Kinetic and catalytic mechanism of HhaI methyltransferase

Kinetic and catalytic properties of the DNA (cytosine-5)-methyltransferase HhaI are described. With poly(dG-dC) as substrate, the reaction proceeds by an equilibrium (or processive) ordered Bi-Bi mechanism in which DNA binds to the enzyme first, followed by S-adenosylmethionine (AdoMet). After methyl transfer, S-adenosylhomocysteine (AdoHcy) dissociates followed by methylated DNA. AdoHcy is a potent competitive inhibitor with respect to AdoMet (Ki = 2.0 microM) and its generation during reactions results in non-linear kinetics. AdoMet and AdoHcy significantly interact with only the substrate enzyme-DNA complex; they do not bind to free enzyme and bind poorly to the methylated enzyme-DNA complex. In the absence of AdoMet, HhaI methylase catalyzes exchange of the 5-H of substrate cytosines for protons of water at about 7-fold the rate of methylation. The 5-H exchange reaction is inhibited by AdoMet or AdoHcy. In the enzyme-DNA-AdoHcy complex, AdoHcy also suppresses dissociation of DNA and reassociation of the enzyme with other substrate sequences. Our studies reveal that the catalytic mechanism of DNA (cytosine-5)-methyltransferases involves attack of the C6 of substrate cytosines by an enzyme nucleophile and formation of a transient covalent adduct. Based on precedents of other enzymes which catalyze similar reactions and the susceptibility of HhaI to inactivation by N-ethylmaleimide, we propose that the sulfhydryl group of a cysteine residue is the nucleophilic catalyst. Furthermore, we propose that Cys-81 is the active-site catalyst in HhaI. This residue is found in a Pro-Cys doublet which is conserved in all DNA (cytosine-5)-methyltransferases whose sequences have been determined to date and is found in related enzymes. Finally, we discuss the possibility that covalent adducts between C6 of pyrimidines and nucleophiles of proteins may be important general components of protein-nucleic acid interactions.     

Inhibition of HhaI DNA (Cytosine-C5) methyltransferase by oligodeoxyribonucleotides containing 5-aza-2'-deoxycytidine: examination of the intertwined roles of co-factor,target, transition state structure and enzyme conformation

The presence of 5-azacytosine (ZCyt) residues in DNA leads to potent inhibition of DNA (cytosine-C5) methyltranferases (C5-MTases) in vivo and in vitro. Enzymatic methylation of cytosine in mammalian DNA is an epigenetic modification that can alter gene activity and chromosomal stability, influencing both differentiation and tumorigenesis. Thus, it is important to understand the critical mechanistic determinants of ZCyt's inhibitory action. Although several DNA C5-MTases have been reported to undergo essentially irreversible binding to ZCyt in DNA, there is little agreement as to the role of AdoMet and/or methyl transfer in stabilizing enzyme interactions with ZCyt. Our results demonstrate that formation of stable complexes between HhaI methyltransferase (M.HhaI) and oligodeoxyribonucleotides containing ZCyt at the target position for methylation (ZCyt-ODNs) occurs in both the absence and presence of co-factors, AdoMet and AdoHcy. Both binary and ternary complexes survive SDS-PAGE under reducing conditions and take on a compact conformation that increases their electrophoretic mobility in comparison to free M.HhaI. Since methyl transfer can occur only in the presence of AdoMet, these results suggest (1) that the inhibitory capacity of ZCyt in DNA is based on its ability to induce a stable, tightly closed conformation of M.HhaI that prevents DNA and co-factor release and (2) that methylation of ZCyt in DNA is not required for inhibition of M.HhaI.     

