Construction of Challenging Proline−Proline Junctions via 2 Diselenide−Selenoester Ligation Chemistry
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Open Access
Type
ArticleAuthor/s
Sayers, JessicaKarpati, Phillip M. T.
Mitchell, Nicholas J.
Goldys, Anna M.
Kwong, Stephen M.
Firth, Neville
Chan, Bun
Payne, Richard J.
Abstract
Polyproline sequences are highly abundant in prokaryotic and eukaryotic proteins, where they serve as key components of secondary structure. To date, construction of the proline–proline motif has not been possible owing to steric congestion at the ligation junction, together with ...
See morePolyproline sequences are highly abundant in prokaryotic and eukaryotic proteins, where they serve as key components of secondary structure. To date, construction of the proline–proline motif has not been possible owing to steric congestion at the ligation junction, together with an n → π* electronic interaction that reduces the reactivity of acylated proline residues at the C-terminus of peptides. Here, we harness the enhanced reactivity of prolyl selenoesters and a trans-γ-selenoproline moiety to access the elusive proline–proline junction for the first time through a diselenide–selenoester ligation–deselenization manifold. The efficient nature of this chemistry is highlighted in the high-yielding one-pot assembly of two proline-rich polypeptide targets, submaxillary gland androgen regulated protein 3B and lumbricin-1. This method provides access to the most challenging of ligation junctions, thus enabling the construction of previously intractable peptide and protein targets of increasing structural complexity.
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See morePolyproline sequences are highly abundant in prokaryotic and eukaryotic proteins, where they serve as key components of secondary structure. To date, construction of the proline–proline motif has not been possible owing to steric congestion at the ligation junction, together with an n → π* electronic interaction that reduces the reactivity of acylated proline residues at the C-terminus of peptides. Here, we harness the enhanced reactivity of prolyl selenoesters and a trans-γ-selenoproline moiety to access the elusive proline–proline junction for the first time through a diselenide–selenoester ligation–deselenization manifold. The efficient nature of this chemistry is highlighted in the high-yielding one-pot assembly of two proline-rich polypeptide targets, submaxillary gland androgen regulated protein 3B and lumbricin-1. This method provides access to the most challenging of ligation junctions, thus enabling the construction of previously intractable peptide and protein targets of increasing structural complexity.
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Date
2018-09-21Publisher
American Chemical SocietyFunding information
ARC DP160101324Licence
OtherFaculty/School
Faculty of ScienceCitation
Jessica Sayers, Phillip M. T. Karpati, Nicholas J. Mitchell, Anna M. Goldys, Stephen M. Kwong, Neville Firth, Bun Chan, and Richard J. Payne , Construction of Challenging Proline–Proline Junctions via Diselenide–Selenoester Ligation Chemistry, Journal of the American Chemical Society 2018 140 (41), 13327-13334 DOI: 10.1021/jacs.8b07877Share