The GATATC-modification enzyme EcoRV is closely related to the GATC-recognizing methyltransferases DpnII and dam from E. coli and phage T4

Investigation of the C-terminal domain of the bacterial DNA-(adenine N6)-methyltransferase CcrM

CcrM-related DNA-(adenine N6)-methyltransferases play very important roles in the biology of Caulobacter crescentus and other alpha-proteobacteria. These enzymes methylate GANTC sequences, but the molecular mechanism by which they recognize their target sequence is unknown. We carried out multiple sequence alignments and noticed that CcrM enzymes contain a conserved C-terminal domain (CTD) which is not present in other DNA-(adenine N6)-methyltransferases and we show here that deletion of this part abrogates catalytic activity and DNA binding of CcrM. A mutational study identified 7 conserved residues in the CTD (out of 13 tested), mutation of which led to a strong reduction in catalytic activity. All of these mutants showed altered DNA binding, but no change in AdoMet binding and secondary structure. Some mutants exhibited reduced DNA binding, but others showed an enhanced DNA binding. Moreover, we show that CcrM does not specifically bind to DNA containing GANTC sequences. Taken together, these findings suggest that the specific CcrM-DNA complex undergoes a conformational change, which is endergonic but essential for catalytic activity and this step is blocked by some of the mutations. Moreover, our data indicate that the CTD of CcrM is involved in DNA binding and recognition. This suggests that the CTD functions as target recognition domain of CcrM and, therefore, CcrM can be considered the first example of a δ-type DNA-(adenine N6)-methyltransferase identified so far.

Conserved sequence motif DPPY in region IV of the phage T4 Dam DNA-[N-adenine]-methyltransferase is important for S-adenosyl-L-methionine binding

Comparison of the deduced amino acid sequences of DNA-[N(6)-adenine]-methyltransferases has revealed several conserved regions. All of these enzymes contain a DPPY-motif, or a variant of it. By site-directed mutagenesis of a cloned T4 dam gene, we have altered the first proline residue in this motif (located in conserved region IV of the T4 Dam-MTase) to alanine or threonine. The mutant enzymic forms, P172A and P172T, were overproduced and purified. Kinetic studies showed that compared to the wild-type (wt) the two mutant enzymic forms had: (i) an increased (6 and 23-fold, respectively) K(m) for substrate, S-adenosyl-methionine (AdoMet) and an increased (6 and 23-fold) K(i) for product, S-adenosyl-homocysteine (AdoHcy); (ii) a slightly reduced (1.5 and 3-fold lower) k(cat); (iii) a strongly reduced k(cat)/K(m) (AdoMet) (10 and 80-fold); and (iv) the same K(m) for substrate DNA. Equilibrium dialysis studies showed that the mutant enzymes had a reduced (3 and 7-fold lower) K(a) for AdoMet; all forms bound two molecules of AdoMet. Taken together these data indicate that the P172A and P172T alterations resulted primarily in a reduced affinity for AdoMet. This suggests that the DPPY-motif is important for AdoMet-binding, and that region IV contains an AdoMet-binding site.

Transition from nonspecific to specific DNA interactions along the substrate-recognition pathway of dam methyltransferase

DNA methyltransferases methylate target bases within specific nucleotide sequences. Three structures are described for bacteriophage T4 DNA-adenine methyltransferase (T4Dam) in ternary complexes with partially and fully specific DNA and a methyl-donor analog. We also report the effects of substitutions in the related Escherichia coli DNA methyltransferase (EcoDam), altering residues corresponding to those involved in specific interaction with the canonical GATC target sequence in T4Dam. We have identified two types of protein-DNA interactions: discriminatory contacts, which stabilize the transition state and accelerate methylation of the cognate site, and antidiscriminatory contacts, which do not significantly affect methylation of the cognate site but disfavor activity at noncognate sites. These structures illustrate the transition in enzyme-DNA interaction from nonspecific to specific interaction, suggesting that there is a temporal order for formation of specific contacts.

The Escherichia coli dam DNA methyltransferase modifies DNA in a highly processive reaction

The Escherichia coli dam adenine-N6 methyltransferase modifies DNA at GATC sequences. It is involved in post-replicative mismatch repair, control of DNA replication and gene regulation. We show that E. coli dam acts as a functional monomer and methylates only one strand of the DNA in each binding event. The preferred way of ternary complex assembly is that the enzyme first binds to DNA and then to S-adenosylmethionine. The enzyme methylates an oligonucleotide containing two dam sites and a 879 bp PCR product with four sites in a fully processive reaction. On lambda-DNA comprising 48,502 bp and 116 dam sites, E. coli dam scans 3000 dam sites per binding event in a random walk, that on average leads to a processive methylation of 55 sites. Processive methylation of DNA considerably accelerates DNA methylation. The highly processive mechanism of E. coli dam could explain why small amounts of E. coli dam are able to maintain the methylation state of dam sites during DNA replication. Furthermore, our data support the general rule that solitary DNA methyltransferase modify DNA processively whereas methyltransferases belonging to a restriction-modification system show a distributive mechanism, because processive methylation of DNA would interfere with the biological function of restriction-modification systems.

