Rational Design of an Organocatalyst for Peptide Bond Formation

Handoko,; Satishkumar, Sakilam; Panigrahi, Nihar R.; Arora, Paramjit S.

doi:10.1021/jacs.9b07742

Cited by 55 publications

(34 citation statements)

References 71 publications

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“…[107] This method has advantages that might be more immediately applicable to peptide chemistry, including low catalyst loadings By contrast, catalytic diselenide activation with the specific aim of achieving a practical catalytic Fmoc peptide synthesis strategy was recently reported by Arora and coworkers. [108] They rationally designed an organocatalyst (Figure 12 Figure 13, 46). [109] The corresponding carbocation is the active catalytic species and can generated in-situ from catalytic amounts of tropone and a slight excess of (COCl) 2 .…”

Section: Organophosphine Catalystsmentioning

confidence: 99%

Recent developments in catalytic amide bond formation

Todorovic

Perrin

2020

Peptide Science

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Amide bond forming reactions are critical for both polypeptide synthesis and medicinal chemistry. Most current approaches for amidation employ stoichiometric activating agents, but such methods are neither atom economical nor synthetically elegant. Catalytic approaches for amidation are potentially green and more ideal substitutes for current standard methods and thus are the subject of this review. Such methods face significant thermodynamic and kinetic barriers and have, as a result, historically

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Section: Organophosphine Catalystsmentioning

confidence: 99%

Recent developments in catalytic amide bond formation

Todorovic

Perrin

2020

Peptide Science

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“…Arora et al developed the catalyst structure further,a nd realized direct condensation reactions between carboxylic acids and amines (Scheme 4). [158] The diselenidem oiety is ac haracteristics tructure of catalyst 37,a nd reduction and oxidation of the diselenide moiety is the key to the catalytic re- action. The diselenide is reduced by tributylphosphine and the carboxyg roup is converted to as elenoester.A na mide bond is formed by nucleophilic attack of the amine on the selenoester, then the catalyst is regenerated by oxidation of the bis-selenolate.…”

Section: Catalytic Reactionsmentioning

confidence: 99%

Section: Intermolecular Hydrogen Bonding Of Urea and Other Speciesmentioning

confidence: 99%

Urea Derivatives as Functional Molecules: Supramolecular Capsules, Supramolecular Polymers, Supramolecular Gels, Artificial Hosts, and Catalysts

Yokoya

Kimura

Yamanaka

2021

Chemistry A European J

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Urea, which has both hydrogen bond acceptor and donor moieties, is an ideal structuref or as upramolecular synthon. Various supramolecules having ureido group(s) have been widelyd eveloped. This article summarizes recent developments of urea derivatives that exhibit various functions:i)supramolecular capsules that form discreteu reaurea intermolecular hydrogen bonds, ii)supramolecular polymers that form continuous urea-urea intermolecularh ydrogen bonds, iii)supramolecular gels that form continuous urea-urea intermolecular hydrogen bonds, iv) artificialh ost molecules based on the molecular recognition ability of the ureido group, and v) catalytic reactions developedb yu tilizing the molecular recognition ability of the ureido group.

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“…Can these methods be used in AFPS and can we develop even more reactive active esters? Can catalytical methods for amide bond formation [ 130–134,135 ] be translated into flow chemistry? And can these methods be used for the synthesis of long peptides or even proteins?…”

Section: Related Research Areas and Future Directionsmentioning

confidence: 99%

Flow‐based SPPS for protein synthesis: A perspective

Gates

Hartrampf

2020

Peptide Science

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Flow‐based approaches to solid phase peptide synthesis (SPPS) have been pursued since the method's early days, with anticipated gains in speed, reaction monitoring, and ease of automation. Here, we discuss how these advantages are being realized by synthesis at elevated temperature, facilitated by a 'preheat/activation' loop. This important modification both accelerates peptide synthesis—providing a wealth of new data from in‐line monitoring—and in conjunction with an optimized protocol, extends the length of peptides routinely accessible by stepwise synthesis. Streamlined synthesis of longer peptides will address a major challenge in chemical protein synthesis: preparation of peptide segments for use in chemical ligation. The context of recent results in flow‐based SPPS is discussed, highlighting remaining challenges and future opportunities.

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Rational Design of an Organocatalyst for Peptide Bond Formation

Cited by 55 publications

References 71 publications

Recent developments in catalytic amide bond formation

Recent developments in catalytic amide bond formation

Urea Derivatives as Functional Molecules: Supramolecular Capsules, Supramolecular Polymers, Supramolecular Gels, Artificial Hosts, and Catalysts

Flow‐based SPPS for protein synthesis: A perspective

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