Phosphorylation and RsbX-dependent dephosphorylation of RsbR in the RsbR-RsbS complex of Bacillus subtilis

In the pathway that controls sigmaB activity, the RsbR-RsbS complex plays an important role by trapping RsbT, a positive regulator of sigmaB of Bacillus subtilis. We have proposed that at the onset of stress, RsbR becomes phosphorylated, resulting in an enhanced activity of RsbT towards RsbS. RsbT is then free to interact with and activate RsbU, which in turn ultimately activates sigmaB. In this study with purified proteins, we used mutant RsbR proteins to analyze the role of its phosphorylatable threonine residues. The results show that the phosphorylation of either of the two RsbT-phosphorylatable threonine residues (T171 and T205) in RsbR enhanced the kinase activity of RsbT towards RsbS. However, it appeared that RsbT preferentially phosphorylates T171. We also present in vitro evidence that identifies RsbX as a potential phosphatase for RsbR T205.     

Serine kinase activity of a Bacillus subtilis switch protein is required to transduce environmental stress signals but not to activate its target PP2C phosphatase

The RsbT serine kinase has two known functions in the signal transduction pathway that activates the general stress factor σ^B of Bacillus subtilis . First, RsbT can phosphorylate and inactivate its specific antagonist protein, RsbS. Second, upon phosphorylation of RsbS, RsbT is released to stimulate RsbU, a PP2C phosphatase, thereby initiating a signalling cascade that ultimately activates σ^B. Here we describe a mutation that separates these two functions of RsbT. Although the mutant RsbT protein had essentially no kinase activity, it still retained the capacity to stimulate the RsbU phosphatase in vitro and to activate σ^B when overexpressed in vivo . These results support the hypothesis that phosphatase activation is accomplished via a long-lived interaction between RsbT and RsbU. In contrast, RsbT kinase activity was found to be integral for the transmission of external stimuli to σ^B. Thus, one route by which environmental stress signals could enter the σ^B network is by modulation of the RsbT kinase activity, thereby controlling the magnitude of the partner switch between the RsbS–RsbT complex and the RsbT–RsbU complex.     

Mutational analysis of RsbT, an activator of the Bacillus subtilis stress response transcription factor, sigmaB

SigmaB, the stress-activated sigma factor of Bacillus subtilis, requires the RsbT protein as an essential positive regulator of its physical stress pathway. Stress triggers RsbT to both inactivate the principal negative regulator of the physical stress pathway (RsbS) by phosphorylation and activate a phosphatase (RsbU) required for sigmaB induction. Neither the regions of RsbT that are involved in responding to stress signaling nor those required for downstream events have been established. We used alanine scanning mutagenesis to examine the contributions of RsbT's charged amino acids to the protein's stability and activities. Eleven of eighteen rsbT mutations blocked sigmaB induction by stress. The carboxy terminus of RsbT proved to be particularly important for accumulation in Bacillus subtilis. Four of the five most carboxy-terminal mutations yielded rsbT alleles whose products were undetectable in B. subtilis extracts. Charged amino acids in the central region of RsbT were less critical, with four of the five substitutions in this region having no measurable effect on RsbT accumulation or activity. Only when the substitutions extended into a region of kinase homology was sigmaB induction affected. Six other RsbT variants, although present at levels adequate for activity, failed to activate sigmaB and displayed significant changes in their ability to interact with RsbT's normal binding partners in a yeast dihybrid assay. These changes either dramatically altered the proteins' tertiary structure without affecting their stability or defined regions of RsbT that are involved in multiple interactions.     

A phylogenomic study of the general stress response sigma factor sigmaB of Bacillus subtilis and its regulatory proteins

Regulation of expression of the general stress regulon of Bacillus subtilis is mediated by the activation of the alternative sigma factor sigmaB. Activation of sigmaB is accomplished by a complex regulatory network involving protein-protein interactions and reversible protein phosphorylation. PSI-BLAST searches were performed and phylogenetic trees for sigmaB and its regulatory proteins were constructed. Occurrence of sigmaB is restricted to a small group of gram-positive bacteria (Bacillus, Staphylococcus, Listeria). Related sigma factors also involved in stress responses are present in Mycobacterium tuberculosis, Streptomyces species and even in cyanobacteria (Synechocystis species). Putative regulatory proteins found in several other bacterial species can be broadly catagorized into three categories: Anti sigma factors, anti-anti sigma factors and phosphatases. Anti sigma factors are able to bind to sigma factors and are also kinases of anti sigma factor antagonists. Only in their nonphosphorylated state, these antagonists are able to bind to the anti sigma factor. Phosphorylated antagonists can be dephosphorylated by PP2C phosphatases. These phosphatases are of pivotal importance for activation of the sigma factor. Different phosphatases identified in this search contain a wide variety of domains found in signal transducing proteins (PAS/PAC, GAF, REC, HATase_c, HAMP). The HATPase_c domain found in several phosphatases most probably constitutes a serine/threonine kinase domain of anti sigma factors. Such proteins are most probably bifunctional anti-anti sigma factor kinases and phosphatases. The regulatory network of anti-anti sigma factors anti sigma factors and phosphatases is probably ancient and most likely evolved from a structurally similar network found in the Deinococcus radiodurans genome. In completely sequenced genomes of several bacterial species, some elements of the network are missing. The N-terminus of RsbU, a phosphatase activated in response to environmental stress exhibits similarities to a region in the beta chain of phenylalanyl-tRNA synthetases.     

