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A Cleavable C2-Symmetric trans-Cyclooctene Enables Fast and Complete Bioorthogonal Disassembly of Molecular Probes.


ABSTRACT: Bioorthogonal chemistry is bridging the divide between static chemical connectivity and the dynamic physiologic regulation of molecular state, enabling in situ transformations that drive multiple technologies. In spite of maturing mechanistic understanding and new bioorthogonal bond-cleavage reactions, the broader goal of molecular ON/OFF control has been limited by the inability of existing systems to achieve both fast (i.e., seconds to minutes, not hours) and complete (i.e., >99%) cleavage. To attain the stringent performance characteristics needed for high fidelity molecular inactivation, we have designed and synthesized a new C2-symmetric trans-cyclooctene linker (C2TCO) that exhibits excellent biological stability and can be rapidly and completely cleaved with functionalized alkyl-, aryl-, and H-tetrazines, irrespective of click orientation. By incorporation of C2TCO into fluorescent molecular probes, we demonstrate highly efficient extracellular and intracellular bioorthogonal disassembly via omnidirectional tetrazine-triggered cleavage.

SUBMITTER: Wilkovitsch M 

PROVIDER: S-EPMC7662912 | biostudies-literature | 2020 Nov

REPOSITORIES: biostudies-literature

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A Cleavable C<sub>2</sub>-Symmetric <i>trans</i>-Cyclooctene Enables Fast and Complete Bioorthogonal Disassembly of Molecular Probes.

Wilkovitsch Martin M   Haider Maximilian M   Sohr Barbara B   Herrmann Barbara B   Klubnick Jenna J   Weissleder Ralph R   Carlson Jonathan C T JCT   Mikula Hannes H  

Journal of the American Chemical Society 20201029 45


Bioorthogonal chemistry is bridging the divide between static chemical connectivity and the dynamic physiologic regulation of molecular state, enabling in situ transformations that drive multiple technologies. In spite of maturing mechanistic understanding and new bioorthogonal bond-cleavage reactions, the broader goal of molecular ON/OFF control has been limited by the inability of existing systems to achieve both fast (i.e., seconds to minutes, not hours) and complete (i.e., >99%) cleavage. To  ...[more]

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