The use of a cysteinyl prolyl ester (CPE) autoactivating unit in peptide ligation reactions

A peptide containing a cysteinyl prolyl ester (CPE) moiety at the C-terminus (CPE peptide) is spontaneously transformed into a diketopiperazine thioester via an intramolecular N-S acyl shift reaction, followed by diketopiperazine formation. The CPE peptide can be ligated with a Cys-peptide in a one-pot procedure. The peptide diketopiperazine thioester can also be transformed into a peptide thioester by intermolecular thiol-thioester exchange with external thiol compounds such as sodium mercaptoethanesulfonate. Since CPE peptides can be prepared by standard Fmoc solid-phase synthesis, it is a versatile alternative to the peptide thioester, providing a flexible ligation strategy that promises to be useful in polypeptide synthesis.     

Leveraging the Knorr Pyrazole Synthesis for the Facile Generation of Thioester Surrogates for use in Native Chemical Ligation

Facile synthesis of C‐terminal thioesters is integral to native chemical ligation (NCL) strategies for chemical protein synthesis. We introduce a new method of mild peptide activation, which leverages solid‐phase peptide synthesis (SPPS) on an established resin linker and classical heterocyclic chemistry to convert C‐terminal peptide hydrazides into their corresponding thioesters via an acyl pyrazole intermediate. Peptide hydrazides, synthesized on established trityl chloride resins, can be activated in solution with stoichiometric acetyl acetone (acac), readily proceed to the peptide acyl pyrazoles. Acyl pyrazoles are mild acylating agents and are efficiently exchanged with an aryl thiol, which can then be directly utilized in NCL. The mild, chemoselective, and stoichiometric activating conditions allow this method to be utilized through multiple sequential ligations without intermediate purification steps.     

Peptide dithiodiethanol esters for in situ generation of thioesters for use in native ligation

A new approach is described for the general Fmoc-based solid-phase synthesis of C-terminal peptide (thio)esters. One hydroxy group of 2,2-dithiodiethanol (used in large excess) was anchored on trityl resin, and the remaining hydroxy group was loaded with the first amino acid. Standard chain elongation and TFA-based peptide release yielded peptide C-terminal dithiodiethanol esters in good purities. Under standard conditions of native chemical ligation (excess thiol, neutral pH), the dithiodiethanol function is presumably reduced and rearranged (or equilibrated) to the thioester via a 5-membered intermediate. The resulting thioesters are shown to undergo native chemical ligation with N-terminal cysteine peptides. Notably, hydrolysis of the reduced ester is a major competing reaction, especially in the presence of 6 M guanidinium chloride, which is often required for solubilization of large peptide fragments.     

Efficient Chemical Protein Synthesis using Fmoc‐Masked N‐Terminal Cysteine in Peptide Thioester Segments

We report an operationally simple method to facilitate chemical protein synthesis by fully convergent and one‐pot native chemical ligations utilizing the fluorenylmethyloxycarbonyl (Fmoc) moiety as an N‐masking group of the N‐terminal cysteine of the middle peptide thioester segment(s). The Fmoc group is stable to the harsh oxidative conditions frequently used to generate peptide thioesters from peptide hydrazide or o‐aminoanilide. The ready availability of Fmoc‐Cys(Trt)‐OH, which is routinely used in Fmoc solid‐phase peptide synthesis, where the Fmoc group is pre‐installed on cysteine residue, minimizes additional steps required for the temporary protection of the N‐terminal cysteinyl peptides. The Fmoc group is readily removed after ligation by short exposure (<7 min) to 20 % piperidine at pH 11 in aqueous conditions at room temperature. Subsequent native chemical ligation reactions can be performed in presence of piperidine in the same solution at pH 7.     

N‐Linked Glycosyl Auxiliary‐Mediated Native Chemical Ligation on Aspartic Acid: Application towards N‐Glycopeptide Synthesis

A practical approach towards N‐glycopeptide synthesis using an auxiliary‐mediated dual native chemical ligation (NCL) has been developed. The first NCL connects an N‐linked glycosyl auxiliary to the thioester side chain of an N‐terminal aspartate oligopeptide. This intermediate undergoes a second NCL with a C‐terminal thioester oligopeptide. Mild cleavage provides the desired N‐glycopeptide.     

