Subspecies-specific distribution of intervening sequences in the Bacillus subtilis prophage ribonucleotide reductase genes.

A collection of 212 gram-positive bacilli isolated from natural habitats was screened for the presence of intervening sequences (introns and intein-coding sequences) in the SPbeta prophage-related ribonucleotide reductase genes bnrdE and bnrdF. Three novel configurations were identified on the basis of the presence of (i) intervening sequences in bnrdE and bnrdF, and (ii) an ORF in the bnrdE-bnrdF spacer. Analysis of the cell wall genetic determinants as well as of the incorporation of radio-labelled glycerol into cell wall allowed newly and previously identified B. subtilis strains with different configurations of bnrdE/bnrdF intervening sequences to be assigned to one of two subspecies. Strains apparently belonging to the subsp. subtilis contain three intervening sequences many of which are associated with the putative homing endonuclease activity. Strains of the subsp. spizizenii contain only one or two ORF-less group I introns. Introns occupying bnrdF are confined to the subspecies subtilis.

Comparative study of the antimutagenic potential of Vitamin E in different E. coli strains.

The antimutagenic potential of Vitamin E due to its antioxidative properties was studied. The new Escherichia coli K12 assay-system designed in our laboratory was employed in order to detect the antimutagenic potential of Vitamin E and to determine its molecular mechanisms of action. The assay is composed of three tests. In Test A, we examine the influence of the antioxidant on induced oxidative mutagenesis in a repair-proficient strain. Spontaneous mutagenesis is monitored in Test B, which is performed with two mutator strains, one mismatch repair-deficient (mutS) and another deficient in 8-oxo-dGTP-ase activity (mutT). In Test M, a repair-proficient strain and its mismatch repair-deficient counterpart (mutH), both carrying a plasmid with microsatellite sequences, are used to measure the level of microsatellite instability. To examine the antimutagenic potential of Vitamin E we also used the WP2 antimutagenicity test. Protective properties of Vitamin E against oxidative mutagenesis were detected in all tests with the E. coli K12 assay-system as well as in the WP2 antimutagenicity test. This study confirms that mismatch repair is essential for repair of oxidative DNA damage. The results obtained indicate that Vitamin E prevents the formation of DNA adducts by lipid peroxidation products rather than those formed by direct oxidation of DNA bases. Moreover, it can reduce microsatellite instability. After further validation, the new E. coli K12 assay-system can be used to test the antimutagenic potential of antioxidants.