Inhibition of DNA methylation by chemical carcinogens in vitro

A diverse range of ultimate chemical carcinogens inhibited the transfer of methyl groups from S-adenosylmethionine to hemimethylated DNA in a reaction catalyzed by mouse spleen methyltransferase. The formation of alkali-labile sites in DNA lessened its ability to accept methyl groups in vitro, but the methylation reaction was much less sensitive to thymine dimers or double-strand breaks. Carcinogens induced the formation of alkali-labile DNA lesions, but the degree of methyltransferase inhibition observed was greater than that expected for this damage alone. Certain carcinogens were also capable of direct modification and inactivation of the methyltransferase enzyme. Benzo(a)pyrene treatment of living BALB/3T3 A31 clone 1-13 but not C3H/10T1/2 clone 8 cells resulted in a 12% decrease in total 5-methylcytosine content of cellular DNA. Carcinogenic agents may therefore cause heritable changes in 5-methylcytosine patterns in certain cell types by a variety of mechanisms, including adduct formation, induction of apurinic sites and single-strand breaks and direct inactivation of DNA methyltransferase.     

DNA甲基化作用与鼠肝细胞的老化

本文比较了不同年龄的鼠肝ＤＮＡ甲基化酶活力及ＤＮＡ甲基化水平,发现它们均与鼠龄呈反相关。又以不同年龄的鼠肝ＤＮＡ为模板,检验了其体外转录活力,发现其与鼠龄呈正相关。     

Effect of hydrocortisone on methylation and molecular population of DNA in rat liver]

The content of 5-methyl cytosine in rat liver DNA increases 1,7-fold 8 hours after intraperitoneal injection of hydrocortisone (5 mg per 100 g animal weight). The content of GC, physicochemical parameters (Tm, delta T, etc.) and DNA renaturation pattern did not show any changes. No changes were observed in the pattern of H3-thymidine incorporation into rat liver DNA: after hydrocortisone injection the radioactivity was found to be equally distributed in all isolated sequences of DNA, differing in the degree of reiteration (specific radioactivities of these DNA, fractions are very similar). Thus, the molecular population of DNA in liver cells remains unchanged, which suggests that the hormone-induced increase in the 5-methyl cytosine content is due to a change in the DNA methylation level. The methyation level of unique sequences (COt greater than 600), i. e. that of structural genes, does not undergo any essential changes. The reversible methylation of DNA regulated by hormones seems to be one of the mechanisms controlling gene activity.     

The effect of preparations of Hirudo medicinalis leeches on DNA methylation in the rat liver

The effect of the salivary gland secretion and dialysable part of the homogenate of the leeches Hirudo medicinalis on the methylation of DNA in the rat liver after the intraperitoneal injection and perfusion of isolated liver has been analysed. The maximum concentration of 5-methylcytosine is observed 1 h later the injection of preparations: for the salivary gland secretion the increase is 39%, for the dialysate of leech homogenate is 28%. The 5-methylcytosine content increases on 28% after the perfusion of isolated liver with the leech saliva and after the dialysate of the leech homogenate--on 20%. No other changes in DNA content is observed. It is suggested that the DNA-methylation of the liver cells is due to the penetration of biologically active substances produced by the medical leech into the cell-targets accompanied by the forming of corresponding ligand-receptor complexes.     

Hypomethylation of DNA during differentiation of friend erythroleukemia cells

DNA from mammalian cells has been shown to contain significant amounts of 5-methyl cytosine resulting from enzymatic transfer of methyl groups from s-adenosylmethionine to cytosine residues in the DNA polymer. The function of this modification is not known. We have found that DNA synthesized during chemically induced differentiation of friend erythroleukemia cells is hypomethylated, as measured by its ability to accept methyl groups transferred by homologous DNA methyltransferases in vitro. The extent of hypomethylation detected by this sensitive method is small, a decrease of less than 1.6 percent in 5-methylcytosine content. Hypomethylated DNA can be isolated from friend erythroleukemia cells grown in the presence of dimethyl sulfoxide, butyrate, hexamethylene-bis- acetamide, pentamethylene-bis acetamide, and ethionine. However, hypomethylated DNA is found only under conditions where differentiation is actually induced. DNA isolated from cells of a dimethyl sulfoxide- resistant subclone grown in the presence of that agent is not hypomethylated, although DNA of these cells becomes hypomethylated after growth in the presence of inducers that can trigger their differentiation. We also find that the DNA of friend erythroleukemia cells does not become hypomethylated when the cells are exposed to inducing agents in the presence of substances that inhibit differentiation. These results suggest a close link between genome modification by methylation and differentiation of friend erythroleukemia cells.     

