Glenn A. Burley scite author profile

[reaction: see text] We report the development of the Cu(I)-catalyzed Huisgen cycloaddition (click) reaction for the multiple postsynthetic labeling of alkyne-modified DNA. A series of alkyne-modified oligodeoxyribonucleotides (ODNs) of increasing alkyne density were prepared, and the click reaction using various azide labels was investigated. Complete high-density conversion was observed for ODNs containing up to six consecutive alkyne functions. Compatibility of the click conditions with long DNA strands was shown using a PCR product obtained with an alkyne-modified primer.

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Nucleic acid and nucleotide-mediated synthesis of inorganic nanoparticles

Berti¹,

2008

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Since the advent of practical methods for achieving DNA metallization, the use of nucleic acids as templates for the synthesis of inorganic nanoparticles (NPs) has become an active area of study. It is now widely recognized that nucleic acids have the ability to control the growth and morphology of inorganic NPs. These biopolymers are particularly appealing as templating agents as their ease of synthesis in conjunction with the possibility of screening nucleotide composition, sequence and length, provides the means to modulate the physico-chemical properties of the resulting NPs. Several synthetic procedures leading to NPs with interesting photophysical properties as well as studies aimed at rationalizing the mechanism of nucleic acid-templated NP synthesis are now being reported. This progress article will outline the current understanding of the nucleic acid-templated process and provides an up to date reference in this nascent field.

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Directed DNA Metallization

Burley¹,

Gierlich²,

Mofid³

et al. 2006

J. Am. Chem. Soc.

286

185

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Genes of interest can be selectively metallized via the incorporation of modified triphosphates. These triphosphates bear functions that can be further derivatized with aldehyde groups via the use of click chemistry. Treatment of the aldehyde-labeled gene mixture with the Tollens reagent, followed by a development process, results in the selective metallization of the gene of interest in the presence of natural DNA strands.

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PROTAC-Mediated Degradation of Bruton’s Tyrosine Kinase Is Inhibited by Covalent Binding

et al. 2019

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The impact of covalent binding on PROTAC-mediated degradation of BTK was investigated through the preparation of both covalent binding and reversible binding PROTACs derived from the covalent BTK inhibitor ibrutinib. It was determined that a covalent binding PROTAC inhibited BTK degradation despite evidence of target engagement, while BTK degradation was observed with a reversible binding PROTAC. These observations were consistently found when PROTACs were employed that were able to recruit either IAP or cereblon E3 ligases. Proteomics analysis determined that use of a covalently bound PROTAC did not result in the degradation of covalently bound targets, whilst degradation was observed for some reversibly bound targets. This observation highlights the importance of catalysis on successful PROTAC-mediated degradation, and highlights a potential caveat for the use of covalent target binders in PROTAC design.Protein degrading bifunctional molecules are emerging as a novel drug discovery strategy with the potential to offer pharmacologic control of biology that is not currently achievable with existing small molecule medicines. 1-3 Mechanistic hallmarks of proteolysis-targeting chimeras (PROTACs) include high cellular degradation potency (DC50, the concentration at which 50% of substrate is degraded) high target selectivity, and extended pharmacodynamic duration of action that is dependent upon both drug pharmacokinetics and target protein resynthesis rate. 4, 5 The targeted protein degradation paradigm is driven by the ability of PROTACs to catalytically promote the degradation of a desired protein in an event-driven process. This contrasts with occupancy-driven pharmacology that is characteristic of traditional small molecule inhibitors. 3

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Formation of Bimetallic Ag–Au Nanowires by Metallization of Artificial DNA Duplexes

Fischler

Simon

Nir

et al. 2007

Small

107

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Uniform bimetallic nanowires, tunable in size, have been grown on artificial DNA templates via a two-step metallization process. Alkyne-modified cytosines were incorporated into 900-base-pair polymerase-chain-reaction fragments. The alkyne modifications serve as addressable metal-binding sites after conversion to a sugar triazole derivative via click chemistry. Reaction of the Tollens reagent with these sugar-coated DNA duplexes generates Ag0 metallization centers around the sugar modification sites of the DNA. After a subsequent enhancement step using gold, nanowires < or = 10 nm in diameter with a homogeneous surface profile were obtained. Furthermore, the advantage of this two-step procedure lies in the high selectivity of the process, due to the exact spatial control of modified DNA base incorporation and hence the confinement of metallization centers at addressable sites. Besides experiments on a membrane as a proof for the selectivity of the method, atomic force microscopy (AFM) studies of the wires produced on Si-SiO2 surfaces are discussed. Furthermore, we demonstrate time-dependent metallization experiments, monitored by AFM.

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Glenn A. Burley

Click Chemistry as a Reliable Method for the High-Density Postsynthetic Functionalization of Alkyne-Modified DNA

Nucleic acid and nucleotide-mediated synthesis of inorganic nanoparticles

Directed DNA Metallization

PROTAC-Mediated Degradation of Bruton’s Tyrosine Kinase Is Inhibited by Covalent Binding

Formation of Bimetallic Ag–Au Nanowires by Metallization of Artificial DNA Duplexes

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