Cysteine/Penicillamine Ligation Independent of Terminal Steric Demands for Chemical Protein Synthesis

The chemical ligation of two unprotected peptides to generate a natural peptidic linkage specifically at the C‐ and N‐termini is a desirable goal in chemical protein synthesis but is challenging because it demands high reactivity and selectivity (chemo‐, regio‐, and stereoselectivity). We report an operationally simple and highly effective chemical peptide ligation involving the ligation of peptides with C‐terminal salicylaldehyde esters to peptides with N‐terminal cysteine/penicillamine. The notable features of this method include its tolerance of steric hinderance from the side groups on either ligating terminus, thereby allowing flexible disconnection at sites that are otherwise difficult to functionalize. In addition, this method can be expanded to selective desulfurization and one‐pot ligation‐desulfurization reactions. The effectiveness of this method was demonstrated by the synthesis of VISTA (216‐311), PD‐1 (192‐288) and Eglin C.     

Protein assembly by orthogonal chemical ligation methods

Chemical synthesis harbors the potential to provide ready access to natural proteins as well as to create nonnatural ones. The Staudinger ligation of a peptide containing a C-terminal phosphinothioester with a peptide containing an N-terminal azide gives an amide with no residual atoms. This method for amide bond formation is orthogonal and complementary to other ligation methods. Herein, we describe the first use of the Staudinger ligation to couple peptides on a solid support. The fragment thus produced is used to assemble functional ribonuclease A via native chemical ligation. The synthesis of a protein by this route expands the versatility of chemical approaches to protein production.     

Design of thiol-containing amino acids for native chemical ligation at non-Cys sites

<正>Protein chemical synthesis usually relies on the use of native chemical ligation that couples peptide thioester with a Cys-peptide.A limitation of this method is the difficulty of finding an appropriate Cys ligation site in many synthetic targets.To overcome this problem,the ligation-desulfurization approach has been developed.This approach involves the use of a thiol-containing amino acid as the ligation partner.After the sequence assembly is completed,the thiol group is removed through a desulfurization reaction to generate the standard amino acids.Currently this strategy has been applied to the ligations at a number of amino acids including Ala,Phe,Val,Lys,Thr,Leu,Pro and Gln.The present article reviews the design and synthesis of these thiol-containing amino acids for native chemical ligation at non-Cys sites.     

Parallel Chemical Protein Synthesis on a Surface Enables the Rapid Analysis of the Phosphoregulation of SH3 Domains

Analysis of postranslationally modified protein domains is complicated by an availability problem, as recombinant methods rarely allow site‐specificity at will. Although total synthesis enables full control over posttranslational and other modifications, chemical approaches are limited to shorter peptides. To solve this problem, we herein describe a method that combines a) immobilization of N‐terminally thiolated peptide hydrazides by hydrazone ligation, b) on‐surface native chemical ligation with self‐purified peptide thioesters, c) radical‐induced desulfurization, and d) a surface‐based fluorescence binding assay for functional characterization. We used the method to rapidly investigate 20 SH3 domains, with a focus on their phosphoregulation. The analysis suggests that tyrosine phosphorylation of SH3 domains found in Abl kinases act as a switch that can induce both the loss and, unexpectedly, gain of affinity for proline‐rich ligands.     

Orthogonal ligation: a three piece assembly of a PNA-peptide-PNA conjugate

A PNA-peptide-PNA conjugate was assembled from three fragments using a combination of native chemical ligation and an orthogonal, auxiliary-mediated ligation.     

Synthesis of peptides and proteins without cysteine residues by native chemical ligation combined with desulfurization.

The highly chemoselective reaction between unprotected peptides bearing an N-terminal Cys residue and a C-terminal thioester enables the total and semi-synthesis of complex polypeptides. Here we extend the utility of this native chemical ligation approach to non-cysteine containing peptides. Since alanine is a common amino acid in proteins, ligation at this residue would be of great utility. To achieve this goal, a specific alanine residue in the parent protein is replaced with cysteine to facilitate synthesis by native chemical ligation. Following ligation, selective desulfurization of the resulting unprotected polypeptide product with H(2)/metal reagents converts the cysteine residue to alanine. This approach, which provides a general method to prepare alanyl proteins from their cysteinyl forms, can be used to chemically synthesize a variety of polypeptides, as demonstrated by the total chemical syntheses of the cyclic antibiotic microcin J25, the 56-amino acid streptococcal protein G B1 domain, and a variant of the 110-amino acid ribonuclease, barnase.     

Synthesis of a selenocysteine-containing peptide by native chemical ligation

[reaction in text] A new method for the synthesis of selenocysteine derivatives and selenocysteine-containing peptides is described. Fmoc-Se-p-methoxybenzylselenocysteine (1) was prepared and used for solid-phase synthesis of peptides with an N-terminal unprotected selenocysteine. Subsequent native chemical ligation with a peptide thioester provided a 17-mer that corresponds to the C-terminus of ribonucleotide reductase with selenocysteine in place of cysteine.     

