Examination of the Antimicrobial Peptide Myticalin A6 Active Site.

In 2017, Leoni et al. reported myticalins as novel cationic linear antimicrobial peptides obtained from marine mussels. The authors focused on myticalin A6 (29 amino acids), which has a relatively short chain length among myticalins and contains a repeating X-proline(Pro)-arginine (Arg) sequence in its structure. We investigated the antimicrobial activity of myticalin A6 against Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus (S. aureus). Fragment derivatives of myticalin A6 were synthesized, and the site required for expression of antimicrobial activity was examined. To investigate the structure-antimicrobial activity relationship of myticalin A6, short-chain derivatives and partially substituted derivatives were synthesized, and the antimicrobial activity was measured. Furthermore, some cyclized derivatives were synthesized and examined for antimicrobial activity. Circular dichroism (CD) spectroscopy of myticalin A6 and its derivatives was carried out to evaluate the secondary structure. Myticalin A6 exhibited an antimicrobial activity of 1.9 µM against S. aureus. Myticalin A6 (3-23)-OH (21 amino acids) exhibited an antimicrobial activity of 2.4 µM against S. aureus, suggesting that the X-Pro-Arg repeat sequence is important for antimicrobial activity. Derivatives with different CD measurement results from myticalin A6 (3-23)-OH exhibited decreased activity. The myticalin A6 (3-23)-OH derivative in which all Arg residues were replaced with lysine (Lys) residues exhibited reduced antimicrobial activity against S. aureus. We succeeded in synthesizing cyclic derivatives using 9-fluorenylmethoxycarbonyl (Fmoc)-aspartic acid (Asp)(Wang resin)-[2-phenylisopropyl ester (OPis)], but the yield of derivatives with 21 amino acids was decreased. The myticalin derivatives synthesized in this study did not exhibit any enhancement in antimicrobial activity due to cyclization.

Development of des-fatty acyl-polymyxin B decapeptide analogs with Pseudomonas aeruginosa-specific antimicrobial activity.

Twelve N-terminal analogs of des-fatty acyl-polymyxin B (Des-FA-[X(1)]-PMB, X=various amino acids or peptides) were synthesized and examined for their antimicrobial activity against Escherichia coli (E. coli), Salmonella Typhimurium (S. Typhimurium) and Pseudomonas aeruginosa (P. aeruginosa). It was found that Des-FA-[Dap(1)]-, Des-FA-[Ser(1)]-, Des-FA-[Dab-Dab-Dab(1)]- and Des-FA-[Arg-Arg-Arg(1)]-PMB had potent activity only against P. aeruginosa, with MIC values of 0.5-1 nmol/ml. Analogs in which X was Lys, Arg, Leu or Ala did not have increased antimicrobial activity against the three bacterial species tested compared with the lead compounds Des-FA-[Dab(1)]-PMB and polymyxin B (PMB). Des-FA-[Trp(1)]-PMB and Des-FA-[Phe(1)]-PMB had reduced activity against P. aeruginosa. The results indicate that compact hydrophilic amino acids (C3) or basic tripeptides at the N-terminal provide specificity for bactericidal activity towards P. aeruginosa. For LPS-binding activity, Des-FA-[Dab-Dab-Dab(1)]-PMB and Des-FA-[Arg-Arg-Arg(1)]-PMB showed activity comparable to PMB, while Des-FA-[Ala-Ala-Ala(1)]-PMB showed very low activity. Reduced acute toxicity of Des-FA-[Dap(1)]-PMB and Des-FA-[Trp(1)]-PMB was demonstrated by a mouse tail intravenous administration test, with LD(50) values of 23.5 and 19.0 micromol/kg, respectively, in contrast to PMB (LD(50), 4.8 micromol/kg).

Contribution of each amino acid residue in polymyxin B(3) to antimicrobial and lipopolysaccharide binding activity.

This study on the structure-activity relationship of polymyxin B, a cyclic peptide antibiotic, used sixteen synthetic polymyxin B(3) analogs including alanine scanning analogs to elucidate the contribution of the side chains to antimicrobial activity and lipopolysaccharide (LPS) binding. Of these analogs, [Ala(5)]-polymyxin B(3) showed greatly reduced antimicrobial activity against Escherichia coli (E. coli), Salmonella Typhimurium (S. Typhimurium) and Pseudomonas aeruginosa (P. aeruginosa) with MIC values of 4-16 nmol/ml, suggesting that the Dab (alpha,gamma-diaminobutyric acid) residue at position 5 is the most important residue contributing to bactericidal activity. The antibacterial contribution of Dab when located within the lactam ring (positions 5, 8 and 9) was greater than when located outside the ring (positions 1 and 3). [D-Ala(6)]-, [L-Phe(6)]-, [Ala(7)]-, and [Gly(7)]-polymyxin B(3) analogs retained potent antimicrobial activity, indicating that neither the reduction of hydrophobic character of the D-Phe(6)-Leu(7) region nor the D-configuration at position 6 is indispensable for antimicrobial activity. LPS binding studies showed that decreased hydrophobicity of the lactam ring had little effect, but the N(gamma)-amino function of the Dab residues at position 1, 3, 5, 8 and 9 greatly affected LPS binding, with the contribution of Dab(5) being the most significant.

