Lipase-mediated detoxification of host-derived antimicrobial fatty acids by Staphylococcus aureus.
Arnaud Kengmo TchoupaAhmed M A ElsherbiniJustine CamusXiaoqing FuXuanheng HuOumayma GhanemeLea SeibertMarco LebtigMarieke A BöckerAnima HorlbeckStilianos P LambidisBirgit SchittekDorothee KretschmerMichael LämmerhoferAndreas PeschelPublished in: Communications biology (2024)
Long-chain fatty acids with antimicrobial properties are abundant on the skin and mucosal surfaces, where they are essential to restrict the proliferation of opportunistic pathogens such as Staphylococcus aureus. These antimicrobial fatty acids (AFAs) elicit bacterial adaptation strategies, which have yet to be fully elucidated. Characterizing the pervasive mechanisms used by S. aureus to resist AFAs could open new avenues to prevent pathogen colonization. Here, we identify the S. aureus lipase Lip2 as a novel resistance factor against AFAs. Lip2 detoxifies AFAs via esterification with cholesterol. This is reminiscent of the activity of the fatty acid-modifying enzyme (FAME), whose identity has remained elusive for over three decades. In vitro, Lip2-dependent AFA-detoxification was apparent during planktonic growth and biofilm formation. Our genomic analysis revealed that prophage-mediated inactivation of Lip2 was rare in blood, nose, and skin strains, suggesting a particularly important role of Lip2 for host - microbe interactions. In a mouse model of S. aureus skin colonization, bacteria were protected from sapienic acid (a human-specific AFA) in a cholesterol- and lipase-dependent manner. These results suggest Lip2 is the long-sought FAME that exquisitely manipulates environmental lipids to promote bacterial growth in otherwise inhospitable niches.
Keyphrases
- staphylococcus aureus
- fatty acid
- biofilm formation
- candida albicans
- mouse model
- escherichia coli
- pseudomonas aeruginosa
- methicillin resistant staphylococcus aureus
- soft tissue
- wound healing
- minimally invasive
- computed tomography
- low density lipoprotein
- magnetic resonance imaging
- cystic fibrosis
- multidrug resistant
- climate change
- gram negative
- risk assessment