Nikolai V. Molochkov

In vitro study of the antibacterial effect of the bacteriophage T5 thermostable endolysin on Escherichia coli cells

This study aimed to evaluate lysis of Escherichia coli stationary cell cultures induced by the combined action of bacteriophage T5 endolysin (l‐alanyl‐d‐glutamate peptidase) and low doses of various cationic agents permeabilizing the outer membrane of Gram‐negative bacteria (polymyxin B, gramicidin D, poly‐l‐lysine, chlorhexidine and miramistin).

High-resolution NMR structure of a Zn2+-containing form of the bacteriophage T5 L-alanyl-D-glutamate peptidase

This paper represents the spatial solution structure of the Zn2+-containing form of the bacteriophage T5 L-alanyl-D-glutamate peptidase (EndoT5-Zn2+). The core of this α + β protein is formed by three α-helices (residues 7–15, 20–30, and 87–104) and a β-sheet containing three β-strands (residues 35–39, 71–76, and 133–135). The protein has two short loops (residues 16–19 and 31–34), a medium-length loop (residues 77–86) containing a short β-hairpin (residues 77–82), and two long loops (residues 40–70 and 105–132). The long loops include a stable 310-helix (residues 66–68) and labile α-helices 46–53 and 113–117. Catalytic Zn2+-binding site is represented by three amino acid residues, His66, Asp73, and His133. The cation-binding His residues are located near the foundations of the long loops, whereas Asp73 is positioned in the middle of the core β-sheet. The catalytic center localization contributes to the stabilization of the entire molecule, with Zn2+-binding playing a key role in the folding of this protein.

Secondary structure of SsoII-like (Cytosine-5)-DNA methyltransferases N-terminal region determined by Circular dichroism spectroscopy

Abstract(Cytosine-5)-DNA methyltransferase SsoII (M.SsoII) has a long N-terminal region (1–71 residues) preceding the sequence with conservative motifs, which are characteristic for all DNA methyltrans-ferases of such kind. The presence of this region provides M.SsoII capability to act as a transcription regulator in SsoII restriction-modification system. To perform its regulatory function, M.SsoII binds specifically to a 15-mer inverted repeat in the promoter region of SsoII restriction-modification system genes. In the present work, properties of the protein Δ(72-379)M.Ecl18kI are studied, which is a deletion mutant of the SsoII-like DNA-methyltransferase M.Ecl18kI and is homologous to M.SsoII N-terminal region. Δ(72-379)M.Ecl18kI capability to bind specifically a DNA duplex containing the regulatory site is demonstrated. However, such a binding takes place only in the presence of high protein excess relative to DNA, which could indicate an altered structure in the deletion mutant in comparison with the full-length M.SsoII. Circular dichroism spectroscopy demonstrated that Δ(72–379)M.Ecl18kI has a strongly pronounced secondary structure and contains 32% α-helices and 20% β-strands. Amino acid sequences alignment of M.SsoII N-terminal region and transcription factors of known spatial structure is made. An assumption is made how α-helices and β-strands are arranged in M.SsoII N-terminal region.

Structure and dynamics of the retro-form of the bacteriophage T5 endolysin

Using high-resolution NMR spectroscopy we conducted a comparative analysis of the structural and dynamic properties of the bacteriophage T5 endolysin (EndoT5) and its retro-form; i.e., a protein with the reversed direction of the polypeptide chain (R-EndoT5). We show that structurally, retro-form can be described as the molten globule-like polypeptide that is easily able to form large oligomers and aggregates. To avoid complications associated with this high aggregation propensity of the retro protein, we compared EndoT5 and R-EndoT5 in the presence of strong denaturants. This analysis revealed that these two proteins possess different internal dynamics in solutions containing 8M urea, with the retro-form being characterized by larger dimensions and slower internal dynamics. We also show that in the absence of denaturant, both forms of the bacteriophage T5 endolysin are able to interact with micelles formed by the zwitterionic detergent dodecylphosphocholine (DPC), and that the formation of the protein-micelle complexes leads to the significant structural rearrangement of polypeptide chain and to the formation of stable hydrophobic core in the R-Endo T5.

2′-aldehyde oligonucleotides: Synthesis and use for affinity modification of DNA-recognizing proteins

Oligonucleotides with 1,2-diol group were prepared from 2′-O-[2-(2,3-dihydroxypropyl)amino-2-oxoethyl]uridine 3′-phosphoramidite. The thermal stability of modified DNA duplexes and their ability to form complexes with the p50 subunit of the NF-ϰB transcription factor and (cytosine-5)-DNA methyltransferase M.SsoII were studied. The periodate oxidation of the 1,2-diol group of the oligonucleotides resulted in reactive 2′-aldehyde derivatives. The opportunity of their use for the affinity modification of DNA-recognizing proteins was studied.

Evidence for the residual tertiary structure in the urea-unfolded form of bacteriophage T5 endolysin.

Using high-resolution NMR spectroscopy, we studied peculiarities of the unfolding process of the bacteriophage T5 endolysin (EndoT5) by strong denaturants. It was shown that in the absence of zinc ions this protein is mostly unfolded in the solution of 8 M urea or 6 M guanidine hydrochloride. However, in the presence of zinc ions EndoT5 unfolding can be achieved only in acidic solutions (at pH < 4.0), whereas at pH > 4.0 NMR spectra of the metal-bound protein (Zn2+–Ca2+–EndoT5 or Zn2+–EndoT5 complexes) exhibit a few chemical shifts characteristic of the native or native-like proteins. Our data, including the pH–titration curve with the pK of ~5, suggested involvement of the zinc-binding histidines in the stabilization of this protein. Up-field signals that appear in the NMR spectra of apo-EndoT5 in the presence of high concentrations of strong denaturants are probably derived from the amino acid residues included in the formation of structured hydrophobic cluster, which likely corresponds to the 81–93 region of EndoT5 and contains some residual tertiary structure. It is possible also that this hydrophobic fragment serves as a foundation for the formation of structured cluster in the unfolded state.

Two novel thermally resistant endolysins encoded by pseudo T-even bacteriophages RB43 and RB49

Identification and cloning of genes as well as biochemical characterization of the gene products were carried out for two novel endolysins of pseudo T-even lytic bacteriophages RB43 and RB49, which represent different myovirus groups of the subfamily Tevenvirinae. Genes RB43ORF159c and RB49р102 were cloned in E. coli cells, and their products were purified to electrophoretic homogeneity with an up to 80 % yield of total activity. In respect to substrate specificity, both enzymes were found to be lytic l-alanoyl-d-glutamate peptidases belonging to the M15 family. The pH optimum functioning of both endolysins was within the range 7.0-9.0, whereas the optimal values of ionic strength were different for the two proteins (25 mM vs 100 mM for the RB43 and RB49 endolysins respectively). Both peptidases were thermally resistant, with the RB43 endolysin being more stable (it restored 81 % of enzyme activity and 96 % of secondary structure after a 10 min heating at 90 °C) than its RB49 counterpart (27 and 77% respectively). The possible origin of genes of lytic l-alanoyl-d-glutamate peptidases of myoviruses as a result of horizontal transfer in the variable parts of genomes between unrelated phages having a common host is discussed.