Recent development in peptide coupling reagents

Two decades of domination of benzotriazole-based chemistry stimulated the progress in peptide synthesis to a high level of effectiveness. However, the growing need for new and more complex peptide structures, particularly for biomedical studies and, very recently, for the large-scale production of peptides as drugs, required manufacturing peptide products by efficient synthetic strategies, at reasonably low prices. Therefore, the search for new, more versatile and low-cost reagents becomes a great challenge. Several comprehensive review articles summarized the great effort undertaken, but up to now, no versatile coupling reagent useful for both amide and ester bond formation, as well as for solution and solid-phase peptide synthesis has been yet developed. The most-widely used coupling reagents are carbodiimides on one hand and phosphonium and aminium salts on the other. Herein in this review article, we summarized the recent development in peptide coupling reagents during the last two decades.     

S-(2-Pyrimidinyl)- and S-(2-(4,6-dimethylpyrimidinyl))-1,1,3,3-tetramethylthiouronium hexafluorophosphates: novel reagents for in situ peptide coupling

Two new reagents for in situ peptide coupling based on the 2-mercaptopyrimidine core have been developed. The readily prepared thiouronium salts were found to promote both peptide and segment coupling efficiently with low racemization/epimerization levels.     

Cyclization of all-L-Pentapeptides by Means of 1-Hydroxy-7-azabenzotriazole-Derived Uronium and Phosphonium Reagents

Due to their restricted conformational flexibility, cyclic peptides are of great interest in connection with structure-activity relationships, especially the elucidation of bioactive conformations. For linear peptides that do not contain turn structure-inducing amino acid residues, the cyclization reaction may be an inherently improbable or slow process, and side reactions, such as cyclodimerization and epimerization at the C-terminal residue, may dominate. A number of 1-hydroxy-7-azabenzotriazole-based onium salts were examined for cyclization of thymopentin-derived pentapeptides and the results compared with data from more conventional coupling reagents. The azabenzotriazol-derived coupling reagents stood out as being the most effective by far. The cyclizations proceed extremely rapidly, and in contrast to other coupling reagents, C-terminal epimerization was generally less than 10%. C-terminal D-amino acid residues favor the formation of monocyclic pentapeptide rings. A similar effect was observed for cyclization of linear N-methylamino acid-containing peptides, suggesting that reversible amide bond alkylation such as Hmb-modification should be useful in promoting the cyclization of pepitdes devoid of turn-inducing amino acid residues.     

3-Hydroxy-4-oxo-3,4-dihydro-5-azabenzo-1,2,3-triazene

The known but long-neglected compound HODhat was shown to be in certain situations a useful peptide coupling additive. Uronium and phosphonium salts with HODhat built into the system were also useful stand-alone coupling reagents. Comparisons with related additives and coupling reagents showed that the new systems were sometimes more and sometimes less effective than previously described systems in the case of stepwise and segment couplings. Applications to assembly of the model decapeptide ACP showed that HDATU was far more effective than HDTU and more effective than HATU under some conditions.     

Structurally defined imidazolium-type ionic oligomers as soluble/solid support for peptide synthesis

Structurally defined ionic liquid-type imidazolium oligomers have been synthesized in multigram scales. These imidazolium salts have been applied to synthesize peptides efficiently in gram scale. The assembly of oligopeptides was conducted in homogeneous solution phase without the need of much excess reagents and capping as in the case of solid-phase peptide synthesis. Importantly, this approach made efficient peptide block couplings possible.     

Efficient Amide Bond Formation through a Rapid and Strong Activation of Carboxylic Acids in a Microflow Reactor

The development of highly efficient amide bond forming methods which are devoid of side reactions, including epimerization, is important, and such a method is described herein and is based on the concept of rapid and strong activation of carboxylic acids. Various carboxylic acids are rapidly (0.5 s) converted into highly active species, derived from the inexpensive and less‐toxic solid triphosgene, and then rapidly (4.3 s) reacted with various amines to afford the desired peptides in high yields (74 %–quant.) without significant epimerization (≤3 %). Our process can be carried out at ambient temperature, and only CO₂ and HCl salts of diisopropylethyl amine are generated. In the long history of peptide synthesis, a significant number of active coupling reagents have been abandoned because the highly active electrophilic species generated are usually susceptible to side reactions such as epimerization. The concept presented herein should renew interest in the use of these reagents.     

