Molecular enzymology of phage T4 Dam DNA-methyltransferase

The review reflects results of studies on the molecular mechanism of phage T4 Dam DNA-methyltransferase action. The enzyme (T4Dam) catalyzes methyl group transfer from S-adenosyl-l-methionine (AdoMet) to N6-adenine position in the palindromic recognition sequence GATC (EC 2.1.1.72). The enzyme subunit structure, substrate-binding and kinetic parameters for a wide range of native and modified oligonucleotide duplexes, as well as steady-state reaction kinetic scheme, included T4Dam isomerization to catalytically active form, are considered. The found mechanisms of DNA induced T4Dam dimerization, target base flipping, enzyme reorientation in an asymmetrically modified recognition sequence, effector action of reaction substrates and processive methylation of DNA substrates, containing more than one specific site, are discussed. The results obtained with T4Dam may be useful for understanding mechanisms of action of other homologous enzymes, most of all for specimens of numerous family of Dam DNA-methyltransferases.     

Differential methylation kinetics of individual target site strands by T4Dam DNA methyltransferase

Prokaryote DNA methyltransferases (MTases) of the Dam family (including those of bacteriophages T2 and T4) catalyze methyl group transfer from S-adenosyl-L-methionine (AdoMet), producing S-adenosyl-L-homocysteine (AdoHcy) and methylated adenine residues in palindromic GATC sequences. Dam DNA MTases, as all site-specific enzymes interacting with polymeric DNA, require a mechanism of action that ensures a rapid search for specific targets for catalytic action, during both the initial and subsequent rounds of methylation. The results of pre-steady-state (reaction burst) and steady-state methylation analyses of individual targets permitted us to monitor the action of T4Dam, which has three degrees of freedom: sliding, reorientation and adaptation to the canonical GATC sequence. The salient results are as follows: (i) 40mer substrate duplexes containing two canonical GATC sites showed differential methylation of the potential targets, i.e., T4Dam exhibited a preference for one site/target, which may present the better 'kinetic trap' for the enzyme. (ii) Prior hemimethylation of the two sites made both targets equally capable of being methylated during the pre-steady-state reaction. (iii) Although capable of moving in either direction along double-stranded DNA, there are some restrictions on T4Dam reorientation/adaptation on 40mer duplexes.     

Bacteriophage T4Dam (DNA-(adenine-N6)-methyltransferase): evidence for two distinct stages of methylation under single turnover conditions

We compared the (pre)steady-state and single turnover methylation kinetics of bacteriophage T4Dam (DNA-(adenine-N6)-methyltransferase)-mediated methyl group transfer from S-adenosyl-l-methionine (AdoMet) to oligodeoxynucleotide duplexes containing a single recognition site (palindrome 5'-GATC/5'-GATC) or some modified variant. T4Dam-AdoMet functions as a monomer under steady-state conditions (enzyme/DNA < 1), whereas under single turnover conditions (enzyme/DNA > 1), a catalytically active complex containing two Dam-AdoMet molecules is formed initially, and two methyl groups are transferred per duplex (to produce a methylated duplex and S-adenosyl-l-homocysteine (AdoHcy)). We propose that the single turnover reaction proceeds in two stages. First, two preformed T4Dam-AdoMet complexes bind opposite strands of the unmodified target site, and one enzyme molecule catalyzes the rapid transfer of the AdoMet-methyl group (kmeth1 = 0.21 s-1); this is 2.5-fold slower than the rate observed with monomeric T4Dam-AdoMet bound under pre-steady-state conditions for burst determination. In the second stage, methyl transfer to adenine in GATC on the complementary strand occurs at a rate that is 1 order of magnitude slower (kmeth2 = 0.023 s-1). We suggest that under single turnover conditions, methylation of the second strand is rate-limited by Dam-AdoHcy dissociation or its clearance from the methylated complementary strand. The hemimethylated duplex 5'-GATC/5'-GMTC also interacts with T4Dam-AdoMet complexes in two stages under single turnover reaction conditions. The first stage (kmeth1) reflects methylation by dimeric T4Dam-AdoMet productively oriented to the strand with the adenine residue capable of methylation. The slower second stage (kmeth2) reflects methylation by enzyme molecules non-productively oriented to the GMTC chain, which then have to re-orient to the opposite productive chain. Substitutions of bases and deletions in the recognition site affect the kinetic parameters in different fashions. When the GAT portion of GATC was disrupted, the proportion of the initial productive enzyme-substrate complexes was sharply reduced.     

