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Adaptive resetting for informed search strategies and the design of non-equilibrium steady-states

Stochastic resetting is known to accelerate search processes and create nonequilibrium steady states. Here, authors introduce adaptive resetting, a state- and time-dependent framework enabling fast informed search strategies and designing complex nonequilibrium steady states.

Tommer D. Keidar
Ofir Blumer
Shlomi Reuveni
ResearchOpen Access06 Aug 2025
Nature Communications

Volume: 16, P: 1-10
High-order Michaelis-Menten equations allow inference of hidden kinetic parameters in enzyme catalysis

Traditional approaches provide limited information on enzyme kinetics. Here, the authors derive high-order Michaelis-Menten equations, enabling inference of hidden parameters like binding rates and enzyme-substrate lifetimes, advancing enzymology beyond classical methods.

Divya Singh
Tal Robin
Shlomi Reuveni
ResearchOpen Access20 Mar 2025
Nature Communications

Volume: 16, P: 1-11
Combining stochastic resetting with Metadynamics to speed-up molecular dynamics simulations

An outstanding limitation of molecular dynamics simulations is sampling of long timescales. Here, authors combine Metadynamics, a popular enhanced sampling method, with stochastic resetting, to achieve higher speedups and improved kinetic inference.

Ofir Blumer
Shlomi Reuveni
Barak Hirshberg
ResearchOpen Access04 Jan 2024
Nature Communications

Volume: 15, P: 1-10
Multisite phosphorylation drives phenotypic variation in (p)ppGpp synthetase-dependent antibiotic tolerance

Individual bacteria within isogenic populations can differ in antibiotic tolerance. Here, Libby et al. show that antibiotic tolerance variability can be driven by ‘noisy’ expression of a gene encoding a (p)ppGpp synthetase, which is in turn regulated by multisite phosphorylation of a transcription factor.

Elizabeth A. Libby
Shlomi Reuveni
Jonathan Dworkin
ResearchOpen Access13 Nov 2019
Nature Communications

Volume: 10, P: 1-10
Single-molecule theory of enzymatic inhibition

Single molecule approaches demonstrated that enzymatic catalysis is stochastic which could lead to deviations from classical predictions. Here authors rebuild the theory of enzymatic inhibition to show that stochastic fluctuations on the single enzyme level could make inhibitors act as activators.

Tal Robin
Shlomi Reuveni
Michael Urbakh
ResearchOpen Access22 Feb 2018
Nature Communications

Volume: 9, P: 1-9
Ribosomes are optimized for autocatalytic production

The large number of small, similarly sized proteins and the small number of heavy RNA molecules that make up a ribosome reduce the time required for reproduction.

Shlomi Reuveni
Måns Ehrenberg
Johan Paulsson
Research20 Jul 2017
Nature

Volume: 547, P: 293-297

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Adaptive resetting for informed search strategies and the design of non-equilibrium steady-states

High-order Michaelis-Menten equations allow inference of hidden kinetic parameters in enzyme catalysis

Combining stochastic resetting with Metadynamics to speed-up molecular dynamics simulations

Multisite phosphorylation drives phenotypic variation in (p)ppGpp synthetase-dependent antibiotic tolerance

Single-molecule theory of enzymatic inhibition

Ribosomes are optimized for autocatalytic production

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