Dermaseptin PD-3-6

The dermaseptin antimicrobial peptide family contains members of 27-34 amino acids in length that have been predominantly isolated from the skins/skin secretions of phyllomedusine leaf frogs. By use of a degenerate primer in Rapid amplification of cDNA ends (RACE) PCR designed to a common conserved domain within the 5'-untranslated regions of previously-characterized dermaseptin encoding cDNAs, two novel members of this peptide family, named dermaseptin-PD-1 and dermaseptin-PD-2, were identified in the skin secretion of the phyllomedusine frog, Pachymedusa dacnicolor. The primary structures of both peptides were predicted from cloned cDNAs, as well as being confirmed by mass spectral analysis of crude skin secretion fractions resulted from reversed-phase high-performance liquid chromatography. Chemically-synthesized replicates of dermaseptin-PD-1 and dermaseptin-PD-2 were investigated for antimicrobial activity using standard model microorganisms (Gram-positive bacteria, Gram-negative bacteria and a yeast) and for cytotoxicity using mammalian red blood cells. The possibility of synergistic effects between the two peptides and their anti-cancer cell proliferation activities were assessed. The peptides exhibited moderate to high inhibition against the growth of the tested microorganisms and cancer cell lines with low haemolytic activity. Synergistic interaction between the two peptides in inhibiting the proliferation of Escherichia coli and human neuronal glioblastoma cell line, U251MG was also manifested.

Antimicrobial resistance has been an increasing public health threat in recent years. Antimicrobial peptides are considered as potential drugs against drug-resistant bacteria because they are mainly broad-spectrum and are unlikely to cause resistance. In this study, a novel peptide was obtained from the skin secretion of Agalychnis callidryas using the "shotgun" cloning method. The amino acid sequence, molecular weight, and secondary structure of Dermaseptin-AC were determined. The in vitro antimicrobial activity, hemolysis, and cytotoxicity of Dermaseptin-AC were evaluated. MICs and minimum bactericidal concentrations (MBCs) of Dermaseptin-AC against seven different bacterial strains ranged between 2 ~ 4 μM and 2 ~ 8 μM. The HC50 (50% maximum hemolysis concentration) of Dermaseptin-AC against horse erythrocytes was 76.55 μM. The in vivo anti-MRSA effect was tested on immune-suppressed MRSA pneumonia in mice. Dermaseptin-AC showed anti-MRSA effects similar to the same dose of vancomycin (10 mg/kg body weight). Short-term (7 days of intraperitoneal injection, 10 mg/kg body weight) in vivo safety evaluation of Dermaseptin-AC was tested on mice. The survival rate during the 7-day injection was 80%. Dermaseptin-AC showed no obvious effect on the liver, heart, spleen, kidney, and blood, but did induce slight pulmonary congestion. The skin safety of Dermaseptin-AC was evaluated on wounds on the back skin of a rat, and no irritation was observed. IMPORTANCE In this study, we discovered a new antimicrobial peptide, Dermaseptin-AC, and studied its in vitro and in vivo antimicrobial activity. These studies provide some data for finding new antimicrobial peptides for overcoming antimicrobial resistance. Dermaseptin-AC showed strong broad-spectrum antibacterial activity and relatively low hemolysis, and was more cytotoxic to cancer cells than to normal cells. Dermaseptin-AC was active in vivo, and its anti-MRSA effect was similar to that of vancomycin when administered by intraperitoneal injection. Safety studies found that continuous injection of Dermaseptin-AC may cause mild pulmonary congestion, while there was no obvious irritation when it was applied to skin wounds. Chronic wounds are often accompanied by high bacterial burdens and, at the same time, antimicrobial resistance is more likely to occur during repeated infections and treatments. Therefore, developing Dermaseptin-AC to treat chronic wound infection may be an attractive choice.

Antimicrobial Peptides (AMPs) are one of the most common components of the innate immune system that protect multicellular organisms against microbial invasion. The vast majority of AMPs are isolated from the frog skin. Anuran (frogs and toads) skin contains abundant AMPs that can be developed therapeutically. Such peptides are a unique but diverse group of molecules. In general, more than 50% of the amino acid residues form the hydrophobic part of the molecule. Normally, there are no conserved structural motifs responsible for activity, although the vast majority of the AMPs are cationic due to the presence of multiple lysine residues; this cationicity has a close relationship with antibacterial activity. Notably, recent evidence suggests that synthesis of AMPs in frog skin may confer an advantage on a particular species, although they are not essential for survival. Frog skin AMPs exert potent activity against antibiotic-resistant bacteria, protozoa, yeasts, and fungi by permeating and destroying the plasma membrane and inactivating intracellular targets. Importantly, since they do not bind to a specific receptor, AMPs are less likely to induce resistance mechanisms. Currently, the best known amphibian AMPs are esculentins, brevinins, ranacyclins, ranatuerins, nigrocin-2, magainins, dermaseptins, bombinins, temporins, and japonicins-1 and -2, and palustrin-2. This review focuses on these frog skin AMPs and the mechanisms underlying their antimicrobial activity. We hope that this review will provide further information that will facilitate further study of AMPs and cast new light on novel and safer microbicides.