Structure of a binary complex of HhaI methyltransferase with S-adenosyl-L-methionine formed in the presence of a short non-specific DNA oligonucleotide

We have determined a structure for a complex formed between HhaI methyltransferase (M.HhaI) and S-adenosyl-L-methionine (AdoMet) in the presence of a non-specific short oligonucleotide. M.HhaI binds to the non-specific short oligonucleotides in solution. Although no DNA is incorporated in the crystal, AdoMet binds in a primed orientation, identical with that observed in the ternary complex of the enzyme, cognate DNA, and AdoMet or S-adenosyl-L-homocysteine (AdoHcy). This orientation differs from the previously observed unprimed orientation in the M.HhaI-AdoMet binary complex, where the S+-CH3 unit of AdoMet is protected by a favorable cation-pi interaction with Trp41. The structure suggests that the presence of DNA can guide AdoMet into the primed orientation. These results shed new light on the proposed ordered mechanism of binding and explains the stable association between AdoMet and M.HhaI.     

Purification, crystallization, and preliminary X-ray diffraction analysis of an M.HhaI-AdoMet complex.

The type-II DNA-(cytosine-5)-methyltransferase M.HhaI was overexpressed in Escherichia coli and purified to apparent homogeneity. The purification scheme exploits a unique high salt back-extraction step to solubilize M.HhaI selectively, followed by FPLC chromatography. The yield of purified protein was 0.75-1.0 mg per gram of bacterial paste. M.HhaI could be isolated in two forms: bound with its cofactor S-adenosylmethionine (AdoMet) or devoid of the cofactor. The AdoMet-bound form was capable of methylating DNA in vitro in the absence of exogenous AdoMet. From kinetic studies of the purified enzyme, values for KmAdoMet (60 nM), KiAdoHye (0.4 nM), and Kcat (0.22 s-1) were determined. The purified enzyme bound with its cofactor was crystallized by the hanging drop vapor diffusion technique. Crystals were of monoclinic space group P2(1) and had unit-cell dimensions of a = 55.3 A, b = 72.7 A, c = 91.0 A, and beta = 102.5 degrees, with two molecules of M.HhaI in each of the two asymmetric units. The crystals diffract beyond 2.5 A and are suitable for structure determination.     

Inhibition of EcoRI DNA methylase with cofactor analogs

Four analogs of the natural cofactor S-adenosylmethionine (AdoMet) were tested for their ability to bind and inhibit the prokaryotic enzyme, EcoRI adenine DNA methylase. The EcoRI methylase transfers the methyl group from AdoMet to the second adenine in the double-stranded DNA sequence 5'GAATTC3'. Dissociation constants (KD) of the binary methylase-analog complexes obtained in the absence of DNA with S-adenosylhomocysteine (AdoHcy), sinefungin, N-methyl-AdoMet, and N-ethylAdoMet are 225, 43, greater than 1000, and greater than 1000 microM, respectively. In the presence of a DNA substrate, all four analogs show simple competitive inhibition with respect to AdoMet. The product of the enzymic reaction, AdoHcy, is a poor inhibitor of the enzyme (KI(AdoHcy) = 9 microM; KM(AdoMet) = 0.60 microM). Two synthetic analogs, N-methyl-AdoMet and N-ethyl-AdoMet, were also shown to be poor inhibitors with KI values of 50 and greater than 1000 microM, respectively. In contrast, the naturally occurring analog sinefungin was shown to be a highly potent inhibitor (KI = 10 nM). Gel retardation assays confirm that the methylase-DNA-sinefungin complex is sequence-specific. The ternary complex is the first sequence-specific complex detected for any DNA methylase. Potential applications to structural studies of methylase-DNA interactions are discussed.     

