Features of Auxiliaries That Enable Native Chemical Ligation beyond Glycine and Cleavage via Radical Fragmentation

Loibl, Simon; Dallmann, André; Hennig, Kathleen; Juds, Carmen; Seitz, Oliver

doi:10.1002/chem.201705927

Cited by 24 publications

(28 citation statements)

References 65 publications

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“…Canne et al (1996) introduced another way of circumventing the cysteine moiety by auxiliarated NCL introduced with the N α -(ethanethiol) and N α -(oxyethanethiol)-peptide. In Loibl et al (2018) applied this protocol for cleavage of 2-mercaptoethyl auxiliary group. A recently introduced NCL approach, the diselenide-selenoester ligation (DSL) opens up possibilities for using further amino acids and will be elucidated in the outlook.…”

Section: Follow-up Protocolsmentioning

confidence: 99%

Challenges and Perspectives in Chemical Synthesis of Highly Hydrophobic Peptides

Mueller

Baumruck

Zhdanova

et al. 2020

Front. Bioeng. Biotechnol.

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Solid phase peptide synthesis (SPPS) provides the possibility to chemically synthesize peptides and proteins. Applying the method on hydrophilic structures is usually without major drawbacks but faces extreme complications when it comes to "difficult sequences." These includes the vitally important, ubiquitously present and structurally demanding membrane proteins and their functional parts, such as ion channels, G-protein receptors, and other pore-forming structures. Standard synthetic and ligation protocols are not enough for a successful synthesis of these challenging sequences. In this review we highlight, summarize and evaluate the possibilities for synthetic production of "difficult sequences" by SPPS, native chemical ligation (NCL) and follow-up protocols.

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Section: Follow-up Protocolsmentioning

confidence: 99%

Challenges and Perspectives in Chemical Synthesis of Highly Hydrophobic Peptides

Mueller

Baumruck

Zhdanova

et al. 2020

Front. Bioeng. Biotechnol.

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“…Die Verlagerung des Phenylsubstituenten von der α‐ zur β‐Position verringert den sterischen Anspruch in der Nähe des reaktiven Amins, wodurch das MPE‐Auxiliar auch NCL‐Reaktionen an nicht‐glycinhaltigen Verbindungen wie Ala‐Asn, Leu‐Asn erlaubt und die Ligation mit sterisch anspruchsvolleren Aminosäureresten wie Arg, Met und Gln ermöglicht. Nach der Ligation wird das MPE‐Auxiliar durch eine radikalische Fragmentierungsreaktion entfernt [8b] . Jedoch sind sterisch stark gehinderte Verknüpfungen an β‐verzweigten Aminosäuren auch mit diesem Auxiliar nicht zugänglich.…”

Section: Einführungunclassified

Ein zur Basenkatalyse befähigtes Ligationsauxiliar ermöglicht die cysteinfreie native chemische Ligation an anspruchsvollen Verknüpfungsstellen

et al. 2021

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Ligationsauxiliare werden in der chemischen Proteinsynthese eingesetzt, um den Anwendungsbereich der nativen chemischen Ligation (NCL) über Cystein hinaus zu erweitern. An sterisch anspruchsvollen Ligationsstellen erweisen sich Auxiliar‐vermittelte Ligationen allerdings als schwierig. Oft akkumuliert das im Thiolaustauschschritt der NCL gebildete Thioester‐Intermediat, da der anschließende S→N‐Acyltransfer nur sehr langsam abläuft. In dieser Arbeit stellen wir die 2‐Mercapto‐2‐(pyridin‐2‐yl)ethyl (MPyE)‐Gruppe als das erste Auxiliar vor, welches in der Lage ist, die Ligationsreaktion durch interne Katalyse zu unterstützen. Bemerkenswerterweise liefert das MPyE‐Auxiliar auch dann nützliche Reaktionsraten, wenn Prolin oder eine β‐verzweigte Aminosäure an der Verknüpfung beteiligt sind. Quantenchemische Rechnungen deuten darauf hin, dass der Pyridin‐Stickstoff im geschwindigkeitsbestimmenden Protonentransferschritt als eine intramolekulare Base agiert. Das Auxiliar wird in nur zwei Schritten hergestellt und durch reduktive Alkylierung in das Peptid eingeführt. Die Abspaltung des Auxiliars erfolgt durch Behandlung mit TCEP/Morpholin in Gegenwart eines MnII‐Komplexes als Radikalstarter. Die Synthese eines de novo designten 99mer‐Peptids und eines 80 Aminosäuren langen MUC1‐Peptids demonstrieren die Nützlichkeit des MPyE‐Auxiliars.

