Copper Driven Mutualism of Candida albicans and Staphylococcus aureus Interkingdom Biofilms

Although fungi and bacteria commonly coexist within polymicrobial communities, the molecular mechanisms underlying their interactions are still not well understood. Here, we show that the fungus Candida albicans forms biofilms with the bacterium Staphylococcus aureus along a nutritional axis of mutualism and propose that “a copper economy” shapes fungal-bacterial biofilm interactions.

Using in vitro biofilms formed on plastic, we found that dual species biofilms are consistently larger than single-species counterparts, indicating a cooperative interaction. Dual species proteomic analysis revealed non-reciprocal copper handling: C. albicans increased copper uptake via transporter Ctr1, while S. aureus enhanced copper export via regulator CsoR and export chaperone CopZ. Dual species biofilms exhibited specific sensitivity to both copper depletion and supplementation, with corresponding reductions in biomass. We identified fungal copper import as the crucial element in mutualistic interactions between C. albicans and staphylococcal species. Moreover, fungal hyphae served as a critical scaffold for biofilm architecture, a role that was compromised under copper-replete conditions. Notably, copper nanoparticles disrupted these dual species biofilms, highlighting a potential therapeutic avenue. Furthermore, we extend the role of C. albicans copper import to mutualistic interactions with additional bacterial species. Our findings establish copper as a central mediator of C. albicans and S. aureus cooperation and suggest that a "copper economy" underpins mutualistic interactions in biofilms.