The phosphate regulon and bacterial virulence: a regulatory network connecting phosphate homeostasis and pathogenesis
440
Citation
142
Reference
10
Related Paper
Citation Trend
Abstract:
Bacterial pathogens regulate virulence factor gene expression coordinately in response to environmental stimuli, including nutrient starvation. The phosphate (Pho) regulon plays a key role in phosphate homeostasis. It is controlled by the PhoR/PhoB two-component regulatory system. PhoR is an integral membrane signaling histidine kinase that, through an interaction with the ABC-type phosphate-specific transport (Pst) system and a protein called PhoU, somehow senses environmental inorganic phosphate (P(i)) levels. Under conditions of P(i) limitation (or in the absence of a Pst component or PhoU), PhoR activates its partner response regulator PhoB by phosphorylation, which, in turn, up- or down-regulates target genes. Single-cell profiling of PhoB activation has shown recently that Pho regulon gene expression exhibits a stochastic, "all-or-none" behavior. Recent studies have also shown that the Pho regulon plays a role in the virulence of several bacteria. Here, we present a comprehensive overview of the role of the Pho regulon in bacterial virulence. The Pho regulon is clearly not a simple regulatory circuit for controlling phosphate homeostasis; it is part of a complex network important for both bacterial virulence and stress response.Keywords:
Regulon
Response regulator
Histidine kinase
Two-component regulatory system
Virulence factor
Bacterial pathogens regulate virulence factor gene expression coordinately in response to environmental stimuli, including nutrient starvation. The phosphate (Pho) regulon plays a key role in phosphate homeostasis. It is controlled by the PhoR/PhoB two-component regulatory system. PhoR is an integral membrane signaling histidine kinase that, through an interaction with the ABC-type phosphate-specific transport (Pst) system and a protein called PhoU, somehow senses environmental inorganic phosphate (P(i)) levels. Under conditions of P(i) limitation (or in the absence of a Pst component or PhoU), PhoR activates its partner response regulator PhoB by phosphorylation, which, in turn, up- or down-regulates target genes. Single-cell profiling of PhoB activation has shown recently that Pho regulon gene expression exhibits a stochastic, "all-or-none" behavior. Recent studies have also shown that the Pho regulon plays a role in the virulence of several bacteria. Here, we present a comprehensive overview of the role of the Pho regulon in bacterial virulence. The Pho regulon is clearly not a simple regulatory circuit for controlling phosphate homeostasis; it is part of a complex network important for both bacterial virulence and stress response.
Regulon
Response regulator
Histidine kinase
Two-component regulatory system
Virulence factor
Cite
Citations (440)
Histidine kinase
Response regulator
Two-component regulatory system
Robustness
Component (thermodynamics)
Stimulus (psychology)
Cite
Citations (54)
Two‐component signal transduction systems (TCS), consisting of a sensor histidine protein kinase and its cognate response regulator, are an important mode of environmental sensing in bacteria. Additionally, they have been found to regulate virulence determinants in several pathogens. Bacillus anthracis , the causative agent of anthrax and a bioterrorism agent, harbours 41 pairs of TCS. However, their role in its pathogenicity has remained largely unexplored. Here, we show that WalRK of B. anthracis forms a functional TCS which exhibits some species‐specific functions. Biochemical studies showed that domain variants of WalK, the histidine kinase, exhibit classical properties of autophosphorylation and phosphotransfer to its cognate response regulator WalR. Interestingly, these domain variants also show phosphatase activity towards phosphorylated WalR, thereby making WalK a bifunctional histidine kinase/phosphatase. An in silico regulon determination approach, using a consensus binding sequence from Bacillus subtilis , provided a list of 30 genes that could form a putative WalR regulon in B. anthracis . Further, electrophoretic mobility shift assay was used to show direct binding of purified WalR to the upstream regions of three putative regulon candidates, an S‐layer protein EA1, a cell division ABC transporter FtsE and a sporulation histidine kinase KinB3. Our work lends insight into the species‐specific functions and mode of action of B. anthracis WalRK.
