Study of the conditions of activation and stabilization of DNA-methylases from Shigella sonnei 47 during fractionation, purification and storage

A comparative study of activation factors and stabilization conditions of partially purified and individual fractions of DNA-methylases of Shigella sonnei 47 was carried out. The stability of DNA-methylases in the course of storage was examined. The influence of activating factors and stabilization conditions differed significantly depending on the degree of purification and composition of methylase preparations. It was shown that glycerol is ineffective as a stabilizing agent. The activating effect of Ca2+ on Shigella sonnei 47 DNA-methylases was found to be universal, while albumin was shown to exert a more potent stabilizing action. The inactivating effect of proteases on DNA methylation enzymes during storage was demonstrated. A phenomenon of spontaneous fluctuations in the methylating activity of enzymatic preparations of Shigella sonnei 47 upon storage was observed.     

Factors of activation and stabilization of DNA-methylases from Shigella sonnei 47 and Mycobacterium smegmatis butyricum cells

A comparative study of factors of activation and stabilization of individual DNA-methylases from two bacterial strains--Shigella sonnei 47 and Mycobacterium smegmatis butyricum--isolated by isoelectrofocusing in a pH gradient has been carried out. Storage of enzymes at +4 degrees C (pH 7.5) is accompanied by periodic changes in the methylating activity. No such changes are observed when the enzymes are stored at pI of the protein. In this case the methylases with alkaline or close to neutral values of pI remain stable over a period of at least two weeks, whereas acidic proteins are irreversibly inactivated by the end of a two-week period. A stabilizing effect of BSA on DNA-methylases of Sso 47 and Mbu strains has been demonstrated. A direct correlation between the stabilizing effect of BSA and the degree of enzyme purity has been established. Ca2+ appear to be a universal activator of methylases of the above strains; these cations produce a potent, although a short-term effect and can be used in the production of enzyme preparations with a high specific activity in DNA recombinant technology. Protease inhibitors do not exert any appreciable effect on the methylase activity upon storage. Storage at -20 degrees C and at neutral pH leads to complete inactivation of all DNA-methylases within 24 hours. In this case glycerol is fairly ineffective as a stabilizing agent.     

Study of the methylation process and DNA methylase specificity in Shigella]

The nature and content of minor bases in DNA of 3 Shigella strains are investigated. DNAs from Shigella stutzeri 2, Sh. sonnei 1188 and Sh. sonnei 311 are found to contain 0.43, 0.56 and 0.45 mol.% of N6-methyladenine respectively. 5-methylcytosine (0.16 mol.%) is discovered in Sh. sonnei 311. Substrate specificity of adenine methylase from Sh. sonnei 1188 with respect to phage DNAs of different host modification is investigated. Recognition sites for guanine methylase of DDVI phage and for adenine methylase of Sh. sonnei 1188 turned to be different. DNA of DDII phage grown in Sh. stutzeri 2 cells does not accept methyl groups under the treatment with Sh. sonnei 1188 extracts, but it is methylated by Escherichia coli extract. Adenine methylases of Sh. sonnei 1188 and Sh. stutzeri 2 are suggested to be either the same enzyme, or enzymes, which recognition sites are partially overlapped.     

Specificity and functions of guanine methylase of Shigella sonnei DDVI phage.

DNA methylase methylating adenine with formation of 6-methylaminopurine has been identified in Shigella sonnei 1188 cells which are the natural host of DDVI phage. At the same time, in DNA of DDVI phage replicating both in Sh. sonnei 1188 cells and in Escherichia coli B cells 7-methylguanine was found as the only minor base in amounts of 0.25 and 0.27 mol per 100 mol of nucleotides, respectively. The extract of the infected cells was found to contain both kinds of DNA methylases: virus-specific guanine methylase and cellular adenine methylase. The lack of 6-methylaminopurine in DNA of this phage is explained by reversible inhibition of the cell enzyme in the infected cells. The amount of methyl groups transferred by DDVI-specific methylase on DNA does not depend on the species of the infected cells and is similar in the case of unmodified SD phage DNA and DNA of T2 phage methylated by E. coli B enzyme. Guanine methylase has been shown to be a DDVI-induced modification enzyme and to protect against restriction of B-type. It methylates double-stranded DNAs only and is inhibited by S-adenosylhomocysteine.     