Complete nucleotide sequence of the 27-kilobase virulence related locus (vrl) of Dichelobacter nodosus: evidence for extrachromosomal origin

The vrl locus is preferentially associated with virulent isolates of the ovine footrot pathogen, Dichelobacter nodosus. The complete nucleotide sequence of this 27.1-kb region has now been determined. The data reveal that the locus has a G+C content much higher than the rest of the D. nodosus chromosome and contains 22 open reading frames (ORFs) encoding products including a putative adenine-specific methylase, two potential DEAH ATP-dependent helicases, and two products with sequence similarity to a bacteriophage resistance system. These ORFs are all in the same orientation, and most are either overlapping or separated by only a few nucleotides, suggesting that they comprise an operon and are translationally coupled. Expression vector studies have led to the identification of proteins that correspond to many of these ORFs. These data, in combination with evidence of insertion of vrl into the 3' end of an ssrA gene, are consistent with the hypothesis that the vrl locus was derived from the insertion of a bacteriophage or plasmid into the D. nodosus genome.

Mutational analysis of target base flipping by the EcoRV adenine-N6 DNA methyltransferase

DNA methyltransferases flip their target base out of the DNA helix. Here, we have investigated base flipping by wild-type EcoRV DNA methyltransferase (M.EcoRV) and five M.EcoRV variants (D193A, Y196A, S229A, W231R and Y258A). These variants bind to DNA and S-adenosylmethionine but have a severely reduced catalytic efficiency or are catalytically inactive. To measure base flipping three different assays were used, viz. analysis of the yields of photocrosslinking reactions between the enzymes and a substrate in which the target base is replaced by 5-iodouracil, analysis of the binding constants to substrates containing a mismatch base-pair at the target position and analysis of the salt dependence of specific complex formation. Our data show that the Y196A, W231R and Y258A variants are not able to stabilize a flipped target base, suggesting that the aromatic amino acid residues (Tyr196, Trp231 and Tyr258) are involved in hydrophobic interactions with the flipped base. The D193A variant behaves like wild-type M.EcoRV with respect to base flipping. The fact that this variant is catalytically inactive indicates that Asp193 has a function in chemical catalysis. The S229A variant can better flip modified bases but does not tightly lock the flipped base into the adenine-binding pocket, suggesting that Ser229 could form a contact to the flipped adenine.

Functional roles of conserved amino acid residues in DNA methyltransferases investigated by site-directed mutagenesis of the EcoRV adenine-N6-methyltransferase

All DNA methyltransferases (MTases) have similar catalytic domains containing nine blocks of conserved amino acid residues. We have investigated by site-directed mutagenesis the function of 17 conserved residues in the EcoRV alpha-adenine-N6-DNA methyltransferase. The structure of this class of MTases has been predicted recently. The variants were characterized with respect to their catalytic activities and their abilities to bind to DNA and the S-adenosylmethionine (AdoMet) cofactor. Amino acids located in motifs X, I, and II are shown to be involved in AdoMet binding (Lys16, Glu37, Phe39, and Asp58). Some of the mutants defective in AdoMet binding are also impaired in DNA binding, suggesting allosteric interactions between the AdoMet and DNA binding site. Asp78 (motif III), which was supposed to form a hydrogen bond to the AdoMet on the basis of the structure predictions, turned out not to be important for AdoMet binding, suggesting that motif III has not been identified correctly. R128A and N130A, having mutations in the putative DNA binding domain, are unable to bind to DNA. Residues located in motifs IV, V, VI, and VIII are involved in catalysis (Asp193, Tyr196, Asp211, Ser229, Trp231, and Tyr258), some of them presumably in binding the flipped target base, because mutations at these residues fail to significantly interfere with DNA and AdoMet binding but strongly reduce catalysis. Our results are in substantial agreement with the structure prediction for EcoRV alpha-adenine-N6-methyltransferase and x-ray structures of other MTases.

Functional mapping of the EcoRV DNA methyltransferase by random mutagenesis and screening for catalytically inactive mutants

M.EcoRV is an alpha-adenine DNA methyltransferase. According to structure predictions, the enzyme consists of a catalytic domain, which has a structure similar to all other DNA-methyltransferases, and a smaller DNA-recognition domain. We have investigated this enzyme by random mutagenesis, using error-prone PCR, followed by selection for catalytically inactive mutants. 20 single mutants were identified that are completely inactive in vivo as His6- and GST-fusion proteins. 13 of them could be overexpressed and purified. All of these mutants are also inactive in vitro. 5 of the mutations are located near the putative binding site for a flipped adenine residue (C192R, D193G, E212G, W231R, N239H). All of these variants bind to DNA, demonstrating the importance of this region of the protein in catalysis. Only the W231R mutant could be purified with high yields. It binds to DNA and AdoMet and, thus, behaves like a bona fide active site mutant. According to the structure prediction Trp231 corresponds to Val121 in M.HhaI, which forms a hydrophobic contact to the flipped target cytosine. 4 of the remaining purified variants are located within a small region of the putative DNA-recognition domain (F115S, F117L, S121P, C122Y). F117L, S121P and C122Y are unable to bind to DNA, suggesting a critical role of this region in DNA binding. Taken together, these results are in good agreement with the structural model of M.EcoRV.

