected, but may be derived from methylation of the ionized form of uracil. 3. Differences between the patterns of methylation of RNA and homopolyribonucleotides by the N-methyl-N-nitroso compounds and dimethyl sulphate were found: the nitroso compounds were able to methylate O-6 of guanine, were relatively more reactive at N-7 of adenine and probably at N-3 of guanine, but less reactive at N-1 of adenine, N-3 of cytosine and probably at N-3 of uridine. They probably reacted more with the ribose-phosphate chain, but no products from this were identified. 4. The possible influences of these differences on biological action of the methylating agents is discussed. Nitroso compounds may differ principally in their ability to induce miscoding in the Watson-Crick sense by reaction at O-6 of guanine. Both types of agent may induce miscoding to a lesser extent through methylation at N-3 of guanine; both can methylate N atoms, presumably preventing Watson-Crick hydrogen-bonding. N-Methyl-N-nitrosourea can degrade RNA, possibly through phosphotriester formation, but this mechanism is not proven.     

Mechanism of CpG DNA methyltransferases M.SssI and Dnmt3a studied by DNA containing 2-aminopurine

Murine DNA methyltransferases Dnmt3a-CD and M.SssI from Spiroplasma methylate cytosines at CpG sites. The role of 6-oxo groups of guanines in DNA methylation by these enzymes has been studied using DNA substrates, which contained 2-aminopurine at different positions. Removal of the 6-oxo group of the guanine located adjacent to the target cytosine in the CpG site dramatically reduces the stability of the methyltransferase-DNA complexes and leads to a significant decrease in the methylation. Apparently, O6 of this guanine is involved in the recognition of CpG sites by the enzymes. Cooperative binding of Dnmt3a-CD to 2-aminopurine-containing DNA and the formation of nonproductive enzyme-substrate complexes were observed.     

Mutants of the N-3 R-Factor Conditionally Defective in hspII Modification and Deoxyribonucleic Acid-Cytosine Methylase Activity

The N-3 drug resistance (R) factor specifies a deoxyribonucleic acid (DNA)-cytosine methylase and a DNA restriction-modification (hspII) system. We have isolated three independent mutants that are conditionally defective in their ability to modify bacteriophage lambda and to methylate DNA-cytosine residues. The ratio of 5-methylcytosine to N(6)-methyladenine in bacterial DNA and in the DNA of phages lambda and fd was determined after labeling with [methyl-(3)H]methionine at various growth temperatures. Although the ability of the wild-type N-3 factor to modify phage lambda and to methylate DNA-cytosine residues was unaffected with increasing temperature, two of the mutants exhibited a parallel loss in modification and cytosine methylation ability. The ability of the third mutant to carry out these functions was dependent on the presence or absence of an amber suppressor mutation in the host genome. These results offer further support for the notion that hspII modification is mediated by a DNA-cytosine methylase. Evidence is also presented that the modification methylase is responsible for the in vivo methylation of phage fd DNA (which is not subject to hspII restriction in vivo).     

Mechanism of CpG DNA Methyltransferases M.SssI and Dnmt3a Studied by DNA Containing 2-Aminopurine

Murine DNA methyltransferases Dnmt3a-CD and M.SssI from Spiroplasma methylate cytosines at CpG sites. The role of 6-oxo groups of guanines in DNA methylation by these enzymes has been studied using DNA substrates, which contained 2-aminopurine at different positions. Removal of the 6-oxo group of the guanine located adjacent to the target cytosine in the CpG site dramatically reduces the stability of the methyltransferase–DNA complexes and leads to a significant decrease in the methylation. Apparently, O6 of this guanine is involved in the recognition of CpG sites by the enzymes. Cooperative binding of Dnmt3a-CD to 2-aminopurine-containing DNA and the formation of nonproductive enzyme–substrate complexes were observed.     

Direct electrochemical detection of DNA methylation for retinoblastoma and CpG fragments using a nanocarbon film

We describe the direct electrochemical detection of DNA methylation in relatively long sequences by using a nanocarbon film electrode. The film was formed by employing the electron cyclotron resonance sputtering method and had a nanocrystalline sp² and sp³ mixed bond structure. Our methylation detection technique measures the differences between the oxidation currents of both 5-methylcytosine and cytosine without a bisulfite reaction or labeling. This was possible because this film electrode has a wide potential window while maintaining the high electrode activity needed to quantitatively detect both bases by direct oxidation. By optimizing the electrode surface conditions using electrochemical pretreatment, we used this film to quantitatively detect single cytosine methylation regardless of the methylation position in the sequence including retinoblastoma gene fragments (∼24mers). This was probably due to the high stability of this film electrode, which we achieved by controlling the surface hydrophilicity to suppress the fouling, and by maintaining electrode activity against all the bases. The pH optimization of the oligonucleotide measurements was also useful for distinguishing both bases separately. Under the optimized conditions, this film electrode allowed us to realize the quantitative detection of DNA methylation ratios solely by measuring methylated 5′-cytosine-phosphoguanosine (CpG) repetition oligonucleotides (60mers) with different methylation ratios.     

