Using the fluorescence decay of 2-aminopurine to investigate conformational change in the recognition sequence of the EcoRV DNA-(adenine-N6)-methyltransferase on enzyme binding.

The EcoRV DNA methyltransferase methylates the first adenine in the GATATC recognition sequence. It is presumed that methylation proceeds by a nucleotide flipping mechanism but no crystal structure is available to confirm this. A popular solution-phase assay for nucleotide flipping employs the fluorescent adenine analogue, 2-aminopurine (2AP), substituted at the methylation target site; a substantial increase in fluorescence intensity on enzyme binding indicates flipping. However, this appeared to fail for M.EcoRV, since 2AP substituted for the non-target adenine in the recognition sequence showed a much greater intensity increase than 2AP at the target site. This anomaly is resolved by recording the fluorescence decay of 2AP which shows that the target 2AP is indeed flipped by the enzyme, but its fluorescence is quenched by interaction with aromatic residues in the catalytic site, whereas bending of the duplex at the non-target site alleviates inter-base quenching and exposes the 2AP to solvent.

Detection and quantitation of the activity of DNA methyltransferases using a biotin/avidin microplate assay.

The biotin-avidin microplate assay is a sensitive method to measure methylation of biotinylated oligonucleotide substrates by DNA methyltransferases (MTases). The methylation reaction is carried out in solution using [methyl-3H]-AdoMet. Afterwards, the oligonucleotides are immobilized on an avidin-coated microplate, where the incorporation of [3H]-labeled methyl groups into the DNA is stopped by addition of unlabeled AdoMet to the binding buffer. Separation of radioactively labeled DNA from unreacted AdoMet and enzyme is performed by washing steps. Subsequently, the radioactivity incorporated into the DNA is released by a nucleolytic digestion of the DNA. By liquid scintillation counting, the amount of DNA methylation can be determined. Advantages of the microplate assay are its high sensitivity which allows the detection of low amounts of DNA methylation, the efficient separation of reaction components resulting in a low background of radioactivity and a high accuracy (+/-10%) and reliability. Furthermore, the assay is very convenient, fast and well suited for automation.

Two alternative conformations of S-adenosyl-L-homocysteine bound to Escherichia coli DNA adenine methyltransferase and the implication of conformational changes in regulating the catalytic cycle.

The crystal structure of the Escherichia coli DNA adenine methyltransferase (EcoDam) in a binary complex with the cofactor product S-adenosyl-L-homocysteine (AdoHcy) unexpectedly showed the bound AdoHcy in two alternative conformations, extended or folded. The extended conformation represents the catalytically competent conformation, identical to that of EcoDam-DNA-AdoHcy ternary complex. The folded conformation prevents catalysis, because the homocysteine moiety occupies the target Ade binding pocket. The largest difference between the binary and ternary structures is in the conformation of the N-terminal hexapeptide ((9)KWAGGK(14)). Cofactor binding leads to a strong change in the fluorescence of Trp(10), whose indole ring approaches the cofactor by 3.3A(.) Stopped-flow kinetics and AdoMet cross-linking studies indicate that the cofactor prefers binding to the enzyme after preincubation with DNA. In the presence of DNA, AdoMet binding is approximately 2-fold stronger than AdoHcy binding. In the binary complex the side chain of Lys(14) is disordered, whereas Lys(14) stabilizes the active site in the ternary complex. Fluorescence stopped-flow experiments indicate that Lys(14) is important for EcoDam binding of the extrahelical target base into the active site pocket. This suggests that the hexapeptide couples specific DNA binding (Lys(9)), AdoMet binding (Trp(10)), and insertion of the flipped target base into the active site pocket (Lys(14)).

Application of DNA methyltransferases in targeted DNA methylation.

