Cloning and sequencing of a cDNA encoding DNA methyltransferase of mouse cells. The carboxyl-terminal domain of the mammalian enzymes is related to bacterial restriction methyltransferases

A cDNA encoding DNA (cytosine-5)-methyltransferase (DNA MeTase) of mouse cells has been cloned and sequenced. The nucleotide sequence contains an open reading frame sufficient to encode a polypeptide of 1573 amino acid residues, which is close to the apparent size of the largest species of DNA MeTase found in mouse cells. The carboxylterminal 570 amino acid residues of the inferred protein sequence shows striking similarities to bacterial type II DNA cytosine methyltransferases and appears to represent a catalytic methyltransferase domain. The amino-terminal portion of the molecule may be involved in regulating the activity of the carboxyl-terminal methyltransferase domain, since antibodies directed against a peptide sequence located within this region inhibits transmethylase activity in vitro. A 5200 base DNA MeTase-specific mRNA was found to be expressed in all mouse cell types tested, and cell lines known to have different genomic methylation patterns were found to contain DNA MeTase proteins of similar or identical sizes and de novo sequence specificities. The implications of these findings for an understanding of the mechanisms involved in the establishment and maintenance of methylation patterns are discussed.     

DNA methylation: evolution of a bacterial immune function into a regulator of gene expression and genome structure in higher eukaryotes

The amino acid sequence of mammalian DNA methyltransferase has been deduced from the nucleotide sequence of a cloned cDNA. It appears that the mammalian enzyme arose during evolution via fusion of a prokaryotic restriction methyltransferase gene and a second gene of unknown function. Mammalian DNA methyltransferase currently comprises an N-terminal domain of about 1000 amino acids that may have a regulatory role and a C-terminal 570 amino acid domain that retains similarities to bacterial restriction methyltransferases. The sequence similarities among mammalian and bacterial DNA cytosine methyltransferases suggest a common evolutionary origin. DNA methylation is uncommon among those eukaryotes having genomes of less than 10(8) base pairs, but nearly universal among large-genome eukaryotes. This and other considerations make it likely that sequence inactivation by DNA methylation has evolved to compensate for the expansion of the genome that has accompanied the development of higher plants and animals. As methylated sequences are usually propagated in the repressed, nuclease-insensitive state, it is likely that DNA methylation compartmentalizes the genome to facilitate gene regulation by reducing the total amount of DNA sequence that must be scanned by DNA-binding regulatory proteins. DNA methylation is involved in immune recognition in bacteria but appears to regulate the structure and expression of the genome in complex higher eukaryotes. I suggest that the DNA-methylating system of mammals was derived from that of bacteria by way of a hypothetical intermediate that carried out selective de novo methylation of exogenous DNA and propagated the methylated DNA in the repressed state within its own genome.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hybrid mouse-prokaryotic DNA (cytosine-5) methyltransferases retain the specificity of the parental C-terminal domain

The mouse (cytosine-5) DNA methyltransferase (Dnmt1) consists of a regulatory N-terminal and a catalytic C-terminal domain, which are fused by a stretch of Gly-Lys dipeptide repeats. The C-terminal region contains all of the conserved motifs found in other cytosine-5 DNA methyltransferases including the relative position of the catalytic Pro-Cys dipeptide. In prokaryotes, the methyltransferases are simpler and lack the regulatory N-terminal domain. We constructed three hybrid methyltransferases, containing the intact N-terminus of the murine Dnmt1 and most of the coding sequences from M.HhaI (GCGC), M.HpaII (CCGG) or M.SssI (CG). These hybrids are biologically active when expressed in a baculovirus system and show the specificity of the parental C-terminal domain. Expression of these recombinant constructs leads to de novo methylation of both host and viral genomes in a sequence-specific manner. Steady-state kinetic analyses were performed on the murine Dnmt1-HhaI hybrid using poly(dG-dC).poly (dG-dC), unmethylated and hemimethylated oligonucleotides as substrates. The enzyme has a slow catalytic turnover number of 4.38 h(-1) for poly(dG-dC). poly(dG-dC), and exhibits 3-fold higher catalytic efficiency for hemimethylated substrates.     

Mutations that confer de novo activity upon a maintenance methyltransferase.

DNA methyltransferases are not only sequence specific in their action, but they also differentiate between the alternative methylation states of a target site. Some methyltransferases are equally active on either unmethylated or hemimethylated DNA and consequently function as de novo methyltransferases. Others are specific for hemimethylated target sequences, consistent with the postulated role of a maintenance methyltransferase in perpetuating a pattern of DNA modification. The molecular basis for the difference between de novo and maintenance methyltransferase activity is unknown, yet fundamental to cellular activities that are affected by different methylation states of the genome. The methyltransferase activity of the type I restriction and modification system, EcoK, is the only known prokaryotic methyltransferase shown to be specific for hemimethylated target sequences. We have isolated mutants of Escherichia coli K-12 which are able to modify unmethylated target sequences efficiently in a manner indicative of de novo methyltransferase activity. Consistent with this change in specificity, some mutations shift the balance between DNA restriction and modification as if both activities now compete at unmethylated targets. Two genes encode the methyltransferase and all the mutations are loosely clustered within one of them.     

