Modular Strategy To Expand the Chemical Diversity of DNA and Sequence-Controlled Polymers

Sequence-defined polymers with customizable sequences, monodispersity, substantial length, and large chemical diversity are of great interest to mimic the efficiency and selectivity of biopolymers. We report an efficient, facile, and scalable synthetic route to introduce many chemical functionalitie...

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Veröffentlicht in:	Journal of organic chemistry 2018-09, Vol.83 (17), p.9774-9786
Hauptverfasser:	de Rochambeau, Donatien, Sun, Yuanye, Barlog, Maciej, Bazzi, Hassan S, Sleiman, Hanadi F
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Sprache:	eng
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container_end_page	9786
container_issue	17
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container_title	Journal of organic chemistry
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creator	de Rochambeau, Donatien Sun, Yuanye Barlog, Maciej Bazzi, Hassan S Sleiman, Hanadi F
description	Sequence-defined polymers with customizable sequences, monodispersity, substantial length, and large chemical diversity are of great interest to mimic the efficiency and selectivity of biopolymers. We report an efficient, facile, and scalable synthetic route to introduce many chemical functionalities, such as amino acids and sugars in nucleic acids and sequence-controlled oligophosphodiesters. Through achiral tertiary amine molecules that are perfectly compatible with automated DNA synthesis, readily available amines or azides can be turned into phosphoramidites in two steps only. Individual attachment yields on nucleic acids and artificial oligophosphodiesters using automated solid-phase synthesis (SPS) were >90% in almost all cases. Using this method, multiple water-soluble sequence-defined oligomers bearing a range of functional groups in precise sequences could be synthesized and purified in high yields. The method described herein significantly expands the library of available functionalities for nucleic acids and sequence-controlled polymers.
doi_str_mv	10.1021/acs.joc.8b01184
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title	Modular Strategy To Expand the Chemical Diversity of DNA and Sequence-Controlled Polymers
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