Dynamical fluctuations in biochemical reactions and cycles
- Creators
- Pressé, S.
- Ghosh, K.
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Phillips, R.
- Dill, K. A.
Abstract
We develop theory for the dynamics and fluctuations in some cyclic and linear biochemical reactions. We use the approach of maximum caliber, which computes the ensemble of paths taken by the system, given a few experimental observables. This approach may be useful for interpreting single-molecule or few-particle experiments on molecular motors, enzyme reactions, ion-channels, and phosphorylation-driven biological clocks. We consider cycles where all biochemical states are observable. Our method shows how: (1) the noise in cycles increases with cycle size and decreases with the driving force that spins the cycle and (2) provides a recipe for estimating small-number features, such as probability of backward spin in small cycles, from experimental data. The back-spin probability diminishes exponentially with the deviation from equilibrium. We believe this method may also be useful for other few-particle nonequilibrium biochemical reaction systems.
Additional Information
© 2010 The American Physical Society. Received 30 October 2009; revised 13 July 2010; published 15 September 2010. We appreciate the support from NIH Grant No. GM- 34993 to K.D. S.P. thanks the FQRNT for its financial support as well as J. van Drie and G. Peterson for their insights. K.G. acknowledges an FRF Grant from DU for financial support.Attached Files
Published - Presse2010p11475Phys_Rev_E.pdf
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Additional details
- Eprint ID
- 20269
- Resolver ID
- CaltechAUTHORS:20101004-094321543
- GM-34993
- NIH
- Fonds Québécois de la Recherche sur la Nature et les Technologies (FQRNT)
- Denver University
- Created
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2010-10-05Created from EPrint's datestamp field
- Updated
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2021-11-08Created from EPrint's last_modified field