蛋白质的化学全合成

含有非天然氨基酸的蛋白质（如翻译后修饰蛋白质、修饰有探针分子的蛋白质等）是化学生物学中重要的生理活性分子。这些分子难以通过生物表达来获取，而必须使用化学方法来合成。半胱氨酸肽片段连接方法是目前应用于蛋白质化学全合成中的一种重要方法，该方法能够在温和的水溶液中高效地实现肽片段的连接，从而生成天然或者非天然的蛋白质。本文系统地综述了半胱氨酸肽片段连接方法的基本原理，详细讨论了近年来人们对该方法的一些重要改进。最后又介绍了该方法在几类重要的蛋白质分子合成中的代表性应用。     

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.     

One-pot dual-labeling of a protein by two chemoselective reactions

Dual system for proteins: The site-specific two-color labeling of a Rab GTPase was achieved in a one-pot procedure by combination of chemoselective native chemical ligation and oxime ligation. This strategy could be a general, facile, and efficient method for specific multiple modifications of a given protein. The Rab GTPase biosensor was demonstrated for protein folding and protein-protein interaction studies.     

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.     

Optimisation of chemical protein cleavage for erythropoietin semi-synthesis using native chemical ligation

Selective protein cleavage at methionine residues is a useful method for the production of bacterially derived protein fragments containing an N-terminal cysteine residue required for native chemical ligation. Here we describe an optimised procedure for cyanogen bromide-mediated protein cleavage, and ligation of the resulting fragments to afford biologically active proteins.     

Sugar-assisted glycopeptide ligation

The chemical synthesis of glycopeptides and glycoproteins from readily available materials presents an attractive route to homogeneous products for structural and functional studies. Chemical synthesis of glycopeptides and glycoproteins based on native chemical ligation represents one of the useful methods for the synthesis of natural glycopeptide structures. Here we describe a method that allows for the synthesis of glycopeptides from cysteine-free peptides. This method utilizes a peptide thioester and a glycopeptide in which the sugar moiety is modified with a thiol handle at the C-2 position. Upon completion of the ligation reaction, the thiol handle can be reduced with H2/metal to the acetamide moiety, furnishing the unmodified glycopeptides. Together, this sequence of reactions displays an attractive potential in glycopeptides and glycoproteins synthesis.     

Combining ligation reaction and capillary gel electrophoresis to obtain reliable long DNA probes

New DNA amplification methods are continuously developed for sensitive detection and quantification of specific DNA target sequences for, e.g. clinical, environmental or food applications. These new applications often require the use of long DNA oligonucleotides as probes for target sequences hybridization. Depending on the molecular technique, the length of DNA probes ranges from 40 to 450 nucleotides, solid-phase chemical synthesis being the strategy generally used for their production. However, the fidelity of chemical synthesis of DNA decreases for larger DNA probes. Defects in the oligonucleotide sequence result in the loss of hybridization efficiency, affecting the sensitivity and selectivity of the amplification method. In this work, an enzymatic procedure has been developed as an alternative to solid-phase chemical synthesis for the production of long oligonucleotides. The enzymatic procedure for probe production was based on ligation of short DNA sequences. Long DNA probes were obtained from smaller oligonucleotides together with a short sequence that acts as bridge stabilizing the molecular complex for DNA ligation. The ligation reactions were monitored by capillary gel electrophoresis with laser-induced fluorescence detection (CGE-LIF) using a bare fused-silica capillary. The capillary gel electrophoresis-LIF method demonstrated to be very useful and informative for the characterization of the ligation reaction, providing important information about the nature of some impurities, as well as for the fine optimization of the ligation conditions (i.e. ligation cycles, oligonucleotide and enzyme concentration). As a result, the yield and quality of the ligation product were highly improved. The in-lab prepared DNA probes were used in a novel multiplex ligation-dependent genome amplification (MLGA) method for the detection of genetically modified maize in samples. The great possibilities of the whole approach were demonstrated by the specific and sensitive detection of transgenic maize at percentages lower than 1%.     

Backbone-Installed Split Intein-Assisted Ligation for the Chemical Synthesis of Mirror-Image Proteins

Membrane-associated D-proteins are an important class of synthetic molecules needed for D-peptide drug discovery, but their chemical synthesis using canonical ligation methods such as native chemical ligation is often hampered by the poor solubility of their constituent peptide segments. Here, we describe a B ackbone- I nstalled S plit I ntein- A ssisted L igation (BISIAL) method for the synthesis of these proteins, wherein the native L-forms of the N- and C-intein fragments of the unique consensus-fast (Cfa) (i.e. L–Cfa^N and L–Cfa^C) are separately installed onto the two D-peptide segments to be ligated via a removable backbone modification. The ligation proceeds smoothly at micromolar (μM) concentrations under strongly chaotropic conditions (8.0 M urea), and the subsequent removal of the backbone modification groups affords the desired D-proteins without leaving any “ligation scar” on the products. The effectiveness and practicality of the BISIAL method are exemplified by the synthesis of the D-enantiomers of the extracellular domains of T cell immunoglobulin and ITIM domain (TIGIT) and tropomyosin receptor kinase C (TrkC). The BISIAL method further expands the chemical protein synthesis ligation toolkit and provides practical access to challenging D-protein targets.     

