DNA-methyltransferase SsoII interaction with own promoter region binding site

Kinetic Basis of the Bifunctionality of SsoII DNA Methyltransferase

Type II restriction–modification (RM) systems are the most widespread bacterial antiviral defence mechanisms. DNA methyltransferase SsoII (M.SsoII) from a Type II RM system SsoII regulates transcription in its own RM system in addition to the methylation function. DNA with a so-called regulatory site inhibits the M.SsoII methylation activity. Using circular permutation assay, we show that M.SsoII monomer induces DNA bending of 31° at the methylation site and 46° at the regulatory site. In the M.SsoII dimer bound to the regulatory site, both protein subunits make equal contributions to the DNA bending, and both angles are in the same plane. Fluorescence of TAMRA, 2-aminopurine, and Trp was used to monitor conformational dynamics of DNA and M.SsoII under pre-steady-state conditions by stopped-flow technique. Kinetic data indicate that M.SsoII prefers the regulatory site to the methylation site at the step of initial protein–DNA complex formation. Nevertheless, in the presence of S-adenosyl-l-methionine, the induced fit is accelerated in the M.SsoII complex with the methylation site, ensuring efficient formation of the catalytically competent complex. The presence of S-adenosyl-l-methionine and large amount of the methylation sites promote efficient DNA methylation by M.SsoII despite the inhibitory effect of the regulatory site.

Flexibility of the linker between the domains of DNA methyltransferase SsoII revealed by small-angle X-ray scattering: implications for transcription regulation in SsoII restriction-modification system

(Cytosine-5)-DNA methyltransferase SsoII (M.SsoII) consists of a methyltransferase domain (residues 72-379) and an N-terminal region (residues 1-71) which regulates transcription in SsoII restriction-modification system. Small-angle X-ray scattering (SAXS) is employed here to study the low resolution structure of M.SsoII and its complex with DNA containing the methylation site. The shapes reconstructed ab initio from the SAXS data reveal two distinct protein domains of unequal size. The larger domain matches the crystallographic structure of a homologous DNA methyltransferase HhaI (M.HhaI), and the cleft in this domain is occupied by DNA in the model of the complex reconstructed from the SAXS data. This larger domain can thus be identified as the methyltransferase domain whereas the other domain represents the N-terminal region. Homology modeling of the M.SsoII structure is performed by using the model of M.HhaI for the methyltransferase domain and representing the N-terminal region either as a flexible chain of dummy residues or as a rigid structure of a homologous protein (phage 434 repressor) connected to the methyltransferase domain by a short flexible linker. Both models are compatible with the SAXS data and demonstrate high mobility of the N-terminal region. The linker flexibility might play an important role in the function of M.SsoII as a transcription factor.

Peculiarities of the Regulation of Gene Expression in the Ecl18kI Restriction-Modification System

Transcription regulation in bacterial restriction-modification (R-M) systems is an important process, which provides coordinated expression levels of tandem enzymes, DNA methyltransferase (MTase) and restriction endonuclease (RE) protecting cells against penetration of alien DNA. The present study focuses on (cytosine-5)-DNA methyltransferase Ecl18kI (M.Ecl18kI), which is almost identical to DNA methyltransferase SsoII (M.SsoII) in terms of its structure and properties. Each of these enzymes inhibits expression of the intrinsic gene and activates expression of the corresponding RE gene via binding to the regulatory site in the promoter region of these genes. In the present work, complex formation of M.Ecl18kI and RNA polymerase from Escherichia сoli with the promoter regions of the MTase and RE genes is studied. The mechanism of regulation of gene expression in the Ecl18kI R-M system is thoroughly investigated. M.Ecl18kI and RNA polymerase are shown to compete for binding to the promoter region. However, no direct contacts between M.Ecl18kI and RNA polymerase are detected. The properties of M.Ecl18kI and M.SsoII mutants are studied. Amino acid substitutions in the N-terminal region of M.Ecl18kI, which performs the regulatory function, are shown to influence not only M.Ecl18kI capability to interact with the regulatory site and to act as a transcription factor, but also its ability to bind and methylate the substrate DNA. The loss of methylation activity does not prevent MTase from performing its regulatory function and even increases its affinity to the regulatory site. However, the presence of the domain responsible for methylation in the M.Ecl18kI molecule is necessary for M.Ecl18kI to perform its regulatory function.

