Sequential peptide chemical ligation by the thioester method and extended chemical ligation

The sequential chemical ligation of peptide thioesters by a combination of the thioester method and extended chemical ligation using a photoremovable auxiliary, 2-mercapto-1-(2-nitrophenyl)ethyl group, is described. The thiazolidine ring was used as a protecting group for the N-terminal 1,2-aminoethanethiol moiety of the auxiliary in the middle peptide thioester. After the first thioester coupling, the thiazolidine ring was opened by treatment with O-methylhydroxylamine. Second coupling by extended chemical ligation followed by UV irradiation gave the target polypeptide.     

多肽片段连接方法及肽硫酯和肽醛的合成*

本文综述了多肽和蛋白质合成中的片段连接方法,这是近年来多肽和蛋白质合成领域中方法学上的重要进展.该方法使用非保护的多肽片段,无需酶或化学活化试剂,在缓冲溶液中能够高产率地获得多肽和蛋白质.还介绍了与多肽片段连接有关的肽硫酯和肽醛的合成方法.     

Fmoc-SPPS chemistry compatible approach for the generation of (glyco)peptide aryl thioesters

A new approach is described for the general Fmoc-based solid-phase synthesis of (glyco)peptide aryl thioesters. A peptide alkyl oxoester obtained by standard Fmoc-based chain elongation undergoes an O-to-S acyl shift, and is followed by alkyl thioester exchanges with a large excess of aryl thiol, affording the corresponding peptide aryl thioester. The newly developed methodology is useful for the chemical synthesis of post-translationally modified proteins because of its compatibility with standard Fmoc-SPPS conditions. In addition, the peptide aryl thioesters are essential intermediates for chemical synthesis of proteins by kinetically controlled convergent strategy.     

Theoretical Analysis of the Detailed Mechanism of Native Chemical Ligation Reactions

The method of native chemical ligation between an unprotected peptide α‐thioester and an N‐terminal cysteine–peptide to give a native peptide in aqueous solution is one of the most effective peptide ligation methods. In this work, a systematic theoretical study was carried out to fully understand the detailed mechanism of ligation. It was found that for the conventional native chemical ligation reaction between a peptide thioalkyl ester and a cysteine in combination with an added aryl thiol as catalyst, both the thiol‐thioester exchange step and the transthioesterification step proceed by an anionic concerted S_N2 displacement mechanism, whereas the intramolecular rearrangement proceeds by an addition–elimination mechanism, and the rate‐limiting step is the thiol‐thioester exchange step. The theoretical method was then extended to study the detailed mechanism of the auxiliary‐mediated peptide ligation between a peptide thiophenyl ester and an N‐2‐mercaptobenzyl peptide in which both the thiol‐thioester exchange step and intramolecular acyl‐transfer step proceed by a concerted S_N2‐type displacement mechanism. The energy barrier of the thiol‐thioester exchange step depends on the side‐chain steric hindrance of the C‐terminal amino acid, whereas that of the acyl‐transfer step depends on the side‐chain steric hindrance of the N‐terminal amino acid.     

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     

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.     

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.     

On-resin peptide ligation via C-terminus benzvl ester

Here, we report 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. On-resin native chemical ligation and auxiliary-assisted peptide ligation were successfully achieved. This method is compatible to both protected and unprotected peptide fragments and has potential application in poor water-soluble peptide ligation.     

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.     

Use of thiosulfonate for the protection of thiol groups in peptide ligation by the thioester method

Use of thiosulfonate for protecting thiol (-SH) groups in peptide ligation by the thioester method was examined. Thiosulfonate was introduced and was stable in the presence of silver ion, 4-dihydro-3-hydroxy-4-oxo-1,2,3-benzotriazine, and diisopropylethylamine. Based on these results, a strategy for using the thioester method and the native chemical ligation method in the synthesis of a single polypeptide is described.     

9-Fluorenylmethoxycarbonyl-based solid-phase synthesis of peptide α-thioesters

Peptide thioesters play a key role in convergent protein synthesis strategies such as native chemical ligation, traceless Staudinger ligation, and Ag(+) -mediated thioester ligation. The Boc-based solid-phase synthesis provides a very reliable access to peptide thioesters. However, the acid lability of many peptide modifications and the requirements of most parallel peptide synthesizers call for the milder Fmoc-based solid-phase synthesis. The Fmoc-based synthesis of peptide thioesters is more cumbersome and typically proceeds with lower yields than the synthesis of peptide acids and peptide amides. The success of native chemical ligation and related technologies has sparked intensive research effort devoted to the development of new methods. The recent progress in this rapidly expanding field is reviewed.     

