Masc2, a C5-DNA-methyltransferase from Ascobolus immersus with similarity to methyltransferases of higher organisms

The filamentous fungus Ascobolus immersus represents an eukaryotic model organism to study genetic phenomena linked to DNA methylation. Following our previous characterization of a gene, masc1 from A. immersus, encoding the 'de novo' C5-DNA-methyltransferase (MTase), we report here the identification of a second MTase gene, masc2. The deduced peptide sequence of Masc2 is similar to previously identified eukaryotic MTases and distinct from Masc1 by having a large N-terminal domain in addition to the ubiquitous C-terminal catalytic domain. Following cloning of the gene, Masc2 was overexpressed and purified. Masc2 shows MTase activity with double stranded DNAs. Structural and biochemical properties of Masc2 suggest that it may function as a 'maintenance' MTase. With this finding, A. immersus represents so far the only eukaryotic organism in which two possibly synergistically operating MTases have been identified.

Complementation of methylation deficiency in embryonic stem cells by a DNA methyltransferase minigene

Previous attempts to express functional DNA cytosine methyltransferase (EC 2.1.1.37) in cells transfected with the available Dnmt cDNAs have met with little or no success. We show that the published Dnmt sequence encodes an amino terminal-truncated protein that is tolerated only at very low levels when stably expressed in embryonic stem cells. Normal expression levels were, however, obtained with constructs containing a continuation of an ORF with a coding capacity of up to 171 amino acids upstream of the previously defined start site. The protein encoded by these constructs comigrated in SDS/PAGE with the endogenous enzyme and restored methylation activity in transfected cells. This was shown by functional rescue of Dnmt mutant embryonic stem cells that contain highly demethylated genomic DNA and fail to differentiate normally. When transfected with the minigene construct, the genomic DNA became remethylated and the cells regained the capacity to form teratomas that displayed a wide variety of differentiated cell types. Our results define an amino-terminal domain of the mammalian MTase that is crucial for stable expression and function in vivo.

Overproduction of DNA cytosine methyltransferases causes methylation and C --> T mutations at non-canonical sites

Multicopy clones of Escherichia coli cytosine methyltransferases Dcm and EcoRII methylase (M. EcoRII) cause an approximately 50-fold increase in C --> T mutations at their canonical site of methylation, 5'-CmeCAGG (meC is 5-methylcytosine). These plasmids also cause transition mutations at the second cytosine in the sequences CCGGG at approximately 10-fold lower frequency. Similarly, M. HpaII was found to cause a significant increase in C --> T mutations at a CCAG site, in addition to causing mutations at its canonical site of methylation, CCGG. Using a plasmid that substantially overproduces M. EcoRII, in vivo methylation at CCSGG (S is C or G) and other non-canonical sites could be detected using a gel electrophoretic assay. There is a direct correlation between the level of M. EcoRII activity in cells, the extent of methylation at non-canonical sites and frequency of mutations at these same sites. Overproduction of M. EcoRII in cells also causes degradation of DNA and induction of the SOS response. In vitro, M. EcoRII methylates an oligonucleotide duplex containing a CCGGG site at a slow rate, suggesting that overproduction of the enzyme is essential for significant amounts of such methylation to occur. Together these results show that cytosine methyltransferases occasionally methylate cellular DNA at non-canonical sites and suggest that in E. coli, methylation-specific restriction systems and sequence specificity of the DNA mismatch correction systems may have evolved to accommodate this fact. These results also suggest that mutational effects of cytosine methyltransferases may be much broader than previously imagined.

Effects of 5-azacytidine on physiological differentiation of Streptomyces antibioticus

We studied the specificity of the effect of 5-azacytidine, a DNA-methylase inhibitor that impairs Streptomyces differentiation. We showed that this compound did not affect global DNA, RNA or protein biosynthesis in submerged cultures of S. antibioticus ETHZ 7451. Among individual proteins, enzymes such as alkaline phosphatase and intracellular protease were produced in similar amounts in the presence and absence of this compound. However, the production of extracellular protease was significantly inhibited. Also DNA-methyltransferases were inhibited, indicating that DNA methylation might be involved in the regulation of differentiation. By contrast, elevated levels of the antibiotic rhodomycin resulted when 5-azacytidine was added to the culture medium. In order to determine whether there was a correlation between sporulation and altered enzymatic activities, these activities were analysed in S. antibioticus submerged cultures. Among them, alkaline phosphatase and intracellular protease activities did not show a clear correlation with sporulation. However, high levels of extracellular protease were produced during septation of hyphae. This association between extracellular protease and sporulation suggests a specific inhibitory effect of 5-azacytidine, not only on spore formation, but also on physiological differentiation.