A supramolecular complex in the environmental stress signalling pathway of Bacillus subtilis

SigmaB, an alternative sigma-factor of Bacillus subtilis, mediates the response of the cell to a variety of physical insults. Within the environmental stress signalling pathway RsbU, a protein phosphatase, is stimulated by its interaction with the protein kinase RsbT. In the absence of stress RsbT is expected to be trapped by an alternative binding partner, RsbS. Here, we have demonstrated that RsbS alone cannot act as an alternative partner for RsbT, but instead requires the presence of RsbR to create a high molecular mass RsbR:RsbS complex (approximately 1 MDa) able to capture RsbT. In this complex the phosphorylation state of RsbS, and not that of RsbR, controlled the binding to RsbT, whose kinase activity towards RsbS could be counterbalanced by the activity of RsbX, the phosphatase for RsbS-P. The RsbR:RsbS complex recruited RsbT from a mixture of RsbT and RsbU. The phosphorylated form of RsbR in the complex enhanced the kinase activity of RsbT towards RsbS. This supramolecular complex thus has the functional properties of an alternative partner for RsbT. Electron micrographs of this complex are presented, and the purification of the RsbR:RsbS complex from cellular extracts provides evidence for the existence of such a complex in vivo.     

The yeast two-hybrid system detects interactions between Bacillus subtilis sigmaB regulators.

SigmaB, the general stress response sigma factor of Bacillus subtilis, is regulated by the products of seven genes (rsbR, S, T, U, V, W, and X) with which it is cotranscribed. Biochemical techniques previously revealed physical associations among RsbW, RsbV, and sigmaB but failed to detect interactions of RsbR, S, T, U, or X with each other or RsbV, RsbW, or sigmaB. Using the yeast two-hybrid system, we have now obtained evidence for such interactions. The yeast reporter system was activated when RsbS was paired with either RsbR or RsbT, RsbR was paired with RsbT, and RsbV was paired with either RsbU or RsbW. In addition, RsbW2 and RsbR2 dimer formation was detected. RsbX failed to show interactions with itself or any of the other sigB operon products.     

Protein Ser/Thr phosphatases PPEF interact with calmodulin

Regulation of protein dephosphorylation by cytoplasmic Ca(2+) levels and calmodulin (CaM) is well established and considered to be mediated solely by calcineurin. Yet, recent identification of protein phosphatases with EF-hand domains (PPEF/rdgC) point to the existence of another group of Ca(2+)-dependent protein phosphatases. We have recently hypothesised that PPEF/rdgC phosphatases might possess CaM-binding sites of the IQ-type in their N-terminal domains. We now employed yeast two-hybrid system and surface plasmon resonance (SPR) to test this hypothesis. We found that entire human PPEF2 interacts with CaM in the in vivo tests and that its N-terminal domain binds to CaM in a Ca(2+)-dependent manner with nanomolar affinity in vitro. The fragments corresponding to the second exons of PPEF1 and PPEF2, containing the IQ motifs, are sufficient for specific Ca(2+)-dependent interaction with CaM both in vivo and in vitro. These findings demonstrate the existence of mammalian CaM-binding protein Ser/Thr phosphatases distinct from calcineurin and suggest that the activity of PPEF phosphatases may be controlled by Ca(2+) in a dual way: via C-terminal Ca(2+)-binding domain and via interaction of the N-terminal domain with CaM.     

The tetratricopeptide repeat domain and a C-terminal region control the activity of Ser/Thr protein phosphatase 5.

Protein Ser/Thr phosphatase 5 is a 58-kDa protein containing a catalytic domain structurally related to the catalytic subunits of protein phosphatases 1, 2A, and 2B and an extended N-terminal domain with three tetratricopeptide repeats. The activity of this enzyme is stimulated 4-14-fold in vitro by polyunsaturated fatty acids and anionic phospholipids. The structural basis for lipid activation of protein phosphatase 5 was examined by limited proteolysis and site-directed mutagenesis. Trypsinolysis removed the tetratricopeptide repeat domain and increased activity to approximately half that of lipid-stimulated, full-length enzyme. Subtilisin removed the tetratricopeptide repeat domain and 10 residues from the C terminus, creating a catalytic fragment with activity that was equal to or greater than that of lipid-stimulated, full-length enzyme. Catalytic fragments generated by proteolysis were no longer stimulated by lipid, and degradation of the tetratricopeptide repeat domain was decreased by association with lipid. A truncated mutant missing 13 C-terminal residues was also insensitive to lipid and was as active as full-length, lipid-stimulated enzyme. These results suggest that the C-terminal and N-terminal domain act in a coordinated manner to suppress the activity of protein phosphatase 5 and mediate its activation by lipid. These regions may be targets for the regulation of protein phosphatase 5 activity in vivo.     