Efficient conjugation of peptides to oligonucleotides by "native ligation"

A new strategy has been developed for conjugation of peptides to oligonucleotides. The method is based on the "native ligation" of an N-terminal thioester-functionalized peptide to a 5'-cysteinyl oligonucleotide. Two new reagents were synthesized for use in solid-phase peptide and oligonucleotide synthesis, respectively. Pentafluorophenyl S-benzylthiosuccinate was used in the final coupling step in standard Fmoc-based solid-phase peptide assembly. Deprotection with trifluoracetic acid generated in solution peptides substituted with an N-terminal S-benzylthiosuccinyl moiety. O-trans-4-(N-alpha-Fmoc-S-tert-butylsulfenyl-L-cysteinyl)aminoc yclohe xyl O-2-cyanoethyl-N,N-diisopropylphosphoramidite was used in the final coupling step in standard phosphoramidite solid-phase oligonucleotide assembly. Deprotection with aqueous ammonia solution generated in solution 5'-S-tert-butylsulfenyl-L-cysteinyl functionalized oligonucleotides. Functionalized peptides and oligonucleotides were used without purification in native ligation conjugation reactions in aqueous/organic solution using tris-(2-carboxyethyl)phosphine to remove the tert-butylsulfenyl group in situ and thiophenol as a conjugation enhancer. A range of peptide-oligonucleotide conjugates were prepared by this route and purified by reversed-phase HPLC.     

Facile Synthesis of Biologically Active Peptides Using Phase Transfer Reagents as C-Terminal Protecting Group

Phase-transfer reagents (basic, neutral, and acidic) can temporarily protect carboxyl groups by salt formation of C-terminal free amino acids or peptides during peptide synthesis. The salts of amino acids or peptides behave as RNH₂ rather than RNH₃⁺. At least there is a sufficient concentration of the free amine to act as a nucleophile under the reaction conditions. Many biologically active small peptides have been synthesized by this procedure. No racemization was detected. Unusual amino acids such as β-alanine, and ε-aminohexanoic acid can be incorporated into peptides in high yields.     

Peptide-Hypervalent Iodine Reagent Chimeras: Enabling Peptide Functionalization and Macrocyclization**

Herein, we report a novel strategy for the modification of peptides based on the introduction of highly reactive hypervalent iodine reagents—ethynylbenziodoxolones (EBXs)—onto peptides. These peptide-EBXs can be readily accessed, by both solution- and solid-phase peptide synthesis (SPPS). They can be used to couple the peptide to other peptides or a protein through reaction with Cys, leading to thioalkynes in organic solvents and hypervalent iodine adducts in water buffer. Furthermore, a photocatalytic decarboxylative coupling to the C-terminus of peptides was developed using an organic dye and was also successful in an intramolecular fashion, leading to macrocyclic peptides with unprecedented crosslinking. A rigid linear aryl alkyne linker was essential to achieve high affinity for Keap1 at the Nrf2 binding site with potential protein-protein interaction inhibition.     

4个新型有机磷缩合试剂的合成及其在生物活性肽合成中的应用

报道了4个新型有机磷化合物：N-二乙氧基磷酰苯并唑酮(DEPBO)、N－(2-氧-1,3,2-二氧杂磷杂环乙烷基)-苯并唑酮(DOPBO)、3－(2'-氧-1',3',2'-二氧杂磷杂环己烷基)-氧-1,2,3-苯共三嗪-4(3H)-酮(DOPBT)和3－(二乙氧基磷酰基)-氧-1,2,3-苯并三嗪-4(3H)-酮(DEPBT)的合成,并研究了它们作为缩会试剂在多肽合成中的应用. 研究结果表明,它们可以成功地用于固相法和溶液法合成多肽,其中DEPBT还可用于环肽的合成. 应用DEPBO和DEPBT合成了促睡眠肽的类似物及从云南中草药繁缕中分离鉴定的一个环七肽等生物活性肽.     

炔酰胺类缩合剂研究进展

缩合剂是指用于促成羧酸与胺或者醇直接缩合构建酰胺键或酯键的一类试剂的总称.由于酰胺和酯的重要性,缩合剂的开发成为了学术界与工业界广泛关注的一个重要研究方向.多肽合成就是α-氨基酸在缩合剂的作用下反复形成酰胺键的过程,因此,缩合剂在多肽合成中发挥着至关重要的作用.当前多肽合成所使用的试剂和技术大多是20世纪50~80年代发展起来的,这些试剂和技术的天生弊端逐渐显现出来.比如传统多肽缩合剂过度活化α-氨基酸而诱发的外消旋化和其它副反应导致的副产物成为药物多肽生产过程中一个极为关切的问题.另外固相多肽合成的低原子经济性给可持续发展带来了极大的挑战.这些问题只能依靠原始创新的颠覆性技术和全新的缩合方法来解决.我们课题组致力于通过发展新试剂和新反应来解决多肽与蛋白质化学合成领域的难题.本文系统介绍了我们发展的一种结构全新的炔酰胺类缩合试剂及其在酰胺、酯、大环内酯、多肽、硫代多肽合成中的应用研究进展.     

