Purification and characterization of the MspI DNA methyltransferase cloned and overexpressed in E. coli

Flexibility of the linker between the domains of DNA methyltransferase SsoII revealed by small-angle X-ray scattering: implications for transcription regulation in SsoII restriction-modification system

(Cytosine-5)-DNA methyltransferase SsoII (M.SsoII) consists of a methyltransferase domain (residues 72-379) and an N-terminal region (residues 1-71) which regulates transcription in SsoII restriction-modification system. Small-angle X-ray scattering (SAXS) is employed here to study the low resolution structure of M.SsoII and its complex with DNA containing the methylation site. The shapes reconstructed ab initio from the SAXS data reveal two distinct protein domains of unequal size. The larger domain matches the crystallographic structure of a homologous DNA methyltransferase HhaI (M.HhaI), and the cleft in this domain is occupied by DNA in the model of the complex reconstructed from the SAXS data. This larger domain can thus be identified as the methyltransferase domain whereas the other domain represents the N-terminal region. Homology modeling of the M.SsoII structure is performed by using the model of M.HhaI for the methyltransferase domain and representing the N-terminal region either as a flexible chain of dummy residues or as a rigid structure of a homologous protein (phage 434 repressor) connected to the methyltransferase domain by a short flexible linker. Both models are compatible with the SAXS data and demonstrate high mobility of the N-terminal region. The linker flexibility might play an important role in the function of M.SsoII as a transcription factor.

Efficient deamination of 5-methylcytosines in DNA by human APOBEC3A, but not by AID or APOBEC3G

The AID/APOBEC family of enzymes in higher vertebrates converts cytosines in DNA or RNA to uracil. They play a role in antibody maturation and innate immunity against viruses, and have also been implicated in the demethylation of DNA during early embryogenesis. This is based in part on reported ability of activation-induced deaminase (AID) to deaminate 5-methylcytosines (5mC) to thymine. We have reexamined this possibility for AID and two members of human APOBEC3 family using a novel genetic system in Escherichia coli. Our results show that while all three genes show strong ability to convert C to U, only APOBEC3A is an efficient deaminator of 5mC. To confirm this, APOBEC3A was purified partially and used in an in vitro deamination assay. We found that APOBEC3A can deaminate 5mC efficiently and this activity is comparable to its C to U deamination activity. When the DNA-binding segment of AID was replaced with the corresponding segment from APOBEC3A, the resulting hybrid had much higher ability to convert 5mC to T in the genetic assay. These and other results suggest that the human AID deaminates 5mC’s only weakly because the 5-methyl group fits poorly in its DNA-binding pocket.

Functional analysis of an acid adaptive DNA adenine methyltransferase from Helicobacter pylori 26695

HP0593 DNA-(N(6)-adenine)-methyltransferase (HP0593 MTase) is a member of a Type III restriction-modification system in Helicobacter pylori strain 26695. HP0593 MTase has been cloned, overexpressed and purified heterologously in Escherichia coli. The recognition sequence of the purified MTase was determined as 5'-GCAG-3'and the site of methylation was found to be adenine. The activity of HP0593 MTase was found to be optimal at pH 5.5. This is a unique property in context of natural adaptation of H. pylori in its acidic niche. Dot-blot assay using antibodies that react specifically with DNA containing m6A modification confirmed that HP0593 MTase is an adenine-specific MTase. HP0593 MTase occurred as both monomer and dimer in solution as determined by gel-filtration chromatography and chemical-crosslinking studies. The nonlinear dependence of methylation activity on enzyme concentration indicated that more than one molecule of enzyme was required for its activity. Analysis of initial velocity with AdoMet as a substrate showed that two molecules of AdoMet bind to HP0593 MTase, which is the first example in case of Type III MTases. Interestingly, metal ion cofactors such as Co(2+), Mn(2+), and also Mg(2+) stimulated the HP0593 MTase activity. Preincubation and isotope partitioning analyses clearly indicated that HP0593 MTase-DNA complex is catalytically competent, and suggested that DNA binds to the MTase first followed by AdoMet. HP0593 MTase shows a distributive mechanism of methylation on DNA having more than one recognition site. Considering the occurrence of GCAG sequence in the potential promoter regions of physiologically important genes in H. pylori, our results provide impetus for exploring the role of this DNA MTase in the cellular processes of H. pylori.

