Novel substrates of Mycobacterium tuberculosis PknH Ser/Thr kinase

PknH Ser/Thr protein kinase of Mycobacterium tuberculosis controls the expression of a variety of cell wall related enzymes and regulates the in vivo growth in mice. Therefore, we predicted that the PknH kinase could phosphorylate several substrates controlling different metabolic and physiological pathways. Using a bioinformatic approach, we identified 40 potential substrates. Two substrates were shown to be phosphorylated by recombinant PknH kinase in vitro. Point mutation studies verified that substrates are phosphorylated at the in silico-predicted sites. Kinetic studies revealed a similar relative-phosphorylation rate (V(max)) of PknH towards two new substrates and the only previously known substrate, EmbR. Unlike the EmbR protein, the Rv0681 and DacB1 proteins do not contain an FHA domain and are possible participants of new signaling pathways mediated by the PknH kinase in M. tuberculosis.     

Pkg2, a Novel Transmembrane Protein Ser/Thr Kinase of Streptomyces granaticolor

A 4.2-kb SphI-BamHI fragment of chromosomal DNA from Streptomyces granaticolor was cloned and shown to encode a protein with significant sequence similarity to the eukaryotic protein serine/threonine kinases. It consists of 701 amino acids and in the N-terminal part contains all conserved catalytic domains of protein kinases. The C-terminal domain of Pkg2 contains seven tandem repeats of 11 or 12 amino acids with similarity to the tryptophan-docking motif known to stabilize a symmetrical three-dimensional structure called a propeller structure. The pkg2 gene was overexpressed in Escherichia coli, and the gene product (Pkg2) has been found to be autophosphorylated at serine and threonine residues. The N- and C-terminal parts of Pkg2 are separated with a hydrophobic stretch of 21 amino acids which translocated a PhoA fusion protein into the periplasm. Thus, Pkg2 is the first transmembrane protein serine/threonine kinase described for streptomycetes. Replacement of the pkg2 gene by the spectinomycin resistance gene resulted in changes in the morphology of aerial hyphae.     

Biochemical and Spatial Coincidence in the Provisional Ser/Thr Protein Kinase Interaction Network of Mycobacterium tuberculosis

Many Gram-positive bacteria coordinate cellular processes by signaling through Ser/Thr protein kinases (STPKs), but the architecture of these phosphosignaling cascades is unknown. To investigate the network structure of a prokaryotic STPK system, we comprehensively explored the pattern of signal transduction in the Mycobacterium tuberculosis Ser/Thr kinome. Autophosphorylation is the dominant mode of STPK activation, but the 11 M. tuberculosis STPKs also show a specific pattern of efficient cross-phosphorylation in vitro. The biochemical specificity intrinsic to each kinase domain was used to map the provisional signaling network, revealing a three-layer architecture that includes master regulators, signal transducers, and terminal substrates. Fluorescence microscopy revealed that the STPKs are specifically localized in the cell. Master STPKs are concentrated at the same subcellular sites as their substrates, providing additional support for the biochemically defined network. Together, these studies imply a branched functional architecture of the M. tuberculosis Ser/Thr kinome that could enable horizontal signal spreading. This systems-level approach provides a biochemical and spatial framework for understanding Ser/Thr phospho-signaling in M. tuberculosis, which differs fundamentally from previously defined linear histidine kinase cascades.     

The Mycobacterium tuberculosis Ser/Thr Kinase Substrate Rv2175c Is a DNA-binding Protein Regulated by Phosphorylation

