Peptide mixed phosphonates for covalent complex formation with thioesterases in nonribosomal peptide synthetases.

Natural macrocyclic peptides derived from microorganisms are medicinal resources that are important for the development of new therapeutic agents. Most of these molecules are biosynthesized by a nonribosomal peptide synthetase (NRPS). The thioesterase (TE) domain in NRPS is responsible for the macrocyclization of mature linear peptide thioesters in a final biosynthetic step. NRPS-TEs can cyclize synthetic linear peptide analogs and can be utilized as biocatalysts for the preparation of natural product derivatives. Although the structures and enzymatic activities of TEs have been investigated, the substrate recognition and substrate-TE interaction during the macrocyclization step are still unknown. To understand the TE-mediated macrocyclization, here we report the development of a substrate-based analog with mixed phosphonate warheads, which can react irreversibly with the Ser residue at the active site of TE. We have demonstrated that the tyrocidine A linear peptide (TLP) with a p-nitrophenyl phosphonate (PNP) enables efficient complex formation with tyrocidine synthetase C (TycC)-TE containing tyrocidine synthetase.

Establishment of One-Pot Disulfide-Driven Cyclic Peptide Synthesis with a 3-Nitro-2-pyridinesulfenate.

We have developed a new one-pot disulfide-driven cyclic peptide synthesis. The entire process is carried out in the solid phase, thus eliminating complicated work up procedures to remove by-products and unreacted reagents and enabling production of high-purity cyclic disulfide peptides by simple cleavage of a peptidyl resin. The one-pot synthesis of oxytocin was accomplished in this way with an isolated yield of 28% over 13 steps. These include peptide chain elongation from an initial resin, sulfenylation of the protected side chain of a cysteine (Cys) residue, disulfide ligation between thiols in an additional peptide fragment and a 3-nitro-2-pyridinesulfenyl-protected cysteine (Cys(Npys))-containing peptide resin, subsequent intramolecular amide bond formation of the disulfide-connected fragments by an Ag+-promoted thioester method, followed by deprotection and HPLC purification.

Photo-oxygenation by a biocompatible catalyst reduces amyloid-ß levels in Alzheimer's disease mice.

Amyloid formation and the deposition of the amyloid-ß peptide are hallmarks of Alzheimer's disease pathogenesis. Immunotherapies using anti-amyloid-ß antibodies have been highlighted as a promising approach for the prevention and treatment of Alzheimer's disease by enhancing microglial clearance of amyloid-ß peptide. However, the efficiency of antibody delivery into the brain is limited, and therefore an alternative strategy to facilitate the clearance of brain amyloid is needed. We previously developed an artificial photo-oxygenation system using a low molecular weight catalytic compound. The photocatalyst specifically attached oxygen atoms to amyloids upon irradiation with light, and successfully reduced the neurotoxicity of aggregated amyloid-ß via inhibition of amyloid formation. However, the therapeutic effect and mode of actions of the photo-oxygenation system in vivo remained unclear. In this study, we demonstrate that photo-oxygenation facilitates the clearance of aggregated amyloid-ß from the brains of living Alzheimer's disease model mice, and enhances the microglial degradation of amyloid-ß peptide. These results suggest that photo-oxygenation may represent a novel anti-amyloid-ß strategy in Alzheimer's disease, which is compatible with immunotherapy.

Development of Methods for Convergent Synthesis of Chloroalkene Dipeptide Isosteres and Its Application.

Improved methods of convergent synthesis for peptidomimetic utilizing a chloroalkene dipeptide isostere (CADI) are reported. In this synthesis, Fmoc- or Boc-protected carboxylic acids can be produced from N- and C-terminal analogues corresponding to each amino acid starting material via an Evans syn aldol reaction, followed by a [3.3] sigmatropic rearrangement utilizing the Ichikawa allylcyanate rearrangement reaction. With this strategy, an Fmoc-protected CADI can be directly applied for solid-phase peptide synthesis. Using this approach, we have also identified the CADI-containing cyclo[-Lys-Leu-Val-Phe-Phe-] peptidomimetic, which is a superior inhibitor of amyloid-ß aggregation than the parent peptide.

Strategic structure-activity relationship study on a follistatin-derived myostatin inhibitory peptide.