Kinetics of methylation and binding of DNA by the EcoRV adenine-N6 methyltransferase

The EcoRV DNA methyltransferase (M.EcoRV) specifically methylates the first adenine within its recognition sequence GATATC. Methylation rates of DNA by this enzyme are strongly influenced by the length of oligonucleotide substrates employed. If substrates >20 bp compared to a 12mer substrate, the kcat/Km increases 100-fold, although the enzyme does not contact more than 12 base-pairs on the DNA. Single-turnover rates are higher than kcat values. M.EcoRV binding to DNA is fast but dissociation from the DNA is slow, demonstrating that the multiple-turnover rate is limited by the rate of product release. The kinetics of DNA binding by M.EcoRV are not in accordance with the thermodynamics binding constant, suggesting that the M.EcoRV-DNA complex is involved in a slow conformational change. The salt dependence of DNA binding is different for non-specific substrates (d ln(KAss)/d ln(cNaCl) = - 2, indicative of electrostatic interactions) and specific substrates (d ln(KAss)/d ln(cNaCl) = + 1, indicative of hydrophobic interactions). This result demonstrates that the M.EcoRV-DNA complex has a different conformation in both binding modes. M.EcoRV does not discriminate between hemimethylated and unmethylated substrates. Using the 20mer we have analyzed the temperature and pH dependence of the single-turnover rate constant of M.EcoRV-DNA methylation by M.EcoRV has an activation energy of 40 kJ/mol and its rate increases with increasing pH. The pH dependence reveals the presence of an ionizable residue with a pKa of 7.9, which must be unprotonated for catalysis. The rates of DNA methylation remain unchanged if an abasic site is introduced instead of the thymidine residue that is base-paired to the target adenine, demonstrating that flipping out the target adenine cannot contribute to the rate-limiting step of the enzymatic reaction.

Function of Pro-185 in the ProCys of conserved motif IV in the EcoRII [cytosine-C5]-DNA methyltransferase

ProCys in the conserved sequence motif IV of [cytosine-C5]-DNA methyltransferases is known to be part of the catalytic site. The Cys residue is directly involved in forming a covalent bond with the C6 of the target cytosine. We have found that substitution of Pro-185 with either Ala or Ser resulted in a reduced rate of methyl group transfer by the EcoRII DNA methyltransferase. In addition, we observed an increase in the Km for substrate S-adenosyl-L-methionine (AdoMet), but a decrease in the Km for substrate DNA. This is reflected in minor changes in kcat/Km for DNA, but in 10- to 100-fold reductions in kcat/Km for AdoMet. This suggests that Pro-185 is important to properly orient the activated cytosine and AdoMet for methyl group transfer by direct interaction with AdoMet and indirectly via the Cys interaction with cytosine.

Evidence for an evolutionary relationship among type-II restriction endonucleases

Type-II restriction-modification (R-M) systems comprise two enzymes, a DNA methyltransferase (MTase) and a restriction endonuclease (ENase), each of which specifically interact with the same 4-8 bp sequence. All type-II MTases share several amino acid (aa) sequence motifs, which makes an evolutionary relatedness among these enzymes probable. The type-II ENases, in contrast, except for some homologous isoschizomers, do not share significant aa sequence similarity. Therefore, ENases in general have been considered unrelated. Here we show that in addition to the analysis of the genotype (aa sequence), a comparison of the phenotype (recognition sequence) of these enzymes can provide independent information regarding evolutionary relationships, and thereby, help to analyze the significance of weak aa sequence similarities. Multistep Monte-Carlo analyses were employed to demonstrate that the recognition sequences of those ENases, which were found to be related by a progressive multiple aa sequence alignment, are more similar to each other than would be expected by chance. This analysis supports the notion that not only type-II MTases, but also type-II ENases did not arise independently in evolution, but rather evolved from one or a few primordial DNA-modifying and DNA-cleaving enzymes, respectively.

Sequence motifs characteristic for DNA [cytosine-N4] and DNA [adenine-N6] methyltransferases. Classification of all DNA methyltransferases

Two additional conserved motifs (CM), CM Is and CM III, have been found in addition to well-known CM I and CM II within the primary amino acid sequences of almost all m6A- and m4C-methyltransferases (MTases). The boundaries of all four CM were defined and their consensus sequences characteristic both for different classes, as well as for all N-MTases, were derived. Some regular deviations at fixed positions of the consensus sequences CM Is, CM I and CM II, typical for separate classes of N-MTases, were presumed to correlate. A possible structural basis for the supposed interregional correlations is discussed and experiments for verification of the assumed interactions between CM are suggested. A classification scheme for all N-MTases is provided.