Effect of vitamin B12 on liver and kidney DNA methylation in guinea pigs in the presence of methionine and ATP

Changes of 5-methylcytosine (m5C) content in DNA of guinea-pigs' liver and kidney under the influence of vitamin B12 in the presence of methionine and ATP have been studied. After B12 injection m5C quantity in liver DNA increases in 1,4 times, in kidney DNA in 1,6 times. The methionine and ATP injection lowers B12 effect on the DNA methylation in liver and kidney.     

Structure of animal mitochondrial DNA: nucleotide composition, pyrimidine clusters, and methylation character.

The nucleotide composition, relative concentration of pyrimidine clusters, and the degree of methylation of the mitochondrial and nuclear DNA's of various vertebrates and the protozoan Crithidia oncopelti have been studied. With respect to the relative concentration of GC pairs, the mtDNA of animals (bull, rat) does not differ from the corresponding nDNA. The relative concentration of GC pairs in the mtDNA of certain fish and birds is 1.5-2.5 mole% higher than in the respective nDNA. The kinetoplast DNA of the protozoan C. oncopelti (where the relative concentration of the GC pairs is 42.9 mole %) differs very sharply in composition from the nDNA (where the relative concentration of GC pairs is 51.3 mole %). The mtDNA's and kDNA's studied are distinguished from the respective nDNA'S by a lower degree of clustering of pyrimidine nucleotides. The proportion of mono- and dipyrimidine fragments in the mtDNA and kDNA is 30 mole %, while in the nDNA it does not exceed 23 mole %. The relative concentration of long pyrimidine clusters (hexapyrimidine clusters of larger) in the mtDNA is smaller than in the nDNA by a factor of 2-5. The low degree of clustering of the pyrimidine nucleotides is apparently characteristic of all the known mtDNA's and may support the fact that they have a single type of organization and are of a single origin. All the vertebrate mtDNA's studied contain 5-methylcytosine as a minor base (1.5-3.15 mole %), and their level of methylation is 1.5-2 times greater than that in the respective nDNA's. It has been shown that animals display species specificity with respect to the 5-methylcytosine content in the mtDNA. Its distribution among the pyrimidine clusters in the bovine heart mtDNA differs substantially from that in the nDNA. This suggests that the methylation specificities of nuclear and mitochondrial DNA are different. A DNA methylase, which effects the in vitro methylation of cytosine residues both in the homologous mtDNA and in different heterologous DNA's, has been found in rat liver and bovine heart mitochondria. The specificity of the in vitro methylation of the cytosine residues in the same heterologous Escherichia coli B DNA by the nuclear and mitochondrial enzymes is different: The mitochondrial enzyme methylates predominantly in monopyrimidine fragments, and the nuclear enzyme methylates mostly in di- and tripyrimidine fragments. They, therefore, recognize different nucleotide sequences.     

DNA modification, differentiation, and transformation

Substantial evidence has accumulated over the last 5 years that the methylation of cytosine residues in vertebrate DNA is implicated in the control of gene expression. We have used analogs of cytidine, modified in the 5 position, as specific inhibitors of DNA methylation to probe the relationship between this process and cellular differentiation. 5-Azacytidine effected marked changes in the differentiated state of cultured cells and induced the formation of biochemically differentiated muscle, fat, and chondrocytes from mouse fibroblast cell lines. Since the analog is a powerful inhibitor of DNA methylation, we suggest that this inhibition is causally related to the mechanism of phenotypic conversion. DNA extracted from cells treated with 5-azacytidine was hemimethylated and was used as an efficient acceptor of methyl groups in an in vitro reaction in the presence of eukaryotic methylases. In vitro methylation was inhibited if the substrate DNA was preincubated with a diverse range of chemical carcinogens including benzo(a)pyrene diolepoxide. Thus, chemical carcinogens may induce changes in gene expression by alteration of cellular methylation patterns. Recent experiments have also demonstrated that freshly explanted diploid fibroblasts from mice, hamsters, and humans lose substantial quantities of 5-methylcytosine during cell division and aging in culture. Taken together, these experiments suggest that the genomic distribution of 5-methylcytosine might have importance in normal differentiation and also in the aberrant gene expression found in cancer and senescence in culture.     

Isolation of Deoxyribonucleic Acid Methylase Mutants of Escherichia coli K-12

Fourteen deoxyribonucleic acid (DNA) and 10 ribonucleic acid (RNA) methylation mutants were isolated from Escherichia coli K-12 by examining the ability of nucleic acids prepared from clones of unselected mutagenized cells to accept methyl groups from wild-type crude extract. Eleven of the DNA methylation mutants were deficient in 5-methylcytosine (5-MeC) and were designated Dcm. Three DNA methylation mutants were deficient in N(6)-methyladenine (N(6)-MeA) and were designated Dam. Extracts of the mutants were tested for DNA-cytosine:S-adenosylmethionine and DNA-adenine:S-adenosylmethionine methyltransferase activities. With one exception, all of the mutants had reduced or absent activity. A representative Dcm mutation was located at 36 to 37 min and a representative Dam mutation was located in the 60-to 66-min region on the genetic map. The Dcm mutants had no obvious associated phenotypic abnormality. The Dam mutants were defective in their ability to restrict lambda. None of the mutations had the effect of being lethal.     