Recent efforts have underlined the role of serine/threonine protein kinases in growth, pathogenesis, and cell wall metabolism in Mycobacterium tuberculosis. Although most kinases have been investigated for their physiological roles, little information is available regarding how serine/threonine protein kinase-dependent phosphorylation regulates the activity of kinase substrates. Herein, we focused on M. tuberculosis Rv2175c, a protein of unknown function, conserved in actinomycetes, and recently identified as a substrate of the PknL kinase. We solved the solution structure of Rv2175c by multidimensional NMR and demonstrated that it possesses an original winged helix-turn-helix motif, indicative of a DNA-binding protein. The DNA-binding activity of Rv2175c was subsequently confirmed by fluorescence anisotropy, as well as in electrophoretic mobility shift assays. Mass spectrometry analyses using a combination of MALDI-TOF and LC-ESI/MS/MS identified Thr⁹ as the unique phosphoacceptor. This was further supported by complete loss of PknL-dependent phosphorylation of an Rv2175c_T9A mutant. Importantly, the DNA-binding activity was completely abrogated in a Rv2175c_T9D mutant, designed to mimic constitutive phosphorylation, but not in a mutant lacking the first 13 residues. This implies that the function of the N-terminal extension is to provide a phosphoacceptor (Thr⁹), which, following phosphorylation, negatively regulates the Rv2175c DNA-binding activity. Interestingly, the N-terminal disordered extension, which bears the phosphoacceptor, was found to be restricted to members of the M. tuberculosis complex, thus suggesting the existence of an original mechanism that appears to be unique to the M. tuberculosis complex.In response to its environment, Mycobacterium tuberculosis (M. tb)³ activates or represses the expression of a number of genes to promptly adjust to new conditions. More precisely, during the infection process, cross-talk of signals between the host and the bacterium take place, resulting in reprogramming the host signaling network. Many of these stimuli are transduced in the bacteria via sensor kinases, enabling the pathogen to adapt its cellular response to survive in hostile environments. Although the two-component systems represent the classic prokaryotic mechanism for detection and response to environmental changes, the serine/threonine and tyrosine protein kinases (STPKs) associated with their phosphatases have emerged as important regulatory systems in prokaryotic cells (1–3). M. tb contains eleven STPKs (4, 5), and most are being investigated for their physiological roles and potential application for future drug development to combat tuberculosis (6). Through phosphorylation these STPKs are also thought to play important functions in cell signaling responses as well as in essential metabolic pathways. The cell wall of M. tb plays a critical role in the defense of this pathogen in the host, and changes in cell wall composition in response to various environmental stimuli are critical to M. tb adaptation during infection. Although little is known regarding the cell wall regulatory mechanisms in M. tb, there is now an increasing body of evidence indicating that these processes largely rely on STPK-dependent mechanisms (7–9).Moreover, little information on the range of functions regulated by the STPKs is available, and the complicated mycobacterial phosphoproteome is still far from being deciphered. Understanding mycobacterial kinase biology has been severely impeded by the difficulty to identify direct kinase substrates and the subsequent characterization of the phosphorylation site(s). However, several recent studies have reported the identification and characterization of the phosphorylation sites in substrates related to various metabolic pathways in mycobacteria. These include the Fork Head associated-containing protein GarA, a key regulator of the tricarboxylic cycle (10, 11); PbpA, a penicillin-binding protein required for cell division (12); Wag31, a homologue of the cell division protein DivIVA that regulates growth, morphology, and polar cell wall biosynthesis in mycobacteria (13); the β-ketoacyl acyl carrier protein synthase mtFabH, which participates in mycolic acid biosynthesis (9); the anti-anti-sigma factor Rv0516c (14); the alternate sigma factor SigH, which is a central regulator of the response to oxidative stress (15); as well as the essential mycobacterial chaperone GroEL1 (16).Therefore, a further characterization of STPKs substrates is critical to unraveling the mechanisms by which STPK-dependent phosphorylation induces modifications, thus regulating their activity, ultimately conditioning biological responses in mycobacteria. Such studies may also provide the key to designing new inhibitors that target signal transduction pathways specific to M. tb.We recently characterized a novel substrate/kinase pair in M. tb, PknL/Rv2175c (17). pknL is associated with the ∼30-kb dcw (division cell wall) gene cluster, which encompasses several genes involved in cell wall synthesis and cell division (17, 18), raising the possibility that PknL might participate in the regulation of this gene cluster. Moreover, pknL (Rv2176) is adjacent to the Rv2175c gene, encoding a 16-kDa protein of unknown function. We further demonstrated that phosphorylation of the activation loop Thr-173 residue was required for optimal PknL-mediated phosphorylation of Rv2175c. Moreover, Rv2175c belongs to a mycobacterial “core” of 219 genes, identified by macroarray and bioinformatic analysis, common to M. tb- and Mycobacterium leprae-encoding proteins showing no similarity with proteins from other organisms. The presence of Rv2175c as a member of this set of genes emphasizes the importance of Rv2175c in the physiology of M. tb. In this context, we reasoned that the structural determination of Rv2175c would provide a valuable basis for a better understanding of the function of this protein.Therefore, we have undertaken the structural determination of Rv2175 using multidimensional NMR techniques. Herein, we provide strong evidence that Rv2175c is a DNA-binding protein and investigated how phosphorylation of a unique Thr residue in the N-terminal domain of the protein affects its DNA-binding activity.     

