Sedimentation of Reversibly Interacting Macromolecules with Changes in Fluorescence Quantum Yield
Sumit K. Chaturvedi, Huaying Zhao, and Peter Schuck

TL;DR
This paper investigates how changes in fluorescence quantum yield affect sedimentation velocity measurements of macromolecular interactions, revealing limitations of traditional analysis and proposing a more comprehensive model.
Contribution
It introduces a new binding model that accounts for signal changes due to fluorescence quantum yield variations during sedimentation analysis.
Findings
Standard sedimentation analysis may misestimate binding parameters when signals change.
Coupled transport effects significantly influence sedimentation behavior in reversible systems.
The proposed model improves accuracy for systems with fluorescence quenching or enhancement.
Abstract
Sedimentation velocity analytical ultracentrifugation with fluorescence detection has emerged as a powerful method for the study of interacting systems of macromolecules. It combines picomolar sensitivity with high hydrodynamic resolution, and can be carried out with photoswitchable fluorophores for multi-component discrimination, to determine the stoichiometry, affinity, and shape of macromolecular complexes with dissociation equilibrium constants from picomolar to micromolar. A popular approach for data interpretation is the determination of the binding affinity by isotherms of weight-average sedimentation coefficients, sw. A prevailing dogma in sedimentation analysis is that the weight-average sedimentation coefficient from the transport method corresponds to the signal- and population-weighted average of all species. We show that this does not always hold true for systems that…
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