Polymer-directed inhibition of reversible to irreversible attachment prevents Pseudomonas aeruginosa biofilm formation

Non-toxic, biocompatible materials that inhibit bacterial biofilm formation on implanted medical devices and so prevent infection are urgently required. Weakly amphiphilic acrylate polymers with rigid hydrocarbon pendant groups resist bacterial biofilm formation in vitro and in vivo but the biological mechanism involved is not known. By comparing biofilm formation on polymers with the same acrylate backbone but with different pendant groups, we show that poly(ethylene glycol dicyclopentenyl ether acrylate; pEGdPEA) but not neopentyl glycol propoxylate diacrylate (pNGPDA) inhibited the transition from reversible to irreversible attachment. By using single-cell tracking algorithms and controlled flow microscopy we observed that fewer Pseudomonas aeruginosa PAO1 cells accumulated on pEGdPEA compared with pNGPDA. Bacteria reaching the pEGdPEA surface exhibited shorter residence times and greater asymmetric division with more cells departing from the surface post-cell division, characteristic of reversible attachment. Migrating cells on pEGdPEA deposited fewer exopolysaccharide trails and were unable top adhere strongly. Discrimination between the polymers required type IV pili and flagella. On pEGdPEA, the lack of accumulation of cyclic diguanylate or expression of sadB were consistent with the failure to transit from reversible to irreversible attachment. Constitutive expression of sadB increased surface adhesion sufficient to enable P. aeruginosa to form biofilms in a Mot flagellar stator dependent manner. These findings were extendable to other biofilm resistant acrylates highlighting their unique ability to inhibit reversible to irreversible attachment as a mechanism for preventing biofilm-associated infections. Significance Bacteria readily attach to surfaces forming biofilms. These are commonly associated with medical device-associated infections and highly refractory to antibiotics. Biocompatible, weakly amphiphilic acrylate polymers with large hydrophobic pendant groups that inhibit biofilm formation and can prevent such infections have been described. However, the biological mechanism involved is not understood. By comparing a biofilm-inhibiting with a biofilm-supporting acrylate, we showed that Pseudomonas aeruginosa PAO1 cells responded differentially to the two polymers and were unable to accumulate and adhere strongly, activate cyclic diguanylate signalling or transit from reversible to irreversible attachment on the inhibitory polymer. Constitutive expression of sadB increased surface adhesion sufficient to enable P. aeruginosa to form biofilms in a flagellar stator dependent manner overcoming the biofilm inhibitory properties of the polymer. ### Competing Interest Statement The authors have declared no competing interest.