The dam and dcm strains of Escherichia coli--a review

The construction of a variety of strains deficient in the methylation of adenine and cytosine residues in DNA by the methyltransferases (MTases) Dam and Dcm has allowed the study of the role of these enzymes in the biology of Escherichia coli. Dam methylation has been shown to play a role in coordinating DNA replication initiation, DNA mismatch repair and the regulation of expression of some genes. The regulation of expression of dam has been found to be complex and influenced by five promoters. A role for Dcm methylation in the cell remains elusive and dcm- cells have no obvious phenotype. dam- and dcm- strains have a range of uses in molecular biology and bacterial genetics, including preparation of DNA for restriction by some restriction endonucleases, for transformation into other bacterial species, nucleotide sequencing and site-directed mutagenesis. A variety of assays are available for rapid detection of both the Dam and Dcm phenotypes. A number of restriction systems in E. coli have been described which recognise foreign DNA methylation, but ignore Dam and Dcm methylation. Here, we describe the most commonly used mutant alleles of dam and dcm and the characteristics of a variety of the strains that carry these genes. A description of several plasmids that carry dam gene constructs is also included.

Conserved sequence motif DPPY in region IV of the phage T4 Dam DNA-[N6-adenine]-methyltransferase is important for S-adenosyl-L-methionine binding

Comparison of the deduced amino acid sequences of DNA-[N6-adenine]-methyltransferases has revealed several conserved regions. All of these enzymes contain a DPPY [or closely related] motif. By site-directed mutagenesis of a cloned T4 dam gene, we have altered the first proline residue in this motif [located in conserved region IV of the T4 Dam-MTase] to alanine or threonine. The mutant enzymic forms, P172A and P172T, were overproduced and purified. Kinetic studies showed that compared to the wild-type [wt] the two mutant enzymic forms had: (i) an increased [5 and 20-fold, respectively] Km for substrate, S-adenosyl-methionine [AdoMet]; (ii) a slightly reduced [2 and 4-fold lower] kcat; (iii) a strongly reduced kcat/KmAdoMet [10 and 100-fold]; and (iv) almost the same Km for substrate DNA. Equilibrium dialysis studies showed that the mutant enzymes had a reduced [4 and 9-fold lower] Ka for AdoMet. Taken together these data indicate that the P172A and P172T alterations resulted primarily in a reduced affinity for AdoMet. This suggests that the DPPY-motif is important for AdoMet-binding, and that region IV contains or is part of an AdoMet-binding site.

Dam methyltransferase from Escherichia coli: sequence of a peptide segment involved in S-adenosyl-methionine binding

DNA adenine methyltransferase (Dam methylase) has been crosslinked with its cofactor S-adenosyl methionine (AdoMet) by UV irradiation. About 3% of the enzyme was radioactively labelled after the crosslinking reaction performed either with (methyl-3H)-AdoMet or with (carboxy-14C)-AdoMet. Radiolabelled peptides were purified after trypsinolysis by high performance liquid chromatography in two steps. They could not be sequenced due to radiolysis. Therefore we performed the same experiment using non-radioactive AdoMet and were able to identify the peptide modified by the crosslinking reaction by comparison of the separation profiles obtained from two analytical control experiments performed with 3H-AdoMet and Dam methylase without crosslink, respectively. This approach was possible due to the high reproducibility of the chromatography profiles. In these three experiments only one radioactively labelled peptide was present in the tryptic digestions of the crosslinked enzyme. Its sequence was found to be XA-GGK, corresponding to amino acids 10-14 of Dam methylase. The non-identified amino acid in the first sequence cycle should be a tryptophan, which is presumably modified by the crosslinking reaction. The importance of this region near the N-terminus for the structure and function of the enzyme was also demonstrated by proteolysis and site-directed mutagenesis experiments.

The role of the preserved sequences of Dam methylase

We have undertaken a site directed mutational analysis of two of the preserved regions in the amino acid sequence of Dam methylase in order to characterize their role. Mutations in region IV (sequence DPPY) abolish catalytic activity and greatly affect AdoMet crosslinking. Mutants in region III display a lowered specific activity with an unchanged AdoMet crosslinking capacity. We have also made a series of deletions both at the N and C terminal parts of the protein, which have been found to provide inactive enzyme. We discuss the significance of these results for the understanding of the functional properties of the enzyme.

Biology of DNA restriction

Our understanding of the evolution of DNA restriction and modification systems, the control of the expression of the structural genes for the enzymes, and the importance of DNA restriction in the cellular economy has advanced by leaps and bounds in recent years. This review documents these advances for the three major classes of classical restriction and modification systems, describes the discovery of a new class of restriction systems that specifically cut DNA carrying the modification signature of foreign cells, and deals with the mechanisms developed by phages to avoid the restriction systems of their hosts.

