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

Molecular enzymology of the EcoRV DNA-(Adenine-N (6))-methyltransferase: kinetics of DNA binding and bending, kinetic mechanism and linear diffusion of the enzyme on DNA

The EcoRV DNA-(adenine-N(6))-methyltransferase recognizes GATATC sequences and modifies the first adenine residue within this site. We show here, that the enzyme binds to the DNA and the cofactor S-adenosylmethionine (AdoMet) in an ordered bi-bi fashion, with AdoMet being bound first. M.EcoRV binds DNA in a non-specific manner and the enzyme searches for its recognition site by linear diffusion with a range of approximately 1800 bp. During linear diffusion the enzyme continuously scans the DNA for the presence of recognition sites. Upon specific M.EcoRV-DNA complex formation a strong increase in the fluorescence of an oligonucleotide containing a 2-aminopurine base analogue at the GAT-2AP-TC position is observed which, most likely, is correlated with DNA bending. In contrast to the GAT-2AP-TC substrate, a G-2AP-TATC substrate in which the target base is replaced by 2-aminopurine does not show an increase in fluorescence upon M.EcoRV binding, demonstrating that 2-aminopurine is not a general tool to detect base flipping. Stopped-flow experiments show that DNA bending is a fast process with rate constants >10 s(-1). In the presence of cofactor, the specific complex adopts a second conformation, in which the target sequence is more tightly contacted by the enzyme. M.EcoRV exists in an open and in a closed state that are in slow equilibrium. Closing the open state is a slow process (rate constant approximately 0.7 min(-1)) that limits the rate of DNA methylation under single turnover conditions. Product release requires opening of the closed complex which is very slow (rate constant approximately 0.05-0.1 min(-1)) and limits the rate of DNA methylation under multiple turnover conditions. M.EcoRV methylates DNA sequences containing more than one recognition sites in a distributive manner. Since the dissociation rate from non-specific DNA does not depend on the length of the DNA fragment, DNA dissociation does not preferentially occur at the ends of the DNA.

Specificity of DNA binding and methylation by the M.FokI DNA methyltransferase

The M.FokI adenine-N(6) DNA methyltransferase recognizes the asymmetric DNA sequence GGATG/CATCC. It consists of two domains each containing all motifs characteristic for adenine-N(6) DNA methyltransferases. We have studied the specificity of DNA-methylation by both domains using 27 hemimethylated oligonucleotide substrates containing recognition sites which differ in one or two base pairs from GGATG or CATCC. The N-terminal domain of M.FokI interacts very specifically with GGATG-sequences, because only one of the altered sites is modified. In contrast, the C-terminal domain shows lower specificity. It prefers CATCC-sequences but only two of the 12 star sites (i.e. sites that differ in 1 bp from the recognition site) are not accepted and some star sites are modified with rates reduced only 2-3-fold. In addition, GGATGC- and CGATGC-sites are modified which differ at two positions from CATCC. DNA binding experiments show that the N-terminal domain preferentially binds to hemimethylated GGATG/C(m)ATCC sequences whereas the C-terminal domain binds to DNA with higher affinity but without specificity. Protein-protein interaction assays show that both domains of M.FokI are in contact with each other. However, several DNA-binding experiments demonstrate that DNA-binding of both domains is mutually exclusive in full-length M.FokI and both domains do not functionally influence each other. The implications of these results on the molecular evolution of type IIS restriction/modification systems are discussed.

On the possibilities and limitations of rational protein design to expand the specificity of restriction enzymes: a case study employing EcoRV as the target

The restriction endonuclease EcoRV has been characterized in structural and functional terms in great detail. Based on this detailed information we employed a structure-guided approach to engineer variants of EcoRV that should be able to discriminate between differently flanked EcoRV recognition sites. In crystal structures of EcoRV complexed with d(CGGGATATCCC)(2) and d(AAAGATATCTT)(2), Lys104 and Ala181 closely approach the two base pairs flanking the GATATC recognition site and thus were proposed to be a reasonable starting point for the rational extension of site specificity in EcoRV [Horton,N.C. and Perona,J.J. (1998) J. Biol. Chem., 273, 21721-21729]. To test this proposal, several single (K104R, A181E, A181K) and double mutants of EcoRV (K104R/A181E, K104R/A181K) were generated. A detailed characterization of all variants examined shows that only the substitution of Ala181 by Glu leads to a considerably altered selectivity with both oligodeoxynucleotide and macromolecular DNA substrates, but not the predicted one, as these variants prefer cleavage of a TA flanked site over all other sites, under all conditions tested. The substitution of Lys104 by Arg, in contrast, which appeared to be very promising on the basis of the crystallographic analysis, does not lead to variants which differ very much from the EcoRV wild-type enzyme with respect to the flanking sequence preferences. The K104R/A181E and K104R/A181K double mutants show nearly the same preferences as the A181E and A181K single mutants. We conclude that even for the very well characterized restriction enzyme EcoRV, properties that determine specificity and selectivity are difficult to model on the basis of the available structural information.

