Evaluating Dye-Labeled DNA Dendrimers for Potential Applications in Molecular Biosensing.
Carl W BrownSusan Buckhout-WhiteSebastian A DiazJoseph S MelingerMario G AnconaEllen R GoldmanIgor L MedintzPublished in: ACS sensors (2017)
DNA nanostructures provide a reliable and predictable scaffold for precisely positioning fluorescent dyes to form energy transfer cascades. Furthermore, these structures and their attendant dye networks can be dynamically manipulated by biochemical inputs, with the changes reflected in the spectral response. However, the complexity of DNA structures that have undergone such types of manipulation for direct biosensing applications is quite limited. Here, we investigate four different modification strategies to effect such dynamic manipulations using a DNA dendrimer scaffold as a testbed, and with applications to biosensing in mind. The dendrimer has a 2:1 branching ratio that organizes the dyes into a FRET-based antenna in which excitonic energy generated on multiple initial Cy3 dyes displayed at the periphery is then transferred inward through Cy3.5 and/or Cy5 relay dyes to a Cy5.5 final acceptor at the focus. Advantages of this design included good transfer efficiency, large spectral separation between the initial donor and final acceptor emissions for signal transduction, and an inherent tolerance to defects. Of the approaches to structural rearrangement, the first two mechanisms we consider employed either toehold-mediated strand displacement or strand replacement and their impact was mainly via direct transfer efficiency, while the other two were more global in their effect using either a belting mechanism or an 8-arm star nanostructure to compress the nanostructure and thereby modulate its spectral response through an enhancement in parallelism. The performance of these mechanisms, their ability to reset, and how they might be utilized in biosensing applications are discussed.
Keyphrases
- energy transfer
- single molecule
- quantum dots
- aqueous solution
- circulating tumor
- optical coherence tomography
- label free
- cell free
- nucleic acid
- living cells
- high resolution
- highly efficient
- dual energy
- tissue engineering
- risk assessment
- pet imaging
- computed tomography
- mass spectrometry
- magnetic resonance
- positron emission tomography
- solar cells
- liquid chromatography