Sequence of the Salmonella typhimurium StyLT1 restriction-modification genes: homologies with EcoP1 and EcoP15 type-III R-M systems and presence of helicase domains

The StyLT1 restriction-modification (R-M) system of Salmonella typhimurium has recently been suggested to belong to the type-III R-M systems [De Backer and Colson, Gene 97 (1991) 103-107]. The nucleotide sequences of StyLT1 mod and res have been determined. Two closely adjacent open reading frames were found 12 bp apart with coding capacities of 651 (Mod) and 982 (Res) amino acids (aa), respectively. The genes, lying in the same direction of transcription in the mod-res order, are transcribed as distinct units. The deduced aa sequences reveal homologies with known type-III enzymes from the Escherichia coli P1 prophage, E. coli P15 plasmid and Bacillus cereus chromosome. In addition, the StyLT1 restriction endonuclease (ENase), like other type-I and type-III ENases, contains sequence motifs characteristic of superfamily-II helicases, which may be involved in DNA unwinding at the cleavage site.

Cloning, sequencing, overproduction, and purification of M. CviBI (GANTC) methyltransferase from Chlorella virus NC-1A [corrected]

We have cloned and sequenced the cvibIM gene from Chlorella virus NC-1A by selecting for the modification phenotype. The modification gene was cloned on a 7-kb BamHI fragment inserted into the BamHI site of the pUC13 plasmid. The cvibIM gene was localized at the 3' end of this fragment. Sequencing of this region revealed a large open reading frame that codes for methyltransferase (MTase; symbol M.) (predicting 260 amino acids). M.CviBI (GANTC) aa sequence is homologous to M.Dam(GATC), M.DpnII(GATC), and M.T4 (GATC), and not so to M.HinfI(GANTC), M.HhaII (GANTC), and M.DpnA(GATC). We also describe the use of the polymerase chain reaction technique to alter transcriptional and translational signals surrounding this gene so as to achieve overexpression in Escherichia coli. This construct yields M.CviBI at 2-3% of the total cellular protein. The MTase was purified by phosphocellulose, DEAE, and gel filtration chromatography. Its size by SDS-PAGE is approx. 28 kDa, in good agreement with that predicted from the nucleotide sequence.

Identification of the CTAG-recognizing restriction-modification systems MthZI and MthFI from Methanobacterium thermoformicicum and characterization of the plasmid-encoded mthZIM gene

Two CTAG-recognizing restriction and modification (R/M) systems, designated MthZI and MthFI, were identified in the thermophilic archaeon Methanobacterium thermoformicicum strains Z-245 and FTF, respectively. Further analysis revealed that the methyltransferase (MTase) genes are plasmid-located in both strains. The plasmid pFZ1-encoded mthZIM gene of strain Z-245 was further characterized by subcloning and expression studies in Escherichia coli followed by nucleotide sequence analysis. The mthZIM gene is 1065 bp in size and may code for a protein of 355 amino acids (M(r) 42,476 Da). The deduced amino acid sequence of the M.MthZI enzyme shares substantial similarity with four distinct regions from several m4C- and m6A-MTases, and contains the TSPPY motif that is so far only found in m4C-MTases. Partially overlapping with the mthZIM gene and in reverse orientation, an additional ORF was identified with a size of 606 bp potentially coding for a protein of 202 amino acids (M(r) 23.710 Da). This ORF is suggested to encode the corresponding endonuclease R.MthZI.

Overexpression of the wild-type gene coding for Escherichia coli DNA adenine methylase (dam)

The gene coding for Escherichia coli dam methylase was isolated from a dam+ K12 strain by the PCR method. The gene was subcloned into an overexpression vector under the control of the strong lambda PL promoter. The resultant construct produced the dam methylase at about 20% of total cellular protein. Purification of the protein was achieved with two chromatography columns and yielded 6 mg of pure methylase per gram cell paste. The methylase readily methylates the synthetic dodecamer GACTGATCAGTC containing its recognition sequence (underlined). It also methylates a synthetic dodecamer containing the EcoRV recognition sequence GATATC. However, methyl transfer is to the second adenine in the EcoRV sequence.

Genetic organization of the KpnI restriction--modification system

The KpnI restriction-modification (KpnI RM) system was previously cloned and expressed in E. coli. The nucleotide sequences of the KpnI endonuclease (R.KpnI) and methylase (M. KpnI) genes have now been determined. The sequence of the amino acid residues predicted from the endonuclease gene DNA sequence and the sequence of the first 12 NH2-terminal amino acids determined from the purified endonuclease protein were identical. The kpnIR gene specifies a protein of 218 amino acids (MW: 25,115), while the kpnIM gene codes for a protein of 417 amino acids (MW: 47,582). The two genes transcribe divergently with a intergeneic region of 167 nucleotides containing the putative promoter regions for both genes. No protein sequence similarity was detected between R.KpnI and M.KpnI. Comparison of the amino acid sequence of M.KpnI with sequences of various methylases revealed a significant homology to N6-adenine methylases, a partial homology to N4-cytosine methylases, and no homology to C5-methylases.

