Carson M Key scite author profile

Researchers have worked for many decades to master the rules of biomolecular design that would allow artificial biopolymer complexes to self-assemble and function similarly to the diverse biochemical constructs displayed in natural biological systems. The rules of nucleic acid assembly (dominated by Watson–Crick base-pairing) have been less difficult to understand and manipulate than the more complicated rules of protein folding. Therefore, nucleic acid nanotechnology has advanced more quickly than de novo protein design, and recent years have seen amazing progress in DNA and RNA design. By combining structural motifs with aptamers that act as affinity handles and add powerful molecular recognition capabilities, nucleic acid-based self-assemblies represent a diverse toolbox for use by bioengineers to create molecules with potentially revolutionary biological activities. In this review, we focus on the development of self-assembling nucleic acid nanostructures that are functionalized with nucleic acid aptamers and their great potential in wide ranging application areas.

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Genetically Encoded, Functional Single‐Strand RNA Origami: Anticoagulant

Krissanaprasit

Key

Fergione

et al. 2019

Advanced Materials

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Nucleic acid aptamers selected for thrombin binding have previously been shown to possess anticoagulant activity, however problems with rapid renal clearance and short circulation half-life prevented translation to clinical usefulness. Here, we describe a family of self-folding, functional RNA origami molecules bearing multiple thrombin-binding RNA aptamers and showing significantly improved anticoagulant activity. These constructs may overcome earlier problems preventing clinical use of nucleic acid anticoagulants. RNA origami structures were designed in silico and produced by in vitro transcription from DNA templates. Incorporation of 2'-fluoro-modified C-and U-nucleotides was shown to increase nuclease resistance and stability during long-term storage. We demonstrate specific binding to human thrombin as well as high stability in the presence of RNase A and in human plasma, comparatively more stable than DNA. The RNA origami constructs show anticoagulant activity seven-fold greater than free aptamer and higher than previous DNA weave tiles decorated with DNA aptamers. Anticoagulation activity was maintained after at least three months of storage in buffer at 4°C. Additionally, inhibition of thrombin is shown to be reversed by addition of single-stranded DNA antidotes. This project paves the way for development of RNA origami for potential therapeutic applications especially as a safer surgical anticoagulant.

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Multivalent Aptamer‐Functionalized Single‐Strand RNA Origami as Effective, Target‐Specific Anticoagulants with Corresponding Reversal Agents

Krissanaprasit

Key

Froehlich

et al. 2021

Adv Healthcare Materials

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Anticoagulants are commonly utilized during surgeries and to treat thrombotic diseases like stroke and deep vein thrombosis. However, conventional anticoagulants have serious side-effects, narrow therapeutic windows, and lack safe reversal agents (antidotes). Here, an alternative RNA origami displaying RNA aptamers as target-specific anticoagulant is described. Improved design and construction techniques for self-folding, single-molecule RNA origami as a platform for displaying pre-selected RNA aptamers with precise orientational and spatial control are reported. Nuclease resistance is added using 2′-fluoro-modified pyrimidines during in vitro transcription. When four aptamers are displayed on the RNA origami platform, the measured thrombin inhibition and anticoagulation activity is higher than observed for free aptamers, ssRNA-linked RNA aptamers, and RNA origami displaying fewer aptamers. Importantly, thrombin inhibition is immediately switched off by addition of specific reversal agents. Results for single-stranded DNA (ssDNA) and single-stranded peptide nucleic acid (PNA) antidotes show restoration of 63% and 95% coagulation activity, respectively. To demonstrate potential for practical, long-term storage for clinical use, RNA origami is freeze-dried, and stored at room temperature. Freshly produced and freeze-dried RNA show identical levels of activity in coagulation assays. Compared to current commercial intravenous anticoagulants, RNA origami-based molecules show promise as safer alternatives with rapid activity switching for future therapeutic applications.

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Enhanced Anticoagulation Activity of Functional RNA Origami

Krissanaprasit

Key

Froehlich

et al. 2020

Preprint

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Anticoagulants are commonly utilized during surgeries and to treat thrombotic diseases like stroke and deep vein thrombosis. However, conventional anticoagulants have serious side-effects, narrow therapeutic windows, and lack safe reversal agents (antidotes). Here, an alternative RNA origami displaying RNA aptamers as target-specific anticoagulant, is described. Improved design and construction techniques for self-folding, single-molecule RNA origami as a platform for displaying pre-selected RNA aptamers with precise orientational and spatial control, are reported. Nuclease resistance is added using 2'-fluoro-modified pyrimidines during in vitro transcription. When four aptamers are displayed on the RNA origami platform, the measured thrombin inhibition and anticoagulation activity is higher than observed for free aptamers, ssRNA-linked RNA aptamers, and RNA origami displaying fewer aptamers. Importantly, thrombin inhibition is immediately switched off by addition of specific reversal agents. Results for ssDNA and ssPNA (peptide nucleic acid) antidotes show restoration of 75% and 95% coagulation activity, respectively. To demonstrate potential for practical, long-term storage for clinical use, RNA origami was freeze-dried, and stored at room temperature. Freshly produced and freeze-dried RNA show identical levels of activity in coagulation assays. Compared to current commercial intravenous anticoagulants, RNA origami-based molecules show promise as safer alternatives with rapid activity switching for future therapeutic applications.

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Production and Testing of RNA Origami Anticoagulants

Krissanaprasit

Key

Froehlich

et al. 2023

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Carson M Key

Self-Assembling Nucleic Acid Nanostructures Functionalized with Aptamers

Genetically Encoded, Functional Single‐Strand RNA Origami: Anticoagulant

Multivalent Aptamer‐Functionalized Single‐Strand RNA Origami as Effective, Target‐Specific Anticoagulants with Corresponding Reversal Agents

Enhanced Anticoagulation Activity of Functional RNA Origami

Production and Testing of RNA Origami Anticoagulants

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