A dual role for substrate S-adenosyl-L-methionine in the methylation reaction with bacteriophage T4 Dam DNA-[N6-adenine]-methyltransferase.

The fluorescence of 2-aminopurine ((2)A)-substituted duplexes (contained in the GATC target site) was investigated by titration with T4 Dam DNA-(N6-adenine)-methyltransferase. With an unmethylated target ((2)A/A duplex) or its methylated derivative ((2)A/(m)A duplex), T4 Dam produced up to a 50-fold increase in fluorescence, consistent with (2)A being flipped out of the DNA helix. Though neither S-adenosyl-L-homocysteine nor sinefungin had any significant effect, addition of substrate S-adenosyl-L-methionine (AdoMet) sharply reduced the Dam-induced fluorescence with these complexes. In contrast, AdoMet had no effect on the fluorescence increase produced with an (2)A/(2)A double-substituted duplex. Since the (2)A/(m)A duplex cannot be methylated, the AdoMet-induced decrease in fluorescence cannot be due to methylation per se. We propose that T4 Dam alone randomly binds to the asymmetric (2)A/A and (2)A/(m)A duplexes, and that AdoMet induces an allosteric T4 Dam conformational change that promotes reorientation of the enzyme to the strand containing the native base. Thus, AdoMet increases enzyme binding-specificity, in addition to serving as the methyl donor. The results of pre-steady-state methylation kinetics are consistent with this model.

Pre-steady state kinetics of bacteriophage T4 dam DNA-[N(6)-adenine] methyltransferase: interaction with native (GATC) or modified sites.

The DNA methyltransferase of bacteriophage T4 (T4 Dam MTase) recognizes the palindromic sequence GATC, and catalyzes transfer of the methyl group from S:-adenosyl-L-methionine (AdoMet) to the N(6)-position of adenine [generating N(6)-methyladenine and S:-adenosyl-L-homocysteine (AdoHcy)]. Pre-steady state kinetic analysis revealed that the methylation rate constant k(meth) for unmethylated and hemimethylated substrates (0.56 and 0.47 s(-1), respectively) was at least 20-fold larger than the overall reaction rate constant k(cat) (0.023 s(-1)). This indicates that the release of products is the rate-limiting step in the reaction. Destabilization of the target-base pair did not alter the methylation rate, indicating that the rate of target nucleoside flipping does not limit k(meth). Preformed T4 Dam MTase-DNA complexes are less efficient than preformed T4 Dam MTase-AdoMet complexes in the first round of catalysis. Thus, this data is consistent with a preferred route of reaction for T4 Dam MTase in which AdoMet is bound first; this preferred reaction route is not observed with the DNA-[C5-cytosine]-MTases.

Comparative studies of the phage T2 and T4 DNA (N6-adenine)methyltransferases: amino acid changes that affect catalytic activity.

The bacteriophage T2 and T4 dam genes code for a DNA (N6-adenine)methyltransferase (MTase). Nonglucosylated, hydroxymethylcytosine-containing T2gt- virion DNA has a higher level of methylation than T4gt- virion DNA does. To investigate the basis for this difference, we compared the intracellular enzyme levels following phage infection as well as the in vitro intrinsic methylation capabilities of purified T2 and T4 Dam MTases. Results from Western blotting (immunoblotting) showed that the same amounts of MTase protein were produced after infection with T2 and T4. Kinetic analyses with purified homogeneous enzymes showed that the two MTases had similar Km values for the methyl donor, S-adenosyl-L-methionine, and for substrate DNA. In contrast, they had different k(cat) values (twofold higher for T2 Dam MTase). We suggest that this difference can account for the ability of T2 Dam to methylate viral DNA in vivo to a higher level than does T4 Dam. Since the T2 and T4 MTases differ at only three amino acid residues (at positions 20 [T4, Ser; T2, Pro], 26 [T4, Asn; T2, Asp], and 188 [T4, Asp; T2, Glu]), we have produced hybrid proteins to determine which residue(s) is responsible for increased catalytic activity. The results of these analyses showed that the residues at positions 20 and 26 are responsible for the different k(cat) values of the two MTases for both canonical and noncanonical sites. Moreover, a single substitution of either residue 20 or 26 was sufficient to increase the k(cat) of T4 Dam.

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.

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).

Studies on the function of conserved sequence motifs in the T4 Dam-[N6-adenine] and EcoRII [C5-cytosine] DNA methyltransferases.

