Multisystem Analysis of Mycobacterium tuberculosis Reveals Kinase-Dependent Remodeling of the Pathogen-Environment Interface

ABSTRACT Tuberculosis is the leading killer among infectious diseases worldwide. Increasing multidrug resistance has prompted new approaches for tuberculosis drug development, including targeted inhibition of virulence determinants and of signaling cascades that control many downstream pathways. We used a multisystem approach to determine the effects of a potent small-molecule inhibitor of the essential Mycobacterium tuberculosis Ser/Thr protein kinases PknA and PknB. We observed differential levels of phosphorylation of many proteins and extensive changes in levels of gene expression, protein abundance, cell wall lipids, and intracellular metabolites. The patterns of these changes indicate regulation by PknA and PknB of several pathways required for cell growth, including ATP synthesis, DNA synthesis, and translation. These data also highlight effects on pathways for remodeling of the mycobacterial cell envelope via control of peptidoglycan turnover, lipid content, a SigE-mediated envelope stress response, transmembrane transport systems, and protein secretion systems. Integrated analysis of phosphoproteins, transcripts, proteins, and lipids identified an unexpected pathway whereby threonine phosphorylation of the essential response regulator MtrA decreases its DNA binding activity. Inhibition of this phosphorylation is linked to decreased expression of genes for peptidoglycan turnover, and of genes for mycolyl transferases, with concomitant changes in mycolates and glycolipids in the cell envelope. These findings reveal novel roles for PknA and PknB in regulating multiple essential cell functions and confirm that these kinases are potentially valuable targets for new antituberculosis drugs. In addition, the data from these linked multisystems provide a valuable resource for future targeted investigations into the pathways regulated by these kinases in the M. tuberculosis cell. IMPORTANCE Tuberculosis is the leading killer among infectious diseases worldwide. Increasing drug resistance threatens efforts to control this epidemic; thus, new antitubercular drugs are urgently needed. We performed an integrated, multisystem analysis of Mycobacterium tuberculosis responses to inhibition of its two essential serine/threonine protein kinases. These kinases allow the bacterium to adapt to its environment by phosphorylating cellular proteins in response to extracellular signals. We identified differentially phosphorylated proteins, downstream changes in levels of specific mRNA and protein abundance, and alterations in the metabolite and lipid content of the cell. These results include changes previously linked to growth arrest and also reveal new roles for these kinases in regulating essential processes, including growth, stress responses, transport of proteins and other molecules, and the structure of the mycobacterial cell envelope. Our multisystem data identify PknA and PknB as promising targets for drug development and provide a valuable resource for future investigation of their functions. IMPORTANCE Tuberculosis is the leading killer among infectious diseases worldwide. Increasing drug resistance threatens efforts to control this epidemic; thus, new antitubercular drugs are urgently needed. We performed an integrated, multisystem analysis of Mycobacterium tuberculosis responses to inhibition of its two essential serine/threonine protein kinases. These kinases allow the bacterium to adapt to its environment by phosphorylating cellular proteins in response to extracellular signals. We identified differentially phosphorylated proteins, downstream changes in levels of specific mRNA and protein abundance, and alterations in the metabolite and lipid content of the cell. These results include changes previously linked to growth arrest and also reveal new roles for these kinases in regulating essential processes, including growth, stress responses, transport of proteins and other molecules, and the structure of the mycobacterial cell envelope. Our multisystem data identify PknA and PknB as promising targets for drug development and provide a valuable resource for future investigation of their functions.

[1]  G. Bemis,et al.  Mtb PKNA/PKNB Dual Inhibition Provides Selectivity Advantages for Inhibitor Design To Minimize Host Kinase Interactions. , 2017, ACS medicinal chemistry letters.

[2]  Wonsik Lee,et al.  Rv3723/LucA coordinates fatty acid and cholesterol uptake in Mycobacterium tuberculosis , 2017, bioRxiv.

[3]  G. Poce,et al.  MmpL3 is the flippase for mycolic acids in mycobacteria , 2017, Proceedings of the National Academy of Sciences.

[4]  D. Sharma,et al.  A Serine/threonine kinase PknL, is involved in the adaptive response of Mycobacterium tuberculosis. , 2016, Microbiological research.

[5]  A. Kruse,et al.  SEDS proteins are a widespread family of bacterial cell wall polymerases , 2016, Nature.

[6]  A. Singh,et al.  Investigating essential gene function in Mycobacterium tuberculosis using an efficient CRISPR interference system , 2016, Nucleic acids research.

[7]  M. Chase,et al.  A cytoplasmic peptidoglycan amidase homologue controls mycobacterial cell wall synthesis , 2016, eLife.

