蛋白质同型寡聚体复合物中共振能量转移的效率
Efficiency of resonance energy transfer in homo-oligomeric complexes of proteins.
作者信息
Raicu Valerică
机构信息
Department of Physics and Department of Biological Sciences, University of Wisconsin-Milwaukee, Milwaukee, WI, USA.
出版信息
J Biol Phys. 2007 Apr;33(2):109-27. doi: 10.1007/s10867-007-9046-z. Epub 2007 Oct 25.
Abstract
A theoretical model is proposed for the apparent efficiency of fluorescence (Förster) resonance energy transfer (FRET) in mixtures of free monomers and homo-oligomeric protein complexes of uniform size. The model takes into account possible pathways for transfer of optical excitations from single donors to multiple acceptors and from multiple donors (non-simultaneously) to single acceptors. This necessary departure from the standard theory has been suggested in the literature, but it has only been successfully implemented for a few particular cases, such as for particular geometries of the oligomers. The predictions of the present theoretical model differ significantly from those of the standard theory, with the exception of the case of dimers, for which agreement is observed. This model therefore provides new insights into the FRET behavior of oligomers comprising more than two monomers, and also suggests means for determining the size of oligomeric protein complexes as well as the proportion of associated and unassociated monomers.
摘要
针对游离单体与大小均匀的同型寡聚蛋白复合物混合物中荧光(Förster)共振能量转移(FRET)的表观效率,提出了一种理论模型。该模型考虑了光激发从单个供体转移到多个受体以及从多个供体(非同时)转移到单个受体的可能途径。文献中已提出这种与标准理论的必要偏离,但仅在少数特定情况下成功实现,例如对于特定几何形状的寡聚物。除了二聚体情况观察到一致外,本理论模型的预测与标准理论的预测有显著差异。因此,该模型为包含两个以上单体的寡聚物的FRET行为提供了新的见解,还提出了确定寡聚蛋白复合物大小以及相关和未相关单体比例的方法。
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