Identification and sequence analysis of a methylase gene in Porphyromonas gingivalis

A gene from the periodontal organism Porphyromonas gingivalis has been identified as encoding a DNA methylase. The gene, referred to as pgiIM, has been sequenced and found to contain a reading frame of 864 basepairs. The putative amino acid sequence of the encoded methylase was 288 amino acids, and shared 47% and 31% homology with the Streptococcus pneumoniae DpnII and E. coli Dam methylases, respectively. The activity and specificity of the pgi methylase (M.PgiI) was confirmed by cloning the gene into a dam- strain of E. coli (JM110) and performing a restriction analysis on the isolated DNA with enzymes whose activities depended upon the methylation state of the DNA. The data indicated that M.PgiI, like DpnII and Dam, methylated the adenine residue within the sequence 5'-GATC-3'.

Crosslinking of Dam methyltransferase with S-adenosyl-methionine

Highly purified DNA-adenine methyltransferase was irradiated in the presence of different concentrations of radiolabelled S-adenosyl-methionine (AdoMet) with a conventional Mineralight UV-lamp from several minutes up to 1 h while incubating in ice. Incorporation of radioactivity was monitored by electrophoresis of the crosslink between S-adenosyl-methionine and Dam methylase on SDS-polyacrylamide gels followed by fluorography. Crosslinking reached a maximum in presence of 10 microM S-adenosyl-methionine; it was inhibited in the presence of substances which competitively inhibit methylation of DNA by Dam methylase, like sinefungin or S-adenosyl-homocysteine, but not in the presence of non-inhibitors like ATP or S-isobutyl-adenosine. The crosslink obtained was resistant against a wide range of even drastic conditions commonly used in protein and peptide chemistry. Proteins, which do not bind S-adenosyl-methionine, as well as heat inactivated Dam methylase were not photolabelled. After limited proteolysis the radioactive label appeared only in certain of the peptides obtained. From Western blots carried out with polyclonal antibodies produced against a synthetic peptide corresponding in its sequence to amino acids 92-106 of the Dam methylase, the crosslinking of AdoMet could be tentatively mapped at a position after amino acid 106.

Characterization of the cloned BamHI restriction modification system: its nucleotide sequence, properties of the methylase, and expression in heterologous hosts

The BamHI restriction modification system was previously cloned into E. coli and maintained with an extra copy of the methylase gene on a high copy vector (Brooks et al., (1989) Nucl. Acids Res. 17, 979-997). The nucleotide sequence of a 3014 bp region containing the endonuclease (R) and methylase (M) genes has now been determined. The sequence predicts a methylase protein of 423 amino acids, Mr 49,527, and an endonuclease protein of 213 amino acids, Mr 24,570. Between the two genes is a small open reading frame capable of encoding a 102 amino acid protein, Mr 13,351. The M. BamHI enzyme has been purified from a high expression clone, its amino terminal sequence determined, and the nature of its substrate modification studied. The BamHI methylase modifies the internal C within its recognition sequence at the N4 position. Comparisons of the deduced amino acid sequence of M. BamHI have been made with those available for other DNA methylases: among them, several contain five distinct regions, 12 to 22 amino acids in length, of pronounced sequence similarity. Finally, stability and expression of the BamHI system in both E. coli and B. subtilis have been studied. The results suggest R and M expression are carefully regulated in a 'natural' host like B. subtilis.

Cloning and characterization of two tandemly arranged DNA methyltransferase genes of Neisseria lactamica: an adenine-specific M.NlaIII and a cytosine-type methylase

The gene encoding the Neisseria lactamica III DNA methyltransferase (M.NlaIII) which recognizes the sequence CATG has been cloned and expressed in Escherichia coli. DNA sequencing of a 3.125 kb EcoRI-PstI fragment localizes the M. NlaIII gene to a 334 codon open reading frame (ORF) and identifies, 468 bp downstream, a second ORF of 313 amino acids, which is referred to as M.NlaX. Both proteins are detectable in the E. coli coupled in vitro transcription-translation system; they are apparently expressed from separate N. lactamica promoters. The N-terminal half of the previously characterized M.FokI, which methylates adenine in one of the DNA strands with its asymmetric recognition sequence (GGATG), is found to have 41% sequence identity and a further 11.7% sequence similarity with M.NlaIII. Among the conserved amino acids is the wellknown DPPY sequence motif. With one exception, analysis of the nucleotides coding for the DP dipeptide in all known DPPY sequences shows the presence of an inherent DNA adenine methylation (dam) recognition site of GATC. A low level of expression of M.NlaX in E. coli prevents the elucidation of its sequence recognition specificity. Sequence analysis of M.NlaX shows that it is closely related to the group of monospecific 5-methylcytosine DNA methyltransferases (M.EcoRII, Dcm, M.HpaII and M.HhaI) which all have a modified cytosine at the second position of the recognition sequences. Both M.EcoRII and Dcm amino acid sequences are about 50% identical with M.NlaX; a considerable degree of sequence identity is found in the so-called variable region which is believed to be responsible for sequence recognition specificity. M.NlaX is probably the counterpart to the E. coli Dcm in N. lactamica.

