Identification of 5-methylcytosine in DNA fragments immobilized on nitrocellulose paper.

A method to identify 5-methylcytosine (m5Cyt) in DNA immobilized on nitrocellulose paper by using antibody against m5Cyt raised in rabbits is described. Immobilized restriction fragments of DNA are incubated first with purified antibody against m5Cyt and then with goat anti-rabbit IgG labeled with 125I. Restriction fragments containing m5Cyt are visualized by autoradiography. By using this method, a heavily methylated fragment of about 1700 base pairs was identified in nuclear DNA fom Chinese hamster cells, the methylation pattern of calf thymus satellite I DNA was examined, and chloroplast DNAs that were extracted from various stage of the Chlamydomonas life cycle were compared. Little if any methylation was detected in chloroplast DNA from vegetative cells or from male gametes, whereas homologous DNAs from female gametes and from zygotes were heavily methylated. The sensitivity of the method was examined with calf thymus satellite I DNA (which contains approximately 40 m5Cyt residues per repeat unit of 1400 base pairs) and with phi X174 virion DNA (which contains a single m5Cyt per molecule). The presence of m5Cyt was detected with as little as 40 ng of phi X174 DNA containing 0.02 pmol of m5Cyt and with 100 ng of satellite DNA containing about 0.5 pmol of m5Cyt. Thus, the method makes possible the identification of individual methylated sites in purified DNAs in the size range of single genes.     

Two DNA methyltransferases from murine erythroleukemia cells: purification, sequence specificity, and mode of interaction with DNA.

Dye-ligand chromatography on Cibacron blue F3GA-agarose has been used to resolve two species of DNA (cytosine-5-)-methyltransferase from nuclear extracts of uninduced Friend murine erythroleukemia cells. Each species has been highly purified; the activities in the first and second peaks were associated with polypeptides of Mr 150,000 and 175,000, respectively. Analysis of substrate specificity with synthetic DNAs and restriction fragments of phi X174 replicative form DNA and pBR322 DNA showed that neither enzyme had dependence on the sequence context of CpG dinucleotides; poly(dG-dC) had the greatest methyl-accepting activity of any unmethylated DNA substrate tested. De novo methylation by both enzymes was inefficient relative to methylation of hemimethylated sites. Methyl-accepting activity was strongly dependent on DNA chain length. This observation suggests that binding to DNA, followed by one-dimensional diffusion of enzyme along the DNA molecule, is important in the mechanism by which DNA methyltransferase locates its recognition sites.     

Mismatch repair in xenopus egg extracts is not strand-directed by DNA methylation

The efficiency of Xenopus laevis egg extract to repair T:G and A:C mismatched base pairs in unmethylated, hemimethylated and fullymethylated heteroduplexes was investigated. Filamentous phage M13mp18 and its derivative M13mp18/MP-1 (C changed to T inside the sequence dCC*C GGG, at the position 6248) were used for heteroduplexes construction. The three origins of mismatched base-pairs in the eukaryotic DNA are mimicked by in vitro methylation: hemimethylated DNA (me-/me+) for replication errors; unmethylated (me-/me-) and fully methylated DNA (me+/me+) for recombination heteroduplexes, and fullymethylated also for locally, spontaneously deaminated 5-methylcytosine (5meC) to T, generating the exclusively T:G mismatch. The methylations were in CpG dinucleotides, mostly characteristic ofeukaryotic cells [5, 24]. In vitro methylation was done by HpaII methylase which methylate central C of dCCGG sequence in the manner of eukaryotic methylation. The position of mismatched bases was chosen so that correction of mismatched bases in any strand would create the sequence for one of the "diagnostic" restriction endonucleases, either BstNI or MspI. Correction efficiency was about 10(8) repair events per egg equivalent. Correction in favor of C:G base pair restoration occurred regardless of the T:G or C:A mispairs, with almost equal efficiency. Repair of T:G to T:A was up to 10 times less efficient comparing to C:G, and repair of C:A to T:A was in our experimental system undetectable. No significant difference in repair efficiency of mismatched bases situated in unmethylated, hemimethylated or fullymethylated heteroduplexes indicate methylation-independent repair of mismatched bases in X. laevis oocite extracts.     

