""""""""Noise"""""""" - random fluctuation of cellular components - is a fundamental aspect of life at the single cell level. Noise plays a dual role in biological systems: On the one hand, it allows cells to make random decisions biased by external conditions. For instance, by sporulating in response to stress individual cells make probabilistic 'bets'about their future environment. On the other hand, noise can interfere with developmental processes that depend on precise genetic regulation. Intracellular noise has recently been detected and quantified in simple synthetic circuits. Here we propose to analyze noise directly within natural genetic circuits that make probabilistic cell-fate decisions and undergo precise developmental processes. Bacillus subtilis presents a unique opportunity to do so: It uses well-characterized genetic circuits to probabilistically initiate the differentiation programs of competence and sporulation. It also undergoes a tightly-coordinated, noise-suppressing developmental process during sporulation. The goal of this research is to understand how B. subtilis gene circuits amplify noise to probabilistically regulate competence events and sporulation initiation, and how they suppress noise to generate an ordered sequence of events during sporulation. We will apply quantitative time-lapse fluorescent microscopy techniques to observe gene circuit dynamics in single cells, and 're-wire'circuits to test specific predictions. The overall approach will be driven by mathematical models of underlying gene circuits. We will specifically address three problems: (1) In the case of competence regulation, we will test the hypothesis that noise- driven excitability generates probabilistic and transient competence episodes. (2) In the case of sporulation initiation, we will test the hypothesis that nested positive feedback loops, together with noise, generate temporal variability in the decision to initiate sporulation. (3) In the developmental process of sporulation, we will determine how noise is suppressed in wild-type cells but determines the fate of partially penetrant (PP) mutants (mutants in which some cells successfully complete sporulation, while others die). The circuit-level strategies identified in this model system are likely to operate in more complex organisms that undergo differentiation and development. Relevance to Public Health: The spread of infectious diseases depends on probabilistic activation of alternative genetic programs, such as competence, sporulation, and antibiotic persistence in bacteria, and latency in viruses. This proposal will address the mechanism by which individual cells randomly enter these alternate states. In addition, the proposal will investigate the mechanisms leading to the partial penetrance (occurring only in some affected individuals) of mutations. Partial penetrance is also found in human diseases.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM079771-04
Application #
7769870
Study Section
Modeling and Analysis of Biological Systems Study Section (MABS)
Program Officer
Anderson, James J
Project Start
2007-02-01
Project End
2012-01-31
Budget Start
2010-02-01
Budget End
2011-01-31
Support Year
4
Fiscal Year
2010
Total Cost
$299,066
Indirect Cost
Name
California Institute of Technology
Department
Type
Schools of Arts and Sciences
DUNS #
009584210
City
Pasadena
State
CA
Country
United States
Zip Code
91125
Park, Jin; Dies, Marta; Lin, Yihan et al. (2018) Molecular Time Sharing through Dynamic Pulsing in Single Cells. Cell Syst 6:216-229.e15
Rosenthal, Adam Z; Qi, Yutao; Hormoz, Sahand et al. (2018) Metabolic interactions between dynamic bacterial subpopulations. Elife 7:
Antebi, Yaron E; Nandagopal, Nagarajan; Elowitz, Michael B (2017) An operational view of intercellular signaling pathways. Curr Opin Syst Biol 1:16-24
Lin, Yihan; Sohn, Chang Ho; Dalal, Chiraj K et al. (2015) Combinatorial gene regulation by modulation of relative pulse timing. Nature 527:54-8
Dalal, Chiraj K; Cai, Long; Lin, Yihan et al. (2014) Pulsatile dynamics in the yeast proteome. Curr Biol 24:2189-2194
Levine, Joe H; Elowitz, Michael B (2014) Polyphasic feedback enables tunable cellular timers. Curr Biol 24:R994-5
Young, Jonathan W; Locke, James C W; Elowitz, Michael B (2013) Rate of environmental change determines stress response specificity. Proc Natl Acad Sci U S A 110:4140-5
Levine, Joe H; Lin, Yihan; Elowitz, Michael B (2013) Functional roles of pulsing in genetic circuits. Science 342:1193-200
Levine, Joe H; Fontes, Michelle E; Dworkin, Jonathan et al. (2012) Pulsed feedback defers cellular differentiation. PLoS Biol 10:e1001252
Locke, James C W; Young, Jonathan W; Fontes, Michelle et al. (2011) Stochastic pulse regulation in bacterial stress response. Science 334:366-9

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