[8]  K. Bassler,et al.  Reconstruction and topological characterization of the sigma factor regulatory network of Mycobacterium tuberculosis , 2016, Nature Communications.

[9]  S. Cole,et al.  Genomic and transcriptomic analysis of the streptomycin-dependent Mycobacterium tuberculosis strain 18b , 2016, BMC Genomics.

[10]  J. Velarde,et al.  NAD+-Glycohydrolase Promotes Intracellular Survival of Group A Streptococcus , 2016, PLoS pathogens.

[11]  N. Soares,et al.  Mass Spectrometry Offers Insight into the Role of Ser/Thr/Tyr Phosphorylation in the Mycobacteria , 2016, Front. Microbiol..

[12]  Jonathan W. Cruz,et al.  tRNA is a new target for cleavage by a MazF toxin , 2016, Nucleic acids research.

[13]  M. Clausen,et al.  Small-molecule kinase inhibitors: an analysis of FDA-approved drugs. , 2016, Drug discovery today.

[14]  Q. Jin,et al.  Phosphoproteomic analysis of bacillus Calmette-Guérin using gel-based and gel-free approaches. , 2015, Journal of proteomics.

[15]  Pratik Datta,et al.  The Psp system of Mycobacterium tuberculosis integrates envelope stress‐sensing and envelope‐preserving functions , 2015, Molecular microbiology.

[16]  A. Steyn,et al.  Regulation of Ergothioneine Biosynthesis and Its Effect on Mycobacterium tuberculosis Growth and Infectivity* , 2015, The Journal of Biological Chemistry.

[17]  J. Basu,et al.  MtrA, an essential response regulator of the MtrAB two-component system, regulates the transcription of resuscitation-promoting factor B of Mycobacterium tuberculosis. , 2015, Microbiology.

[18]  Ruedi Aebersold,et al.  Using data‐independent, high‐resolution mass spectrometry in protein biomarker research: Perspectives and clinical applications , 2015, Proteomics. Clinical applications.

[19]  Sathya Narayanan Nagarajan,et al.  Protein Kinase A (PknA) of Mycobacterium tuberculosis Is Independently Activated and Is Critical for Growth in Vitro and Survival of the Pathogen in the Host* , 2015, The Journal of Biological Chemistry.

[20]  Nagarjuna Nagaraj,et al.  Phosphoproteomics analysis of a clinical Mycobacterium tuberculosis Beijing isolate: expanding the mycobacterial phosphoproteome catalog , 2015, Front. Microbiol..

[21]  Matthew E. Ritchie,et al.  limma powers differential expression analyses for RNA-sequencing and microarray studies , 2015, Nucleic acids research.

[22]  Nathan D. Price,et al.  The DNA-binding network of Mycobacterium tuberculosis , 2015, Nature Communications.

[23]  Heiner Koch,et al.  Comprehensive and Reproducible Phosphopeptide Enrichment Using Iron Immobilized Metal Ion Affinity Chromatography (Fe-IMAC) Columns , 2014, Molecular & Cellular Proteomics.

[24]  B. G. Davis,et al.  The Three Mycobacterium tuberculosis Antigen 85 Isoforms Have Unique Substrates and Activities Determined by Non-active Site Regions* , 2014, The Journal of Biological Chemistry.

[25]  C. Nathan,et al.  Isocitrate lyase mediates broad antibiotic tolerance in Mycobacterium tuberculosis , 2014, Nature Communications.

[26]  Richard S. Rogers,et al.  Mycobacterium tuberculosis supports protein tyrosine phosphorylation , 2014, Proceedings of the National Academy of Sciences.

[27]  C. Vilchèze,et al.  Phosphorylation of KasB Regulates Virulence and Acid-Fastness in Mycobacterium tuberculosis , 2014, PLoS pathogens.

[28]  Sathya Narayanan Nagarajan,et al.  Protein Kinase B (PknB) of Mycobacterium tuberculosis Is Essential for Growth of the Pathogen in Vitro as well as for Survival within the Host* , 2014, The Journal of Biological Chemistry.

[29]  K. Rhee,et al.  Methylcitrate cycle defines the bactericidal essentiality of isocitrate lyase for survival of Mycobacterium tuberculosis on fatty acids , 2014, Proceedings of the National Academy of Sciences.

[30]  Jason T. Huff,et al.  Role of the Mce1 transporter in the lipid homeostasis of Mycobacterium tuberculosis. , 2014, Tuberculosis.

[31]  D. Sherman,et al.  Mycobacterium tuberculosis Ser/Thr Protein Kinase B Mediates an Oxygen-Dependent Replication Switch , 2014, PLoS biology.

[32]  Yan Zhang,et al.  PATRIC, the bacterial bioinformatics database and analysis resource , 2013, Nucleic Acids Res..

