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      Native chemical ligation in protein synthesis and semi-synthesis

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          Abstract

          Combining modern synthetic and molecular biology toolkits, native chemical ligation and expressed protein ligation enables robust access to modified proteins.

          Abstract

          Native chemical ligation (NCL) provides a highly efficient and robust means to chemoselectively link unprotected peptide and protein segments to generate proteins. The ability to incorporate non-proteinogenic amino acids ( e.g. d-amino acids or fluorescent labels) and post-translational modifications into proteins by stitching together peptide fragments has driven extremely important developments in peptide and protein science over the past 20 years. Extensions of the original NCL concept (including the development of thiol- and selenol-derived amino acids and desulfurisation and deselenisation methods), improved access to peptide thioesters, and the use of the methodology in combination with recombinantly expressed polypeptide fragments (termed Expressed Protein Ligation, EPL) have helped to further expand the utility of the methodology. Over the past five years, there has been a dramatic increase in the number of proteins that have been accessed by total chemical synthesis and semi-synthesis, including a large range of modified proteins; new records have also been set with regards to the size of proteins that can now be accessed via ligation chemistry. Together these efforts have not only contributed to a better understanding of protein structure and function, but have also driven innovations in protein science. In this tutorial review, we aim to provide the reader with the latest developments in NCL- and EPL-based ligation technologies as well as illustrated examples of using these methods, together with synthetic logic, to access proteins and modified proteins for biological study.

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          Most cited references46

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          Total chemical synthesis of proteins.

          This tutorial review outlines the modern ligation methods that enable the efficient total chemical synthesis of enzymes and other protein molecules. Key to this success is the chemoselective reaction of unprotected synthetic peptides ('chemical ligation'). Notably, native chemical ligation enables the reaction of two unprotected peptides in aqueous solution at neutral pH to form a single product in near quantitative yield. Full-length synthetic polypeptides are folded to form the defined tertiary structure of the target protein molecule, which is characterized by mass spectrometry, NMR, and X-ray crystallography, in addition to biochemical and/or biological activity.
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            Free-radical-based, specific desulfurization of cysteine: a powerful advance in the synthesis of polypeptides and glycopolypeptides.

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              Inteins: Nature's Gift to Protein Chemists.

              Inteins are auto-processing domains found in organisms from all domains of life. These proteins carry out a process known as protein splicing, which is a multi-step biochemical reaction comprised of both the cleavage and formation of peptide bonds. While the endogenous substrates of protein splicing are specific essential proteins found in intein-containing host organisms, inteins are also functional in exogenous contexts and can be used to chemically manipulate virtually any polypeptide backbone. Given this, protein chemists have exploited various facets of intein reactivity to modify proteins in myriad ways for both basic biological research as well as potential therapeutic applications. Here, we review the intein field, first focusing on the biological context and phylogenetic diversity of inteins, followed by a description of intein structure and biochemical function. Finally, we discuss prevalent inteinbased technologies, focusing on their applications in chemical biology, followed by persistent caveats of intein chemistry and approaches to alleviate these shortcomings. The findings summarized herein describe two and a half decades of research, leading from a biochemical curiosity to the development of powerful protein engineering tools.
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                Author and article information

                Journal
                CSRVBR
                Chemical Society Reviews
                Chem. Soc. Rev.
                Royal Society of Chemistry (RSC)
                0306-0012
                1460-4744
                December 10 2018
                2018
                : 47
                : 24
                : 9046-9068
                Affiliations
                [1 ]Faculty of Chemistry
                [2 ]Institute of Biological Chemistry
                [3 ]University of Vienna
                [4 ]Vienna
                [5 ]Austria
                [6 ]School of Chemistry
                [7 ]The University of Sydney
                [8 ]Sydney
                [9 ]Australia
                Article
                10.1039/C8CS00573G
                30418441
                a9e16c61-ebbe-4d08-ab34-964a5fab86ec
                © 2018

                http://rsc.li/journals-terms-of-use

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