Let-them-stick: Increasing biofilm formation by the acetogen Sporomusa ovata through adaptive laboratory evolution

Acetogenic bacteria are attractive biocatalysts for the conversion of CO ₂ with H ₂ into acetate, as in gas fermentation. Gas fermentation reactors may benefit from biofilm formation, but cell attachment by acetogens is often limited. This study indeed found that the acetogen Sporomusa ovata 2663 was mainly planktonic and aimed to increase its biofilm formation through adaptive laboratory evolution. The adaptation strategy consisted of growing S. ovata on plastic carriers in bottles with a H ₂ :CO ₂ headspace and transferring few carriers to bottles with fresh carriers over eight serial transfers. This procedure resulted in the evolved S. ovata 2663-BF, which had a consistent increased propensity to attach. In heterotrophic growth conditions, four times more cells attached to the bottom of well plates in comparison to the wild type. Moreover, twice as many cells adhered to carriers when grown on H ₂ :CO ₂ . This improved attachment, however, did not lead to higher acetate production rates in simple trickle bed reactors, as the used experimental setup likely stimulated planktonic growth due to a low trickling frequency. Only after some medium replacements to remove planktonic cells, higher gas consumption rates were recorded for the evolved culture. Interestingly, the evolved S. ovata had a relevant point mutation in the gene galU , encoding UDP-glucose pyrophosphorylase, an enzyme involved in the synthesis of extracellular polysaccharides. Overall, this study demonstrates that cell attachment by S. ovata was increased through adaptive laboratory evolution, offering the prospect of investigating the importance of biofilm formation in biofilm-based gas fermentation reactors.