Design and synthesis of novel antimicrobial pseudopeptides with selective membrane-perturbation activity

By incorporating carbamate bond(s) into a cytolytic peptide, novel pseudopeptides with potent antibacterial activity and low hemolytic activity were synthesized. Circular dichroism spectra suggested that the incorporation of carbamate bond(s) decrease the alpha helical conformation of the peptide in lipid membrane circumstances, which must be regarded as a major factor for the separation of antibacterial activity from cytotoxic activity for mammalian cell. Experiments in which dye was released from vesicles indicated that the potent antibacterial activity and low hemolytic activity of the pseudopeptides must be due to their great lipid membrane selectivity. The present result suggest that backbone modifications can be a great tool for developing pseudopeptides with improved biological activity and bioavailability from cytolytic peptides.     

MSP-1 malaria pseudopeptide analogs: biological and immunological significance and three-dimensional structure

Merozoite Surface Protein-1 (MSP-1) has been considered as a malaria vaccine candidate. It is processed during the Plasmodium falciparum invasion process of red blood cells (RBCs). A conserved MSP-1 C-terminal peptide was identified as a high-activity erythrocyte-binding peptide (HAEBP) termed 1585. Since conserved HAEBPs are neither antigenic nor immunogenic we decided to assess the significance of a single peptide bond replacement in 1585. Thus, two pseudopeptides were obtained by introducing a Y[CH2-NH] reduced amide isoster into the 1585 critical binding motif. The pseudopeptides bound to different HLA-DR alleles, suggesting that backbone modifications affect MHC-II binding patterns. Pseudopeptide-antibodies inhibit in vitro parasite RBC invasion by recognizing MSP-1. Each pseudopeptide-induced antibody shows distinct recognition patterns. 1H-NMR studies demonstrated that isoster bonds modulate the pseudopeptides' structure and thus their immunological properties, therefore representing a possible subunit malaria vaccine component.     

Determination of dissociation constant of phosphinate group in phosphinic pseudopeptides by capillary zone electrophoresis

Capillary zone electrophoresis (CZE) was used for determination of dissociation constant of phosphinate group in phosphinic pseudopeptides, i.e. peptides where one peptide bond is substituted by phosphinic acid moiety -PO2--CH2-. The dissociation constants were determined for a set of newly synthesized pseudopeptides derived from a structure N-Ac-Val-Ala(psi)(PO2--CH2)Leu-His-NH2 by nonlinear regression of experimentally measured pH dependence of their effective electrophoretic mobilities. CZE experiments were carried out in Tris-phosphate background electrolytes in the pH range 1.4-3.2. The pseudopeptides were synthesized as a mixture of four diastereomers, the separation of which was achieved in most cases. Moreover, differences of the effective mobilities of the pseudopeptide diastereomers enabled simultaneous determination of the dissociation constant of their phosphinate group without necessity of previous isolation of individual isomers.     

Synthesis of antibacterial pseudopeptides with less hemolytic activity from a cytotoxic peptide and their pH-dependent activity

We synthesized antibacterial pseudopeptides with less hemolytic activity by incorporation of reduced amide bond ψ[CH₂NH] into α helical antibacterial peptide with hemolytic activity. As the pK_a value of reduced amide bond is 7–8, it is protonated depending on the pH. We investigated the secondary structure, the binding affinity and the leakage activity for the vesicles, and the antibacterial activity of the peptide and its pseudopeptides at neutral and basic pH. Unlike the peptide, the pseudopeptides showed a more potent leakage activity when pH increased. The peptide exhibited a lower antibacterial activity at basic pH than at neutral pH, whereas the pseudopeptide showed the same antibacterial activity at basic and neutral pH. Overall results indicated that hydrophobicity of backbone of the pseudopeptide plays an important role in the increase of leakage activity and retention of antibacterial activity at basic pH.     