Carbodiimide-Mediated Beckmann Rearrangement of Oxyma-B as a Side Reaction in Peptide Synthesis

The suppression of side reactions is one of the most important objectives in peptide synthesis, where highly reactive compounds are involved. Recently, the violuric acid derivative Oxyma-B was introduced into peptide synthesis protocols as a promising additive to efficiently control the optical purity of the amino acids prone to racemization. However, we discovered a side reaction involving the Beckmann rearrangement of Oxyma-B during the coupling reaction, which compromises the yield and purity of the target peptides. Here, we present the investigation of the mechanism of this rearrangement and the optimization of the coupling reaction conditions to control it. These results can be taken into account for the design of novel efficient oxime-based coupling reagents.     

Enzymatic coupling of specific peptides at nonspecific ligation sites: effect of Asp189Glu mutation in trypsin on substrate mimetic-mediated reactions

Two main drawbacks seriously restrict the synthetic value of proteases as reagents in peptide fragment coupling: (i) native proteolytic activity and, thus, risk of undesired peptide cleavage; (ii) limited enzyme specificities restricting the amino acid residues between which a peptide bond can be formed. While the latter can be overcome by the use of substrate mimetics achieving peptide bond formation at nonspecific ligation sites, the risk of proteolytic cleavage still remains and hinders the wide acceptance of this powerful strategy for peptide coupling. This paper reports on the effect of the trypsin point mutant Asp189Glu on substrate mimetic-mediated reactions. The effect of this mutation on the steady-state hydrolysis of substrate mimetics of the 4-guanidinophenyl ester type and on trypsin-specific Lys- and Arg-containing peptides was investigated. The results were confirmed by enzymatic coupling reactions using substrate mimetics as the acyl donor and specific amino acid-containing peptides as the acyl acceptor. The competition assay verifies the predicted shift in substrate preference from Lys and Arg to the substrate mimetics and, thus, from cleavage to synthesis of peptide bonds. The combination of results obtained qualifies the trypsin mutant D189E as the first substrate mimetic-specific peptide ligase.     

Enabling routine fluorous capping in solid phase peptide synthesis

We describe here the use of polyfluorinated trivalent iodonium salts as efficient and robust capping reagents during solid phase peptide synthesis using either t-Boc or Fmoc chemistry. Standard protocols established for solid phase peptide synthesis can be utilized without any change in solvent or reagent conditions. The capping reaction was carried out at sites where amino acid coupling steps failed. At the termination of the synthesis, the crude peptide mixture obtained from release of materials from the resin, is either simply centrifuged in aqueous solution to yield pure peptide, or purified by passage through fluorous silica gel in solvents with high water content. We envision that the chemistry and reagents described here will find wide use in peptide and protein chemistry, and also in combinatorial library synthesis where terminal amines are coupled to reaction partners.     

Synthesis and Chemical Constitution of Diphenoxyphosphoryl Derivatives and Phosphonium Salts as Coupling Reagents for Peptide Segment Condensation

The reactions of diphenoxyphosphoryl chloride ((PhO) 2 P(O)Cl) and different chlorophosphonium salts ([R 3 PCl]X, R = (CH 3 ) 2 N, pyrrolidine, X = PF 6 m , BF 4 m ), respectively, with 7-aza-1-hydroxybenzotriazole (HOAt), 1-hydroxybenzotriazole (HOBt), hydroximinomalonitrile (HOxDCO), and ethyl hydroximinocyanoacetate (HOxO) are described. The structures of the new compounds, which are useful coupling reagents for epimerization-free peptide segment condensation, are discussed on the basis of their 1 H, 13 C, 31 P NMR, and IR spectra. The reactions of (PhO) 2 P(O)Cl lead to mixtures of O - and N -phosphorylated isomers of varying ratios. Contrary, reactions of chlorophosphonium salts yield exclusively one isomer.     

Improved procedure for the synthesis of thiazolium-type peptide coupling reagents: BMTB as a new efficient reagent

An efficient scalable synthesis of 2-halothiazolium-type peptide coupling reagents has been developed. The key step is the formation of the 2-bromothiazole scaffold through cyclization of α-thiocyanato ketones with hydrogen bromide. Using this method, the new coupling reagent 2-bromo-N-methylthiazolium bromide (BMTB) was synthesized. BMTB was tested in a difficult model coupling reaction of two sterically hindered N-methylated amino acids and showed higher activity than the well-established peptide coupling reagent HATU.     