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.     

Structure of the bacteriophage T4 DNA adenine methyltransferase

DNA-adenine methylation at certain GATC sites plays a pivotal role in bacterial and phage gene expression as well as bacterial virulence. We report here the crystal structures of the bacteriophage T4Dam DNA adenine methyltransferase (MTase) in a binary complex with the methyl-donor product S-adenosyl-L-homocysteine (AdoHcy) and in a ternary complex with a synthetic 12-bp DNA duplex and AdoHcy. T4Dam contains two domains: a seven-stranded catalytic domain that harbors the binding site for AdoHcy and a DNA binding domain consisting of a five-helix bundle and a beta-hairpin that is conserved in the family of GATC-related MTase orthologs. Unexpectedly, the sequence-specific T4Dam bound to DNA in a nonspecific mode that contained two Dam monomers per synthetic duplex, even though the DNA contains a single GATC site. The ternary structure provides a rare snapshot of an enzyme poised for linear diffusion along the DNA.     

The effect of methylation outside the recognition sequence of restriction endonuclease PvuII on its cleavage efficiency.

This study is to extend our earlier observation that Dam and Dcm methylation outside the PvuII recognition sequence inhibited PvuII cleavage in one of the three PvuII sites of pGEM4Z-ras DNA. In this paper, a new recombinant plasmid DNA, pGEM4-SV40ori-anti-ras, was constructed which has only two PvuII sites, I and II. The Dam and Dcm-methylated and unmethylated DNAs were produced in Escherichia coli and linearized by ScaI. The DNA molecules were digested with different amounts of PvuII. The results show that by comparing the DNA fragment number and intensity of the partial and final products in agarose gel, PvuII site I on the methylated DNA molecule was digested four- to eight-fold more slowly than site II. In the unmethylated plasmid DNA, the two PvuII sites were cleaved at about the same rate. The difference was caused only by methylation of Dam and Dcm sites outside the PvuII recognition sequence. A methylated Dam site immediately adjacent to the less efficiently cut PvuII site I may be responsible for the inhibitory effect. We suggest that a new parameter, involving methylation of sites outside the recognition sequence, be considered in kinetic experiments on cleavage.     

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.     

DNA (cytosine-N4-)- and -(adenine-N6-)-methyltransferases have different kinetic mechanisms but the same reaction route. A comparison of M.BamHI and T4 Dam

We studied the kinetics of methyl group transfer by the BamHI DNA-(cytosine-N(4)-)-methyltransferase (MTase) from Bacillus amyloliquefaciens to a 20-mer oligodeoxynucleotide duplex containing the palindromic recognition site GGATCC. Under steady state conditions the BamHI MTase displayed a simple kinetic behavior toward the 20-mer duplex. There was no apparent substrate inhibition at concentrations much higher than the K(m) for either DNA (100-fold higher) or S-adenosyl-l-methionine (AdoMet) (20-fold higher); this indicates that dead-end complexes did not form in the course of the methylation reaction. The DNA methylation rate was analyzed as a function of both substrate and product concentrations. It was found to exhibit product inhibition patterns consistent with a steady state random bi-bi mechanism in which the dominant order of substrate binding and product release (methylated DNA, DNA(Me), and S-adenosyl-l-homocysteine, AdoHcy) was Ado-Met DNA DNA(Me) AdoHcy. The M.BamHI kinetic scheme was compared with that for the T4 Dam (adenine-N(6)-)-MTase. The two differed with respect to an effector action of substrates and in the rate-limiting step of the reaction (product inhibition patterns are the same for the both MTases). From this we conclude that the common chemical step in the methylation reaction, methyl transfer from AdoMet to a free exocyclic amino group, is not sufficient to dictate a common kinetic scheme even though both MTases follow the same reaction route.     

