Ribosome Flow Model on a Ring

Alon Raveh; Yoram Zarai; Michael Margaliot; Tamir Tuller

doi:https://doi.org/10.1109/TCBB.2015.2418782

Ribosome Flow Model on a Ring

Alon Raveh, Yoram Zarai, Michael Margaliot, Tamir Tuller

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

The asymmetric simple exclusion process (ASEP) is an important model from statistical physics describing particles that hop randomly from one site to the next along an ordered lattice of sites, but only if the next site is empty. ASEP has been used to model and analyze numerous multiagent systems with local interactions including the flow of ribosomes along the mRNA strand. In ASEP with periodic boundary conditions a particle that hops from the last site returns to the first one. The mean field approximation of this model is referred to as the ribosome flow model on a ring (RFMR). The RFMR may be used to model both synthetic and endogenous gene expression regimes. We analyze the RFMR using the theory of monotone dynamical systems. We show that it admits a continuum of equilibrium points and that every trajectory converges to an equilibrium point. Furthermore, we show that it entrains to periodic transition rates between the sites. We describe the implications of the analysis results to understanding and engineering cyclic mRNA translation in-vitro and in-vivo.

Original language	English
Article number	7078877
Pages (from-to)	1429-1439
Number of pages	11
Journal	IEEE/ACM Transactions on Computational Biology and Bioinformatics
Volume	12
Issue number	6
DOIs	https://doi.org/10.1109/TCBB.2015.2418782
State	Published - 1 Nov 2015

Keywords

Monotone dynamical systems
asymmetric simple exclusion process
asymptotic stability
cyclic mRNA
entrainment
first integral
mRNA translation
mean field approximation
ribosome flow model

All Science Journal Classification (ASJC) codes

Biotechnology
Genetics
Applied Mathematics

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https://doi.org/10.1109/TCBB.2015.2418782

Cite this

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title = "Ribosome Flow Model on a Ring",

abstract = "The asymmetric simple exclusion process (ASEP) is an important model from statistical physics describing particles that hop randomly from one site to the next along an ordered lattice of sites, but only if the next site is empty. ASEP has been used to model and analyze numerous multiagent systems with local interactions including the flow of ribosomes along the mRNA strand. In ASEP with periodic boundary conditions a particle that hops from the last site returns to the first one. The mean field approximation of this model is referred to as the ribosome flow model on a ring (RFMR). The RFMR may be used to model both synthetic and endogenous gene expression regimes. We analyze the RFMR using the theory of monotone dynamical systems. We show that it admits a continuum of equilibrium points and that every trajectory converges to an equilibrium point. Furthermore, we show that it entrains to periodic transition rates between the sites. We describe the implications of the analysis results to understanding and engineering cyclic mRNA translation in-vitro and in-vivo.",

keywords = "Monotone dynamical systems, asymmetric simple exclusion process, asymptotic stability, cyclic mRNA, entrainment, first integral, mRNA translation, mean field approximation, ribosome flow model",

author = "Alon Raveh and Yoram Zarai and Michael Margaliot and Tamir Tuller",

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AU - Raveh, Alon

AU - Zarai, Yoram

AU - Margaliot, Michael

AU - Tuller, Tamir

PY - 2015/11/1

Y1 - 2015/11/1

N2 - The asymmetric simple exclusion process (ASEP) is an important model from statistical physics describing particles that hop randomly from one site to the next along an ordered lattice of sites, but only if the next site is empty. ASEP has been used to model and analyze numerous multiagent systems with local interactions including the flow of ribosomes along the mRNA strand. In ASEP with periodic boundary conditions a particle that hops from the last site returns to the first one. The mean field approximation of this model is referred to as the ribosome flow model on a ring (RFMR). The RFMR may be used to model both synthetic and endogenous gene expression regimes. We analyze the RFMR using the theory of monotone dynamical systems. We show that it admits a continuum of equilibrium points and that every trajectory converges to an equilibrium point. Furthermore, we show that it entrains to periodic transition rates between the sites. We describe the implications of the analysis results to understanding and engineering cyclic mRNA translation in-vitro and in-vivo.

AB - The asymmetric simple exclusion process (ASEP) is an important model from statistical physics describing particles that hop randomly from one site to the next along an ordered lattice of sites, but only if the next site is empty. ASEP has been used to model and analyze numerous multiagent systems with local interactions including the flow of ribosomes along the mRNA strand. In ASEP with periodic boundary conditions a particle that hops from the last site returns to the first one. The mean field approximation of this model is referred to as the ribosome flow model on a ring (RFMR). The RFMR may be used to model both synthetic and endogenous gene expression regimes. We analyze the RFMR using the theory of monotone dynamical systems. We show that it admits a continuum of equilibrium points and that every trajectory converges to an equilibrium point. Furthermore, we show that it entrains to periodic transition rates between the sites. We describe the implications of the analysis results to understanding and engineering cyclic mRNA translation in-vitro and in-vivo.

KW - Monotone dynamical systems

KW - asymmetric simple exclusion process

KW - asymptotic stability

KW - cyclic mRNA

KW - entrainment

KW - first integral

KW - mRNA translation

KW - mean field approximation

KW - ribosome flow model

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M3 - مقالة

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JO - IEEE/ACM Transactions on Computational Biology and Bioinformatics

JF - IEEE/ACM Transactions on Computational Biology and Bioinformatics

IS - 6

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ER -

Ribosome Flow Model on a Ring

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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