Specificity of restriction endonucleases and DNA modification methyltransferases a review (Edition 3)

The properties and sources of all known class-I, class-II and class-III restriction endonucleases (ENases) and DNA modification methyltransferases (MTases) are listed and newly subclassified according to their sequence specificity. In addition, the enzymes are distinguished in a novel manner according to sequence specificity, cleavage position and methylation sensitivity. Furthermore, new nomenclature rules are proposed for unambiguously defined enzyme names. In the various Tables, the enzymes are cross-indexed alphabetically according to their names (Table I), classified according to their recognition sequence homologies (Table II), and characterized within Table II by the cleavage and methylation positions, the number of recognition sites on the DNA of the bacteriophages lambda, phi X174, and M13mp7, the viruses Ad2 and SV40, the plasmids pBR322 and pBR328, and the microorganisms from which they originate. Other tabulated properties of the ENases include relaxed specificities (integrated within Table II), the structure of the generated fragment ends (Table III), interconversion of restriction sites (Table IV) and the sensitivity to different kinds of DNA methylation (Table V). Table VI shows the influence of class-II MTases on the activity of class-II ENases with at least partially overlapping recognition sequences. Table VII lists all class-II restriction endonucleases and MTases which are commercially available. The information given in Table V focuses on the influence of methylation of the recognition sequences on the activity of ENases. This information might be useful for the design of cloning experiments especially in Escherichia coli containing M.EcodamI and M.EcodcmI [H16, M21, U3] or for studying the level and distribution of site-specific methylation in cellular DNA, e.g., 5'- (M)CpG-3' in mammals, 5'-(M)CpNpG-3' in plants or 5'-GpA(M)pTpC-3' in enterobacteria [B29, E4, M30, V4, V13, W24]. In Table IV a cross index for the interconversion of two- and four-nt 5'-protruding ends into new recognition sequences is complied. This was obtained by the fill-in reaction with the Klenow (large) fragment of the E. coli DNA polymerase I (PolIk), or additional nuclease S1 treatment followed by ligation of the modified fragment termini [P3]. Interconversion of restriction sites generates novel cloning sites without the need of linkers. This should improve the flexibility of genetic engineering experiments [K56, P3].(ABSTRACT TRUNCATED AT 400 WORDS)

Cloning, nucleotide sequence, and expression of the HincII restriction-modification system

Two genes, coding for the HincII from Haemophilus influenzae Rc restriction-modification system, were cloned and expressed in Escherichia coli RR1. Their DNA sequences were determined. The HincII methylase (M.HincII) gene was 1,506 base pairs (bp) long, corresponding to a protein of 502 amino acid residues (Mr = 55,330). The HincII endonuclease (R.HincII) gene was 774 bp long, corresponding to a protein of 258 amino acid residues (Mr = 28,490). The amino acid residues predicted from the R.HincII and the N-terminal amino acid sequence of the enzyme found by analysis were identical. These methylase and endonuclease genes overlapped by 1 bp on the H. influenzae Rc chromosomal DNA. The clone, named E. coli RR1-Hinc, overproduced R.HincII. The R.HincII activity of this clone was 1,000-fold that from H. influenzae Rc. The amino acid sequence of M.HincII was compared with the sequences of four other adenine-specific type II methylases. Important homology was found between tne M.HincII and these other methylases.

Cloning and nucleotide sequence of the gene encoding the Ecal DNA methyltransferase

The gene coding for the GGTNACC specific Ecal DNA methyltransferase (M.Ecal) has been cloned in E. coli from Enterobacter cloacae and its nucleotide sequence has been determined. The ecalM gene codes for a protein of 452 amino acids (Mr: 51,111). It was determined that M.Ecal is an adenine methyltransferase. M.Ecal shows limited amino acid sequence similarity to other adenine methyltransferases. A clone that expresses Ecal methyltransferase at high level was constructed.

Sequence motifs characteristic of DNA[cytosine-N4]methyltransferases: similarity to adenine and cytosine-C5 DNA-methylases

The sequences coding for DNA[cytosine-N4]methyltransferases MvaI (from Micrococcus varians RFL19) and Cfr9I (from Citrobacter freundii RFL9) have been determined. The predicted methylases are proteins of 454 and 300 amino acids, respectively. Primary structure comparison of M.Cfr9I and another m4C-forming methylase, M.Pvu II, revealed extended regions of homology. The sequence comparison of the three DNA[cytosine-N4]-methylases using originally developed software revealed two conserved patterns, DPF-GSGT and TSPPY, which were found similar also to those of adenine and DNA[cytosine-C5]-methylases. These data provided a basis for global alignment and classification of DNA-methylase sequences. Structural considerations led us to suggest that the first region could be the binding site of AdoMet, while the second is thought to be directly involved in the modification of the exocyclic amino group.

