Kinetics of biopolymerization on nucleic acid templates

MacDonald, Carolyn T.; Gibbs, Julian H.; Pipkin, A. C.

doi:10.1002/bip.1968.360060102

Cited by 830 publications

(947 citation statements)

References 6 publications

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“…Repeating the previous step gives det F (B N , A N ; 0) = δ k 1 ,l 1 δ k 2 ,l 2 det F (2) . Iterating this procedure N times finally gives det…”

Section: Solution Of the Master Equationmentioning

confidence: 97%

“…Assuming that the particles were initially at sites y 1 , y 2 it turns out that choosing f (p 1 , p 2 ) = e −ip 1 y 1 −ip 2 y 2 and defining the position of the pole in S 21 by p 1 → p 1 + i0 gives the correct initial condition P (x 1 , x 2 ; 0) = δ x 1 ,y 1 δ x 2 ,y 2 . This gives P (x 1 , x 2 ; t|y 1 , y 2 ; 0) = 1 (2π) 2 2π 0 dp 1 2π 0 dp 2 e −(ǫp 1 +ǫp 2 )t−ip 1 y 1 −ip 2 y 2 e ip 1 x 1 +ip 2 x 2 − 1 − e ip 2 1 − e ip 1 e ip 2 x 1 +ip 1 x 2 (3.11)…”

Section: Bethe Ansatz Solutionmentioning

confidence: 99%

“…The ASEP (for a definition see below) has been suggested already in 1968 as a model for the kinetics of biopolymerization [2]. Two years later this process was introduced into the mathematical literature [3] where it has received considerable attention in the context of interacting particle systems [4].…”

Section: Introductionmentioning

confidence: 99%

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Exact solution of the master equation for the asymmetric exclusion process

1997

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“…Repeating the previous step gives det F (B N , A N ; 0) = δ k 1 ,l 1 δ k 2 ,l 2 det F (2) . Iterating this procedure N times finally gives det…”

Section: Solution Of the Master Equationmentioning

confidence: 97%

Section: Bethe Ansatz Solutionmentioning

confidence: 99%

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Exact solution of the master equation for the asymmetric exclusion process

1997

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“…The mean-field approach predicts phase transitions in the steady state as parameters controlling the rate of insertion and extraction of particles at the boundaries are varied [31]. The existence of these phase transitions is confirmed through an exact solution of the ASEP [29][30][31], achieved using a powerful matrix product approach [32,34] which has subsequently been used to solve many generalisations of the ASEP. The details of the matrix product method are not necessary for the following-suffice to say that one ends up calculating a normalisation proportional to (23) through a product of matrices, often of infinite dimension.…”

Section: Iv1 Driven Diffusive Systemsmentioning

confidence: 99%

The Lee-Yang theory of equilibrium and nonequilibrium phase transitions

2003

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We present a pedagogical account of the Lee-Yang theory of equilibrium phase transitions and review recent advances in applying this theory to nonequilibrium systems. Through both general considerations and explicit studies of specific models, we show that the Lee-Yang approach can be used to locate and classify phase transitions in nonequilibrium steady states. I IntroductionIn this work we seek a mathematical understanding of phase transitions in the steady state of stochastic many-body systems. Systems at equilibrium with their environment provide examples of such steady states, and the mechanisms underlying equilibrium phase transitions are long known and understood. Experimentally, one can distinguish between two types of transition: the first-order transition at which there is phase coexistence, e.g. between a high-density solid and a low-density fluid, and the continuous transition at which fluctuations and correlations grow to such an extent as to be macroscopically observable.From a thermodynamical perspective, one can understand first-order transitions by associating with each phase a free energy. For a given set of external parameters, the phase 'chosen' by the system is that with the lowest free energy, and so a phase transition occurs when the free energies of two (or more) phases are equal. The sudden changes in macroscopically measurable quantities that take place at first-order transitions are described mathematically as discontinuities in the first derivative of the free energy. Discontinuities in higher derivatives relate to continuous (higherorder) phase transitions.The tools of equilibrium statistical physics allow onein principle at least-to express the free energy solely in terms of microscopic interactions. More specifically, the free energy is given by the logarithm of a partition function, a quantity that normalises the steady-state probability distribution of microscopic configurations. Initially it was not universally accepted that this approach could faithfully describe phase transitions, in particular the first-order solidfluid transition [1]. In order to show that the statistical mechanical approach can reproduce the correct discontinuities in the free energy at a first-order transition, Lee and Yang [2] introduced a description of phase transitions concerning zeros of the partition function when generalised to the complex plane of an intensive thermodynamic quantity. Initially, the theory was couched in terms of zeros in the complex fugacity plane which is appropriate for fluids in the grand canonical (fluctuating particle number) ensemble. However, by mapping a lattice gas onto the Ising model [3], the theory was found to hold equally well for a magnet in a fixed magnetic field. Later [4-6] it became clear that the distribution of zeros in the complex temperature plane can reveal information about phase transitions in the canonical ensemble.In section II we present a brief, self-contained discussion of the Lee-Yang theory of equilibrium phase transitions which relates nonanalytic ...

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“…Kinetic models of biopolymerization on nucleic acid templates were developed early on (MacDonald et al, 1968), (MacDonald and Gibbs], 1969).…”

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confidence: 99%

A mathematical modelling framework for elucidating the role of feedback control in translation termination

Silva

Krishnan

Betney

et al. 2010

Journal of Theoretical Biology

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Translation is the final stage of gene expression where messenger RNA is used as a template for protein polymerisation from appropriate amino acids. Release of the completed protein requires a release factor protein acting at the termination/stop codon to liberate it. In this paper we focus on a complex feedback control mechanism involved in the translation and synthesis of release factor proteins, which has been observed in different systems. These release factor proteins are involved in the termination stage of their own translation. Further, mutations in the release factor gene can result in a premature stop codon. In this case translation can result either in early termination and the production of a truncated protein or readthrough of the premature stop codon and production of the complete release factor protein. Thus during translation of the release factor mRNA containing a premature stop codon, the full length protein negatively regulates its production by its action on a premature stop codon, while positively regulating its production by its action on the regular stop codon. This paper develops a mathematical modelling framework to investigate this complex feedback control system involved in translation. A series of models is established to carefully investigate the role of individual mechanisms and how they work together. The steady state and dynamic behaviour of the resulting models are examined both analytically and numerically.

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Kinetics of biopolymerization on nucleic acid templates

Cited by 830 publications

References 6 publications

Exact solution of the master equation for the asymmetric exclusion process

Exact solution of the master equation for the asymmetric exclusion process

The Lee-Yang theory of equilibrium and nonequilibrium phase transitions

A mathematical modelling framework for elucidating the role of feedback control in translation termination

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