Mechanism of action of rat liver DNA methylase. I. Interaction with double-stranded methyl-acceptor DNA

Rat liver DNA methylase forms two types of complexes with DNA which are distinguishable on the basis of their sensitivity to ionic strength. A weak complex which is dissociable by 0.2 m-NaCl is formed at 0 °C. A more tightly bound complex which is stable to 0.2 m-NaCl is formed at higher temperatures. On the basis of a comparison of the effects of salt upon tight complex formation and upon enzyme activity, it would appear that formation of the tightly bound complex is required for DNA methylation to occur. With tightly bound enzyme the methylation of high molecular weight DNA is nearly linear for 30 minutes in the presence of salt. Under the same conditions low molecular weight DNA's give non-linear kinetics which demonstrate a sharp reduction in the rate of methylation with time. The lower the molecular weight of the DNA fragments, the more marked is the deviation from linearity. On the basis of these data it is suggested that rat liver DNA cytosine-methylase which is tightly bound to DNA is able to accomplish several methyl group transfers without becoming detached from the DNA and that the enzyme must therefore walk along the DNA helix. We calculate that the walk is probably not random, but linear, and that the rate of walk may be about 1.5 to 3.5 base pairs per second.     

In vitro methylation of total and foldback DNAs in normal and virus-transformed cells

The levels of the in vitro methylation of total and palindromic DNAs in nuclei isolated from normal and virus-transformed cells are compared. The methylation rate of total DNA in normal rat kidney cells is much higher than that detected in normal mouse fibroblasts. However, for both cell species, while the maximal rate of DNA methylation is observed in the mid-logarithmic phase of the cell culture growth, palindromes are always found to be more heavily methylated than total DNA. The 5-methylcytosine content of DNA, especially of palindromes, is higher in virus-transformed cells than in untransformed cells.     

Celebrating the discovery of DNA demethylase

Maintaining correct DNA methylation patterns entails the addition of methyl groups by DNA methyltransferases and the active removal of methylation from DNA. Removing a methyl group from 5-methylcytosine requires breaking a strong C–C bond, suggesting that demethylation might occur by an alternative mechanism that does not involve severing this bond. Indeed, the discovery of the 5-methylcytosine DNA glycosylase (also known as DNA demethylase) REPRESSOR OF SILENCING 1 (ROS1) by (Gong et al., 2002) revolutionized thinking in this field, as the study of ROS1 revealed a mechanism by which 5-methylcytosine is excised and replaced by the DNA repair machinery. This special issue celebrates the 20th anniversary of the discovery of ROS1 and the remarkable research that followed.     

5-Methylcytosine content of rat hepatoma DNA substituted with bromodeoxyuridine.

The aim of these experiments was to test whether incorporation of bromodeoxyuridine into DNA affects DNA methylation. Rat hepatoma (HTC) cells in culture were labeled for two generations with [14C]bromodeoxyuridine and [3H]thymidine to yield DNA which was 2.1, 20.6, 52.6, and 95.0% bromodeoxyuridine-substituted in the newly made strands. The DNA then was fractionated into highly repetitive, moderately repetitive, and single copy sequences. As determined by a comparison of 14C and 3H counts per min, the percentage of substitution with bromodeoxyuridine was found to be the same in each repetition class. The 5-methylcytosine content of each fraction was determined using high pressure liquid chromatography. It was found that bromodeoxyuridine, even at a level of substitution into newly mad DNA of 95%, has no effect on the 5-methylcytosine content of DNA. At all levels of bromodeoxyuridine substitution, highly repetitive DNA has slightly more 5-methylcytosine (3.0% of total cytosine) than does single copy DNA or moderately repetitive DNA (2.3%). The 5-methylcytosine content of whole HTC DNA is the same as that of rat liver DNA (2.4%).     

