Copper-free click chemistry for dynamic
            <i>in vivo</i>
            imaging

Baskin, Jeremy M.; Prescher, Jennifer A.; Laughlin, Scott T.; Agard, Nicholas J.; Chang, Pamela V.; Miller, Isaac A.; Lo, Anderson; Codelli, Julian A.; Bertozzi, Carolyn R.

doi:10.1073/pnas.0707090104

Cited by 1,658 publications

(1,461 citation statements)

References 28 publications

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“…Replacement of an alkyne with an azide group in P2 ( 7 a ) had no detrimental effect on the antimalarial potency of the trioxolane azide probe as indicated in Figure S2, Figure 3 and Table S1. However, the labeling profile intensity with P2 ( 7 a ) was much higher compared to P1 ( 6 a ) (Figure 3 c,d) suggesting greater efficiency of the copper‐free click reaction 8b. Reduction of P2 ( 7 a ) concentrations to 100 n m (LC90) had no impact on the labeling pattern observed (Figure 3 f).…”

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confidence: 95%

A Click Chemistry‐Based Proteomic Approach Reveals that 1,2,4‐Trioxolane and Artemisinin Antimalarials Share a Common Protein Alkylation Profile

et al. 2016

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In spite of the recent increase in endoperoxide antimalarials under development, it remains unclear if all these chemotypes share a common mechanism of action. This is important since it will influence cross‐resistance risks between the different classes. Here we investigate this proposition using novel clickable 1,2,4‐trioxolane activity based protein‐profiling probes (ABPPs). ABPPs with potent antimalarial activity were able to alkylate protein target(s) within the asexual erythrocytic stage of Plasmodium falciparum (3D7). Importantly, comparison of the alkylation fingerprint with that generated from an artemisinin ABPP equivalent confirms a highly conserved alkylation profile, with both endoperoxide classes targeting proteins in the glycolytic, hemoglobin degradation, antioxidant defence, protein synthesis and protein stress pathways, essential biological processes for plasmodial survival. The alkylation signatures of the two chemotypes show significant overlap (ca. 90 %) both qualitatively and semi‐quantitatively, suggesting a common mechanism of action that raises concerns about potential cross‐resistance liabilities.

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confidence: 95%

A Click Chemistry‐Based Proteomic Approach Reveals that 1,2,4‐Trioxolane and Artemisinin Antimalarials Share a Common Protein Alkylation Profile

et al. 2016

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“…[17] By monitoring the disappearance of the characteristic tetrazine absorption band at 520 nm, we measured a second-order rate constant of 0.137 ±0.004M −1 s −1 at 37°C in a solution of water/ DMSO (12% DMSO by volume; Figure 2c). Although this rate constant is comparable to previous bioorthogonal labeling strategies, [8] it is much slower than the reaction of other strained alkenes with tetrazine, such as trans-cyclooctene and even norbornene. [1] Faster kinetics would improve coupling yields, particularly for applications where it is not possible to flood the target with a large excess of reactant, for example in live-cell intracellular labeling or in vivo.…”

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confidence: 76%

“…[1,6] This situation is in contrast to Staudinger ligations or strain-promoted azide-cycloalkyne cycloadditions that utilize a small azide functional group. [7,8] This requirement has limited the use of tetrazine reactions in methods that require tags with minimal steric impact or nominal effect on the partition ratio. [2] The development of smaller dienophile partners capable of reacting rapidly with tetrazines would therefore represent a major advance.…”

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confidence: 99%

Live‐Cell Imaging of Cyclopropene Tags with Fluorogenic Tetrazine Cycloadditions

et al. 2012

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There is growing interest in the use of inverse Diels-Alder tetrazine cycloadditions as rapid catalyst-free bioorthogonal reactions. [1][2][3] Fluorogenic tetrazines that increase in fluorescence after reaction with dienophiles are particularly useful for live-cell imaging applications. [4] Fluorogenic tetrazines have been recently used for live-cell imaging of small molecules, biomolecules tagged enzymatically with dienophiles, and proteins modified by reactive unnatural amino acids. [4,5] Although fluorogenic tetrazine probes hold great potential for intracellular imaging of small molecules, previous approaches are limited by requiring a large strained dienophile, such as trans-cyclooctene, cyclooctyne, or norbornene. [1,6] This situation is in contrast to Staudinger ligations or strain-promoted azide-cycloalkyne cycloadditions that utilize a small azide functional group. [7,8] This requirement has limited the use of tetrazine reactions in methods that require tags with minimal steric impact or nominal effect on the partition ratio. [2] The development of smaller dienophile partners capable of reacting rapidly with tetrazines would therefore represent a major advance. However, it has been unclear whether small dienophiles could be developed that react rapidly with tetrazines while maintaining their stability. Herein, we demonstrate the applicability of methylcyclopropene tags as dienophiles for reaction with fluorogenic tetrazines. Through systematic synthetic modifications we have optimized the stability, size, and reactivity of the cyclopropene scaffold. We have developed methylcyclopropene derivatives that react rapidly with tetrazines while retaining their aqueous stability and small size. These cyclopropene handles elicit fluorescent responses from quenched tetrazine dyes and are suitable for cellular imaging applications, which we demonstrate by imaging cyclopropene phospholipids distributed in live human breast cancer cells.The use of cyclopropenes offers a possible approach to smaller dienophile partners for tetrazine cycloadditions. It has long been known that cyclopropenes react rapidly with tetrazines to form stable diazanorcaradienes (Figure 1a). [9] In seminal work, Sauer and coworkers demonstrated that unsubstituted cyclopropene reacts with dimethyl 1,2,4,5-** We greatly acknowledge Ralph Mazitschek, Michael Hardy, and Carlos Guerrero for helpful discussions.

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“…And third, the required strained cyclic alkynes are available only following long synthetic sequences. 8 Thus, a void exists in the field of chemical biology for a fast, reliable, copper-free, solid-phase oligonucleotide conjugation strategy which will proceed under physiological conditions.…”

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confidence: 99%

Fast, copper-free click chemistry: a convenient solid-phase approach to oligonucleotide conjugation

2009

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Copper-free click chemistry for dynamic in vivo imaging

Cited by 1,658 publications

References 28 publications

A Click Chemistry‐Based Proteomic Approach Reveals that 1,2,4‐Trioxolane and Artemisinin Antimalarials Share a Common Protein Alkylation Profile

A Click Chemistry‐Based Proteomic Approach Reveals that 1,2,4‐Trioxolane and Artemisinin Antimalarials Share a Common Protein Alkylation Profile

Live‐Cell Imaging of Cyclopropene Tags with Fluorogenic Tetrazine Cycloadditions

Fast, copper-free click chemistry: a convenient solid-phase approach to oligonucleotide conjugation

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