Crosslinking of (cytosine-5)-DNA methyltransferase SsoII and its complexes with specific DNA duplexes provides an insight into their structures

(Cytosine-5)-DNA methyltransferase SsoII (M.SsoII) functions as a methyltransferase and also as a transcription factor. Chemical and photochemical crosslinking was used for exploring the structure of M.SsoII-DNA complexes and M.SsoII in the absence of DNA. Photocrosslinking with 4-(N-maleimido)benzophenone demonstrated that in the M.SsoII complex with DNA containing the regulatory site, the M.SsoII region responsible for methylation was bound to DNA flanking the regulatory site, which contained no methylation sequence. This required high flexibility of the linker connecting the M.SsoII N-terminal domain and the M.SsoII region responsible for methylation. The flexibility was demonstrated by crosslinking with bis-maleimidoethane and 1,11-bis-maleimidotetraethyleneglycol.

The study of the interaction of (cytosine-5)-DNA methyltransferase SsoII with DNA by acoustic method

The interaction of (cytosine-5)-DNA methyltransferase SsoII (M.SsoII) with double-stranded DNA was studied by means of thickness shear mode acoustic method (TSM) and gel electrophoresis. M.SsoII recognizes in double-stranded DNA the methylation site 5'-CCNGG-3' (N=A, C, G, T) and methylates the inner cytosine residue. M.SsoII also acts as a transcription factor via binding to the regulatory site 5'-AGGACAAATTGTCCT-3' in the promoter region of SsoII restriction-modification system. We designed three 60-mer biotinylated DNA duplexes: with the methylation site (60met), with the regulatory site (60reg), and without a specific binding site (60oct). A strong binding of M.SsoII with each one of the studied DNA immobilized on the TSM transducer has been shown. The equilibrium dissociation constants, K(D), of the M.SsoII-DNA complexes decreased in the order 60oct>60reg>60met, suggesting a higher stability of M.SsoII-60met complex in comparison with the others. The association rate constant, k(a), was also higher for 60met, while similar values were obtained for 60reg and 60oct. The difference in the kinetic parameters for 60met and 60reg suggested a possible way of coordination between the two M.SsoII functions in a cell.

SsoII-like DNA-methyltransferase Ecl18kI: interaction between regulatory and methylating functions

The interaction of DNA-methyltransferase Ecl18kI (M.Ecl18kI) with a fragment of promoter region of restriction-modification system SsoII was studied. It is shown that dissociation constants of M.Ecl18kI and M.SsoII complexes with DNA ligand carrying a regulatory site previously characterized for M.SsoII have comparable values. A deletion derivative of M.Ecl18kI, Delta(72-379)Ecl18kI, representing the N-terminal protein region responsible for regulation, was obtained. It is shown that such polypeptide fragment has virtually no interaction with the regulatory site. Therefore, the existence of a region responsible for methylation is necessary for maintaining M.Ecl18kI regulatory function. The properties of methyltransferase NlaX, which is actually a natural deletion derivative of M.Ecl18kI and M.SsoII lacking the first 70 amino acid residues and not being able to regulate gene expression of the SsoII restriction-modification system, were studied. The ability of mutant forms of M.Ecl18kI incorporating single substitutions in regions responsible for regulation and methylation to interact with both sites of DNA recognition was characterized. The data show a correlation between DNA-binding activity of two M.Ecl18kI regions-regulatory and methylating.