The mechanism of DNA cytosine-5 methylation. Kinetic and mutational dissection of Hhai methyltransferase

Kinetic and binding studies involving a model DNA cytosine-5-methyltransferase, M.HhaI, and a 37-mer DNA duplex containing a single hemimethylated target site were applied to characterize intermediates on the reaction pathway. Stopped-flow fluorescence studies reveal that cofactor S-adenosyl-l-methionine (AdoMet) and product S-adenosyl-l-homocysteine (AdoHcy) form similar rapidly reversible binary complexes with the enzyme in solution. The M.HhaI.AdoMet complex (k(off) = 22 s(-)1, K(D) = 6 microm) is partially converted into products during isotope-partitioning experiments, suggesting that it is catalytically competent. Chemical formation of the product M.HhaI.(Me)DNA.AdoHcy (k(chem) = 0.26 s(-)1) is followed by a slower decay step (k(off) = 0.045 s(-)1), which is the rate-limiting step in the catalytic cycle (k(cat) = 0.04 s(-)1). Analysis of reaction products shows that the hemimethylated substrate undergoes complete (>95%) conversion into fully methylated product during the initial burst phase, indicating that M.HhaI exerts high binding selectivity toward the target strand. The T250N, T250D, and T250H mutations, which introduce moderate perturbation in the catalytic site, lead to substantially increased K(D)(DNA(ternary)), k(off)(DNA(ternary)), K(M)(AdoMet(ternary)) values but small changes in K(D)(DNA(binary)), K(D)(AdoMet(binary)), k(chem), and k(cat). When the target cytosine is replaced with 5-fluorocytosine, the chemistry step leading to an irreversible covalent M.HhaI.DNA complex is inhibited 400-fold (k(chem)(5FC) = 0.7 x 10(-)3 s(-)1), and the Thr-250 mutations confer further dramatic decrease of the rate of the covalent methylation k(chem). We suggest that activation of the pyrimidine ring via covalent addition at C-6 is a major contributor to the rate of the chemistry step (k(chem)) in the case of cytosine but not 5-fluorocytosine. In contrast to previous reports, our results imply a random substrate binding order mechanism for M.HhaI.     

Characterization of the DNA methylase activity of the restriction enzyme from Escherichia coli K

The restriction endonuclease from Escherichia coli K is a multifunctional protein which efficiently methylates heteroduplex DNA (one strand modified and one strand unmodified) in the presence of S-adenosylmethionine (AdoMet), ATP, and Mg2+. The methylase activity is catalytic, and seems to modify different heteroduplex host specificity sites for E. coli K with equal efficiency. In the methylase reaction, both AdoMet and ATP (or its imido analog) act as allosteric effectors, but AdoMet also serves as a methyl donor. Preincubation of the enzyme with AdoMet eliminates the lag period observed in DNA methylation. The rate of enzyme activation was determined using the AdoMet analog Sinefungin. The result are consistent with the hypothesis that the early steps of AdoMet binding and enzyme activation are common to both restriction and modification reactions.     

Water-assisted dual mode cofactor recognition by HhaI DNA methyltransferase.

Energetically competent binary recognition of the cofactor S-adenosyl-L-methionine (AdoMet) and the product S-adenosyl-L-homocysteine (AdoHcy) by the DNA (cytosine C-5) methyltransferase (M.HhaI) is demonstrated herein. Titration calorimetry reveals a dual mode, involving a primary dominant exothermic reaction followed by a weaker endothermic one, for the recognition of AdoMet and AdoHcy by M.HhaI. Conservation of the bimodal recognition in W41I and W41Y mutants of M.HhaI excludes the cation-pi interaction between the methylsulfonium group of AdoMet and the pi face of the Trp(41) indole ring from a role in its origin. Small magnitude of temperature-independent heat capacity changes upon AdoMet or AdoHcy binding by M.HhaI preclude appreciable conformational alterations in the reacting species. Coupled osmotic-calorimetric analyses of AdoMet and AdoHcy binding by M.HhaI indicate that a net uptake of nearly eight and 10 water molecules, respectively, assists their primary recognition. A change in water activity at constant temperature and pH is sufficient to engender and conserve enthalpy-entropy compensation, consistent with a true osmotic effect. The results implicate solvent reorganization in providing the major contribution to the origin of this isoequilibrium phenomenon in AdoMet and AdoHcy recognition by M.HhaI. The observations provide unequivocal evidence for the binding of AdoMet as well as AdoHcy to M.HhaI in solution state. Isotope partitioning analysis and preincubation studies favor a random mechanism for M.HhaI-catalyzed reaction. Taken together, the results clearly resolve the issue of cofactor recognition by free M.HhaI, specifically in the absence of DNA, leading to the formation of an energetically and catalytically competent binary complex.     

