Designer DNA NanoGripper

DNA has shown great biocompatibility, programmable mechanical properties, and structural addressability at the nanometer scale, making it a versatile material for building high precision nanorobotics for biomedical applications. Herein, we present design principle, synthesis, and characterization of a DNA nanorobotic hand, called the “NanoGripper”, that contains a palm and four bendable fingers as inspired by human hands, bird claws, and bacteriophages evolved in nature. Each NanoGripper finger has three phalanges connected by two flexible and rotatable joints that are bendable in response to binding to other entities. Functions of the NanoGripper have been enabled and driven by the interactions between moieties attached to the fingers and their binding partners. We showcase that the NanoGripper can be engineered to interact with and capture various objects with different dimensions, including gold nanoparticles, gold NanoUrchins, and SARS-CoV-2 virions. When carrying multiple DNA aptamer nanoswitches programmed to generate fluorescent signal enhanced on a photonic crystal platform, the NanoGripper functions as a sensitive viral biosensor that detects intact SARS-CoV-2 virions in human saliva with a limit of detection of ∼ 100 copies/mL, providing RT-PCR equivalent sensitivity. Additionally, we use confocal microscopy to visualize how the NanoGripper-aptamer complex can effectively block viral entry into the host cells, indicating the viral inhibition. In summary, we report the design, synthesis, and characterization of a complex nanomachine that can be readily tailored for specific applications. The study highlights a path toward novel, feasible, and efficient solutions for the diagnosis and therapy of other diseases such as HIV and influenza. One-sentence summary Design, synthesis, characterization, and functional showcase of a human-hand like designer DNA nanobot

[1]  Blake Lash,et al.  Programmable protein delivery with a bacterial contractile injection system , 2023, Nature.

[2]  M. Schachtner,et al.  DNA origami traps for large viruses , 2023, Cell Reports Physical Science.

[3]  B. Cunningham,et al.  Photonic-Plasmonic Coupling Enhanced Fluorescence Enabling Digital-Resolution Ultrasensitive Protein Detection , 2022, bioRxiv.

[4]  H. Dietz,et al.  Broad-Spectrum Virus Trapping with Heparan Sulfate-Modified DNA Origami Shells , 2022, ACS nano.

[5]  Taylor D. Canady,et al.  Photonic crystal enhanced fluorescence emission and blinking suppression for single quantum dot digital resolution biosensing , 2022, Nature Communications.

[6]  F. Simmel,et al.  A DNA origami rotary ratchet motor , 2022, Nature.

[7]  B. Cunningham,et al.  Net-Shaped DNA Nanostructures Designed for Rapid/Sensitive Detection and Potential Inhibition of the SARS-CoV-2 Virus , 2022, bioRxiv.

[8]  B. Cunningham,et al.  Microscopies Enabled by Photonic Metamaterials , 2022, Sensors.

[9]  Xinliang Liu,et al.  Rapid testing for coronavirus disease 2019 (COVID-19) , 2022, MRS Communications.

[10]  Paul S. Kwon,et al.  Designer DNA nanostructures for viral inhibition , 2022, Nature Protocols.

[11]  B. Cunningham,et al.  Label-Free Digital Detection of Intact Virions by Enhanced Scattering Microscopy. , 2021, Journal of the American Chemical Society.

[12]  M. Hagan,et al.  Programmable icosahedral shell system for virus trapping , 2021, Nature Materials.

[13]  H. Su,et al.  Integrated computer-aided engineering and design for DNA assemblies , 2021, Nature Materials.

[14]  A. Chandrasekaran Nuclease resistance of DNA nanostructures , 2021, Nature Reviews Chemistry.

[15]  B. Nelson,et al.  Trends in Micro‐/Nanorobotics: Materials Development, Actuation, Localization, and System Integration for Biomedical Applications , 2020, Advanced materials.

[16]  N. Krogan,et al.  An ultrapotent synthetic nanobody neutralizes SARS-CoV-2 by stabilizing inactive Spike , 2020, Science.

[17]  Paul S. Kwon,et al.  Sulfated polysaccharides effectively inhibit SARS-CoV-2 in vitro , 2020, Cell Discovery.

[18]  O. Pybus,et al.  Clinical, immunological and virological characterization of COVID-19 patients that test re-positive for SARS-CoV-2 by RT-PCR , 2020, EBioMedicine.

[19]  Yanling Song,et al.  Discovery of Aptamers Targeting the Receptor-Binding Domain of the SARS-CoV-2 Spike Glycoprotein , 2020, Analytical chemistry.

[20]  William M. Shih,et al.  Glutaraldehyde crosslinking of oligolysines coating DNA origami greatly reduces susceptibility to nuclease degradation. , 2020, Journal of the American Chemical Society.

[21]  Michael Matthies,et al.  Design, optimization and analysis of large DNA and RNA nanostructures through interactive visualization, editing and molecular simulation , 2020, bioRxiv.

[22]  Iftikhar Ali,et al.  The functions of kinesin and kinesin-related proteins in eukaryotes , 2020, Cell adhesion & migration.

[23]  P. Yin,et al.  Enhancing Biocompatible Stability of DNA Nanostructures Using Dendritic Oligonucleotides and Brick Motifs , 2019, Angewandte Chemie.