An epigenetic switch involving overlapping fur and DNA methylation optimizes expression of a type VI secretion gene cluster

Type VI secretion systems (T6SS) are macromolecular machines of the cell envelope of Gram-negative bacteria responsible for bacterial killing and/or virulence towards different host cells. Here, we characterized the regulatory mechanism underlying expression of the enteroagregative Escherichia coli sci1 T6SS gene cluster. We identified Fur as the main regulator of the sci1 cluster. A detailed analysis of the promoter region showed the presence of three GATC motifs, which are target of the DNA adenine methylase Dam. Using a combination of reporter fusion, gel shift, and in vivo and in vitro Dam methylation assays, we dissected the regulatory role of Fur and Dam-dependent methylation. We showed that the sci1 gene cluster expression is under the control of an epigenetic switch depending on methylation: fur binding prevents methylation of a GATC motif, whereas methylation at this specific site decreases the affinity of Fur for its binding box. A model is proposed in which the sci1 promoter is regulated by iron availability, adenine methylation, and DNA replication.     

Methylation by a mutant T2 DNA [N(6)-adenine] methyltransferase expands the usage of RecA-assisted endonuclease (RARE) cleavage

Properties of a mutant bacteriophage T2 DNA [N:(6)-adenine] methyltransferase (T2 Dam MTase) have been investigated for its potential utilization in RecA-assisted restriction endonuclease (RARE) cleavage. Steady-state kinetic analyses with oligonucleotide duplexes revealed that, compared to wild-type T4 Dam, both wild-type T2 Dam and mutant T2 Dam P126S had a 1.5-fold higher k(cat) in methylating canonical GATC sites. Additionally, T2 Dam P126S showed increased efficiencies in methylation of non-canonical GAY sites relative to the wild-type enzymes. In agreement with these steady-state kinetic data, when bacteriophage lambda DNA was used as a substrate, maximal protection from restriction nuclease cleavage in vitro was achieved on the sequences GATC, GATN and GACY, while protection of GACR sequences was less efficient. Collectively, our data suggest that T2 Dam P126S can modify 28 recognition sequences. The feasibility of using the mutant enzyme in RARE cleavage with BCL:I and ECO:RV endonucleases has been shown on phage lambda DNA and with BCL:I and DPN:II endonucleases on yeast chromosomal DNA embedded in agarose.     

Proximal recognition sites facilitate intrasite hopping by DNA adenine methyltransferase: mechanistic exploration of epigenetic gene regulation

The methylation of adenine in palindromic 5'-GATC-3' sites by Escherichia coli Dam supports diverse roles, including the essential regulation of virulence genes in several human pathogens. As a result of a unique hopping mechanism, Dam methylates both strands of the same site prior to fully dissociating from the DNA, a process referred to as intrasite processivity. The application of a DpnI restriction endonuclease-based assay allowed the direct interrogation of this mechanism with a variety of DNA substrates. Intrasite processivity is disrupted when the DNA flanking a single GATC site is longer than 400 bp on either side. Interestingly, the introduction of a second GATC site within this flanking DNA reinstates intrasite methylation of both sites. Our results show that intrasite methylation occurs only when GATC sites are clustered, as is found in gene segments both known and postulated to undergo in vivo epigenetic regulation by Dam methylation. We propose a model for intrasite methylation in which Dam bound to flanking DNA is an obligate intermediate. Our results provide insights into how intrasite processivity, which appears to be context-dependent, may contribute to the diverse biological roles that are carried out by Dam.     

Dam methylase from Escherichia coli: kinetic studies using modified DNA oligomers: hemimethylated substrates.

