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.     

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.     

The use of elements of the E. coli Ntr-system for the design of an optimized recombinant expression system for high cell density cultivations.

The inducible glnA promoter 2 of the E. coli glutamine synthetase gene is suitable as an expression unit for the production of recombinant proteins at low and high cell densities. It is active when the concentration of ammonium as the sole nitrogen source in the culture medium is below 1 mM. This nitrogen regulatory system was optimized by introduction of expression cassettes consisting of additional elements of the ntr-system. These artificial constructions result in enhanced recombinant gene expression in the production phase. Furthermore, the basic recombinant protein level during the growth phase is reduced due to a tighter promoter control. A three- to four-fold higher accumulation of chloramphenicol-acetyltransferase (as reporter protein) and of anti-EGF-receptor miniantibodies was achieved by increasing the amount of the final regulator molecule NtrC approximately P via plasmidal co-expression of the ntrC gene. The introduction of a modified glnA promoter 1 inverse to glnAp2 lowered the basic activity of glnAp2 to about one half. It is assumed that under nitrogen excess conditions sigma 70-RNA polymerase binds at glnAp1 and thereby prevents most of the binding of sigma 54-RNA polymerase at glnAp2. The optimized expression systems were successfully applied in low and high cell density cultivations. In the fed-batch phase of high cell density cultivations recombinant protein formation was induced through external nitrogen limitation under FIA-controlled concentration of glucose as carbon source.     

The expression of the serine proteinase gene of Bacillus intermedius in Bacillus subtilis

The gene encoding for Bacillus intermedius serine proteinase was cloned and the complete nucleotide sequence was determined. Gene expression was explored in the protease-deficient strain Bacillus subtilis AJ73 during different stages of growth. Catabolite repression involved in control of proteinase expression during transition state and onset of sporulation was not efficient at the late stationary phase. Salt stress leads to induction of serine proteinase production during B. subtilis AJ73(pCS9) post-exponential growth. Expression of proteinase in B. subtilis deg-mutants may be controlled by DegU regulator. B. subtilis spo0-mutants failed to accomplish B. intermedius proteinase production. These data suggest complex network regulation of B. intermedius serine proteinase expression, including the action of spo0, degU, catabolite repression and demonstrate changes in control of enzyme biosynthesis at different stages of growth.     

Binding of response regulator DegU to the aprE promoter is inhibited by RapG,which is counteracted by extracellular PhrG in Bacillus subtilis

We screened the putative rap-phr (response regulator aspartyl-phosphate phosphatase-phosphatase regulator) systems identified in the Bacillus subtilis genome for a rap gene that affects aprE (alkaline protease gene) expression by using a multicopy plasmid. We found that rapG was involved in the regulation of aprE, which belongs to the regulon of DegU, the response regulator of the DegS-DegU two-component system. Disruption of rapG and phrG resulted in enhancement and reduction of aprE-lacZ expression, respectively, suggesting that PhrG inhibits RapG activity. Addition of 1-30 nM of a synthetic pentapeptide (PhrG; NH2-EKMIG-COOH) to the phrG disruptant completely rescued aprE-lacZ expression, indicating that the PhrG peptide is indeed involved in aprE-lacZ expression. Surprisingly, either introduction of multicopy phrG or addition of the PhrG peptide at high concentrations (100-300 nM) to the phrG cells decreased aprE-lacZ expression. These results are reminiscent of the previous observation that at higher concentrations the PhrC peptide inhibits srfA-lacZ expression directed by ComA, the regulator of the ComP-ComA two-component system. Because the Rap proteins belong to a family of aspartyl protein phosphatases, we tried to investigate the possible influence of RapG on dephosphorylation of DegU-P (phosphorylated DegU) in vitro. RapG, however, did not affect dephosphorylation of DegU-P under the adopted experimental conditions. Therefore, we hypothesized that RapG might inhibit the binding activity of DegU to the target promoters. We analysed the interaction of DegU and RapG using the aprE promoter and another target, a comK promoter. Gel shift analysis revealed that RapG served as the inhibitor of DegU binding to the promoter regions of aprE and comK and that this inhibition was counteracted by the PhrG peptide.     

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.     

Response regulator DegU of Listeria monocytogenes regulates the expression of flagella-specific genes

An isogenic mutant of Listeria monocytogenes EGD with a deletion of the response regulator gene degU showed a lack of motility due to the absence of flagella. In the present study, we used two-dimensional gel electrophoresis, mass-spectrometry and microarray analyses to identify the listerial genes that depend on DegU for expression. We found that the two L. monocytogenes operons encoding flagella-specific genes and the monocistronically transcribed flaA gene are positively regulated by DegU at 24 degrees C, but are not expressed at 37 degrees C.     

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.     

Molecular analysis and regulation of the glnA gene of the gram-positive anaerobe Clostridium acetobutylicum.

The nucleotide sequence of a 2.0-kilobase DNA segment containing the Clostridium acetobutylicum glnA gene was determined. The upstream region of the glnA gene contained two putative extended promoter consensus sequences (p1 and p2), characteristic of gram-positive bacteria. A third putative extended gram-positive promoter consensus sequence (p3), oriented towards the glnA gene, was detected downstream of the structural gene. The sequences containing the proposed promoter regions p1 and p2 or p3 were shown to have promoter activity by subcloning into promoter probe vectors. The complete amino acid sequence (444 residues) of the C. acetobutylicum glutamine synthetase (GS) was deduced, and comparisons were made with the reported amino acid sequences of GS from other organisms. To determine whether the putative promoter p3 and a downstream region with an extensive stretch of inverted repeat sequences were involved in regulation of C. acetobutylicum glnA gene expression by nitrogen in Escherichia coli, deletion plasmids were constructed lacking p3 and various downstream sequences. Deletion of the putative promoter p3 and downstream inverted repeat sequences affected the regulation of GS and reduced the levels of GS approximately fivefold under nitrogen-limiting conditions but did not affect the repression of GS levels in cells grown under nitrogen-excess conditions.