Dimeric/oligomeric DNA methyltransferases: an unfinished story

DNA methyltransferases (MTases) are enzymes that carry out post-replicative sequence-specific modifications. The initial experimental data on the structure and kinetic characteristics of the EcoRI MTase led to the paradigm that type II systems comprise dimeric endonucleases and monomeric MTases. In retrospect, this was logical because, while the biological substrate of the restriction endonuclease is two-fold symmetrical, the in vivo substrate for the MTase is generally hemi-methylated and, hence, inherently asymmetric. Thus, the paradigm was extended to include all DNA MTases except the more complex bifunctional type I and type III enzymes. Nevertheless, a gradual enlightenment grew over the last decade that has changed the accepted view on the structure of DNA MTases. These results necessitate a more complex view of the structure and function of these important enzymes.

M1.MboII and M2.MboII type IIS methyltransferases: different specificities, the same target

Methylation of a base in a specific DNA sequence protects the DNA from nucleolytic cleavage by restriction enzymes recognizing the same sequence. The MboII restriction-modification (R-M) system of Moraxella bovis ATCC 10900 consists of a restriction endonuclease gene and two methyltransferase genes. The enzymes encoded by this system recognize an asymmetrical sequence 5'-GAAGA-3'/3'-CTTCT-5'. M1.MboII modifies the last adenine in the recognition sequence 5'-GAAGA-3' to N(6)-methyladenine. A second methylase, M2.MboII, was cloned and purified to electrophoretic homogeneity using a four-step chromatographic procedure. It was demonstrated that M2.MboII modifies the internal cytosine in the recognition sequence 3'-CTTCT-5', yielding N(4)-methylcytosine, and moreover is able to methylate single-stranded DNA. The protein exists in solution as a monomer of molecular mass 30 000+/-1000 Da under denaturing conditions. Divalent cations (Ca(2+), Mg(2+), Mn(2+) and Zn(2+)) inhibit M2.MboII methylation activity. It was found that the isomethylomer M2.NcuI from Neisseria cuniculi ATCC 14688 behaves in the same manner. Functional analysis showed that the complete MboII R-M system, consisting of two methyltransferases genes and the mboIIR gene, is the most stable and the least harmful to bacterial cells.

Binding of MmeI restriction-modification enzyme to its specific recognition sequence is stimulated by S-adenosyl-L-methionine

Restriction endonucleases serve as a very good model for studying specific protein-DNA interaction. MmeI is a very interesting restriction endonuclease, but although it is useful in Serial Analysis of Gene Expression, still very little is known about the mechanism of its interaction with DNA. MmeI is a unique enzyme as besides cleaving DNA it also methylates specific sequence. For endonucleolytic activity MmeI requires Mg(II) and S-adenosyl-l-methionine (AdoMet). AdoMet is a methyl donor in the methylation reaction, but its requirement for DNA cleavage remains unclear. In the present article we investigated MmeI interaction with DNA with the use of numerous methods. Our electrophoretic mobility shift assay revealed formation of two types of specific protein-DNA complexes. We speculate that faster migrating complex consists of one protein molecule and one DNA fragment whereas, slower migrating complex, which appears in the presence of AdoMet, may be a dimer or multimer form of MmeI interacting with specific DNA. Additionally, using spectrophotometric measurements we showed that in the presence of AdoMet, MmeI protein undergoes conformational changes. We think that such change in the enzyme structure, upon addition of AdoMet, may enhance its specific binding to DNA. In the absence of AdoMet MmeI binds DNA to the much lower extent.

Binding of MmeI restriction-modification enzyme to its specific recognition sequence is stimulated by S-adenosyl-L-methionine