Role of Mycobacterium tuberculosis Ser/Thr kinase PknF: implications in glucose transport and cell division

Protein kinases have a diverse array of functions in bacterial physiology, with a distinct role in the regulation of development, stress responses, and pathogenicity. pknF, one of the 11 kinases of Mycobacterium tuberculosis, encodes an autophosphorylating, transmembrane serine/threonine protein kinase, which is absent in the fast-growing, nonpathogenic Mycobacterium smegmatis. Herein, we investigate the physiological role of PknF using an antisense strategy with M. tuberculosis and expressing PknF and its kinase mutant (K41M) in M. smegmatis. Expression of PknF in M. smegmatis led to reduction in the growth rate and shortening and swelling of cells with constrictions. Interestingly, an antisense strain of M. tuberculosis expressing a low level of PknF displayed fast growth and a deformed cell morphology compared to the wild-type strain. Electron microscopy showed that most of the cells of the antisense strain were of a smaller size with an aberrant septum. Furthermore, nutrient transport analysis of these strains was conducted using 3H-labeled and 14C-labeled substrates. A significant increase in the uptake of D-glucose but not of glycerol, leucine, or oleic acid was observed in the antisense strain compared to the wild-type strain. The results suggest that PknF plays a direct/indirect role in the regulation of glucose transport, cell growth, and septum formation in M. tuberculosis.     

肺炎衣原体蛋白激酶Cpn0148的克隆表达和定位

目前认为肺炎衣原体(Chlamydia pneumonia, Cpn)除导致呼吸道疾病外, 也是与冠心病相关的重要病原体。作为一种细胞内寄生的病原菌, Cpn激活宿主细胞信号通路, 维护其在细胞内生长代谢, 并导致疾病。肺炎衣原体基因Cpn0148可编码真核细胞样的丝/苏氨酸蛋白激酶, 利用PCR技术扩增全长Cpn0148 ORF, 将其定向插入pGEX-6p原核表达载体, 在大肠杆菌XL-1blue中表达, 测序显示Cpn0148 ORF全长1860 bp, 编码619个氨基酸, 分子量大约70 kD,     

In-Depth Characterization of the Clostridioides difficile Phosphoproteome to Identify Ser/Thr Kinase Substrates

Clostridioides difficile is the leading cause of postantibiotic diarrhea in adults. During infection, the bacterium must rapidly adapt to the host environment by using survival strategies. Protein phosphorylation is a reversible post-translational modification employed ubiquitously for signal transduction and cellular regulation. Hanks-type serine/threonine kinases (STKs) and serine/threonine phosphatases have emerged as important players in bacterial cell signaling and pathogenicity. C. difficile encodes two STKs (PrkC and CD2148) and one phosphatase. We optimized a titanium dioxide phosphopeptide enrichment approach to determine the phosphoproteome of C. difficile. We identified and quantified 2500 proteins representing 63% of the theoretical proteome. To identify STK and serine/threonine phosphatase targets, we then performed comparative large-scale phosphoproteomics of the WT strain and isogenic ΔprkC, CD2148, Δstp, and prkC CD2148 mutants. We detected 635 proteins containing phosphorylated peptides. We showed that PrkC is phosphorylated on multiple sites in vivo and autophosphorylates in vitro. We were unable to detect a phosphorylation for CD2148 in vivo, whereas this kinase was phosphorylated in vitro only in the presence of PrkC. Forty-one phosphoproteins were identified as phosphorylated under the control of CD2148, whereas 114 proteins were phosphorylated under the control of PrkC including 27 phosphoproteins more phosphorylated in the ?stp mutant. We also observed enrichment for phosphothreonine among the phosphopeptides more phosphorylated in the Δstp mutant. Both kinases targeted pathways required for metabolism, translation, and stress response, whereas cell division and peptidoglycan metabolism were more specifically controlled by PrkC-dependent phosphorylation in agreement with the phenotypes of the ΔprkC mutant. Using a combination of approaches, we confirmed that FtsK was phosphorylated in vivo under the control of PrkC and that Spo0A was a substrate of PrkC in vitro. This study provides a detailed mapping of kinase–substrate relationships in C. difficile, paving the way for the identification of new biomarkers and therapeutic targets.     