[24]  Taylor D. Canady,et al.  Digital-resolution detection of microRNA with single-base selectivity by photonic resonator absorption microscopy , 2019, Proceedings of the National Academy of Sciences.

[25]  Aram J. Chung,et al.  Hydroporator: a hydrodynamic cell membrane perforator for high-throughput vector-free nanomaterial intracellular delivery and DNA origami biostability evaluation. , 2019, Lab on a chip.

[26]  Jie Chao,et al.  Designer DNA architecture offers precise and multivalent spatial pattern-recognition for viral sensing and inhibition , 2019, bioRxiv.

[27]  Hale Bila,et al.  Engineering a stable future for DNA-origami as a biomaterial. , 2019, Biomaterials science.

[28]  Steve Y. Cho,et al.  DNA origami nanostructures can exhibit preferential renal uptake and alleviate acute kidney injury , 2018, Nature Biomedical Engineering.

[29]  Hai-Jun Su,et al.  Paper Origami-Inspired Design and Actuation of DNA Nanomachines with Complex Motions. , 2018, Small.

[30]  Veikko Linko,et al.  Structural stability of DNA origami nanostructures under application-specific conditions , 2018, Computational and structural biotechnology journal.

[31]  Hendrik Dietz,et al.  Sequence-programmable covalent bonding of designed DNA assemblies , 2018, Science Advances.

[32]  Salvador Pané,et al.  Soft Micro- and Nanorobotics , 2018, Annu. Rev. Control. Robotics Auton. Syst..

[33]  Baoquan Ding,et al.  A DNA nanorobot functions as a cancer therapeutic in response to a molecular trigger in vivo , 2018, Nature Biotechnology.

[34]  Hélder A. Santos,et al.  Protein Coating of DNA Nanostructures for Enhanced Stability and Immunocompatibility , 2017, Advanced healthcare materials.

[35]  David J. Mooney,et al.  Oligolysine-based coating protects DNA nanostructures from low-salt denaturation and nuclease degradation , 2017, Nature Communications.

[36]  Michael Matthies,et al.  Block Copolymer Micellization as a Protection Strategy for DNA Origami. , 2017, Angewandte Chemie.

[37]  Joseph Wang,et al.  Micro/nanorobots for biomedicine: Delivery, surgery, sensing, and detoxification , 2017, Science Robotics.

[38]  S. Kim,et al.  Interaction of Zika Virus Envelope Protein with Glycosaminoglycans. , 2017, Biochemistry.

[39]  C. Toumey From nano machines to Nobel prizes. , 2017, Nature nanotechnology.

[40]  R. Kane,et al.  Nanostructured glycan architecture is important in the inhibition of influenza A virus infection. , 2017, Nature nanotechnology.

[41]  Yi Guan,et al.  Genomic Analysis of the Emergence, Evolution, and Spread of Human Respiratory RNA Viruses. , 2016, Annual review of genomics and human genetics.

[42]  Arun Richard Chandrasekaran,et al.  Beyond the Fold: Emerging Biological Applications of DNA Origami , 2016, Chembiochem : a European journal of chemical biology.

[43]  William M. Shih,et al.  Addressing the Instability of DNA Nanostructures in Tissue Culture , 2014, ACS nano.

[44]  William M. Shih,et al.  Virus-Inspired Membrane Encapsulation of DNA Nanostructures To Achieve In Vivo Stability , 2014, ACS nano.

[45]  Yue Zhuo,et al.  Single nanoparticle detection using photonic crystal enhanced microscopy. , 2014, The Analyst.

[46]  H. Su,et al.  DNA origami compliant nanostructures with tunable mechanical properties. , 2014, ACS nano.

[47]  R. Linhardt,et al.  Characterization of human placental glycosaminoglycans and regional binding to VAR2CSA in malaria infected erythrocytes , 2014, Glycoconjugate Journal.

[48]  I. Willner,et al.  Functionalized DNA nanostructures. , 2012, Chemical reviews.

[49]  D. Meldrum,et al.  Stability of DNA origami nanoarrays in cell lysate. , 2011, Nano letters.

[50]  B. Mahy,et al.  The Evolution and Emergence of RNA Viruses , 2010, Emerging Infectious Diseases.

[51]  N. Hirokawa,et al.  Kinesin superfamily motor proteins and intracellular transport , 2009, Nature Reviews Molecular Cell Biology.

[52]  Adam H. Marblestone,et al.  Rapid prototyping of 3D DNA-origami shapes with caDNAno , 2009, Nucleic acids research.

[53]  Tim Liedl,et al.  Self-assembly of DNA into nanoscale three-dimensional shapes , 2009, Nature.

[54]  Shawn M. Douglas,et al.  Self-assembly of DNA into nanoscale three-dimensional shapes , 2009, Nature.

[55]  A. Turberfield,et al.  DNA nanomachines. , 2007, Nature nanotechnology.

[56]  P. Rothemund Folding DNA to create nanoscale shapes and patterns , 2006, Nature.

[57]  R. Fraser The structure of deoxyribose nucleic acid. , 2004, Journal of structural biology.

[58]  David Tollervey,et al.  The function and synthesis of ribosomes , 2001, Nature Reviews Molecular Cell Biology.

[59]  J. Esko,et al.  Dengue virus infectivity depends on envelope protein binding to target cell heparan sulfate , 1997, Nature Medicine.

[60]  F. Crick,et al.  Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid , 1974, Nature.