Genes involved in SkfA killing factor production protect a Bacillus subtilis lipase against proteolysis

Small lipases of Bacillus species, such as LipA from Bacillus subtilis, have a high potential for industrial applications. Recent studies showed that deletion of six AT-rich islands from the B. subtilis genome results in reduced amounts of extracellular LipA. Here we demonstrate that the reduced LipA levels are due to the absence of four genes, skfABCD, located in the prophage 1 region. Intact skfABCD genes are required not only for LipA production at wild-type levels by B. subtilis 168 but also under conditions of LipA overproduction. Notably, SkfA has bactericidal activity and, probably, requires the SkfB to SkfD proteins for its production. The present results show that LipA is more prone to proteolytic degradation in the absence of SkfA and that high-level LipA production can be improved significantly by employing multiple protease-deficient B. subtilis strains. In conclusion, our findings imply that SkfA protects LipA, directly or indirectly, against proteolytic degradation. Conceivably, SkfA could act as a modulator in LipA folding or as a protease inhibitor.     

Sporulating bacteria prefers predation to cannibalism in mixed cultures

Predatory behavior, a property associated with ecosystems, is not commonly observed in microorganisms. However, cannibalistic tendencies have been observed in microorganisms under stress. For example, pure culture of Bacillus subtilis exhibits cannibalism under nutrient limitation. It has been proposed that a fraction of cells in the population produce Spo0A, a regulatory protein that is responsible for delaying sporulation. Cells containing spo0A would produce a killing factor by activating skf operon and an associated pump to export the factor. Cells that do not contain spo0A in the population are lysed. However in addition to the competition among the cells of B. subtilis, these cells also compete with other organisms for the limited nutrients. In this work, we report the cannibalistic behavior of B. subtilis in presence of Escherichia coli under severe nutritional limitation. We demonstrate that B. subtilis lyses cells of E. coli using an antibacterial factor under the regulation of Spo0A. Our experiments also suggest that B. subtilis prefers predation of E. coli to cannibalism in mixed cultures. B. subtilis also demonstrated predation in mixed cultures with other soil microorganisms, such as, Xanthomonas campestris, Pseudomonas aeruginosa and Acinetobactor lwoffi. This may offer B. subtilis a niche to survive in an environment with limited nutrients and under competition from other microorganisms.     

Cannibalism enhances biofilm development in Bacillus subtilis

Cannibalism is a mechanism to delay sporulation in Bacillus subtilis. Cannibal cells express the skf and sdp toxin systems to lyse a fraction of their sensitive siblings. The lysed cells release nutrients that serve to feed the community, effectively delaying spore formation. Here we provide evidence that the subpopulation of cells that differentiates into cannibals is the same subpopulation that produces the extracellular matrix that holds cells together in biofilms. Cannibalism and matrix formation are both triggered in response to the signalling molecule surfactin. Nutrients released by the cannibalized cells are preferentially used by matrix-producing cells, as they are the only cells expressing resistance to the Skf and Sdp toxins. As a result this subpopulation increases in number and matrix production is enhanced when cannibalism toxins are produced. The cannibal/matrix-producing subpopulation is also generated in response to antimicrobials produced by other microorganisms and may thus constitute a defense mechanism to protect B. subtilis from the action of antibiotics in natural settings.     

Genome-wide transcriptional analysis of the phosphate starvation stimulon of Bacillus subtilis

Bacillus subtilis responds to phosphate starvation stress by inducing the PhoP and SigB regulons. While the PhoP regulon provides a specific response to phosphate starvation stress, maximizing the acquisition of phosphate (P(i)) from the environment and reducing the cellular requirement for this essential nutrient, the SigB regulon provides nonspecific resistance to stress by protecting essential cellular components, such as DNA and membranes. We have characterized the phosphate starvation stress response of B. subtilis at a genome-wide level using DNA macroarrays. A combination of outlier and cluster analyses identified putative new members of the PhoP regulon, namely, yfkN (2',3' cyclic nucleotide 2'-phosphodiesterase), yurI (RNase), yjdB (unknown), and vpr (extracellular serine protease). YurI is thought to be responsible for the nonspecific degradation of RNA, while the activity of YfkN on various nucleotide phosphates suggests that it could act on substrates liberated by YurI, which produces 3' or 5' phosphoribonucleotides. The putative new PhoP regulon members are either known or predicted to be secreted and are likely to be important for the recovery of inorganic phosphate from a variety of organic sources of phosphate in the environment.     

Cloning of genetic material in Bacillus

Plasmid vectors capable for propagation of Bacillus subtilis DNA fragments containing riboflavin genes were constructed. Cloning of rib operon using pUB110 derivatives was performed in recE4 strain by using sequentional rescue of plasmids containing subfragments of the operon. Also, rib operon was cloned on the vectors containing DNA repeats. It was shown that the presence of direct and inverted repeats within plasmids allows to transform B. subtilis cells by monomers of plasmid DNA. Vectors that contained repeated sequences of DNA and ensured efficient cloning of genetic material in B. subtilis recipient cells were constructed. The use of streptococcal plasmid pSM19035 allowed to obtain vectors which were suitable for cloning large DNA fragments (6 MD and even more) in B. subtilis. A model of B. subtilis transformation by various types of plasmid DNA is presented. The model is in agreement with the general conception of chromosomal DNA transformation.     

Amplification of the Bacillus subtilis maf gene results in arrested septum formation.

The Bacillus subtilis homolog of the Escherichia coli morphogene orfE (of the mre operon) has been identified. The determinant is located on the chromosome immediately upstream of the mreBCD-minCD (divIVB) operon. The Maf protein shares substantial amino acid sequence identity with the E. coli OrfE protein. Introduction of the B. subtilis maf determinant on a multicopy plasmid into B. subtilis cells results in an inhibition of septation, which leads to extensive filamentation and loss of viability in the transformed cell population. Insertional inactivation of maf indicated that this gene is not essential for cell division.     

Molecular analysis of the Escherichia coli phoP-phoQ operon.

The phoP-phoQ operon of Salmonella typhimurium is a member of the family of two-component regulatory systems and controls expression of the phoN gene that codes for nonspecific acid phosphatase and the genes involved in the pathogenicity of the bacterium. The phoP-phoQ operon of Escherichia coli was cloned on a plasmid vector by complementation of a phoP mutant, and the 4.1-kb nucleotide sequence, which includes the phoP-phoQ operon and its flanking regions, was determined. The phoP-phoQ operon was mapped at 25 min on the standard E. coli linkage map by hybridization with the Kohara mini set library of the E. coli chromosome (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The predicted phoP and phoQ gene products consist of 223 and 486 amino acids with estimated molecular masses of 25,534 and 55,297 Da, respectively, which correspond well with the sizes of the PhoP and PhoQ proteins identified by the maxicell method. The amino acid sequences of PhoP and PhoQ of E. coli were 93 and 86% identical, respectively, to those of S. typhimurium.