Sequence specificity of isolated DNA-cytosine methylases from Shigella sonnei 47 cells

Five individual DNA-cytosine methylases differing in pI (isoelectric point) values are present in Shigella sonnei 47-cells. The sequence specificity of each of those was determined 'in vitro' by a highly efficient combined approach that included pyrimidine tract (isostic) analysis, identification of the immediate neighbourhood of the methylated base within the recognition sequence and the calculation method. The enzyme with pI 5.3 (MSso5.3) is the counterpart of the RSso 47 II in the Sso 47 II restriction-modification system and methylates the internal cytosine residue of the 'palindromic' 5'-C-C-N-G-G-3' sequence. The enzymes with pI 6.2 (MSso6.2) and 7.4 (MSso7.4) exhibit identical specificity upon methylation of the 'palindromic' 5'-Py-C-N-G-Pu-3' sequence, but differ in the pI values of the proteins. The enzyme with pI 4.2 (MSso4.2) recognizes the unique tetranucleotide 5'-C-C-C-C-3' sequence and methylates the second cytosine residue at the 5'-end of the sequence. The enzyme with pI 8.4 (MSso8.4) methylates the central cytosine residue within the degenerative trinucleotide 5'-(PuC)-C-C-3' sequence. MSso5.3, MSso6.2, and MSso7.4 are presumed to belong to the 'family' of sequence-specific (Eco RII-like) enzymes. These DNA-cytosine methylases are likely to be evolutionary related to Eco RII and to have undergone a sufficient genetic drift so as to recognize similar (but more degenerative) nucleotide sequences.     

Functional characteristics of plasmids of Shigella sonnei 47 strains

The phenotypic characteristics of Shigella sonnei strain 47 containing 7 plasmids of low molecular weight and 2 plasmids 60-100 Md large have been studied. The strains of Escherichia coli containing the single plasmids or plasmid groups from Shigella sonnei have been obtained by transformation and conjugation. The comparison of phenotypes of the obtained strains has helped to find the plasmid location of the determinants for streptomycin resistance (P7), genes for colicinogenicity and colicin immunity (P5), the enzymes of host cell specificity system Sso47I (P6), Sso47II (P4), and the genes for the conjugative DNA transfer (P9). Escherichia coli strains producing individual restriction enzymes SsoI and SsoII have been isolated.     

Use of bacterial DNA-methylases for structuro-functional analysis of the eukaryotic genome

Bacterial DNA-methylases with known recognition sites (RS) were used as probes for structural-and-functional analysis of eukaryotic genome. Adenine and cytosine DNA-methylases recognizing 4 to 6-member unique and degenerative nucleotide sequences having a symmetrical and asymmetrical structure were used for probing. The use of a set of methylases enabled the selection of a probe that was the most sensitive for the given pathology. Thus, severe hypothyrosis was found to be associated with changes in the acceptor capacity of liver DNA in the heterologous++ methylation reaction as could be evidenced from testing by two probes, CCCC and GAATGC. In the cells of chicken liver hepatoma MC29, the acceptor capacity of DNA during GGA methylation appeared to be altered in the greatest degree. DNA-methylases with degenerative SR are weakly specific probes for the study of structural changes (methylation) of the animal genome.     

Sequence specificity of isolated DNA-adenine methylases from Mycobacterium smegmatis (butyricum) and Shigella sonnei 47 cells

