In silico evidence for the horizontal transfer of gsiB, a σ(B)-regulated gene in gram-positive bacteria, to lactic acid bacteria.

gsiB, coding for glucose starvation-inducible protein B, is a characteristic member of the σ(Β) stress regulon of Bacillus subtilis and several other Gram-positive bacteria. Here we provide in silico evidence for the horizontal transfer of gsiB in lactic acid bacteria that are devoid of the σ(Β) factor.

Comparative and evolutionary analysis of plasmid pREN isolated from Lactobacillus rennini, a novel member of the theta-replicating pUCL287 family.

Here, we describe plasmid pREN of Lactobacillus rennini ACA-DC 1534, isolated from traditional Kopanisti cheese. pREN is a circular molecule of 4371 bp. Orf calling revealed a novel repA-orf2 operon with the deduced product of orf2 showing no similarity to other known proteins. Downstream of this operon, a gene cluster encoding different mobilization proteins, namely mobC, mobA1, mobA2 and mobB, was detected. Based on the sequence of the origin of replication (ori) and the similarity pattern of RepA, pREN was placed in the pUCL287 family of theta-replicating plasmids. Multiple sequence alignment demonstrated for the first time the degree of conservation in the pUCL287 oris. Our analysis supported that the identified conserved repeats could drive similar secondary structures in the oris of all plasmids. Furthermore, comparative mapping of pREN with its related plasmids (i.e. pLB925A03 and pLJ42) showed that they retain a unique combination in the architecture of their replication and mobilization elements within the pUCL287 family. Phylogenetic analysis also established that these plasmids have undergone a modular evolutionary process in order to acquire their mob genes. Research on plasmids from uncommon lactic acid bacteria will expand our appreciation for their divergence and will aid their rational selection for biotechnological applications.

Characterization of pLAC1, a cryptic plasmid isolated from Lactobacillus acidipiscis and comparative analysis with its related plasmids.

The pLAC1 plasmid of Lactobacillus acidipiscis ACA-DC 1533, a strain isolated from traditional Kopanisti cheese, was characterised. Nucleotide sequence analysis revealed a circular molecule of 3478bp with a G+C content of 37.2%. Ab initio annotation indicated four putative open reading frames (orfs). orf1 and orf4 were found to encode a replication initiation protein (Rep) and a mobilization protein (Mob), respectively. The deduced products of orf2 and orf3 revealed no significant homology to other known proteins. However, in silico examination of the plasmid sequence supported the existence of a novel operon that includes rep, orf2 and orf3 in pLAC1 and that this operon is highly conserved also in plasmids pLB925A02, pSMA23, pLC88 and pC7. RT-PCR experiments allowed us to verify that these three genes are co-transcribed as a single polycistronic mRNA species. Furthermore, phylogenetic analysis of pLAC1 Rep and Mob proteins demonstrated that they may have derived from different plasmid origins, suggesting that pLAC1 is a product of a modular evolution process. Comparative analysis of full length nucleotide sequences of pLAC1 and related Lactobacillus plasmids showed that pLAC1 shares a very similar replication backbone with pLB925A02, pSMA23 and pLC88. In contrast, mob of pLAC1 was almost identical with the respective gene of plasmids pLAB1000, pLB4 and pPB1. These findings lead to the conclusion that pLAC1 acquired mob probably via an ancestral recombination event. Our overall work highlights the importance of characterizing plasmids deriving from non-starter 'wild' isolates in order to better appreciate plasmid divergence and evolution of lactic acid bacteria.