Biotin-avidin microplate assay for the quantitative analysis of enzymatic methylation of DNA by DNA methyltransferases

An assay is described to measure methylation of biotinylated oligonucleotide substrates by DNA methyltransferases using [methyl-3H]-AdoMet. After the methylation reaction the oligonucleotides are immobilized on an avidin-coated microplate. The incorporation of [3H] into the DNA is quenched by addition of unlabeled AdoMet to the binding buffer. Unreacted AdoMet and enzyme are removed by washing. To release the radioactivity incorporated into the DNA, the wells are incubated with a non-specific endonuclease and the radioactivity determined by liquid scintillation counting. As an example, we have studied methylation of DNA by the EcoRV DNA methyltransferase. The reaction progress curves measured with this assay are linear with respect to time. Methylation rates linearly increase with enzyme concentration. The rates are comparable to results obtained with the same enzyme using a different assay. The biotin-avidin assay is inexpensive, convenient, quantitative, fast and well suited to process many samples in parallel. The accuracy of the assay is high, allowing to reproduce results within +/- 10%. The assay is very sensitive as demonstrated by the detection of incorporation of 0.8 fmol methyl groups into the DNA. Under the experimental conditions, this corresponds to methylation of only 0.03% of all target sites of the substrate. Using this assay, the DNA methylation activity of some M.EcoRV variants could be detected that was not visible by other in vitro methylation assays.

Expression and functional interaction of the catalytic and regulatory subunits of human methionine adenosyltransferase in mammalian cells

Methionine adenosyltransferase (MAT) catalyzes the synthesis of S-adenosylmethionine (AdoMet). The mammalian MAT II isozyme consists of catalytic alpha(2) and regulatory beta subunits. The aim of this study was to investigate the interaction and kinetic behavior of the human MAT II subunit proteins in mammalian cells. COS-1 cells were transiently transfected with pTargeT vector harboring full-length cDNA that encodes for the MAT II alpha(2) or beta subunits. Expression of the His-tagged recombinant alpha(2) (ralpha(2)) subunit in COS-1 cells markedly increased MAT II activity and resulted in a shift in the K(m) for L-methionine (L-Met) from 15 microM (endogenous MAT II) to 75 microM (ralpha(2)), and with the apparent existence of two kinetic forms of MAT in the transfected COS-1 cell extracts. By contrast, expression of the recombinant beta (rbeta) subunit had no effect on the K(m) for L-Met of the endogenous MAT II, while it did cause an increase in both the V(max) and the specific activity of endogenous MAT. Co-expression of both ralpha(2) and rbeta subunits resulted in a significant increase of MAT specific activity with the appearance of a single kinetic form of MAT (K(m) = 20 microM). The recombinant MAT II alpha(2) and rbeta subunit associated spontaneously either in cell-free system or in COS-1 cells co-expressing both subunits. Analysis of nickel-agarose-purified His-tagged ralpha(2) subunit from COS-1 cell extracts showed that the beta subunit co-purified with the alpha(2) subunit. Furthermore, the alpha(2) and beta subunits co-migrated in native polyacrylamide gels. Together, the data provide evidence for alpha(2) and beta MAT subunit association. In addition, the beta subunit regulated MAT II activity by reducing its K(m) for L-Met and by rendering the enzyme more susceptible to feedback inhibition by AdoMet. We believe that the previously described differential expression of MAT II beta subunit may be an important mechanism by which MAT activity can be modulated to provide different levels of AdoMet that may be required at different stages of cell growth and differentiation.

