Abstract
Biofilms frequently cause complications in various areas of human life, e.g. in medicine and in the food industry. More recently, biofilms are discussed as new types of living materials with tuneable mechanical properties. In particular, Escherichia coli produces a matrix composed of amyloid-forming curli and phosphoethanolamine-modified cellulose fibres in response to suboptimal environmental conditions. It is currently unknown how the interaction between these fibres contributes to the overall mechanical properties of the formed biofilms and if extrinsic control parameters can be utilized to manipulate these properties. Using shear rheology, we show that biofilms formed by the E. coli K-12 strain AR3110 stiffen by a factor of two when exposed to the trivalent metal cations Al(III) and Fe(III) while no such response is observed for the bivalent cations Zn(II) and Ca(II). Strains producing only one matrix component did not show any stiffening response to either cation or even a small softening. No stiffening response was further observed when strains producing only one type of fibre were co-cultured or simply mixed after biofilm growth. These results suggest that the E. coli biofilm matrix is a uniquely structured composite material when both matrix fibres are produced from the same bacterium. While the exact interaction mechanism between curli, phosphoethanolamine-modified cellulose and trivalent metal cations is currently not known, our results highlight the potential of using extrinsic parameters to understand and control the interplay between biofilm structure and mechanical properties. This will ultimately aid the development of better strategies for controlling biofilm growth.
Competing Interest Statement
The authors have declared no competing interest.