Chemical ligation as a method for the assembly of double-stranded nucleic acids: Modifications and local structure studies

A new procedure was developed as an alternative to the enzymatic assembly of natural and modified double-stranded DNAs using chemical reagent (chemical ligation). BrCN was suggested as an efficient coupling reagent, which induces superfast reactions in DNA duplexes. The physicochemical properties and the structure of new types of DNA duplexes, which are the substrates for chemical ligation, with breaks in phosphodiester chains, including concatemers, were studied. Chemical ligation was applied to prepare biologically active 17–200 base-pair double-stranded DNAs and DNA-RNA block-copolymers, to incorporate various modifications into DNA duplexes including pyrophosphate and phosphoramidate unnatural internucleotide bonds. The unique possibilities of this approach were demonstrated in the development of methods for circularization of oligodeoxy ribonucleotides and assembly of branched DNAs. The structural-kinetic concept of chemicalligation was created and the relationship between the reactivity of interacting groups and sequence-dependent local conformation of the ligation site in B-DNA was established. The lesser efficiency of chemical ligation of RNA fragments in comparison to that of DNA analogs was demonstrated and rationalized. This approach was used as a sensitive monitor of a stable double helix formation and third-strand binding to a DNA duplex.Translated from Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 8, pp. 1889–1911, August, 1996.     

Synthesis of an O-acyl isopeptide by using native chemical ligation to efficiently construct a hydrophobic polypeptide

By using dimethylformamide to suppress the O-to-N acyl migration, we efficiently synthesized an O-acyl isopeptide by native chemical ligation of a peptide-thioester and a Cys-O-acyl isopeptide. The reaction mixture was then loaded onto an octadecylsilane reverse-phase HPLC column, and the isopeptide was purified by using a linear gradient of CH₃CN in 0.1% aqueous trifluoroacetic acid. The recovery rate of the O-acyl isopeptide was considerably higher than that of the corresponding native polypeptide. Synthesis of O-acyl isopeptides via native chemical ligation, with O-to-N acyl migration as the final step to give the native form, has potential as an efficient method of constructing hydrophobic polypeptides.     

An advance in proline ligation

Native chemical ligation (NCL) is widely applicable for building proteins in the laboratory. Since the discovery of this method, many strategies have been developed to enhance its capability and efficiency. Because of the poor reactivity of proline thioesters, ligation at a C-terminal proline site is not readily accomplished. Here, we demonstrate that ligation at an N-terminal protein is feasible using the combined logic of NCL and metal-free dethiylation (MFD).     

Hexafluoro-2-propanol as a potent cosolvent for chemical ligation of membrane proteins

The study on membrane proteins is an important challenge mainly because of their very poor solubility in various solvents.The traditional recombinant expression strategy and the native chemical ligation method both have difficulty in generating sufficient amounts of desired proteins with high efficiency.Previous studies have shown that multiply fluorinated alcohols exhibit good ability to dissolve difficult peptide sequences,especially hexafluoro-2-propanol (HFIP).In the present study we systematically stud...     

Generation of a dual-labeled fluorescence biosensor for Crk-II phosphorylation using solid-phase expressed protein ligation

BACKGROUND: The site-specific chemical modification of proteins has proved to be extremely powerful for generating tools for the investigation of biological processes. Although a few elegant methods exist for engineering a recombinant protein at a unique position, these techniques cannot be easily extended to allow several different chemical probes to be specifically introduced into a target sequence. As such multiply labeled proteins could be used to study many biological processes, and in particular biomolecular interactions, we decided to investigate whether such protein reagents could be generated using an extension of the semisynthesis technique known as expressed protein ligation. RESULTS: A solid-phase expressed protein ligation (SPPL) technology is described that enables large semisynthetic proteins to be assembled on a solid support by the controlled sequential ligation of a series of recombinant and synthetic polypeptide building blocks. This modular approach allows multiple, different chemical modifications to be introduced site-specifically into a target protein. This process, which is analogous to solid-phase peptide synthesis, was used to dual-label the amino and carboxyl termini of the Crk-II adapter protein with the fluorescence resonance energy transfer pair tetramethylrhodamine and fluorescein, respectively. The resulting construct reports (through a fluorescence change) the phosphorylation of Crk-II by the nonreceptor protein tyrosine kinase, c-Abl, and was used to probe the protein-protein interactions that regulate this important post-translational process. CONCLUSIONS: SPPL provides a powerful method for specifically modifying proteins at multiple sites, as was demonstrated by generating a protein-based biosensor for Crk-II phosphorylation. Such protein derivatives are extremely useful for investigating protein function in vitro and potentially in vivo. This modular approach should be applicable to many different protein systems.