Ernst G. Malygin

Identification of the gene encoding vaccinia virus immunodominant protein p35

The major envelope protein, p35, of vaccinia virus (VV; strain LIVP) was purified by extraction from virions with the non-ionic detergent Nonidet P-40. The protein was cleaved with CNBr. Four homogeneous peptides were isolated and their N-terminal amino-acid (aa) sequences determined. A computer search of a protein sequence databank revealed complete identity of the determined sequences with aa 44-63, 144-149, 154-165 and 224-238 of ORF H3 of the HindIII-H fragment of the VV genome [Rosel et al., J. Virol. 60 (1989) 436-446]. Earlier, Gordon et al. [Virology 167 (1988) 361-369] determined that the p35 surface protein of VV strain IHD-W is encoded by the H6 gene. Muravlev et al. [Biopolymery i kletka 6 (1990) 83-89 (Russian)] deduced from their data that gene A2 encodes this prominent antigen. Taking into account this ambiguity, we cloned the genes H3, H6 and A2 in expression vectors, prepared the specific antisera against the expression products and conducted the immunochemical analysis of the recombinant and native VV-specific proteins. It has been established that the H6 codes for an early protein that is found only in the infected cell extracts, but is absent in mature virions. The immunodominant protein p35 of VV strain LIVP is encoded by the gene H3. The gene A2 protein product is present mainly in the infected cell extract, but the antiserum against the A2 product shows a rather weak interaction with the 35-kDa fraction of structural VV proteins resolved by electrophoresis.

Bacteriophage T4 Dam DNA-(N6-adenine)-methyltransferase: Processivity and orientation to the methylation target

We carried out steady state and pre-steady state (burst) kinetic analyses of the bacteriophage T4 Dam DNA-(N 6-adenine)-methyltransferase (MTase)-mediated methyl group transfer fromS-adenosyl-l-methionine (AdoMet) to Ade in oligonucleotide duplexes containing one or two specific GATC sites with different combinations of methylated and unmodified targets. We compared the results for ligated 40-mer duplexes with those of the mixtures of the two unligated duplexes used to generate the 40-mers. The salient results are as follows: (i) T4 Dam MTase modifies 40-mer duplexes in a processive fashion. (ii) During processive movement, T4 Dam rapidly exchanges productS-adenosyl-l-homocysteine (AdoHcy) for substrate AdoMet without dissociating from the DNA duplex. (iii) T4 Dam processivity is consistent with an ordered bi-bi mechanism AdoMet↓DNA↓DNAMe↑AdoHcy↑. However, in contrast to the steady state, here DNAMe↑ signifies departure from a methylated site GMTC↑ without physically dissociating from the DNA. (iv) Following methyl transfer at one site and linear diffusion to a hemimethylated site, a reconstituted T4 Dam-AdoMet complex rapidly reorients itself to the (productive) unmethylated strand. T4 Dam-AdoHcy cannot reorient at an enzymatically created GMTC site. (v) The inhibition potential of fully methylated sites 5′-GMTC/5′-GMTC is much lower for a long DNA molecule compared with short single-site duplexes.

High-performance method for specific effect on nucleic acids in cells using TiO2~DNA nanocomposites

Nanoparticles are used to solve the current drug delivery problem. We present a high-performance method for efficient and selective action on nucleic acid target in cells using unique TiO2·PL-DNA nanocomposites (polylysine-containing DNA fragments noncovalently immobilized onto TiO2 nanoparticles capable of transferring DNA). These nanocomposites were used for inhibition of human influenza A (H3N2) virus replication in infected MDCK cells. They showed a low toxicity (TC50 ≈ 1800 μg/ml) and a high antiviral activity (>99.9% inhibition of the virus replication). The specificity factor (antisense effect) appeared to depend on the delivery system of DNA fragments. This factor for nanocomposites is ten-times higher than for DNA in the presence of lipofectamine. IC50 for nanocomposites was estimated to be 1.5 μg/ml (30 nM for DNA), so its selectivity index was calculated as ~1200. Thus, the proposed nanocomposites are prospective for therapeutic application.

