Adaptor bypass mutations of Bacillus subtilis spx suggest a mechanism for YjbH‐enhanced proteolysis of the regulator Spx by ClpXP

The global regulator, Spx, is under proteolytic control exerted by the adaptor YjbH and ATP‐dependent protease ClpXP in Bacillus subtilis. While YjbH is observed to bind the Spx C‐terminus, YjbH shows little affinity for ClpXP, indicating adaptor activity that does not operate by tethering. Chimeric proteins derived from B. subtilis AbrB and the Spx C‐terminus showed that a 28‐residue C‐terminal section of Spx (AbrB28), but not the last 12 or 16 residues (AbrB12, AbrB16), was required for YjbH interaction and for ClpXP proteolysis, although the rate of AbrB28 proteolysis was not affected by YjbH addition. The result suggested that the YjbH‐targeted 28 residue segment of the Spx C‐terminus bears a ClpXP‐recognition element(s) that is hidden in the intact Spx protein. Residue substitutions in the conserved helix α6 of the C‐terminal region generated Spx substrates that were degraded by ClpXP at accelerated rates compared to wild‐type Spx, and showed reduced dependency on the YjbH activity. The residue substitutions also weakened the interaction between Spx and YjbH. The results suggest a model in which YjbH, through interaction with residues of helix α6, exposes the C‐terminus of Spx for recognition and proteolysis by ClpXP.     

Engineering Bacillus subtilis ATCC 6633 for improved production of the lantibiotic subtilin

To improve the production of the lantibiotic subtilin in Bacillus subtilis ATCC 6633, two genetic engineering strategies were followed. Firstly, additional copies of subtilin self-protection (immunity) genes spaIFEG have been integrated into the genome of the producer strain. Their expression significantly enhanced the subtilin tolerance level, and concomitantly, the subtilin yield 1.7-fold. Secondly, a repressor of subtilin gene expression, the B. subtilis general transition state regulator protein AbrB, was deleted. A sixfold enhancement of the subtilin yield could be achieved with the abrB deletion mutant; however, the produced subtilin fraction predominantly consists of succinylated subtilin species with less antimicrobial activity compared to unmodified subtilin.     

Oxygen-Limiting Growth Conditions and Deletion of the Transition State Regulator Protein Abrb in Bacillus subtilis 6633 Result in an Increase in Subtilosin Production and a Decrease in Subtilin Production

It has been recently shown, that certain strains/isolates of Bacillus subtilis can be used as a probiotic for humans. The production of the macrocyclic sactibiotic subtilosin in B. subtilis ATCC 6633 is highly regulated. To improve the subtilosin productivity of B. subtilis, different growth conditions were compared for maximal expression of the sbo promoter that regulates the expression of the subtilosin biosynthetic gene cluster. Oxygen-limiting conditions led to a strong increase of sbo promoter activities compared to aerobic conditions, and accordingly, the subtilosin amount determined by reversed phase HPLC (7.8 mg/L) was 15-fold superior to the amount of aerobic grown cultures (0.5 mg/L). A further promising enhancement of the subtilosin yield was achieved using a deletion mutant that is avoiding the general transition state regulator protein AbrB. The subtilosin titer of 42 mg/L produced by ΔabrB cells grown under oxygen-limiting conditions corresponds to an 84-fold increase compared to the subtilosin titer obtained from B. subtilis wild type cells propagated in aerobic conditions. Furthermore, evidence is provided that oxygen-limiting conditions led to a strong decrease in the productivity of the lantipeptide subtilin suggesting contrary regulatory mechanisms for the B. subtilis antimicrobials subtilin and subtilosin.

     

Comparative genomic study of <Emphasis Type="Italic">spo0E</Emphasis> family genes and elucidation of the role of Spo0E in <Emphasis Type="Italic">Bacillus anthracis</Emphasis>

