Abstract

Elucidating the structure and/or dynamics of gene regulatory networks from experimental data is a major goal of systems biology. Stochastic models have the potential to absorb noise, account for un-certainty, and help avoid data overfitting. Within the frame work of probabilistic polynomial dynamical systems, we present an algorithm for the reverse engineering of any gene regulatory network as a discrete, probabilistic polynomial dynamical system. The resulting stochastic model is assembled from all minimal models in the model space and the probability assignment is based on partitioning the model space according to the likeliness with which a minimal model explains the observed data. We used this method to identify stochastic models for two published synthetic network models. In both cases, the generated model retains the key features of the original model and compares favorably to the resulting models from other algorithms.[PUBLICATION ABSTRACT]

Details

Title
Probabilistic polynomial dynamical systems for reverse engineering of gene regulatory networks
Author
Dimitrova, Elena S; Mitra, Indranil; Jarrah, Abdul Salam
Pages
1-13
Section
Computational Systems Biology
Publication year
2011
Publication date
Jun 2011
Publisher
Springer Nature B.V.
ISSN
16874145
e-ISSN
16874153
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.1186/1687-4153-2011-1
ProQuest document ID
1314383179
Copyright
Springer International Publishing AG 2011