Sergio Bárcena-Varela scite author profile

The most potent cell wall-derived inflammatory toxins (“pathogenicity factors”) of Gram-negative and -positive bacteria are lipopolysaccharides (LPS) (endotoxins) and lipoproteins (LP), respectively. Despite the fact that the former signals via toll-like receptor 4 (TLR4) and the latter via TLR2, the physico-chemistry of these compounds exhibits considerable similarity, an amphiphilic molecule with a polar and charged backbone and a lipid moiety. While the exterior portion of the LPS (i.e., the O-chain) represents the serologically relevant structure, the inner part, the lipid A, is responsible for one of the strongest inflammatory activities known. In the last years, we have demonstrated that antimicrobial peptides from the Pep19-2.5 family, which were designed to bind to LPS and LP, act as anti-inflammatory agents against sepsis and endotoxic shock caused by severe bacterial infections. We also showed that this anti-inflammatory activity requires specific interactions of the peptides with LPS and LP leading to exothermic reactions with saturation characteristics in calorimetry assays. Parallel to this, peptide-mediated neutralization of LPS and LP involves changes in various physical parameters, including both the gel to liquid crystalline phase transition of the acyl chains and the three-dimensional aggregate structures of the toxins. Furthermore, the effectivity of neutralization of pathogenicity factors by peptides was demonstrated in several in vivo models together with the finding that a peptide-based therapy sensitizes bacteria (also antimicrobial resistant) to antibiotics. Finally, a significant step in the understanding of the broad anti-inflammatory function of Pep19-2.5 was the demonstration that this compound is able to block the intracellular endotoxin signaling cascade.

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AMPs as Anti-biofilm Agents for Human Therapy and Prophylaxis

Shahrour

Ferrer‐Espada

Dandache

et al. 2019

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Lipoproteins/peptides are sepsis-inducing toxins from bacteria that can be neutralized by synthetic anti-endotoxin peptides

Tejada

Heinbockel

Ferrer‐Espada

et al. 2015

Sci Rep

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Sepsis, a life-threatening syndrome with increasing incidence worldwide, is triggered by an overwhelming inflammation induced by microbial toxins released into the bloodstream during infection. A well-known sepsis-inducing factor is the membrane constituent of Gram-negative bacteria, lipopolysaccharide (LPS), signalling via Toll-like receptor-4. Although sepsis is caused in more than 50% cases by Gram-positive and mycoplasma cells, the causative compounds are still poorly described. In contradicting investigations lipoproteins/-peptides (LP), lipoteichoic acids (LTA), and peptidoglycans (PGN), were made responsible for eliciting this pathology. Here, we used human mononuclear cells from healthy donors to determine the cytokine-inducing activity of various LPs from different bacterial origin, synthetic and natural, and compared their activity with that of natural LTA and PGN. We demonstrate that LP are the most potent non-LPS pro-inflammatory toxins of the bacterial cell walls, signalling via Toll-like receptor-2, not only in vitro, but also when inoculated into mice: A synthetic LP caused sepsis-related pathological symptoms in a dose-response manner. Additionally, these mice produced pro-inflammatory cytokines characteristic of a septic reaction. Importantly, the recently designed polypeptide Aspidasept® which has been proven to efficiently neutralize LPS in vivo, inhibited cytokines induced by the various non-LPS compounds protecting animals from the pro-inflammatory activity of synthetic LP.

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Antibacterial action of synthetic antilipopolysaccharide peptides (SALP) involves neutralization of both membrane‐bound and free toxins

et al. 2019

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Increasing failure of conventional antibiotics to combat bacterial infections requires the urgent development of new antibacterial drugs; a promising class of new drugs based on antimicrobial peptides. Here, we studied the molecular interaction of polycationic synthetic antilipopolysaccharide peptides (SALPs) with various gram‐negative and gram‐positive bacteria, including resistant strains. The analysis of antimicrobial activity by conventional techniques and atomic force microscopy showed a strict dependence on amino acid (aa) sequences, with the type of amino acid, its position within the primary structure, and the sequence length being critical parameters. By monitoring lipopolysaccharide (LPS)‐ or bacteria‐induced cytokine production in human mononuclear cells and whole blood, we found a direct link between the binding of the lead compound Pep19‐2.5 to Salmonella enterica and the anti‐inflammatory activity of the peptide. Thermodynamic analysis of Pep19‐2.5 binding to the bacterial cell envelope showed an exothermic reaction with saturation characteristics, whereas small‐angle X‐ray scattering data indicated a direct attachment of Pep19‐2.5 to the bacterial cell envelope. This binding preferentially takes place to the LPS outer monolayer, as evidenced by the change in the LPS acyl chain and phosphate vibrational bands seen by Fourier‐transform infrared spectroscopy. We report here that the anti‐inflammatory activity of Pep19‐2.5 is not only connected with neutralization of cell‐free bacterial toxins but also with a direct binding of the peptide to the outer leaflet of the bacterial outer membrane.

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Antimicrobial endotoxin‐neutralizing peptides promote keratinocyte migration via P2X7 receptor activation and accelerate wound healing in vivo

Pfalzgraff

Bárcena-Varela

Heinbockel

et al. 2018

British J Pharmacology

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