Escherichia coli host factor required specifically for the phi X174 stage III reaction: in vitro identification and partial purification.

A cell-free extract prepared from phi X174-infected Escherichia coli cells sustained in vitro synthesis of viral DNA (stage III reaction) when supplemented with fraction II from uninfected cells. The reaction was dependent upon deoxyribonucleoside triphosphate, ATP, added phi X174 replicative form I DNA template, and the fraction II from uninfected cells. This reaction differed from the stage II reaction (semiconservative replication of duplex replicative form DNA) by the production of stable viral protein-DNA complexes sensitive to anti-phi X174 antiserum. Three types of protein-DNA complexes were identified, 50S, 92S, and a 114S complex that cobanded in CsCl and cosedimented in neutral sucrose gradients with a phi X174 phage marker. The sensitivity of these complexes to anti-phi X174 antiserum and Staphylococcus aureus provided a relatively rapid biochemical assay for direct measurement of the amount of DNA synthesized by the stage III reaction. With this assay, an E. coli factor (SIII) required specifically for the synthesis of viral protein-DNA complexes was identified and purified 200-fold from uninfected E. coli cells. The partially purified SIII factor was required for the synthesis of DNA and viral protein-DNA complexes in the phi X174-infected cell extracts and could not be replaced by rep protein, single-strand binding protein, or DNA polymerase III holoenzyme.     

Methylation of foreign DNA sequences in eukaryotic cells.

The herpesvirus thymidine kinase gene has been used to introduce foreign DNA sequences into mouse L cells by DNA-mediated gene transfer. These inserted genes were then assayed for methylation at the specific sequence C-C-G-G by using the restriction enzyme isoschizomers Hpa II and Msp I. Despite the fact that 70% of the cellular C-C-G-G sites are methylated, herpesvirus sequences, plasmid DNA, and growth hormone gene DNA were found to remain unmethylated in 90% of the clones that contain these genes. DNA that had been methylated in vitro with Hpa II methylase was also inserted into L cells. The presence of this modification in the vector DNA did not, however, guarantee that these sequences remained methylated in the recipient clones. Only 10% of all transformed clones were found to contain methylated C-C-G-G sequences in the vector DNA, and these modifications were stable for 25-50 generations. Hha I and Mbo I were used to probe for methyl groups at these restriction sites, but none of the inserted sequences acquired these modifications. These results are discussed in relation to various models put forth to explain the process of methylation in eukaryotic cells.     

Mechanistic aspects of genome-wide demethylation in the preimplantation mouse embryo.

Gene-specific methylation patterns in mammals play a role in a variety of biological processes in the embryo and adult tissues. These patterns are established during embryo development by a process that involves genome-wide demethylation in the morula and de novo methylation in the pregastrula. To elucidate the mechanism of demethylation in the early mouse embryo, we have injected mouse zygotes with gene sequences that were methylated in vitro by Hpa II methylase and analyzed the methylation status of specific sites in blastocyst DNA. Because it had been propagated in Escherichia coli, the DNA used for these injections was also methylated at adenine residues in GATC sites. This allowed us to eliminate fully methylated, unintegrated DNA by Dpn I digestion and fully unmethylated, integrated DNA that underwent several rounds of replication by Mbo I digestion. The integrated, originally injected DNA strands were in a hemimethylated state and survived this treatment. The methylation status of Hpa II sites in these molecules was analyzed by Hpa II digestion of the genomic DNA isolated from blastocysts, followed by PCR amplification using appropriate primers. The results demonstrate that demethylation is achieved by an active mechanism and that specific sites in imprinted genes escape demethylation, maintaining a methylated state throughout preimplantation development.     