Restriction endonucleases serve as a very good model for studying specific protein-DNA interaction. MmeI is a very interesting restriction endonuclease, but although it is useful in Serial Analysis of Gene Expression, still very little is known about the mechanism of its interaction with DNA. MmeI is a unique enzyme as besides cleaving DNA it also methylates specific sequence. For endonucleolytic activity MmeI requires Mg(II) and S-adenosyl-l-methionine (AdoMet). AdoMet is a methyl donor in the methylation reaction, but its requirement for DNA cleavage remains unclear. In the present article we investigated MmeI interaction with DNA with the use of numerous methods. Our electrophoretic mobility shift assay revealed formation of two types of specific protein-DNA complexes. We speculate that faster migrating complex consists of one protein molecule and one DNA fragment whereas, slower migrating complex, which appears in the presence of AdoMet, may be a dimer or multimer form of MmeI interacting with specific DNA. Additionally, using spectrophotometric measurements we showed that in the presence of AdoMet, MmeI protein undergoes conformational changes. We think that such change in the enzyme structure, upon addition of AdoMet, may enhance its specific binding to DNA. In the absence of AdoMet MmeI binds DNA to the much lower extent.

Functional analysis of amino acid residues at the dimerisation interface of KpnI DNA methyltransferase

KpnI DNA-(N6-adenine) methyltransferase (M.KpnI) recognises the sequence 5'-GGTACC-3' and transfers the methyl group from S-adenosyl-L-methionine (AdoMet) to the N6 position of the adenine residue in each strand. Earlier studies have shown that M.KpnI exists as a dimer in solution, unlike most other MTases. To address the importance of dimerisation for enzyme function, a three-dimensional model of M.KpnI was obtained based on protein fold-recognition analysis, using the crystal structures of M.RsrI and M.MboIIA as templates. Residues I146, I161 and Y167, the side chains of which are present in the putative dimerisation interface in the model, were targeted for site-directed mutagenesis. Methylation and in vitro restriction assays showed that the mutant MTases are catalytically inactive. Mutation at the I146 position resulted in complete disruption of the dimer. The replacement of I146 led to drastically reduced DNA and cofactor binding. Substitution of I161 resulted in weakening of the interaction between monomers, leading to both monomeric and dimeric species. Steady-state fluorescence measurements showed that the wild-type KpnI MTase induces structural distortion in bound DNA, while the mutant MTases do not. The results establish that monomeric MTase is catalytically inactive and that dimerisation is an essential event for M.KpnI to catalyse the methyl transfer reaction.

Dimerization of the bacterial RsrI N6-adenine DNA methyltransferase

Dimeric restriction endonucleases and monomeric modification methyltransferases were long accepted as the structural paradigm for Type II restriction systems. Recent studies, however, have revealed an increasing number of apparently dimeric DNA methyltransferases. Our initial characterization of RsrI methyltransferase (M.RsrI) was consistent with the enzyme functioning as a monomer, but, subsequently, the enzyme crystallized as a dimer with 1500 Ų of buried surface area. This result led us to re-examine the biochemical properties of M.RsrI. Gel-shift studies of M.RsrI binding to DNA suggested that binding cooperativity targets hemimethylated DNA preferentially over unmethylated DNA. Size-exclusion chromatography indicated that the M.RsrI–DNA complex had a size and stoichiometry consistent with a dimeric enzyme binding to the DNA. Kinetic measurements revealed a quadratic relationship between enzyme velocity and concentration. Site-directed mutagenesis at the dimer interface affected the kinetics and DNA-binding of the enzyme, providing support for a model proposing an active enzyme dimer. We also identified a conserved motif in the dimer interfaces of the β-class methyltransferases M.RsrI, M.MboIIA and M2.DpnII. Taken together, these data suggest that M.RsrI may be part of a sub-class of MTases that function as dimers.

Structure of the Q237W mutant of HhaI DNA methyltransferase: an insight into protein-protein interactions

We have determined the structure of a mutant (Q237W) of HhaI DNA methyltransferase, complexed with the methyl-donor product AdoHcy. The Q237W mutant proteins were crystallized in the monoclinic space group C2 with two molecules in the crystallographic asymmetric unit. Protein-protein interface calculations in the crystal lattices suggest that the dimer interface has the specific characteristics for homodimer protein-protein interactions, while the two active sites are spatially independent on the outer surface of the dimer. The solution behavior suggests the formation of HhaI dimers as well. The same HhaI dimer interface is also observed in the previously characterized binary (M.HhaI-AdoMet) and ternary (M.HhaI-DNA-AdoHcy) complex structures, crystallized in different space groups. The dimer is characterized either by a non-crystallographic two-fold symmetry or a crystallographic symmetry. The dimer interface involves three segments: the amino-terminal residues 2-8, the carboxy-terminal residues 313-327, and the linker (amino acids 179-184) between the two functional domains--the catalytic methylation domain and the DNA target recognition domain. Both the amino- and carboxy-terminal segments are part of the methylation domain. We also examined protein-protein interactions of other structurally characterized DNA MTases, which are often found as a 2-fold related 'dimer' with the largest dimer interface area for the group-beta MTases. A possible evolutionary link between the Type I and Type II restriction-modification systems is discussed.

