Selective inhibition of the amyloid matrix of Escherichia coli biofilms by a bifunctional microbial metabolite

The propensity of bacteria to grow collectively in communities known as biofilms and their ability to overcome clinical treatments in this condition has become a major medical problem, emphasizing the need for anti-biofilm strategies. Antagonistic microbial interactions have extensively served as se...

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Bibliographic Details
Published in:NPJ biofilms and microbiomes 2023-10, Vol.9 (1), p.81-81, Article 81
Main Authors: Cordisco, Estefanía, Zanor, María Inés, Moreno, Diego Martín, Serra, Diego Omar
Format: Article
Language:English
Subjects:
631/326/22
631/326/2565/107
Amyloid
Antibiotics
Biofilms
Biomedical and Life Sciences
Competitiveness
E coli
Escherichia coli
Extracellular matrix
Fibers
Life Sciences
Medical Microbiology
Metabolites
Microbial Ecology
Microbial Genetics and Genomics
Microbiology
Soil microorganisms
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Summary:The propensity of bacteria to grow collectively in communities known as biofilms and their ability to overcome clinical treatments in this condition has become a major medical problem, emphasizing the need for anti-biofilm strategies. Antagonistic microbial interactions have extensively served as searching platforms for antibiotics, but their potential as sources for anti-biofilm compounds has barely been exploited. By screening for microorganisms that in agar-set pairwise interactions could antagonize Escherichia coli’s ability to form macrocolony biofilms, we found that the soil bacterium Bacillus subtilis strongly inhibits the synthesis of amyloid fibers –known as curli-, which are the primary extracellular matrix (ECM) components of E. coli biofilms. We identified bacillaene, a B. subtilis hybrid non-ribosomal peptide/polyketide metabolite, previously described as a bacteriostatic antibiotic, as the effector molecule. We found that bacillaene combines both antibiotic and anti-curli functions in a concentration-dependent order that potentiates the ecological competitiveness of B. subtilis , highlighting bacillaene as a metabolite naturally optimized for microbial inhibition. Our studies revealed that bacillaene inhibits curli by directly impeding the assembly of the CsgB and CsgA curli subunits into amyloid fibers. Moreover, we found that curli inhibition occurs despite E. coli attempts to reinforce its protective ECM by inducing curli genes via a RpoS-mediated competition sensing response trigged by the threatening presence of B. subtilis . Overall, our findings illustrate the relevance of exploring microbial interactions not only for finding compounds with unknown and unique activities, but for uncovering additional functions of compounds previously categorized as antibiotics.
ISSN:2055-5008
2055-5008
DOI:10.1038/s41522-023-00449-6