Altered sequence recognition specificity of a C5-DNA methyltransferase carrying a chimeric 'target recognizing domain'

A MTase with a chimeric TRD with the N-terminal half derived from a TRD recognizing GCNGC, the C-terminal half from one with CCWGG recognition, was constructed. Its target specificity is reported.

Analysis of overlapping cDNA clones specific for a putative second DNA methyltransferase-encoding gene in Arabidopsis thaliana

We have isolated and sequenced overlapping cDNA clones specific for a putative second DNA methyltransferase (MTase)-encoding gene (MTase11) from Arabidopsis thaliana (At) recently described as a genomic DNA fragment [Scheidt et al., Nucleic Acids Res. 22 (1994) 953-958]. The gene seems to be present as a single copy in the At genome and is transcribed into a 2.2-kb messenger detectable only in young seedlings. Using sequence comparison we found structural differences between the cDNA clones and the previously reported genomic fragment. The amino-acid sequence deduced from the 1.8-kb cDNA sequence shows the occurrence of the conserved motif number VI characteristic for m5C-MTases. Northern and Southern analysis detects no cross-hybridization with the originally described MTase-encoding At gene (MTase1) [Finnegan and Dennis, Nucleic Acids Res. 21 (1993) 2383-2388].

Stabilization of DNA methyltransferase levels and CpG island hypermethylation precede SV40-induced immortalization of human fibroblasts

De novo methylation of normally unmethylated CpG islands and increased expression of DNA (cytosine-5)-methyltransferase (DNA MTase) are common characteristics of immortalized cell lines and human tumors. To examine the acquisition of these properties with respect to cellular immortalization, we studied CpG island methylation and DNA MTase expression in aging normal human fibroblasts and their SV40-infected preimmortal (precrisis) and immortal (postcrisis) derivatives. The levels of DNA MTase enzyme activity decreased by 50% as normal fibroblasts were cultured to senescence. By contrast, DNA MTase activity did not decrease in SV40-infected pre- or postcrisis cells but remained similar to that of young fibroblasts and 2-4-fold higher than that of senescent fibroblasts. DNA MTase mRNA levels paralleled those of enzyme activity. Several loci were examined to determine the relationship between the dynamics of DNA MTase expression and the appearance of de novo CpG island methylation. Ten CpG island loci examined were unmethylated in normal young fibroblasts. By contrast, four of these loci (the CALC1, MyoD, and IGF-2 genes on chromosome 11p and the estrogen receptor gene on chromosome 6q) were de novo methylated in fully immortalized, postcrisis cells. Two of these four were actually methylated in extended life span precrisis cells, and one, the estrogen receptor locus, exhibited de novo methylation with aging in normal fibroblasts. The data indicate that an ability to maintain DNA MTase levels is acquired with SV40-induced escape from senescence. Furthermore, aberrant CpG island methylation can be established prior to immortalization, either as a function of normal aging or in response to SV40-induced escape from senescence.

Baculovirus-mediated high level expression of a mammalian DNA methyltransferase

The murine C-5 cytosine DNA methyltransferase (MTase, E.C.2.1.1.37) containing a hexahistidine affinity leader peptide has been expressed at levels which are at least 50-fold higher than previously reported. The recombinant enzyme has activity levels similar to the wild-type enzyme. The recombinant polypeptide binds to and elutes from a nickel affinity resin (IMAC resin). No dramatic differences in post-translational modification between the wild-type and recombinant enzyme were observed. The recombinant system will be useful in performing site-directed mutagenesis and will facilitate enzymological and biological investigations of this enzyme.

