Motile bacteria regulate chemotaxis through a highly conserved chemosensory signal-transduction system. System-wide analyses and mathematical modeling are facilitated by extensive experimental observations regarding bacterial chemotaxis proteins, including biochemical parameters, protein structures and protein-protein interaction maps. Thousands of signaling and regulatory chemotaxis proteins within a bacteria cell form a highly interconnected network through distinct protein-protein interactions. A bacterial cell is able to respond to multiple stimuli through a collection of chemoreceptors with different sensory modalities, which interact to affect the cooperativity and sensitivity of the chemotaxis response. The robustness or insensitivity of the chemotaxis system to perturbations in biochemical parameters is a product of the system's hierarchical network architecture.
Curr. Opin. Microbiol.
Stock Lab Princeton University
Department of Molecular Biology 253 Lewis Thomas Laboratory Washington Road Princeton, NJ 08544
Faculty Assistant Gail Huber 252 Lewis Thomas Lab p: 609-258-1894 f: 609-258-2340 firstname.lastname@example.org