A set of four individual DNA-adenine methylases differing in pI (isoelectric point) values (MMbu4.2, MMbu6.4, MMbu7.3, and MMbu8.7), and a sole methylating enzyme with the same base specificity (MSso9.5) are present in M. smegmatis (butyricum) and Sh. sonnei 47 cells, respectively. The sequence specificity of each of those was studied 'in vitro' by a combined approach that comprised isostich (purine tract) analysis and identification of the immediate neighbourhood of the methylated base within the sequence methylated. The MSso9.5 recognition site has been established as the hexanucleotide 'palindromic' 5'-G-A-A-T-T-C-3' sequence which is structurally similar to the analogous MEco RI recognition site. However, in contrast to MEco RI, MSso9.5 methylates the 5'-end adenine residue in the sequence and thus it appears to be an isometimer of MEco RI. By means of the same approach, the partial nucleotide sequences methylated by each of the four individual M. butyricum enzymes were determined. MMbu7.3 and MMbu8.7 exhibit the identical sequence specificity upon methylation of the degenerative trinucleotide 5'-Py-A-Py-3' sequence and thus these enzymes are assumed to represent the different molecular forms of the methylase. MMbu4.2 methylates the 5'-G-G-A-3' sequence and thus it is of a great value as the tool for negating effects of the RBam HI and RAva II-type restriction. MMbu6.4 is of a particular interest on account of its unique DNA methylation pattern which is distinguished in the pronounced clustering of purine bases in the 5'-Pu-Pu-Pu-Pu-Pu-3' sequence methylated.     

Activity of restriction endonuclease Sso II in Escherichia coli strains transformed by Shigella sonnei 47 plasmids

The inverse dependence of activity of restriction endonuclease SsoII preparations on the number of low molecular mass plasmids of Shigella sonnei transforming Escherichia coli recipient cells producing the enzyme has been shown. Escherichia coli strain producing efficiently one of two Shigella sonnei 47 restriction endonucleases SsoII has been isolated. The producer strain harbours two of the nine Shigella sonnei 47 plasmids. One of them P4 codes for SsoII+ phenotype while the other P9 determines the plasmids conjugation transfer. Biochemical and physiological characteristics of the producer strain XS13 are identical to the ones of the recipient Escherichia coli strain PS200. XS13 is unable to induce keratoconjunctivitis in guinea pigs in pathogenicity test.     

Site-specificity of DNA methylases from Shigella sonnei 47 cells

A complex approach involving isoplith analysis, enzymatic treatment of methylated isopliths and a computer analysis of experimental data has been used for determining site specificity of six methylases from Shigella sonnei 47 cells termed according to their specificity for a nitrous base and pI as MC4.2, MC5.3, MC6.2, MC7.4, MC8.4 and MA9.5. It has been found that the recognition site of MA9.5 is a palyndrome six-member structure of the 5'...GAATTC...3' type and that this enzyme is an isometimer with respect to MEcoRI. It has been demonstrated for the first time for methylases that the recognition site of MC4.2 is represented by a non-symmetrical four-member sequence, 5'...NCCCCN...3' characterized by unique blocking of cytosines. MC8.4 possesses a broad specificity of substrate recognition and methylates the cytosine residue within the composition of the non-symmetrical unique sequence 5'...N (C/Pu) CCN...3', whose 5'-terminal base is depleted in three nucleotides. MC5.3 methylates the 3'-terminal cytosine residue within the composition of the pentanucleotide palindrome recognition site, 5'...CCNGG...3'. MC6.2 and MC7.4 possess identical pentanucleotide recognition sites of 5'...(Py)CNG(Pu)...3', but are distinguished in pI. The latter finding has been shown for the first time for different methylases within one strain.     

Localization of SsoII restriction endonuclease and methylase genes on the map of the P4 plasmid

The restrictional mapping of naturally occurring plasmid P4 from Shigella sonnei 47 strain coding for the SsoII restriction endonuclease and methylase genes has been made. Using the genetic engineering approach the locations of the SsoII host cell specificity system enzymes genes have been determined.     

Fractionation and specificity of DNA methylases from the Escherichia coli SK cells