Expression of DNA methyltransferase gene in mature and immature neurons as well as proliferating cells in mice

A major role of DNA-methyltransferase (MTase) is thought to be maintaining the DNA methylation profile through DNA replication. However, previous surveys of mRNA distribution in different tissues by Northern-blot analysis have shown unexpectedly high levels of expression of DNA-MTase mRNA in adult mouse brain, which consists mostly of slowly proliferating glial and nonproliferating neuronal cells. In order to identify cells expressing the gene in the brain, we performed an in situ hybridization analysis of mature brain as well as whole embryos of different ages. In addition to various embryonic tissues with active cell proliferation such as the ventricular neurogenic layer, hair follicle epithelia, thymus and epithelia of the base of intestinal villi, almost all mature neurons in brain of adult and even aged mice expressed DNA-MTase mRNA at substantial levels. No significant expression of the gene was detected in the white matter. These findings suggest some neuron-specific biological function of DNA methylation, unrelated to DNA replication.

Modulation of human DNA methyltransferase activity and mRNA levels in the monoblast cell line U937 induced to differentiate with dibutyryl cyclic AMP and phorbol ester

The regulation of DNA (cytosine-5) methyltransferase (DNA MeTase) enzyme activity and gene expression was examined in the monoblastoid U937 cell line induced to differentiate with either dibutyryl cyclic AMP (dbcAMP) or phorbol ester. dbcAMP treatment was found to cause the rapid (< 4 h) suppression of DNA MeTase specific activity, with no DNA MeTase activity detectable after 10 h. Equally, no DNA MeTase activity was detectable in nuclear extracts of fresh peripheral blood monocytes. Using both a U937 DNA MeTase cDNA and a mouse DNA MeTase cDNA as probes, steady-state levels of DNA MeTase mRNA were found to decline sharply between 4 and 15 h after dbcAMP treatment. No DNA MeTase mRNA was detectable after 20 h of dbcAMP treatment. Nuclear run-on analysis showed there to be only a small (40%) suppression of DNA MeTase gene transcription in cells treated with dbcAMP for 24 h, implying a role for post-transcriptional processes in the regulation of DNA MeTase mRNA levels. The observed decline in DNA MeTase activity/mRNA levels appeared to precede the dbcAMP-induced arrest in DNA replication, as judged by the incorporation of tritiated thymidine into DNA. In contrast to the effect of dbcAMP, treatment of U937 cells with the phorbol ester 12-O-tetradecanoyl phorbol-13-acetate (TPA) led to an overall stimulation of DNA MeTase specific activity. The TPA response was found to be complex and broadly consisted of an early (0-15 h) burst of DNA MeTase activity followed by a more gradual sustained increase in DNA MeTase activity after prolonged (16-40 h) TPA treatment. The early phase of high DNA MeTase activity was not mirrored by an increase in steady-state levels of DNA MeTase mRNA, as judged by Northern blot analysis. However, a substantial induction of DNA MeTase mRNA levels was observed after 20-24 h of TPA treatment. Nuclear run-on analysis showed this not to be due to any significant increase in DNA MeTase gene transcription. The observed increases in DNA MeTase activity/mRNA levels were observed whilst cells were undergoing deproliferation. Interestingly, the addition of TPA and more physiological protein kinase C (PKC) activators, such as diacylglycerol and phosphatidylserine, to DNA MeTase-enriched nuclear extracts generated a 4.5-fold and a 1.5-fold increase in DNA MeTase specific activity respectively. The TPA-induced stimulation of DNA MeTase activity could be inhibited by the PKC inhibitor H-9, implicating a role for PKC in the regulation of DNA MeTase activity in vivo.

Expression of an exogenous eukaryotic DNA methyltransferase gene induces transformation of NIH 3T3 cells

Abnormal regional increases in DNA methylation, which have potential for causing gene inactivation and chromosomal instability, are consistently found in immortalized and tumorigenic cells. Increased DNA methyltransferase activity, which is also a characteristic of such cells, is a candidate to mediate these abnormal DNA methylation patterns. We now show that, in NIH 3T3 mouse fibroblasts, constitutive overexpression of an exogenous mouse DNA methyltransferase gene results in a marked increase in overall DNA methylation which is accompanied by tumorigenic transformation. These transformation changes can also be elicited by dexamethasone-inducible expression of an exogenous DNA methyltransferase gene. Our findings provide strong evidence that the increase in DNA methyltransferase activity associated with tumor progression could be a key step in carcinogenesis and provide a model system that can be used to further study this possibility.

