Correlated particle transport enables biological free energy transduction.
Studies of biological transport frequently neglect the explicit statistical correlations among particle site occupancies (i.e., they use a mean-field approximation). Neglecting correlations sometimes captures biological function, even for out-of-equilibrium and interacting systems. We show that neglecting correlations fails to describe free energy transduction, mistakenly predicting an abundance of slippage and energy dissipation, even for networks that are near reversible and lack interactions among particle sites. Interestingly, linear charge transport chains are well described without including correlations, even for networks that are driven and include site-site interactions typical of biological electron transfer chains. We examine three specific bioenergetic networks: a linear electron transfer chain (as found in bacterial nanowires), a near-reversible electron bifurcation network (as in complex III of respiration and other recently discovered structures), and a redox-coupled proton pump (as in complex IV of respiration).
Duke Scholars
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Related Subject Headings
- Protons
- Proton Pumps
- Oxidation-Reduction
- Energy Metabolism
- Electron Transport Complex IV
- Electron Transport
- Biophysics
- Biological Transport
- 51 Physical sciences
- 34 Chemical sciences
Citation
Published In
DOI
EISSN
ISSN
Publication Date
Volume
Issue
Start / End Page
Related Subject Headings
- Protons
- Proton Pumps
- Oxidation-Reduction
- Energy Metabolism
- Electron Transport Complex IV
- Electron Transport
- Biophysics
- Biological Transport
- 51 Physical sciences
- 34 Chemical sciences