Förster Resonance Energy Transfer between Core/Shell Quantum Dots and Bacteriorhodopsin.

Molecular biology international Pub Date : 2012-01-01 Epub Date: 2012-06-10 DOI:10.1155/2012/910707

Mark H Griep, Eric M Winder, Donald R Lueking, Gregory A Garrett, Shashi P Karna, Craig R Friedrich

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Abstract

An energy transfer relationship between core-shell CdSe/ZnS quantum dots (QDs) and the optical protein bacteriorhodopsin (bR) is shown, demonstrating a distance-dependent energy transfer with 88.2% and 51.1% of the QD energy being transferred to the bR monomer at separation distances of 3.5 nm and 8.5 nm, respectively. Fluorescence lifetime measurements isolate nonradiative energy transfer, other than optical absorptive mechanisms, with the effective QD excited state lifetime reducing from 18.0 ns to 13.3 ns with bR integration, demonstrating the Förster resonance energy transfer contributes to 26.1% of the transferred QD energy at the 3.5 nm separation distance. The established direct energy transfer mechanism holds the potential to enhance the bR spectral range and sensitivity of energies that the protein can utilize, increasing its subsequent photocurrent generation, a significant potential expansion of the applicability of bR in solar cell, biosensing, biocomputing, optoelectronic, and imaging technologies.

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核/壳量子点与细菌发光素之间的福斯特共振能量转移

图中显示了核壳 CdSe/ZnS 量子点（QDs）与光学蛋白质 bacteriorhodopsin（bR）之间的能量转移关系，表明能量转移与距离有关，在 3.5 nm 和 8.5 nm 的分离距离上，分别有 88.2% 和 51.1% 的 QD 能量转移到 bR 单体上。荧光寿命测量隔离了光吸收机制以外的非辐射能量转移，有效的 QD 激发态寿命随着 bR 的整合从 18.0 ns 缩短到 13.3 ns，这表明在 3.5 nm 的分离距离上，福斯特共振能量转移占 QD 能量转移的 26.1%。已建立的直接能量转移机制有可能提高 bR 的光谱范围和蛋白质可利用能量的灵敏度，从而增加其随后产生的光电流，大大扩展了 bR 在太阳能电池、生物传感、生物计算、光电和成像技术中的应用潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Molecular biology international

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