Direct identification of the active-site nucleophile in a DNA (cytosine-5)-methyltransferase

The overproduction, purification, and determination of the active-site catalytic nucleophile of the DNA (cytosine-5)-methyltransferase (DCMtase) enzyme M.HaeIII are reported. Incubation of purified M.HaeIII with an oligodeoxynucleotide specifically modified with the mechanism-based inhibitor 5-fluoro-2'-deoxycytidine [Osterman, D. G., et al. (1988) Biochemistry 27, 5204-5210], in the presence of the cofactor S-adenosyl-L-methionine (AdoMet), resulted in the formation of a covalent DNA-M.HaeIII complex, which was purified to homogeneity. Characterization of the intact complex showed it to consist of one molecule of the FdC-containing duplex oligonucleotide, one molecule of M.HaeIII, and one methyl group derived from AdoMet. Exhaustive proteolysis, reduction, and alkylation of the DNA-M.HaeIII complex led to the isolation of two DNA-bound peptides--one each from treatment with Pronase or trypsin--which were subjected to peptide sequencing in order to identify the DNA attachment site. Both peptides were derived from the region of M.HaeIII containing a Pro-Cys sequence that is conserved in all known DCMtases. At the position of this conserved Cys residue (Cys71), in the sequence of each peptide, was found an unidentified amino acid residue; all other amino acid residues were in accord with the known sequence. It is thus concluded that Cys71 of M.HaeIII forms a covalent bond to DNA during catalytic methyl transfer. This finding represents a direct experimental verification for the hypothesis that the conserved Cys residue of DCMtases is the catalytic nucleophile [Wu, J. C., & Santi, D. V. (1987) J. Biol. Chem. 262, 4778-4786].(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in DNA methyltransferase induced by treatment with N-2-acetylaminofluorene

We have compared the levels of DNA methyltransferases from rat liver and spleen in both sexes following a single injection of N-2-acetylaminofluorene (AAF). Enzyme extracts from treated animals were obtained at different intervals (2-34 days) after treatment. The extracts were assayed in the presence of chicken erythrocyte DNA and S-adenosyl-L-[Me-3H]methionine. A 55% increase in male rat-liver methyltransferase activity measured by Me-3H incorporation into DNA occurred on day 14. By contrast, female methyltransferase after a similar period revealed a 33% decrease in activity. Between days 21 and 34, there is a progressive return to normal methyltransferase levels. Spleen-derived enzyme studied between days 7 and 14, showed a decrease in methylating activity in both sexes. After replacing corn seed oil by ethanol as the vehicle for AAF injection, we observed a change in liver methyltransferase 48 h after injection. Quantification of radioactive eluates in m5C fractions together with the increase in the integrated area identified as m5C in HPLC chromatograms allowed positive identification of methylated products.

Cloning, sequencing, in vivo promoter mapping, and expression in Escherichia coli of the gene for the HhaI methyltransferase

A 1476-base pair DNA fragment from Haemophilus haemolyticus containing the HhaI methyltransferase gene was isolated from a cell library and cloned into pBR322. The nucleotide sequence of this fragment was determined. The structural gene is 981 nucleotides in length coding for a protein of 327 amino acids (Mr 37,000). The translational start signal (ATG) is preceded by the putative ribosome-binding site (TAAG). Recombinant plasmids containing the 1476-basepair fragment are completely methylated when isolated from Escherichia coli, as judged by their insusceptibility to the HhaI restriction endonuclease. However, the presence of an active HhaI methylase gene in certain E. coli strains results in a very poor yield of transformants and/or in vivo-originated deletions due to the Rg1 functions of these hosts. The in vivo transcription initiation sites have been identified by S1 protection and primer-extension experiments using specific probes with total RNA prepared from E. coli cells (HB101 or RR1) which tolerate the expression of MHhaI.