Non-catalytic functions of DNMT1

Mammalian DNA methyltransferase 1 (DNMT1) is essential during early embryo development. Consistent with its key role in embryogenesis, depletion of this protein in adult somatic cells promotes severe cellular dysfunctions and cell death. DNMT1 contains a highly evolutionary conserved C-terminal catalytic DNA methyltransferase domain that is thought to be the responsible for the maintenance of CpG methylation patterns in the genome. DNMT1 has also a large N-terminal region with different functional protein-protein and protein-DNA binding domains. The multi-domain N-terminal region and the abundant molecular binding patterns suggest potential non-catalytic functions for DNMT1. However, this hypothesis remains controversial and conflicting results can be found in the literature. Here, recent results presenting a functional role for DNMT1 independent of its catalytic domain are discussed.     

Cloning of a mammalian DNA methyltransferase

Cloning and sequencing of cDNA clones has shown that mammalian DNA (cytosine-5)-methyltransferase comprises a 1000-amino acid (aa) N-terminal region of unknown function and a 570-aa C-terminal region that is clearly related to bacterial type-II cytosine restriction methyltransferases. These findings indicate that the mammalian enzyme contains at least two structural domains and suggest a common evolutionary origin for mammalian and prokaryotic DNA (cytosine-5)-methyltransferases.     

Recombinant human DNA (cytosine-5) methyltransferase. III. Allosteric control, reaction order, and influence of plasmid topology and triplet repeat length on methylation of the fragile X CGG.CCG sequence

Steady-state kinetic analyses revealed that the methylation reaction of the human DNA (cytosine-5) methyltransferase 1 (DNMT1) is repressed by the N-terminal domain comprising the first 501 amino acids, and that repression is relieved when methylated DNA binds to this region. DNMT1 lacking the first 501 amino acids retains its preference for hemimethylated DNA. The methylation reaction proceeds by a sequential mechanism, and either substrate (S-adenosyl-l-methionine and unmethylated DNA) may be the first to bind to the active site. However, initial binding of S-adenosyl-l-methionine is preferred. The binding affinities of DNA for both the regulatory and the catalytic sites increase in the presence of methylated CpG dinucleotides and vary considerably (more than one hundred times) according to DNA sequence. DNA topology strongly influences the reaction rates, which increased with increasing negative superhelical tension. These kinetic data are consistent with the role of DNMT1 in maintaining the methylation patterns throughout development and suggest that the enzyme may be involved in the etiology of fragile X, a syndrome characterized by de novo methylation of a greatly expanded CGG.CCG triplet repeat sequence.     

Allosteric activator domain of maintenance human DNA (cytosine-5) methyltransferase and its role in methylation spreading

The human maintenance DNA (cytosine-5) methyltransferase (hDNMT1) consists of a large N-terminal regulatory domain fused to a catalytic C-terminal domain by randomly repeated Gly-Lys dipeptides. Several N-terminal deletion mutants of hDNMT1 were made, purified, and tested for substrate specificity. Deletion mutants lacking 121, 501, 540, or 580 amino acids from the N-terminus still functioned as DNA methyltransferases, methylated CG sequences, and preferred hemimethylated to unmethylated DNA, as did the full-length hDNMT1. Methylated DNA stimulated methylation spreading on unmethylated CpG sequences for the full-length and the 121 amino acid deletion hDNMT1 equally well but not for the mutants lacking 501, 540, or 580 amino acids, indicating the presence of an allosteric activation determinant between amino acids 121 and 501. Peptides from the N- and C-termini bound methylated DNA independently. Point mutation analysis within the allosteric region revealed that amino acids 284-287 (KKHR) were involved in methylated DNA-mediated allosteric activation. Allosteric activation was reduced in the double point mutant enzymes D25 (K284A and K285A) and D12 (H286A and R287A). Retinoblastoma gene product (Rb), a negative regulator of DNA methylation, bound to the allosteric site of hDNMT1 and inhibited methylation, suggesting Rb may regulate methylation spreading.     