Regulon
Bacillus anthracis
Response regulator
Histidine kinase
Two-component regulatory system
Anthrax toxin
Cite
Citations (31)
When Bacillus subtilis is subjected to phosphate starvation, the Pho regulon is activated by the PhoP-PhoR two-component signal transduction system to elicit specific responses to this nutrient limitation. The response regulator, PhoP, and its cognate histidine sensor kinase, PhoR, are encoded by the phoPR operon that is transcribed as a 2.7-kb bicistronic mRNA. The phoPR operon is transcribed from two sigma(A)-dependent promoters, P(1) and P(2). Under conditions where the Pho regulon was not induced (i.e., phosphate-replete conditions or phoR-null mutant), a low level of phoPR transcription was detected only from promoter P(1). During phosphate starvation-induced transition from exponential to stationary phase, the expression of the phoPR operon was up-regulated in a phosphorylated PhoP (PhoP approximately P)-dependent manner; in addition to P(1), the P(2) promoter becomes active. In vitro gel shift assays and DNase I footprinting experiments showed that both PhoP and PhoP approximately P could bind to the control region of the phoPR operon. The data indicate that while low-level constitutive expression of phoPR is required under phosphate-replete conditions for signal perception and transduction, autoinduction is required to provide sufficient PhoP approximately P to induce other members of the Pho regulon. The extent to which promoters P(1) and P(2) are activated appears to be influenced by the presence of other sigma factors, possibly the result of sigma factor competition. For example, phoPR is hyperinduced in a sigB mutant and, later in stationary phase, in sigH, sigF, and sigE mutants. The data point to a complex regulatory network in which other stress responses and post-exponential-phase processes influence the expression of phoPR and, thereby, the magnitude of the Pho regulon response.
L-arabinose operon
gal operon
Cite
Citations (59)
The Pho regulon of Bacillus subtilis is controlled by three two‐component signal‐transduction systems: PhoP/PhoR, ResD/ResE, and the phosphorelay leading to the phosphorylation of Spo0A. Two of these systems act as positive regulators, while the third is involved in negative regulation of the Pho regulon. Under phosphate‐starvation‐induction conditions, the response regulator (RR) PhoP, and the histidine protein kinase (HK) PhoR, are involved in the induction of Pho‐regulon genes including the phoPR operon and genes encoding the major vegetative alkaline phosphatases, phoA and phoB . ResD (the RR) and ResE (the HK) are positive regulators of both aerobic and anaerobic respiration in B. subtilis . Current data suggest that they are also positive regulators of the Pho regulon, as is the transition‐state regulatory protein AbrB. Data presented reveal that ResDE and AbrB are involved in activation of the Pho regulon through separate regulatory pathways. Spo0A∼P (RR) exerts a negative effect on the Pho regulon through its repression of AbrB, and possibly through repression of ResDE. Both pathways converge to regulate transcription of the phoPR operon.
Component (thermodynamics)
SIGNAL (programming language)
Transduction (biophysics)
Cite
Citations (86)
Bacillus subtilis PhoP-PhoR two-component system (TCS) senses phosphate deficiency conditions, and then controls expression of the Pho regulon to prolong survival. The sensor histidine kinase, PhoR, is autophosphorylated and transfers the phosphate to the response regulator, PhoP. Phosphorylated PhoP (PhoP~P) binds to repeated 6-bp consensus PhoP binding sequences of Pho regulon promoters and activates or represses gene expression. Pho signal transduction systems are part of interconnected signal transduction network involving at least three TCSs (PhoP-PhoR, ResD-ResE TCS, SpoOA phosphorelay), a global carbon metabolism regulator (CcpA), and transition state regulators (AbrB, ScoC). In addition, PhoP-PhoR TCS is cross related with YycF-YycG TCS by cross-regulation. While indescribable progress has been made in understanding phosphate deficiency stress response through refined expression of the Pho regulon in the recent past years, many important questions still remain. Solving these questions may provide important information for application study using B. subtilis.