Myostatin, a negative regulator of muscle mass is a promising target for the treatment of muscle atrophic diseases. The novel myostatin inhibitory peptide, DF-3 is derived from the N-terminal α-helical domain of follistatin, which is an endogenous inhibitor of myostatin and other TGF-ß family members. It has been suggested that the optimization of hydrophobic residues is important to enhance the myostatin inhibition. This study describes a structure-activity relationship study focused on hydrophobic residues of DF-3 and designed to obtain a more potent peptide. A methionine residue in DF-3, which is susceptible to oxidation, was successfully converted to homophenylalanine in DF-100, and a new derivative DF-100, with four amino acid substitutions in DF-3 shows twice the potent inhibitory ability as DF-3. This report provides a new platform of a 14-mer peptide muscle enhancer.

Development of functionalized peptides for efficient inhibition of myostatin by selective photooxygenation.

For the inhibition of myostatin, which is an attractive strategy for the treatment of muscle atrophic disorders including muscular dystrophy, myostatin-binding peptides were synthesized with an on/off-switchable photooxygenation catalyst at different positions on the peptide chain. These functionalized peptides oxygenated and inactivated myostatin upon irradiation with near-infrared light. Among the peptides tested, a peptide (5) with the catalyst moiety at the 16 position induced myostatin-selective photooxygenation, and efficiently inhibited myostatin. These peptides exhibited low phototoxicity. Such functionalized peptides would provide a precedented strategy for myostatin-targeting therapy, in which myostatin is irreversibly and catalytically inactivated by photooxygenation.

Proposal for the binding mode of the 23-mer inhibitory peptide to myostatin.

Inhibition of myostatin is a promising strategy for the treatment of amyotrophic disorders. Previously, we identified a minimum 23-mer peptide spanning positions 21-43 of a mouse myostatin precursor-derived prodomain and identified the nine key residues for effective myostatin inhibition through Ala scanning. We also reported the 23-mer peptides that show the propensity to form an α-helical structure around positions 32-36. Here, based on these findings, we conducted a docking simulation of a peptide-myostatin interaction. The results showed that by α-helix restraint docking of the 30-41 main chain, we obtained a proposed binding mode in which all nine of the key residues interact with myostatin. By analyzing the binding mode of four proposed docking models, we identified six of the myostatin residues that play an important role in the interaction with the peptide. This result provides a valuable insight into the relationship between myostatin and peptide interaction sites and may help in the design of future inhibitors.

Structural Revision of Natural Cyclic Depsipeptide MA026 Established by Total Synthesis and Biosynthetic Gene Cluster Analysis.

A revised structure of natural 14-mer cyclic depsipeptide MA026, isolated from Pseudomonas sp. RtlB026 in 2002 was established by physicochemical analysis with HPLC, MS/MS, and NMR and confirmed by total solid-phase synthesis. The revised structure differs from that previously reported in that two amino acid residues, assigned in error, have been replaced. Synthesized MA026 with the revised structure showed a tight junction (TJ) opening activity like that of the natural one in a cell-based TJ opening assay. Bioinformatic analysis of the putative MA026 biosynthetic gene cluster (BGC) of RtIB026 demonstrated that the stereochemistry of each amino acid residue in the revised structure can be reasonably explained. Phylogenetic analysis with xantholysin BGC indicates an exceptionally high homology (ca. 90 %) between xantholysin and MA026. The TJ opening activity of MA026 when binding to claudin-1 is a key to new avenues for transdermal administration of large hydrophilic biologics.

Disulfide-Driven Cyclic Peptide Synthesis of Human Endothelin-2 with a Solid-Supported Npys-Cl.

We report here the synthesis of human endothelin-2, a peptide of 21 amino acid residues with two disulfide bonds, based on the novel idea of a disulfide-driven cyclic peptide synthesis (DdCPS). This synthesis has two steps: (1) a one-pot solid-phase disulfide ligation of two different sulfur-containing peptide fragments using an Npys-Cl resin and (2) intramolecular cyclization of the disulfide peptide via amide bond formation using a thioester ligation. Human endothelin-2 was obtained in a total yield of 2.2% with two such DdCPS procedures and subsequent deprotection and HPLC purification. This strategy is the basis of a new solid-phase assisted practical synthesis of cyclic disulfide peptides.

Discovery of a follistatin-derived myostatin inhibitory peptide.

Follistatin is well known as an inhibitor of transforming growth factor (TGF)-ß superfamily ligands including myostatin and activin A. Myostatin, a negative regulator of muscle growth, is a promising target with which to treat muscle atrophic diseases. Here, we focused on the N-terminal domain (ND) of follistatin (Fst) that interacts with the type I receptor binding site of myostatin. Through bioassay of synthetic ND-derived fragment peptides, we identified DF-3, a new myostatin inhibitory 14-mer peptide which effectively inhibits myostatin, but fails to inhibit activin A or TGF-ß1, in an in vitro luciferase reporter assay. Injected intramuscularly, DF-3 significantly increases skeletal muscle mass in mice and consequently, it can serve as a platform for development of muscle enhancement based on myostatin inhibition.

