From cell membrane to nucleotides: the phosphate regulon in Escherichia coli

Most of the essential cellular components, like nucleic acids, lipids and sugars, are phosphorylated. The phosphate equilibrium in Escherichia coli is regulated by the phosphate (Pi) input from the surrounding medium. Some 90 proteins are synthesized at an increased rate during Pi starvation and the global control of the cellular metabolism requires cross-talk with other regulatory mechanisms. Since the Pi concentration is normally low in E. coli's natural habitat, these cells have devised a mechanism for synthesis of about 15 proteins to accomplish two specific functions: transport of Pi and its intracellular regulation. The synthesis of these proteins is controlled by two genes (the phoB-phoR operon), involving both negative and positive functions. PhoR protein is a histidine protein kinase, induced in Pi starvation and is a transmembrane protein. It phosphorylates the regulator protein PhoB which is also Pi starvation-induced. The PhoB phosphorylated form binds specifically to a DNA sequence of 18 nucleotides (the pho Box), which is part of the promoters of the Pho genes. The genes controlled by phoB constitute the Pho regulon. The repression of phoA (the gene encoding alkaline phosphatase) by high Pi concentrations in the medium requires the presence of an intact Pst operon (pstS, pstC, pstA, pstB and phoU) and phoR. The products of pstA and pstC are membrane bound, whereas the product of pstS is periplasmic and PstB and PhoU proteins are cytoplasmic. The function of the PhoU protein may be regulated by cofactor nucleotides and may be involved in signaling the activation of the regulon via PhoR.     

Evolutionary Tuning of Protein Expression Levels of a Positively Autoregulated Two-Component System

Cellular adaptation relies on the development of proper regulatory schemes for accurate control of gene expression levels in response to environmental cues. Over- or under-expression can lead to diminished cell fitness due to increased costs or insufficient benefits. Positive autoregulation is a common regulatory scheme that controls protein expression levels and gives rise to essential features in diverse signaling systems, yet its roles in cell fitness are less understood. It remains largely unknown how much protein expression is ‘appropriate’ for optimal cell fitness under specific extracellular conditions and how the dynamic environment shapes the regulatory scheme to reach appropriate expression levels. Here, we investigate the correlation of cell fitness and output response with protein expression levels of the E. coli PhoB/PhoR two-component system (TCS). In response to phosphate (Pi)-depletion, the PhoB/PhoR system activates genes involved in phosphorus assimilation as well as genes encoding themselves, similarly to many other positively autoregulated TCSs. We developed a bacteria competition assay in continuous cultures and discovered that different Pi conditions have conflicting requirements of protein expression levels for optimal cell fitness. Pi-replete conditions favored cells with low levels of PhoB/PhoR while Pi-deplete conditions selected for cells with high levels of PhoB/PhoR. These two levels matched PhoB/PhoR concentrations achieved via positive autoregulation in wild-type cells under Pi-replete and -deplete conditions, respectively. The fitness optimum correlates with the wild-type expression level, above which the phosphorylation output saturates, thus further increase in expression presumably provides no additional benefits. Laboratory evolution experiments further indicate that cells with non-ideal protein levels can evolve toward the optimal levels with diverse mutational strategies. Our results suggest that the natural protein expression levels and feedback regulatory schemes of TCSs are evolved to match the phosphorylation output of the system, which is determined by intrinsic activities of TCS proteins.     

The phosphate regulon and bacterial virulence: a regulatory network connecting phosphate homeostasis and pathogenesis

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.     

The pho regulon of Shigella flexneri

Growth of Escherichia coli K-12 in low-phosphate conditions results in the induction of the synthesis of many proteins, including the outer membrane porin PhoE, alkaline phosphatase, and the Pst system for the transport of phosphate (P_i). This response is controlled by a two-component regulatory system of which PhoB and PhoR are the response-regulator and the sensor/kinase, respectively. When Shigella flexneri was starved for P_i, neither PhoE nor alkaline phosphatase was produced. However, induction of the synthesis of the PstS protein was observed, indicating that S. flexneri contains a functional PhoB/PhoR regulatory system. Consistent with this notion, the introduction of the B. coli phoA gene in S. flexneri resulted in the induction of alkaline phosphatase synthesis under phosphate limitation. However, introduction of phoE on a plasmid did not lead to the expression of PhoE protein, indicating that S. flexneri PhoB does not recognize the phoE promoter region. The phoB gene was cloned and sequenced and in the deduced amino acid sequence two deviations from that of E. coli PhoB were detected. Site-directed mutagenesis revealed that one of these deviations, i.e. Leu-172, which is Arg in E. coli PhoB, is responsible for the lack of expression of the PhoE protein in S. flexneri.     

