Enantioselective total synthesis of parnafungin A1 and 10a-epi-hirtusneanine

The first and enantioselective total synthesis of the heterodimeric biaryl antifungal natural product parnafungin A1 as well as complex biaryl tetrahydroxanthone 10a-epi-hirtusneanine is accomplished, by employing cross-coupling through the benzoxaborole strategy to construct their sterically hindered biaryl cores. Besides the powerful Suzuki–Miyaura cross-coupling, the synthesis of parnafungin A1 also features a highly diastereoselective oxa-Michael addition to construct a tetrahydroxanthone skeleton, and an effective Zn-mediated reductive cyclization-Mitsunobu sequence to furnish the isoxazolidinone structure. Key innovations in total synthesis of 10a-epi-hirtusneanine include the employment of DTBS protection for functional group manipulation on the tetrahydroxanthone skeleton, stereoselective methylations, and complete reversal of the stereochemistry of the C5-hydroxy group using oxidation/Evans–Saksena reduction, as well as the strategy of preparing both complex tetrahydroxanthone monomers from the same chiral intermediate 25.

The first, enantioselective total synthesis of the heterodimeric biaryl antifungal natural product parnafungin A1 as well as 10a-epi-hirtusneanine is accomplished, using a cross-coupling strategy to construct their sterically hindered biaryl cores.     

Tricine as a convenient scaffold for the synthesis of C-terminally branched collagen-model peptides

A novel and convenient method for the synthesis of C-terminally branched collagen-model peptides has been achieved using tricine (N-[tris(hydroxymethyl)methyl]glycine) as a branching scaffold and 1,2-diaminoethane or 1,4-diaminobutane as a linker. The peptide sequence was incorporated directly onto the linker and scaffold during solid-phase synthesis without additional manipulations. The resulting branched triple-helical peptides exhibited comparable thermal stabilities to the parent, unbranched sequence, and served as substrates for matrix metalloproteinase-1 (MMP-1). The tricine-based branch reported herein represents the simplest synthetic scaffold for the convenient synthesis of covalently linked homomeric collagen-model triple-helical peptides.     

Modelling of prebiotic synthesis and selection of peptides under isothermal conditions and thermal cycling mode

The model peptide synthesis from mixtures of amino acids was carried out under the thermal cycling and isothermal modes. The compositions of the obtained mixtures of products and the primary amino acid sequence of the synthesized peptides were determined by Fourier transform ion cyclotron resonance mass spectrometry and tandem mass spectrometry in combination with high-performance liquid chromatography with the application of de novo sequencing of the synthesized products. The processes of abiogenous synthesis of peptides were shown to occur under relatively mild temperature conditions and give a substantially less number of peptides as compared with the possible statistical set. The evolution of the system takes place in the process of the synthesis in solid phase with the disappearance of a series of the most unstable peptides. The selection process with the formation of complementary peptides takes place in peptide synthesis under the thermal cyclic mode.     

A One‐Pot Chemically Cleavable Bis‐Linker Tether Strategy for the Synthesis of Heterodimeric Peptides

Heterodimeric peptides linked by disulfide bonds are attractive drug targets. However, their chemical assembly can be tedious, time‐consuming, and low yielding. Inspired by the cellular synthesis of pro‐insulin in which the two constituent peptide chains are expressed as a single‐chain precursor separated by a connecting C‐peptide, we have developed a novel chemically cleavable bis‐linker tether which allows the convenient assembly of two peptide chains as a single “pro”‐peptide on the same solid support. Following the peptide cleavage and post‐synthetic modifications, this bis‐linker tether can be removed in one‐step by chemical means. This method was used to synthesize a drug delivery‐cargo conjugate, TAT‐PKCi peptide, and a two‐disulfide bridged heterodimeric peptide, thionin (7‐19)‐(24‐32R), a thionin analogue. To our knowledge, this is the first report of a one‐pot chemically cleavable bis‐linker strategy for the facile synthesis of cross‐bridged two‐chain peptides.     