Bacteriophage T4Dam DNA-(adenine-N(6))-methyltransferase. Comparison of pre-steady state and single turnover methylation of 40-mer duplexes containing two (un)modified target sites

We analyzed pre-steady state and single turnover kinetics of bacteriophage T4Dam DNA-(adenine-N(6))-methyltransferase-mediated methyl group transfer from S-adenosyl-l-methionine (AdoMet) to 40-mer duplexes containing native recognition sites (5'-GATC/5'-GATC) or some modified variant(s). The results extend a model from studies with single-site 20-mer duplexes. Under pre-steady state conditions, monomeric T4Dam methyltransferase-AdoMet complexes were capable of rapid methylation of adenine residues in 40-mer duplexes containing two sites. During processive movement of T4Dam to the next site, the rate-limiting step was the exchange of the product S-adenosyl-l-homocysteine (AdoHcy) for AdoMet without T4Dam dissociating from the duplex. Consequently, instead of a single exponential rate dependence, complex methylation curves were obtained with at least two pre-steady state steps. With 40-mer duplexes containing a single target site, the kinetics were simpler, fitting a single exponential followed by a linear steady state phase. Single turnover methylation of 40-mer duplexes also proceeded in two stages. First, two dimeric T4Dam-AdoMet molecules bound, and each catalyzed a two-step methylation. Instead of processive movement of T4Dam, a conformational adaptation occurred. We propose that following methyl transfer to one strand, dimeric (T4Dam-AdoMet)-(T4Dam-AdoHcy) was capable of rapidly reorienting itself and catalyzing methyl transfer to the target adenine on the complementary, unmethylated strand. This second stage methyl transfer occurred at a rate about 25-fold slower than in the first step; it was rate-limited by Dam-AdoHcy dissociation or its clearance from the methylated complementary strand. Under single turnover conditions, there was complete methylation of all target adenine residues with each of the two-site 40-mer duplexes.

Crystal structure of MboIIA methyltransferase

DNA methyltransferases (MTases) are sequence-specific enzymes which transfer a methyl group from S-adenosyl-L-methionine (AdoMet) to the amino group of either cytosine or adenine within a recognized DNA sequence. Methylation of a base in a specific DNA sequence protects DNA from nucleolytic cleavage by restriction enzymes recognizing the same DNA sequence. We have determined at 1.74 A resolution the crystal structure of a beta-class DNA MTase MboIIA (M.MboIIA) from the bacterium Moraxella bovis, the smallest DNA MTase determined to date. M.MboIIA methylates the 3' adenine of the pentanucleotide sequence 5'-GAAGA-3'. The protein crystallizes with two molecules in the asymmetric unit which we propose to resemble the dimer when M.MboIIA is not bound to DNA. The overall structure of the enzyme closely resembles that of M.RsrI. However, the cofactor-binding pocket in M.MboIIA forms a closed structure which is in contrast to the open-form structures of other known MTases.

Kinetic and catalytic properties of dimeric KpnI DNA methyltransferase

KpnI DNA-(N(6)-adenine)-methyltransferase (KpnI MTase) is a member of a restriction-modification (R-M) system in Klebsiella pneumoniae and recognizes the sequence 5'-GGTACC-3'. It modifies the recognition sequence by transferring the methyl group from S-adenosyl-l-methionine (AdoMet) to the N(6) position of adenine residue. KpnI MTase occurs as a dimer in solution as shown by gel filtration and chemical cross-linking analysis. The nonlinear dependence of methylation activity on enzyme concentration indicates that the functionally active form of the enzyme is also a dimer. Product inhibition studies with KpnI MTase showed that S-adenosyl-l-homocysteine is a competitive inhibitor with respect to AdoMet and noncompetitive inhibitor with respect to DNA. The methylated DNA showed noncompetitive inhibition with respect to both DNA and AdoMet. A reduction in the rate of methylation was observed at high concentrations of duplex DNA. The kinetic analysis where AdoMet binds first followed by DNA, supports an ordered bi bi mechanism. After methyl transfer, methylated DNA dissociates followed by S-adenosyl-l-homocysteine. Isotope-partitioning analysis showed that KpnI MTase-AdoMet complex is catalytically active.