The activation of PhoB by acetylphosphate

PhoB is a response-regulator protein from Escherichia coli that controls an adaptive response to limiting phosphate. It is activated by autophosphorylation of a conserved aspartate residue within its regulatory domain. Its primary phospho-donor is its cognate histidine kinase PhoR; however, it also becomes phos-phorylated when incubated with acetylphosphate. To further characterize its activation, PhoB was considered to be an acetylphosphatase whose enzymatic mechanism involves a phospho-enzyme intermediate. The kinetic constants for autophosphorylation were determined using ³²P- and fluorescence-based assays and indicated that PhoB has a K_m for acetylphosphate of between 7 and 8 mM. These constants are not consistent with an in vivo role for acetylphosphate in the normal control of the Pho regulon. In addition, when PhoB was phosphorylated by acetylphosphate it eluted from a high-performance liquid chromatography (HPLC) size-exclusion column in two peaks. The larger form of PhoB eluted from the column in a similar manner to a chemically cross-linked dimer of PhoB. The smaller form of PhoB is a monomer. Phosphorylated PhoB bound pho-box DNA approximately 10 times tighter than PhoB. These observations show that PhoB forms a dimer when phosphorylated and suggest that the characteristics of activated PhoB result from its dimer ization.     

The phosphotransferase protein EIIA(Ntr) modulates the phosphate starvation response through interaction with histidine kinase PhoR in Escherichia coli

Many Proteobacteria possess the paralogous PTS^Ntr, in addition to the sugar transport phosphotransferase system (PTS). In the PTS^Ntr phosphoryl‐groups are transferred from phosphoenolpyruvate to protein EIIA^Ntr via the phosphotransferases EI^Ntr and NPr. The PTS^Ntr has been implicated in regulation of diverse physiological processes. In Escherichia coli, the PTS^Ntr plays a role in potassium homeostasis. In particular, EIIA^Ntr binds to and stimulates activity of a two‐component histidine kinase (KdpD) resulting in increased expression of the genes encoding the high‐affinity K⁺ transporter KdpFABC. Here, we show that the phosphate (pho) regulon is likewise modulated by PTS^Ntr. The pho regulon, which comprises more than 30 genes, is activated by the two‐component system PhoR/PhoB under conditions of phosphate starvation. Mutants lacking EIIA^Ntr are unable to fully activate the pho genes and exhibit a growth delay upon adaptation to phosphate limitation. In contrast, pho expression is increased above the wild‐type level in mutants deficient for EIIA^Ntr phosphorylation suggesting that non‐phosphorylated EIIA^Ntr modulates pho. Protein interaction analyses reveal binding of EIIA^Ntr to histidine kinase PhoR. This interaction increases the amount of phosphorylated response regulator PhoB. Thus, EIIA^Ntr is an accessory protein that modulates the activities of two distinct sensor kinases, KdpD and PhoR, in E. coli.     

Genetic analysis,structural modeling,and direct coupling analysis suggest a mechanism for phosphate signaling in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Background

Proper phosphate signaling is essential for robust growth of Escherichia coli and many other bacteria. The phosphate signal is mediated by a classic two component signal system composed of PhoR and PhoB. The PhoR histidine kinase is responsible for phosphorylating/dephosphorylating the response regulator, PhoB, which controls the expression of genes that aid growth in low phosphate conditions. The mechanism by which PhoR receives a signal of environmental phosphate levels has remained elusive. A transporter complex composed of the PstS, PstC, PstA, and PstB proteins as well as a negative regulator, PhoU, have been implicated in signaling environmental phosphate to PhoR.

Results

This work confirms that PhoU and the PstSCAB complex are necessary for proper signaling of high environmental phosphate. Also, we identify residues important in PhoU/PhoR interaction with genetic analysis. Using protein modeling and docking methods, we show an interaction model that points to a potential mechanism for PhoU mediated signaling to PhoR to modify its activity. This model is tested with direct coupling analysis.

Conclusions

These bioinformatics tools, in combination with genetic and biochemical analysis, help to identify and test a model for phosphate signaling and may be applicable to several other systems.