Probing a rate-limiting step by mutational perturbation of AdoMet binding in the HhaI methyltransferase

DNA methylation plays important roles via regulation of numerous cellular mechanisms in diverse organisms, including humans. The paradigm bacterial methyltransferase (MTase) HhaI (M.HhaI) catalyzes the transfer of a methyl group from the cofactor S-adenosyl-L-methionine (AdoMet) onto the target cytosine in DNA, yielding 5-methylcytosine and S-adenosyl-L-homocysteine (AdoHcy). The turnover rate (k cat) of M.HhaI, and the other two cytosine-5 MTases examined, is limited by a step subsequent to methyl transfer; however, no such step has so far been identified. To elucidate the role of cofactor interactions during catalysis, eight mutants of Trp41, which is located in the cofactor binding pocket, were constructed and characterized. The mutants show full proficiency in DNA binding and base-flipping, and little variation is observed in the apparent methyl transfer rate k chem as determined by rapid-quench experiments using immobilized fluorescent-labeled DNA. However, the Trp41 replacements with short side chains substantially perturb cofactor binding (100-fold higher K(AdoMet)D and K(AdoMet)M) leading to a faster turnover of the enzyme (10-fold higher k cat). Our analysis indicates that the rate-limiting breakdown of a long-lived ternary product complex is initiated by the dissociation of AdoHcy or the opening of the catalytic loop in the enzyme.     

Direct photolabeling of the EcoRII methyltransferase with S-adenosyl-L-methionine

Ultraviolet irradiation of EcoRII methyltransferase in the presence of its substrate, S-adenosyl-L-methionine (AdoMet), results in the formation of a stable enzyme-substrate adduct. This adduct can be demonstrated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after irradiation of the enzyme in the presence of either [methyl-3H]AdoMet or [35S]AdoMet. The extent of photolabeling is low. Under optimal conditions, 4.5 pmol of [3H]AdoMet is incorporated into 100 pmol of enzyme. Use of the 8-azido derivative of AdoMet as the photolabeling substrate increases the incorporation by approximately 2-fold. However, this adduct, unlike the one formed with AdoMet, is not stable when treated with thiol reagents or precipitated with trichloroacetic acid. A catalytically active conformation of the enzyme is needed for AdoMet photolabeling. Heat-inactivated enzyme or proteins for which AdoMet is not a substrate or cofactor do not undergo adduct formation. Two other methyltransferases, MspI and dam methylases are also shown to form adducts with AdoMet upon UV irradiation. The binding constant of the EcoRII methyltransferase for AdoMet determined with the photolabeling reaction is 11 microM, which is similar to the binding constant of 9 microM previously reported (Friedman, S. (1986) Nucleic Acids Res. 14, 4543-4556). The AdoMet analogs S-adenosyl-L-homocysteine (Ki = 0.83 microM) and sinefungin (Ki = 4.3 microM) are effective inhibitors of photolabeling, whereas S-adenosyl-D-homocysteine (Ki = 46 microM) is a poor inhibitor. These experiments indicate that AdoMet becomes covalently bound at the AdoMet-binding site on the enzyme molecule. The EcoRII methyltransferase-AdoMet adduct is very stable and could be used to identify the AdoMet-binding site on DNA methyltransferases.     

