Gabriele Lillacci1, Mustafa Khammash. 1. ETH Zürich, Department of Biosystems Science and Engineering, Mattenstrasse 26, 4058, Basel, Switzerland.
Abstract
MOTIVATION: In the noisy cellular environment, stochastic fluctuations at the molecular level manifest as cell-cell variability at the population level that is quantifiable using high-throughput single-cell measurements. Such variability is rich with information about the cell's underlying gene regulatory networks, their architecture and the parameters of the biochemical reactions at their core. RESULTS: We report a novel method, called Inference for Networks of Stochastic Interactions among Genes using High-Throughput data (INSIGHT), for systematically combining high-throughput time-course flow cytometry measurements with computer-generated stochastic simulations of candidate gene network models to infer the network's stochastic model and all its parameters. By exploiting the mathematical relationships between experimental and simulated population histograms, INSIGHT achieves scalability, efficiency and accuracy while entirely avoiding approximate stochastic methods. We demonstrate our method on a synthetic gene network in bacteria and show that a detailed mechanistic model of this network can be estimated with high accuracy and high efficiency. Our method is completely general and can be used to infer models of signal-activated gene networks in any organism based solely on flow cytometry data and stochastic simulations. AVAILABILITY: A free C source code implementing the INSIGHT algorithm, together with test data is available from the authors. CONTACT: mustafa.khammash@bsse.ethz.ch SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
MOTIVATION: In the noisy cellular environment, stochastic fluctuations at the molecular level manifest as cell-cell variability at the population level that is quantifiable using high-throughput single-cell measurements. Such variability is rich with information about the cell's underlying gene regulatory networks, their architecture and the parameters of the biochemical reactions at their core. RESULTS: We report a novel method, called Inference for Networks of Stochastic Interactions among Genes using High-Throughput data (INSIGHT), for systematically combining high-throughput time-course flow cytometry measurements with computer-generated stochastic simulations of candidate gene network models to infer the network's stochastic model and all its parameters. By exploiting the mathematical relationships between experimental and simulated population histograms, INSIGHT achieves scalability, efficiency and accuracy while entirely avoiding approximate stochastic methods. We demonstrate our method on a synthetic gene network in bacteria and show that a detailed mechanistic model of this network can be estimated with high accuracy and high efficiency. Our method is completely general and can be used to infer models of signal-activated gene networks in any organism based solely on flow cytometry data and stochastic simulations. AVAILABILITY: A free C source code implementing the INSIGHT algorithm, together with test data is available from the authors. CONTACT: mustafa.khammash@bsse.ethz.ch SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.
Authors: Jameson K Rogers; Christopher D Guzman; Noah D Taylor; Srivatsan Raman; Kelley Anderson; George M Church Journal: Nucleic Acids Res Date: 2015-07-07 Impact factor: 16.971
Authors: Jakob Ruess; Francesca Parise; Andreas Milias-Argeitis; Mustafa Khammash; John Lygeros Journal: Proc Natl Acad Sci U S A Date: 2015-06-17 Impact factor: 11.205