Phosphoproteomic Approaches to Discover Novel Substrates of Mycobacterial Ser/Thr Protein Kinases

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Highlights

• •Mapping kinase-substrate relationships is vital in discovering new tuberculosis drug targets.
• •LC-MS/MS-based phosphoproteomics expand mycobacterial STPK substrate catalogues.
• •We review and integrate MS-generated datasets on novel candidate substrates.
• •Validation studies are necessary to confirm true physiological substrates of STPKs.

     

Auto‐activation mechanism of the Mycobacterium tuberculosis PknB receptor Ser/Thr kinase

Many Ser/Thr protein kinases are activated by autophosphorylation, but the mechanism of this process has not been defined. We determined the crystal structure of a mutant of the Ser/Thr kinase domain (KD) of the mycobacterial sensor kinase PknB in complex with an ATP competitive inhibitor and discovered features consistent with an activation complex. The complex formed an asymmetric dimer, with the G helix and the ordered activation loop of one KD in contact with the G helix of the other. The activation loop of this putative ‘substrate’ KD was disordered, with the ends positioned at the entrance to the partner KD active site. Single amino‐acid substitutions in the G‐helix interface reduced activation‐loop phosphorylation, and multiple replacements abolished KD phosphorylation and kinase activation. Phosphorylation of an inactive mutant KD was reduced by G‐helix substitutions in both active and inactive KDs, as predicted by the idea that the asymmetric dimer mimics a trans‐autophosphorylation complex. These results support a model in which a structurally and functionally asymmetric, ‘front‐to‐front’ association mediates autophosphorylation of PknB and homologous kinases.     

Allosteric activation mechanism of the Mycobacterium tuberculosis receptor Ser/Thr protein kinase, PknB

The essential Mycobacterium tuberculosis Ser/Thr protein kinase (STPK), PknB, plays a key role in regulating growth and division, but the structural basis of activation has not been defined. Here, we provide biochemical and structural evidence that dimerization through the kinase-domain (KD) N-lobe activates PknB by an allosteric mechanism. Promoting KD pairing using a small-molecule dimerizer stimulates the unphosphorylated kinase, and substitutions that disrupt N-lobe pairing decrease phosphorylation activity in vitro and in vivo. Multiple crystal structures of two monomeric PknB KD mutants in complex with nucleotide reveal diverse inactive conformations that contain large active-site distortions that propagate > 30 ? from the mutation site. These results define flexible, inactive structures of a monomeric bacterial receptor KD and show how "back-to-back" N-lobe dimerization stabilizes the active KD conformation. This general mechanism of bacterial receptor STPK activation affords insights into the regulation of homologous eukaryotic kinases that form structurally similar dimers.     

Allosteric activation by dimerization of the PknD receptor Ser/Thr protein kinase from Mycobacterium tuberculosis

To define how extracellular signals activate bacterial receptor Ser/Thr protein kinases, we characterized the regulatory functions of a weak dimer interface identified in the Mycobacterium tuberculosis PknB and PknE receptor kinases. Sequence comparisons revealed that the analogous interface is conserved in PknD orthologs from diverse bacterial species. To analyze the roles of dimerization, we constructed M. tuberculosis PknD kinase domain (KD) fusion proteins that formed dimers upon addition of rapamycin. Dimerization of unphosphorylated M. tuberculosis PknD KD fusions stimulated phosphorylation activity. Mutations in the dimer interface reduced this activation, limited autophosphorylation, and altered substrate specificity. In contrast, an inactive catalytic site mutant retained the ability to stimulate the wild-type KD by dimerization. These results support the idea that dimer formation allosterically activates unphosphorylated PknD. The phosphorylated PknD KD was fully active even in the absence of dimerization, suggesting that phosphorylation provides an additional regulatory mechanism. The conservation of analogous dimers in diverse prokaryotic and eukaryotic Ser/Thr protein kinases implies that this mechanism of protein kinase regulation is ancient and broadly distributed.     