Summary Specificity of DNA methylation enzymes from the E. coli SK cells and conditions for their separation have been investigated. Column chromatography on carboxymethylcellulose permits fractionation of methylase activity into six discrete peaks whose specificity to the methylated base has been determined in vitro with H³-SAM as precursor. All methylases specific for adenine produced 6-methylaminopurine, all methylases specific for cytosine yielded 5-methylcytosine.The first enzymatic activity peak containing cytosine methylase free of traces of adenine-methyiating activity (E₁), and the second peak containing both the enzymes (E₂) were not adsorbed on the ion exchanger and went off the column with the effluent (column buffer). Adenine specific methylase E₂ is retarded to a small extent during the passage through the column. The second adenine methylases (W) was characterized by weak bonds with the ion exchanger and was removed when washing the column with column buffer. The elution with NaCl gradient produced successively three enzymatic activity peaks: adenine methylase (G_I), cytosine methylase (G_II), and one more adenine methylase (G_III) removed from the column by 0.16 m, 0.24 m and 0.43 m NaCl respectively.Using a new modification of the complementary methylation test, the specificity with regard to recognition site was examined for all enzymes, except for W and G_III, which were extremely unstable. The adenine methylases E₂ and G_I and the cytosine methylases E₁ and G_II were shown to recognize different sites and to be different enzymes. In view of the drastic differences in their chromatographic behaviour and physical stability, the adenine methylases W and G_III are probably also different enzymes.     

Mobilization of phase I plasmid in Shigella sonnei and stability of its inheritance in rough strains of Shigella and Escherichia

The plasmid pSS120, determining the synthesis of species specific I phase antigen of Shigella sonnei is mobilized for genetic transfer into E. coli K12 recipient cells with the frequency 12-41%. The frequency depends on the type of mobilized plasmid and recipient strain. The I phase antigen is normally expressed in II phase recipient cells and in E. coli cells. During mobilization pSS120 forms cointegrates representing a recombinant of mobilizing and mobilized plasmids DNA. The study of pSS120 inheritance stability has shown the plasmid to be unstable during culturing of bacteria and to be partially lost from the parent Shigella sonnei strains as well as from the "hybrid" transconjugants obtained. The 60 Md plasmid present in the donor strains of Shigella sonnei is prone to structural fragmentation particularly expressed in Shigella sonnei/E. coli hybrids.     

The modulation of hela cells secretory patterns by invasive Shigella spp. and enteroinvasive E. coli bacterial cells and their soluble components

Considering the important role of cytokines in the initiation and evolution of the inflammatory process induced by Shigella and EIEC strains, the purpose of this study was the characterization of the secretory patterns of HeLa cells induced by Shigella ssp. and EIEC strains and to link the obtained results with the invasiveness level of bacterial strains on this cellular line. During this study there were analyzed two EIEC strains and 12 strains of the following Shigella species: 2 Sh. flexneri 2a, 2 Sh. flexneri 3a, 2 Sh. flexneri 4a, 2 Sh. boydii, 2 Sh. sonnei strains isolated in Romania during 2005 from children with dysentery and diarrhoea and confirmed for their invasive ability by Sereny test. The level of the main pro and anti-inflammatory cytokines, IL-1 beta, IL-6, IL-10, IL-13, IL-17 and TNF-alpha induced by whole bacterial cultures as well as by their soluble mediators was determined by an ELISA test. Our results showed that HeLa cells can be used not only for the qualitative and quantitative assessment of Shigella and EIEC strains invasion ability, but also as a simple work procedure for the investigation of an in vitro complex crosstalk communication mechanisms that involves physical interactions between bacterial cells and epithelial cells (adhesins and complementary receptors) and pro- and anti-inflammatory molecules regulation.The majority of the analyzed Shigella serogroups, with the exception of Shigella sonnei and EIEC strains, inhibited the inflammatory response by reducing the expression of majority of pro-inflammatory cytokines, i.e., IL-1 beta, IL-6, TNF-alpha and IL-17. The reduced cost of the in vitro procedure, the possibility of results interpretation and the strict regulations concerning the use of animals for experimental purposes are the main reasons that support the implementation of such an in vitro test in the research labs.     

Gene cloning and characterization of alanine racemases from Shigella dysenteriae, Shigella boydii, Shigella flexneri, and Shigella sonnei.

