Maria Luisa Mangoni

Temporin L: antimicrobial, haemolytic and cytotoxic activities, and effects on membrane permeabilization in lipid vesicles

The temporins are a family of small, linear antibiotic peptides with intriguing biological properties. We investigated the antibacterial, haemolytic and cytotoxic activities of temporin L (FVQWFSKFLGRIL-NH2), isolated from the skin of the European red frog Rana temporaria. The peptide displayed the highest activity of temporins studied to date, against both human erythrocytes and bacterial and fungal strains. At variance with other known temporins, which are mainly active against Gram-positive bacteria, temporin L was also active against Gram-negative strains such as Pseudomonas aeruginosa A.T.C.C. 15692 and Escherichia coli D21 at concentrations comparable with those that are microbiocidal to Gram-positive bacteria. In addition, temporin L was cytotoxic to three different human tumour cell lines (Hut-78, K-562 and U-937), causing a necrosis-like cell death, although sensitivity to the peptide varied markedly with the specific cell line tested. A study of the interaction of temporin L with liposomes of different lipid compositions revealed that the peptide causes perturbation of bilayer integrity of both neutral and negatively charged membranes, as revealed by the release of a vesicle-encapsulated fluorescent marker, and that the action of the peptide is modulated to some extent by membrane lipid composition. In particular, the presence of negatively charged lipids in the model bilayer inhibits the lytic power of temporin L. We also show that the release of fluorescent markers caused by temporin L is size-dependent and that the peptide does not have a detergent-like effect on the membrane, suggesting that perturbation of bilayer organization takes place on a local scale, i.e. through the formation of pore-like openings.

Temporins, anti-infective peptides with expanding properties

Abstract.Antimicrobial peptides are effector molecules of the innate immune response of all pluricellular organisms, providing them with first-line defence against pathogens. Amphibian skin secretions represent one of the richest natural sources for such peptide antibiotics, and temporins, a large family of antimicrobial peptides from frog skin, are among the smallest ones found in nature to date. Their functional role and modes of action have been described, along with their interesting and unique properties. These properties make temporins good molecules for an in-depth understanding of host defence peptides in general. Furthermore, they are attractive templates for the future design of new therapeutics against infectious diseases with new modes of action, urgently needed due to the increasing resistance of microorganisms to the available drugs.

Short native antimicrobial peptides and engineered ultrashort lipopeptides: similarities and differences in cell specificities and modes of action

Due to the rapid emergence of resistant microbes to the currently available antibiotics, cationic antimicrobial peptides have attracted considerable interest as a possible new generation of anti-infective compounds. However, low cost development for therapeutic or industrial purposes requires, among other properties, that the peptides will be small and with simple structure. Therefore, considerable research has been devoted to optimizing peptide length combined with a simple design. This review focuses on the similarities and differences in the mode of action and target cell specificity of two families of small peptides: the naturally occurring temporins from the skin of amphibia and the engineered ultrashort lipopeptides. We will also discuss the finding that acylation of cationic peptides results in molecules with a more potent spectrum of activity and a higher resistance to proteolytic degradation. Conjugation of fatty acids to linear native peptide sequences is a powerful strategy to engineer novel successful anti-infective drugs.

Lipopolysaccharide, a Key Molecule Involved in the Synergism between Temporins in Inhibiting Bacterial Growth and in Endotoxin Neutralization

Lipopolysaccharide (LPS) is the major structural component of the outer membrane of Gram-negative bacteria and shields them from a variety of host defense factors, including antimicrobial peptides (AMPs). LPS is also recognized by immune cells as a pathogen-associated molecular pattern and stimulates them to secrete pro-inflammatory cytokines that, in extreme cases, lead to a harmful host response known as septic shock. Previous studies have revealed that a few isoforms of the AMP temporin, produced within the same frog specimen, can synergize to overcome bacterial resistance imposed by the physical barrier of LPS. Here we found that temporins can synergize in neutralizing the LPS-induced macrophage activation. Furthermore, the synergism between temporins, to overcome the protective function of LPS as well as its endotoxic effect, depends on the length of the polysaccharide chain of LPS. Importantly, mode of action studies, using spectroscopic and thermodynamic methods, have pointed out different mechanisms underlying the synergism of temporins in antimicrobial and anti-endotoxin activities. To the best of our knowledge, such a dual synergism between isoforms of AMPs from the same species has not been observed before, and it might explain the ability of such amphibians to resist a large repertoire of microorganisms.

The synthesis of antimicrobial peptides in the skin of Rana esculenta is stimulated by microorganisms

Secretions of amphibian skin glands contain numerous antimicrobial peptides that play a crucial role in the defense against microorganisms. The location of these glands on the surface of the animal makes them a useful model for in vivo studies of the relationships between the innate immune system and the natural flora. Here, we present the results of a study showing that in Rana esculenta the total antimicrobial activity of skin secretion is modulated by the presence of the natural flora. Frogs kept in a sterile environment do not produce antimicrobial peptides. This finding represents the first in vivo demonstration of the induction of defense peptides in a vertebrate. We also present data on the morphological changes in skin glands of animals kept in sterile conditions or treated with glucocorticoids. Cells from glands regenerated under normal conditions, but not those from “sterile” frogs, contain κB‐binding activity in the cytoplasm.