Regulon
Response regulator
Two-component regulatory system
Histidine kinase
Bacillaceae
Cite
Citations (0)
The regulation and timely expression of bacterial genes during infection is critical for a pathogen to cause an infection. Bacteria have multiple mechanisms to regulate gene expression in response to their environment, one of which is two-component systems (TCS). TCS have two components. One component is a sensory histidine kinase (HK) that autophosphorylates when activated by a signal. The activated sensory histidine kinase then transfers the phosphoryl group to the second component, the response regulator, which activates transcription of target genes.
Component (thermodynamics)
Cite
Citations (26)
Two-component systems are the major means by which bacteria couple adaptation to environmental changes. All utilize a phosphorylation cascade from a histidine kinase to a response regulator, and some also employ an accessory protein. The system-wide signaling fidelity of two-component systems is based on preferential binding between the signaling proteins. However, information on the interaction kinetics between membrane embedded histidine kinase and its partner proteins is lacking. Here, we report the first analysis of the interactions between the full-length membrane-bound histidine kinase CpxA, which was reconstituted in nanodiscs, and its cognate response regulator CpxR and accessory protein CpxP. Using surface plasmon resonance spectroscopy in combination with interaction map analysis, the affinity of membrane-embedded CpxA for CpxR was quantified, and found to increase by tenfold in the presence of ATP, suggesting that a considerable portion of phosphorylated CpxR might be stably associated with CpxA in vivo. Using microscale thermophoresis, the affinity between CpxA in nanodiscs and CpxP was determined to be substantially lower than that between CpxA and CpxR. Taken together, the quantitative interaction data extend our understanding of the signal transduction mechanism used by two-component systems.
Response regulator
Histidine kinase
Two-component regulatory system
Microscale Thermophoresis
Cite
Citations (18)
Bacillus subtilis PhoP-PhoR two-component system (TCS) senses phosphate deficiency conditions, and then controls expression of the Pho regulon to prolong survival. The sensor histidine kinase, PhoR, is autophosphorylated and transfers the phosphate to the response regulator, PhoP. Phosphorylated PhoP (PhoP~P) binds to repeated 6-bp consensus PhoP binding sequences of Pho regulon promoters and activates or represses gene expression. Pho signal transduction systems are part of interconnected signal transduction network involving at least three TCSs (PhoP-PhoR, ResD-ResE TCS, SpoOA phosphorelay), a global carbon metabolism regulator (CcpA), and transition state regulators (AbrB, ScoC). In addition, PhoP-PhoR TCS is cross related with YycF-YycG TCS by cross-regulation. While indescribable progress has been made in understanding phosphate deficiency stress response through refined expression of the Pho regulon in the recent past years, many important questions still remain. Solving these questions may provide important information for application study using B. subtilis.Keywords: B. subtilis, PhoPR two component system, Pho regulon, phosphate deficiency, signal transduction network
Regulon
Response regulator
Two-component regulatory system
Histidine kinase
Sigma factor
Bacillaceae
Cite
Citations (1)
A two-dimensional (2-D) gel electrophoresis study of Bacillus subtilis strain 168 identified 20 proteins that are strongly induced in response to phosphate starvation. The induction of nine of these phosphate-starvation-induced (Psi) proteins was dependent on a functional PhoR protein. PhoR is the histidine sensor-kinase component of a phosphate-concentration-sensing two-component regulatory system which, together with its partner response regulator PhoP, controls the expression of genes in the Pho regulon. Genes encoding PhoR-dependent Psi proteins are therefore likely to be members of the Pho regulon. SpoOA ~ P, the response regulator of the signal transduction pathway required for the induction of sporulation, has previously been shown to negatively affect the induction of the Pho regulon by repressing the phoP-phoR operon. The induction pattern of some PhoR-dependent Psi proteins was altered in a spoOA mutant such that their synthesis continued for longer than was found with the wild-type. The most abundant Psi protein, Psi1–3, was characterized by N-terminal sequencing of internal peptide fragments and shown to have a high similarity to an Escherichia coli protein which is involved in phosphate uptake during phosphate starvation.
Regulon
Response regulator
Two-component regulatory system
Histidine kinase
Starvation response
Cite
Citations (52)