Capillary electrophoresis of cationic random coil peptide standards: effect of anionic ion-pairing reagents and comparison with reversed-phase chromatography

The present study compares a charge/hydrophobicity capillary electrophoresis (CE) approach to reversed-phase high-performance liquid chromatography (RP-HPLC) for the separation of three series of four synthetic, random coil peptide standards. Each series has peptides of the same positive charge (+1, +2 and +3 series) and length but differing in hydrophobicity. Complete resolution of the 12 peptides was achieved via a novel CE approach: a capillary zone electrophoresis (CZE) mode effected a separation of identically charged peptides; within each charged group of peptides, the addition of perfluorinated acid anionic ion-pairing reagents allowed resolution of the peptides through a mechanism based on peptide hydrophobicity which we have termed ioninteraction (II)-CZE. The peak capacity and peptide resolution of this CE approach was superior to that of RP-HPLC and stresses an important role for CE for peptide/proteomic applications.     

Effect of anionic ion-pairing reagent concentration (1-60 mM) on reversed-phase liquid chromatography elution behaviour of peptides

The homologous series of volatile perfluorinated acids-trifluoroacetic acid (TFA), pentafluoropropionic acid (PFPA) and heptafluorobutyric acid (HFBA)--continue to be excellent anionic ion-pairing reagents for reversed-phase high-performance liquid chromatography (RP-HPLC) after more than two decades since their introduction to this field. It was felt that a thorough, step-by-step re-examination of the effects of anionic ion-pairing reagents over a wide concentration range on RP-HPLC peptide elution behaviour is now due, particularly considering the continuing dominance of such reagents for peptide applications. Thus, RP-HPLC was applied over a range of 1-60 mM phosphoric acid, TFA, PFPA and HFBA to two mixtures of 18-residue synthetic peptides containing either the same net positive charge (+4) or varying positive charge (+1, +2, +3, +4). Peptides with the same charge are resolved very similarly independent of the ion-pairing reagent used, although the overall retention times of the peptides increase with increasing hydrophobicity of the anion: phosphate < TFA- < PFPA- < HFBA-. Peptides of differing charge move at differing rates relative to each other depending on concentration of ion-pairing reagents. All four ion-pairing reagents increased peptide retention time with increasing concentration, albeit to different extents, again based on hydrophobicity of the anion, i.e., the more hydrophobic the anion, the greater the increase in peptide retention time at the same reagent concentration. Interestingly, phosphoric acid produced the best separation of the four-peptide mixture (+1 to +4 net charge). In addition, concentrations above 10 mM HFBA produced a reversal of the elution order of the four peptides (+1 < + 2 < + 3 < + 4) compared to the elution order produced by the other three reagents over the entire concentration range (+4 < + 3 < + 2 < + 1).     

N-triazinylammonium tetrafluoroborates. A new generation of efficient coupling reagents useful for peptide synthesis

A new generation of triazine-based coupling reagents (TBCRs), designed according to the concept of "superactive esters", was obtained by treatment of 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium (DMTMM) chloride with lithium or silver tetrafluoroborate. The structure of 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium tetrafluoroborate was confirmed by X-ray diffraction. Activation of carboxylic acids by using this reagent proceeds via triazine "superactive ester". The coupling reagent was successfully used for the synthesis of Z-, Boc-, and Fmoc-protected dipeptides derived from natural and unnatural sterically hindered amino acids and for fragment condensation, in 80-100% yield and with high enantiomeric purity. The manual SPPS of the ACP(65-74) peptide fragment (H-Val-Gln-Ala-Ala-Ile-Asp-Tyr-Ile-Asn-Gly-OH) proceeded significantly faster than with TBTU or HATU, as well as the automated SPPS of the same fragment gave a purer product than by using TBTU or PyBOP. The reagent was also demonstrated to be efficient in on-resin head-to-tail cyclization of constrained cyclopeptides, in SPPS synthesis of Aib peptides, and in the synthesis of esters from appropriate acids, alcohols, and phenols. The high efficiency and versatility of this new generation of TBCRs confirm, for the first time, the usefulness of the concept of "superactive esters" in rational design of the structure of coupling reagents.     

有机磷试剂在肽合成中的应用

本文综述有机磷试剂在肽合成中的应用情况,介绍了各种用作氨基保护试剂的磷(膦)酰氯及硫代膦酰氯和四价鏻盐;并着重介绍了不同价态的有机磷试剂用于羧基活化的发展状况。 . t