[33]  Wei Shi,et al.  featureCounts: an efficient general purpose program for assigning sequence reads to genomic features , 2013, Bioinform..

[34]  K. Sarva,et al.  Mycobacterium tuberculosis MtrAY102C is a gain-of-function mutant that potentially acts as a constitutively active protein. , 2013, Tuberculosis.

[35]  P. Alzari,et al.  GarA is an essential regulator of metabolism in Mycobacterium tuberculosis , 2013, Molecular microbiology.

[36]  M. Pop,et al.  Robust methods for differential abundance analysis in marker gene surveys , 2013, Nature Methods.

[37]  H. Steen,et al.  iFASP: combining isobaric mass tagging with filter-aided sample preparation. , 2013, Journal of proteome research.

[38]  Yves Van de Peer,et al.  The Mycobacterium tuberculosis regulatory network and hypoxia , 2013, Nature.

[39]  N. Woychik,et al.  Mycobacterial toxin MazF-mt6 inhibits translation through cleavage of 23S rRNA at the ribosomal A site , 2013, Proceedings of the National Academy of Sciences.

[40]  K. Rhee,et al.  Multifunctional essentiality of succinate metabolism in adaptation to hypoxia in Mycobacterium tuberculosis , 2013, Proceedings of the National Academy of Sciences.

[41]  Thomas R. Gingeras,et al.  STAR: ultrafast universal RNA-seq aligner , 2013, Bioinform..

[42]  K. Sarva,et al.  Septal Localization of the Mycobacterium tuberculosis MtrB Sensor Kinase Promotes MtrA Regulon Expression* , 2012, The Journal of Biological Chemistry.

[43]  C. Bertozzi,et al.  Cholesterol catabolism by Mycobacterium tuberculosis requires transcriptional and metabolic adaptations. , 2012, Chemistry & biology.

[44]  C. Gee,et al.  A Phosphorylated Pseudokinase Complex Controls Cell Wall Synthesis in Mycobacteria , 2012, Science Signaling.

[45]  D. Moody,et al.  A comparative lipidomics platform for chemotaxonomic analysis of Mycobacterium tuberculosis. , 2011, Chemistry & biology.

[46]  Daniel Schwartz,et al.  Biological sequence motif discovery using motif-x. , 2011, Current protocols in bioinformatics.

[47]  R. Husson,et al.  The Extracytoplasmic Domain of the Mycobacterium tuberculosis Ser/Thr Kinase PknB Binds Specific Muropeptides and Is Required for PknB Localization , 2011, PLoS pathogens.

[48]  S. Peterson,et al.  A novel copper‐responsive regulon in Mycobacterium tuberculosis , 2011, Molecular microbiology.

[49]  M. Bott,et al.  Target Genes, Consensus Binding Site, and Role of Phosphorylation for the Response Regulator MtrA of Corynebacterium glutamicum , 2010, Journal of bacteriology.

[50]  Gulcin Gulten,et al.  Phosphorylation of InhA inhibits mycolic acid biosynthesis and growth of Mycobacterium tuberculosis , 2010, Molecular microbiology.

[51]  Sabine Ehrt,et al.  Metabolomics of Mycobacterium tuberculosis reveals compartmentalized co-catabolism of carbon substrates. , 2010, Chemistry and Biology.

[52]  Belinda Phipson,et al.  Opposing roles of polycomb repressive complexes in hematopoietic stem and progenitor cells. , 2010, Blood.

[53]  George M. Church,et al.  Extensive phosphorylation with overlapping specificity by Mycobacterium tuberculosis serine/threonine protein kinases , 2010, Proceedings of the National Academy of Sciences.

[54]  M. Madiraju,et al.  Mycobacterium tuberculosis Origin of Replication and the Promoter for Immunodominant Secreted Antigen 85B Are the Targets of MtrA, the Essential Response Regulator* , 2010, The Journal of Biological Chemistry.

[55]  L. Kremer,et al.  Phosphorylation of the Mycobacterium tuberculosis β-Ketoacyl-Acyl Carrier Protein Reductase MabA Regulates Mycolic Acid Biosynthesis* , 2010, The Journal of Biological Chemistry.

[56]  Mark D. Robinson,et al.  edgeR: a Bioconductor package for differential expression analysis of digital gene expression data , 2009, Bioinform..

[57]  S. Howell,et al.  An Intramolecular Switch Regulates Phosphoindependent FHA Domain Interactions in Mycobacterium tuberculosis , 2009, Science Signaling.

[58]  J. Dworkin,et al.  A Eukaryotic-like Ser/Thr Kinase Signals Bacteria to Exit Dormancy in Response to Peptidoglycan Fragments , 2008, Cell.

