Wan Long Zhu

Effects of dimerization of the cell-penetrating peptide Tat analog on antimicrobial activity and mechanism of bactericidal action

The cell‐penetrating peptide Tat (48–60) (GRKKRRQRRRPPQ) derived from HIV‐1 Tat protein showed potent antibacterial activity (MIC: 2–8 µM). To investigate the effect of dimerization of Tat (48–60) analog, [Tat(W): GRKKRRQRRRPWQ‐NH2], on antimicrobial activity and mechanism of bactericidal action, its dimeric peptides, di‐Tat(W)‐C and di‐Tat(W)‐K, were synthesized by a disulfide bond linkage and lysine linkage of monomeric Tat(W), respectively. From the viewpoint of a weight basis and the monomer concentration, these dimeric peptides displayed almost similar antimicrobial activity against six bacterial strains tested but acted more rapidly against Staphylococcus aureus on kinetics of bactericidal activity, compared with monomeric Tat(W). Unlike monomeric Tat(W), these dimeric peptides significantly depolarized the cytoplasmic membrane of intact S. aureus cells at MIC and induced dye leakage from bacterial‐membrane‐mimicking egg yolk L‐α‐phosphatidylethanolamine/egg yolk L‐α‐phosphatidyl‐DL‐glycerol (7:3, w/w) vesicles. Furthermore, these dimeric peptides were less effective to translocate across lipid bilayers than monomeric Tat(W). These results indicated that the dimerization of Tat analog induces a partial change in the mode of its bactericidal action from intracellular target mechanism to membrane‐targeting mechanism. Collectively, our designed dimeric Tat peptides with high antimicrobial activity and rapid bactericidal activity appear to be excellent candidates for future development as novel antimicrobial agents. Copyright

Effects of Pro → Peptoid Residue Substitution on Cell Selectivity and Mechanism of Antibacterial Action of Tritrpticin-Amide Antimicrobial Peptide†

To investigate the effect of Pro --> peptoid residue substitution on cell selectivity and the mechanism of antibacterial action of Pro-containing beta-turn antimicrobial peptides, we synthesized tritrpticin-amide (TP, VRRFPWWWPFLRR-NH(2)) and its peptoid residue-substituted peptides in which two Pro residues at positions 5 and 9 are replaced with Nleu (Leu peptoid residue), Nphe (Phe peptoid residue), or Nlys (Lys peptoid residue). Peptides with Pro --> Nphe (TPf) or Pro --> Nleu substitution (TPl) retained antibacterial activity but had significantly higher toxicity to mammalian cells. In contrast, Pro --> Nlys substitution (TPk) increased the antibacterial activity but decreased the toxicity to mammalian cells. Tryptophan fluorescence studies indicated that the bacterial cell selectivity of TPk is closely correlated with a preferential interaction with negatively charged phospholipids. Interestingly, TPk was much less effective at depolarizing of the membrane potential of Staphylococus aureus and Escherichia coli spheroplasts and causing the leakage of a fluorescent dye entrapped within negatively charged vesicles. Furthermore, confocal laser-scanning microscopy showed that TPk effectively penetrated the membrane of both E. coli and S. aureus and accumulated in the cytoplasm, whereas TP and TPf did not penetrate the cell membrane but remained outside or on the cell membrane. These results suggest that the bactericidal action of TPk is due to inhibition of the intracellular components after penetration of the bacterial cell membrane. In addition, TPK with Lys substitution effectively depolarized the membrane potential of S. aureus and E. coli spheroplasts. TPK induced rapid and effective dye leakage from bacterial membrane-mimicking liposomes and did not penetrate the bacterial cell membranes. These results suggested that the ability of TPk to penetrate the bacterial cell membranes appears to involve the dual effects that are related to the increase in the positive charge and the peptides backbone change by peptoid residue substitution. Collectively, our results showed that Pro --> Nlys substitution in Pro-containing beta-turn antimicrobial peptides is a promising strategy for the design of new short bacterial cell-selective antimicrobial peptides with intracellular mechanisms of action.

Cell selectivity and mechanism of action of short antimicrobial peptides designed from the cell-penetrating peptide Pep-1.

Pep‐1‐K (PK) is a good cell‐selective antimicrobial peptide designed from cell‐penetrating peptide Pep‐1. To develop novel short antimicrobial peptides with higher cell selectivity and shorter length compared with PK, several PK analogs were designed by the deletion, addition and/or substitution of amino acids. Among these analogs, PK‐12‐KKP (KKPWWKPWWPKWKK) showing the sequence and structure homology with a Trp/Pro‐rich natural antimicrobial peptide, indolicidin (IN), displayed a 20‐fold higher cell selectivity as compared to IN. Circular dichroism analysis revealed that PK‐12‐KKP adopts a folded structure combined with some portions of unordered structure. PK‐12‐KKP selectively binds to negatively charged bacterial membrane–mimetic vesicles, and its high phospholipid selectivity corresponds well with its high cell selectivity. Moreover, it showed very weak potential in depolarization of the cytoplasmic membrane of Staphylococcus aureus at 8 µM (4× minimal inhibitory concentration) and dye leakage from negatively charged liposomes. These results suggest that the ultimate target of our designed PK‐12‐KKP maybe the intracellular components (e.g. protein, DNA or RNA) rather than the cytoplasmic membranes. Collectively, our designed short Trp/Pro‐rich peptide, PK‐12‐KKP, appears to be an excellent candidate for future development as a novel antimicrobial agent. Copyright

Improvement of Bacterial Cell Selectivity of Melittin by a Single Trp Mutation with a Peptoid Residue

To design melittin (ME) analogues that are not cytotoxic against mammalian cells but which possessing potent antimicrobial activity, we synthesized a ME analogue (ME-w) in which the Trp-19 residue of ME was replaced by a Trp-peptoid residue (Nhtrp). ME-w exhibited similar antimicrobial activity compared to ME against the tested six bacteria and C. albicans. However, it was much less cytotoxic against the hRBCs and HeLa and NIH-3T3 cells than ME. Tryptophan fluorescence and CD spectra revealed that the Trp-19 --> Nhtrp substitution in ME contributed to a much lower helical assembly in an aqueous environment and structural flexibility and exterior localization to zwitterionic membrane which modulates its selectivity toward bacterial cells.

Mechanism of antibacterial action of a synthetic peptide with an Ala-peptoid residue based on the scorpion-derived antimicrobial peptide IsCT

A novel bacterial cell-selective antimicrobial peptide, IsCT-P (ILKKIWKPIKKLF-NH2), was designed based on the scorpion-derived α-helical antimicrobial peptide, IsCT. Here, we investigated the effect of substituting Pro8 of IsCT-P with the Ala-peptoid residue (N-methylglycine) on the peptide’s structure and mechanism of action. Circular dichroism analysis revealed that the modified peptide, IsCT-a, has a much lower α-helicity than IsCT-P in membrane mimicking conditions, suggesting the peptoid residue provides much more structural flexibility than the proline residue. IsCT-a was also much less effective than IsCT-P at causing leakage of fluorescent dye entrapped within negatively charged vesicles and at dissipating the membrane potential of Staphylococcus aureus. Collectively, our results suggest that the antibacterial action of IsCT-a is due to the inhibition of intracellular targets rather than the disruption and depolarization of bacterial cell membranes.