The N-terminus of m5C-DNA methyltransferase MspI is involved in its topoisomerase activity

DNA cytosine methyltransferase MspI (M.MspI) must require a different type of interaction of protein with DNA from other bacterial DNA cytosine methyltransferases (m5C-MTases) to evoke the topoisomerase activity that it possesses in addition to DNA-methylation ability. This may require a different structural organization in the solution phase from the reported consensus structural arrangement for m5C-MTases. Limited proteolysis of M.MspI, however, generates two peptide fragments, a large one (p26) and a small one (p18), consistent with reported m5C-MTase structures. Examination of the amino-acid sequence of M.MspI revealed similarity to human topoisomerase I at the N-terminus. Alignment of the amino-acid sequence of M.MspI also uncovered similarity (residues 245-287) to the active site of human DNA ligase I. To evaluate the role of the N-terminus of M.MspI, 2-hydroxy-5-nitrobenzyl bromide (HNBB) was used to truncate M.MspI between residues 34 and 35. The purified HNBB-truncated protein has a molecular mass of approximately equal 45 kDa, retains DNA binding and methyltransferase activity, but does not possess topoisomerase activity. These findings were substantiated using a purified recombinant MspI protein with the N-terminal 34 amino acids deleted. Changing the N-terminal residues Trp34 and Tyr74 to alanine results in abolition of the topoisomerase I activity while the methyltransferase activity remains intact.

Kinetic mechanism of cytosine DNA methyltransferase MspI

A kinetic analysis of MspI DNA methyltransferase (M.MspI) is presented. The enzyme catalyzes methylation of lambda-DNA, a 50-kilobase pair linear molecule with multiple M.MspI-specific sites, with a specificity constant (kcat/KM) of 0.9 x 10(8) M-1 s-1. But the values of the specificity constants for the smaller DNA substrates (121 and 1459 base pairs (bp)) with single methylation target or with multiple targets (sonicated lambda-DNA) were less by an order of magnitude. Product inhibition of the M.MspI-catalyzed methylation reaction by methylated DNA is competitive with respect to DNA and noncompetitive with respect to S-adenosylmethionine (AdoMet). The S-adenosylhomocysteine inhibition of the methylation reaction is competitive with respect to AdoMet and uncompetitive with respect to DNA. The presteady state kinetic analysis showed a burst of product formation when AdoMet was added to the enzyme preincubated with the substrate DNA. The burst is followed by a constant rate of product formation (0.06 mol per mol of enzyme s-1) which is similar to catalytic constants (kcat = approximately 0.056 s-1) measured under steady state conditions. The isotope exchange in chasing the labeled methyltransferase-DNA complex with unlabeled DNA and AdoMet leads to a reduced burst as compared with the one involving chase with labeled DNA and AdoMet. The enzyme is capable of exchanging tritium at C-5 of target cytosine in the substrate DNA in the absence of cofactor AdoMet. The kinetic data are consistent with an ordered Bi Bi mechanism for the M.MspI-catalyzed DNA methylation where DNA binds first.

