Albertas Timinskas

Specificities of Eleven Different DNA Methyltransferases of Helicobacter pylori Strain 26695

Methyltransferases (MTases) of procaryotes affect general cellular processes such as mismatch repair, regulation of transcription, replication, and transposition, and in some cases may be essential for viability. As components of restriction-modification systems, they contribute to bacterial genetic diversity. The genome of Helicobacter pylori strain 26695 contains 25 open reading frames encoding putative DNA MTases. To assess which MTase genes are active, strain 26695 genomic DNA was tested for cleavage by 147 restriction endonucleases; 24 were found that did not cleave this DNA. The specificities of 11 expressed MTases and the genes encoding them were identified from this restriction data, combined with the known sensitivities of restriction endonucleases to specific DNA modification, homology searches, gene cloning and genomic mapping of the methylated bases m(4)C, m(5)C, and m(6)A.

Cloning and analysis of translational control for genes encoding the Cfr9I restriction-modification system.

The complete type-II Cfr9I restriction-modification (R-M) system of Citrobacter freundii strain RFL9, recognizing the DNA sequence CCCGGG, has been cloned and expressed, and functionally active enzymes have been produced in Escherichia coli. Both the methyltransferase (MTase; M.Cfr9I) and restriction endonuclease (ENase; R.Cfr9I) were found to be encoded on a 2.3-kb cloned fragment in the same transcriptional orientation, but differing in translational phases. The last codon (underlined) (ATGA) of the MTase-encoding gene (Cfr9IM) overlaps with the start codon for the ENase-encoding gene (overlined) (cfr9IR). A nucleotide sequence complementary to a predicted Shine-Dalgarno sequence preceding cfr9IR is within this gene. Predicted free energy (delta G) for formation of the mRNA secondary structure involving these complementary sequences was found to be -16.1 kcal/mol. Amino-acid sequence homology of 80% was found between R.Cfr9I and R.XcyI.