Protection against lymphocytic choriomeningitis virus infection induced by a reduced peptide bond analogue of the H-2Db-restricted CD8(+) T cell epitope GP33

Recent investigations have suggested that pseudopeptides containing modified peptide bonds might advantageously replace natural peptides in therapeutic strategies. We have generated eight reduced peptide bond Psi(CH2-NH) analogues corresponding to the H-2Db-restricted CD8(+) T cell epitope (called GP33) of the glycoprotein of the lymphocytic choriomeningitis virus. One of these pseudopeptides, containing a reduced peptide bond between residues 6 and 7 (Psi(6-7)), displayed very similar properties of binding to major histocompatibility complex (MHC) and recognition by T cell receptor transgenic T cells specific for GP33 when compared with the parent peptide. We assessed in vitro and in vivo the proteolytic resistance of GP33 and Psi(6-7) and analyzed its contribution to the priming properties of these peptides. The Psi(6-7) analogue exhibited a dramatically increased proteolytic resistance when compared with GP33, and we show for the first time that MHC-peptide complexes formed in vivo with a pseudopeptide display a sustained half-life compared with the complexes formed with the natural peptide. Furthermore, in contrast to immunizations with GP33, three injections of Psi(6-7) in saline induced significant antiviral protection in mice. The enhanced ability of Psi(6-7) to induce antiviral protection may result from the higher stability of the analogue and/or of the MHC-analogue complexes.     

Formation of gels in the presence of metal ions

A small library of stereoisomeric pseudopeptides able to make gels in different solvents has been prepared and their attitude to make gels in the presence of several metal ions was evaluated. Four benzyl esters and four carboxylic acids, all containing a moiety of azelaic acid (a long chain dicarboxylic acid) coupled with four different pseudopeptide moieties sharing the same skeleton (a phenyl group one atom apart from the oxazolidin-2-one carboxylic group), were synthesized in solution, by standard coupling reaction. The tendency of these pseudopeptides to form gels was evaluated using the inversion test of 10 mM solutions of pure compounds and of stoichiometric mixtures of pseudopeptides and metal ions. To obtain additional information on the molecular association, the gel samples were left dry in the air to form xerogels that were further analyzed using SEM and XRD. The formation of gel containing Zn(II) or Cu(II) ions gave good results in term of incorporation of the metal ions, while the presence of Cu(I), Al(III) and Mg(II) gave less satisfactory results. This outcome is a first insight in the formation of stable LMWGs formed by stoichiometric mixtures of pseudopeptides and metal ions. Further studies will be carried out to develop similar compounds of pharmacological interest.     

Antibodies induced by Plasmodium falciparum merozoite surface antigen-2-designed pseudopeptides possess neutralizing properties of the in vitro malarial infection

Pseudopeptide chemistry is gaining ground in the field of synthetic vaccine development. We have previously demonstrated the potential scope of introducing reduced amide peptide bond isosters in a site-directed design for obtaining structurally modified probes able to induce malaria infection-neutralizing antibodies derived from the MSP-1 antigen. This work reports the functional properties of polyclonal and monoclonal antibodies induced by site-directed designed MSP-2 N-terminus pseudopeptides and their capacity for antibody isotype switching in in vitro immunization. Structural properties of the native peptide and its pseudopeptide analogs are discussed within the context of these novel pseudopeptides' induced monoclonal antibody functional and physical-chemical properties.     

In vitro activity profiles of cyclic and linear enkephalin pseudopeptide analogs

The peptide bond in the 4-5 position of the cyclic and linear enkephalin analogs H-Tyr-cyclo[-D-Lys-Gly-Phe-L(or D)-Leu-] and H-Tyr-D-Ala-Gly-Phe-L(or D)-Leu-OH was replaced by a thiomethylene ether linkage. Each of the configurational isomers of the cyclic pseudopeptide H-Tyr-cyclo[-D-Lys-Gly-Phe psi [CH2S]L(or D)-Leu-] showed high potency in both the guinea pig ileum and the mouse vas deferens assay and, therefore, had no preference for either mu- or delta-opioid receptors, in contrast to the cyclic parent peptides H-Tyr-cyclo[-D-Lys-Gly-Phe-L(or D)-Leu-] which are mu-receptor selective. The loss of selectivity observed with the cyclic pseudopeptides may be due to the greater flexibility of their 18-membered ring structures as a consequence of the peptide bond substitution. The linear pseudopeptide analogs were both less potent and less delta-receptor selective than their parent compounds. These results indicate that thiomethylene ether peptide bond replacements can have a pronounced effect on the activity profile of peptide hormones and neurotransmitters.     

A rational approach to the synthesis of phosphonamidate peptides

Summary A rational approach to the synthesis of phosphonamidate pseudopeptides is described. This strategy can be easily applied to the preparation of peptides containing phosphonic acid residues at various positions, as well as sidechain-functionalized amino acid residues. The reaction conditions are compatible with the severe lability of the P-N bond, and the absence of racemization is demonstrated by³¹P NMR analysis. This approach is suitable for application in solid-phase synthesis of biologically active phosphonopeptides.     

