Stabilization of the phosphorylated form of Bacillus subtilis DegU caused by degU9 mutation

Abstract A Bacillus subtilis response regulator, DegU9, carrying an amino acid alteration caused by the degU9 (Hy) mutation was partially purified, and phosphorylation and dephosphorylation of the protein was studied. The extent of phosphorylation was not as high as the level attained with wild-type DegU, but the DegU9-phosphate once formed was more stable than the wild-type DegU-phosphate. An in vivo study with a degU9 mutant showed that degS was necessary for the overproduction of exoproteases. These results suggest that phosphorylation is necessary for the mutant DegU9 to exert its effect and that the higher stability of phosphorylated DegU9 is responsible for the overproulation phenotype.     

The phosphorylation state of the DegU response regulator acts as a molecular switch allowing either degradative enzyme synthesis or expression of genetic competence in Bacillus subtilis.

Two classes of mutations were identified in the degS and degU regulatory genes of Bacillus subtilis, leading either to deficiency of degradative enzyme synthesis (degS or degU mutations) or to a pleiotropic phenotype which includes overproduction of degradative enzymes and the loss of genetic competence (degS(Hy) or degU(Hy) mutations). We have shown previously that the DegS protein kinase and the DegU response regulator form a signal transduction system in B. subtilis. We now demonstrate that the DegS protein kinase also acts as a DegU phosphatase. We present evidence that the DegU response regulator has two active conformations: a phosphorylated form which is necessary for degradative enzyme synthesis and a nonphosphorylated form required for expression of genetic competence. The degU146-encoded response regulator, allowing expression of genetic competence, has been purified and seems to be modified within the putative phosphorylation site (D56----N) since it is no longer phosphorylated by DegS. Both the degU146 mutation as well as the degS220 mutation, which essentially abolishes DegS protein kinase activity, lead to deficiency of degradative enzyme synthesis, indicating the requirement of phosphorylated DegU for the expression of this phenotype. We also purified the degU32(Hy)-encoded protein and showed that this response regulator is phosphorylated by the DegS protein kinase in vitro. In addition, the phosphorylated form of the degU32(Hy)-encoded protein presented a strongly increased stability as compared with the wild type DegU protein, thus leading to hyperproduction of degradative enzymes in vivo.     

Mutations suppressing the loss of DegQ function in Bacillus subtilis (natto) poly-γ-glutamate synthesis

The degQ gene of Bacillus subtilis (natto), encoding a small peptide of 46 amino acids, is essential for the synthesis of extracellular poly-gamma-glutamate (γPGA). To elucidate the role of DegQ in γPGA synthesis, we knocked out the degQ gene in Bacillus subtilis (natto) and screened for suppressor mutations that restored γPGA synthesis in the absence of DegQ. Suppressor mutations were found in degS, the receptor kinase gene of the DegS-DegU two-component system. Recombinant DegS-His(6) mutant proteins were expressed in Escherichia coli cells and subjected to an in vitro phosphorylation assay. Compared with the wild type, mutant DegS-His(6) proteins showed higher levels of autophosphorylation (R208Q, M195I, L248F, and D250N), reduced autodephosphorylation (D250N), reduced phosphatase activity toward DegU, or a reduced ability to stimulate the autodephosphorylation activity of DegU (R208Q, D249G, M195I, L248F, and D250N) and stabilized DegU in the phosphorylated form. These mutant DegS proteins mimic the effect of DegQ on wild-type DegSU in vitro. Interestingly, DegQ stabilizes phosphorylated DegS only in the presence of DegU, indicating a complex interaction of these three proteins.     

Mutational analysis of the Bacillus subtilis DegU regulator and its phosphorylation by the DegS protein kinase.

The DegS-DegU protein kinase-response regulator pair controls the expression of genes encoding degradative enzymes as well as other cellular functions in Bacillus subtilis. Both proteins were purified. The DegS protein was autophosphorylated and shown to transfer its phosphate to the DegU protein. Phosphoryl transfer to the wild-type DegU protein present in crude extracts was shown by adding 32P-labeled DegS to the reaction mixture. Under similar conditions, the modified proteins encoded by the degU24 and degU31 alleles presented a stronger phosphorylation signal compared with that of the wild-type DegU protein. This may suggest an increased phosphorylation of these modified proteins, responsible for the hyperproduction of degradative enzymes observed in the degU24 and degU31 mutants. However, the degU32 allele, which also leads to hyperproduction of degradative enzymes, encodes a modified DegU response regulator which seems not to be phosphorylatable. The expression of the hyperproduction phenotype of the degU32 mutant is still dependent on the presence of a functional DegS protein. DegS may therefore induce a conformational change of the degU32-encoded response regulator enabling this protein to stimulate degradative enzyme synthesis. Two alleles, degU122 and degU146, both leading to deficiency of degradative enzyme synthesis, seem to encode phosphorylatable and nonphosphorylatable DegU proteins, respectively.     

Multiple copies of the proB gene enhance degS-dependent extracellular protease production in Bacillus subtilis.