Reconciling structure and function in HhaI DNA cytosine-C-5 methyltransferase

Pre-steady state partitioning analysis of the HhaI DNA methyltransferase directly demonstrates the catalytic competence of the enzyme.DNA complex and the lack of catalytic competence of the enzyme.S-adenosyl-L-methionine (AdoMet) complex. The enzyme.AdoMet complex does form, albeit with a 50-fold decrease in affinity compared with the ternary enzyme.AdoMet.DNA complex. These findings reconcile the distinct binding orientations previously observed within the binary enzyme.AdoMet and ternary enzyme. S-adenosyl-L-homocysteine.DNA crystal structures. The affinity of the enzyme for DNA is increased 900-fold in the presence of its cofactor, and the preference for hemimethylated DNA is increased to 12-fold over unmethylated DNA. We suggest that this preference is partially due to the energetic cost of retaining a cavity in place of the 5-methyl moiety in the ternary complex with the unmethylated DNA, as revealed by the corresponding crystal structures. The hemi- and unmethylated substrates alter the fates and lifetimes of discrete enzyme.substrate intermediates during the catalytic cycle. Hemimethylated substrates partition toward product formation versus dissociation significantly more than unmethylated substrates. The mammalian DNA cytosine-C-5 methyltransferase Dnmt1 shows an even more pronounced partitioning toward product formation.     

The core element of the EcoRII methylase as defined by protease digestion and deletion analysis.

Binding of the EcoRII DNA methyltransferase to azacytosine-containing DNA protects the enzyme from digestion by proteases. The limit digest yields a product having a Mr on SDS-PAGE 20% less than the intact protein. The N terminus of the tryptic digestion product was sequenced and found to be missing the N terminal 82 amino acids. Under the conditions used unbound enzyme was digested to small peptides. Protection of the enzyme from protease digestion implies that the enzyme undergoes major conformational changes when bound to DNA. The trypsin sensitive region of the EcoRII methyltransferase occurs prior to the first constant region shared with other procaryotic DNA(cytosine-5)methyltransferases. To determine if this region played a role in substrate binding or specificity, N-terminal deletion mutants were studied. Deletion of 97 amino acids resulted in a decrease of enzyme activity. Further deletions caused a complete loss of activity. Enzyme deleted through amino acid 85 was purified and found to have the same specificity as wild type however there was an increase in Km for both S-adenosylmethionine (AdoMet) and DNA of 27 and 18 fold respectively. The N-terminus of the EcoRII methylase, although a variable region present in many procaryotic DNA(cytosine-5)methylases, plays no role in determining enzyme specificity, although it does contribute to the interaction with both AdoMet and DNA.     

Stereochemical studies of the C-methylation of deoxycytidine catalyzed by HhaI methylase and the N-methylation of deoxyadenosine catalyzed by EcoRI methylase

The steric course of methyl group transfer catalyzed by two DNA methylases, HhaI methylase, a DNA (cytosine-5)-methyltransferase, and EcoRI methylase, which methylates at N6 of adenosine, has been studied with (methyl-R)- and (methyl-S)-[methyl-2H1,3H]adenosylmethionine as the methyl donor, using as substrates poly-d(GC) (HhaI) and the dodecamer oligonucleotide duplex d(CGCGAATTCGCG) (EcoRI), respectively. The methylated nucleotides were degraded to convert the chiral methyl groups into acetic acid for configurational analysis. It was found that both enzymatic reactions proceed with inversion of configuration of the methyl group.     

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.     

