Flagellar motility mediates biofilm formation in Aeromonas dhakensis

Aeromonas dhakensis possesses dual flagellar systems for motility under different environments. Flagella -mediated motility is necessary for biofilm formation through an initial attachment of bacteria to the surface, but this has not been elucidated in A. dhakensis. This study investigates the role of polar (flaH, maf1) and lateral (lafB, lafK and lafS) flagellar genes in the biofilm formation of a clinical A. dhakensis strain WT187 isolated from burn wound infection. Five deletion mutants and corresponding complemented strains were constructed using pDM4 and pBAD33 vectors, respectively, and analyzed for motility and biofilm formation using crystal violet staining and real-time impedance-based assays. All mutants were significantly reduced in swimming (p < 0.0001), swarming (p < 0.0001) and biofilm formation using crystal violet assay (p < 0.05). Real-time imped-ance-based analysis revealed WT187 biofilm was formed between 6 to 21 h, consisting of early (6-10 h), middle (11-18 h), and late (19-21 h) stages. The highest cell index of 0.0746 was recorded at 22-23 h and biofilms began to disperse starting from 24 h. Mutants Delta maf1, Delta lafB, Delta lafK and Delta lafS exhibited reduced cell index values at 6-48 h when compared to WT187 which indicates less biofilm formation. Two complemented strains cmaf1 and clafB exhibited full restoration to wild-type level in swimming, swarming, and biofilm formation using crystal violet assay, hence suggesting that both maf1 and lafB genes are involved in biofilm formation through flagella-mediated motility and surface attachment. Our study shows the role of flagella in A. dhakensis biofilm formation warrants further investigations.

Automated summary

This study investigates the role of flagellar genes in the biofilm formation of Aeromonas dhakensis. Results show that mutants lacking certain flagellar genes exhibited reduced swimming, swarming, and biofilm formation. However, complemented strains with these genes restored wild-type levels of motility and biofilm formation. This suggests that these flagellar genes play an important role in biofilm formation through flagella-mediated motility and surface attachment.