[59]  Christopher M. Sassetti,et al.  Mycobacterial persistence requires the utilization of host cholesterol , 2008, Proceedings of the National Academy of Sciences.

[60]  J. Suh,et al.  Wag31, a homologue of the cell division protein DivIVA, regulates growth, morphology and polar cell wall synthesis in mycobacteria. , 2008, Microbiology.

[61]  Martin Cohen-Gonsaud,et al.  The Mycobacterium tuberculosis serine/threonine kinase PknL phosphorylates Rv2175c: Mass spectrometric profiling of the activation loop phosphorylation sites and their role in the recruitment of Rv2175c , 2008, Proteomics.

[62]  Tige R. Rustad,et al.  The Enduring Hypoxic Response of Mycobacterium tuberculosis , 2008, PloS one.

[63]  G. Puzo,et al.  6 Structure, Biosynthesis, and Activities of the Phosphatidyl-myo-Inositol-Based Lipoglycans , 2008 .

[64]  Marco Bellinzoni,et al.  Mycobacterial Ser/Thr protein kinases and phosphatases: physiological roles and therapeutic potential. , 2008, Biochimica et biophysica acta.

[65]  D. Russell,et al.  Mycobacterium tuberculosis invasion of macrophages: linking bacterial gene expression to environmental cues. , 2007, Cell host & microbe.

[66]  T. Terwilliger,et al.  Domain orientation in the inactive response regulator Mycobacterium tuberculosis MtrA provides a barrier to activation. , 2007, Biochemistry.

[67]  F. Berven,et al.  Comprehensive analysis of exported proteins from Mycobacterium tuberculosis H37Rv , 2007, Proteomics.

[68]  Tom Alber,et al.  M. tuberculosis Ser/Thr Protein Kinase D Phosphorylates an Anti-Anti–Sigma Factor Homolog , 2007, PLoS pathogens.

[69]  Tong Liu,et al.  CsoR is a novel Mycobacterium tuberculosis copper-sensing transcriptional regulator. , 2007, Nature chemical biology.

[70]  Matthew J. Brauer,et al.  Conservation of the metabolomic response to starvation across two divergent microbes , 2006, Proceedings of the National Academy of Sciences.

[71]  Raymond L. Hovey,et al.  MprAB Is a Stress-Responsive Two-Component System That Directly Regulates Expression of Sigma Factors SigB and SigE in Mycobacterium tuberculosis , 2006, Journal of bacteriology.

[72]  R. Abagyan,et al.  XCMS: processing mass spectrometry data for metabolite profiling using nonlinear peak alignment, matching, and identification. , 2006, Analytical chemistry.

[73]  L. Cantley,et al.  The Mycobacterium tuberculosis serine/threonine kinases PknA and PknB: substrate identification and regulation of cell shape. , 2005, Genes & development.

[74]  Sahadevan Raman,et al.  Transcription Regulation by the Mycobacterium tuberculosis Alternative Sigma Factor SigD and Its Role in Virulence , 2004, Journal of bacteriology.

[75]  T. Myers,et al.  The Transcriptional Responses of Mycobacterium tuberculosis to Inhibitors of Metabolism , 2004, Journal of Biological Chemistry.

[76]  G. Altavilla,et al.  The Extra Cytoplasmic Function Sigma Factor σE Is Essential for Mycobacterium tuberculosis Virulence in Mice , 2004, Infection and Immunity.

[77]  E. Rubin,et al.  Genes required for mycobacterial growth defined by high density mutagenesis , 2003, Molecular microbiology.

[78]  Claudine Médigue,et al.  Re-annotation of the genome sequence of Mycobacterium tuberculosis H37Rv. , 2002, Microbiology.

[79]  J. Betts,et al.  Evaluation of a nutrient starvation model of Mycobacterium tuberculosis persistence by gene and protein expression profiling , 2002, Molecular microbiology.

[80]  Y Av-Gay,et al.  The eukaryotic-like Ser/Thr protein kinases of Mycobacterium tuberculosis. , 2000, Trends in microbiology.

[81]  L. Collins,et al.  Microplate alamar blue assay versus BACTEC 460 system for high-throughput screening of compounds against Mycobacterium tuberculosis and Mycobacterium avium , 1997, Antimicrobial agents and chemotherapy.

[82]  T. Hunter,et al.  The eukaryotic protein kinase superfamily: kinase (catalytic) domain structure and classification 1 , 1995, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[83]  C. Walsh,et al.  The behavior and significance of slow-binding enzyme inhibitors. , 2006, Advances in enzymology and related areas of molecular biology.

[84]  熊礼宽,et al.  Mycobacterium , 1977, Bacteriological reviews.