Structural studies of inhibition of S-adenosylmethionine synthetase by slow, tight-binding intermediate and product analogues

S-Adenosylmethionine synthetase (ATP: L-methionine S-adenosyltransferase) catalyzes a two-step reaction in which tripolyphosphate (PPPi) is a tightly bound intermediate. Diimidotriphosphate (O(3)P-NH-PO(2)-NH-PO(3); PNPNP), a non-hydrolyzable analogue of PPPi, is the most potent known inhibitor of AdoMet synthetase with a K(i) of 2 nM. The structural basis for the slow, tight-binding inhibition by PNPNP has been investigated by spectroscopic methods. UV difference spectra reveal environmental alterations of aromatic protein residues upon PNPNP binding to form the enzyme.2Mg(2+).PNPNP complex, and more extensive changes upon formation of the enzyme.2Mg(2+).PNPNP.AdoMet complex. Stopped-flow kinetic studies of complex formation revealed that two slow isomerizations follow PNPNP binding in the presence of AdoMet, in contrast to the lower affinity, rapid-equilibrium binding in the absence of AdoMet. (31)P NMR spectra of enzyme complexes with PNPNP revealed electronic perturbations of each phosphorus atom by distinct upfield chemical shifts for each of the three phosphoryl groups in the enzyme.2Mg(2+).PNPNP complex, and further upfield shifts of at least 2 resonances in the complex with AdoMet. Comparison of the chemical shifts for the enzyme-bound PNPNP with the enzyme complexes containing either the product analogue O(3)P-NH-PO(3) or O(3)P-O-PO(2)-NH-PO(3) indicates that the shifts on binding are largest at the binding sites corresponding to those for the alpha and gamma phosphoryl groups of the nucleotide (-3.1 to -4.1 ppm), while the resonance at the beta phosphoryl group position shifts by -2.1 ppm. EPR spectra of Mn(2+) complexes demonstrate spin coupling between the two Mn(2+) in both enzyme.2Mn(2+).PNPNP and enzyme.2Mn(2+).PNPNP.AdoMet, indicating that the metal ions have comparable distances in both cases. The combined results indicate that formation of the highest affinity complex is associated with protein side chain rearrangements and increased electron density at the ligand phosphorus atoms, likely due to ionization of an -NH- group of the inhibitor. The energetic feasibility of ionization of a -NH- group when two Mg(2+) ions are bound to O(3)P-NH-PO(3) is supported by density functional theoretical calculations on model chelates. This mode of interaction is uniquely available to compounds with P-NH-P linkages and may be possible with other proteins in which multiple cations coordinate a polyphosphate chain.     

Identification of peptides involved in S-adenosylmethionine binding in the EcoRI DNA methylase. Photoaffinity laveling with 8-azido-S-adenosylmethionine

The Mr 38,050 monomeric EcoRI DNA methylase is part of a bacterial restriction-modification system. The methylase transfers the methyl group from S-adenosylmethionine (AdoMet) to the second adenine in the double-stranded DNA sequence 5'-GAATTC-3'. We have used the radiolabeled photoaffinity analog 8-azido-S-adenosylmethionine (8-N3-AdoMet) to identify peptides at the AdoMet binding site in the binary methylase-cofactor analog complex. The dissociation constants in the absence of DNA for the analog and AdoMet are 12.9 and 4.8 microM, respectively. The apparent kcat and Km values, obtained with the double-stranded DNA substrate 5'-CGCGAATTCGCG-3', are 5.0 s-1 and 0.710 microM (8-N3-AdoMet) and 4.3 s-1 and 0.335 microM (AdoMet). Photolabeling by 8-N3-AdoMet occurs upon irradiation with ultraviolet light and is inhibited by AdoMet. Digestion of the adducted methylase with subtilisin generated several radiolabeled peptides. Peptide sequencing from independent photolabeling experiments revealed two radiolabeled peptides containing amino acids 206-212 and 213-221. Instability of the adducted peptides precluded assignment of modified amino acids.     