One‐Pot/Sequential Native Chemical Ligation Using N‐Sulfanylethylanilide Peptide

N‐Sulfanylethylanilide (SEAlide) peptides were developed with the aim of achieving facile synthesis of peptide thioesters by 9‐fluorenylmethyloxycarbonyl (Fmoc)‐based solid‐phase peptide synthesis (Fmoc SPPS). Initially, SEAlide peptides were found to be converted to the corresponding peptide thioesters under acidic conditions. However, the SEAlide moiety was proved to function as a thioester in the presence of phosphate salts and to participate in native chemical ligation (NCL) with N‐terminal cysteinyl peptides, and this has served as a powerful protein synthesis methodology. The reactivity of a SEAlide peptide (anilide vs. thioester) can be easily tuned with or without the use of phosphate salts. This interesting property of SEAlide peptides allows sequential three‐fragment or unprecedented four‐fragment ligation for efficient one‐pot peptide/protein synthesis. Furthermore, dual‐kinetically controlled ligation, which enables three peptide fragments simultaneously present in the reaction to be ligated in the correct order, was first achieved using a SEAlide peptide. Beyond our initial expectations, SEAlide peptides have served in protein chemistry fields as very useful crypto‐peptide thioesters. DOI 10.1002/tcr.201200007     

Enhancement in the rate of conversion of peptide Cys-Pro esters to peptide thioesters by structural modification

We previously reported that the peptide containing a Cys-Pro ester (CPE) moiety is spontaneously transformed into a peptide thioester via an N to S acyl shift followed by diketopiperazine formation. In an attempt to identify more reactive structures for the formation of a peptide thioester, we modified the CPE structure, in which the Pro residue in the CPE moiety was replaced with N-substituted glycine derivatives. These peptides were transformed into a peptide thioester more rapidly. Alternatively, the addition of an amino acid residue at the C-terminus of the CPE moiety also accelerated thioester formation.     

A Native‐Chemical‐Ligation‐Mechanism‐Based Ratiometric Fluorescent Probe for Aminothiols

Thiol‐containing amino acids (aminothiols) such as cysteine (Cys) and homocysteine (Hcy) play a key role in various biological processes including maintaining the homeostasis of biological thiols. However, abnormal levels of aminothiols are associated with a variety of diseases. The native chemical ligation (NCL) reaction has attracted great attention in the fields of chemistry and biology. NCL of peptide segments involves cascade reactions between a peptide‐α‐thioester and an N‐terminal cysteine peptide. In this work, we employed the NCL reaction mechanism to formulate a Förster resonance energy transfer (FRET) strategy for the design of ratiometric fluorescent probes that were selective toward aminothiols. On the basis of this new strategy, the ratiometric fluorescent probe 1 for aminothiols was judiciously designed. The new probe is highly selective toward aminothiols over other thiols and exhibits a very large variation (up to 160‐fold) in its fluorescence ratio (I₄₅₈/I₆₀₃). The new fluorescent probe is capable of ratiometric detection of aminothiols in newborn calf and human serum samples and is also suitable for ratiometric fluorescent imaging of aminothiols in living cells.     

Decomposition of 2‐Mercaptoethyl O‐Ester: SN2 Displacement or Acyl Transfer? A Theoretical Study

The mechanism for the decomposition of 2‐mercaptoethyl O‐ester was theoretically investigated. The mechanism that 2‐mercaptoethyl O‐ester undergoes an S_N2 displacement of the O atom by the S atom on α‐C is much favored over the mechanism of N‐to‐S acyl transfer. The length of the alcohol moiety has large effects on the decomposition efficiency of thiol‐substituted alkyl O‐esters. The reactivities of these esters are controlled by distortion energies. Only 2‐mercaptoethyl O‐ester can undergo the decomposition at room temperature due to the low distortion energy to achieve the transition state geometry. If the thiol group of 2‐mercaptoethyl O‐ester is replaced by an amino group, the N‐to‐N acyl transfer mechanism is more favored than the S_N2 displacement mechanism.     

Theoretical investigations on the thiol–thioester exchange steps of different thioesters

As the rate-determining step in native chemical ligation reactions, the thiol–thioester exchange step is important in determining the efficiency of the ligations of peptides. In the present study, systematic theoretical calculations were carried out on the relationships between the structure of different thioesters and the free energy barriers of the thiol–thioester exchange step. According to the calculation results, the thiol–thioester exchange step is disfavored by the steric hindrance around the carbonyl center, while the electronic effect(i.e. conjugation and hyper-conjugation effects) becomes important when the steric hindrance is insignificant.     

Mechanism of N-to-S acyl transfer of N-(2-hydroxybenzyl) cysteine derivatives and origin of phenol acceleration effect

The mechanism of N-to-S acyl transfer of N-(2-hydroxybenzyl) cysteine derivatives and the origin of acceleration effect of phenol substitutes were investigated by DFT methods.     

Extending synthetic access to proteins with a removable acyl transfer auxiliary

A chemo- and regioselective auxiliary-mediated peptide ligation has been developed that is effective under nonidealized conditions for the synthesis of proteins. This general amide bond ligation utilizes a removable auxiliary that is analogous to the role of cysteine in native chemical ligation, combining chemoselective thioester exchange with efficient regioselective intramolecular acyl transfer. Acid lability and improved ligation efficiency were introduced into the 2-mercaptobenzyl auxiliary by increasing the electron density of the aromatic ring. The 62 amino acid SH3 domain from alpha-spectrin was synthesized using the auxiliary-mediated ligation at a Lys-Gly sequence. The auxiliary was removed with TFA and scavengers from the ligated product. This methodology enables unprotected peptides to be coupled at noncysteine ligation sites expanding the scope of protein synthesis and semisynthesis.     