Liposome fusion with orthogonal coiled coil peptides as fusogens: the efficacy of roleplaying peptides

Biological membrane fusion is a highly specific and coordinated process as a multitude of vesicular fusion events proceed simultaneously in a complex environment with minimal off-target delivery. In this study, we develop a liposomal fusion model system with specific recognition using lipidated derivatives of a set of four de novo designed heterodimeric coiled coil (CC) peptide pairs. Content mixing was only obtained between liposomes functionalized with complementary peptides, demonstrating both fusogenic activity of CC peptides and the specificity of this model system. The diverse peptide fusogens revealed important relationships between the fusogenic efficacy and the peptide characteristics. The fusion efficiency increased from 20% to 70% as affinity between complementary peptides decreased, (from K_F ≈ 10⁸ to 10⁴ M⁻¹), and fusion efficiency also increased due to more pronounced asymmetric role-playing of membrane interacting ‘K’ peptides and homodimer-forming ‘E’ peptides. Furthermore, a new and highly fusogenic CC pair (E₃/P1_K) was discovered, providing an orthogonal peptide triad with the fusogenic CC pairs P2_E/P2_K and P3_E/P3_K. This E₃/P1_k pair was revealed, via molecular dynamics simulations, to have a shifted heptad repeat that can accommodate mismatched asparagine residues. These results will have broad implications not only for the fundamental understanding of CC design and how asparagine residues can be accommodated within the hydrophobic core, but also for drug delivery systems by revealing the necessary interplay of efficient peptide fusogens and enabling the targeted delivery of different carrier vesicles at various peptide-functionalized locations.

We developed a liposomal fusion model system with specific recognition using a set of heterodimeric coiled coil peptide pairs. This study unravels important structure–fusogenic efficacy relationships of peptide fusogens.     

A new route to the synthesis of isoxazoline derivatives from dihydropyran via cycloaddition reaction in ionic liquid

A new approach to the synthesis and 1,3-dipolar cycloadditions of nitrones has been described from 2,3-dihydro-4H-pyran and various hydroxylamines, with electron-deficient alkynes for the synthesis of isoxazoline derivatives. Significant rate acceleration and improved yields of exclusively exo isoxazolines in 1-butyl-3-methylimidazolium based ionic liquids have been observed. Novel isoxazolines may be used as a precursor for the synthesis of variety of peptides.     

Diastereoselective synthesis of homologous bicyclic lactams--potential building blocks for peptide mimics

Bicyclic lactams serve as building blocks for the synthesis of conformationally restricted peptides. A route to these building blocks is described. They can serve as cis- and trans-peptide bond surrogates. Due to the de novo synthesis, both enantiomeric forms of these products can be produced. Key steps are a lipase-catalyzed saponification of oximes and a highly diastereoselective cyclization utilizing phenylselenyl bromide. In addition, attachment to a solid support has been achieved.     

A novel and efficient approach for the amidation of C-terminal peptides

A highly efficient and practical synthesis of C-terminal amidated peptides has been developed. According to this approach, amidation of the C-terminus of peptides was carried out using NH₄Cl, alkylammonium chloride (RNH₃Cl) and semicarbazide hydrochloride in the presence of TBTU as a coupling reagent and a tertiary amine as the base at room temperature in good to high yields. Some opioid peptides such as enkephalin derivatives were synthesized according to this novel method.     

A convenient solid phase synthesis of S-palmitoyl transmembrane peptides

S-Palmitoylated peptides are important tools as models for integral membrane proteins to study peptide-lipid interactions. Herein, we report a convenient solid phase synthesis of S-palmitoyl transmembrane peptides. The highly acid labile S-(4-methoxytrityl) group is preferred over the S-(tert-butylsulfanyl) group for protection of the cysteine side chain since the latter gives rise to quantitative desulfurization during on-resin deprotection. The resulting free thiol function is modified with palmitic acid via a carbodiimide-mediated coupling and the title compounds are obtained in good yields and purity.     

Synthesis of cell-permeable stapled BH3 peptide-based Mcl-1 inhibitors containing simple aryl and vinylaryl cross-linkers

We report the synthesis of a series of distance-matching aryl and vinylaryl cross-linkers for constructing stapled peptides containing cysteines at i,i+7 positions. Langevin dynamics simulation studies helped to classify these cross-linkers into two categories: the rigid cross-linkers with narrower S–S distance distribution and the flexible cross-linkers with wider S–S distance distribution. The stapled Noxa BH3 peptides with the flexible distance-matching cross-linkers gave the highest degree of helicity as well as the most potent inhibitory activity against Mcl-1. However, the stapled peptides with the highest hydrophobicity showed the most efficient cellular uptake. Together, this work illustrates the divergent nature of binding affinity and cellular uptake, and the vital importance of choosing appropriate cross-linkers in constructing stapled peptides with the drug-like properties.     