De novo and maintenance DNA methylation by a mouse plasmacytoma cell DNA methyltransferase

A DNA methyltransferase of Mr = 140,000 that is active on both unmethylated and hemimethylated DNA substrates has been purified from the murine plasma-cytoma cell line MPC 11. The maximal rate of methylation was obtained with maintenance methylation of hemimethylated Micrococcus luteus or M13 DNAs. At low enzyme concentrations, the highest rate of de novo methylation occurred with single-stranded DNA or relatively short duplex DNA containing single-stranded regions. Strong substrate inhibition was observed with hemimethylated but not unmethylated DNA substrates. Fully methylated single-stranded M13 phage DNA inhibited neither the de novo nor the maintenance reactions, but unmethylated single-stranded M13 DNA strongly inhibited the maintenance reaction. The kinetics observed with hemimethylated and single-stranded substrates could be explained if the enzyme were to bind irreversibly to a DNA molecule and to aggregate if present in molar excess. Such aggregates would be required for activity upon hemimethylated but not single-stranded DNA. For de novo methylation of duplex DNA, single-stranded regions or large amounts of methyltransferase appear to be required. The relative substrate preference for the enzyme is hemimethylated DNA greater than fully or partially single-stranded DNA greater than fully duplex DNA.     

Enzymatic properties of recombinant Dnmt3a DNA methyltransferase from mouse: the enzyme modifies DNA in a non-processive manner and also methylates non-CpG [correction of non-CpA] sites

We present the first in vitro study investigating the catalytic properties of a mammalian de novo DNA methyltransferase. Dnmt3a from mouse was cloned and expressed in Escherichia coli. It was shown to be catalytically active in E. coli cells in vivo. The methylation activity of the purified protein was highest at pH 7.0 and 30 mM KCl. Our data show that recombinant Dnmt3a protein is indeed a de novo methyltransferase, as it catalyzes the transfer of methyl groups to unmethylated substrates with similar efficiency as to hemimethylated substrates. With oligonucleotide substrates, the catalytic activity of Dnmt3a is similar to that of Dnmt1: the K(m) values for the unmethylated and hemimethylated oligonucleotide substrates are 2.5 microM, and the k(cat) values are 0.05 h(-1) and 0.07 h(-1), respectively. The enzyme catalyzes the methylation of DNA in a distributive manner, suggesting that Dnmt3a and Dnmt1 may cooperate during de novo methylation of DNA. Further, we investigated the methylation activity of Dnmt3a at non-canonical sites. Even though the enzyme shows maximum activity at CpG sites, with oligonucleotide substrates, a high methylation activity was also found at CpA sites, which are modified only twofold slower than CpG sites. Therefore, the specificity of Dnmt3a is completely different from that of the maintenance methyltransferase Dnmt1, which shows a 40 to 50-fold preference for hemimethylated over unmethylated CpG sites and has almost no methylation activity at non-CpG sites.     

The fragment structure of a putative HsdR subunit of a type I restriction enzyme from Vibrio vulnificus YJ016: implications for DNA restriction and translocation activity

Among four types of bacterial restriction enzymes that cleave a foreign DNA depending on its methylation status, type I enzymes composed of three subunits are interesting because of their unique DNA cleavage and translocation mechanisms performed by the restriction subunit (HsdR). The elucidated N-terminal fragment structure of a putative HsdR subunit from Vibrio vulnificus YJ016 reveals three globular domains. The nucleolytic core within an N-terminal nuclease domain (NTD) is composed of one basic and three acidic residues, which include a metal-binding site. An ATP hydrolase (ATPase) site at the interface of two RecA-like domains (RDs) is located close to the probable DNA-binding site for translocation, which is far from the NTD nucleolytic core. Comparison of relative domain arrangements with other functionally related ATP and/or DNA complex structures suggests a possible translocation and restriction mechanism of the HsdR subunit. Furthermore, careful analysis of its sequence and structure implies that a linker helix connecting two RDs and an extended region within the nuclease domain may play a central role in switching the DNA translocation into the restriction activity.     

On the structure and operation of type I DNA restriction enzymes.

Type I DNA restriction enzymes are large, molecular machines possessing DNA methyltransferase, ATPase, DNA translocase and endonuclease activities. The ATPase, DNA translocase and endonuclease activities are specified by the restriction (R) subunit of the enzyme. We demonstrate that the R subunit of the Eco KI type I restriction enzyme comprises several different functional domains. An N-terminal domain contains an amino acid motif identical with that forming the catalytic site in simple restriction endonucleases, and changes within this motif lead to a loss of nuclease activity and abolish the restriction reaction. The central part of the R subunit contains amino acid sequences characteristic of DNA helicases. We demonstrate, using limited proteolysis of this subunit, that the helicase motifs are contained in two domains. Secondary structure prediction of these domains suggests a structure that is the same as the catalytic domains of DNA helicases of known structure. The C-terminal region of the R subunit can be removed by elastase treatment leaving a large fragment, stable in the presence of ATP, which can no longer bind to the other subunits of Eco KI suggesting that this domain is required for protein assembly. Considering these results and previous models of the methyltransferase part of these enzymes, a structural and operational model of a type I DNA restriction enzyme is presented.     

