1. TIGER: the universal biosensor
- Author
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Christian Massire, John Mcneil, Neill White, Rachael Melton, Raymond Ranken, Duane J. Knize, Cristina Ivy, Vanessa Zapp, Lendell L. Cummins, Mark W. Eshoo, Vivek Samant, Anjali Desai, Steven A. Hofstadler, Harold B. Levene, David Robbins, Kristin A. Sannes-Lowery, Amy Schink, Sheri Manalili, David J. Ecker, Yun Jiang, Thomas A. Hall, Greg Barrett-Wilt, Demetrius J. Walcott, Jared J. Drader, Emily Moradi, Rangarajan Sampath, James C. Hannis, Brian Libby, Lawrence B. Blyn, Feng Li, Karl Rudnick, and Jose R. Gutierrez
- Subjects
Biodefense ,biology ,Chemistry ,Outbreak ,Computational biology ,Condensed Matter Physics ,biology.organism_classification ,Bacillus anthracis ,Infectious disease (medical specialty) ,Biological warfare ,Emerging infectious disease ,Poxviridae ,Variola virus ,Physical and Theoretical Chemistry ,Instrumentation ,Spectroscopy - Abstract
In this work, we describe a strategy for the detection and characterization of microorganisms associated with a potential biological warfare attack or a natural outbreak of an emerging infectious disease. This approach, termed TIGER (Triangulation Identification for the Genetic Evaluation of Risks), relies on mass spectrometry-derived base composition signatures obtained from PCR amplification of broadly conserved regions of the microbial genome(s) in a sample. The sample can be derived from air filtration devices, clinical samples, or other sources. Core to this approach are “intelligent PCR primers” that target broadly conserved regions of microbial genomes that flank variable regions. This approach requires that high-performance mass measurements be made on PCR products in the 80–140 bp size range in a high-throughput, robust modality. As will be demonstrated, the concept is equally applicable to bacteria and viruses and could be further applied to fungi and protozoa. In addition to describing the fundamental strategy of this approach, several specific examples of TIGER are presented that illustrate the impact this approach could have on the way biological weapons attacks are detected and the way that the etiologies of infectious diseases are determined. The first example illustrates how any bacterial species might be identified, using Bacillus anthracis as the test agent. The second example demonstrates how DNA-genome viruses are identified using five members of Poxviridae family, whose members includes Variola virus, the agent responsible for smallpox. The third example demonstrates how RNA-genome viruses are identified using the Alphaviruses (VEE, WEE, and EEE) as representative examples. These examples illustrate how the TIGER technology can be applied to create a universal identification strategy for all pathogens, including those that infect humans, livestock, and plants.
- Published
- 2005
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