Studies on acid stability and solid-phase block synthesis of peptide-peptoid hybrids: ligands for formyl peptide receptors.

α-Peptoids as well as peptide/α-peptoid hybrids and peptide/ß-peptoid hybrids constitute major classes of proteolytically stable peptidomimetics that have been extensively investigated as mimetics of biologically active peptides. Representatives of lipidated peptide/ß-peptoid hybrids have been identified as promising immunomodulatory lead compounds, and hence access to these via protocols suitable for gram-scale synthesis is warranted to enable animal in vivo studies. Recent observations indicated that several byproducts appear in crude mixtures of relatively short benzyl-based peptide/ß-peptoid oligomers, and that these were most predominant when the ß-peptoid units displayed an α-chiral benzyl side chain. This prompted an investigation of their stability under acidic conditions. Simultaneous deprotection and cleavage of peptidomimetics containing either α-chiral α- or ß-peptoid residues required treatment with strong acid only for a short time to minimize the formation of partially debenzylated byproducts. The initial work on peptide/ß-peptoid oligomers with an alternating design established that it was beneficial to form the amide bond between the carboxyl group of the α-amino acid and the congested amino functionality of the ß-peptoid residue in solution. To further simplify oligomer assembly on solid phase, we now present a protocol for purification-free solid-phase synthesis of tetrameric building blocks. Next, syntheses of peptidomimetic ligands via manual solid-phase methodologies involving tetrameric building blocks were found to give more readily purified products as compared to those obtained with dimeric building blocks. Moreover, the tetrameric building blocks could be utilized in automated synthesis with microwave-assisted heating, albeit the purity of the crude products was not increased.

Lactam hybrid analogues of solonamide B and autoinducing peptides as potent S. aureus AgrC antagonists.

Emergence of antibiotic-resistant bacteria constitutes an increasing threat to human health. For example, treatment options for Staphylococcus aureus infections is declining with the worldwide spreading of highly virulent community-associated methicillin-resistant S. aureus (CA-MRSA) strains. Anti-virulence therapy has been proposed as an alternative treatment strategy, as it typically involves inhibition of expression of virulence factors rather than direct bacterial killing, thereby attenuating the risk of resistance development. An intriguing target is the agr quorum-sensing system, which is a major inducer of virulence in CA-MRSA upon activation by agr-encoded staphylococcal autoinducing peptides (AIPs). In the present work a previously identified lactam hybrid analogue based on the marine depsipeptide solonamide B and the general structure of AIPs was investigated with respect to structure-function relationships. An array of 27 analogues exploring expansion of ring size, type of side chain, amino acid substitutions, and stereochemistry was designed and tested for AgrC-inhibitory activity. Interestingly, it was found that an analogue derived from the mirror image of the original hit proved to be the hitherto most efficient AgrC inhibitor resembling solonamide B in amino acid sequence. This and closely related compounds were 20- to 40-fold more potent in AgrC inhibition than the starting hit compound.

Combining Elements from Two Antagonists of Formyl Peptide Receptor 2 Generates More Potent Peptidomimetic Antagonists.

Structural optimization of a peptidomimetic antagonist of formyl peptide receptor 2 (FPR2) was explored by an approach involving combination of elements from the two most potent FPR2 antagonists described: a Rhodamine B-conjugated 10-residue gelsonin-derived peptide (i.e., PBP10, RhB-QRLFQVKGRR-OH) and the palmitoylated α-peptide/ß-peptoid hybrid Pam-(Lys-ßNspe)6-NH2. This generated an array of hybrid compounds from which a new subclass of receptor-selective antagonists was identified. The most potent representatives displayed activity in the low nanomolar range. The resulting stable and potent FPR2-selective antagonists (i.e., RhB-(Lys-ßNphe)n-NH2; n = 4-6) are expected to become valuable tools in further elucidation of the physiological role of FPR2 in health and disease.

The Lipidated Peptidomimetic Lau-((S)-Aoc)-(Lys-ßNphe)6-NH2 Is a Novel Formyl Peptide Receptor 2 Agonist That Activates Both Human and Mouse Neutrophil NADPH Oxidase.

Neutrophils expressing formyl peptide receptor 2 (FPR2) play key roles in host defense, immune regulation, and resolution of inflammation. Consequently, the search for FPR2-specific modulators has attracted much attention due to its therapeutic potential. Earlier described agonists for this receptor display potent activity for the human receptor (FPR2) but low activity for the mouse receptor orthologue (Fpr2), rendering them inapplicable in murine models of human disease. Here we describe a novel FPR2 agonist, the proteolytically stable α-peptide/ß-peptoid hybrid Lau-((S)-Aoc)-(Lys-ßNphe)6-NH2 (F2M2), showing comparable potency in activating human and mouse neutrophils by inducing a rise in intracellular Ca(2+) concentration and assembly of the superoxide-generating NADPH oxidase. This FPR2/Fpr2 agonist contains a headgroup consisting of a 2-aminooctanoic acid (Aoc) residue acylated with lauric acid (C12 fatty acid), which is linked to a peptide/peptoid repeat ((Lys-ßNphe)6-NH2). Both the fatty acid moiety and the (S)-Aoc residue were required for FPR2/Fpr2 activation. This type of proteolytically stable FPR2-specific peptidomimetics may serve as valuable tools for future analysis of FPR2 signaling as well as for development of prophylactic immunomodulatory therapy. This novel class of cross-species FPR2/Fpr2 agonists should enable translation of results obtained with mouse neutrophils (and disease models) into enhanced understanding of human inflammatory and immune diseases.