Alanine racemase genes (alr) from Shigella dysenteriae, Shigella boydii, Shigella flexneri, and Shigella sonnei were cloned and expressed in Escherichia coli JM109. All genes encoded a polypeptide of 359 amino acids, and showed more than 99% sequence identities with each other. In particular, the S. dysenteriae alr was identical with the S. flexneri alr. Differences in the amino acid sequences between the four Shigella enzymes were only two residues: Gly138 in S. dysenteriae and S. flexneri (Glu138 in the other) and Ile225 in S. sonnei (Thr225 in the other). The S. boydii enzyme was identical with the E. coli K12 alr enzyme. Each Shigella alr enzyme purified to homogeneity has an apparent molecular mass about 43,000 by SDS-gel electrophoresis, and about 46,000 by gel filtration. However, all enzymes showed an apparent molecular mass about 60,000 by gel filtration in the presence of a substrate, 0.1 M l-alanine. These results suggest that the Shigella alr enzymes having an ordinary monomeric structure interact with other monomer in the presence of the substrate. The enzymes were almost identical in the enzymological properties, and showed lower catalytic activities (about 210 units/mg) than those of homodimeric alanine racemases reported.     

Significance of determination of Shigella antibiotic resistance in bacteriological diagnosis of dysentery]

The results of the Shigella antibiotic susceptibility assay within 1995-2002 are presented. 1472 cultures from 1158 patients with intestinal infections and bacteria carriers were isolated. The isolates were tested for their susceptibility to tetracycline, chloramphenicol, gentamicin, kanamycin, ampicillin and ofloxacin. It was shown that S. flexneri and S. sonnei were resistant to tetracycline. The S. flexneri isolates were highly resistant to chloramphenicol (73.3 to 96.0%) while resistance to it in the isolates of S. sonnei varied from 7.7 to 88.5%. In this connection the Levin medium with tetracycline was used to increase the Shigella isolation. In the study of the culture media efficiency with respect to isolation of Shigella it was observed that the Levin medium with tetracycline provided higher rates of S. flexneri and S. sonnei isolation (2.3- and 1.7-fold increase respectively) vs. the Shigella isolation on the Ploskirev medium without the antibiotic.     

Dynamics of the change in sensitivity of shigellae to gentamycin and cephaloridine in vitro]

The dynamics of the changes in the Shigella sensitivity to gentamicin and cephaloridin was studied in vitro using liquid nutrient media with gradually increasing concentrations of the drugs. 50 passages were performed. It was found that Shigella flexner and sonnei decreased their sensitivity to gentamicin to a little extent and remained middle sensitive. Sensitivity of Shigella flexner to cephaloridin also changed to a little extent, while Shigella sonnei became moderately resistant.     

Selective inhibition of uracil tRNA methylases of E. coli by ethionine.

L-ethionine has been found to inhibit uracil tRNA methylating enzymes in vitro under conditions where methylation of other tRNA bases is unaffected. No selective inhibitor for uracil tRNA methylases has been identified previously. 15 mM L-ethionine or 30 mM D,L-ethionine caused about 40% inhibition of tRNA methylation catalyzed by enzyme extracts from E. coli B or E. coli M3S (mixtures of methylases for uracil, guanine, cytosine, and adenine) but did not inhibit the activity of preparations from an E. coli mutant that lacks uracil tRNA methylase. Analysis of the 14CH3 bases in methyl-deficient E. coli tRNA after its in vitro methylation with E. coli B3 enzymes in the presence or absence of ethionine showed that ethionine inhibited 14CH3 transfer to uracil in tRNA, but did not diminish significantly the 14CH3 transfer to other tRNA bases. Under similar conditions 0.6 mM S-adenosylethionine and 0.2 mM ethylthioadenosine inhibited the overall tRNA base methylating activity of E. coli B preparations about 50% but neither of these ethionine metabolites preferentially inhibited uracil methylation. Ethionine was not competitive with S-adenosyl methionine. Uracil methylation was not inhibited by alanine, valine, or ethionine sulfoxide. It is suggested that the thymine deficiency that we found earlier in tRNA from ethionine-treated E. coli B cells, resulted from base specific inhibition by the amino acid, ethionine, of uracil tRNA methylation in vivo.     

Shigella toxicity in immunological tolerance

The toxic effect of killed and live Shigella sonnei cultures on normal mice and on mice, tolerant to Shigella O-antigen and to human erythrocytes of different blood groups (in the ABO system) was under study. The toxicity of shigellae, introduced intraperitoneally, has been found to depend on their viability, on their capacity for penetration into the blood, and on the split character of immunological tolerance to Shigella antigens.