Time-resolved and steady-state FRET spectroscopy on commercial biocompatible quantum dots

Semiconductor nanocrystals (quantum dots - QDs) possess unique photophysical properties that make them highly interesting for many biochemical applications. Besides their common use as fluorophores in conventional spectroscopy and microscopy, QDs are well-suited for studying Forster resonance energy transfer (FRET). Size-dependent broadband absorption and narrow emission bands offer several advantages for the use of QDs both as FRET donors and acceptors. QD-based FRET pairs can be efficiently used as biological and chemical sensors for highly sensitive multiplexed detection. In this contribution we present the use of several commercially available QDs (Qdot® Nanocrystals - Invitrogen) as FRET donors in combination with commercial organic dyes as FRET acceptors. In order to investigate the FRET process within our donor-acceptor pairs, we used biotinylated QDs and streptavidin-labeled dyes. The well-known biotinstreptavidin molecular recognition enables effective FRET from QDs to dye molecules and provides defined distances between donor and acceptor. Steady-state and time-resolved fluorescence measurements were performed in order to investigate QD-to-dye FRET. Despite a thick polymer shell around the QDs, our results demonstrate the potential of these QDs as efficient donors both for steady-state and time-resolved FRET applications in nano-biotechnology.