Bioinformatic and partial functional analysis of pEspA and pEspB, two plasmids from Exiguobacterium arabatum sp. nov. RFL1109.

The complete nucleotide sequences of two plasmids from Exiguobacterium arabatum sp. nov. RFL1109, pEspA (4563bp) and pEspB (38,945bp), have been determined. Five ORFs were identified in the pEspA plasmid, and putative functions were assigned to two of them. Using deletion mapping approach, the Rep-independent replication region of pEspA, which functions in Bacillus subtilis, was localized within a 0.6kb DNA region. Analysis of the pEspB sequence revealed 42 ORFs. From these, function of two genes encoding enzymes of the Lsp1109I restriction-modification system was confirmed experimentally, while putative functions of another 18 ORFs were suggested based on comparative analysis. Three functional regions have been proposed for the pEspB plasmid: the putative conjugative transfer region, the region involved in plasmid replication and maintenance, and the region responsible for transposition of the IS21 family-like transposable elements.

Generation of DNA cleavage specificities of type II restriction endonucleases by reassortment of target recognition domains.

Type II restriction endonucleases (REases) cleave double-stranded DNA at specific sites within or close to their recognition sequences. Shortly after their discovery in 1970, REases have become one of the primary tools in molecular biology. However, the list of available specificities of type II REases is relatively short despite the extensive search for them in natural sources and multiple attempts to artificially change their specificity. In this study, we examined the possibility of generating cleavage specificities of REases by swapping putative target recognition domains (TRDs) between the type IIB enzymes AloI, PpiI, and TstI. Our results demonstrate that individual TRDs recognize distinct parts of the bipartite DNA targets of these enzymes and are interchangeable. Based on these properties, we engineered a functional type IIB REase having previously undescribed DNA specificity. Our study suggests that the TRD-swapping approach may be used as a general technique for the generation of type II enzymes with predetermined specificities.