[Regulation of gene expression in type II restriction-modification system]

Type II restriction-modification systems are comprised of a restriction endonuclease and methyltransferase. The enzymes are coded by individual genes and recognize the same DNA sequence. Endonuclease makes a double-stranded break in the recognition site, and methyltransferase covalently modifies the DNA bases within the recognition site, thereby down-regulating endonuclease activity. Coordinated action of these enzymes plays a role of primitive immune system and protects bacterial host cell from the invasion of foreign (for example, viral) DNA. However, uncontrolled expression of the restriction-modification system genes can result in the death of bacterial host cell because of the endonuclease cleavage of host DNA. In the present review, the data on the expression regulation of the type II restriction-modification enzymes are discussed.

Maintenance forced by a restriction-modification system can be modulated by a region in its modification enzyme not essential for methyltransferase activity

Several type II restriction-modification gene complexes can force their maintenance on their host bacteria by killing cells that have lost them in a process called postsegregational killing or genetic addiction. It is likely to proceed by dilution of the modification enzyme molecule during rounds of cell division following the gene loss, which exposes unmethylated recognition sites on the newly replicated chromosomes to lethal attack by the remaining restriction enzyme molecules. This process is in apparent contrast to the process of the classical types of postsegregational killing systems, in which built-in metabolic instability of the antitoxin allows release of the toxin for lethal action after the gene loss. In the present study, we characterize a mutant form of the EcoRII gene complex that shows stronger capacity in such maintenance. This phenotype is conferred by an L80P amino acid substitution (T239C nucleotide substitution) mutation in the modification enzyme. This mutant enzyme showed decreased DNA methyltransferase activity at a higher temperature in vivo and in vitro than the nonmutated enzyme, although a deletion mutant lacking the N-terminal 83 amino acids did not lose activity at either of the temperatures tested. Under a condition of inhibited protein synthesis, the activity of the L80P mutant was completely lost at a high temperature. In parallel, the L80P mutant protein disappeared more rapidly than the wild-type protein. These results demonstrate that the capability of a restriction-modification system in forcing maintenance on its host can be modulated by a region of its antitoxin, the modification enzyme, as in the classical postsegregational killing systems.

DNA-methyltransferase SsoII as a bifunctional protein: Features of the interaction with the promoter region of SsoII restriction-modification genes

DNA duplexes bearing an aldehyde group at the 2'-position of the sugar moiety were used for affinity modification of (cytosine-5)-DNA methyltransferase SsoII. It is shown that lysine residues of M.SsoII N-terminal region are located in proximity to DNA sugar-phosphate backbone of a regulatory sequence of promoter region of SsoII restriction-modification enzyme coding genes. The ability of the two M.SsoII subunits to interact with DNA regulatory sequence has been demonstrated by affinity modification using DNA duplexes with two 2'-aldehyde groups. Changes in nucleotide sequence of one half of the regulatory region prevented cross-linking of the second M.SsoII subunit. The results on sequential affinity modification of M.SsoII by two types of modified DNA ligands (i.e. by 2'-aldehyde-containing and phosphoryldisulfide-containing) have demonstrated the possibility of covalent attachment of the protein to two different DNA recognition sites: regulatory sequence and methylation site.

Two sequential phosphates 3' adjacent to the 8-oxoguanosine are crucial for lesion excision by E. coli Fpg protein and human 8-oxoguanine-DNA glycosylase

