Phosphatase PstP Research Articles

Inactivation of Phosphoserine/Threonine Phosphatase PstP in H37Rv Mycobacterium tuberculosis by In silico Drug Design Approach

Inactivation of Phosphoserine/Threonine Phosphatase PstP in H37Rv Mycobacterium tuberculosis by In silico Drug Design Approach

Mycobacterial serine/threonine phosphatase PstP is phosphoregulated and localized to mediate control of cell wall metabolism.

The mycobacterial cell wall is profoundly regulated in response to environmental stresses, and this regulation contributes to antibiotic tolerance. The reversible phosphorylation of different cell wall regulatory proteins is a major mechanism of cell wall regulation. Eleven serine/threonine protein kinases phosphorylate many critical cell wall-related proteins in mycobacteria. PstP is the sole serine/ threonine phosphatase, but few proteins have been verified as PstP substrates. PstP is itself phosphorylated, but the role of its phosphorylation in regulating its activity has been unclear. In this study, we aim to discover novel substrates of PstP in Mycobacterium tuberculosis (Mtb). We show in vitro that PstP dephosphorylates two regulators of peptidoglycan in Mtb, FhaA, and Wag31. We also show that a phosphomimetic mutation of T137 on PstP negatively regulates its catalytic activity against the cell wall regulators FhaA, Wag31, CwlM, PknB, and PknA, and that the corresponding mutation in Mycobacterium smegmatis causes misregulation of peptidoglycan in vivo. We show that PstP is localized to the septum, which likely restricts its access to certain substrates. These findings on the regulation of PstP provide insight into the control of cell wall metabolism in mycobacteria.

Phosphorylation on PstP Regulates Cell Wall Metabolism and Antibiotic Tolerance in Mycobacterium smegmatis.

Mycobacterium tuberculosis and its relatives, like many bacteria, have dynamic cell walls that respond to environmental stresses. Modulation of cell wall metabolism in stress is thought to be responsible for decreased permeability and increased tolerance to antibiotics. The signaling systems that control cell wall metabolism under stress, however, are poorly understood. Here, we examine the cell wall regulatory function of a key cell wall regulator, the serine/threonine phosphatase PstP, in the model organism Mycobacterium smegmatis We show that the peptidoglycan regulator CwlM is a substrate of PstP. We find that a phosphomimetic mutation, pstP T171E, slows growth, misregulates both mycolic acid and peptidoglycan metabolism in different conditions, and interferes with antibiotic tolerance. These data suggest that phosphorylation on PstP affects its activity against various substrates and is important in the transition between growth and stasis.IMPORTANCE Regulation of cell wall assembly is essential for bacterial survival and contributes to pathogenesis and antibiotic tolerance in mycobacteria, including pathogens such as Mycobacterium tuberculosis However, little is known about how the cell wall is regulated in stress. We describe a pathway of cell wall modulation in Mycobacterium smegmatis through the only essential Ser/Thr phosphatase, PstP. We showed that phosphorylation on PstP is important in regulating peptidoglycan metabolism in the transition to stasis and mycolic acid metabolism in growth. This regulation also affects antibiotic tolerance in growth and stasis. This work helps us to better understand the phosphorylation-mediated cell wall regulation circuitry in Mycobacteria.

Global discovery the PstP interactions using Mtb proteome microarray and revealing novel connections with EthR

Mycobacterium tuberculosis (Mtb) serine/threonine protein phosphatase PstP plays an important role in regulating Mtb cell division and growth by reversible phosphorylation signaling. However, the substrates of Mtb with which the PstP interacts, and the underlying molecular mechanisms are still largely unknown. In this study, we performed an Mtb proteome microarray to globally identify the PstP bindings. In this way, we discovered 78 interactors between PstP and Mtb proteins, and found a novel connections with EthR. The interaction between PstP and EthR has been validated by Bio-Layer interferometry and Yeast-two-hybrid. And functional studies showed that PstP significantly enhances the binding between EthR and related DNA domain through its interaction with EthR. Phenotypically, overexpression of PstP promoted the resistance of Mycobacterium smegmatis with the antibiotic of ethionamide. Overall, we hopefully wish that the PstP interactors identified in this study will serve as a useful resource for further systematic studies of the roles that PstP plays in the regulation of Mtb dephosphorylation. SignificanceMycobacterium tuberculosis (Mtb) is the causative agent of tuberculosis, which is responsible of ~1.5 million death per year. Understanding the knowledge about the basic biological regulation pathways in Mtb is an effective approach to discover the novel drug targets for cure TB. PstP is a serine/threonine protein phosphatase in Mtb, and plays important roles in regulating Mtb cell division and growth by reversible phosphorylation signaling. In this study, we identified 78 PstP interacting Mtb proteins using Mtb proteome microarray, which could preliminarily explain the roles of PstP played in Mtb. Moreover, functional analysis showed that a novel transcription factor EthR had been found regulated by PstP through binding, which could enhance the resistance to the antibiotic ETH. Overall, this network constructed with PstP-Mtb proteins could serve as a valuable resource for studying Mtb growth.

