Biological Sciences Division
Investigating Infectious Disease Interactions
Multi-omics strategy gives systems-level insight toward Salmonella pathogenesis
Results: Researchers from Pacific Northwest National Laboratory and Oregon Health & Science University combined extensive ‘omics measurements with a novel computational network analysis approach to better understand the complex regulatory interactions in the pathogen Salmonella Typhimurium and identify virulence-related proteins that cause systemic infection in a host. Their results, which appeared in BMC Systems Biology, demonstrate the utility of this approach to infectious disease research and offer new biological insights that may lead to new prevention and treatment strategies.
Parallel transcriptomics and proteomics measurements of Salmonella wild-type and 14 mutant strains, each lacking a specific regulatory protein required for systemic infection, provided data for a systems approach to network analysis. From the resulting network predictions, the research team discovered proteins not previously known to be required for virulence. Additional cellular analysis revealed a subset of these bacterial proteins that were secreted into the host cytoplasm independent of the known Salmonella mechanisms for transporting virulence proteins into host cells
"Of particular interest, we identified two new virulence proteins that revealed a new class of secreted virulence proteins and that we are currently investigating," said PNNL scientist Dr. Charles Ansong, one of the investigators.
Why it matters: Salmonella is a leading cause of food-borne illness and is the culprit bacterium in high-profile food recalls, such as peanut butter in 2008/2009 and the current one of ground turkey that has led to 77 illnesses and one fatality reported in the United States to date. Systemic bacterial infections such as those caused by Salmonella are highly regulated and complex processes that include sophisticated offensive and defensive strategies by both pathogen and host that are orchestrated by virulence factors. Identifying the proteins required for Salmonella virulence is important for developing approaches to effectively combat persistent and adapting pathogens.
Association network inferred from integrated proteomic and transcriptomic data is shown at left. The functional cluster containing known virulence factors is shown in detail at right. Blue proteins are those with similar expression and abundance profiles relative to known virulence proteins that were validated.
Methods: The researchers used capillary liquid chromatography-mass spectrometry to extensively characterize proteins present in the Salmonella wild-type and mutant strains. Parallel whole-genome microarray analysis was used to determine the transcriptome in matched samples.
Acknowledgments. This work was supported by the National Institute of Allergy and Infectious Diseases (interagency agreement number Y1-AI-8401), the NIH National Center for Research Resources, and the U.S. Department of Energy Office of Biological and Environmental Research. Significant portions of this work were performed at EMSL, a DOE/BER national scientific user facility located at PNNL. The research team included Charles Ansong, Jason McDermott, Marina Gritsenko, Richard Smith and Joshua Adkins, all PNNL, and Hyunjin Yoon and Fred Heffron, OHSU.
Reference. Yoon H*, C Ansong*, JE McDermott, MA Gritsenko, RD Smith, F Heffron, and JN Adkins. 2011. "Systems analysis of multiple regulator perturbations allows discovery of virulence factors in Salmonella." BMC Systems Biology 5:100. DOI: 10.1186/1752-0509-5-100