The Removal of <i>S</i>‐Cysteine Protection by Means of 2‐Pyridine Sulfenyl Chloride and the Subsequent Formation of Disulfide Bonds. Preliminary communication

Castell, José V.; Tun‐Kyi, A.

doi:10.1002/hlca.19790620744

Cited by 31 publications

(14 citation statements)

References 9 publications

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“…[46] The addition of slight excesses of strong acids,such as hydrochloric acid to possibly protonate the indole group,orofAc-Trp-OH, as ascavenger, were found to be equally as effective. [48] Although the rate of thiolysis increases as the pH increases,the rate of disproportionation is concomitantly enhanced, thereby leading to accumulation of symmetric disulfides.N evertheless,t he rates are sufficiently high even at pH 5-7;however, the authors used pH 8.5, which led to al arge accumulation of the B-chain homodimer and consequently to the poor yield of 15 %ofthe HPLC-purified heterodimer.This reaction has been significantly improved by the use of 3-nitro-2-pyridylsulfanyl- [49] and more recently of 5-nitro-2-pyridylsulfanylcysteine [50] derivatives,which allow for high rates of thiolysis even at pH 3.5-6, where such side reactions are completely suppressed. This allowed Kiso and co-workers to use established cysteinepairing procedures for the sequential, unambiguous formation of the human insulin heterodimer,a so utlined in Scheme 6.…”

Section: Angewandte Chemiementioning

confidence: 99%

Insulin—From its Discovery to the Industrial Synthesis of Modern Insulin Analogues

Moröder

Musiol

2017

Angew Chem Int Ed

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After the discovery of insulin as a drug for diabetes, the pharmaceutical companies were faced with the challenge to meet the demand for insulin with the highest possible degree of purity in the required quantities from animal sources. The observation of an immune reaction of patients to insulin from animal pancreatic extracts made the availability of human insulin of highest priority. Only the enzyme-catalyzed semisynthesis at the C-terminus of the insulin B-chain led to a commercial process, but it depended on porcine insulin and was aggravated by supply concerns. The advent of rDNA technology allowed the commercial preparation of human insulin by biosynthesis in virtually unlimited quantities. An increased chemical diversity was only envisaged through chemical synthesis, which was simplified by advances in solid-phase peptide synthesis and chemical ligation. Single-chain insulin precursors are now being synthesized that should enable fast screening of insulin analogues for improved biophysical, biological, and thus promising new therapeutic properties, as well as for the industrial manufacture of insulin analogues not accessible by biosynthesis.

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Section: Angewandte Chemiementioning

confidence: 99%

Insulin—From its Discovery to the Industrial Synthesis of Modern Insulin Analogues

Moröder

Musiol

2017

Angew Chem Int Ed

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“…Further electron‐withdrawing activating group such as 2‐ and 4‐nitrophenyl ( S ‐Nps) and 2‐ and 4‐pyridyl groups ( S ‐Pyr) have been used because the disulfide formation is promoted by the low p K a of the aromatic thiol leaving group (Scheme C). The introduction of thiol reactive moieties by 2‐pyridinesulfenyl chloride is, however, susceptible to hydrolysis . An alternative strategy includes N‐terminal‐thiol deprotection followed by activation with excess 2,2′‐dipyridyldisulfide and coupling with a free thiol in the presence of DTT at pH 7 .…”

Section: Synthesis Of Polypeptidesmentioning

confidence: 99%

Of Thiols and Disulfides: Methods for Chemoselective Formation of Asymmetric Disulfides in Synthetic Peptides and Polymers

Schäfer

Barz

2018

Chemistry A European J

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In protein or peptide chemistry, thiols are frequently chosen as a chemical entity for chemoselective modification reactions. Although it is a well-established methodology to address cysteines and homocysteines in aqueous media to form S-C bonds, possibilities for the chemoselective formation of asymmetric disulfides have been less approached. Focusing on bioreversibility in conjugation chemistry, the formation of disulfide bonds is highly desirable for the attachment of thiol-containing bioactive agents to proteins or in cross-linking reactions, because disulfide bonds can combine stability in blood with degradability inside cells. In this Concept article, recent approaches in the field of activating groups for thiol moieties incorporated in peptide and polymer materials are highlighted. Advantageous combinations of stability during synthesis of the material with high reactivity towards thiols are explored focusing on simplification and prevention of side reactions as well as additional deprotection and activation steps prior to disulfide formation. Moreover, applications of this chemistry are highlighted and future perspectives are envisioned.

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“…PyS has been proposed for deprotection of cysteine protected with Trt, Dpm, Acm, Bu t , and SBu t groups and subsequent preparation of asymmetrical disulfides. 108 Reactions with this reagent are carried out in glacial acetic acid. The reactive mixed disulfide formed reacts with a free SH group to give the target disulfide.…”

Section: Sulfoxides In the Presence Of Silyl Chloridesmentioning

confidence: 99%

“…Free SH groups may be liberated by the action of an excess of thiols (e.g., b-mercaptoethanol). 108 Nps-Cl was used to remove Trt, Dpm, Ddm, and Acm protections 109 and intermediate mixed disulfides can be isolated. Free SH-derivatives can be obtained under the action of an excess of a thiol (e.g., b-mercaptoethanol or dithiothreitol).…”

Section: Sulfoxides In the Presence Of Silyl Chloridesmentioning

confidence: 99%

“…Deprotection and formation of disulfide bonds using Nps-Cl occur much more slowly than with PyS-Cl. 108 The use of aromatic sulfenyl halides is limited because of difficulties associated with their synthesis and isolation (these compounds are easily hydrolysed even in humid air) and due to the fact that tryptophan can undergo side reactions under the action of these compounds.…”

Section: Sulfoxides In the Presence Of Silyl Chloridesmentioning

confidence: 99%

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Some peculiarities of synthesis of cysteine-containing peptides

Kudryavtseva¹,

Sidorova²,

Evstigneeva³

1998

Russ. Chem. Rev.

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The Removal of S‐Cysteine Protection by Means of 2‐Pyridine Sulfenyl Chloride and the Subsequent Formation of Disulfide Bonds. Preliminary communication

Cited by 31 publications

References 9 publications

Insulin—From its Discovery to the Industrial Synthesis of Modern Insulin Analogues

Insulin—From its Discovery to the Industrial Synthesis of Modern Insulin Analogues

Of Thiols and Disulfides: Methods for Chemoselective Formation of Asymmetric Disulfides in Synthetic Peptides and Polymers

Some peculiarities of synthesis of cysteine-containing peptides

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