The propensity of bacterium to sporulate or retain the vegetative form depends on the amount of phosphorylated Spo0A (Spo0A^-P), regulated by Spo0E multigene family of phosphatases (Spo0E, YisI and YnzD). Phylogenetic analysis revealed that Spo0E multigene family of phosphatases (SMFP) descends in two distinct clades of aerobic (Bacillus cluster) and anaerobic (Clostridia cluster) sporulating bacteria. High sequence conservation within species gives a notion that these members could have evolved through lineage and species-specific duplication event. Of the five genes in Bacillus cereus group, three are pathogen specific, and their synteny suggests that these paralogs could be involved in the regulation of amino acid metabolism and its transport. Overexpression of B. subtilis Spo0E, an ortholog of SMFP members in B. anthracis (BAS1251), resulted in sporulation deficient phenotype in B. anthracis. B. anthracis Spo0A^-P binds to a consensus DNA sequence 5′-TGNCGAA-3′ (‘0A-like box’) and loses its DNA binding ability following treatment with B. subtilis Spo0E. Thus, B. subtilis Spo0E acts on B. anthracis Spo0A^-P and, therefore could complement the function of BAS1251. Further, since ‘0A-like box’ are present in the promoter region of abrB gene, a known regulator of anthrax toxin gene expression, cross talk among SMFP members and Spo0A^-P–AbrB could regulate the expression of anthrax toxin genes. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Bacillus subtilis SalA is a phosphorylation‐dependent transcription regulator that represses scoC and activates the production of the exoprotease AprE

Bacillus subtilis Mrp family protein SalA has been shown to indirectly promote the production of the exoprotease AprE by inhibiting the expression of scoC, which codes for a repressor of aprE. The exact mechanism by which SalA influences scoC expression has not been clarified previously. We demonstrate that SalA possesses a DNA‐binding domain (residues 1–60), which binds to the promoter region of scoC. The binding of SalA to its target DNA depends on the presence of ATP and is stimulated by phosphorylation of SalA at tyrosine 327. The B. subtilis protein‐tyrosine kinase PtkA interacts specifically with the C‐terminal domain of SalA in vivo and in vitro and is responsible for activating its DNA binding via phosphorylation of tyrosine 327. In vivo, a mutant mimicking phosphorylation of SalA (SalA Y327E) exhibited a strong repression of scoC and consequently overproduction of AprE. By contrast, the non‐phosphorylatable SalA Y327F and the ΔptkA exhibited the opposite effect, stronger expression of scoC and lower production of the exoprotease. Interestingly, both SalA and PtkA contain the same ATP‐binding Walker domain and have thus presumably arisen from the common ancestral protein. Their regulatory interplay seems to be conserved in other bacteria.     

Phosphorylation of the cell division protein GpsB regulates PrkC kinase activity through a negative feedback loop in Bacillus subtilis

Although many membrane Ser/Thr‐kinases with PASTA motifs have been shown to control bacterial cell division and morphogenesis, inactivation of the Ser/Thr‐kinase PrkC does not impact Bacillus subtilis cell division. In this study, we show that PrkC localizes at the division septum. In addition, three proteins involved in cell division/elongation, GpsB, DivIVA and EzrA are required for stimulating PrkC activity in vivo. We show that GpsB interacts with the catalytic subunit of PrkC that, in turn, phosphorylates GpsB. These observations are not made with DivIVA and EzrA. Consistent with the phosphorylated residue previously detected for GpsB in a high‐throughput phosphoproteomic analysis of B. subtilis, we show that threonine 75 is the single PrkC‐mediated phosphorylation site in GpsB. Importantly, the substitution of this threonine by a phospho‐mimetic residue induces a loss of PrkC kinase activity in vivo and a reduced growth under high salt conditions as observed for gpsB and prkC null mutants. Conversely, substitution of threonine 75 by a phospho‐ablative residue does not induce such growth and PrkC kinase activity defects. Altogether, these data show that proteins of the divisome control PrkC activity and thereby phosphorylation of PrkC substrates through a negative feedback loop in B. subtilis.     

Spo0A positively regulates epr expression by negating the repressive effect of co-repressors, SinR and ScoC, in Bacillus subtilis

Bacillus subtilis under nutritional deprivation exhibits several physiological responses such as synthesis of degradative enzymes, motility, competence, sporulation, etc. At the onset of post-exponential phase the global response regulator, Spo0A, directly or indirectly activates the expression of genes involved in the above processes. These genes are repressed during the exponential phase by a group of proteins called transition state regulators, e.g. AbrB, ScoC and SinR. One such post-exponentially expressed gene is epr, which encodes a minor extracellular serine protease and is involved in the swarming motility of B. subtilis. Deletion studies of the upstream region of epr promoter revealed that epr is co-repressed by transition state regulators, SinR and ScoC. Our study shows that Spo0A positively regulates epr expression by nullifying the repressive effect of co-repressors, SinR and ScoC. We demonstrate via in vitro mobility shift assays that Spo0A binds to the upstream region of epr promoter and in turn occludes the binding site of one of the co-repressor, SinR. This explains the mechanism behind the positive regulatory effect of Spo0A on epr expression.