Bacillus subtilis secretes extracellular proteases whose production is positively regulated by a two-component regulatory system, DegS-DegU, and other regulatory factors including DegR. To identify an additional regulatory gene(s) for exoprotease production, we performed a shotgun cloning in the cell carrying multiple copies of degR and found a transformant producing large amounts of the exoproteases. The plasmid in this transformant, pLC1, showed a synergistic effect with multiple copies of degR on the production of the extracellular proteases, and it required degS for its enhancing effect. The DNA region responsible for the enhancement contained the proB gene, as shown by restriction analyses and sequence determination. The proB gene encoding gamma-glutamyl kinase was followed by the proA gene encoding glutamyl-gamma-semialdehyde dehydrogenase at an interval of 39 nucleotides, suggesting that the genes constitute an operon. pLC1 contained the complete proB gene and a part of proA lacking the proA C-terminal region. It was also found that proB on the chromosome showed a synergistic effect with multiple copies of degR. We consider on the basis of these results that the metabolic intermediate, gamma-glutamyl phosphate, would transmit a signal to DegS, resulting in a higher level of phosphorylated DegU. Possible involvement of DegR in this process is discussed.     

Signal transduction pathway controlling synthesis of a class of degradative enzymes in Bacillus subtilis: expression of the regulatory genes and analysis of mutations in degS and degU.

The rates of synthesis of a class of both secreted and intracellular degradative enzymes in Bacillus subtilis are controlled by a signal transduction pathway defined by at least four regulatory genes: degS, degU, degQ (formerly sacQ), and degR (formerly prtR). The DegS-DegU proteins show amino acid similarities with two-component procaryotic modulator-effector pairs such as NtrB-NtrC, CheA-CheY, and EnvZ-OmpR. By analogy with these systems, it is possible that DegS is a protein kinase which could catalyze the transfer of a phosphoryl moiety to DegU, which acts as a positive regulator. DegR and DegQ correspond to polypeptides of 60 and 46 amino acids, respectively, which also activate the synthesis of degradative enzymes. We show that the degS and degU genes are organized in an operon. The putative sigma A promoter of the operon was mapped upstream from degS. Mutations in degS and degU were characterized at the molecular level, and their effects on transformability and cell motility were studied. The expression of degQ was shown to be subject both to catabolite repression and DegS-DegU-mediated control, allowing an increase in the rate of synthesis of degQ under conditions of nitrogen starvation. These results are consistent with the hypothesis that this control system responds to an environmental signal such as limitations of nitrogen, carbon, or phosphate sources.     

Autoregulation of the Bacillus subtilis response regulator gene degU is coupled with the proteolysis of DegU‐P by ClpCP

The response regulator DegU and its cognate kinase DegS constitute a two‐component system in Bacillus subtilis that regulates many cellular processes, including exoprotease production and competence development. Using DNA footprint assay, gel shift assay and mutational analyses of P3degU‐lacZ fusions, we showed that phosphorylated DegU (DegU‐P) binds to two direct repeats (DR1 and DR2) of the consensus DegU‐binding sequence in the P3degU promoter. The alteration of chromosomal DR2 severely decreased degU expression, demonstrating its importance in positive autoregulation of degU. Observation of DegU protein levels suggested that DegU is degraded. Western blot analysis of DegU in disruption mutants of genes encoding various ATP‐dependent proteases strongly suggested that ClpCP degrades DegU. Moreover, when de novo protein synthesis was blocked, DegU was rapidly degraded in the wild‐type but not in the clpC and clpP strains, and DegU with a mutated phosphorylation site was much stable. These results suggested preferential degradation of DegU‐P by ClpCP, but not of unphosphorylated DegU. We confirmed that DegU‐P was degraded preferentially using an in vitro ClpCP degradation system. Furthermore, a mutational analysis showed that the N‐terminal region of DegU is important for proteolysis.     

Bacillus subtilis two-component system sensory kinase DegS is regulated by serine phosphorylation in its input domain

Bacillus subtilis two-component system DegS/U is well known for the complexity of its regulation. The cytosolic sensory kinase DegS does not receive a single predominant input signal like most two-component kinases, instead it integrates a wide array of metabolic inputs that modulate its activity. The phosphorylation state of the response regulator DegU also does not confer a straightforward "on/off" response; it is fine-tuned and at different levels triggers different sub-regulons. Here we describe serine phosphorylation of the DegS sensing domain, which stimulates its kinase activity. We demonstrate that DegS phosphorylation can be carried out by at least two B. subtilis Hanks-type kinases in vitro, and this stimulates the phosphate transfer towards DegU. The consequences of this process were studied in vivo, using phosphomimetic (Ser76Asp) and non-phosphorylatable (Ser76Ala) mutants of DegS. In a number of physiological assays focused on different processes regulated by DegU, DegS S76D phosphomimetic mutant behaved like a strain with intermediate levels of DegU phosphorylation, whereas DegS S76A behaved like a strain with lower levels of DegU phophorylation. These findings suggest a link between DegS phosphorylation at serine 76 and the level of DegU phosphorylation, establishing this post-translational modification as an additional trigger for this two-component system.     