Protein Ser/Thr phosphatases with kelch-like repeat domains

This report describes the presence in plants of protein Ser/Thr phosphatases of the PPP family, homologous to PfPPalpha phosphatase from Plasmodium falciparum. Like PfPPalpha, they possess large N-terminal domains and catalytic domains that are more closely related to the protein phosphatase 1 group. The N-terminal domains of PfPPalpha and its plant homologues contain tandem kelch-like repeats, not previously identified in any protein phosphatases, suggesting that the N-terminal domains may form beta-propeller structures mediating protein-protein interactions. We therefore suggest that this novel phosphatase group be designated as PPKLs for protein phosphatases with kelch-like repeat domains. Four PPKL isoforms are encoded in the Arabidopsis thaliana genome, of which at least three are expressed. PPKLs appear to be ubiquitous in Viridiplantae. The existence of a protein phosphatase group shared by Viridiplantae and Apicomplexa, but not other eukaryotes, is in line with the theory of the origin of Apicomplexa by endosymbiosis of nonphotosynthetic eukaryotes with red algae.     

The icfG Gene Cluster of Synechocystis sp. Strain PCC 6803 Encodes an Rsb/Spo-Like Protein Kinase, Protein Phosphatase, and Two Phosphoproteins

A set of open reading frames (ORFs) potentially encoding signal transduction proteins are clustered around icfG, a gene implicated in the regulation of carbon metabolism, in the genome of Synechocystis sp. strain PCC 6803. slr1860 is the ORF for icfG, whose predicted product resembles the protein phosphatases SpoIIE, RsbU, and RsbX from Bacillus subtilis. Bracketing slr1860/icfG are (i) ORF slr1861, whose predicted product resembles the SpoIIAB, RsbT, and RsbW protein kinases from B. subtilis, and (ii) ORFs slr1856 and slr1859, whose predicted products resemble the respective phosphoprotein substrates for the B. subtilis protein kinases: SpoIIAA, RsbS, and RsbV. In order to determine whether the protein products encoded by these ORFs possessed the functional capabilities suggested by sequence comparisons, each was expressed in Escherichia coli as a histidine-tagged fusion protein and analyzed for its ability to participate in protein phosphorylation-dephosphorylation processes in vitro. It was observed that ORF slr1861 encoded an ATP-dependent protein kinase capable of phosphorylating Slr1856 and, albeit with noticeably lower efficiency, Slr1859. Site-directed mutagenesis suggests that Slr1861 phosphorylated these proteins on Ser-54 and Ser-57, respectively. Slr1860 exhibited divalent metal ion-dependent protein-serine phosphatase activity. It catalyzed the dephosphorylation of Slr1856, but not Slr1859, in vitro.     

Solution structure of the MAPK phosphatase PAC-1 catalytic domain. Insights into substrate-induced enzymatic activation of MKP

Inactivation of mitogen-activated protein kinases (MAPKs) by MAPK phosphatases (MKPs) is accomplished via substrate-induced activation of the latter enzymes; however, the structural basis for the underlying mechanism remains elusive. Here, we report the three-dimensional solution structure of the C-terminal phosphatase domain of the prototypical MKP PAC-1, determined when bound to phosphate. Structural and biochemical analyses reveal unique active site geometry of the enzyme important for binding to phosphorylated threonine and tyrosine of MAPK ERK2. Our study further demonstrates that the dynamic interaction between the N-terminal kinase binding domain and the C-terminal phosphatase domain of an MKP is directly coupled to MAPK-induced conformational change of the phosphatase active site, which is essential for eliciting its full enzymatic activity.     

Structure and regulation of MAPK phosphatases

MAP kinases (MAPKs), which control mitogenic signal transduction in all eukaryotic organisms, are inactivated by dual specificity MAPK phosphatases (DS-MKPs). Recent studies reveal that substrate specificity and enzymatic activity of MKPs are tightly controlled not only by the conserved C-terminal phosphatase domain but also by an N-terminal (NT) kinase-binding domain. Notably, MKPs that consist of a kinase-binding domain and a phosphatase domain exhibit little phosphatase activity in the absence of their physiological substrates. MKP binding to a specific MAPK results in enzymatic activation of the phosphatase in a substrate-induced activation mechanism. This direct coupling of inactivation of an MAPK to activation of an MKP provides a tightly controlled regulation that enables these two key enzymes to keep each other in check, thus guaranteeing the fidelity of signal transduction. This review discusses the recent understanding of structure and regulation of the large family of dual specificity MKPs, which can be divided into four subgroups according to their functional domains and mechanism of substrate recognition and enzymatic regulation. Moreover, detailed comparison of the structural basis between this unique substrate-induced activation mechanism and the common auto-inhibition mechanism is provided.