Escherichia coli formamidopyrimidine-DNA glycosylase (Fpg) and human 8-oxoguanine-DNA glycosylase (hOGG1) are base excision repair enzymes involved in the 8-oxoguanine (oxoG) repair pathway. Specific contacts between these enzymes and DNA phosphate groups play a significant role in DNA-protein interactions. To reveal the phosphates crucial for lesion excision by Fpg and hOGG1, modified DNA duplexes containing pyrophosphate and OEt-substituted pyrophosphate internucleotide (SPI) groups near the oxoG were tested as substrate analogues for both proteins. We have shown that Fpg and hOGG1 recognize and specifically bind the DNA duplexes tested. We have found that both enzymes were not able to excise the oxoG residue from DNA containing modified phosphates immediately 3' to the 8-oxoguanosine (oxodG) and one nucleotide 3' away from it. In contrast, they efficiently incised DNA duplexes bearing the same phosphate modifications 5' to the oxodG and two nucleotides 3' away from the lesion. The effect of these phosphate modifications on the substrate properties of oxoG-containing DNA duplexes is discussed. Non-cleavable oxoG-containing DNA duplexes bearing pyrophosphate or SPI groups immediately 3' to the oxodG or one nucleotide 3' away from it are specific inhibitors for both 8-oxoguanine-DNA glycosylases and can be used for structural studies of complexes comprising a wild-type enzymes bound to oxoG-containing DNA.

Transcriptional analysis and regulation of expression of the ScrFI restriction-modification system of Lactococcus lactis subsp. cremoris UC503

ScrFI is a type II restriction-modification system from Lactococcus lactis which recognizes the nucleotide sequence 5'-CC downward arrow NGG-3', cleaving at the point indicated by the arrow, and it comprises an endonuclease gene that is flanked on either side by genes encoding two 5-methylcytosine methylases. An open reading frame (orfX) of unknown function is located immediately upstream of these genes. In this study Northern analysis was performed, and it revealed that orfX, scrFIBM, and scrFIR are cotranscribed as a single polygenic mRNA molecule, while scrFIAM is transcribed independently. 5' extension analysis indicated that the start site for the scrFIAM promoter was a thymine located 4 bp downstream of the -10 motif. The transcriptional start site for the orfX promoter was also found to be a thymine which is more atypically located 24 bp downstream of the -10 motif proximal to the start codon. A helix-turn-helix motif was identified at the N-terminal end of one of the methylases (M.ScrFIA). In order to determine if this motif played a role in regulation of the ScrFI locus, M.ScrFIA was purified. It was then employed in gel retardation assays using fragments containing the two promoters found on the ScrFI operon, one located upstream of orfX and the other located just upstream of scrFIAM. M.ScrFIA was found to bind to the promoter region upstream of the gene encoding it, indicating that it may have a regulatory role. In further studies the two putative promoters were introduced into a vector (pAK80) upstream of a promoterless lacZ gene, and cloned fragments of the ScrFI locus were introduced in trans with each of these promoter constructs to investigate the effect on promoter activity. These results implicated M.ScrFIA in regulation of both promoters on the ScrFI locus.

Gilbert's conjecture: the search for DNA (cytosine-5) demethylases and the emergence of new functions for eukaryotic DNA (cytosine-5) methyltransferases

In 1985 Walter Gilbert challenged members of the DNA methylation community assembled at a National Institutes of Health meeting organized by Giulio Cantoni and Ahron Razin with the following words: "The most exciting aspect about the methyl groups on DNA is the thought that they might provide a locally inherited change in a DNA structure. However, for that to be interesting, those changes have to be different in different cells. Furthermore, the alterations in methylation have to be freely imposable and have to be maintained. It is not yet clear that all these properties are true. So I don't think one will find that methylation ever is one of the primary, top-level controls on gene expression."In essence, Gilbert's conjecture, that DNA methylation is not one of the top-level controls on gene expression, assumes that evidence in favor of both of its testable propositions will not be obtained. Evidence for the first proposition, that alterations in methylation status associated with gene-expression states have to be maintained, was already available in 1985 and has been strengthened by a number of very recent experiments. However, the extensive effort to obtain evidence for the second proposition, that alterations in methylation status be freely imposable, has not been successful in its original intent. The effort has, on the other hand, resulted in the emergence of new functions for 5-methylcytosine and the cytosine methyltransferases in eukaryotic DNA repair, recombination and chromosome stability.