Genetic analysis of the 5-azacytidine sensitivity of Escherichia coli K-12

DNA containing 5-azacytidine (5-azaC) has been shown to form stable detergent-resistant complexes with cytosine methylases. We reasoned that if 5-azaC treatment causes protein-DNA cross-links in vivo, then mutations in DNA repair and recombination genes may increase the sensitivity of a cell to 5-azaC. We found that although recA (defective) and lexA (induction-negative) mutants of Escherichia coli were very sensitive to the drug, mutations in uvrA and ung genes had little effect on cell lethality. The sensitivity of recA strains to 5-azaC was dose dependent and was enhanced by the overproduction of a DNA cytosine methylase in the cell. Unexpectedly, a strain of E. coli carrying a recA mutation and a deletion of the DNA cytosine methylase gene (dcm) was found to be significantly sensitive to 5-azaC. Study of mutations in the pyrimidine salvage pathway of E. coli suggests that direct phosphorylation of 5-azaC, rather than phosphorylation of its degradation products, is largely responsible for the lethal effects of the drug. The addition of uracil to the growth medium has little effect on cell lethality of recA mutants, but it partially reversed the inhibition of cell growth caused by 5-azaC. This reversal of the bacteriostatic effects of the drug could not be achieved by adding cytosine or orotic acid to the growth medium and required the presence of functional UMP-pyrophosphorylase (gene upp) in the cell.

DNA methyltransferase genes of Bacillus subtilis phages: structural relatedness and gene expression

The DNA methyltransferase (Mtase) genes of temperate Bacillus subtilis phages phi 3T, rho 11 and SP beta were cloned and expressed in Escherichia coli. Each gene specifies a 47-kDa1 protein, which modifies BsuR (GGCC) and Fnu4HI (GCNGC) target sequences. Transcription is controlled by phage promoters located on the cloned fragments. The direction of transcription and the approximate position of the Mtase genes were determined. DNA/DNA hybridization experiments revealed close structural relatedness of the phi 3T, rho 11 and SP beta genes. A significant degree of homology was also found among these genes and the Mtase gene of related phage SPR, which codes for an enzyme with different modification specificity. These results suggest a common ancestor of the different phage Mtase genes. Phage Z, the only BsuR-sensitive member of this phage group, lacks a modification gene, but contains regions homologous to sequences flanking the SPR, phi 3T, rho 11 and SP beta Mtase genes.

Genetic recombination during transformation in Bacillus subtilis: appearance of a deoxyribonucleic acid methylase

In Bacillus subtilis the ability to take up deoxyribonucleic acid (DNA) and undergo genetic transformation may coincide with the induction of defective phage(s) and the expression of possibly related cryptic genes. A restriction-modification enzyme system appears to be expressed. Targets of the restriction activity on the DNA can be blocked my methylation catalyzed by the methyl transferase. It is shown that cellular DNA becomes progressively methylated and reaches the maxium level during the peak of competency. Deoxycytidine residues of both incoming donor and resident DNA are methylated. The possible participation of these enzymes in recombination and the general role of cryptic genes in inducible functions are discussed.

In vivo methylation by Escherichia coli K-12 mec+ deoxyribonucleic acid-cytosine methylase protects against in vitro cleavage by the RII restriction endonuclease (R. Eco RII)

We have analyzed the susceptibility of the deoxyribonucleic acid (DNA) of phage fd replicative form (RF) and of Escherichia coli to in vitro cleavage by purified RII restriction endonuclease (R. Eco RII). The results are summarized as follows: (i) fd, mec- RFI, isolated from infected E. coli K-12 mec- bacteria (a mutant strain lacking DNA-cytosine methylase activity), is cleaved into at least two fragments, whereas fd. mec+ RFI, isolated from the parental mec+ strain, is not cleaved. (ii) E. coli mec- DNA is extensively degraded, whereas mec+ DNA-cytosine methylase acts as an RII modification enzyme.

[Rat liver methylation of nuclear DNA following hydrocortisone induction]

After intravenous hydrocortisone injection (2 mg per 100 g of animal weight) DNA methylase activity in rat liver increases 1.5-2 times. Rat liver DNA is capable of being methylated in vitro by homologous and heterologous (from rat spleen and ascite carcinoma cells) enzymes. Rat liver DNA isolated 40 min after hydrocortisone injection contains 1.5 times more 5-methylcytosine and is able to accept 1.5 times less methyl groups from (3H-methyl)-S-adenosylmethionine in the in vitro methylation reaction by enzymes from rat spleen as compared to liver DNA isolated from nontreated rats. Thus, there is DNA supermethylation in rat liver cells occurring under the action of the hormone. This induced change in the methylation level of DNA in rat liver is reversible: 6 hours after a single hydrocortisone injection the amount of 5-methylcytosine in DNA decreases to normal, and the DNA ability to accept methyl groups in the in vitro methylation is the same as compared to that of liver DNA from control animals. The induced reversible DNA methylation is to be considered as a mechanism for the regulation of DNA transcription and cell genetic activity.