We have measured steady-state kinetics of the N6-adenine methyltransferase Dam Mtase using as substrates non-selfcomplementary tetradecamer duplexs (d[GCCGGATCTAGACG]-d[CGTCTAGATCC-GGC]) containing the hemimethylated GATC target sequence in one or the other strand and modifications in the GATC target sequence of the complementary strands. Modifications included substitution of guanine by hypoxanthine (I), thymine by uracil (U) or 5-ethyl-uracil (E) and adenine by 2,6-diamino-purine (D). Thermodynamic parameters were obtained from the concentration dependence of the melting temperature (Tm) of the duplexes. Large differences in DNA methylation of duplexes containing single dI for dG substitution of the Dam recognition site were observed compared with the canonical substrate, if the substitution involved the top strand (on the G.C rich side). Substitution in either strand by uracil (dU) or 5-ethyluracil (dE) resulted in small perturbation of the methylation patterns. When 2,6-diamino-purine (dD) replaced the adenine to be methylated, small, but significant methylation was observed. The kinetic parameters of the methylation reaction were compared with the thermodynamic free energies and significant correlation was observed.     

Interaction of the phage T4 Dam DNA-[N6-adenine] methyltransferase with oligonucleotides containing native or modified (defective) recognition sites.

The DNA-[N 6-adenine]-methyltransferase (Dam MTase) of phage T4 catalyzes methyl group transfer from S-adenosyl-l-methionine (AdoMet) to the N6-position of adenine in the palindromic sequence, GATC. We have used a gel shift assay to monitor complex formation between T4 Dam and various synthetic duplex oligonucleotides, either native or modified/defective. The results are summarized as follows. (i) T4 Dam bound with approximately 100-fold higher affinity to a 20mer specific (GATC-containing) duplex containing the canonical palindromic methylation sequence, GATC, than to a non-specific duplex containing another palindrome, GTAC. (ii) Compared with the unmethylated duplex, the hemimethylated 20mer specific duplex had a slightly increased ( approximately 2-fold) ability to form complexes with T4 Dam. (iii) No stable complex was formed with a synthetic 12mer specific (GATC-containing) duplex, although T4 Dam can methylate it. This indicates that there is no relation between formation of a catalytically competent 12mer-Dam complex and one stable to gel electrophoresis. (iv) Formation of a stable complex did not require that both strands be contiguous or completely complementary. Absence of a single internucleotide phosphate strongly reduced complex formation only when missing between the T and C residues. This suggests that if T4 Dam makes critical contact(s) with a backbone phosphate(s), then the one between T and C is the only likely candidate. Having only one half of the recognition site intact on one strand was sufficient for stable complex formation provided that the 5'G.C base-pairs be present at both ends of the palindromic, GATC. Since absence of either a G or C abolished T4 Dam binding, we conclude that both strands are recognized by T4 Dam.     

Effect of base analog substitutions in the specific GATC site on binding and methylation of oligonucleotide duplexes by the bacteriophage T4 Dam DNA-[N6-adenine] methyltransferase.

The interaction of the phage T4 Dam DNA-[N6-adenine] methyltransferase with 24mer synthetic oligonucleotide duplexes having different purine base substitutions in the palindromic recognition sequence, GATC, was investigated by means of gel shift and methyl transfer assays. The substitutions were introduced in either the upper or lower strand: guanine by 7-deazaguanine (G-->D) or 2-aminopurine (G-->N) and target adenine by purine (A-->P) or 2-aminopurine (A-->N). The effects of each base modification on binding/methylation were approximately equivalent for both strands. G-->D and G-->N substitutions resulted in a sharp decrease in binary complex formation. This suggests that T4 Dam makes hydrogen bonds with either the N7- or O6-keto groups (or both) in forming the complex. In contrast, A-->P and A-->N substitutions were much more tolerant for complex formation. This confirms our earlier observations that the presence of intact 5'-G:C base pairs at both ends of the methylation site is critical, but that base substitutions within the central A:T base pairs show less inhibition of complex formation. Addition of T4 Dam to a complete substrate mixture resulted in a burst of [3H]methylated product. In all cases the substrate dependencies of bursts and methylation rates were proportional to each other. For the perfect 24mer k cat = 0.014/s and K m = 7.7 nM was obtained. In contrast to binary complex formation the two guanine substitutions exerted relatively minor effects on catalytic turnover (the k cat was reduced at most 2. 5-fold), while the two adenine substitutions showed stronger effects (5- to 15-fold reduction in k cat). The effects of base analog substitutions on K m(DNA) were more variable: A-->P (decreased); A-->N and G-->D (unchanged); G-->N (increased).     