PPARGC1A基因Thr394Thr/Gly482Ser多态性与2型糖尿病的关联研究

对344例2型糖尿病患者和307名正常人的PPARGC1A基因单核苷酸多态性rs2970847(Thr394Thr)和rs8192678(Gly482Ser)与2型糖尿病的关系进行了单标记和单体型关联分析以及Logistic回归分析。在单标记分析中,对照组与病例组Thr394Thr的基因型和等位基因频率有显著差异(基因型, P =0.006; 等位基因, P < 0.001); Logistic回归和单体型分析表明, Thr394Thr的AA基因型及Thr394(ACA)-Ser482单体型增加患2型糖尿病的风险。Gly482Ser的基因型和等位基因频率在对照组与病例组间无显著差异。PPARGC1A基因是湖北汉人的一个2型糖尿病易感基因。     

丝/苏氨酸蛋白激酶Plk1研究进展

Plk1是一类从酵母到人类都高度保守的丝氨酸/苏氨酸蛋白激酶。Plk1与不同的细胞周期检查点的精密调控有关,从而确保了细胞周期事件按照严格的时间和顺序正常进行。Plk1在增殖活跃的细胞中呈高水平表达,Plk1的高度表达和肿瘤患者的低存活率之间具有显著的统计相关性。Plk1可能是非常有效的抗癌药物设计的靶点。     

Phosphorylation of Mycobacterium tuberculosis Ser/Thr phosphatase by PknA and PknB

Background

The integrated functions of 11 Ser/Thr protein kinases (STPKs) and one phosphatase manipulate the phosphorylation levels of critical proteins in Mycobacterium tuberculosis. In this study, we show that the lone Ser/Thr phosphatase (PstP) is regulated through phosphorylation by STPKs.

Principal Findings

PstP is phosphorylated by PknA and PknB and phosphorylation is influenced by the presence of Zn²⁺-ions and inorganic phosphate (Pi). PstP is differentially phosphorylated on the cytosolic domain with Thr¹³⁷, Thr¹⁴¹, Thr¹⁷⁴ and Thr²⁹⁰ being the target residues of PknB while Thr¹³⁷ and Thr¹⁷⁴ are phosphorylated by PknA. The Mn²⁺-ion binding residues Asp³⁸ and Asp²²⁹ are critical for the optimal activity of PstP and substitution of these residues affects its phosphorylation status. Native PstP and its phosphatase deficient mutant PstP_c ^D38G are phosphorylated by PknA and PknB in E. coli and addition of Zn²⁺/Pi in the culture conditions affect the phosphorylation level of PstP. Interestingly, the phosphorylated phosphatase is more active than its unphosphorylated equivalent.

Conclusions and Significance

This study establishes the novel mechanisms for regulation of mycobacterial Ser/Thr phosphatase. The results indicate that STPKs and PstP may regulate the signaling through mutually dependent mechanisms. Consequently, PstP phosphorylation may play a critical role in regulating its own activity. Since, the equilibrium between phosphorylated and non-phosphorylated states of mycobacterial proteins is still unexplained, understanding the regulation of PstP may help in deciphering the signal transduction pathways mediated by STPKs and the reversibility of the phenomena.     

