Project description:In bacterial two-component regulatory systems (TCSs), dephosphorylation of phosphorylated response regulator is essential for resetting the activated systems to the pre-activation state. However, in the SaeRS TCS, a major virulence TCS of Staphylococcus aureus, the mechanism for dephosphorylation of the response regulator SaeR has not been identified. Here we report that two auxiliary proteins from the sae operon, SaeP and SaeQ, form a ternary complex with the sensor kinase SaeS and activate the sensor kinase’s phosphatase activity. Efficient activation of the phosphatase activity of SaeS required the presence of both SaeP and SaeQ. When SaeP and SaeQ were expressed, the expression of coagulase, a sae target with low affinity to phosphorylated SaeR, was greatly reduced, while the expression of alpha-hemolysin, a sae target with high affinity to phosphorylated SaeR, was not, demonstrating a differential effect of SaePQ on sae target gene expression. When expression of SaePQ was abolished, most sae target genes were induced at an elevated level. Since the expression of SaeP and SaeQ is induced by SaeRS TCS, these results suggest that the SaeRS TCS returns to pre-activation state by a negative feedback mechanism. To examine the global effect of SaePQ on sae target gene expression, we treated the wild type strain of USA300-P23 and its P1 promoter mutant with HNP-1 and analyzed the transcription of sae target genes by microarray assays. WT and P1 cells were compared against a each other at the same time point and against a T=0 reference.

Project description:In bacterial two-component regulatory systems (TCSs), dephosphorylation of phosphorylated response regulator is essential for resetting the activated systems to the pre-activation state. However, in the SaeRS TCS, a major virulence TCS of Staphylococcus aureus, the mechanism for dephosphorylation of the response regulator SaeR has not been identified. Here we report that two auxiliary proteins from the sae operon, SaeP and SaeQ, form a ternary complex with the sensor kinase SaeS and activate the sensor kinase’s phosphatase activity. Efficient activation of the phosphatase activity of SaeS required the presence of both SaeP and SaeQ. When SaeP and SaeQ were expressed, the expression of coagulase, a sae target with low affinity to phosphorylated SaeR, was greatly reduced, while the expression of alpha-hemolysin, a sae target with high affinity to phosphorylated SaeR, was not, demonstrating a differential effect of SaePQ on sae target gene expression. When expression of SaePQ was abolished, most sae target genes were induced at an elevated level. Since the expression of SaeP and SaeQ is induced by SaeRS TCS, these results suggest that the SaeRS TCS returns to pre-activation state by a negative feedback mechanism.

Project description:In bacterial two-component regulatory systems (TCSs), dephosphorylation of phosphorylated response regulators is essential for resetting the activated systems to the pre-activation state. However, in the SaeRS TCS, a major virulence TCS of Staphylococcus aureus, the mechanism for dephosphorylation of the response regulator SaeR has not been identified. Here we report that two auxiliary proteins from the sae operon, SaeP and SaeQ, form a protein complex with the sensor kinase SaeS and activate the sensor kinase's phosphatase activity. Efficient activation of the phosphatase activity required the presence of both SaeP and SaeQ. When SaeP and SaeQ were ectopically expressed, the expression of coagulase, a sae target with low affinity for phosphorylated SaeR, was greatly reduced, while the expression of alpha-haemolysin, a sae target with high affinity for phosphorylated SaeR, was not, demonstrating a differential effect of SaePQ on sae target gene expression. When expression of SaePQ was abolished, most sae target genes were induced at an elevated level. Since the expression of SaeP and SaeQ is induced by the SaeRS TCS, these results suggest that the SaeRS TCS returns to the pre-activation state by a negative feedback mechanism.

Project description:Two-component systems (TCS) are widespread signaling systems present in all domains of life. TCS typically consist of a signal receptor/transducer and a response regulator. The receptors (histidine kinases, chemoreceptors and photoreceptors) are often embedded in the membrane and have a similar modular structure. Chemoreceptors were shown to function in highly ordered arrays, with trimers of dimers being the smallest functional unit. However, much less is known about photoreceptors. Here, we use small-angle scattering (SAS) to show that detergent-solubilized sensory rhodopsin II in complex with its cognate transducer forms dimers at low salt concentration, which associate into trimers of dimers at higher buffer molarities. We then fit an atomistic model of the whole complex into the SAS data. The obtained results suggest that the trimer of dimers is "tripod"-shaped and that the contacts between the dimers occur only through their cytoplasmic regions, whereas the transmembrane regions remain unconnected.

Project description:Pseudomonas aeruginosa is an opportunistic pathogen that is capable of causing both acute and chronic infections. P. aeruginosa virulence is subject to sophisticated regulatory control by two-component systems that enable it to sense and respond to environmental stimuli. We recently reported that the two-component sensor KinB regulates virulence in acute P. aeruginosa infection. Furthermore, it regulates acute-virulence-associated phenotypes such as pyocyanin production, elastase production, and motility in a manner independent of its kinase activity. Here we show that KinB regulates virulence through the global sigma factor AlgU, which plays a key role in repressing P. aeruginosa acute-virulence factors, and through its cognate response regulator AlgB. However, we show that rather than phosphorylating AlgB, KinB's primary role in the regulation of virulence is to act as a phosphatase to dephosphorylate AlgB and alleviate phosphorylated AlgB's repression of acute virulence.