Bacteriophage T4 Dam DNA-[N6-adenine]methyltransferase. Kinetic evidence for a catalytically essential conformational change in the ternary complex.

We carried out a steady state kinetic analysis of the bacteriophage T4 DNA-[N6-adenine]methyltransferase (T4 Dam) mediated methyl group transfer reaction from S-adenosyl-l-methionine (AdoMet) to Ade in the palindromic recognition sequence, GATC, of a 20-mer oligonucleotide duplex. Product inhibition patterns were consistent with a steady state-ordered bi-bi mechanism in which the order of substrate binding and product (methylated DNA, DNA(Me) and S-adenosyl-l-homocysteine, AdoHcy) release was AdoMet downward arrow DNA downward arrow DNA(Me) upward arrow AdoHcy upward arrow. A strong reduction in the rate of methylation was observed at high concentrations of the substrate 20-mer DNA duplex. In contrast, increasing substrate AdoMet concentration led to stimulation in the reaction rate with no evidence of saturation. We propose the following model. Free T4 Dam (initially in conformational form E) randomly interacts with substrates AdoMet and DNA to form a ternary T4 Dam-AdoMet-DNA complex in which T4 Dam has isomerized to conformational state F, which is specifically adapted for catalysis. After the chemical step of methyl group transfer from AdoMet to DNA, product DNA(Me) dissociates relatively rapidly (k(off) = 1.7 x s(-1)) from the complex. In contrast, dissociation of product AdoHcy proceeds relatively slowly (k(off) = 0.018 x s(-1)), indicating that its release is the rate-limiting step, consistent with kcat = 0.015 x s(-1). After AdoHcy release, the enzyme remains in the F conformational form and is able to preferentially bind AdoMet (unlike form E, which randomly binds AdoMet and DNA), and the AdoMet-F binary complex then binds DNA to start another methylation cycle. We also propose an alternative pathway in which the release of AdoHcy is coordinated with the binding of AdoMet in a single concerted event, while T4 Dam remains in the isomerized form F. The resulting AdoMet-F binary complex then binds DNA, and another methylation reaction ensues. This route is preferred at high AdoMet concentrations.     

Structure and substrate recognition of the Escherichia coli DNA adenine methyltransferase

The structure of the Escherichia coli Dam DNA-(adenine-N6)-methyltransferase in complex with cognate DNA was determined at 1.89 A resolution in the presence of S-adenosyl-L-homocysteine. DNA recognition and the dynamics of base-flipping were studied by site-directed mutagenesis, DNA methylation kinetics and fluorescence stopped-flow experiments. Our data illustrate the mechanism of coupling of DNA recognition and base-flipping. Contacts to the non-target strand in the second (3') half of the GATC site are established by R124 to the fourth base-pair, and by L122 and P134 to the third base-pair. The aromatic ring of Y119 intercalates into the DNA between the second and third base-pairs, which is essential for base-flipping to occur. Compared to previous published structures of bacteriophage T4 Dam, three major new observations are made in E.coli Dam. (1) The first Gua is recognized by K9, removal of which abrogates the first base-pair recognition. (2) The flipped target Ade binds to the surface of EcoDam in the absence of S-adenosyl-L-methionine, which illustrates a possible intermediate in the base-flipping pathway. (3) The orphaned Thy residue displays structural flexibility by adopting an extrahelical or intrahelical position where it is in contact to N120.     

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.