Structure of mammalian DNA methyltransferase as deduced from the inferred amino acid sequence and direct studies of the protein

DNA (cytosine-5)-methyltransferase (DNA MeTase) establishes and maintains methylation patterns in the genome of higher eukaryotes. This enzyme has been purified, and the cDNA which encodes it has been cloned and sequenced. DNA MeTase appears to contain a large (1000 amino acid) N-terminal domain that contains potential metal-binding sites. This domain appears to contain a series of five to seven structural units of Mr about 20,000, since post-translational processing in vivo or partial proteolysis of the purified protein in vitro leads to the production of a series of catalytically active species differing in Mr by units of 20,000. The N-terminal domain is fused to a smaller (570 amino acid) C-terminal domain that is related to bacterial type II cytosine methyltransferases. The relevance of these findings for the biological function of DNA MeTase is discussed.     

CXXC domain of human DNMT1 is essential for enzymatic activity

DNA cytosine methylation is one of the major epigenetic gene silencing marks in the human genome facilitated by DNA methyltransferases. DNA cytosine-5 methyltransferase 1 (DNMT1) performs maintenance methylation in somatic cells. In cancer cells, DNMT1 is responsible for the aberrant hypermethylation of CpG islands and the silencing of tumor suppressor genes. Here we show that the catalytically active recombinant DNMT1, lacking 580 amino acids from the amino terminus, binds to unmethylated DNA with higher affinity than hemimethylated or methylated DNA. To further understand the binding domain of enzyme, we have used gel shift assay. We have demonstrated that the CXXC region (C is cysteine; X is any amino acid) of DNMT1 bound specifically to unmethylated CpG dinucleotides. Furthermore, mutation of the conserved cysteines abolished CXXC mediated DNA binding. In transfected COS-7 cells, CXXC deleted DNMT1 (DNMT1 (DeltaCXXC)) localized on replication foci. Both point mutant and DNMT1 (DeltaCXXC) enzyme displayed significant reduction in catalytic activity, confirming that this domain is crucial for enzymatic activity. A permanent cell line with DNMT1 (DeltaCXXC) displayed partial loss of genomic methylation on rDNA loci, despite the presence of endogenous wild-type enzyme. Thus, the CXXC domain encompassing the amino terminus region of DNMT1 cooperates with the catalytic domain for DNA methyltransferase activity.     

Interactions within the mammalian DNA methyltransferase family

Background  

In mammals, epigenetic information is established and maintained via the postreplicative methylation of cytosine residues by the DNA methyltransferases Dnmt1, Dnmt3a and Dnmt3b. Dnmt1 is required for maintenance methylation whereas Dnmt3a and Dnmt3b are responsible for de novo methylation. Contrary to Dnmt3a or Dnmt3b, the isolated C-terminal region of Dnmt1 is catalytically inactive, despite the presence of the sequence motifs typical of active DNA methyltransferases. Deletion analysis has revealed that a large part of the N-terminal domain is required for enzymatic activity.     

Recombinant human DNA (cytosine-5) methyltransferase. I. Expression, purification, and comparison of de novo and maintenance methylation.

A method is described to express and purify human DNA (cytosine-5) methyltransferase (human DNMT1) using a protein splicing (intein) fusion partner in a baculovirus expression vector. The system produces approximately 1 mg of intact recombinant enzyme >95% pure per 1.5 x 10(9) insect cells. The protein lacks any affinity tag and is identical to the native enzyme except for the two C-terminal amino acids, proline and glycine, that were substituted for lysine and aspartic acid for optimal cleavage from the intein affinity tag. Human DNMT1 was used for steady-state kinetic analysis with poly(dI-dC).poly(dI-dC) and unmethylated and hemimethylated 36- and 75-mer oligonucleotides. The turnover number (k(cat)) was 131-237 h(-1) on poly(dI-dC).poly(dI-dC), 1.2-2.3 h(-1) on unmethylated DNA, and 8.3-49 h(-1) on hemimethylated DNA. The Michaelis constants for DNA (K(m)(CG)) and S-adenosyl-L-methionine (AdoMet) (K(m)(AdoMet)) ranged from 0.33-1.32 and 2.6-7.2 microM, respectively, whereas the ratio of k(cat)/K(m)(CG) ranged from 3.9 to 44 (237-336 for poly(dI-dC).poly(dI-dC)) x 10(6) M(-1) h(-1). The preference of the enzyme for hemimethylated, over unmethylated, DNA was 7-21-fold. The values of k(cat) on hemimethylated DNAs showed a 2-3-fold difference, depending upon which strand was pre-methylated. Furthermore, human DNMT1 formed covalent complexes with substrates containing 5-fluoro-CNG, indicating that substrate specificity extended beyond the canonical CG dinucleotide. These results show that, in addition to maintenance methylation, human DNMT1 may also carry out de novo and non-CG methyltransferase activities in vivo.