Enzyme-mediated cytosine deamination by the bacterial methyltransferase M.MspI

Most prokaryotic (cytosine-5)-DNA methyltransferases increase the frequency of deamination at the cytosine targeted for methylation in vitro in the absence of the cofactor S-adenosylmethionine (AdoMet) or the reaction product S-adenosylhomocysteine (AdoHcy). We show here that, under the same in vitro conditions, the prokaryotic methyltransferase, M.MspI (from Moraxella sp.), causes very few cytosine deaminations, suggesting a mechanism in which M.MspI may avoid enzyme-mediated cytosine deamination. Two analogues of AdoMet, sinefungin and 5'-amino-5'-deoxyadenosine, greatly increased the frequency of cytosine deamination mediated by M.MspI presumably by introducing a proton-donating amino group into the catalytic centre, thus facilitating the formation of an unstable enzyme-dihydrocytosine intermediate and hydrolytic deamination. Interestingly, two naturally occurring analogues, adenosine and 5'-methylthio-5'-deoxyadenosine, which do not contain a proton-donating amino group, also weakly increased the deamination frequency by M.MspI, even in the presence of AdoMet or AdoHcy. These analogues may trigger a conformational change in the enzyme without completely inhibiting the access of solvent water to the catalytic centre, thus allowing hydrolytic deamination of the enzyme-dihydrocytosine intermediate. Under normal physiological conditions the enzymes M.HpaII (from Haemophilus parainfluenzae), M. HhaI (from Haemophilus hemolytica) and M.MspI all increased the in vivo deamination frequency at the target cytosines with comparable efficiency.

Angle and locus of the bend induced by the msp I DNA methyltransferase in a sequence-specific complex with DNA

Bending of DNA induced by M.Msp I, one of the m5C-DNA methyltransferases, has been investigated using circular permutation analysis. The M.Msp I MTase induced sharp bends in DNA containing its recognition sequence 5'-CCGG-3'which was estimated to be 142+/-4 degrees and 132+/-4 degrees for circularly permuted DNA fragments of 127 and 1459 bp respectively. The bend centre was found to be asymmetric with respect to the CCGG sequence and appeared to exclude the 'target cytosine'. An estimate of approximately 15 kcal/mol was obtained for the free energy associated with M.Msp I-induced DNA bending.

Characterization of the intergenic region which regulates the MspI restriction-modification system

The 110-bp intergenic region between mspIM and mspIR, the genes encoding the MspI modification (M.MspI) and restriction (R.MspI) enzymes, respectively, was fused, in both orientations, with lacZ. Expression of a single-copy mspIM-lacZ fusion is more than 400-fold stronger than expression of an mspIR-lacZ fusion. M.MspI in trans represses expression of the mspIM-lacZ fusion by binding to the DNA but does not affect expression of the mspIR-lacZ fusion. Transcription start sites of the genes were identified, and a set of nonoverlapping promoters was assigned. DNase I footprinting showed that M.MspI binds to a site within the intergenic region that includes only the mspIM regulatory elements.

Overproduction, purification and characterization of M.EcoHK31I, a bacterial methyltransferase with two polypeptides

The two overlapping genes coding for EcoHK31I methyltransferase have previously been cloned, sequenced and expressed [Lee, Kam and Shaw (1995) Nucleic Acids Res. 23, 103-108]. Here we describe protocols developed to purify polypeptides alpha and beta together or separately, to apparent homogeneity by various chromatographic media. M.EcoHK31I is a heterodimer with a native molecular mass of 61 kDa. Its specific activity towards non-methylated lambda DNA was 3.0 x 10(5) units per mg of protein. The respective denatured molecular masses of polypeptides alpha and beta were 38 and 23 kDa, and their pI values were 8.7 and 6.8. Initial rate kinetic parameters of the native enzyme were 2.0 nM, 0.58 microM and 3 min-1 for KmDNA, KmAdoMet and kcat. respectively, where AdoMet stands for S-adenosyl-L-methionine. Fully active enzyme was reconstituted by co-purifying the two separately synthesized polypeptides, and activity assays confirmed our previous finding that two polypeptides were needed to methylate substrate DNA.

Phage T4 DNA [N6-adenine]methyltransferase. Overexpression, purification, and characterization

The bacteriophage T4 dam gene, encoding the Dam DNA [N6-adenine]methyltransferase (MTase), has been subcloned into the plasmid expression vector, pJW2. In this construct, designated pINT4dam, transcription is from the regulatable phage lambda pR and pL promoters, arranged in tandem. A two-step purification scheme using DEAE-cellulose and phosphocellulose columns in series, followed by hydroxyapatite chromatography, was developed to purify the enzyme to near homogeneity. The yield of purified protein was 2 mg/g of cell paste. The MTase has an s20,w of 3.0 S and a Stokes radius of 23 A and exists in solution as a monomer. The Km for the methyl donor, S-adenosylmethionine, is 0.1 x 10(-6) M, and the Km for substrate nonglucosylated, unmethylated T4 gt- dam DNA is 1.1 x 10(-12) M. The products of DNA methylation, S-adenosyl-L-homocysteine and methylated DNA, are competitive inhibitors of the reaction; Ki values of 2.4 x 10(-6) M and 4.6 x 10(-12) M, respectively, were observed. T4 Dam methylates the palindromic tetranucleotide, GATC, designated the canonical sequence. However, at high MTase:DNA ratios, T4 Dam can methylate some noncanonical sequences belonging to GAY (where Y represents cytosine or thymine).