We used site-directed oligodeoxyribonucleotide-mediated mutagenesis and kinetic studies with purified wild-type (wt) and mutant proteins to evaluate the role of the conserved sequence motifs in two prokaryotic DNA MTases. We suggest that: (i) the main role of Pro in the M.EcoRII PC-motif is to restrict the conformational freedom of Cys and orient it in a manner essential for catalysis; (ii) in both M.EcoRII and T4 Dam the FXGXG-motif positions AdoMet with respect to the catalytic site; (iii) the DPPY-motif in T4 Dam (region IV) is important for AdoMet-binding and may be part of the binding site; and (iv) the RXNXKXXFXXPFK-motif in T4 Dam (region III) is part of the DNA binding/recognition domain.

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.

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.

The UV excision-repair system of Saccharomyces cerevisiae is involved in the removal of methylcytosines formed in vivo by a cloned prokaryotic DNA methyltransferase.

DNA methyltransferase activity is not normally found in yeast. To investigate the response of Saccharomyces cerevisiae to the presence of methylated bases, we introduced the Bacillus subtilis SPR phage DNA-[cytosine-5] methyltransferase gene on the shuttle vector, YEp51. The methyltransferase gene was functionally expressed in yeast under the control of the inducible yeast GAL 10 promoter. Following induction we observed a time-dependent methylation of yeast DNA in RAD+ and rad2 mutant strains; the rad2 mutant is defective in excision-repair of UV-induced DNA damage. Analysis of restriction endonuclease digestion patterns revealed that the relative amount of methylated DNA was greater in the excision defective rad2 mutant than in the RAD+ strain. These data indicate that the yeast excision-repair system is capable of recognizing and removing m5C residues.

The bacteriophage T2 and T4 DNA-[N6-adenine] methyltransferase (Dam) sequence specificities are not identical.

Bacteriophages T2 and T4 encode DNA-[N6-adenine] methyltransferases (Dam) which differ from each other by only three amino acids. The canonical recognition sequence for these enzymes in both cytosine and 5-hydroxymethylcytosine-containing DNA is GATC; at a lower efficiency they also recognize some non-canonical sites in sequences derived from GAY (where Y is cytosine or thymine). We found that T4 Dam fails to methylate certain GATA and GATT sequences which are methylated by T2 Dam. This indicates that T2 Dam and T4 Dam do not have identical sequence specificities. We analyzed DNA sequence data files obtained from GenBank, containing about 30% of the T4 genome, to estimate the overall frequency of occurrence of GATC, as well as non-canonical sites derived from GAY. The observed N6methyladenine (m6A) content of T4 DNA, methylated exclusively at GATC (by Escherichia coli Dam), was found to be in good agreement with this estimate. Although GATC is fully methylated in virion DNA, only a small percentage of the non-canonical sequences are methylated.

Single amino acid changes that alter the DNA sequence specificity of the DNA-[N6-adenine] methyltransferase (Dam) of bacteriophage T4.

Bacteriophage T4 codes for a DNA-[N6-adenine] methyltransferase (Dam) which recognizes primarily the sequence GATC in both cytosine- and hydroxymethylcytosine-containing DNA. Hypermethylating mutants, damh, exhibit a relaxation in sequence specificity, that is, they are readily able to methylate non-canonical sites. We have determined that the damh mutation produces a single amino acid change (Pro126 to Ser126) in a region of homology (III) shared by three DNA-adenine methyltransferases; viz, T4 Dam, Escherichia coli Dam, and the DpnII modification enzyme of Streptococcus pneumoniae. We also describe another mutant, damc, which methylates GATC in cytosine-containing DNA, but not in hydroxymethylcytosine-containing DNA. This mutation also alters a single amino acid (Phe127 to Val127). These results implicate homology region III as a domain involved in DNA sequence recognition. The effect of several different amino acids at residue 126 was examined by creating a polypeptide chain terminating codon at that position and comparing the methylation capability of partially purified enzymes produced in the presence of various suppressors. No enzyme activity is detected when phenylalanine, glutamic acid, or histidine is inserted at position 126. However, insertion of alanine, cysteine, or glycine at residue 126 produces enzymatic activity similar to Damh.

The DNA [adenine-N6]methyltransferase (Dam) of bacteriophage T4.