Design and synthesis of peptidic partial agonists of human neuromedin U receptor 1 with enhanced serum stability.

Neuromedin U (NMU) activates two receptors (NMUR1 and NMUR2) and is a promising candidate for development of drugs to combat obesity. Previously, we obtained hexapeptides as selective full NMUR agonists. Development of a partial agonist which mildly activates receptors is an effective strategy which lead to an understanding of the functions of NMU receptors. In 2014, we reported hexapeptide 3 (CPN-124) as an NMUR1-selective partial agonist but its selectivity and serum stability were unsatisfactory. Herein, we report the development of a hexapeptide-type partial agonist (8, CPN-223) based on a peptide (3) but with higher NMUR1-selectivity and enhanced serum stability. A structure-activity relationship study of synthetic pentapeptide derivatives suggested that a hexapeptide is a minimum structure consistent with both good NMUR1-selective agonistic activity and serum stability.

Use of solid-supported 4-fluorophenyl 3-nitro-2-pyridinesulfenate in the construction of disulfide-linked hybrid molecules.

To construct disulfide-linked hybrid molecules systematically and efficiently, we established a more practical solid-phase disulfide ligation (SPDSL) system with enhanced utility. The group Npys-OPh(pF) shows reactivity similar to that of Npys-Cl, but it is more stable. An efficient synthesis of the cyclic peptide oxytocin and a peptide-sugar conjugate was accomplished as models. These results indicate that the Npys-OPh(pF) resin functions as a common synthetic platform in SPDSL.

A chemically stable peptide agonist to neuromedin U receptor type 2.

Neuromedin U (NMU) is a peptide with appetite suppressive activity and other physiological activities via activation of the NMU receptors NMUR1 and NMUR2. In 2014, we reported the first NMUR2 selective agonist, 3-cyclohexylpropionyl-Leu-Leu-Dap-Pro-Arg-Asn-NH2 (CPN-116). However, we found that CPN-116 in phosphate buffer is unstable because of Nα-to-Nß acyl migration at the Dap residue. In this study, the chemical stability of CPN-116 was evaluated under various conditions, and it was found to be relatively stable in buffers such as HEPES and MES. We also performed a structure-activity relationship study to obtain an NMUR2-selective agonist with improved chemical stability. Consequently, CPN-219 bearing a Dab residue in place of Dap emerged as a next-generation hexapeptidic NMUR2 agonist.

Enzymatic Stability of Myostatin Inhibitory 16-mer Peptides.

Inhibition of myostatin is a promising strategy for treatment of muscle atrophic disorders. A 16-mer myostatin inhibitory linear peptide, MIPE-1686, administered intramuscularly, significantly increases muscle mass and hindlimb grip strength in Duchenne muscular dystrophic model mice. In this paper, we describe our examination of the enzymatic stabilities of this peptide with recombinant human proteases, aminopeptidase N, chymotrypsin C, and trypsin 3. MIPE-1686 was found to be stable in the presence of these enzymes, in contrast to a peptide (1), from which MIPE-1686 was developed. Modification of the peptides at a position distant from the protease cleavage site altered their enzymatic stability. These results suggest the possibility that the stability to proteases of 16-mer myostatin inhibitory peptides is associated with an increase in their known ß-sheet formation properties. This study suggests that MIPE-1686 has a potential to serve as a long-lasting agent in vivo.

Design and synthesis of potent myostatin inhibitory cyclic peptides.

Myostatin is a negative regulator of skeletal muscle growth and myostatin inhibitors are promising lead compounds against muscle atrophic disorders such as muscular dystrophy. Previously, we published the first report of synthetic myostatin inhibitory 23-mer peptide 1, which was identified from a myostatin precursor-derived prodomain protein. Our structure-activity relationship study afforded the potent inhibitory peptide 3. In this paper, we report an investigation of the synthesis of conformationally-constrained cyclic peptide based on the linear peptide 3. To examine the potency of side chain-to-side chain cyclized peptides, a series of disulfide-, lactam- and diester-bridged derivatives were designed and synthesized, and their myostatin inhibitory activities were evaluated. The diester-bridged peptide (11) displayed potent inhibitory activity with an in vitro IC50 value of 0.26 µM, suggesting that it could serve as a new platform for development of cyclic peptide inhibitors.