Morphogenesis of phi X174: in vitro synthesis of infectious phage from purified viral components.

An in vitro system that synthesizes infectious phage phi X174 was developed. The synthesis depended on phi X174 supercoiled replicative form DNA, purified phi X174 gene A protein, gene C protein, gene J protein, prohead (phage head precursor composed of gene F, G, H, B, and D proteins), and uninfected host crude extract. The infectious phage synthesis was coupled with DNA synthesis. De novo initiation, elongation, and termination of phi X174 single-stranded DNA was observed. The phage synthesized in vitro cosedimented with in vivo phage in sucrose gradients and had the same buoyant density as in vivo phage in a CsCl gradient. Our results indicate that the in vitro system mimics the in vivo phi X174 assembly process.     

In vitro synthesis of bacteriophage phi X174 by purified components.

An in vitro system capable of synthesizing infectious phi X174 phage particles was reconstituted from purified components. The synthesis required phi X174 supercoiled replicative form DNA, phi X174-encoded proteins A, C, J, and prohead, Escherichia coli DNA polymerase III holoenzyme, rep protein, and deoxyuridinetriphosphatase (dUTPase, dUTP nucleotidohydrolase, EC 3.6.1.23) as well as MgCl2, four deoxyribonucleoside triphosphates, and ATP. Phage production was coupled to the synthesis of viral single-stranded DNA. More than 70% of the synthesized particles sedimented at the position of mature phage in a sucrose gradient and associated with the infectivity. The simple requirement of the host proteins suggests that the mechanism of viral strand synthesis in the phage-synthesizing reaction resembles that of viral strand synthesis during the replication of replicative form DNA.     

In vitro DNA replication of recombinant plasmid DNAs containing the origin of progeny replicative form DNA synthesis of phage phi X174.

The origin of phage phi X174 progeny replicative form (RF) DNA synthesis has been inserted into the plasmid vector pBR322 and cloned. In direct contrast to pBR322, the recombinant superhelical plasmids can substitute for phi X174 RFI DNA as template in phi X174-specific reactions in vitro. We have shown that the recombinant plasmids: (i) are cleaved by the phi X174 A protein; (ii) support net synthesis of unit-length single-stranded circular DNA in the presence of the phi X174 A protein and Escherichia coli rep protein, DNA-binding protein, and DNA polymerase III elongation system; (iii) support replication of duplexes catalyzed by the phi X174 A protein and extracts of E. coli.     

Differential activity of DNA methyltransferase in the life cycle of Chlamydomonas reinhardi.

Two molecular weight forms of DNA (cytosine-5-)-methyltransferase [S-adenosyl-L-methionine:DNA (cytosine-5-)- methyltransferase, EC 2.1.1.37], both active in assays in vitro, were isolated from the green alga Chlamydomonas reinhardi at various stages of the life cycle. The enzyme with Mr 60,000 was found in vegetative cells and gametes of both male (mt-) and female (mt+) mating types. The enzyme with Mr 200,000 was specific to gametic cells and zygotes, which are the only stages at which methylation of chloroplast DNA occurs in vivo. Chloroplast DNA from gametes was shown to be methylated on both strands at most if not all methylation sites and the Mr 200,000 enzyme was shown to methylate both unmethylated and hemimethylated sites, the latter at an elevated rate. Micrococcus luteus DNA showed the same nearest-neighbor frequencies of methylation after methylation by each molecular weight component. The data suggest strongly that the Mr 200,000 enzyme is the active multimeric form of the Mr 60,000 enzyme and that it acts as both initiation and maintenance methylase. It is proposed that methylation of chloroplast DNA in female gametes and zygotes is regulated by assembly of the multimeric Mr 200,000 active enzyme, which in turm determines the maternal inheritance of chloroplast DNA.     

Indiscriminate recombination in simian virus 40-infected monkey cells.