A functional bacteriophage T4 dam+ gene, which specifies a DNA [adenine-N6]methyltransferase (Dam), was cloned on a 1.8-kb HindIII fragment [Schlagman and Hattman, Gene 22 (1983) 139-156]. Sequence analysis [Macdonald and Mosig, EMBO J. 3 (1984) 2863-2871] revealed two overlapping in-phase open reading frames (ORFs). The 5' proximal ORF initiates translation at an AUG and encodes a 30-kDa polypeptide, whereas the downstream ORF initiates translation at a GUG and encodes a 26-kDa polypeptide. Analysis of BAL 31 deletions in our original dam+ clone has verified that at least one of these overlapping ORFs, in fact, encodes T4 Dam. To investigate where T4 Dam translation is initiated, we have constructed plasmids in which a tac or lambda PL promoter is placed 5' to either the longer ORF or just the shorter ORF. Only clones which contain a promoter in front of the longer ORF produce active T4 Dam. This indicates that the 26-kDa polypeptide alone cannot be T4 Dam. Additional experiments suggest that only the 30-kDa polypeptide is required for enzyme activity and that the shorter ORF is not translated in plasmid-carrying cells. We also present evidence that T4 Dam is capable of methylating 5'-GATC-3', GATm5C, and GAThmC sequences; non-canonical sites (e.g., GACC) are also methylated, but much less efficiently.

Direct role of the Escherichia coli Dam DNA methyltransferase in methylation-directed mismatch repair.

The T4 dam+ gene has been cloned (S. L. Schlagman and S. Hattman, Gene 22:139-156, 1983) and transferred into an Escherichia coli dam-host. In this host, the T4 Dam DNA methyltransferase methylates mainly, if not exclusively, the sequence 5'-GATC-3'; this sequence specificity is the same as that of the E. coli Dam enzyme. Expression of the cloned T4 dam+ gene suppresses almost all the phenotypic traits associated with E. coli dam mutants, with the exception of hypermutability. In wild-type hosts, 20- to 500-fold overproduction of the E. coli Dam methylase by plasmids containing the cloned E. coli dam+ gene results in a hypermutability phenotype (G.E. Herman and P. Modrich, J. Bacteriol. 145:644-646, 1981; M.G. Marinus, A. Poteete, and J.A. Arraj, Gene 28:123-125, 1984). In contrast, the same high level of T4 Dam methylase activity, produced by plasmids containing the cloned T4 dam+ gene, does not result in hypermutability. To account for these results we propose that the E. coli Dam methylase may be directly involved in the process of methylation-instructed mismatch repair and that the T4 Dam methylase is unable to substitute for the E. coli enzyme.

Molecular cloning of a functional dam+ gene coding for phage T4 DNA adenine methylase.

Phages T2 and T4 induce synthesis of a DNA-adenine methylase which is coded for by a phage gene, dam+. These enzymes methylate adenine residues in specific sequences which include G-A-T-C, the methylation site of the host Escherichia coli dam+ methylase. Methylation of G-A-T-C to G-m6A-T-C protects the site against cleavage by the MboI restriction nuclease. We have taken advantage of this property to enrich and screen for transformants which contain a cloned, functional T4 dam+ gene. These recombinant molecules consist of a 1.85-kb HindIII fragment inserted into the plasmid pBR322; both orientations of the fragment express the methylase gene, suggesting that transcription is from a T4 promoter. We have tested the 1.85-kb insert for sensitivity to a variety of restriction nucleases and have found single sites for EcoRI, BalI, XbaI, and at least two sites for BstNI (EcoRII). The relative positions of these restriction sites have also been determined. Physical mapping was carried out by Southern blot hybridization with 32P-labeled (nick-translated clone) probe. These experiments showed that the insert corresponds to a HindIII fragment located on the physical map of T4 between positions 16.2 and 18.1 kb from the T4rIIA-rIIB junction. E. coli dam- possesses several phenotypic differences from the wild-type dam+ parent, including an increased sensitivity to 2-aminopurine (2-AP). We found that T4 dam+ clones could relieve dam- cells of their increased sensitivity to 2-AP.

Complementation of gene deletions by cell hybridization.

Overlapping deletions in chromosome 7 of the mouse are responsible for activity deficiencies of various liver-specific enzymes, including tyrosine aminotransferase (TAT). In an effort to elucidate the nature and type of action of the deleted genes, somatic cell hybridization experiments were carried out. Enzyme-deficient liver cells of homozygous mutant mice or normal liver cells of control newborn mice were hybridized with 2S Faza rat hepatoma cells and the hybrid cell colonies were analyzed for TAT activity, The results show the presence of inducible mouse TAT activity in mutant-2S Faza hybrid cells, thereby excluding the possibility that the structural gene for TAT is included in the gene sequences deleted in the mutants. Furthermore, determinations of mouse glucose-6-phosphate isomerase 1 as a marker eliminate chromosome 7 as the possible carrier of the TAT structural gene, which therefore appears to map on a different chromosome. The deletions interfering with normal enzyme activities apparently include genes other than the respective structural genes, namely those with essential functions in controlling the expression of the differentiated state of the liver cell.