Potent antibacterial activity of MSI-1 derived from the magainin 2 peptide against drug-resistant bacteria.

The structural modification of existing AMPs is an effective strategy to develop antimicrobial agents with high-efficiency, low-cost and low-toxicity antimicrobial agents. Methods: Here, we truncated 14-amino-acids at the N-terminus of MSI-78 to obtain MSI and further modified MSI to obtain four peptide analogs: MSI-1, MSI-2, MSI-3 and MSI-4. These peptide mutants were evaluated regarding their antibacterial activity against various sensitive or resistant bacteria; toxicity against mammalian cells or mice; and stability against violent pH, temperature variations and high NaCl concentrations. Finally, we also elucidated the possible mechanisms underlying its mode of action. Results: The results showed that MSI-1 and MSI-3 displayed activity that was superior to that of MSI-78 with MICs of 4-16 µg/ml and MBCs of 8-64 µg/ml, respectively, especially against drug-resistant bacteria, due to the increase in percent helicity and amphiphilicity. However, MSI-3, with higher hydrophobicity and antibacterial activity, had a relatively higher hemolysis rate and toxicity than MSI-1. MSI-1 exerted rapid bactericidal activity and effectively improved the survival rate and wound closure in penicillin-resistant E. coli-infected mice by eliminating bacterial counts in mouse organs or subeschar, further inhibiting the systemic dissemination of bacteria. Additionally, MSI-1 displayed perfect stability against violent pH, temperature variations and high NaCl concentrations and has the ability to circumvent the development of drug resistance. In terms of the mode of action, we found that at the super-MIC level, MSI-1 exhibited direct antimicrobial activity by disrupting the integrity of the bacterial cell membrane, while at the sub-MIC level, it bound to bacterial DNA to inhibit DNA replication and protein expression and ultimately disrupted bacterial biological function. Conclusions: This novel peptide MSI-1 could be a potential candidate for drug development against infection induced by drug-resistant bacteria.

Efficacy of designer K11 antimicrobial peptide (a hybrid of melittin, cecropin A1 and magainin 2) against Acinetobacter baumannii-infected wounds.

Due to emergence of multidrug resistance in pathogens, the attention of the scientific community is now directed towards strengthening the reservoir of antimicrobial compounds. Prior to in vivo studies, the interaction and penetration of a hybrid peptide K11 in bacterial cells using confocal microscopy was assessed which was observed as early as 10 min after incubation with the peptide. Cell lysis along with leakage of cytoplasmic content was confirmed by electron microscopy. To evaluate the in vivo performance of the peptide, it was contained in carbopol hydrogel. Efficacy of the hydrogel formulation was then evaluated against Acinetobacter baumannii-infected wounds using a murine excision model. Treatment resulted in restoration of body weight, complete clearance of infection from the wound by day 7 and 99% wound enclosure by day 21, in contrast to the persistence of infection and 70% wound enclosure in the infected group. Further, this treatment resulted in a 2.6-fold decrease in the levels of malondialdehyde along with a 4.5-fold increase in the levels of catalase on day 3. Appearance of normal histo-architecture was observed in the treatment group. Based on these results, the peptide hydrogel can be exploited in future as one of the strategies for developing a topical anti-infective therapeutic agent.

Enhanced transdermal delivery with less irritation by magainin pore-forming peptide with a N-lauroylsarcosine and sorbitan monolaurate mixture.

Transdermal drug delivery is advantageous over other conventional drug administration routes. However, it can be inefficient because of the natural barrier of the stratum corneum which is the uppermost layer of the skin. A previous study verified that the treatment of magainin pore-forming peptide with N-lauroylsarcosine (NLS) on human skin can increase skin permeability by 47-fold. However, NLS is well known as a potential skin irritant. The irritation potential of NLS is known to decrease when mixed with sorbitan monolaurate (S20). Encouraged by these results, we combined S20 with magainin-NLS to enhance transdermal drug transport with less skin irritation. In this study, nine groups with magainin and NLS:S20 mixtures at different concentrations and weight fractions were screened to maximize their synergistic effect. To quantify the efficacy to toxicity ratio of each formulation, we defined the ratio as the "enhancement ratio/irritation potential (ER/IP)." The ER was observed by Franz cell diffusion of the target drug fluorescein, and the IP was measured by the cytotoxicity of the NIH/3T3 mouse fibroblast cell line. As a result, the magainin with the NLS:S20 mixture increased the permeability of porcine skin as well as decreased the toxicity. Among the various combinations, a formulation of 2% (w/v) NLS:S20 with a weight fraction of 0.6:0.4 had the largest ER/IP. ATR-FTIR spectroscopy of the formulations and skin was done to analyze the interactions in the formulations themselves and between the formulations and the skin. Both the intercellular lipidic route and transcellular route through the stratum corneum protein were involved in the delivery of fluorescein. This study turned pore-forming peptides into an efficient and safe penetration enhancer by combining them with other chemical penetration enhancers. Moreover, this discovery could be a possible method for enabling the transdermal delivery of macromolecules.

Magainin-AM2 improves glucose homeostasis and beta cell function in high-fat fed mice.

