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Main Authors: Jia, Chen, Qian, Hong, Zhang, Michael Q.
Format: Preprint
Published: 2019
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Online Access:https://arxiv.org/abs/1909.09769
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author Jia, Chen
Qian, Hong
Zhang, Michael Q.
author_facet Jia, Chen
Qian, Hong
Zhang, Michael Q.
contents Stochastic oscillations in individual cells are usually characterized by a non-monotonic power spectrum with an oscillatory autocorrelation function. Here we develop an analytical approach of stochastic oscillations in a minimal hybrid model of stochastic gene expression including promoter state switching, protein synthesis and degradation, as well as a genetic feedback loop. The oscillations observed in our model are noise-induced since the deterministic theory predicts stable fixed points. The autocorrelated function, power spectrum, and steady-state distribution of protein concentration fluctuations are computed in closed form without making any approximations. Using the exactly solvable model, we illustrate sustained oscillations as a circular motion along a stochastic hysteresis loop induced by gene state switching. A triphasic stochastic bifurcation upon the increasing strength of negative feedback is observed, which reveals how stochastic bursts evolve into stochastic oscillations. In our model, oscillations tend to occur when the protein is relatively stable and when gene switching is relatively slow. Translational bursting is found to enhance the robustness and broaden the region of stochastic oscillations. These results provide deeper insights into R. Thomas' two conjectures for single-cell gene expression kinetics.
format Preprint
id arxiv_https___arxiv_org_abs_1909_09769
institution arXiv
publishDate 2019
record_format arxiv
spellingShingle Exact power spectrum in a minimal hybrid model of stochastic gene expression oscillations
Jia, Chen
Qian, Hong
Zhang, Michael Q.
Molecular Networks
Chaotic Dynamics
Biological Physics
34A38, 60H10, 60J25, 92C40, 92B05
Stochastic oscillations in individual cells are usually characterized by a non-monotonic power spectrum with an oscillatory autocorrelation function. Here we develop an analytical approach of stochastic oscillations in a minimal hybrid model of stochastic gene expression including promoter state switching, protein synthesis and degradation, as well as a genetic feedback loop. The oscillations observed in our model are noise-induced since the deterministic theory predicts stable fixed points. The autocorrelated function, power spectrum, and steady-state distribution of protein concentration fluctuations are computed in closed form without making any approximations. Using the exactly solvable model, we illustrate sustained oscillations as a circular motion along a stochastic hysteresis loop induced by gene state switching. A triphasic stochastic bifurcation upon the increasing strength of negative feedback is observed, which reveals how stochastic bursts evolve into stochastic oscillations. In our model, oscillations tend to occur when the protein is relatively stable and when gene switching is relatively slow. Translational bursting is found to enhance the robustness and broaden the region of stochastic oscillations. These results provide deeper insights into R. Thomas' two conjectures for single-cell gene expression kinetics.
title Exact power spectrum in a minimal hybrid model of stochastic gene expression oscillations
topic Molecular Networks
Chaotic Dynamics
Biological Physics
34A38, 60H10, 60J25, 92C40, 92B05
url https://arxiv.org/abs/1909.09769