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Biophys J, December 2001, p. 3510-3521, Vol. 81, No. 6
and
*Departimento di Biochimica e Biofisica, Seconda Universita di
Napoli, 80138 Napoli, Italy; and Department of Physics,
University of Illinois at Urbana-Champaign, Urbana, Illinois 61801-3080 USA
The dynamics of the binding reaction of ANS to native and
partly folded (molten globule) tuna and horse apomyoglobins has been
investigated by fluorescence correlation spectroscopy and frequency
domain fluorometry. The reaction rate has been measured as a function
of apomyoglobin and ANS concentrations, pH, and temperature.
Examination of the autocorrelation functions shows that the reaction
rate is fast enough to be observed in tuna apomyoglobin, whereas the
reaction rate in horse apomyoglobin is on the same time scale as
diffusion through the volume or longer. Specifically, for tuna
apomyoglobin at pH 7 and room temperature the on rate is 2200 µM
1 s1 and the off rate is 5900 s1, in comparison with
kon = 640 µM1
s1 and koff = 560 s1 for horse myoglobin as measured previously.
The independence of the reaction rate from the ANS concentration
indicates that the reaction rate is dominated by the off rate. The
temperature dependence of the on-rate shows that this rate is diffusion
limited. The temperature dependence of the off rates analyzed by
Arrhenius and Ferry models indicates that the off rate depends on the
dynamics of the protein. The differences between horse and tuna
apomyoglobins in the ANS binding rate can be explained in terms of the
three-dimensional apoprotein structures obtained by energy minimization
after heme removal starting from crystallographic coordinates. The
comparison of the calculated apomyoglobin surfaces shows a 15% smaller
cavity for tuna apomyoglobin. Furthermore, a negative charge (D44) is present in the heme cavity of tuna apomyoglobin that could decrease the
strength of ANS binding. At pH 5 the fluorescence lifetime distribution
of ANS-apomyoglobin is bimodal, suggesting the presence of an
additional binding site in the protein. The binding rates determined by
FCS under these conditions show that the protein is either in the open
configuration or is more flexible, making it much easier to bind. At pH
3, the protein is in a partially denatured state with multiple
potential binding sites for ANS molecule, and the interpretation of the
autocorrelation function is not possible by simple models. This
conclusion is consistent with the broad distribution of ANS
fluorescence lifetimes observed in frequency domain measurements.
Biophys J, December 2001, p. 3510-3521, Vol. 81, No. 6
© 2001 by the Biophysical Society 0006-3495/01/12/3510/12 $2.00
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