Temporins and their synergism against Gram-negative bacteria and in lipopolysaccharide detoxification

Ribosomally synthesized antimicrobial peptides (AMPs) represent an essential component of the ancient and non-specific innate immune system in all forms of life, with the primary role of killing infectious microorganisms. Amphibian skin is one of the richest storehouses for them. Each frog species produces its own set of peptides with up to 10 isoforms, as in the case of the species Rana temporaria. Nowadays, human health is facing two major threats: (i) the increasing emergence of resistant pathogens to one or more available drugs, and (ii) the onset of septic shock, which is associated with the release of lipopolysaccharide (LPS) from the cell walls of Gram-negative bacteria, particularly upon antibiotic treatment. AMPs are considered as potential new anti-infective compounds with a novel mode of action, because many of them can kill bacteria and, at the same time, neutralize the toxic effects of LPS. Recent studies have suggested that the production of large number of structurally similar AMPs within the same animal is a strategy used by nature to increase the spectrum of antimicrobial activities, by using combinations of the peptides isoforms. The biological rationale for their coexistence within the same organism is discussed. In addition, the distinctive and attractive synergistic effects of temporins in both antimicrobial and anti-endotoxin activities are reviewed, along with their plausible underlying molecular mechanism.

Effect of glucocorticoids on the synthesis of antimicrobial peptides in amphibian skin

Gene‐encoded peptide antibiotics are widespread in insects, plants and vertebrates and confer protection against bacterial and fungal infections. NF‐κB is an important transcription factor for many immunity‐related mammalian proteins and also for insect immune genes. The activity of NF‐κB is regulated by the interaction with an inhibitor, IκB. It was recently demonstrated that glucocorticoids induce the synthesis of IκB in human cell lines. So far, all genes for peptide antibiotics have promoter motifs with NF‐κB binding sites, but its actual function in peptide regulation has been studied only in insects. Here we show that glucocorticoid treatment of the frog Rana esculenta inhibits the transcription of all genes encoding antibacterial peptides by inducing the synthesis of IκBα. These results suggest that also in vertebrates peptide‐mediated innate immunity is controlled by NF‐κB‐regulated transcription.

Comparative Analysis of the Bactericidal Activities of Amphibian Peptide Analogues against Multidrug-Resistant Nosocomial Bacterial Strains

ABSTRACT Due to the widespread resistance of bacteria to the available drugs, the discovery of new classes of antibiotics is urgently needed, and naturally occurring antimicrobial peptides (AMPs) are considered promising candidates for future therapeutic use. Amphibian skin is one of the richest sources of such AMPs. In the present study we compared the in vitro bactericidal activities of five AMPs from three different species of anurans against multidrug-resistant clinical isolates belonging to species often involved in nosocomial infections (Staphylococcus aureus, Enterococcus faecium, Pseudomonas aeruginosa, Stenotrophomonas maltophilia, and Acinetobacter baumannii). The peptides tested were temporins A, B, and G from Rana temporaria; the fragment from positions 1 to 18 of esculentin 1b [Esc(1-18)] from Rana esculenta; and bombinin H2 from Bombina variegata. When they were tested in buffer, all the peptides were bactericidal against all bacterial species tested (three strains of each species) at concentrations ranging from 0.5 to 48 μΜ, with only a few exceptions. The temporins were found to be more active against gram-positive bacteria, especially when they were assayed in human serum; Esc(1-18) showed fast and strong bactericidal activity, within 2 to 20 min, especially against the gram-negative species, which were killed by Esc(1-18) at concentrations ranging from 0.5 to 1 μΜ; bombinin H2 displayed similar bactericidal activity toward all isolates. Interestingly, while the activities of the temporins and bombinin H2 were almost completely inhibited in the presence of 20% human serum, the activity of Esc(1-18) against the gram-negative species was partially preserved in the presence of 40% serum. This property renders this peptide an attractive molecule for use in the development of new compounds for the treatment of infectious diseases.

NMR Structures and Interactions of Temporin-1Tl and Temporin-1Tb with Lipopolysaccharide Micelles MECHANISTIC INSIGHTS INTO OUTER MEMBRANE PERMEABILIZATION AND SYNERGISTIC ACTIVITY

Temporins are a group of closely related short antimicrobial peptides from frog skin. Lipopolysaccharide (LPS), the major constituent of the outer membrane of Gram-negative bacteria, plays important roles in the activity of temporins. Earlier studies have found that LPS induces oligomerization of temporin-1Tb (TB) thus preventing its translocation across the outer membrane and, as a result, reduces its activity on Gram-negative bacteria. On the other hand, temporin-1Tl (TL) exhibits higher activity, presumably because of lack of such oligomerization. A synergistic mechanism was proposed, involving TL and TB in overcoming the LPS-mediated barrier. Here, to gain insights into interactions of TL and TB within LPS, we investigated the structures and interactions of TL, TB, and TL+TB in LPS micelles, using NMR and fluorescence spectroscopy. In the context of LPS, TL assumes a novel antiparallel dimeric helical structure sustained by intimate packing between aromatic-aromatic and aromatic-aliphatic residues. By contrast, independent TB has populations of helical and aggregated conformations in LPS. The LPS-induced aggregated states of TB are largely destabilized in the presence of TL. Saturation transfer difference NMR studies have delineated residues of TL and TB in close contact with LPS and enhanced interactions of these two peptides with LPS, when combined together. Fluorescence resonance energy transfer and 31P NMR have pointed out the proximity of TL and TB in LPS and conformational changes of LPS, respectively. Importantly, these results provide the first structural insights into the mode of action and synergism of antimicrobial peptides at the level of the LPS-outer membrane.

Antimicrobial peptides and wound healing: biological and therapeutic considerations

Repair of tissue wounds is a fundamental process to re‐establish tissue integrity and regular function. Importantly, infection is a major factor that hinders wound healing. Multicellular organisms have evolved an arsenal of host‐defense molecules, including antimicrobial peptides (AMPs), aimed at controlling microbial proliferation and at modulating the hosts immune response to a variety of biological or physical insults. In this brief review, we provide the evidence for a role of AMPs as endogenous mediators of wound healing and their promising therapeutic potential for the treatment of non‐life‐threatening skin and other epithelial injuries.