Turning a Kinase Deoxyribozyme into a Sensor

McManus, Simon A.; Li, Yingfu

doi:10.1021/ja311850u

Cited by 55 publications

(49 citation statements)

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“…1–5 The sequence programmability, automated controllable synthesis, high stability and intrinsic functionalities make DNA nanostructures advantageous over other counterparts in many biomedical applications. Conventional approaches to DNA nanostructure construction typically rely on Watson-Crick base-pairing between short DNA building blocks.…”

Section: Introductionmentioning

confidence: 99%

Noncanonical Self-Assembly of Multifunctional DNA Nanoflowers for Biomedical Applications

et al. 2013

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DNA nanotechnology has been extensively explored to assemble various functional nanostructures for versatile applications. Mediated by Watson-Crick base-pairing, these DNA nanostructures have been conventionally assembled through hybridization of many short DNA building blocks. Here we report the noncanonical self-assembly of multifunctional DNA nanostructures, termed as nanoflowers (NFs), and the versatile biomedical applications. These NFs were assembled from long DNA building blocks generated via Rolling Circle Replication (RCR) of a designer template. NF assembly was driven by liquid crystallization and dense packaging of building blocks, without relying on Watson-Crick base-pairing between DNA strands, thereby avoiding the otherwise conventional complicated DNA sequence design. NF sizes were readily tunable in a wide range, by simply adjusting such parameters as assembly time and template sequences. NFs were exceptionally resistant to nuclease degradation, denaturation, or dissociation at extremely low concentration, presumably resulting from the dense DNA packaging in NFs. The exceptional biostability is critical for biomedical applications. By rational design, NFs can be readily incorporated with myriad functional moieties. All these properties make NFs promising for versatile applications. As a proof-of-principle demonstration, in this study, NFs were integrated with aptamers, bioimaging agents, and drug loading sites, and the resultant multifunctional NFs were demonstrated for selective cancer cell recognition, bioimaging, and targeted anticancer drug delivery.

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Section: Introductionmentioning

confidence: 99%

Noncanonical Self-Assembly of Multifunctional DNA Nanoflowers for Biomedical Applications

et al. 2013

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“…Deoxyribozymes are specific DNA sequences with catalytic activity that have been used to catalyze a variety of reactions, 7 including self-5′-phosphorylation. 8 We have initiated a research program to use deoxyribozymes to perform covalent modification of amino acid side chains in peptide and protein substrates. 9 In the present study, we report that deoxyribozymes can be identified for phosphorylation of tyrosine residues in peptide substrates, using as the phosphoryl donor either a 5′-triphosphorylated RNA oligonucleotide (pppRNA) or guanosine 5′-triphosphate (GTP).…”

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confidence: 99%

DNA Catalysts with Tyrosine Kinase Activity

2013

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We show that DNA catalysts (deoxyribozymes, DNA enzymes) can phosphorylate tyrosine residues of peptides. Using in vitro selection, we identified deoxyribozymes that transfer the γ-phosphoryl group from a 5′-triphosphorylated donor (a pppRNA oligonucleotide or GTP) to the tyrosine hydroxyl acceptor of a tethered hexapeptide. Tyrosine kinase deoxyribozymes that use pppRNA were identified from each of N30, N40, and N50 random-sequence pools. Each deoxyribozyme requires Zn2+, and most additionally require Mn2+. The deoxyribozymes have little or no selectivity for the amino acid identities near the tyrosine, but they are highly selective for phosphorylating tyrosine rather than serine. Analogous GTP-dependent DNA catalysts were identified and found to have apparent Km(GTP) as low as ca. 20 μM. These findings establish that DNA has the fundamental catalytic ability to phosphorylate the tyrosine side chain of a peptide substrate.

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“…The first example, reported by Andrew Ellington's group in 2005, used a two‐piece DNA assembly with an ATP‐dependent DNA‐ligating DNAzyme and its substrate arranged in a special way such that binding of ATP to the aptamer domain activates the ligase DNAzyme, which creates the needed circular DNA template for subsequent RCA reaction . The second example of making the requisite circular template for RCA was reported by our group, with a goal of detecting guanosine‐5′‐triphosphates (GTP) . In this case, a self‐phosphorylating DNAzyme first transfers a γ‐phosphate from GTP to the 5′‐end of the DNAzyme.…”

Section: Isothermal Amplification Of the Action Of Rna‐cleaving Dnazymesmentioning

confidence: 99%

DNAzymes: Selected for Applications

2018

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DNA‐based enzymes, also known as deoxyribozymes or DNAzymes, are single‐stranded DNA molecules with catalytic activity. DNAzymes do not exist in nature but can be isolated from random‐sequence DNA pools using in vitro selection. To date, many DNAzymes that collectively catalyze a diverse range of chemical transformations have been reported. Here, examples of new DNAzymes engineered to mimic some intriguing functions of naturally occurring protein‐based enzymes are discussed. This is followed by discussions of recent examples of a particular class of DNAzymes, known as “RNA‐cleaving DNAzymes”, that have been derived specifically so that their activity is strictly dependent on a given chemical or biological stimulus. Some unique ways to employ ligand‐responsive DNAzymes for the design of bioanalytical assays and biosensors are then highlighted. Being DNA molecules, DNAzymes have proven to be entirely compatible with DNA amplification. Several approaches are then discussed, which relay the activity of an analyte‐activated DNAzyme into the production of massive amounts of DNA amplicons, via “rolling circle amplification”, in biosensing applications designed to deliver very high levels of detection sensitivity.

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Turning a Kinase Deoxyribozyme into a Sensor

Cited by 55 publications

References 50 publications

Noncanonical Self-Assembly of Multifunctional DNA Nanoflowers for Biomedical Applications

Noncanonical Self-Assembly of Multifunctional DNA Nanoflowers for Biomedical Applications

DNA Catalysts with Tyrosine Kinase Activity

DNAzymes: Selected for Applications

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