Litcius/Paper detail

Exact distributions for stochastic gene expression models with arbitrary promoter architecture and translational bursting

Meiling Chen, Songhao Luo, Mengfang Cao, Chengjun Guo, Tianshou Zhou, Jiajun Zhang

2022Physical review. E23 citationsDOI

Abstract

Gene expression in individual cells is inherently variable and sporadic, leading to cell-to-cell variability in mRNA and protein levels. Recent single-cell and single-molecule experiments indicate that promoter architecture and translational bursting play significant roles in controlling gene expression noise and generating the phenotypic diversity that life exhibits. To quantitatively understand the impact of these factors, it is essential to construct an accurate mathematical description of stochastic gene expression and find the exact analytical results, which is a formidable task. Here, we develop a stochastic model of bursty gene expression, which considers the complex promoter architecture governing the variability in mRNA expression and a general distribution characterizing translational burst. We derive the analytical expression for the corresponding protein steady-state distribution and all moment statistics of protein counts. We show that the total protein noise can be decomposed into three parts: the low-copy noise of protein due to probabilistic individual birth and death events, the noise due to stochastic switching between promoter states, and the noise resulting from translational busting. The theoretical results derived provide quantitative insights into the biochemical mechanisms of stochastic gene expression.

Topics & Concepts

BurstingNoise (video)Gene expressionStochastic modellingExpression (computer science)GeneBiologyComputational biologyMessenger RNAStochastic processRegulation of gene expressionPhysicsStatistical physicsGeneticsComputer scienceMathematicsStatisticsNeuroscienceArtificial intelligenceImage (mathematics)Programming languageGene Regulatory Network AnalysisEvolution and Genetic DynamicsSingle-cell and spatial transcriptomics