Validation of Fractal-Like Kinetic Models by Time-Resolved Binding Kinetics of Dansylamide and Carbonic Anhydrase in Crowded Media

Kinetic studies of biochemical reactions are typically carried out in a dilute solution that rarely contains anything more than reactants, products, and buffers. In such studies, mass-action-based kinetic models are used to analyze the progress curves. However, intracellular compartments are crowded...

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Bibliographic Details
Published in:Biophysical journal 2011-05, Vol.100 (10), p.2495-2503
Main Authors: Neff, Kevin L., Offord, Chetan P., Caride, Ariel J., Strehler, Emanuel E., Prendergast, Franklyn G., Bajzer, Željko
Format: Article
Language:English
Subjects:
allometry
Animals
Binding sites
Biochemistry
buffers
carbonate dehydratase
Carbonic Anhydrases - chemistry
Carbonic Anhydrases - metabolism
Cattle
Dansyl Compounds - chemistry
Dansyl Compounds - metabolism
dissociation
Enzymes
ficoll
Ficoll - chemistry
Fractals
Kinetics
Least-Squares Analysis
Macromolecular Substances - chemistry
Models, Chemical
Molecular Weight
Molecules
polyethylene glycol
Polyethylene Glycols - chemistry
Protein
Protein Binding
Reaction kinetics
Reproducibility of Results
selection criteria
Studies
Time Factors
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Summary:Kinetic studies of biochemical reactions are typically carried out in a dilute solution that rarely contains anything more than reactants, products, and buffers. In such studies, mass-action-based kinetic models are used to analyze the progress curves. However, intracellular compartments are crowded by macromolecules. Therefore, we investigated the adequacy of the proposed generalizations of the mass-action model, which are meant to describe reactions in crowded media. To validate these models, we measured time-resolved kinetics for dansylamide binding to carbonic anhydrase in solutions crowded with polyethylene glycol and Ficoll. The measured progress curves clearly show the effects of crowding. The fractal-like model proposed by Savageau was used to fit these curves. In this model, the association rate coefficient ka allometrically depends on concentrations of reactants. We also considered the fractal kinetic model proposed by Schnell and Turner, in which ka depends on time according to a Zipf-Mandelbrot distribution, and some generalizations of these models. We found that the generalization of the mass-action model, in which association and dissociation rate coefficients are concentration-dependent, represents the preferred model. Other models based on time-dependent rate coefficients were inadequate or not preferred by model selection criteria.
ISSN:0006-3495
1542-0086
DOI:10.1016/j.bpj.2011.04.016