DNA transfection of African green monkey BSC-1 cells with simian virus 40 (SV40) DNA and bacterial virus phi X174 replicative form DNA ("cotransfection") yielded stocks containing SV40/phi X174 recombinant virus, which was detected by an infectious-center in situ plaque hybridization procedure and which was sensitive to anti-SV40 antiserum. The recombinant virus replicated during serial passage. Restriction endonuclease cleavage of the SV40/phi X174 DNA indicated that several different types of recombinant DNA structures had arisen. Similar SV40 DNA cotransfection experiments with polyoma virus DNA, bacterial plasmid (pBR322) DNA, and a plasmid-cloned segment of the mouse genome (coding for intracisternal type A particles) yielded stocks that generated recombinant plaques as judged by in situ plaque hybridization with the appropriate labeled probe. It appears, therefore, that an active indiscriminate recombination process, incapable of distinguishing between diverse DNAs of prokaryotic and eukaryotic origin, occurs in SV40-infected monkey cells.     

Pattern of methylation of two genes coding for housekeeping functions.

The distribution of sites that can be methylated was analyzed in the Chinese hamster adenine phosphoribosyl-transferase (aprt) gene and the patterns of methylation of this gene and the mouse dihydrofolate reductase (dhfr) gene were studied by using CpG restriction enzymes. Both genes were found to be unmethylated completely at their 5'-end region and methylated heavily throughout the rest of the gene. Because the hamster aprt gene can be inhibited by DNA methylation in vivo, the results suggest that 5' undermethylation of this gene may be a necessary condition for its expression. The pattern of methylation of each of these two genes was similar in sperm and all other somatic tissue DNAs. This is in contrast to many tissue-specific genes that were found to be highly methylated in sperm DNA and undermethylated in the tissue in which they are expressed. This result is consistent with the fact that both aprt and dhfr are key enzymes in the biosynthesis of nucleotides and therefore expected to be synthesized in all cells.     

In vitro methylation of the hamster adenine phosphoribosyltransferase gene inhibits its expression in mouse L cells.

The effect of DNA methylation on the expression of the hamster adenine phosphoribosyltransferase (aprt) gene in mouse cells has been examined. This gene was methylated in vitro at all of its C-C-G-G sites by using Hpa II methylase and was inserted into mouse Ltk- aprt- L cells by cotransformation, with the herpes virus thymidine kinase gene as a selectable vector. Whereas clones carrying unmethylated aprt sequences were found to have an aprt+ phenotype as shown by their ability to grow in azaserine-containing medium, almost all clones carrying methylated aprt sequences were shown to be phenotypically aprt-. Blot hybridization analysis demonstrated that both the methylated and unmethylated aprt sequences were integrated into the cellular genome to the same extent and that the in vitro modification was stably maintained in these cells for many generations. When clones containing methylated aprt genes were exposed to conditions that select for the expression of the aprt gene, a low frequency of reversion to the aprt+ phenotype was observed. In all of these clones, this reversion was accompanied by reorganization and undermethylation of the aprt sequences. These results show that the expression of certain genes may be inhibited by site-specific methylation of these sequences and suggest that methylation may play a direct role in the regulation of gene expression.     

DNA methylation is a reversible biological signal

The pattern of DNA methylation plays an important role in regulating different genome functions. To test the hypothesis that DNA methylation is a reversible biochemical process, we purified a DNA demethylase from human cells that catalyzes the cleavage of a methyl residue from 5-methyl cytosine and its release as methanol. We show that similar to DNA methyltransferase, DNA demethylase shows CpG dinucleotide specificity, can demethylate mdCpdG sites in different sequence contexts, and demethylates both fully methylated and hemimethylated DNA. Thus, contrary to the commonly accepted model, DNA methylation is a reversible signal, similar to other physiological biochemical modifications.     

Identification of ColE1 DNA sequences that direct single strand-to-double strand conversion by a phi X174 type mechanism.

