Modular DNA-Origami-Based Nanoarrays Enhance Cell Binding Affinity through the "Lock-and-Key" Interaction.
Miao MaoZhun LinLiang ChenZhengyu ZouJie ZhangQuanhao DouJiacheng WuJinglin ChenMinhao WuLi NiuChun-Hai FanYuanqing ZhangPublished in: Journal of the American Chemical Society (2023)
Surface proteins of cells are generally recognized through receptor-ligand interactions (RLIs) in disease diagnosis, but their nonuniform spatial distribution and higher-order structure lead to low binding affinity. Constructing nanotopologies that match the spatial distribution of membrane proteins to improve the binding affinity remains a challenge. Inspired by the multiantigen recognition of immune synapses, we developed modular DNA-origami-based nanoarrays with multivalent aptamers. By adjusting the valency and interspacing of the aptamers, we constructed specific nanotopology to match the spatial distribution of target protein clusters and avoid potential steric hindrance. We found that the nanoarrays significantly enhanced the binding affinity of target cells and synergistically recognized low-affinity antigen-specific cells. In addition, DNA nanoarrays used for the clinical detection of circulating tumor cells successfully verified their precise recognition ability and high-affinity RLIs. Such nanoarrays will further promote the potential application of DNA materials in clinical detection and even cell membrane engineering.
Keyphrases
- circulating tumor
- induced apoptosis
- circulating tumor cells
- cell cycle arrest
- cell free
- single molecule
- binding protein
- nucleic acid
- endoplasmic reticulum stress
- cell death
- dna binding
- oxidative stress
- risk assessment
- stem cells
- loop mediated isothermal amplification
- cell proliferation
- human health
- mass spectrometry
- climate change