Mechanism of photoacid generation for an arylcycloalkylsulfonium salt by ring opening and aryl cleavage.

The photochemistry of 1-(4-tert-butylphenyl)-tetrahydro-thiopyranium triflate (1), an arylcycloalkylsulfonium salt, was investigated in acetonitrile and methanol at low conversion in order to understand the reaction mechanism and its efficiency as photoacid generator. Both types of C-S bond in 1 are cleaved from the excited state. The heterolytic cleavage of the methylene C-S bond produces 4-t-BuC(6)H(4)S(CH(2))(4)CH(2)(+) by ring opening. The carbocation generates acid and arylalkenylsufides by elimination or 1,2 hydride shift and elimination. The predominantly homolytic cleavage of the aryl C-S bond yields 4-t-BuC(6)H(4)* and c-C(5)H(10)S(+)* as the fragmentation products. The radicals react with the solvent forming acid, pentamethylene sulfide and tert-butylbenzene. In methanol, the formation of 4-tert-butylanisole indicates a contribution of solvolysis in the excited state of 1 or a competing formation of free aryl cation by heterolytic fragmentation. The acid generation efficiency of 1 in solution (acetonitrile or methanol) is lower than that corresponding to triphenylsulfonium triflate (TPS OTf) under the same conditions. This suggests a pathway for the regeneration of 1 after photocleavage. The photochemistry of 1 is discussed in terms of the contribution of fragmentation and ring opening reaction paths to its overall acid generation efficiency, a key property in terms of its applications in resist formulations.     

A mixed NCP pincer palladacycle as catalyst precursor for the coupling of aryl halides with aryl boronic acids

The reaction of phosphinite Me₂NCH₂CC(CH₂)₂OP(i-Pr)₂ (2) with Li₂PdCl₄ in methanol at room temperature affords the air and water stable mixed pincer palladacycle (Me₂NCH₂(Cl)CC(CH₂)₂OP(i-Pr)₂-κNκCκP)PdCl (3) whose structure has been ascertained by means of an X-ray diffraction study. This pincer palladacycle is a highly efficient catalyst precursor for the coupling of aryl boronic acids and aryl chlorides. Both electron-rich and -poor aryl chlorides are efficiently coupled in the presence of 3 to furnish the corresponding cross-coupled products in excellent yields, and a wide variety of functional groups are tolerated in both aryl chloride and aryl boronic acid. The experimental protocol has also been extended for the coupling of iodo and bromo arenes with aryl boronic acids for the generation of hindered biphenyls. The coupling process afforded very good yields of biphenyl products containing two ortho substituents. Steric hindrance is more sensitive for ortho substituents in the aryl boronic acid and is more pronounced when the coupling reaction involves three ortho substituents.     

The comparison of characteristics between membrane-active antifungal peptide and its pseudopeptides

By the introduction of various amide surrogates, novel pseudopeptides corresponding to a membrane active depsipeptide were synthesized and their native characteristics compared with that of the peptide. The pseudopeptides had more resistance to serum proteases than the peptide and similar antimicrobial activities to that of the peptide without hemolytic activity. The pseudopeptides like the peptide were active against current drug resistant fungi and pathogenic fungi isolated from patients, and also had a strong synergism with current antifungal drugs against Candida albicans. The leakage assay suggested that the pseudopeptides also acted on the lipid membrane of pathogenic cells. These results indicated that the novel pseudopeptides had advantages over the peptide as a candidate for a novel antifungal drug and backbone modifications can be a tool in the development of a novel antifungal agent from membrane-active peptides isolated from natural sources or chemically synthesized.     

New methods for solid phase peptide synthesis of transitionstate analog inhibitors of HIV-1 protease and DPP-IV

Summary A new and stereoselective method to synthesize hydroxyethylamine and hydroxymethylamide peptide bond isosteres is developed. The key step is the addition of 2-trimethylsilylthiazole to -aminoaldehydes, followed by transformation to -hydroxy--aminoaldehydes. The stereochemistry of the addition can be manipulated by the choice of the nitrogen substitution. The isosteres are easily synthesized via Solid Phase Peptide Synthesis, which rapidly gives the desired pseudopeptides.     