DNA methylation is an essential epigenetic modification. In bacteria, it is involved in gene regulation, DNA repair, and control of cell cycle. In eukaryotes, it acts in concert with other epigenetic modifications to regulate gene expression and chromatin structure. In addition to these biological roles, DNA methyltransferases have several interesting applications in biotechnology, which are the main focus of this review, namely, (1) in vivo footprinting: as several bacterial DNA methyltransferases cannot methylate DNA bound to histone proteins, the pattern of DNA methylation after expression of DNA methyltransferases in the cell allows determining nucleosome positioning; (2) mapping the binding specificity of DNA binding proteins: after fusion of a DNA methyltransferase to a DNA-binding protein and expression of the fusion protein in a cell, the DNA methylation pattern reflects the DNA-binding specificity of the DNA-binding protein; and (3) targeted gene silencing: after fusion of a DNA methyltransferase to a suitable DNA-binding domain, DNA methylation can be directed to promoter regions of target genes. Thereby, gene expression can be switched off specifically, efficiently, and stably, which has a number of potential medical applications.

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.

Mechanism of stimulation of catalytic activity of Dnmt3A and Dnmt3B DNA-(cytosine-C5)-methyltransferases by Dnmt3L.

Dnmt3L has been identified as a stimulator of the catalytic activity of de novo DNA methyltransferases. It is essential in the development of germ cells in mammals. We show here that Dnmt3L stimulates the catalytic activity of the Dnmt3A and Dnmt3B enzymes by directly binding to their respective catalytic domains via its own C-terminal domain. The catalytic activity of Dnmt3A and -3B was stimulated approximately 15-fold, and Dnmt3L directly binds to DNA but not to S-adenosyl-L-methionine (AdoMet). Complex formation between Dnmt3A and Dnmt3L accelerates DNA binding by Dnmt3A 20-fold and lowers its K(m) for DNA. Interaction of Dnmt3L with Dnmt3A increases the binding of the coenzyme AdoMet to Dnmt3A, and it lowers the K(m) of Dnmt3A for AdoMet. On the basis of our data we propose a model in which the interaction of Dnmt3A with Dnmt3L induces a conformational change of Dnmt3A that opens the active site of the enzyme and promotes binding of DNA and the AdoMet. We demonstrate that the interaction of Dnmt3A and Dnmt3L is transient, and after DNA binding to Dnmt3A, Dnmt3L dissociates from the complex. Following dissociation of Dnmt3L, Dnmt3A adopts a closed conformation leading to slow rates of DNA release. Therefore, Dnmt3L acts as a substrate exchange factor that accelerates DNA and AdoMet binding to de novo DNA methyltransferases.

Stopped-flow and mutational analysis of base flipping by the Escherichia coli Dam DNA-(adenine-N6)-methyltransferase.

By stopped-flow kinetics using 2-aminopurine as a probe to detect base flipping, we show here that base flipping by the Escherichia coli Dam DNA-(adenine-N6)-methyltransferase (MTase) is a biphasic process: target base flipping is very fast (k(flip)>240 s(-1)), but binding of the flipped base into the active site pocket of the enzyme is slow (k=0.1-2 s(-1)). Whereas base flipping occurs in the absence of S-adenosyl-l-methionine (AdoMet), binding of the target base in the active site pocket requires AdoMet. Our data suggest that the tyrosine residue in the DPPY motif conserved in the active site of DNA-(adenine-N6)-MTases stacks to the flipped target base. Substitution of the aspartic acid residue of the DPPY motif by alanine abolished base flipping, suggesting that this residue contacts and stabilizes the flipped base. The exchange of Ser188 located in a loop next to the active center by alanine led to a seven- to eightfold reduction of k(flip), which was also reduced with substrates having altered GATC recognition sites and in the absence of AdoMet. These findings provide evidence that the enzyme actively initiates base flipping by stabilizing the transition state of the process. Reduced rates of base flipping in substrates containing the target base in a non-canonical sequence demonstrate that DNA recognition by the MTase starts before base flipping. DNA recognition, cofactor binding and base flipping are correlated and efficient base flipping takes place only if the enzyme has bound to a cognate target site and AdoMet is available.