Abstract
The inherent stochasticity of gene expression in the context of regulatory networks profoundly influences the dynamics of the involved species. Mathematically speaking, the propagators which describe the evolution of such networks in time are typically defined as solutions of the corresponding chemical master equation (CME). However, it is not possible in general to obtain exact solutions to the CME in closed form, which is due largely to its high dimensionality. In the present article, we propose an analytical method for the efficient approximation of these propagators. We illustrate our method on the basis of two categories of stochastic models for gene expression that have been discussed in the literature. The requisite procedure consists of three steps: a probability-generating function is introduced which transforms the CME into (a system of) partial differential equations (PDEs); application of the method of characteristics then yields (a system of) ordinary differential equations (ODEs) which can be solved using dynamical systems techniques, giving closed-form expressions for the generating function; finally, propagator probabilities can be reconstructed numerically from these expressions via the Cauchy integral formula. The resulting ‘library’ of propagators lends itself naturally to implementation in a Bayesian parameter inference scheme, and can be generalised systematically to related categories of stochastic models beyond the ones considered here.
Highlights
1.1 MotivationUnderstanding the process of gene expression in the context of gene regulatory networks is indispensable for gaining insight into the fundamentals of numerous biological processes
We develop an analytical method for the efficient evaluation of time-dependent propagators in stochastic gene expression models, for arbitrary values of the model parameters
chemical master equation (CME) system → PDE system: We introduce a probability-generating function to convert the CME into a partial differential equations (PDEs)
Summary
1.1 MotivationUnderstanding the process of gene expression in the context of gene regulatory networks is indispensable for gaining insight into the fundamentals of numerous biological processes. Gene expression can be highly stochastic in nature, both in prokaryotic and in eukaryotic organisms; see e.g. the work by Elowitz et al (2002), Raj and Oudenaarden (2008), Shahrezaei and Swain (2008b), and the references therein. This inherent stochasticity has a profound influence on the dynamics of the involved species, in particular when their abundance is low. Gene expression is often appropriately described by stochastic models (Bressloff 2014; Karlebach and Shamir 2008; Thattai and Oudenaarden 2001; Wilkinson 2009). The processes of transcription, translation, and degradation are approximated by single rates
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