Peptide synthesis with benzisoxazolium salts—III : Utility of 7-hydroxy-2-ethylbenzisoxazolium fluoroborate in the synthesis of peptides

The scope and limitations of the 7-hydroxy-2-ethylbenzisoxazolium salt method of forming amide bonds are outlined through the synthesis of a variety of simple peptide derivatives containing all of the common amino acids with the exceptions of arginine and histidine. The 3-acyloxy-2-hydroxy-N-ethylbenzamides derived from C-terminal serine or threonine containing peptides are found to react with amines at anomalously slow rates and with the formation of transesterified byproducts; a mechanistic explanation is offered. The utility of the method for the synthesis of medium sized peptides is examined by synthesis of oligomers of Gly-L-Leu-Gly.     

A novel method for identification and relative quantification of N-terminal peptides using metal-element-chelated tags coupled with mass spectrometry

By means of the reaction between a DOTA-NHS-ester bifunctional reagent and N-terminal peptides of proteins,and then chelation of lanthanide metal ions as tags,we established a novel method for the identification of N-terminal peptides of proteins and their relative quantification using metal-element-chelated tags coupled with mass spectrometry.The experimental results indicate that metal elements are able to completely label N-terminal peptides at the protein level.The N-terminal peptides are enriched as the peptides digested with trypsin are selectively eliminated by isothiocyanate-coupled silica beads.We successfully identified the N-terminal peptides of 158 proteins of Thermoanaerobacter tengcongensis incubated at 55 and 75°C,among which N-terminal peptides of 24 proteins are partially acetylated.Moreover,metal-element tags with high molecule weights make it convenient for N-terminal peptides consisting of less than 6 amino acids to be identified;these make up 55percent of the identified proteins.Finally,we developed a general approach for the relative quantification of proteins based on N-terminal peptides.We adopted lysozyme and ribonuclease B as model proteins;the correlation coefficients(R2)of the standard curves for the quantitative method were 0.9994 and 0.9997,respectively,with each concentration ratio ranging from0.1 to 10 and both relative standard derivations(RSD)measured at less than 5%.In T.tengcongensis at two incubation temperatures,80 proteins possess quantitative information.In addition,compared with the proteins of T.tengcongensis incubated at 55°C,in T.tengcongensis incubated at 75°C,7 proteins upregulate whereas 16 proteins downregulate,and most differential proteins are related to protein synthesis.     

Preparation of orthogonally protected (2S,3R)-2-amino-3-methyl-4-phosphonobutyric acid (Pmab) as a phosphatase-stable phosphothreonine mimetic and its use in the synthesis of polo-box domain-binding peptides

Reported herein is the first stereoselective synthesis of (2S,3R)-4-[bis-(tert-butyloxy)phosphinyl]-2-[(9H-fluoren-9-ylmethoxy)carbonyl]amino-3-methylbutanoic acid [(N-Fmoc, O,O-(bis-(tert-butyl))-Pmab), 4] as a hydrolytically-stable phosphothreonine mimetic bearing orthogonal protection compatible with standard solid-phase protocols. The synthetic approach used employs Evans' oxazolidinone for chiral induction. Also presented is the application of 4 in the solid-phase synthesis of polo-like kinase 1 (Plk1) polo box domain (PBD)-binding peptides. These Pmab-containing peptides retain PBD binding efficacy similar to a parent pThr containing peptide. Reagent 4 should be a highly useful reagent for the preparation of signal transduction-directed peptides.     

N-Alkyl cysteine-assisted thioesterification of peptides

A new method for the preparation of peptide thioester by the post-solid phase peptide synthesis (SPPS) approach was developed. A series of N-alkyl cysteine derivatives were prepared and used as the C-terminus residue of the peptides prepared by the Fmoc SPPS. The synthetic peptides released from resin by TFA were readily converted to the peptide thioester in aqueous 3-mercaptopropionic acid (MPA) without significant side reactions.     

Synthesis of Ag-Fe3O4 heterodimeric nanoparticles

We report a general synthetic method for construction of size-controlled Ag-Fe3O4 heterodimeric nanoparticles using the Fe3O4 nanoparticles as the seeds. The Ag-Fe3O4 heterodimeric nanoparticle can be controlled by tuning the size of the Fe3O4 seed and reaction conditions for synthesis of the Ag nanoparticles grown on it. The as-synthesized nanoparticles can be readily converted into aqueous-soluble form with newly introduced functional groups on the surface of Ag-Fe3O4 heterodimeric nanoparticles.     