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“…A suitable ligation template should provide high reactivity for both the thiol exchange and the S → N acyl migratory steps and must lend itself to facile removal under conditions that leave the ligation product unharmed. We systematically analyzed the architecture of the ligation template and found that the substituents at the α‐ and β‐positions in 15′ play key roles . A comparison of the three mercaptoethyl templates ME, MP, and MPE showed, perhaps surprisingly, that the additional β‐substituents in MP and MPE accelerated the ligation.…”

Section: Unimolecular Templates As Ligation Scaffolds In Protein Syntmentioning

confidence: 99%

“…However, we discovered a potentially general approach for the removal of N‐amide–linked mercaptoethyl groups. Nuclear magnetic resonance (NMR) analysis of a C 13 ‐labelled ligation template suggested that treatment with phosphine in aqueous morpholine at pH 8.5 triggers a radical‐induced oxidative fragmentation (Figure B) . The investigation led us to the 2‐mercapto‐2‐phenethyl (MPE) template, which is the first ligation auxiliary that enables NCL at ligation sites beyond glycine.…”

Section: Unimolecular Templates As Ligation Scaffolds In Protein Syntmentioning

confidence: 99%

“…Typical examples (Figure B) for stand‐alone templates are small molecule scaffolds such as cyclodextrins ( 1 ), calixarenes ( 2 ), and many more as well as larger molecules such as dendrimers ( 3 ), peptides (including oligoproline 4 ), or even entire proteins ( 8 ) or polymers ( 5 ) . In another application scenario, conjugated unimolecular templates are frequently used as reaction scaffolds to facilitate chemical reactions such as ligation auxiliaries in protein synthesis via native chemical ligation (NCL) ( vide infra ) …”

Section: Templatesmentioning

confidence: 99%

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Templated chemistry for bioorganic synthesis and chemical biology

Seitz

2019

Journal of Peptide Science

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In light of the 2018 Max Bergmann Medal, this review discusses advancements on chemical biology–driven templated chemistry developed in the author's laboratories. The focused review introduces the template categories applied to orient functional units such as functional groups, chromophores, biomolecules, or ligands in space. Unimolecular templates applied in protein synthesis facilitate fragment coupling of unprotected peptides. Templating via bimolecular assemblies provides control over proximity relationships between functional units of two molecules. As an instructive example, the coiled coil peptide–templated labelling of receptor proteins on live cells will be shown. Termolecular assemblies provide the opportunity to put the proximity of functional units on two (bio)molecules under the control of a third party molecule. This allows the design of conditional bimolecular reactions. A notable example is DNA/RNA–triggered peptide synthesis. The last section shows how termolecular and multimolecular assemblies can be used to better characterize and understand multivalent protein‐ligand interactions.

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Features of Auxiliaries That Enable Native Chemical Ligation beyond Glycine and Cleavage via Radical Fragmentation

Cited by 24 publications

References 65 publications

Challenges and Perspectives in Chemical Synthesis of Highly Hydrophobic Peptides

Challenges and Perspectives in Chemical Synthesis of Highly Hydrophobic Peptides

Ein zur Basenkatalyse befähigtes Ligationsauxiliar ermöglicht die cysteinfreie native chemische Ligation an anspruchsvollen Verknüpfungsstellen

Templated chemistry for bioorganic synthesis and chemical biology

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