Semi-synthesis of polymyxin B (2-10) and colistin (2-10) analogs employing the Trichloroethoxycarbonyl (Troc) group for side chain protection of alpha,gamma-diaminobutyric acid residues.

Improved strategies for the chemical conversion of natural polymyxin B and colistin to their N-terminal analogs are reported. First, the protection of the side chains of five L-alpha,gamma-diaminobutyric acid (Dab) residues in natural polymyxin B and colistin was achieved with trichloroethoxycarbonyl (Troc), then the resulting pentakis(N gamma-Troc)-polymyxin B and pentakis(N gamma)Troc)-colistin were treated with trifluoroacetic acid (TFA) : methanesulfonic acid (MSA) : dimethylformamide (DMF) : H2O (10 : 30 : 55 : 5) at 40 degrees C in order to remove N alpha-alkanoyl-Dab(Troc)-OH selectively. The new key compounds, tetrakis(N gamma-Troc)-polymyxin B (2-10) and tetrakis(N gamma-Troc)-colistin (2-10), were obtained in 19% and 15% yields, respectively, which is higher than previous reports using trifluoroacetyl (Tfa) for tetrakis(N gamma-Tfa)-polymyxin B (2-10) and tetrakis(N gamma-Tfa)-colistin (2-10), respectively. Acylation of tetrakis(N gamma-Troc)-polymyxin B (2-10) and tetrakis(N gamma-Troc)-colistin (2-10) with various hydrophobic acids bearing aliphatic or aromatic ring structures, followed by the deprotection of Troc by Zn in AcOH, produced polymyxin B (2-10) and colistin (2-10) analogs which were used for structure-activity relationship studies. It was found that cyclohexylbutanoyl-, 4-biphenylacetyl-, and 1-adamantaneacetyl-polymyxin B (2-10) showed potent antimicrobial activity equal to that of polymyxin B against three Gram-negative bacterial strains. The lipopolysacharide (LPS) binding activity of cyclohexylbutanoyl-, 4-biphenylacetyl-, and cyclododecanecarbonyl-polymyxin B (2-10) increased greatly in comparison with that of polymyxin B (2-10). The various N alpha-acylated polymyxin B (2-10) analogs showed slightly higher antimicrobial and LPS binding activities than the corresponding N alpha-acylated colistin (2-10) analogs.

Hydrolytic cleavage of pyroglutamyl-peptide bond. V. selective removal of pyroglutamic acid from biologically active pyroglutamylpeptides in high concentrations of aqueous methanesulfonic acid.

Application of aqueous methanesulfonic acid (MSA) for selective chemical removal of pyroglutamic acid (pGlu) residue from five biologically active pyroglutamyl-peptides (pGlu-X-peptides, X=amino acid residue at position 2) was examined. Gonadotropin releasing hormone (Gn-RH), dog neuromedin U-8 (d-NMU-8), physalaemin (PH), a bradykinin potentiating peptide (BPP-5a) and neurotensin (NT) as pGlu-X-peptides were incubated in either 70% or 90% aqueous MSA at 25 degrees C. HPLC analysis of the incubation solutions showed that the main decomposition product was H-X-peptide derived from each pGlu-X-peptide by the removal of pGlu. The results revealed that the pGlu-X peptide bond had higher susceptibility than various internal amide bonds in the five peptides examined, including the Trp-Ser bond in Gn-RH, the C-terminal Asn-NH(2) in d-NMU-8, and the Asp-Pro bond in PH, whose acid susceptibility is well known. Thus, mild hydrolysis with high concentrations of aqueous MSA may be applicable to chemically selective removal of pGlu from pGlu-X-peptides for structural examinations.

HPLC analysis of fatty acyl-glycine in the aqueous methanesulfonic acid hydrolysates of N-terminally fatty acylated peptides.

Acylation with long-chain fatty acids is a common modification at the N-terminal glycine residues of natural proteins. In this work, we performed HPLC analysis of myristoylglycine (Myr-Gly-OH), palmitoylglycine (Pal-Gly-OH) or lauroylglycine (Lau-Gly-OH), which were produced in the hydrolysates of synthetic Myr-Gly-, Pal-Gly-, or Lau-Gly-peptides, respectively, by means of a mild acid hydrolysis in methanesulfonic acid : dioxane : water (2 : 1 : 1) at 60 degrees C for 12 h. Myr-Gly-OH, Pal-Gly-OH and Lau-Gly-OH were quite stable under hydrolysis conditions. These fatty acyl-Gly-OH were conveniently detectable at a 20 nmol level by direct reversed-phase HPLC. Thus, mild acid hydrolysis, followed by HPLC analysis of the hydrolysate, provides a simple method of identification of the N-terminal structure of fatty acyl-Gly-peptides.