Project description:Bifunctional sensor transmitter modules of two-component systems exert both positive and negative control on the receiver domain of the cognate response regulator. In negative control, the transmitter module accelerates the rate of phospho-receiver dephosphorylation. This transmitter phosphatase reaction serves the important physiological functions of resetting response regulator phosphorylation level and suppressing cross-talk. Although the biochemical reactions underlying positive control are reasonably well understood, the mechanism for transmitter phosphatase activity has been unknown. A recent hypothesis is that the transmitter phosphatase reaction is catalysed by a conserved Gln, Asn or Thr residue, via a hydrogen bond between the amide or hydroxyl group and the nucleophilic water molecule in acyl-phosphate hydrolysis. This hypothetical mechanism closely resembles the established mechanisms of auxiliary phosphatases such as CheZ and CheX, and may be widely conserved in two-component signal transduction. In addition to the proposed catalytic residues, transmitter phosphatase activity also requires the correct transmitter conformation and appropriate interactions with the receiver. Evidence suggests that the phosphatase-competent and autokinase-competent states are mutually exclusive, and the corresponding negative and positive activities are likely to be reciprocally regulated through dynamic control of transmitter conformations.

Project description:Negative control in two-component signal transduction results from sensor transmitter phosphatase activity for phospho-receiver dephosphorylation. A hypothetical mechanism for this reaction involves a catalytic residue in the H-box active-site region. However, a complete understanding of transmitter phosphatase regulation is hampered by the abundance of kinase-competent, phosphatase-defective missense substitutions (K(+) P(-) phenotype) outside of the active-site region. For the Escherichia coli?NarX sensor, a model for the HisKA_3 sequence family, DHp domain K(+) P(-) mutants defined two classes. Interaction mutants mapped to the active site-distal base of the DHp helix 1, whereas conformation mutants were affected in the X-box region of helix 2. Thus, different types of perturbations can influence transmitter phosphatase activity indirectly. By comparison, K(+) P(-) substitutions in the HisKA sensors EnvZ and NtrB additionally map to a third region, at the active site-proximal top of the DHp helix 1, independently identified as important for DHp-CA domain interaction in this sensor class. Moreover, the NarX transmitter phosphatase activity was independent of nucleotides, in contrast to the activity for many HisKA family sensors. Therefore, distinctions involving both the DHp and the CA domains suggest functional diversity in the regulation of HisKA and HisKA_3 transmitter phosphatase activities.

Project description:Two-component systems regulate crucial cellular processes in microorganisms, and each comprises a homodimeric histidine kinase receptor and a cytoplasmic response regulator. Histidine kinases, often membrane associated, detect environmental input at sensor domains and propagate resulting signals to catalytic cytoplasmic transmitter domains. Recent studies on the great diversity of sensor domains reveal patterns of domain organization and biochemical properties that provide insight into mechanisms of signaling. Despite the enormous sequence variability found within sensor input domains, they fall into a relatively small number of discrete structural classes. Subtle rearrangements along a structurally labile dimer interface, in the form of possible sliding or rotational motions, are propagated from the sensor domain to the transmitter domain to modulate activity of the receptor.

Project description:The WalRK two-component system plays important roles in maintaining cell wall homeostasis and responding to antibiotic stress in low-GC Gram-positive bacteria. In the major human pathogen, Streptococcus pneumoniae, phosphorylated WalR(Spn) (VicR) response regulator positively controls the transcription of genes encoding the essential PcsB division protein and surface virulence factors. WalR(Spn) is phosphorylated by the WalK(Spn) (VicK) histidine kinase. Little is known about the signals sensed by WalK histidine kinases. To gain information about WalK(Spn) signal transduction, we performed a kinetic characterization of the WalRK(Spn) autophosphorylation, phosphoryltransferase, and phosphatase reactions. We were unable to purify soluble full-length WalK(Spn). Consequently, these analyses were performed using two truncated versions of WalK(Spn) lacking its single transmembrane domain. The longer version (Delta35 amino acids) contained most of the HAMP domain and the PAS, DHp, and CA domains, whereas the shorter version (Delta195 amino acids) contained only the DHp and CA domains. The autophosphorylation kinetic parameters of Delta35 and Delta195 WalK(Spn) were similar [K(m)(ATP) approximately 37 microM; k(cat) approximately 0.10 min(-1)] and typical of those of other histidine kinases. The catalytic efficiency of the two versions of WalK(Spn) approximately P were also similar in the phosphoryltransfer reaction to full-length WalR(Spn). In contrast, absence of the HAMP-PAS domains significantly diminished the phosphatase activity of WalK(Spn) for WalR(Spn) approximately P. Deletion and point mutations confirmed that optimal WalK(Spn) phosphatase activity depended on the PAS domain as well as residues in the DHp domain. In addition, these WalK(Spn) DHp domain and DeltaPAS mutations led to attenuation of virulence in a murine pneumonia model.

Project description:The signal transduction paradigm in bacteria involves two-component systems (TCSs). Asgardarchaeota are archaea that may have originated the current eukaryotic lifeforms. Most research on these archaea has focused on eukaryotic-like features, such as genes involved in phagocytosis, cytoskeleton structure, and vesicle trafficking. However, little attention has been given to specific prokaryotic features. Here, the sequence and predicted structural features of TCS sensor kinases analyzed from two metagenome assemblies and a genomic assembly from cultured Asgardian archaea are presented. The homology of the sensor kinases suggests the grouping of Lokiarchaeum closer to bacterial homologs. In contrast, one group from a Lokiarchaeum and a meta-genome assembly from Candidatus Heimdallarchaeum suggest the presence of a set of kinases separated from the typical bacterial TCS sensor kinases. AtoS and ArcB homologs were found in meta-genome assemblies along with defined domains for other well-characterized sensor kinases, suggesting the close link between these organisms and bacteria that may have resulted in the metabolic link to the establishment of symbiosis. Several kinases are predicted to be cytoplasmic; some contain several PAS domains. The data shown here suggest that TCS kinases in Asgardian bacteria are witnesses to the transition from bacteria to eukaryotic organisms.