Thioester-isocyanides: versatile reagents for the synthesis of cycle-tail peptides

A novel class of reagents, thioester isocyanides, have been prepared and applied in the synthesis of peptide macrocycles. The isocyanide part of the molecule is deployed in a multicomponent macrocyclization step. This step is followed by chemoselective peptide ligation at the thioester part of the macrocycle. Our method can now be used for rapid assembly and evaluation of cycle-tail peptides.     

Synthesis of Heavily Glycosylated Peptide αThioester

Erythropoietin (EPO) needs to be heavily glycosylated to exhibit its bioactivity in vivo. In order to synthesize heavily glycosylated EPO analogues, corresponding glycosylated peptide ^αthioesters are essential to prepare glycosylated whole EPO peptide backbones through native chemical ligation. After construction of the peptide ^αthioester corresponding to the 1–32 amino acid sequence in EPO, we aimed to incorporate three complex-type biantennary sialyloligosaccharides to this peptide ^αthioester by the haloacetamide method. The reaction afforded the desired heavily glycosylated peptide ^αthioester.     

Solid-phase synthesis of peptide and glycopeptide thioesters through side-chain-anchoring strategies

An efficient new strategy for the synthesis of peptide and glycopeptide thioesters is described. The method relies on the side-chain immobilization of a variety of Fmoc-amino acids, protected at their C-termini, on solid supports. Once anchored, peptides were constructed using solid-phase peptide synthesis according to the Fmoc protocol. After unmasking the C-terminal carboxylate, either thiols or amino acid thioesters were coupled to afford, after cleavage, peptide and glycopeptide thioesters in high yields. Using this method a significant proportion of the proteinogenic amino acids could be incorporated as C-terminal amino acid residues, therefore providing access to a large number of potential targets that can serve as acyl donors in subsequent ligation reactions. The utility of this methodology was exemplified in the synthesis of a 28 amino acid glycopeptide thioester, which was further elaborated to an N-terminal fragment of the glycoprotein erythropoietin (EPO) by native chemical ligation.     

Self-assembled templates for polypeptide synthesis

The chemical synthesis of polypeptide chains >50 amino acids with prescribed sequences is challenging. In one approach, native chemical ligation (NCL), short, unprotected peptides are connected through peptide bonds to render proteins in water. Here we combine chemical ligation with peptide self-assembly to deliver extremely long polypeptide chains with stipulated, repeated sequences. We use a self-assembling fiber (SAF) system to form structures tens of micrometers long. In these assemblies, tens of thousands of peptides align with their N- and C-termini abutting. This arrangement facilitates chemical ligation without the usual requirement for a catalytic cysteine residue at the reactive N-terminus. We introduced peptides with C-terminal thioester moieties into the SAFs. Subsequent ligation and disassembly of the noncovalent components produced extended chains > or =10 microm long and estimated at > or =3 MDa in mass. These extremely long molecules were characterized by a combination of biophysical, hydrodynamic, and microscopic measurements.     

A photoremovable ligation auxiliary for use in polypeptide synthesis

A photoremovable auxiliary for use in peptide synthesis via the native chemical ligation method is described. A 2-mercapto-1-(2-nitrophenyl)ethylamine (Mnpe-amine) moiety was attached to the N-terminus of a peptide via the periodate oxidation of a seryl peptide. The resulting peptide was then ligated to a peptide thioester, and UV (365 nm) irradiation resulted in the removal of the auxiliary from the peptide.     

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.     

Synthesis of the sphingolipid activator protein, saposin C, using an azido-protected O-acyl isopeptide as an aggregation-disrupting element

In order to achieve an efficient synthesis of highly hydrophobic proteins by the native chemical ligation (NCL) reaction, we examined to incorporate the O-acyl isopeptide method, which is known to improve the solubility of the segment, to the NCL reaction: a peptide thioester having O-acyl isopeptide structures is prepared by the Boc mode solid-phase method using an azido group as a protecting group for the isopeptide site, and then ligated with C-terminal segment with an in situ reduction of the azido group followed by an O- to N-acyl shift. This method was successfully applied to the synthesis of the sphingolipid activator protein, saposin C.     

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.     

Synthesis of lipidated green fluorescent protein and its incorporation in supported lipid bilayers

Herein we report a semisynthetic method of producing membrane-anchored proteins. Ligation of synthetic lipids with designed anchor structures to proteins was performed using native chemical ligation (NCL) of a C-terminal peptide thioester and an N-terminal cysteine lipid. This strategy mimics the natural glycosylphosphatidylinositol (GPI) linkage found in many natural membrane-associated proteins; however, the synthetic method utilizes simple lipid anchors without glycans. Synthetically lipidated recombinant green fluorescent protein (GFP) was shown to be stably anchored to the membrane, and its lateral fluidity was quantitatively characterized by direct fluorescence imaging in supported membranes. Circumventing the steps of purification from native cell membranes, this methodology facilitates the reconstitution of membrane-associated proteins.