Cell Research | 2019
Probiotic fengycins dis(Agr)ee with Staphylococcus aureus colonization
Abstract
Competition between bacterial species can mediate protection against infection, albeit by mechanisms that are largely unknown. A recent study in Nature by Piewngam et al. demonstrates that a Bacillus lipopeptide, fengycin, restricts intestinal Staphylococcus aureus colonization by inhibiting quorum sensing. The human pathogen Staphylococcus aureus utilizes an extensive arsenal of virulence factors to cause substantial morbidity and mortality worldwide. Although S. aureus infections typically arise following asymptomatic nasal or skin carriage, recent studies have proposed that intestinal carriage also serves as an important reservoir. The intestinal tract harbors a multitude of microbes, collectively known as the microbiota, which confers benefits to the host by promoting a variety of functions including immune development and colonization resistance to pathogens, albeit by mechanisms that are largely unknown. In a recent issue of Nature, Piewngam and colleagues identified an inverse correlation between human colonization with Bacillus species and with S. aureus, and subsequently discovered a primary mechanism by which Bacillus species can exclude S. aureus from the gut: inhibition of quorum sensing. The authors initially hypothesized that gut microbiota composition could alter colonization by S. aureus. Intriguingly, analysis of fecal samples from a rural Thai population revealed a strong correlation between the presence of Bacillus spp. in the gut and the exclusion of both intestinal and nasal colonization by S. aureus. The genus Bacillus comprises Gram-positive soil bacteria that form endospores. Upon ingestion (e.g., on vegetables), the spores germinate into vegetative cells, allowing the bacteria to temporarily colonize the gut. Of note, some Bacillus species are included in probiotic preparations, although the mechanisms by which they exhibit beneficial activities are not well understood. The absence of S. aureus colonization in individuals where Bacillus was present in the gut led the authors to hypothesize that Bacillus species could produce a factor that directly targeted S. aureus, akin to bacteriocins secreted by commensal enterococci and to microcins secreted by probiotic E. coli Nissle 1917. However, culture filtrates from Bacillus isolates generally failed to exhibit direct antimicrobial activity against S. aureus, indicating that an alternative mechanism of bacterial competition was being employed. Prompted by, and extrapolating upon, relatively limited information on intestinal colonization by S. aureus, the authors hypothesized that Bacillus species were inhibiting the S. aureus accessory gene regulator (Agr) quorum-sensing system. The ability to sense and to respond to changes in cell density is known as quorum sensing, a function that allows bacteria to coordinate population-level changes in gene expression, including genes involved in pathogenesis. In S. aureus, the expression of numerous virulence factors is primarily mediated by Agr. On this front, the authors investigated whether S. aureus required Agr in a mouse model of intestinal colonization. Subsequent experiments using wild-type S. aureus and an isogenic agrmutant revealed that the mutant strain had a severe defect in colonizing the murine intestine, a defect that could be rescued by ectopic expression of the Agr effector, RNAIII. Taken together, these findings revealed an essential role for Agr-dependent quorum sensing during S. aureus colonization of the gut. Next, Piewngam et al. discovered that Bacillus subtilis reduced S. aureus Agr activity in vitro. Meticulous chromatography and mass spectrometry analyses identified fengycins, specific classes of lipopeptides with antifungal activity, as potential Agr-targeting candidates secreted by Bacillus species. Despite the heterogeneity of fengycin profiles among Bacillus isolates, the predominant fengycin species was identified as β-OH-C17-fengycin B. Importantly, culture filtrates from a B. subtilis strain defective in fengycin synthesis failed to impede Agr signaling, indicating that the lipopeptide accounts for the Agr-inhibiting activity of B. subtilis. Induction of S. aureus Agr is initiated by interaction of Agr autoinducing peptides (AIPs) with the extracellular quorumsensing receptor AgrC. As fengycins exhibit structural similarity to AIPs, AgrC interference appeared to be a likely mechanism of quorum-sensing inhibition. In line with this, exogenous addition of AIPs reduced fengycin-mediated Agr inhibition in a dosedependent fashion in vitro. To assess whether Bacillus fengycins were inhibiting intestinal colonization by S. aureus, mice were orally inoculated with wild-type and fengycin-mutant (ΔfenA) B. subtilis spores, mimicking the typical route of probiotic administration. Levels of Bacillus within the murine intestine were comparable between wild-type and the fengycin mutant, indicating that loss of fengycin production did not adversely affect Bacillus colonization. As predicted, wild-type B. subtilis spores abolished S. aureus colonization of the murine intestine (Fig. 1a), whereas spores from the fengycin mutant did not (Fig. 1b). Altogether, the murine model recapitulated the S. aureus colonization trend observed in humans and enabled the identification of fengycin-mediated quorum-sensing disruption as a mechanism providing colonization resistance against S. aureus. This finding is