Reshuffling of the Bacillus subtilis 168 genome by multifold inversion.

The genome of Bacillus subtilis 168 was modified to yield a genome vector for the cloning of DNA several Mb in size. Unlike contemporary plasmid-based vectors, this 4.2 Mb genome vector requires specific in vivo handling protocols because of its large size. Inversion mutagenesis, a method to modify local genome structure without gain or loss of genes, was applied intensively to the B. subtilis genome; this technique made possible both exchange and translocation of designated regions of the genome. This method not only reshuffles the genome of B. subtilis, but can provide insight into the biologic principles underlying genome plasticity.

I-CeuI recognition sites in the rrn operons of the Bacillus subtilis 168 chromosome: inherent landmarks for genome analysis.

The Bacillus subtilis 168 circular chromosome yielded ten fragments on I-CeuI endonuclease digestion. I-CeuI recognizes a 26 bp sequence that is located within the gene encoding the 23S subunit of the rRNA in Chlamydomonas eugametos, Escherichia coli and Salmonella typhimurium. The precise locations of the I-CeuI sites of the B. subtilis chromosome were determined on a NotI-SfiI physical map by (i) double digestion analyses with I-CeuI and SfiI, (ii) comparison of mutant strains lacking a specific rrn operon, (iii) using an I-CeuI linking clone and (iv) analysis of nucleotide sequence data of some rrn operons. In conclusion, all the I-CeuI sites were located within the B. subtilis rrn operons and the I-CeuI sites were conserved in all the B. subtilis 168 derivatives tested. Thus, variations in size of the I-CeuI fragments must be due to genome alterations. A B. subtilis 168 strain was investigated with I-CeuI. We demonstrated that the aberrant structure was the outcome of the inversion of an approximately 1700 kb DNA segment.