Biochemical and Biophysical Research Communications, Vol.413, No.4, 545-549, 2011
Effects on the conformation of FVIIa by sTF and Ca2+ binding: Studies of fluorescence resonance energy transfer and quenching
The apparent length of FVIIa in solution was estimated by a FRET analysis. Two fluorescent probes, fluorescein (Fl-FPR) and a rhodamine derivative (TMR), were covalently attached to FVIIa. The binding site of Fl-FPR was in the protease domain whereas TMR was positioned in the Gla domain, thus allowing a length measure over virtually the whole extension of the protein. From the FRET measurements, the distances between the two probes were determined to be 61.4 for free FVIIa and 65.5 angstrom for FVIIa bound to soluble tissue factor (sTF). These seemingly short distances, compared to those anticipated based on the complex crystal structure, require that the probes stretch towards each other. Thus, the apparent distance from the FRET analysis was shown to increase with 4 angstrom upon formation of a complex with sTF in solution. However, considering how protein dynamics, based on recent molecular dynamics simulations of FVIIa and sTF:FVIIa (Y.Z. Ohkubo, J.H. Morrissey, E. Tajkhorshid, J. Thromb. Haemost. 8 (2010) 1044-1053), can influence the apparent fluorescence signal our calculations indicated that the global average conformation of active-site inhibited FVIIa is nearly unaltered upon ligation to sTF. It is known from amidolytic activity measurements that Ca2+ binding leads to activation of FVIIa, but we have for the first time directly demonstrated conformational changes in the environment of the active site upon Ca2+ binding. Interestingly, this Ca2+-induced conformational change can be noted even in the presence of an inhibitor. Forming a complex with sTF further stabilized this conformational change, leading to a more inaccessible active-site located probe. (C) 2011 Elsevier Inc. All rights reserved.
Keywords:Factor VIIa;Fluorescence quenching;Fluorescence resonance energy transfer;Tissue factor;Fluorescein;Rhodamine;Conformational dynamics