Differential impact on motility and biofilm dispersal of closely related phosphodiesterases in Pseudomonas aeruginosa

Bacteria typically occur either as free-swimming planktonic cells or within a sessile, biofilm mode of growth. In Pseudomonas aeruginosa, the transition between these lifestyles is known to be modulated by the intracellular secondary messenger cyclic dimeric-GMP (c-di-GMP). We are interested in the control of distinct biofilm-relevant phenotypes in P. aeruginosa through the modulation of intracellular c-di-GMP. Here, we characterise motility and associated biofilm formation and dispersal in two pairs of related multi-domain proteins with putative c-di-GMP turnover domains, selected to contain additional PAS (Per-Arnt-Sim) homology domains known for their ability to process environmental stimuli. The enzymes PA0861 (RbdA) and PA2072 have distinct functions despite their similar domain structures. The ΔrbdA deletion mutant showed significantly increased biofilm formation while biofilm formation was impaired in ΔPA2072. Using a GFP transcriptional reporter fused to the cyclic di-GMP-responsive cdrA promoter, we show correlation between biofilm phenotype and c-di-GMP levels. Both proteins are shown to play a role in nitric oxide (NO) induced biofilm dispersal. We further studied pseudo-enzymes of similar architecture. PA5017 (DipA) is an inactive cyclase, and PA4959 (FimX) is described here as an inactive cyclase/phosphodiesterase. Loss of swimming and twitching motilities, respectively, is observed in deletion variants, which correlated with NO-induced biofilm dispersal phenotypes, as ΔdipA dispersed less well while ΔfimX dispersed better than wild type. The study highlights how Pseudomonas differentiates c-di-GMP output – in this case motility – using structurally very similar proteins and underlines a significant role for pseudo-enzymes in motility regulation and associated biofilm dispersal.ImportanceBacterial biofilms exert pervasive economic and societal impact across a range of environmental, engineered and clinical contexts. The secondary messenger cyclic guanosine di-phosphate, c-di-GMP, is known to control the ability of many bacteria to form biofilms. The opportunistic human pathogen Pseudomonas aeruginosa PAO1 has 38 putative enzymes that can regulate c-di-GMP turnover, and these proteins modulate various cellular functions and influence bacterial lifestyle. The specific protein sensory domains and mechanisms of motility that lead to biofilm dispersal remain to be fully understood. Here we studied multi-domain proteins with the PAS (Per-Arnt-Sim) homology domains, these being classic sensors to environmental stimuli. Our study demonstrates the significant roles for the pseudo-enzymes PA4959 (FimX) and PA5017 (DipA) in regulation of biofilm phenotype and motility. Further, enzymes with highly homologous structures, such as PA0861 (RbdA) and PA2072, have almost orthogonal function in biofilm and motility control.