Isolation of mitochondrial DNA, purified of nuclear DNA, from animal tissues (degree of methylation and level of pyrimidine nucleotide clustering--criteria of purity)]

A method of preparation of mitochondria free of nuclear DNA and its fragments by treatment of mitochondria with DEAE-cellulose has been developed. This method is based on binding nuclear nucleic acids and nucleoproteins to DEAE-cellulose particles in the media used for isolation of mitochondria. Treatment with DEAE-cellulose under the conditions described does not induce any visible degradation of mitochondria and mitochondrial DNA. The mitochondrial DNA preparations obtained from beef and rat liver are represented with closed circular molecules of contour length about 5.5 mu. The 5-methylcytosine content in beef and rat mitochondrial DNA (3.03 and 2.0 mole %, respectively) is twice as much as in corresponding nuclear DNA. Besides, mitochondrial DNA strongly differs from nuclear ones by a lower degree of pyrimidine clustering: the amount of mono- and dipyrimidine fragments (about 32 mole %) in mitochondrial DNA is 1.5 times as large and the content of long pyrimidine clusters (hexa- and others) is 2--4 times as low as those in nuclear DNA. The methylation level and the pyrimidine clustering degree may be used as criteria for the purity of mitochondrial DNA from nuclear DNA.     

DNA-methylase activities from animal mitochondria and nuclei: different specificity of DNA methylation]

DNA-methylase activities which methylate cytosine residues in homo- and heterologous DNA were detected in mitochondria and nuclei from rat liver and beef heart. Adenine modifying DNA-methylases in mitochondria and nuclei were not found. DNA from mitochondria and nuclei differ significantly in the methylation degree and in the pattern of the 5-methyl-cytosine distribution by pyrimidine isostichs as DNA in vivo and in vitro being methylated. Mitochondrial DNA methylase has the maximum activity at 30 degrees and pH 7.8 this enzyme(s) differ(s) from the nuclear one(s) in the pH dependence of its activity. After exhaustive in vitro methylation of various DNA by the nuclear enzyme DNA-methylase from mitochondria additionally introduces CH3 groups from S-adenosylmethionine into these DNA (about 3 times more CH3 groups than nuclear enzyme). Nuclear DNA-methylase also methylates DNA which is previously fully-methylated by the mitochondrial enzyme, but to a lesser degree. In conditions of exhaustive DNA methylation mitochondrial enzyme introduces into E. coli B DNA about four times more methyl groups as compared to the nuclear one. After the methylation of E. coli B DNA by mitochondrial enzyme the label (3H-methyl) was detected predominantly in mono-, and in case of nuclear enzyme--in di- and tripyrimidine fragments. Mitochondrial DNA-methylase differs from the nuclear one in the nature of recognized DNA sequences; these enzymes seems to be represented by different proteins. The mitochondrial enzyme methylates shorter nucleotide sequences in DNA as compared to the nuclear DNA-methylase. All these data suggest there exist organoid specificity of genome methylation in animal cell and the modification-restriction systems in animal nucleus and mitochondria are different in character.     

Methylation of satellite deoxyribonucleic acid in mouse neoplastic and non-neoplastic cell cultures

Summary Comparisons of nucleic acid methylation between paired neoplastic and non-neoplastic mouse cell lines have shown a striking difference in the deoxyribonucleic acid (DNA) peak eluted from methylated albumin-kieselguhr columns (R. Gantt and V. J. Evans, 1969, Cancer Res. 29: 536–541). Since mouse satellite DNA is relatively highly methylated, its 5-methylcytosine content was compared with mainband DNA in these two paired cell lines to determine whether this might account for the observed differences. The cell DNA was labeled with methyl-labeled methionine and isolated from the cells by repeated neutral cesium chloride isopycnic centrifugation. The satellite DNA strands were then separated in an alkaline cesium chloride gradient. Both the 5-methylcytosine content and the relative amounts of satellite DNA were indistinguishable in the paired cell lines. Further, the results showed that both strands of satellite DNA had virtually equal amounts of 5-methylcytosine, although the heavy strand contains 1.5 times more cytosine than the light strand.     

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.     

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.     

Properties of DNA-methylase reaction in isolated nuclei of normal and regenerating rat liver]

Evidence from comparative determination of DNA radioactivity methylation degree of acidic extraction and chlorophormic deproteination of the samples suggest that the former technique is a more efficient one. The properties of the DNA-methylase reaction in isolated rat liver nuclei were studied. The DNA-methylase activity is found to be considerably stable during incubation of the nuclei at 37 degrees C; a broad pH-optimum in the alkaline region is observed (pH 8.6--9.8); this activity is inhibited by Mn2+, nucleotides, actynomycin and S-adenosyl methionine analogs and is activated by Mg2+; the incorporation of methyl groups into DNA is reversible. The data suggest that the DNA-methylase activities of the nuclei isolated at different stages of regeneration do not show substantial variations. No differences in DNA methylation before and after DNA synthesis in the regenerating nuclei were observed. Inhibition of DNA synthesis in the course of regeneration does not decrease the level of DNA methylation. The interrelationship between methylation and replication of DNA is discussed.