BACKGROUND: Magainin-AM2, a previously described amphibian host-defense peptide, stimulates insulin- and glucagon-like peptide-1-release in vitro. This study investigated anti-diabetic effects of the peptide in mice with diet-induced obesity and glucose intolerance. METHODS: Male National Institute of Health Swiss mice were maintained on a high-fat diet for 12-weeks prior to the daily treatment with magainin-AM2. Various indices of glucose tolerance were monitored together with insulin secretory responsiveness of islets at conclusion of study. RESULTS: Following twice daily treatment with magainin-AM2 for 15 days, no significant difference in body weight and food intake was observed compared with saline-treated high fat control animals. However, non-fasting blood glucose was significantly (P<0.05) decreased while plasma insulin concentrations were significantly (P<0.05) increased. Oral and intraperitoneal glucose tolerance and insulin secretion following glucose administration via both routes were significantly (P<0.05) enhanced. The peptide significantly (P<0.001) improved insulin sensitivity as well as the beta cell responses of islets isolated from treated mice to a range of insulin secretagogues. Oxygen consumption, CO2production, respiratory exchange ratio and energy expenditure were not significantly altered by sub-chronic administration of magainin-AM2 but a significant (P<0.05) reduction in fat deposition was observed. CONCLUSION: These results indicate that magainin-AM2 improves glucose tolerance, insulin sensitivity and islet beta cells secretory responsiveness in mice with obesity-diabetes. GENERAL SIGNIFICANCE: The activity of magainin-AM2 suggests the possibility of exploiting this peptide for treatment of type 2 diabetes.

Magainin-related peptides stimulate insulin-release and improve glucose tolerance in high fat fed mice.

Earlier peptidomic analysis of the skin secretion of Xenopus amieti led to the identification of orthologs of magainins and other peptides. This study investigated the degradation, in vitro insulin-releasing and acute metabolic effects of magainin-AM1 (GIKEFAHSLGKFG KAFVGGILNQ) and magainin-AM2 (GVSKILHSAGKFGKAFLGEIMKS). Plasma degradation was investigated using reversed-phase HPLC and MALDI-TOF mass spectroscopy. Insulin-releasing effects were determined using BRIN-BD11 clonal beta cells and mouse islets. Effects of magainin peptides on cytosolic enzyme lactate dehydrogenase release, membrane potential and intracellular Ca(2+) concentration were assessed using BRIN-BD11 cells while their in vivo effects on glucose tolerance and insulin release were assessed in obese, insulin-resistant Swiss National Institute of Health (NIH) mice. Both peptides were resistant to degradation by plasma enzymes in vitro for up to 8 h. Though magainin-AM1 elicited non-toxic, concentration-dependent stimulation of insulin-release from clonal BRINBD11 cells at concentrations ≥ 100nM, magainin-AM2 produced a higher stimulation of insulin-release from BRIN-BD11 cells and isolated mouse islets. Membrane depolarization and intracellular [Ca(2+)]i in BRIN-BD11 cells were significantly (P<0.05) induced by both peptides and chelation of extracellular Ca(2+), addition of diazoxide or verapamil significantly (P<0.01) reduced the insulinotropic actions of the peptides. Administration of magainin-AM2 (75 nmol/kg body weight) to high-fat fed mice significantly enhanced insulin-release (P<0.01) and improved glucose tolerance (P<0.05). These data indicate magainin-AM2 peptides have potential for development into agents for treatment of type 2 diabetes.

Magainin II modified polydiacetylene micelles for cancer therapy.

Polydiacetylene (PDA) micelles have been widely used to deliver anticancer drugs in the treatment of a variety of tumours and for imaging living cells. In this study, we developed an effective strategy to directly conjugate magainin II (MGN-II) to the surface of PDA micelles using a fluorescent dye. These stable and well-defined PDA micelles had high cytotoxicity in cancer cell lines, and were able to reduce the tumour size in mice. The modified PDA micelles improved the anticancer effects of MGN-II in the A549 cell line only at a concentration of 16.0 µg mL(-1) (IC50). In addition, following irradiation with UV light at 254 nm, the PDA micelles gave rise to an energy transfer from the fluorescent dye to the backbone of PDA micelles to enhance the imaging of living cells. Our results demonstrate that modified PDA micelles can not only be used in the treatment of tumors in vitro and in vivo in a simple and directed way, but also offer a new platform for designing functional liposomes to act as anticancer agents.

The cytotoxic effect of magainin II on the MDA-MB-231 and M14K tumour cell lines.

Many studies have highlighted the tumoricidal properties of some natural peptides known to have antimicrobial virtues. Also, the increasingly higher resistance to conventional antibiotics has become a global public health issue, and the need for new antibiotics has stimulated interest in finding and synthesizing new antimicrobial peptides, which may also be used as chemotherapeutic agents. Relying on the literature, the purpose of our in vitro research was to assess the tumoricidal potential of magainin II on a series of tumour cell lines, namely, MDA-MB-231 (breast adenocarcinoma) and M14K (human mesothelioma). The experimental results of our study revealed that the cytotoxic effects of magainin II depend on its concentration. Its efficiency is significant at 120 µM concentrations, and, although it is much lower, it persists even at 60 µM concentrations. The effects were insignificant at 30 µM concentrations. In our experimental research, the tumoricidal effect of magainin II was not significantly dependent on the type of tumour cell line used.

Biomaterials as novel penetration enhancers for transdermal and dermal drug delivery systems.

The highly organized structure of the stratum corneum provides an effective barrier to the drug delivery into or across the skin. To overcome this barrier function, penetration enhancers are always used in the transdermal and dermal drug delivery systems. However, the conventional chemical enhancers are often limited by their inability to delivery large and hydrophilic molecules, and few to date have been routinely incorporated into the transdermal formulations due to their incompatibility and local irritation issues. Therefore, there has been a search for the compounds that exhibit broad enhancing activity for more drugs without producing much irritation. More recently, the use of biomaterials has emerged as a novel method to increase the skin permeability. In this paper, we present an overview of the investigations on the feasibility and application of biomaterials as penetration enhancers for transdermal or dermal drug delivery systems.