DNA methyltransferases: Mechanistic models derived from kinetic analysis

The sequence-specific transfer of methyl groups from donor S-adenosyl-L-methionine (AdoMet) to certain positions of DNA-adenine or -cytosine residues by DNA methyltransferases (MTases) is a major form of epigenetic modification. It is virtually ubiquitous, except for some notable exceptions. Site-specific methylation can be regarded as a means to increase DNA information capacity and is involved in a large spectrum of biological processes. The importance of these functions necessitates a deeper understanding of the enzymatic mechanism(s) of DNA methylation. DNA MTases fall into one of two general classes; viz. amino-MTases and [C5-cytosine]-MTases. Amino-MTases, common in prokaryotes and lower eukaryotes, catalyze methylation of the exocyclic amino group of adenine ([N6-adenine]-MTase) or cytosine ([N4-cytosine]-MTase). In contrast, [C5-cytosine]-MTases methylate the cyclic carbon-5 atom of cytosine. Characteristics of DNA MTases are highly variable, differing in their affinity to their substrates or reaction products, their kinetic parameters, or other characteristics (order of substrate binding, rate limiting step in the overall reaction). It is not possible to present a unifying account of the published kinetic analyses of DNA methylation because different authors have used different substrate DNAs and/or reaction conditions. Nevertheless, it would be useful to describe those kinetic data and the mechanistic models that have been derived from them. Thus, this review considers in turn studies carried out with the most consistently and extensively investigated [N6-adenine]-, [N4-cytosine]- and [C5-cytosine]-DNA MTases.

Application of the small-angle x-ray scattering technique for the study of two-step equilibrium enzyme-substrate interactions

The small-angle x-ray scattering (SAXS) technique is used for the investigation of two-stage equilibrium macromolecular interactions of the enzyme-substrate type in solution. Experimental procedures and methods of analyzing the data obtained from SAXS have been elaborated. The algorithm for the data analysis allows one to determine the stoichiometric, equilibrium, and structural parameters of the enzyme-substrate complexes obtained. The thermodynamic characteristics for the formation of complexes of double-stranded oligonucleotide with Eco dam methyltransferase (MTase) have been determined and demonstrate a high cooperativity of MTase binding when the ternary complex containing the dimeric enzyme is formed. The structural parameters (Rg, Rc, semiaxes) have been determined for free enzyme and polynucleotides and of enzyme-substrate complexes, indicating structural rearrangements of the enzyme in the interaction with substrates.

Functional analysis of BamHI DNA cytosine-N4 methyltransferase

We show that the kinetic mechanism of the DNA (cytosine-N(4)-)-methyltransferase M.BamHI, which modifies the underlined cytosine (GGATCC), differs from cytosine C(5) methyltransferases, and is similar to that observed with adenine N(6) methyltransferases. This suggests that the obligate order of ternary complex assembly and disassembly depends on the type of methylation reaction. In contrast, the single-turnover rate of catalysis for M.BamHI (0.10s(-1)) is closer to the DNA (cytosine-C(5)-)-methyltransferases (0.14s(-1)) than the DNA (adenine-N(6)-)-methyltransferases (>200s(-1)). The nucleotide flipping transition dominates the single-turnover constant for adenine N(6) methyltransferases, and, since the disruption of the guanine-cytosine base-pair is essential for both types of cytosine DNA methyltransferases, this transition may be a common, rate-limiting step for methylation for these two enzyme subclasses. The similar overall rate of catalysis by M.BamHI and other DNA methyltransferases is consistent with a common rate-limiting catalytic step of product dissociation. Our analyses of M.BamHI provide functional insights into the relationship between the three different classes of DNA methyltransferases that complement both prior structural and evolutionary insights.

Dimeric/oligomeric DNA methyltransferases: an unfinished story.

Abstract DNA methyltransferases (MTases) are enzymes that carry out post-replicative sequence-specific modifications. The initial experimental data on the structure and kinetic characteristics of the EcoRI MTase led to the paradigm that type II systems comprise dimeric endonucleases and monomeric MTases. In retrospect, this was logical because, while the biological substrate of the restriction endonuclease is two-fold symmetrical, the in vivo substrate for the MTase is generally hemi-methylated and, hence, inherently asymmetric. Thus, the paradigm was extended to include all DNA MTases except the more complex bifunctional type I and type III enzymes. Nevertheless, a gradual enlightenment grew over the last decade that has changed the accepted view on the structure of DNA MTases. These results necessitate a more complex view of the structure and function of these important enzymes.

