DocumentCode
1256998
Title
Multiparameter Spectral Representation of Noise-Induced Competence in Bacillus Subtilis
Author
Sargsyan, K. ; Safta, Cosmin ; Debusschere, B. ; Najm, H.
Author_Institution
Sandia Nat. Labs., Livermore, CA, USA
Volume
9
Issue
6
fYear
2012
Firstpage
1709
Lastpage
1723
Abstract
In this work, the problem of representing a stochastic forward model output with respect to a large number of input parameters is considered. The methodology is applied to a stochastic reaction network of competence dynamics in Bacillus subtilis bacterium. In particular, the dependence of the competence state on rate constants of underlying reactions is investigated. We base our methodology on Polynomial Chaos (PC) spectral expansions that allow effective propagation of input parameter uncertainties to outputs of interest. Given a number of forward model training runs at sampled input parameter values, the PC modes are estimated using a Bayesian framework. As an outcome, these PC modes are described with posterior probability distributions. The resulting expansion can be regarded as an uncertain response function and can further be used as a computationally inexpensive surrogate instead of the original reaction model for subsequent analyses such as calibration or optimization studies. Furthermore, the methodology is enhanced with a classification-based mixture PC formulation that overcomes the difficulties associated with representing potentially nonsmooth input-output relationships. Finally, the global sensitivity analysis based on the multiparameter spectral representation of an observable of interest provides biological insight and reveals the most important reactions and their couplings for the competence dynamics.
Keywords
belief networks; biological techniques; biology computing; chaos; microorganisms; optimisation; stochastic processes; Bacillus subtilis bacterium; Bayesian framework; PC mode; calibration; classification-based mixture PC formulation; global sensitivity analysis; multiparameter spectral representation; noise-induced competence; optimization; polynomial chaos spectral expansion; posterior probability distribution; reaction model; stochastic forward model output; stochastic reaction network; Bioinformatics; Computational biology; Computational modeling; Response surface methodology; Stochastic processes; Uncertainty; Approximation; probability and statistics; spectral methods; Bacillus subtilis; Bayes Theorem; Computational Biology; DNA Transformation Competence; Models, Biological; Models, Statistical; Stochastic Processes;
fLanguage
English
Journal_Title
Computational Biology and Bioinformatics, IEEE/ACM Transactions on
Publisher
ieee
ISSN
1545-5963
Type
jour
DOI
10.1109/TCBB.2012.107
Filename
6257362
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