4-Fluorophenyl 3-nitro-2-pyridinesulfenate as a practical protecting agent for amino acids.

We report a new protecting agent (1, Npys-OPh(pF)) for 3-nitro-2-pyridine (Npy) sulfenylation of amino, hydroxy, and thiol functional groups. Several Npys phenoxides were synthesized from Npys chloride (Npys-Cl) and phenols in the presence of base in 1-step reaction, and their ability for Npy-sulfenylation was evaluated. As a result, 1 was selected as a new Npy-sulfenylation agent with advantages including improved physicochemical stability, more controllable reactivity, and easier handling than the conventional protecting agent Npys-Cl.

An Efficient Method for the Conjugation of Hydrophilic and Hydrophobic Components by Solid-Phase-Assisted Disulfide Ligation.

Chemical conjugation between hydrophilic and hydrophobic components is difficult because of their extremely different solubility. Herein, we report a new versatile method with a solid-phase-assisted disulfide ligation to overcome the difficulty of conjugation attributed to solubility. The method involves two steps in a one-pot process: 1) loading of a hydrophobic molecule onto a resin in an organic solvent, and 2) release of the solid-supported hydrophobic molecule as a conjugate with a hydrophilic molecule into an aqueous solvent. This strategy allows the use of a suitable solvent system for the substrates in each step. Conjugates of a water-insoluble drug, plinabulin, with hydrophilic carriers that could not be prepared by solution-phase reactions were obtained in moderate yields (29-45 %). This strategy is widely applicable to the conjugation of compounds with solubility problems.

Attenuation of the aggregation and neurotoxicity of amyloid-ß peptides by catalytic photooxygenation.

Alzheimer's disease (AD), a progressive severe neurodegenerative disorder, is currently incurable, despite intensive efforts worldwide. Herein, we demonstrate that catalytic oxygenation of amyloid-ß peptides (Aß) might be an effective approach to treat AD. Aß1-42 was oxygenated under physiologically-relevant conditions (pH 7.4, 37 °C) using a riboflavin catalyst and visible light irradiation, with modifications at the Tyr(10) , His(13) , His(14) , and Met(35) residues. The oxygenated Aß1-42 exhibited considerably lower aggregation potency and neurotoxicity compared with native Aß. Photooxygenation of Aß can be performed even in the presence of cells, by using a selective flavin catalyst attached to an Aß-binding peptide; the Aß cytotoxicity was attenuated in this case as well. Furthermore, oxygenated Aß1-42 inhibited the aggregation and cytotoxicity of native Aß.

Rational design and identification of a non-peptidic aggregation inhibitor of amyloid-ß based on a pharmacophore motif obtained from cyclo[-Lys-Leu-Val-Phe-Phe-].

Inhibition of pathogenic protein aggregation may be an important and straightforward therapeutic strategy for curing amyloid diseases. Small-molecule aggregation inhibitors of Alzheimer's amyloid-ß (Aß) are extremely scarce, however, and are mainly restricted to dye- and polyphenol-type compounds that lack drug-likeness. Based on the structure-activity relationship of cyclic Aß16-20 (cyclo-[KLVFF]), we identified unique pharmacophore motifs comprising side-chains of Leu(2), Val(3), Phe(4), and Phe(5) residues without involvement of the backbone amide bonds to inhibit Aß aggregation. This finding allowed us to design non-peptidic, small-molecule aggregation inhibitors that possess potent activity. These molecules are the first successful non-peptidic, small-molecule aggregation inhibitors of amyloids based on rational molecular design.

Discovery of a Pentapeptide Antagonist to Human Neuromedin U Receptor 1.

Neuromedin U (NMU) activates two types of receptors (NMUR1 and NMUR2), and the former is mainly expressed in the peripheral tissues, including the intestinal tract and lung tissues. Since NMUR1 contributes to the promotion of type 2 inflammation in these tissues, it is a potential target to suppress inflammatory responses. However, promising antagonist candidates for human NMUR1 have not yet been developed. Here we successfully identified pentapeptide antagonist 9a through a structure-activity relationship study based on hexapeptide lead 1. Its antagonistic activity against human NMUR1 was 10 times greater than that against NMUR2. This is a breakthrough in the development of NMUR1-selective antagonists. Although 9a was relatively stable in the plasma, the C-terminal amide was rapidly degraded to the carboxylic acid by the serum endopeptidase thrombin, which acted as an amidase. This basic information would aid in sample handling in future biological evaluations.