Biosynthesis of the subtilisin-like serine proteinase of Bacillus intermedius under salt stress conditions

The biosynthesis of the subtilisin-like serine proteinase of Bacillus intermedius 3–19 by the recombinant strain Bacillus subtilis AJ73(pCS9) was found to be enhanced under salt stress conditions (growth in a medium containing 1 MNaCl and 0.25 M sodium citrate). In a recombinant strain of B. subtilis deficient in the regulatory proteins DegS and DegU, which control the synthesis of degradative enzymes, the expression of the proteinase gene was inhibited. In contrast, in the strain B. subtilis degU32(Hy), which provides for the overproduction of proteins positively regulated by the DegS-DegU system, the biosynthesis of the subtilisin-like proteinase of B. intermedius 3–19 increased by 6–10 fold. These data suggest that the DegS-DegU system is involved in the positive regulation of the expression of the subtilisin-like B. intermedius proteinase gene in recombinant B. subtilis strains.     

Biosynthesis of the subtilisin-like serine proteinase of Bacillus intermedius under salt stress conditions

The biosynthesis of the subtilisin-like serine proteinase of Bacillus intermedius 3-19 by the recombinant strain Bacillus subtilis AJ73(pCS9) was found to be enhanced under salt stress conditions (growth in a medium containing 1 M NaCl and 0.25 M sodium citrate). In a recombinant strain of B. subtilis deficient in the regulatory proteins DegS and DegU, which control the synthesis of degradative enzymes, the expression of the proteinase gene was inhibited. In contrast, in the strain B. subtilis degU32 (Hy), which provides for the over-synthesis of proteins positively regulated by the DegS-DegU system, the biosynthesis of the subtilisin-like proteinase of B. intermedius 3-19 increased by 6-10 times. These data suggest that the DegS-DegU system is involved in the positive regulation of the expression of the subtilisin-like B. intermedius proteinase gene in recombinant B. subtilis strains.     

The Pta–AckA pathway controlling acetyl phosphate levels and the phosphorylation state of the DegU orphan response regulator both play a role in regulating Listeria monocytogenes motility and chemotaxis

DegU is considered to be an orphan response regulator in Listeria monocytogenes since the gene encoding the cognate histidine kinase DegS is absent from the genome. We have previously shown that DegU is involved in motility, chemotaxis and biofilm formation and contributes to L. monocytogenes virulence. Here, we have investigated the role of DegU phosphorylation in Listeria and shown that DegS of Bacillus subtilis can phosphorylate DegU of L. monocytogenes in vitro. We introduced the B. subtilis degS gene into L. monocytogenes, and showed that this leads to highly increased expression of motility and chemotaxis genes, in a DegU‐dependent fashion. We inactivated the predicted phosphorylation site of DegU by replacing aspartate residue 55 with asparagine and showed that this modified protein (DegU_D55N) is no longer phosphorylated by DegS in vitro. We show that although the unphosphorylated form of DegU retains much of its activity in vivo, expression of motility and chemotaxis genes is lowered in the degU_D55N mutant. We also show that the small‐molecular‐weight metabolite acetyl phosphate is an efficient phosphodonor for DegU in vitro and our evidence suggests this is also true in vivo. Indeed, a L. monocytogenesΔptaΔackA mutant that can no longer synthesize acetyl phosphate was found to be strongly affected in chemotaxis and motility gene expression and biofilm formation. Our findings suggest that phosphorylation by acetyl phosphate could play an important role in modulating DegU activity in vivo, linking its phosphorylation state to the metabolic status of L. monocytogenes.     

Inducer exclusion in Escherichia coli by non-PTS substrates: the role of the PEP to pyruvate ratio in determining the phosphorylation state of enzyme IIAGlc

The main mechanism causing catabolite repression in Escherichia coli is the dephosphorylation of enzyme IIA^Glc, one of the enzymes of the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS). The PTS is involved in the uptake of a large number of carbohydrates that are phosphorylated during transport, phosphoenolpyruvate (PEP) being the phosphoryl donor. Dephosphorylation of enzyme IIA^Glc causes inhibition of uptake of a number of non-PTS carbon sources, a process called inducer exclusion. In this paper, we show that dephosphorylation of enzyme IIA^Glc is not only caused by the transport of PTS carbohydrates, as has always been thought, and that an additional mechanism causing dephosphorylation exists. Direct monitoring of the phosphorylation state of enzyme IIA^Glc also showed that many carbohydrates that are not transported by the PTS caused dephosphorylation during growth. In the case of glucose 6-phosphate, it was shown that transport and the first metabolic step are not involved in the dephosphorylation of enzyme IIA^Glc, but that later steps in the glycolysis are essential. Evidence is provided that the [PEP]–[pyruvate] ratio, the driving force for the phosphorylation of the PTS proteins, determines the phosphorylation state of enzyme IIA^Glc. The implications of these new findings for our view on catabolite repression and inducer exclusion are discussed.