An Effective Strategy to Develop Potent and Selective Antifungal Agents from Cell Penetrating Peptides in Tackling Drug-Resistant Invasive Fungal Infections.

The high mortality rate of invasive fungal infections and quick emergence of drug-resistant fungal pathogens urgently call for potent antifungal agents. Inspired by the cell penetrating peptide (CPP) octaarginine (R8), we elongated to 28 residues poly(d,l-homoarginine) to obtain potent toxicity against both fungi and mammalian cells. Further incorporation of glutamic acid residues shields positive charge density and introduces partial zwitterions in the obtained optimal peptide polymer that displays potent antifungal activity against drug-resistant fungi superior to antifungal drugs, excellent stability upon heating and UV exposure, negligible in vitro and in vivo toxicity, and strong therapeutic effects in treating invasive fungal infections. Moreover, the peptide polymer is insusceptible to antifungal resistance owing to the unique CPP-related antifungal mechanism of fungal membrane penetration followed by disruption of organelles within fungal cells. All these merits imply the effectiveness of our strategy to develop promising antifungal agents.

Microbial Metabolite Inspired ß-Peptide Polymers Displaying Potent and Selective Antifungal Activity.

Potent and selective antifungal agents are urgently needed due to the quick increase of serious invasive fungal infections and the limited antifungal drugs available. Microbial metabolites have been a rich source of antimicrobial agents and have inspired the authors to design and obtain potent and selective antifungal agents, poly(DL-diaminopropionic acid) (PDAP) from the ring-opening polymerization of ß-amino acid N-thiocarboxyanhydrides, by mimicking ε-poly-lysine. PDAP kills fungal cells by penetrating the fungal cytoplasm, generating reactive oxygen, and inducing fungal apoptosis. The optimal PDAP displays potent antifungal activity with minimum inhibitory concentration as low as 0.4 µg mL-1 against Candida albicans, negligible hemolysis and cytotoxicity, and no susceptibility to antifungal resistance. In addition, PDAP effectively inhibits the formation of fungal biofilms and eradicates the mature biofilms. In vivo studies show that PDAP is safe and effective in treating fungal keratitis, which suggests PDAPs as promising new antifungal agents.

Peptide polymer displaying potent activity against clinically isolated multidrug resistant Pseudomonas aeruginosa in vitro and in vivo.

Multidrug resistant (MDR) Pseudomonas aeruginosa has caused serious nosocomial infections owing to its high intrinsic resistance and ease of acquiring resistance to common antibiotics. There is an urgent need to develop antimicrobial agents against MDR Pseudomonas aeruginosa. Here we report a 27-mer peptide polymer 90 : 10 DLL : BLG, as a synthetic mimic of a host defense peptide, that displayed potent in vitro and in vivo activities against multiple strains of clinically isolated MDR Pseudomonas aeruginosa, performing even better than antibiotics within our study. This peptide polymer also showed negligible hemolysis and low cytotoxicity, as well as quick bacterial killing efficacy. The structural diversity of peptide polymers, their easy synthesis from lithium hexamethyldisilazide-initiated fast N-carboxyanhydride polymerization, and the excellent reproducibility of their chemical structure and biological profiles altogether suggested great potential for antimicrobial applications of peptide polymers as synthetic mimics of host defense peptides.

Host Defense Peptide Mimicking Peptide Polymer Exerting Fast, Broad Spectrum, and Potent Activities toward Clinically Isolated Multidrug-Resistant Bacteria.

Multidrug-resistant (MDR) bacteria have emerged quickly and have caused serious nosocomial infections. It is urgent to develop novel antimicrobial agents for treating MDR bacterial infections. In this study, we isolated 45 strains of bacteria from hospital patients and found shockingly that most of these strains were MDR to antimicrobial drugs. This inspired us to explore antimicrobial peptide polymers as synthetic mimics of host defense peptides in combating drug-resistant bacteria and the formidable antimicrobial challenge. We found that peptide polymer 80:20 DM:Bu (where DM is a hydrophilic/cationic subunit and Bu is a hydrophobic subunit) displayed fast bacterial killing, broad spectrum, and potent activity against clinically isolated strains of MDR bacteria. Moreover, peptide polymer 80:20 DM:Bu displayed potent in vivo antibacterial efficacy, comparable to the performance of polymyxin B, in a Pseudomonas aeruginosa (P. aeruginosa) infected rat full-thickness wound model. The peptide polymer can be easily synthesized from ring-opening polymerization with remarkable reproducibility in structural properties and biological activities. The peptide polymer's potent and broad spectrum antimicrobial activities against MDR bacteria in vitro and in vivo, resistance to proteolysis, and high structural diversity altogether imply a great potential of peptide polymer 80:20 DM:Bu in antimicrobial applications as synthetic mimics of host defense peptides.

Efficient synthesis of amino acid polymers for protein stabilization.

Proteins are fragile such that even freezing, drying and dehydration may induce their denaturation, aggregation, and activity loss. To protect proteins from these kinds of damage, we prepared two types of amino acid polymers, poly-(l-glutamate)-r-poly-(l-lysine) (PLG-r-PLL) and poly-l-glutamate (PLG), from the efficient ring-opening polymerization of α-amino acid N-carboxyanhydride (NCA) using lithium hexamethyldisilazide (LiHMDS) as the initiator. ß-galactosidase (ß-Gal) was used in this study to examine the protein protecting effect of the synthesized amino acid polymers during lyophilization. The results indicate that both PLG-r-PLL and PLG exert significant protection on ß-Gal during lyophilization and improve the activity of the resulting protein from 40%, without using a protecting agent during lyophilization, to 80% of the original protein activity. Nevertheless, PLG generally performs better than PLG-r-PLL independent of the chain length. Our studies also show that PLG and PLG-r-PLL with a high content of PLG subunits display no observable cytotoxicity and hemolytic effect. Furthermore, dynamic light scattering (DLS) and transmission electron microscopy (TEM) characterization indicate that PLG protects ß-Gal upon lyophilization by preventing the aggregation of ß-Gal. Our studies demonstrate that amino acid polymers, such as PLG, can exert potent activity for protein stabilization. The easy operation of LiHMDS-initiated and efficient NCA polymerization implies the great potential of this strategy to prepare amino acid polymers quickly for the screening of protein stabilization and mechanism study.