Reaction of nucleic acids with cis-diamminedichloroplatinum(II): interstrand cross-links

In the reaction of cis-diamminedichloroplatinum(II) (cis-DDP) with double-helical (dC-dG)4.(dC-dG)4 or (dC-dG)5.(dC-dG)5, intrastrand and interstrand cross-links between two guanine residues are formed. This is shown by gel electrophoresis in denaturing conditions of the reaction products and by high-performance liquid chromatography (HPLC) analysis of the products digested with nuclease P1. In the reaction of cis-DDP and poly(dG-dC).poly(dG-dC), at relatively low levels of platination, it is mainly interstrand cross-links between two guanine residues that are formed. This is shown by HPLC analysis of the nuclease P1 digest and by gel electrophoresis in denaturing and nondenaturing conditions of the platinated polymer after cleavage with the restriction enzyme HhaI. Moreover, the antibodies to platinated poly(dG-dC).poly(dG-dC) cross-react with the interstrand cross-linked (dC-dG)4 or (dC-dG)5 but not with the intrastrand cross-linked (dC-dG)4 or (dC-dG)5. These antibodies cross-react with platinated natural DNA. The amount of interstrand cross-links deduced from radioimmunoassays (0.5% of the total bound platinum) is lower than that (2%) deduced by gel electrophoresis in denaturing conditions of a platinated DNA restriction fragment. By gel electrophoresis, it is also shown that in vitro the isomer trans-DDP is more efficient in forming interstrand cross-links than cis-DDP.     

Kinetic mechanism of the EcoRI DNA methyltransferase

We present a kinetic analysis of the EcoRI DNA N6-adenosine methyltransferase (Mtase). The enzyme catalyzes the S-adenosylmethionine (AdoMet)-dependent methylation of a short, synthetic 14 base pair DNA substrate and plasmid pBR322 DNA substrate with kcat/Km values of 0.51 X 10(8) and 4.1 X 10(8) s-1 M-1, respectively. The Mtase is thus one of the most efficient biocatalysts known. Our data are consistent with an ordered bi-bi steady-state mechanism in which AdoMet binds first, followed by DNA addition. One of the reaction products, S-adenosylhomocysteine (AdoHcy), is an uncompetitive inhibitor with respect to DNA and a competitive inhibitor with respect to AdoMet. Thus, initial DNA binding followed by AdoHcy binding leads to formation of a ternary dead-end complex (Mtase-DNA-AdoHcy). We suggest that the product inhibition patterns and apparent order of substrate binding can be reconciled by a mechanism in which the Mtase binds AdoMet and noncanonical DNA randomly but that recognition of the canonical site requires AdoMet to be bound. Pre-steady-state and isotope partition analyses starting with the binary Mtase-AdoMet complex confirm its catalytic competence. Moreover, the methyl transfer step is at least 10 times faster than catalytic turnover.     

Covalent adducts between tRNA (m5U54)-methyltransferase and RNA substrates.

The interaction of tRNA (m5U54)-methyltransferase (RUMT) with in vitro synthesized unmodified tRNA and a 17-base oligoribonucleotide analog of the T-arm of tRNA in the absence of AdoMet has been investigated. Binary complexes are formed which are isolable on nitrocellulose filters and are composed of noncovalent and covalent complexes in nearly equal amounts. The covalent RUMT-RNA complexes are stable to SDS-PAGE and migrate slower than free enzyme or RNA. Kinetic and thermodynamic constants involved in formation and disruption of noncovalent and covalent binary complexes have been determined and interpreted in the context of steady-state kinetic parameters of the enzyme-catalyzed methylation and 5-H exchange of substrate. The results show that the isolable covalent complex is kinetically incompetent as an intermediate for methylation. Isotope trapping experiments show that when AdoMet is added to preformed binary complex, all bound tRNA is converted to methylated product; thus, the covalent complexes are chemically competent to form products. We have concluded that, after a reversible binary complex is formed, the catalytic thiol adds to the 6-carbon of the U54 of tRNA. The initial adduct leaves the reaction pathway to protonation at carbon 5; the latter can deprotonate and re-enter the pathway to form methylated product. It is speculated that covalent binary RUMT-RNA adducts may serve as depots of enzyme-tRNA complexes primed for methylation, or in unknown roles with RNAs other than tRNA.     

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.