Project 2 will apply systems approaches to dissect the complex problem of TB disease progression in vivo, a first for the field. We first describe an innovative screening strategy to identify the MTB genes critical for disease progression in the lung. Previously we built a DNA binding/gene expression model that allows us to predict a regulon for every MTB transcription factor, and assembled a unique collection of MTB strains in which expression of every regulator is perturbed. We will use these strains to perturb every MTB gene regulatory network during aerosol infection of mouse lungs. Once key regulators are identified, we will quantitate and characterize the changes in infected cell types and determine the specific points in disease progression where particular mutants show altered responses. We then perform detailed systems analysis of the key genes and their predicted regulons using bone marrow macrophages infected ex vivo. We will collect host and MTB transcriptomes, MTB global protein level changes and condition-specific ChlP-seq on key MTB regulators from within matched samples of infected macrophages. These data will fuel modeling of both the bacterial and host response networks, predictions from which will drive a new round of mutant evaluation, omics-scale data collection and additional modeling. Our ultimate modeling Aim, a novel integrated host/MTB network model will be tested using samples from humans, with both candidate mutant bacteria and specific host genes modulated by siRNA. In recent years, we have contributed substantially to the infrastructure needed for systems biology, including the development of key tools for data generation, analysis and modeling. We have also made a strong start for systems analysis of MTB, producing predictive gene regulatory networks based on large-scale ChlP-seq and expression studies. This project combines separate advances in microbiology, transcriptomics, molecular genetics, ChlP-seq, proteomics and network modeling to produce an experimentally grounded and verifiable systems-level model of the MTB regulatory networks that affect disease progression.

Public Health Relevance

Mycobacterium tuberculosis causes ~9 million new cases of active disease and 1.4 million deaths each year, and our tools to combat tuberculosis (TB) disease are universally outdated and overmatched. This project combines separate advances in systems biology and network modeling to produce an experimentally grounded and verifiable systems-level model of the MTB regulatory networks that affect disease progression

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Program--Cooperative Agreements (U19)
Project #
5U19AI106761-05
Application #
9275350
Study Section
Special Emphasis Panel (ZAI1-EC-M)
Project Start
Project End
Budget Start
2017-06-01
Budget End
2018-05-31
Support Year
5
Fiscal Year
2017
Total Cost
$763,150
Indirect Cost
$356,809
Name
Seattle Biomedical Research Institute
Department
Type
Research Institutes
DUNS #
070967955
City
Seattle
State
WA
Country
United States
Zip Code
98109
Hansen, Scott G; Zak, Daniel E; Xu, Guangwu et al. (2018) Prevention of tuberculosis in rhesus macaques by a cytomegalovirus-based vaccine. Nat Med 24:130-143
Parihar, S P; Ozturk, M; Marakalala, M J et al. (2018) Protein kinase C-delta (PKC?), a marker of inflammation and tuberculosis disease progression in humans, is important for optimal macrophage killing effector functions and survival in mice. Mucosal Immunol 11:496-511
Cohen, Sara B; Gern, Benjamin H; Delahaye, Jared L et al. (2018) Alveolar Macrophages Provide an Early Mycobacterium tuberculosis Niche and Initiate Dissemination. Cell Host Microbe 24:439-446.e4
Thompson, Ethan G; Shankar, Smitha; Gideon, Hannah P et al. (2018) Prospective Discrimination of Controllers From Progressors Early After Low-Dose Mycobacterium tuberculosis Infection of Cynomolgus Macaques using Blood RNA Signatures. J Infect Dis 217:1318-1322
Boot, Maikel; van Winden, Vincent J C; Sparrius, Marion et al. (2017) Cell envelope stress in mycobacteria is regulated by the novel signal transduction ATPase IniR in response to trehalose. PLoS Genet 13:e1007131
Thompson, Ethan G; Du, Ying; Malherbe, Stephanus T et al. (2017) Host blood RNA signatures predict the outcome of tuberculosis treatment. Tuberculosis (Edinb) 107:48-58
Nicod, Charlotte; Banaei-Esfahani, Amir; Collins, Ben C (2017) Elucidation of host-pathogen protein-protein interactions to uncover mechanisms of host cell rewiring. Curr Opin Microbiol 39:7-15
Moguche, Albanus O; Musvosvi, Munyaradzi; Penn-Nicholson, Adam et al. (2017) Antigen Availability Shapes T Cell Differentiation and Function during Tuberculosis. Cell Host Microbe 21:695-706.e5
Banaei-Esfahani, Amir; Nicod, Charlotte; Aebersold, Ruedi et al. (2017) Systems proteomics approaches to study bacterial pathogens: application to Mycobacterium tuberculosis. Curr Opin Microbiol 39:64-72
Woodworth, J S; Cohen, S B; Moguche, A O et al. (2017) Subunit vaccine H56/CAF01 induces a population of circulating CD4 T cells that traffic into the Mycobacterium tuberculosis-infected lung. Mucosal Immunol 10:555-564

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