Mycobacterial phosphatase PstP regulates global serine threonine phosphorylation and cell division

Protein phosphatase PstP is conserved throughout the Actinobacteria in a genetic locus related to cell wall synthesis and cell division. In many Actinobacteria it is the sole annotated serine threonine protein phosphatase to counter the activity of multiple serine threonine protein kinases. We used transcriptional knockdown, electron microscopy and comparative phosphoproteomics to investigate the putative dual functions of PstP as a specific regulator of cell division and as a global regulator of protein phosphorylation. Comparative phosphoproteomics in the early stages of PstP depletion showed hyperphosphorylation of protein kinases and their substrates, confirming PstP as a negative regulator of kinase activity and global serine and threonine phosphorylation. Analysis of the 838 phosphorylation sites that changed significantly, suggested that PstP may regulate diverse phosphoproteins, preferentially at phosphothreonine near acidic residues, near the protein termini, and within membrane associated proteins. Increased phosphorylation of the activation loop of protein kinase B (PknB) and of the essential PknB substrate CwlM offer possible explanations for the requirement for pstP for growth and for cell wall defects when PstP was depleted.

Targeting the messengers: Serine/threonine protein kinases as potential targets for antimycobacterial drug development.

The emergence of increasingly drug-resistant Mycobacterium tuberculosis strains has become a crucial public health concern. In order to effectively treat tuberculosis, it is imperative to find newer drug targets, which are important for the in vivo bacterial survival and persistence. Phosphorylation based signaling cascades modulated by eukaryotic-like serine/threonine protein kinases and phosphatase in M. tuberculosis, transduce extracellular stimuli to a cellular response ensuing pathogen's growth, persistence and pathogenesis. Of the 11 STPKs that M. tuberculosis genome encodes, three kinases, namely PknA, PknB and PknG and the sole serine/threonine phosphatase PstP are crucial for the intracellular survival of the bacteria. PknA and PknB regulates cell growth, cell wall synthesis and morphological changes during bacterial cell division; while PknG modulates metabolic changes in response to stress and aids in bacterial survival during latency like conditions. PstP functions to dephosphorylate STPKs and their substrates and hence is important at nearly all stages of infection. Here, we review the current knowledge on PstP, PknA, PknB and PknG based on the genetic, biochemical, and functional studies in M. tuberculosis physiopathology. We further explore the potential of these molecules as targets for therapeutic intervention and discuss the advancement made in the development of inhibitors against these targets. © 2018 IUBMB Life, 70(9):889-904, 2018.

Serine/Threonine Protein Phosphatase PstP of Mycobacterium tuberculosis Is Necessary for Accurate Cell Division and Survival of Pathogen

Protein phosphatases play vital roles in phosphorylation-mediated cellular signaling. Although there are 11 serine/threonine protein kinases in Mycobacterium tuberculosis, only one serine/threonine phosphatase, PstP, has been identified. Although PstP has been biochemically characterized and multiple in vitro substrates have been identified, its physiological role has not yet been elucidated. In this study, we have investigated the impact of PstP on cell growth and survival of the pathogen in the host. Overexpression of PstP led to elongated cells and partially compromised survival. We find that depletion of PstP is detrimental to cell survival, eventually leading to cell death. PstP depletion results in elongated multiseptate cells, suggesting a role for PstP in regulating cell division events. Complementation experiments performed with PstP deletion mutants revealed marginally compromised survival, suggesting that all of the domains, including the extracellular domain, are necessary for complete rescue. On the other hand, the catalytic activity of PstP is absolutely essential for the in vitro growth. Mice infection experiments establish a definitive role for PstP in pathogen survival within the host. Depletion of PstP from established infections causes pathogen clearance, indicating that the continued presence of PstP is necessary for pathogen survival. Taken together, our data suggest an important role for PstP in establishing and maintaining infection, possibly via the modulation of cell division events.

Structural Analysis of the PP2C Phosphatase tPphA from Thermosynechococcus elongatus: A Flexible Flap Subdomain Controls Access to the Catalytic Site

The homologue of the phosphoprotein PII phosphatase PphA from Thermosynechococcus elongatus, termed tPphA, was identified and its structure was resolved in two different space groups, C2221 and P41212, at a resolution of 1.28 and 3.05 Å, respectively. tPphA belongs to a large and widely distributed subfamily of Mg2+/Mn2+-dependent phosphatases of the PPM superfamily characterized by the lack of catalytic and regulatory domains. The core structure of tPphA shows a high degree of similarity to the two PPM structures identified so far. In contrast to human PP2C, but similar to Mycobacterium tuberculosis phosphatase PstP, the catalytic centre exhibits a third metal ion in addition to the dinuclear metal centre universally conserved in all PPM members. The fact that the third metal is only liganded by amino acids, which are universally conserved in all PPM members, implies that the third metal could be general for all members of this family. As a specific feature of tPphA, a flexible subdomain, previously recognized as a flap domain, could be revealed. Comparison of different structural isomers of tPphA as well as site-specific mutagenesis implied that the flap domain is involved in substrate binding and catalytic activity. The structural arrangement of the flap domain was accompanied by a large side-chain movement of an Arg residue (Arg169) at the basis of the flap. Mutation of this residue strongly impaired protein stability as well as catalytic activity, emphasizing the importance of this amino acid for the regional polysterism of the flap subdomain and confirming the assumption that flap domain flexibility is involved in catalysis.

