Multiple-scale stochastic processes: Decimation, averaging and beyond

Bò, Stefano; Celani, Antonio

doi:10.1016/j.physrep.2016.12.003

Cited by 71 publications

(97 citation statements)

References 105 publications

(248 reference statements)

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“…However, as experiments show [13], in the flagellar motor regulation mechanism of E. coli it is possible to identify a hierarchy of widely separated time scales. This opens up the possibility of operating a reduction of the set of states by gradually integrating out/decimating fast degrees of freedom, operating a quasi-stationary approximation: the time scale of the slow degrees of freedom is much longer than the time needed for the fast variables to relax to a stationary distribution; hence, the fast degrees of freedom enter the slow dynamics only through quantities averaged over such stationary distribution (conditioned to the state of the slow variables) [16][17][18]. The application of such techniques to the study of the allosteric regulation of the motor of E. coli will be the subject of the following sections.…”

Section: Ccw Cw Fli Moleculesmentioning

confidence: 99%

From conformational spread to allosteric and cooperative models of E. coli flagellar motor

2017

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Abstract. Escherichia coli swims using flagella activated by rotary motors. The direction of rotation of the motors is indirectly regulated by the binding of a single messenger protein. The conformational spread model has been shown to accurately describe the equilibrium properties as well as the dynamics of the flagellar motor. In this paper we study this model from an analytic point of view. By exploiting the separation of time scales observed in experiments, we show how to reduce the conformational spread model to a coarse-grained, cooperative binding model. We show that this simplified model reproduces very well the dynamics of the motor switch.

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Section: Ccw Cw Fli Moleculesmentioning

confidence: 99%

From conformational spread to allosteric and cooperative models of E. coli flagellar motor

2017

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“…In these cases, the dissipation in a nonequililibrium process is typically underestimated-although also overestimations may occur [23]. For a general overview of coarse-graining in Markov processes, see [24] and references therein.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamically consistent coarse graining of biocatalysts beyond Michaelis–Menten

2018

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Starting from the detailed catalytic mechanism of a biocatalyst we provide a coarse-graining procedure which, by construction, is thermodynamically consistent. This procedure provides stoichiometries, reaction fluxes (rate laws), and reaction forces (Gibbs energies of reaction) for the coarse-grained level. It can treat active transporters and molecular machines, and thus extends the applicability of ideas that originated in enzyme kinetics. Our results lay the foundations for systematic studies of the thermodynamics of large-scale biochemical reaction networks. Moreover, we identify the conditions under which a relation between one-way fluxes and forces holds at the coarse-grained level as it holds at the detailed level. In doing so, we clarify the speculations and broad claims made in the literature about such a general flux-force relation. As a further consequence we show that, in contrast to common belief, the second law of thermodynamics does not require the currents and the forces of biochemical reaction networks to be always aligned.

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“…In this case, the Markovian model illustrated in Fig. 1(b) can be reduced to a much simpler one by using a classical simplification method of multiscale Markov jump processes called averaging [24][25][26]. Since σ b and σ u are large, for each n ≥ m, the two microstates (0, n) and (1, n − m) are in rapid equilibrium and thus can be aggregated into a group that is labelled by group n, as depicted in Fig.…”

Section: Deriving a Reduced Model Of Auto-regulated Bursty Gene Exprementioning

confidence: 99%

Dynamical phase diagram of an auto-regulating gene in fast switching conditions

Chen

Grima

2020

Preprint

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AbstractWhile the steady-state behavior of stochastic gene expression with auto-regulation has been extensively studied, its time-dependent behavior has received much less attention. Here, under the assumption of fast promoter switching, we derive and solve a reduced chemical master equation for an auto-regulatory gene circuit with translational bursting and cooperative protein-gene interactions. The analytical expression for the time-dependent probability distribution of protein numbers enables a fast exploration of large swaths of parameter space. For a unimodal initial distribution, we identify three distinct types of stochastic dynamics: (i) the protein distribution remains unimodal at all times; (ii) the protein distribution becomes bimodal at intermediate times and then reverts back to being unimodal at long times (transient bimodality) and (iii) the protein distribution switches to being bimodal at long times. For each of these, the deterministic model predicts either monostable or bistable behaviour and hence there exist six dynamical phases in total. We investigate the relationship of the six phases to the transcription rates, the protein binding and unbinding rates, the mean protein burst size, the degree of cooperativity, the relaxation time to the steady state, the protein mean and the type of feedback loop (positive or negative). We show that transient bimodality is a noise-induced phenomenon that occurs when protein expression is sufficiently bursty and we use theory to estimate the observation time window when it is manifest.

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Multiple-scale stochastic processes: Decimation, averaging and beyond

Cited by 71 publications

References 105 publications

From conformational spread to allosteric and cooperative models of E. coli flagellar motor

From conformational spread to allosteric and cooperative models of E. coli flagellar motor

Thermodynamically consistent coarse graining of biocatalysts beyond Michaelis–Menten

Dynamical phase diagram of an auto-regulating gene in fast switching conditions

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