Synthesis of pseudopeptides containing aza-phenylalanine surrogates of the Phe-pNA motif: Influence on the binding to the human cyclophilin hCyp-18

Summary Tripeptides bearing aza-phenylalanine derivatives Aphe-X-(4-nitrophenyl), where X is CH₂, O or NH, were synthesized starting from benzylhydrazine via a 4-step strategy. The pseudopeptides were evaluated as ligands of cyclophilin hCyp-18, an important human peptidyl-prolyl isomerase (PPlase), All pseudopeptides bind to hCyp-18, although only Suc-Ala-Pro-Phe-pNA11 and Suc-Ala-Pro-Aphe-pNB (X=CH₂)4 are able to inhibit the PPIase activity, suggesting that they can bind to the S1-S1′ and S2′-S3′ subsites of hCyp-18 simultaneously. A circular dichroism study showed that only compounds4 and11 have β-turns conformations in 0.47 M LiCl/TFE (which favors acis-Ala-Pro conformation). In addition, the hydrazide (X=CH₂)4 as well as the aza-urea (X=NH)6 are resistant to both trypsin and alpha-chymotrypsin. The corresponding carbazate (X=O)10 readily reacts with alpha-chymotrypsin and is also hydrolyzed by trypsin.     

A spectroscopic and molecular modeling study on novel pseudopeptides exhibiting biological activity.

A series of pseudopeptides, containing two fluorophores, such as naphthalene (N) and indole (I), and exhibiting interesting biological activity as tachykinin receptor antagonists, were investigated by electronic absorption, CD and steady-state fluorescence experiments. In polar solvents (e.g. methanol), bioactivity is coupled with a stacked, charge-separated complex between I and N, the amount of which depends on the stereochemical features and conformational mobility of the central scaffold in the molecules examined. This agrees with the idea that dipolar charged, spatially close, aromatic moieties are important topochemical elements in the mechanism of action of these receptor antagonists. Molecular mechanics calculations allowed us to build up hypothetical, low-energy conformations of a few representative pseudopeptides, whose structural features are consistent with the experimental findings.     

Expedient synthesis of N-Z-pyroglutamyl-amino acid derivatives

N-Z-pyroglutamyl pseudopeptides 3a-c are shown to be conveniently prepared from glutamyl-bis-Bt 1a by cyclization of an N-terminal glutamic acid residue. Structures are supported by 2D NMR studies and by comparison with the same products prepared by direct coupling of the C-terminus activated N-pGlu 1b and free amino acids 2a-c.     

Barley serine proteinase inhibitor 2-derived cyclic peptides as potent and selective inhibitors of convertases PC1/3 and furin

Proprotein convertases (PCs) are serine proteases containing a subtilisin-like catalytic domain that are involved in the conversion of hormone precursors into their active form. This study aims at designing small cyclic peptides that would specifically inhibit two members of this family of enzymes, namely, the neuroendocrine PC1/3 and the ubiquitously expressed furin. We studied peptide sequences related to the 18-residue loop identified as the active site of the 83 amino acid barley serine protease inhibitor 2 (BSPI-2). Peptides incorporating mutations at various positions in the sequence were synthesized on solid phase and purified by HPLC. Cyclization was achieved by the introduction of a disulfide bridge between the two Cys residues located at both the N- and C-terminal extremities. Peptides VIIA and VIIB incorporating P4Arg, P2Lys, P1Arg, and P2'Lys were the most potent inhibitors with K(i) around 4 microM for furin and around 0.5 microM for PC1/3. Whereas peptide VIIB behaved as a competitive inhibitor of furin, peptide VIIA acted as a noncompetitive one. However, all peptides were eventually cleaved after variable incubation times by PC1/3 or furin. To avoid this problem, we incorporated at the identified cleavage site a nonscissile aminomethylene bond (psi[CH(2)-NH]). Those pseudopeptides, in particular peptide VIID, were shown not to be cleaved and to inhibit potently furin. Conversely, they were not able to inhibit PC1/3 at all. Those results show the validity of this approach in designing new effective PC inhibitors showing a certain level of discrimination between PC1/3 and furin.     

Pseudopeptides containing the 2-hydrazonoacyl fragment: analogs of the chemotactic agent HCO-Met-Leu-Phe-OMe.