Scalable synthesis and coupling of quaternary α-arylated amino acids: α-aryl substituents are tolerated in α-helical peptides

Quaternary amino acids are important tools for the modification and stabilisation of peptide secondary structures. Here we describe a practical and scalable synthesis applicable to quaternary alpha-arylated amino acids (Q4As), and the development of solid-phase synthesis conditions for their incorporation into peptides. Monomeric and dimeric α-helical peptides are synthesised with varying degrees of Q4A substitution and their structures examined using biophysical methods. Both enantiomers of the Q4As are tolerated in folded monomeric and oligomeric α-helical peptides, with the (R)-enantiomer slightly more so than the (S).

Both R and S enantiomers of Fmoc-protected amino acids bearing α-aryl substituents may be made on gram scale. Solid-phase synthesis leads to helical peptides unperturbed by the presence of these additional α-aryl groups.     

Facile solid phase synthesis of N-cycloguanidinyl-formyl peptides

A novel strategy of solid phase synthesis of N-cycloguanidinyl-formyl peptides has been established and investigated which involved coupling orthogonal protected diaminoacid with resin bound peptide, α-amino group deprotection, guanidinylation of α-amino group by bis-Cbz-1H-pyrazole-1-carboxamidine followed by cleavage and cyclization in solution, and finally removing Cbz by palladium catalyzed hydrogenation. Through this method, cycloguanidine could be introduced to either N-terminus or sidechain of designated peptides. The reaction conditions were facile, straightforward, and totally adaptive to common solid phase peptide synthesis strategy.     

Modelluntersuchungen zur papainkatalysierten Peptidsynthese im wäßrig-organischen Zweiphasensystem

Several model peptides have been synthesized enzymatically using papain as a catalyst in biphasic aqueous-organic systems. The effect of different cosolvents,pH, buffer concentration, and reaction time on the papaincatalyzed synthesis was examined. A comparison of the results obtained indicates that water-immiscible organic solvents provide higher yields than methanol in papain mediated peptide synthesis with carboxyl components in the carboxyl free form. Furthermore, it could be established that papaincatalyzed peptide synthesis can be considerably speeded up by employing acyl peptide esters instead of acyl peptides. The former should promote the rapid formation of the acyl-enzyme intermediate.     

Fmoc-based solid-phase synthesis of adenylylated peptides using diester-type adenylylated amino acid derivatives

Phosphodiester-type adenylylated (AMPylated) Ser, Thr, and Tyr derivatives were developed for Fmoc solid phase peptide synthesis of AMPylated peptides. One-pot/sequential reaction consisting of condensation of an N-nonprotected adenosine derivative and Fmoc-Ser/Thr/Tyr-OAllyl using allyl-N,N-diisopropylchlorophosphoramidite and subsequent oxidation with m-chloroperbenzoic acid gave phosphotriester-type AMPylated Ser/Thr/Tyr derivatives. After Pd(0)-mediated deprotection of allyl groups, the resulting phosphodiester-type AMPylated Ser/Thr/Tyr derivatives were successfully incorporated into peptides by standard Fmoc solid phase peptide synthesis without significant side reactions including dehydroalanine formation.     

Efficient solid-phase synthesis of cyclic RGD peptides under controlled microwave heating

Cyclic RGD peptides are potent antagonists for the α_vβ₃ integrin receptor. In this Letter, microwave-assisted solid-phase synthesis of cyclic RGD peptides is described. In a coupling reaction between Fmoc-Arg(Pbf)-OH and high-loading H-Gly-Trt(2-Cl) resin, multiple coupling reactions were required for completion under the conventional HBTU activation. We found that the use of COMU, a new coupling reagent, under microwave heating to 50 °C accelerated the reaction even inside the resin. This method was applicable to the synthesis of linear pentapeptides, H-Asp(OtBu)-Xxx-Yyy-Arg(Pbf)-Gly-OH (Xxx = d-Phe(p-Br) or d-Tyr, Yyy = Lys(Boc) or MeVal). Cyclization of these peptides followed by deprotection gave the desired cyclic RGD peptides with high purity.