Biochemical complexity drives log-normal variation in genetic expression

Biochemical complexity drives log-normal variation in genetic expression

Cells exhibit a high degree of variation in levels of gene expression, even within otherwise homogeneous populations. The standard model to describe this variation centres on a gamma distribution driven by stochastic bursts of translation. Stochastic bursting, however, cannot account for the well-es...

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Bibliographic Details
Main Author: Jacob Beal
Format: Article
Language:English
Published: Wiley 2017-07-01
Series:Engineering Biology
Subjects:
genetics
cellular biophysics
gamma distribution
stochastic processes
biochemical complexity
log-normal variation
genetic expression
gene expression
stochastic bursting
transcriptional repressors
stochastically constrained distributions
Online Access:https://digital-library.theiet.org/content/journals/10.1049/enb.2017.0004
Description
Summary:Cells exhibit a high degree of variation in levels of gene expression, even within otherwise homogeneous populations. The standard model to describe this variation centres on a gamma distribution driven by stochastic bursts of translation. Stochastic bursting, however, cannot account for the well-established behaviour of strong transcriptional repressors. Instead, it can be shown that the very complexity of the biochemical processes involved in gene expression drives an emergent log-normal distribution of expression levels. Emergent log-normal distributions can account for the observed behaviour of transcriptional repressors, are still compatible with stochastically constrained distributions, and have important implications for both analysis of gene expression data and the engineering of biological organisms.
ISSN:2398-6182

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