In order to further examine the properties of pseudopeptides containing the 2-hydrazonoacyl fragment, two new series of analogs of the prototypical chemotactic N-formyl-tripeptide HCO-Met-Leu-Phe-OMe were designed and synthesized. The first group contains the new fragment as the N-terminal residue and is represented by the N-aryl derivatives p-Cl-C6H4-NH-N=C(R)-CO-Leu-Phe-OMe (2 and 3) and by the corresponding N-aroyl analogs p-CH3-C6H4-CO-NH-N=C(R)-CO-Leu-Phe-OMe (4). The second group contains the new fragment in place of the central Leu residue and is represented by compounds HCO-Xaa-NH-N=C(R)-CO-Phe-OMe (7a and 7b) where Xaa is Nle and Met, respectively. The conformational and biochemical properties of the new products were examined.     

Crystal structure and nmr conformation of a cyclic pseudotetrapeptide containing urethane backbone linkages

Urethane bonds, derived from the hydroxyl group of the tyrosine side chain, have been investigated as a new type of amide bond mimetic in the design of pseudopeptides. The structure of a representative cyclic pseudotetrapeptide that consists of an — Ala — Tyr(urethane) Ala — Tyr (urethane) sequence fused into a rigid ring has been studied in the solid state by x-ray crystallography and in solution by two-dimensional nmr techniques. The cyclic pseudotetrapeptide has an oblong shape. The backbone urethane bonds assume a trans–trans conformation. The carbonyl groups in the ring have an alternating pattern of down, up, down, up with respect to the average ring plane. Solution nmr studies give observed nuclear Overhauser effects and coupling constants largely in agreement with the crystal structure. However, in solution the observed structure is likely to be conformationally averaged, and in the averaged structure, the urethane bond is perpendicular to the plane of the aromatic ring of the tyrosine, while in the crystal it is close to this plane. These differences may be explained by intermolecular hydrogen-bonding interactions. Four aspects of the conformation of the cyclic pseudotetrapeptide were investigated in detail: the tyrosine residue with the attached side-chain urethane bond (the tyrosine-urethane unit), the conformation of the two urethane backbone linkages, the conformation of the two conventional peptide bonds within this unusual ring structure, and the tight turns within the cyclic pseudotetrapeptide. The conformation of the tight turns present in the cyclic pseudotetrapeptide is very similar to that of a β-bend of type II. Intermolecular hydrogen bonding, joining adjacent layers of the cyclic pseudotetrapeptide in the solid state, resemble a parallel β-pleated sheet. The presence of these structural motifs in the cyclic pseudotetrapeptide indicates that the tyrosine urethane unit may find applications in peptide and protein engineering. © 1994 John Wiley & Sons, Inc.     

Enzymatic hydrolysis of p-nitroacetanilide: mechanistic studies of the aryl acylamidase from Pseudomonas fluorescens.

Aryl acylamidase (EC 3.1.5.13; AAA) catalyzes the hydrolysis of p-nitroacetanilide (PNAA) via the standard three-step mechanism of serine hydrolases: binding of substrate (K(s)), acylation of active-site serine (k(acyl)), and hydrolytic deacylation (k(deacyl)). Key mechanistic findings that emerged from this study include that (1) AAA requires a deprotonated base with a pK(a) of 8.3 for expression of full activity toward PNAA. Limiting values of kinetic parameters at high pH are k(c) = 7 s(-1), K(m) = 20 microM, and k(c)/K(m) = 340 000 M(-1) s(-1). (2) At pH 10, where all the isotope effects were conducted, k(c) is equally rate-limited by k(acyl) and k(deacyl). (3) The following isotope effects were determined: (D)()2(O)(k(c)/K(m)) = 1.7 +/- 0.2, (D)()2(O)k(c) = 3.5 +/- 0.3, and (beta)(D)(k(c)/K(m)) = 0.83 +/- 0.04, (beta)(D)k(c) = 0.96 +/- 0.01. These values, together with proton inventories for k(c)/K(m) and k(c), suggest the following mechanism: (i) The initial binding of substrate to enzyme to form the Michaelis complex is accompanied by solvation changes that generate solvent deuterium isotope effects originating from hydrogen ion fractionation at multiple sites on the enzyme surface. (ii) From within the Michaelis complex, the active site serine attacks the carbonyl carbon of PNAA with general-base catalysis to form a substantially tetrahedral transition state enroute to the acyl-enzyme. (iii) Finally, deacylation occurs through a process involving a rate-limiting solvent isotope effect, generating conformational change of the acyl-enzyme that positions the carbonyl bond in a polarizing environment that is optimal for attack by water.