In situ monitoring of exopolymer-dependent Mn mineralization on bacterial surfaces.
Thaïs CouasnonDamien AlloyeauBenedicte MenezFrançois GuyotJean-Marc GhigoAlexandre GélabertPublished in: Science advances (2020)
Bacterial biomineralization is a widespread process that affects cycling of metals in the environment. Functionalized bacterial cell surfaces and exopolymers are thought to initiate mineral formation, however, direct evidences are hampered by technical challenges. Here, we present a breakthrough in the use of liquid-cell scanning transmission electron microscopy to observe mineral growth on bacteria and the exopolymers they secrete. Two Escherichia coli mutants producing distinct exopolymers are investigated. We use the incident electron beam to provoke and observe the precipitation of Mn-bearing minerals. Differences in the morphology and distribution of Mn precipitates on the two strains reflect differences in nucleation site density and accessibility. Direct observation under liquid conditions highlights the critical role of bacterial cell surface charges and exopolymer types in metal mineralization. This has strong environmental implications because biofilms structured by exopolymers are widespread in nature and constitute the main form of microbial life on Earth.
Keyphrases
- electron microscopy
- escherichia coli
- cell surface
- single cell
- cell therapy
- room temperature
- biofilm formation
- cardiovascular disease
- ionic liquid
- microbial community
- high resolution
- human health
- stem cells
- metal organic framework
- type diabetes
- mesenchymal stem cells
- bone marrow
- staphylococcus aureus
- heavy metals
- single molecule
- klebsiella pneumoniae