Sites of methylation of DNA bases by the action of organophosphorus insecticides in vitro

Methylation in vitro of DNA by three methyl-14C-labelled organophosphorus insecticides has been studied. The ability of methylbromphenvinphos, methylparathion and malathion to methylate N-7 of guanine in DNA can be expressed as 100:40:15. Among the methylation products, no O6-methylguanine, a known mutagen, was found. Both in the reaction with dsDNA and with ssDNA 7-methyl-guanine was the main methylation product. However, all methyl derivatives of adenine (3-methyladenine, 1-methyladenine and 7-methyladenine) constituted about 40% and 50% of all methylation products in the case of dsDNA and ssDNA, respectively. The only methyl derivative of pyrimidine we have identified was 3-methylcytosine. In the case of dsDNA 3-methylcytosine appeared in small amounts but in the alkylated ssDNA 3-methylcytosine C constituted about 20% of all alkylation products.     

Revealing structural peculiarities of homopurine GA repetition stuck by i-motif clip

Non-canonical forms of nucleic acids represent challenging objects for both structure-determination and investigation of their potential role in living systems. In this work, we uncover a structure adopted by GA repetition locked in a parallel homoduplex by an i-motif. A series of DNA oligonucleotides comprising GAGA segment and C₃ clip is analyzed by NMR and CD spectroscopies to understand the sequence–structure–stability relationships. We demonstrate how the relative position of the homopurine GAGA segment and the C₃ clip as well as single-base mutations (guanine deamination and cytosine methylation) affect base pairing arrangement of purines, i-motif topology and overall stability. We focus on oligonucleotides C₃GAGA and methylated GAGAC₃ exhibiting the highest stability and structural uniformity which allowed determination of high-resolution structures further analyzed by unbiased molecular dynamics simulation. We describe sequence-specific supramolecular interactions on the junction between homoduplex and i-motif blocks that contribute to the overall stability of the structures. The results show that the distinct structural motifs can not only coexist in the tight neighborhood within the same molecule but even mutually support their formation. Our findings are expected to have general validity and could serve as guides in future structure and stability investigations of nucleic acids.     

Recognition of unusual DNA structures by human DNA (cytosine-5)methyltransferase

The symmetry of the responses of the human DNA (cytosine-5)methyltransferase to alternative placements of 5-methylcytosine in model oligodeoxynucleotide duplexes containing unusual structures has been examined. The results of these experiments more clearly define the DNA recognition specificity of the enzyme. A simple three-nucleotide recognition motif within the CG dinucleotide pair can be identified in each enzymatically methylated duplex. The data can be summarized by numbering the four nucleotides in the dinucleotide pair thus: 1 4/2 3. With reference to this numbering scheme, position 1 can be occupied by cytosine or 5-methylcytosine; position 2 can be occupied by guanosine or inosine; position 3, the site of enzymatic methylation, can be occupied only by cytosine; and position 4 can be occupied by guanosine, inosine, O6-methylguanosine, cytosine, adenosine, an abasic site, or the 3' hydroxyl group at the end of a gapped molecule. Replacing the guanosine normally found at position 4 with any of the moieties introduces unusual (non-Watson-Crick) pairing at position 3 and generally enhances methylation of the cytosine at that site. The exceptional facility of the enzyme in actively methylating unusual DNA structures suggests that the evolution of the DNA methyltransferase, and perhaps DNA methylation itself, may be linked to the biological occurrence of unusual DNA structures.     

Effect of a single treatment with the alkylating carcinogens dimethylnitrosamine and methyl methanesulphonate on liver regenerating after partial hepatectomy. IV. Effect on methylase-mediated methylation of DNA.

The possibility that carcinogens may affect methylase-mediated methylation of replicating DNA was investigated. A system eminently suitable for this purpose is liver regenerating after partial hepatectomy, as one injection of dimethylnitrosamine (DMN) given during the ensuing period of increased DNA synthesis induces hepatocellular carcinoma. Methylation of DNA by DNA methylase normally occurs only in proportion to DNA synthesis. Therefore simultaneous measurements were made of synthesis (incorporation of [14C]adenine into DNA adenine, or of d[5-3H]cytidine into DNA cytosine), and of methylation (incorporation of [methyl-3H]methionine into 5-methylcytosine of DNA) in liver regenerating after partial hepatectomy. After treatment with DMN, the ratio of methylation: synthesis remained within the normal range. Methyl methanesulphonate (MMS), a compound which damages DNA in regenerating liver in a similar but not identical way to DMN and which does not induce tumors in liver even when given after partial hepatectomy, caused an increase in methylation in relation to synthesis. These experiments therefore do not support the view that altered DNA methylase activity is involved in carcinogenesis.     

Non-enzymatic DNA methylation by S-adenosylmethionine results in the formation of minor thymine residues and 5-methylcytosine from cytosine

It was found that nonenzymatic DNA methylation proceeds in water solution in the presence of S-adenosylmethionine (AdoMet). The main reaction products are thymine and 5-methylcytosine residues. It was shown that labelled thymine residues are formed also upon DNA incubation in the presence of [methyl-14C]methionine as well as [methyl-14C]cobalamine. Only cytosine reacts with AdoMet resulting in thymine production. AdoMet may be a potential mutagen that induces GC----AT transitions during DNA replication in the cell.