Interaction of the MboII restriction endonuclease with DNA

The binding of the MboII restriction endonuclease (R.MboII; ENase) to DNA containing its recognition site was investigated using a mobility shift assay. R.MboII forms specific, stable and immunodetectable complexes with its canonical target sequence. The association constant (Ka) of R.MboII was calculated to be 2.8 x 10(9)/M, and is about 10(4)-fold higher than the Ka value for non-specific binding. Based on results obtained after sedimentation of the R.MboII-DNA complex in a glycerol gradient and measurement of the retardation of the complexes in polyacrylamide gels, we conclude that specific binding to the canonical sequence involves a monomer of R.MboII. DNase I footprinting has shown that the enzyme covers 16 nucleotides of DNA on the 5'-GAAGA-3' strand.

Determination of the order of substrate addition to MspI DNA methyltransferase using a novel mechanism-based inhibitor

The cloning and overexpression of the MspI DNA methyltransferase as a functional fusion with glutathione S-transferase is described. The fusion enzyme retains full biological activity and has been used to investigate the interaction of substrates and inhibitors with MspI DNA methyltransferase. The fusion enzyme has been purified to homogeneity in a single step on GSH-agarose and is free from contaminating exonuclease activity. The enzyme can be photolabelled with S-adenosyl-L-methionine and the level of incorporation of label is enhanced by the presence of a nonspecific DNA duplex. In the presence of a cognate oligodeoxynucleotide, no photolabelling was observed since methyl transfer occurs instead. The inclusion of a mechanism-based inhibitor of C-5 deoxycytidine DNA methylation (an oligodeoxynucleotide containing the base 2-pyrimidinone-1-beta-D-2'-deoxyribofuranoside in the position of the deoxycytidine to which methyl addition occurs), which is thought to form a covalent interaction with the reactive cysteine of such enzymes, led to an enhancement of S-adenosyl-L-methionine photolabelling which suggests that, in contrast with results obtained with EcoRII DNA methyltransferase [Som and Friedman (1991) J. Biol. Chem. 266, 2937-2945], methylcysteine is not the photolabelled product. The implications of the results obtained with this mechanism-based inhibitor are discussed with respect to other C-5-specific DNA methyltransferases. Gel-retardation assays in the presence of cognate oligodeoxynucleotides that contain the reactive pyrimidinone base in place of the deoxycytidine target base are described. These demonstrate that most probably a stable covalent bond is formed between the methyltransferase and this oligodeoxynucleotide. However, the alternative of extremely tight non-covalent binding cannot be rigorously excluded. Furthermore, the results from these experiments indicate that the reaction mechanism proceeds in a manner similar to that of HhaI DNA methyltransferase with sequence-specific DNA binding being followed by addition of S-adenosyl-L-methionine and concomitant isomerization of the ternary complex leading to methyl transfer. S-Adenosyl-L-homocysteine appears to inhibit the reaction pathway as a result of either competition with the methyl donor and potentiation of a high-affinity interaction between the enzyme and DNA in an abortive ternary complex or through an allosteric interaction.

How M.MspI and M.HpaII decide which base to methylate

The HpaII methylase (M.HpaII) recognizes the sequence CCGG and methylates the inner cytosine residue. The MspI methylase (MspI) recognizes the same sequence but methylates the outer cytosine residue. Both methylases have the usual architecture of 10 well-conserved motifs surrounding a variable region, responsible for sequence specific recognition, that is quite different in the two methylases. We have constructed hybrids between these two methylases and studied their methylation properties. A hybrid containing the variable region and C-terminal sequences from M.MspI methylates the outer cytosine residue. A second hybrid identical to the first except that the variable region derives from the M.HpaII methylates the inner cytosine residue. Thus the choice of base to be methylated within the recognition sequence is determined by the variable region.