Due to increasing antibiotic resistance in pathogens that cause infections, the development of new antibacterial substances is important. Hopes are pinned on a new group of substances produced by gram-positive bacteria, the lantibiotics. Named after the amino acid lanthionine, these antimicrobial peptides often have a very narrow spectrum of activity. "Such compounds are highly interesting from a medical point of view, as they could specifically attack individual groups of organisms without affecting the entire bacterial flora, as is the case with broad-spectrum antibiotics, for example," says corresponding author Dr Fabian Grein from the Institute of Pharmaceutical Microbiology at the University Hospital Bonn (UKB) who until recently served as head of the “Bacterial Interference” research group at the German Center for Infection Research (DZIF).
Essential competitive advantage over corynebacteria
The UKB research team led by Fabian Grein and Tanja Schneider, together with the team led by Ulrich Kubitscheck, Professor of Biophysical Chemistry at the University of Bonn, have now discovered a new lantibiotic—called epilancin A37. It is produced by staphylococci, which are typical colonisers of the skin and mucous membranes. Little is known about these antimicrobial peptides. "We were able to show that epilancins are widespread in staphylococci, which underlines their ecological importance," says first author Jan-Samuel Puls, a doctoral student at the UKB’s Institute of Pharmaceutical Microbiology. This is because staphylococci and corynebacteria are important genera of the human microbiota - i.e. the totality of all microorganisms such as bacteria and viruses - in the nose and skin, which are closely linked to health and disease. The need to produce such a substance indicates a pronounced competition between the species. The researchers were able to show that the newly discovered epilancin A37 acts very specifically against corynebacteria, which are among the main competitors of staphylococci within the skin microbiome.
New mode of action in the "bacterial war" decoded
"This specificity is presumably mediated by a very special mechanism of action that we were able to decipher in detail," says Grein. Epilancin A37 penetrates the corynebacterial cell, initially without destroying it. The antimicrobial peptides accumulate in the cell and then dissolve the cell membrane from the inside, thus killing the corynebacterium. Co-author Dr. Thomas Fließwasser from the UKB’s Institute of Pharmaceutical Microbiology and acting head of the DZIF research group "Bacterial Interference" adds: "Our study shows how a specific mechanism of action can be used to specifically combat a single bacterial species. It therefore serves us as 'proof of concept'".