A DNA single-strand initiation sequence, named rriA (called rri-1 previously), was detected in the origin region (Hae II fragment E) of the ColE1 plasmid [Nomura, N. & Ray, D. S. (1980) Proc. Natl. Acad. Sci. USA 77, 6566-6570]. Another site, called rriB, has been found on the opposite strand of Hae II fragment C. Both rriA and rriB (i) direct conversion of chimeric M13 phage single-stranded DNA to parental replicative form DNA in vivo by a rifampicin-resistant mechanism that is dependent on the dnaG and dnaB gene products, (ii) provide effector sites of dATP hydrolysis by primosomal protein n', and (iii) require the same primosomal proteins as phi X174 DNA for directing the in vitro conversion that rriA is the DNA sequence that determines the mechanism of lagging strand synthesis of ColE1 DNA and that the mechanism of discontinuous synthesis involves the primosomal proteins utilized in the in vitro conversion of phi X174 single strands to the double-stranded replicative form.     

The in vivo mutagenic frequency and specificity of O6-methylguanine in phi X174 replicative form DNA.

A bacteriophage phi X174-based site-specific mutagenesis system for the study of the in vivo mutagenic frequency and specificity of carcinogen-induced modification in DNA is presented. A (-)-strand primer containing O6-methylguanine in a specific site was hybridized to a single-stranded region in gene G of phi X gapped duplex DNA. The hybrid was enzymatically converted to replicative form DNA and was used to transform Escherichia coli cells. All gene G mutants generated by the modification were rescued by genetic complementation. An amber mutation in lysis gene E of the (+) strand of the replicative form DNA prevented lytic growth of wild-type phage derived from this strand. In each mutant-containing infective center produced from the transformed cells, gene G mutant phage were present in a 3:1 ratio compared to wild type. Thus, in vivo, O6-methylguanine in replicating phi X DNA has a mutagenic frequency of 75%. When repair of O6 methylguanine occurred, it was prereplicative. The mutations were due exclusively to the misincorporation of thymine.     

Hemimethylation of DNA prevents chromatin expression.

The activity of hemimethylated herpes simplex virus thymidine kinase DNA and chromatin was analyzed by microinjection and thymidine incorporation into the DNA of thymidine kinase-negative Rat2 cells. Hemimethylated DNA was obtained by in vitro replication of single-stranded M13 DNA constructs and of chromatin produced by in vitro reconstitution of the DNA with purified chicken histone octamers. We found that methylation of either the coding or the noncoding DNA strand was sufficient to block expression of the hemimethylated chromatin. In contrast, the hemimethylated DNA was as active as the unmethylated control DNA after microinjection until chromatin formation occurred in the recipient cells. Microinjection of chromatin hemimethylated by bacterial Hae III methyltransferase excluded the possibility that inactivation was caused by symmetrical methylation of the injected molecules.     

Integrated hepatitis B virus DNA sequences specifying the major viral core polypeptide are methylated in PLC/PRF/5 cells.

The methylation of various hepatitis B virus (HBV) DNA sequences was examined using the restriction endonucleases Hpa II and Msp I. HBV DNA from virions (Dane particles) and virus-infected liver tissue was digested with Hpa II or Msp I and fractionated by electrophoresis in agarose gels, and the restriction enzyme cleavage pattern was examined by Southern blot analysis. No methylation of the 5' C-C-G-G 3' recognition sequence was detected in either virion DNA or HBV DNA from infected liver tissue. The tissue culture cell line PLC/PRF/5, derived from a human hepatoma, possesses HBV DNA exclusively integrated at several sites. Digestion of PLC/PRF/5 DNA with Hpa II and Msp I revealed that the integrated HBV DNA sequences were methylated. Further analysis using probes specific for various regions of the HBV genome showed that some of the hepatitis B viral DNA sequences, including those specifying the major surface antigen polypeptide, were methylated infrequently or not at all. In contrast, the viral DNA sequences coding for the major core polypeptide were extensively methylated. Because the surface antigen is expressed in these cells while the core antigen is not, our results suggest that DNA methylation could account for the selective expression of HBV genes in this hepatoma cell line.