Multiplex Charge-Transfer Interactions between Quantum Dots and Peptide-Bridged Ruthenium Complexes

Simultaneous detection of multiple independent fluorescent signals or signal multiplexing has the potential to significantly improve bioassay throughput and to allow visualization of concurrent cellular events. Applications based on signal multiplexing, however, remain hard to achieve in practice due to difficulties in both implementing hardware and the photophysical liabilities associated with available organic dye and protein fluorophores. Here, we used charge-transfer interactions between luminescent semiconductor quantum dots (QDs) and proximal redox complexes to demonstrate controlled quenching of QD photoemission in a multiplexed format. In particular, we show that, because of the ability of the Ru complex to effectively interact with CdSe−ZnS QDs emitting over a broad window of the optical spectrum, higher orders of multiplexed quenching can be achieved in a relatively facile manner. Polyhistidine-appended peptides were site-specifically labeled with a redox-active ruthenium (Ru) phenanthroline com...