Bacteriophage T4Dam DNA-(Adenine-N6)-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-N6)-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.

DNA-(N4-Cytosine)-Methyltransferase from Bacillus amyloliquefaciens: Kinetic and Substrate-binding Properties

Interaction of DNA-(N4-cytosine)-methyltransferase from the Bacillus amyloliquefaciens (BamHI MTase, 49 kDa) with a 20-mer duplex containing a palindromic recognition site GGATCC was studied by methods of steady-state and pre-steady-state kinetics of the methyl group transfer, gel retardation, and crosslinking of the enzyme subunits with glutaraldehyde. In steady-state conditions, BamHI MTase displays a simple kinetic behavior toward the 20-mer substrate. A linear dependence was observed for the reaction rate on the enzyme concentration and a Michaelis dependence of the reaction rate on the concentration of both substrates: S-adenosyl-L-methionine (SAM), the methyl group donor, and DNA, the methyl group acceptor. In independent experiments, the concentration of the 20-mer duplex or SAM was changed, the enzyme concentration being substantially lower than the concentrations of substrates. The kcat values determined in these conditions are in good agreement with one another and approximately equal to 0.05 s–1. The KM values for the duplex and SAM are 0.35 and 1.6 μM, respectively. An analysis of single turnover kinetics (at limiting concentration of the 20-mer duplex) revealed the following characteristics of the BamHI MTase-dependent methylation of DNA. The value of rate constant of the DNA methylation step at the enzyme saturating concentration is on average 0.085 s–1, which is only 1.6 times higher than the value determined in steady-state conditions. Only one of two target cytidine residues was methylated in a single turnover of the enzyme, which coincides with the earlier data on EcoRI MTase. Regardless of the order of enzyme preincubation with SAM and DNA, both curves for the single turnover methylation are comparable. These results are consistent with the model of the random order of the productive ternary enzyme–substrate complex formation. In contrast to the relatively simple kinetic behavior of BamHI MTase in the steady-state reaction are the data on the enzyme binding with DNA. In gel retardation experiments, there was no stoichiometrically simple complex with the oligonucleotide duplex even at low enzyme concentrations. The molecular mass of the complexes was so high that they did not enter 12% PAG. In experiments on crosslinking of the BamHI MTase subunits, it was shown that the enzyme in a free state exists as a dimer. Introduction of substoichiometric amounts of DNA into the reaction mixture results in pronounced multimerization of the enzyme. However, addition of SAM in saturating concentration at an excess of the oligonucleotide duplex over BamHI MTase converts most of the enzyme into a monomeric state.

Design of deoxyribozymes for inhibition of influenza a virus reproduction

Influenza A viruses play a significant role in human and animal pathologies that cause epidemics and epizootics. Therefore, the development of new anti-flu drugs has become increasingly urgent. Deoxyribozymes can be considered as promising antiviral agents due to their ability to efficiently cleave RNA molecules with high specificity. In this study, a number of genomic sequences of the most relevant influenza A virus subtypes, i.e., H5N1, H3N2, and H1N1, were analyzed. Conserved regions were revealed in the five least variable segments of the fragmented viral RNA genome, and potential sites of their cleavage with 10–23 deoxyribozymes were determined. We designed and synthesized 46 virus-specific 33-mer deoxyribozymes with the general structure of 5′N8AGGCTAGCTACAACGAN9. Screening of the antiviral activity of these agents in combination with lipofectin on the Madin-Darby Canine Kidney cells infected with highly pathogenic avian influenza virus A/chicken/Kurgan/05/2005(H5N1) revealed 17 deoxyribozymes that suppressed the titer of virus cytopathicity by more than 2.5 logTCID50/mL (i.e. the neutralization index of the virus was more than 300), five of which suppressed the virus titer by a factor of 1000 or more. The most active deoxyribozymes appeared to be specific to segment 5 of the influenza A virus genome, which encoded NP nucleoprotein.