Cells are intrinsically noisy biochemical reactors: low reactant numbers can lead to significant statistical fluctuations in molecule numbers and reaction rates. Here we use an analytic model to investigate the emergent noise properties of genetic systems. We find for a single gene that noise is essentially determined at the translational level, and that the mean and variance of protein concentration can be independently controlled. The noise strength immediately following single gene induction is almost twice the final steady-state value. We find that fluctuations in the concentrations of a regulatory protein can propagate through a genetic cascade; translational noise control could explain the inefficient translation rates observed for genes encoding such regulatory proteins. For an autoregulatory protein, we demonstrate that negative feedback efficiently decreases system noise. The model can be used to predict the noise characteristics of networks of arbitrary connectivity. The general procedure is further illustrated for an autocatalytic protein and a bistable genetic switch. The analysis of intrinsic noise reveals biological roles of gene network structures and can lead to a deeper understanding of their evolutionary origin.
Description
Intrinsic noise in gene regulatory networks. [Proc Natl Acad Sci U S A. 2001] - PubMed result
%0 Journal Article
%1 thattai2001intrinsic
%A Thattai, M
%A van Oudenaarden, A
%D 2001
%J Proc Natl Acad Sci U S A
%K Fano_factor stochastic_transcription
%N 15
%P 8614-8619
%R 10.1073/pnas.151588598
%T Intrinsic noise in gene regulatory networks
%U http://www.ncbi.nlm.nih.gov/pubmed/11438714?dopt=abstract
%V 98
%X Cells are intrinsically noisy biochemical reactors: low reactant numbers can lead to significant statistical fluctuations in molecule numbers and reaction rates. Here we use an analytic model to investigate the emergent noise properties of genetic systems. We find for a single gene that noise is essentially determined at the translational level, and that the mean and variance of protein concentration can be independently controlled. The noise strength immediately following single gene induction is almost twice the final steady-state value. We find that fluctuations in the concentrations of a regulatory protein can propagate through a genetic cascade; translational noise control could explain the inefficient translation rates observed for genes encoding such regulatory proteins. For an autoregulatory protein, we demonstrate that negative feedback efficiently decreases system noise. The model can be used to predict the noise characteristics of networks of arbitrary connectivity. The general procedure is further illustrated for an autocatalytic protein and a bistable genetic switch. The analysis of intrinsic noise reveals biological roles of gene network structures and can lead to a deeper understanding of their evolutionary origin.
@article{thattai2001intrinsic,
abstract = {Cells are intrinsically noisy biochemical reactors: low reactant numbers can lead to significant statistical fluctuations in molecule numbers and reaction rates. Here we use an analytic model to investigate the emergent noise properties of genetic systems. We find for a single gene that noise is essentially determined at the translational level, and that the mean and variance of protein concentration can be independently controlled. The noise strength immediately following single gene induction is almost twice the final steady-state value. We find that fluctuations in the concentrations of a regulatory protein can propagate through a genetic cascade; translational noise control could explain the inefficient translation rates observed for genes encoding such regulatory proteins. For an autoregulatory protein, we demonstrate that negative feedback efficiently decreases system noise. The model can be used to predict the noise characteristics of networks of arbitrary connectivity. The general procedure is further illustrated for an autocatalytic protein and a bistable genetic switch. The analysis of intrinsic noise reveals biological roles of gene network structures and can lead to a deeper understanding of their evolutionary origin.},
added-at = {2010-10-20T05:54:56.000+0200},
author = {Thattai, M and van Oudenaarden, A},
biburl = {https://www.bibsonomy.org/bibtex/2bcf881fa1a0a703bd3f20cc69b1b76f5/peter.ralph},
description = {Intrinsic noise in gene regulatory networks. [Proc Natl Acad Sci U S A. 2001] - PubMed result},
doi = {10.1073/pnas.151588598},
interhash = {4b4005efc980a4e53d333d6efdeeccd1},
intrahash = {bcf881fa1a0a703bd3f20cc69b1b76f5},
journal = {Proc Natl Acad Sci U S A},
keywords = {Fano_factor stochastic_transcription},
month = jul,
number = 15,
pages = {8614-8619},
pmid = {11438714},
timestamp = {2010-10-20T05:54:56.000+0200},
title = {Intrinsic noise in gene regulatory networks},
url = {http://www.ncbi.nlm.nih.gov/pubmed/11438714?dopt=abstract},
volume = 98,
year = 2001
}