On the substrate specificity of DNA methyltransferases. adenine-N6 DNA methyltransferases also modify cytosine residues at position N4

Methylation of DNA is important in many organisms and essential in mammals. Nucleobases can be methylated at the adenine-N6, cytosine-N4, or cytosine-C5 atoms by specific DNA methyltransferases. We show here that the M.EcoRV, M.EcoRI, and Escherichia coli dam methyltransferases as well as the N- and C-terminal domains of the M. FokI enzyme, which were formerly all classified as adenine-N6 DNA methyltransferases, also methylate cytosine residues at position N4. Kinetic analyses demonstrate that the rate of methylation of cytosine residues by M.EcoRV and the M.FokI enzymes is reduced by only 1-2 orders of magnitude in relation to methylation of adenines. This result shows that although these enzymes methylate DNA in a sequence specific manner, they have a low substrate specificity with respect to the target base. This unexpected finding has implications on the mechanism of adenine-N6 DNA methyltransferases. Sequence comparisons suggest that adenine-N6 and cytosine-N4 methyltransferases have changed their reaction specificity at least twice during evolution, a model that becomes much more likely given the partial functional overlap of both enzyme types. In contrast, methylation of adenine residues by the cytosine-N4 methyltransferase M.BamHI was not detectable. On the basis of our results, we suggest that adenine-N6 and cytosine-N4 methyltransferases should be grouped into one enzyme family.

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.

Crystal structure of the DpnM DNA adenine methyltransferase from the DpnII restriction system of streptococcus pneumoniae bound to S-adenosylmethionine

BACKGROUND

. Methyltransferases (Mtases) catalyze the transfer of methyl groups from S-adenosylmethionine (AdoMet) to a variety of small molecular and macromolecular substrates. These enzymes contain a characteristic alpha/beta structural fold. Four groups of DNA Mtases have been defined and representative structures have been determined for three groups. DpnM is a DNA Mtase that acts on adenine N6 in the sequence GATC; the enzyme represents group alpha DNA Mtases, for which no structures are known.

RESULTS

. The structure of DpnM in complex with AdoMet was determined at 1.80 A resolution. The protein comprises a consensus Mtase fold with a helical cluster insert. DpnM binds AdoMet in a similar manner to most other Mtases and the enzyme contains a hollow that can accommodate DNA. The helical cluster supports a shelf within the hollow that may recognize the target sequence. Modeling studies indicate a potential site for binding the target adenine, everted from the DNA helix. Comparison of the DpnM structure and sequences of group alpha DNA Mtases indicates that the group is a genetically related family. Structural comparisons show DpnM to be most similar to a small-molecule Mtase and then to macromolecular Mtases, although several dehydrogenases show greater similarity than one DNA Mtase.

CONCLUSIONS

. DpnM, and by extension the DpnM family or group alpha Mtases, contains the consensus fold and AdoMet-binding motifs found in most Mtases. Structural considerations suggest that macromolecular Mtases evolved from small-molecule Mtases, with different groups of DNA Mtases evolving independently. Mtases may have evolved from dehydrogenases. Comparison of these enzymes indicates that in protein evolution, the structural fold is most highly conserved, then function and lastly sequence.

Crosslinking the EcoRV restriction endonuclease across the DNA-binding site reveals transient intermediates and conformational changes of the enzyme during DNA binding and catalytic turnover

EcoRV completely encircles bound DNA with two loops, forming the entry and exit gate for the DNA substrate. These loops were crosslinked generating CL-EcoRV which binds and releases linear DNA only slowly, because threading linear DNA into and out of the DNA-binding 'tunnel' of CL-EcoRV is not very effective. If the crosslinking reaction is carried out with a circular bound DNA, CL-EcoRV is hyperactive towards the trapped substrate which is cleaved very quickly but not very accurately. CL-EcoRV also binds to, but does not cleave, circular DNA when added from the outside, because it cannot enter the active site. Based on these results a two-step binding model is proposed for EcoRV: initial DNA binding occurs at the outer side of the loops before the gate opens and then the DNA is transferred to the catalytic center.

Towards the design of rare cutting restriction endonucleases: using directed evolution to generate variants of EcoRV differing in their substrate specificity by two orders of magnitude

The restriction endonuclease EcoRV cleaves DNA highly specifically within GATATC sequences. In order to create EcoRV variants that have an extended recognition site we have employed a semi-rational random mutagenesis/selection procedure. Twenty-two amino acid residues were subjected to random mutagenesis and about 500 EcoRV variants representing three generations of mutants were screened. Among these some highly active variants that strongly prefer AT-flanked cleavage sites (e.g. S183A/Q224R, T93S/I103F/S183A/T222S or N97T/S183A/T222S) and others that prefer GC flanks (e.g. K104N/A181T) were identified. As wild-type EcoRV does not discriminate between these cleavage sites, the generation of these variants represents a significant first step towards redesigning EcoRV to become an 8 or 10 bp cutter. Such enzymes, only very rarely found in nature, could be extremely helpful for the manipulation of large DNA fragments.