Facile peptide thioester synthesis via solution-phase tosylamide preparation

Preparation of peptide thioester is essential for native chemical ligation and block condensation. Our novel methodology involves conversion of the carboxylic acid of a peptide into a thioester using p-toluenesulfonyl isocyanate, followed by alkylation, then thiol substitution. Our methodology can also be used for the preparation of glycopeptide thioesters. Furthermore, it is possible to carry out the reaction as a sequential peptide chemical ligation.     

Native chemical ligation through in situ O to S acyl shift

[reaction: see text] A novel strategy to generate thioester peptides compatible with Fmoc chemistry is presented. Peptide-C(alpha)oxy-(2-mercapto-1-carboxyamide)ethyl ester undergoes an O to S acyl shift during ligation and the newly formed thioester intermediate reacts with an N-terminal cysteine fragment generating a product with native amide bond at the ligation site.     

Semisynthesis of a Post‐Translationally Modified Protein by Using Chemical Cleavage and Activation of an Expressed Fusion Polypeptide

Herein, we describe a new semisynthetic strategy of a post‐translationally modified protein in which the middle region is glycosylated. We designed a single‐plasmid coding for a fusion polypeptide, which can provide both an N‐terminal α‐thioester and a C‐terminal cysteine peptide of a target glycoprotein by using chemical‐cleavage and activation methods. The use of these resultant peptide derivatives resulted in the successful synthesis of N‐glycosylated‐interleukin 13.     

On-resin peptide ligation via C-terminus benzyl ester

Here, we reported a new approach of on-resin peptide ligation using C-terminal benzyl ester as the stabilized precursor of thioester, which enables both N-terminal elongation and C-terminal peptide ligation on a Rink Amide resin.     

Cleavable and tunable cysteine-specific arylation modification with aryl thioethers

Cysteine represents an attractive target for peptide/protein modification due to the intrinsic high nucleophilicity of the thiol group and low natural abundance. Herein, a cleavable and tunable covalent modification approach for cysteine containing peptides/proteins with our newly designed aryl thioethers via a S_NAr approach was developed. Highly efficient and selective bioconjugation reactions can be carried out under mild and biocompatible conditions. A series of aryl groups bearing different bioconjugation handles, affinity or fluorescent tags are well tolerated. By adjusting the skeleton and steric hindrance of aryl thioethers slightly, the modified products showed a tunable profile for the regeneration of the native peptides.

A cleavable and tunable covalent modification approach for cysteine by aryl thioethers via a S_NAr approach was developed. The highly efficient and selective bioconjugation reactions can proceed under the mild and biocompatible conditions.     

Theoretical study on formation of thioesters via O-to-S acyl transfer

Peptide thioester preparation via intramolecular O-to-S acyl transfer is a recently developed method for protein chemical synthesis through Fmoc chemistry. Theoretical calculations have been carried out to study the mechanism for the formation of thioesters via O-to-S acyl transfer. It is found that the O-to-S acyl transfer occurs via an anionic stepwise mechanism in which the cleavage of the C-O bond is the rate-limiting step. The side reaction of hydrolysis also proceeds through an anionic stepwise process, and its rate-limiting step is the attack of the hydroxide ion on the carbonyl carbon. Increase of the chain length between the ester O atom and the S atom can increase the energy barrier of the O-to-S acyl transfer. On the other hand, substituents at the α-position of the ester can reduce the energy barrier.     

Preparation of solid surfaces for native chemical ligation in the quartz crystal microbalance

The preparation of a nonporous solid surface for native chemical ligation is described. A cysteine residue is covalently attached to the surface by means of a series of reactions. In a reaction analogous to that used for native chemical ligation, the surface‐attached cysteine residue reacts with a thioester to form an amide linkage. All of the reaction steps except the derivatization of the nonporous solid surface with amino‐ended silane are conducted within the flow cell of a quartz crystal microbalance with dissipation monitoring. This sensitive instrument allows each reaction step to be followed in real time, with simultaneous quantification of the mass added and removed in different steps. The number of protected cysteine residues attached per square nanometer is consistent with the number of protecting groups removed in each deprotection step and also with the number of thioesters reacting with the deprotected cysteine. Copyright © 2013 John Wiley & Sons, Ltd.     

Long‐Range Chemical Ligation from N→N Acyl Migrations in Tryptophan Peptides via Cyclic Transition States of 10‐ to 18‐Members

Chemical ligations to form native peptides from N→N acyl migrations in Trp‐containing peptides via 10‐ to 18‐membered cyclic transition states are described. In this study, a statistical, predictive model that uses an extensive synthetic and computational approach to rationalize the chemical ligation is reported. N→N acyl migrations that form longer native peptides without the use of Cys/Ser/Tyr residues or an auxiliary group at the ligation site were achieved. The feasibility of these traceless chemical ligations is supported by the N?C bond distance in N‐acyl isopeptides. The intramolecular nature of the chemical ligations is justified by using competitive experiments and theoretical calculations.