Characterization of a membrane-linked Ser/Thr protein kinase in Bacillus subtilis,implicated in developmental processes

PrkC was shown to be a eukaryotic-like (Hanks-type) protein kinase from Bacillus subtilis with a structural organization similar to that of the eukaryotic sensor Ser/Thr or Tyr kinases (e.g. the TGF beta or PDGF receptors). The molecule consists of a catalytic domain located in the cytoplasm, joined by a single transmembrane-spanning region (TMD) to a large extracellular domain. Using a genetic reporter system, involving the cI repressor of lambda, evidence was obtained indicating that PrkC forms a dimer, involving both the TMD and the external domain in dimerization. The purified catalytic domain of PrkC was shown to autophosphorylate and to phosphorylate an external target, MBP, in both cases on threonine. These two functions require the completely conserved K40 residue in subdomain II, which is essential for enzymatic activity. Importantly, both the mutant deleted for prkC and a K40R mutant exhibit decreased efficiency of sporulation and a significant reduction in biofilm formation, demonstrating that the catalytic activity of PrkC is necessary for these two developmental processes. In addition, we showed that the product of prpC, a PPM phosphatase encoded by the adjacent gene, co-transcribed with prkC, is also required for normal biofilm and spore formation.     

酿酒酵母丝氨酸/苏氨酸蛋白磷酸酯酶的功能与调控

从酿酒酵母蛋白磷酸酯酶的分类和结构特征入手,阐述了该蛋白家族中的亚家族成员丝氨酸/苏氨酸蛋白磷酸酯酶的功能和表达调控.深入研究酿酒酵母丝氨酸/苏氨酸蛋白磷酸酯酶,特别是PP2C蛋白磷酸酯酶的细胞功能及其调控,将对新药研发和疾病干预治疗提供重要基础.     

Interdomain interaction reconstitutes the functionality of PknA, a eukaryotic type Ser/Thr kinase from Mycobacterium tuberculosis

Eukaryotic type Ser/Thr protein kinases have recently been shown to regulate a variety of cellular functions in bacteria. PknA, a transmembrane Ser/Thr protein kinase from Mycobacterium tuberculosis, when constitutively expressed in Escherichia coli resulted in cell elongation and therefore has been thought to be regulating morphological changes associated with cell division. Bioinformatic analysis revealed that PknA has N-terminal catalytic, juxtamembrane, transmembrane, and C-terminal extracellular domains, like known eukaryotic type Ser/Thr protein kinases from other bacteria. To identify the minimum region capable of exhibiting phosphorylation activity of PknA, we created several deletion mutants. Surprisingly, we found that the catalytic domain itself was not sufficient for exhibiting phosphorylation ability of PknA. However, the juxtamembrane region together with the kinase domain was necessary for the enzymatic activity and thus constitutes the catalytic core of PknA. Utilizing this core, we deduce that the autophosphorylation of PknA is an intermolecular event. Interestingly, the core itself was unable to restore the cell elongation phenotype as manifested by the full-length protein in E. coli; however, its co-expression along with the C-terminal region of PknA can associate them in trans to reconstitute a functional protein in vivo. Therefore, these findings argue that the transmembrane and extracellular domains of PknA, although dispensable for phosphorylation activities, are crucial in responding to signals. Thus, our results for the first time establish the significance of different domains in a bacterial eukaryotic type Ser/Thr kinase for reconstitution of its functionality.     

A conserved dimer and global conformational changes in the structure of apo-PknE Ser/Thr protein kinase from Mycobacterium tuberculosis

The "eukaryotic-like" receptor Ser/Thr protein kinases (STPKs) are candidates for the sensors that mediate environmental adaptations of Mycobacterium tuberculosis (Mtb). To define the mechanisms of regulation and substrate recognition, we determined the crystal structure of the ligand-free, activated kinase domain (KD) of the Mtb STPK, PknE. Remarkably, the PknE KD formed a dimer similar to that first observed in the structure of the ATPgammaS complex of the Mtb paralog, PknB. This structural similarity, which occurs despite little sequence conservation between the PknB and PknE dimer interfaces, supports the idea that dimerization regulates the Mtb receptor STPKs. Insertion of the DFG motif into the ATP-binding site and other conformational differences compared the ATPgammaS:PknB complex suggest that apo-PknE is not pre-organized to bind nucleotides. This structure may represent an inactive conformation stabilized by dimerization or, alternatively, an active conformation that reveals shifts that mediate nucleotide exchange and order substrate binding.