The Condensing Activities of the Mycobacterium tuberculosis Type II Fatty Acid Synthase Are Differentially Regulated by Phosphorylation

Phosphorylation of proteins by Ser/Thr protein kinases (STPKs) has recently become of major physiological importance because of its possible involvement in virulence of bacterial pathogens. Although Mycobacterium tuberculosis has eleven STPKs, the nature and function of the substrates of these enzymes remain largely unknown. In this work, we have identified for the first time STPK substrates in M. tuberculosis forming part of the type II fatty acid synthase (FAS-II) system involved in mycolic acid biosynthesis: the malonyl-CoA::AcpM transacylase mtFabD, and the beta-ketoacyl AcpM synthases KasA and KasB. All three enzymes were phosphorylated in vitro by different kinases, suggesting a complex network of interactions between STPKs and these substrates. In addition, both KasA and KasB were efficiently phosphorylated in M. bovis BCG each at different sites and could be dephosphorylated by the M. tuberculosis Ser/Thr phosphatase PstP. Enzymatic studies revealed that, whereas phosphorylation decreases the activity of KasA in the elongation process of long chain fatty acids synthesis, this modification enhances that of KasB. Such a differential effect of phosphorylation may represent an unusual mechanism of FAS-II system regulation, allowing pathogenic mycobacteria to produce full-length mycolates, which are required for adaptation and intracellular survival in macrophages.

Conserved autophosphorylation pattern in activation loops and juxtamembrane regions of Mycobacterium tuberculosis Ser/Thr protein kinases

The identification of phosphorylation sites in proteins provides a powerful tool to study signal transduction pathways and to establish interaction networks involving signaling elements. Using different strategies to identify phosphorylated residues, we report here mass spectrometry studies of the entire intracellular regions of four ‘receptor-like’ protein kinases from Mycobacterium tuberculosis (PknB, PknD, PknE, and PknF), each consisting of an N-terminal kinase domain and a juxtamembrane region of varying length (26–100 residues). The enzymes were observed to incorporate different numbers of phosphates, from five in PknB up to 11 in PknD or PknE, and all detected sites were dephosphorylated by the cognate mycobacterial phosphatase PstP. Comparison of the phosphorylation patterns reveals two recurrent clusters of pThr/pSer residues, respectively, in their activation loops and juxtamembrane regions, which have a distinct effect on kinase activity. All studied kinases have at least two conserved phosphorylated residues in their activation loop and mutations of these residues in PknB significantly decreased the kinase activity, whereas deletion of the entire juxtamembrane regions in PknB and PknF had little effect on their activities. These results reinforce the hypothesis that mycobacterial kinase regulation includes a conserved activation loop mechanism, and suggest that phosphorylation sites in the juxtamembrane region might be involved in putative kinase-mediated signaling cascades.

First Structural Glimpse at a Bacterial Ser/Thr Protein Phosphatase

In this issue of Structure, we describe the crystal structure of the Ser/Thr protein phosphatase PstP from Mycobacterium tuberculosis, opening new perspectives to understand the putative roles of "eukaryotic-like" signaling elements in bacteria.

PknB kinase activity is regulated by phosphorylation in two Thr residues and dephosphorylation by PstP, the cognate phospho-Ser/Thr phosphatase, in Mycobacterium tuberculosis.

Bacterial genomics revealed the widespread presence of eukaryotic-like protein kinases and phosphatases in prokaryotes, but little is known on their biochemical properties, regulation mechanisms and physiological roles. Here we focus on the catalytic domains of two trans-membrane enzymes, the Ser/Thr protein kinase PknB and the protein phosphatase PstP from Mycobacterium tuberculosis. PstP was found to specifically dephosphorylate model phospho-Ser/Thr substrates in a Mn2+-dependent manner. Autophosphorylated PknB was shown to be a substrate for Pstp and its kinase activity was affected by PstP-mediated dephosphorylation. Two threonine residues in the PknB activation loop, found to be mostly disordered in the crystal structure of this kinase, namely Thr171 and Thr173, were identified as the target for PknB autophosphorylation and PstP dephosphorylation. Replacement of these threonine residues by alanine significantly decreased the kinase activity, confirming their direct regulatory role. These results indicate that, as for eukaryotic homologues, phosphorylation of the activation loop provides a regulation mechanism of mycobacterial kinases and strongly suggest that PknB and PstP could work as a functional pair in vivo to control mycobacterial cell growth.