     

Cognate sensor kinase‐independent activation of Mycobacterium tuberculosis response regulator DevR (DosR) by acetyl phosphate: implications in anti‐mycobacterial drug design

The DevRS/DosT two‐component system is essential for mycobacterial survival under hypoxia, a prevailing stress within granulomas. DevR (also known as DosR) is activated by an inducing stimulus, such as hypoxia, through conventional phosphorylation by its cognate sensor kinases, DevS (also known as DosS) and DosT. Here, we show that the DevR regulon is activated by acetyl phosphate under ‘non‐inducing’ aerobic conditions when Mycobacterium tuberculosis devS and dosT double deletion strain is cultured on acetate. Overexpression of phosphotransacetylase caused a perturbation of the acetate kinase‐phosphotransacetylase pathway, a decrease in the concentration of acetyl phosphate and dampened the aerobic induction response in acetate‐grown bacteria. The operation of two pathways of DevR activation, one through sensor kinases and the other by acetyl phosphate, was established by an analysis of wild‐type DevS and phosphorylation‐defective DevSH395Q mutant strains under conditions partially mimicking a granulomatous‐like environment of acetate and hypoxia. Our findings reveal that DevR can be phosphorylated in vivo by acetyl phosphate. Importantly, we demonstrate that acetyl phosphate‐dependent phosphorylation can occur in the absence of DevR’s cognate kinases. Based on our findings, we conclude that anti‐mycobacterial therapy should be targeted to DevR itself and not to DevS/DosT kinases.     

Regulation of the phosphate regulon of Escherichia colt Properties of phoR deletion mutants and subcellular localization of PhoR protein

Summary The phoR gene is a bifunctional regulatory gene for the phosphate regulon of Escherichia coli. It acts as a negative regulator in the presence of excess phosphate and as a positive regulator with limited phosphate, through modification of PhoB protein. We constructed several phoR genes, with various deletions in the 5 regions, which were regulated by the trp-lac hybrid promoter. The PhoR1084 and PhoR1159 proteins that lack the 83 and 158 N-terminal amino acids, respectively, retained the positive function for the expression of phoA that codes for alkaline phosphatase, but lacked the negative function. The PhoR1263 protein that lacks the 262 N-terminal amino acids was deficient in both functions. An antiserum against PhoR1084 protein was prepared. Western blot analysis of the subcellular fractions obtained by differential centrifugation indicated that the intact PhoR and PhoR1084 proteins are located in the inner membrane and cytoplasmic fractions, respectively. The results suggest that PhoR protein is anchored to the cytoplasmic membrane by the amino-terminal region.     

Effect of ADP on the rate of acetyl phosphate hydrolysis by the Ca2+-ATPase of sarcoplasmic reticulum

Hydrolysis of acetyl phosphate is inhibited by high concentrations of Pi and MgCl2, probably due to an increase in the steady-state level of phosphoenzyme formed from Pi in the medium. A dual effect of ADP during steady-state hydrolysis of acetyl phosphate was observed. ADP inhibited hydrolysis in the presence of 5 mM MgCl2 and no added Pi, whereas it stimulated hydrolysis when phosphoenzyme formation by Pi was favored by including 6 mM Pi and 20 mM MgCl2 in the assay medium. ATP inhibited acetyl phosphate hydrolysis in both of these assay media. When phosphoenzyme formation by Pi in the presence of acetyl phosphate was stimulated at Ca2+ concentrations sufficient to saturate the low-affinity Ca2+-binding sites, ADP stimulated acetyl phosphate hydrolysis and also promoted ATP synthesis by reversal of the catalytic cycle. The rate of ATP synthesis was dependent on ADP, Pi and Ca2+. Phosphoenzyme formation by Pi and MgCl2, whether in the absence of Ca2+ and acetyl phosphate, or during acetyl phosphate hydrolysis, was inhibited by ADP and ATP. These results suggest that ADP interacts with different intermediates of the catalytic cycle and that expression of inhibition or activation of acetyl phosphate hydrolysis depends on the steady-state level of phosphoenzyme formed by Pi.     

Two-component systems of Corynebacterium glutamicum: deletion analysis and involvement of the PhoS-PhoR system in the phosphate starvation response

Corynebacterium glutamicum contains genes for 13 two-component signal transduction systems. In order to test for their essentiality and involvement in the adaptive response to phosphate (Pi) starvation, a set of 12 deletion mutants was constructed. One of the mutants was specifically impaired in its ability to grow under Pi limitation, and therefore the genes lacking in this strain were named phoS (encoding the sensor kinase) and phoR (encoding the response regulator). DNA microarray analyses with the C. glutamicum wild type and the DeltaphoRS mutant supported a role for the PhoRS system in the adaptation to Pi starvation. In contrast to the wild type, the DeltaphoRS mutant did not induce the known Pi starvation-inducible (psi) genes within 1 hour after a shift from Pi excess to Pi limitation, except for the pstSCAB operon, which was still partially induced. This indicates an activator function for PhoR and the existence of at least one additional regulator of the pst operon. Primer extension analysis of selected psi genes (pstS, ugpA, phoR, ushA, and nucH) confirmed the microarray data and provided evidence for positive autoregulation of the phoRS genes.