Nucleotide sequence of the FokI restriction-modification system: separate strand-specificity domains in the methyltransferase

The genes for FokI, a type-IIS restriction-modification system from Flavobacterium okeanokoites (asymmetric recognition sequence: 5'-GGATG/3'-CCTAC), were cloned into Escherichia coli. Recombinants carrying the fokIR and fokIM genes were found to modify their DNA completely, and to restrict lambdoid phages weakly. The nt sequences of the genes were determined, and the probable start codons were confirmed by aa sequencing. The FokI endonuclease (R.FokI) and methyltransferase (M.FokI) are encoded by single, adjacent genes, aligned in the same orientation, in the order M then R. The genes are large by the standards of type-II systems, 1.9 kb for the M gene, and 1.7 kb for the R gene. Preceding each gene is a pair of FokI recognition sites; it is conceivable that interactions between the sites and the FokI proteins could regulate expression of the genes. The aa sequences of the N- and C-terminal halves of M.FokI are similar to one another, and to certain other DNA-adenine methyltransferases, suggesting that the enzyme has a 'tandem' structure, such as could have arisen by the fusion of a pair of adjacent, ancestral M genes. Truncated derivatives of M. FokI were constructed by deleting the 5'- or 3'-ends of the fokIM gene. Deleting most of the C-terminus of M.FokI produced derivatives that methylated only the top (GGATG) strand of the recognition sequence. Conversely, deleting most of the N-terminus produced derivatives that methylated only the bottom (CATCC) strand of the recognition sequence. These results indicate that the domains in M.FokI for methylating the two strands of the recognition sequence are largely separate.

Sequence, internal homology and high-level expression of the gene for a DNA-(cytosine N4)-methyltransferase, M.Pvu II

The base sequence of the pvuIIM gene has been determined. This gene codes for a DNA-(cytosine N4)-methyltransferase, M.Pvu II. The base sequence contains a single large open reading frame that predicts a 38.3kDa polypeptide, consistent with experimental data. The pvuIIM gene contains some sequences common to DNA methyltransferases in general, but includes none of the sequences specifically conserved among DNA-(cytosine 5)-methyltransferases. The pvuIIM sequence also reveals an internal homology at the amino acid level, each half of which spans over 100 amino acids and is itself homologous to the sequences of some DNA-(adenine N6)-methyltransferases. A derivative of the pvuIIM plasmid was constructed to allow high-level production of M.Pvu II. Specifically, the composite Ptac promoter was inserted 5' to pvuIIM, intervening DNA was deleted, and the resulting construct was used to transform an mcrB laclq strain of Escherichia coli. When this transformant was induced with isopropyl-B-D-galactopyranoside (IPTG), growth rapidly ceased and M.Pvu II accumulated to the point of comprising over 10% of the total soluble protein.

Cloning and characterization of the genes encoding the MspI restriction modification system

The genes encoding the MspI restriction modification system, which recognizes the sequence 5' CCGG, have been cloned into pUC9. Selection was based on expression of the cloned methylase gene which renders plasmid DNA insensitive to MspI cleavage in vitro. Initially, an insert of 15 kb was obtained which, upon subcloning, yielded a 3 kb EcoRI to HindIII insert, carrying the genes for both the methylase and the restriction enzyme. This insert has been sequenced. Based upon the sequence, together with appropriate subclones, it is shown that the two genes are transcribed divergently with the methylase gene encoding a polypeptide of 418 amino acids, while the restriction enzyme is composed of 262 amino acids. Comparison of the sequence of the MspI methylase with other cytosine methylases shows a striking degree of similarity. Especially noteworthy is the high degree of similarity with the HhaI and EcoRII methylases.

M.FokI methylates adenine in both strands of its asymmetric recognition sequence

M.FokI, a type-IIS modification enzyme from Flavobacterium okeanokoites, was purified, and its activity was characterized in vitro. The enzyme was found to be a DNA-adenine methyltransferase and to methylate both strands of the asymmetric FokI recognition sequence: (formula; see text) M.FokI does not methylate single-stranded DNA, nor does it methylate double-stranded DNA at sequences other than FokI sites.

Predictive motifs derived from cytosine methyltransferases

Thirteen bacterial DNA methyltransferases that catalyze the formation of 5-methylcytosine within specific DNA sequences possess related structures. Similar building blocks (motifs), containing invariant positions, can be found in the same order in all thirteen sequences. Five of these blocks are highly conserved while a further five contain weaker similarities. One block, which has the most invariant residues, contains the proline-cysteine dipeptide of the proposed catalytic site. A region in the second half of each sequence is unusually variable both in length and sequence composition. Those methyltransferases that exhibit significant homology in this region share common specificity in DNA recognition. The five highly conserved motifs can be used to discriminate the known 5-methylcytosine forming methyltransferases from all other methyltransferases of known sequence, and from all other identified proteins in the PIR, GenBank and EMBL databases. These five motifs occur in a mammalian methyltransferase responsible for the formation of 5-methylcytosine within CG dinucleotides. By searching the unidentified open reading frames present in the GenBank and EMBL databases, two potential 5-methylcytosine forming methyltransferases have been found.