Cloning and sequence analysis of the plasmid-borne genes encoding the Eco29kI restriction and modification enzymes.

The Eco29kI restriction-modification system (RMS2) has been found to be localized on the plasmid pECO29 occurring naturally in the Escherichia coli strain 29k (Pertzev, A.V., Ruban, N.M., Zakharova, M.V., Beletskaya, I.V., Petrov, S.I., Kravetz, A.N., Solonin, A.S., 1992. Eco29kI, a novel plasmid encoded restriction endonuclease from Escherichia coli. Nucleic Acids Res. 20, 1991). The genes coding for this RMS2, a SacII isoschizomer recognizing the sequence CCGCGG have been cloned in Escherichia coli K802 and sequenced. The DNA sequence predicts the restriction endonuclease (ENase) of 214 amino acids (aa) (24,556 Da) and the DNA-methyltransferase (MTase) of 382 aa (43,007 Da) where the genes are separated by 2 bp and arranged in tandem with eco29kIR preceding eco29kIM. The recombinant plasmid with eco29kIR produces a protein of expected size. MEco29kI contains all the conserved aa sequence motifs characteristic of m5C-MTases. Remarkably, its variable region exhibits a significant similarity to the part of the specific target-recognition domain (TRD) from MBssHII--multispecific m5C-MTase (Schumann, J.J., Walter, J., Willert, J., Wild, C., Koch D., Trautner, T.A., 1996. MBssHII: a multispecific cytosine-C5-DNA-methyltransferase with unusual target recognizing properties. J. Mol. Biol. 257, 949-959), which recognizes five different sites on DNA (HaeII, MluI, Cfr10I, SacII and BssHII), and the comparison of the nt sequences of its variable regions allowed us to determine the putative TRD of MEco29kI.

Transfer RNA(Phe) isoacceptors possess non-identical set of identity elements at high and low Mg2+ concentration.

Primary structures of phage T5- and Escherichia coli-encoded tRNA(Phe) are distinct at four out of 11 positions known as identity elements for E. coli phenylalanyl-tRNA synthetase (FRS). In order to reveal structural requirements for FRS recognition, aminoacylation of wild-type phage T5 tRNA(Phe) gene transcript and mutants containing substitutions of the identity elements at positions 20, 34, 35 and 36 was compared with E. coli tRNA(Phe) gene transcript. The wild-type phage T5 transcript can be aminoacylated with the same catalytic efficiency as the E. coli counterpart. However, the maximal aminoacylation rate for T5 and E. coli transcripts was reached at different Mg2+ concentrations: 4 and 15 mM, respectively. Aminoacylation assays with tRNA(Phe) mutants revealed that (i) phage transcripts with the substituted anticodon bases at positions 35 and 36 were efficient substrates for aminoacylation at 15 mM Mg2+ but not at optimal 4 mM Mg2+; (ii) any change of G34 in phage transcripts dramatically decreased the aminoacylation efficiency at both 4 and 15 mM Mg2+ whereas G34A mutation in the E. coli transcript exhibits virtually no influence on aminoacylation rate at 15 mM Mg2+; (iii) substitution of A20 with U in the phage transcript caused no significant change in the aminoacylation rate at both Mg2+ concentrations; (iv) phage transcripts with double substitutions A20U+A35C and A20U+A36C were very poor substrates for FRS. Collectively, the results indicate the non-identical mode of tRNA(Phe) recognition by E. coli FRS at low and high Mg2+ concentrations. Probably, along with identity elements, the local tRNA conformation is essential for recognition by FRS.

Isolation of a strain overproducing endonuclease Eco29kI: purification and characterization of the homogeneous enzyme.

The physical map of the plasmid pSACII1 carrying the genes of restriction-modification system Eco29kI (isoschizomer of SacII) was determined. The cloning of the Eco29kI endonuclease and methylase genes into the plasmid vector pUC129 produced recombinant strain Escherichia coli K802[pECO29A15] with Eco29kI synthesis level about 100 times higher than in the parent strain. The restriction endonuclease was purified from Escherichia coli K802 [pECO29A15] cells to near homogeneity using column chromatography sequentially on phosphocellulose, hydroxyapatite, and heparin-Sepharose and rechromatography on phosphocellulose. Biochemical characterization of the homogeneous R Eco29kI is given. The enzyme has molecular mass 24.5 kD and is present in the solution as a monomer.

Hemolysin II is more characteristic of Bacillus thuringiensis than Bacillus cereus.

To investigate the distribution of the hemolysin II determinant among strains of Bacillus cereus and Bacillus thuringiensis, thirteen strains of B. cereus and fourteen strains of B. thuringiensis strains were tested for hybridization of their chromosomal DNAs with a DNA probe containing the B. cereus hemolysin II gene. In addition, the production of hemolysin II, whose activity is not inhibited by cholesterol, was tested. The presence (absence) of the hydridization response in the microorganisms's genome correlated with the presence (absence) of cholesterol-unaffected hemolysin production. Only four out of thirteen B. cereus strains were found to give a positive response in hybridization experiments, whereas thirteen out of fourteen B. thuringiensis strains responded positively. DNAs from ten B. thuringiensis strains contained a 3.5 kb EcoRV fragment, which hybridized with the B. cereus hemolysin II gene probe. The 3.5 kb EcoRV DNA fragment from one of these strains (B. thuringiensis VKM-B1555) was cloned and expressed in Escherichia coli cells. The hemolysin encoded by the cloned DNA fragment was not inhibited by cholesterol and possessed all other properties of B. cereus hemolysin II. The obtained data clearly show limited distribution of hemolysin II among B. cereus strains and demonstrate that hemolysin II is more characteristic of B. thuringiensis than B. cereus.