Probing Ligand Protein Binding Equilibria with Fluorescence Fluctuation Spectroscopy

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Probing Ligand Protein Binding Equilibria with Fluorescence Fluctuation Spectroscopy

Yan Chen,^* Joachim D. Müller,^* Sergey Y. Tetin, Joan D. Tyner, and Enrico Gratton^*

^*Laboratory for Fluorescence Dynamics, University of Illinois at Urbana-Champaign, Urbana, Illinois 61801, and Abbott Diagnostics Division, Abbott Laboratories, Abbott Park, Illinois 60064, USA

We examine the binding of fluorescent ligands to proteins by analyzing the fluctuation amplitude g(0) of fluorescence fluctuationexperiments. The normalized variance g(0) depends on the molecularbrightness and the concentration of each species in the sample.Thus a single g(0) measurement is not sufficient to resolve individualspecies. Titration of the ligand with protein establishes thelink between molecular brightness and concentration by fittingg(0) to a binding model and allows the separation of species.We first apply g(0) analysis to binary dye mixtures with brightnessratios of 2 and 4 to demonstrate the feasibility of this technique.Next we consider the influence of binding on the fluctuation amplitudeg(0). The dissociation coefficient, the molecular brightness ratio,and the stochiometry of binding strongly influence the fluctuationamplitude. We show that proteins with a single binding site canbe clearly differentiated from proteins with two independent bindingsites. The binding of fluorescein-labeled digoxigenin to a high-affinityanti-digoxin antibody was studied experimentally. A global analysisof the fluctuation amplitude and the fluorescence intensity notonly recovered the dissociation coefficient and the number ofbinding sites, but also revealed the molecular heterogeneity ofthe hapten-antibody complex. Two species were used to model themolecular heterogeneity. We confirmed the molecular heterogeneityindependently by fluorescence lifetime experiments, which gavefractional populations and molecular brightness values that werevirtually identical to those of the g(0) analysis. The identificationand characterization of molecular heterogeneity have far-reachingconsequences for many biomolecular systems. We point out the importantrole fluctuation experiments may have in this area ofresearch.

Biophys J, August 2000, p. 1074-1084, Vol. 79, No. 2
© 2000 by the Biophysical Society 0006-3495/00/08/1074/11 $2.00

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