A biofilm, or a matrix-embedded community of cells, promotes the ability of the bacterium Vibrio fischeri to colonize its symbiotic host, the Hawaiian squid Euprymna scolopes. Biofilm formation and colonization depend on syp, an 18-gene polysaccharide locus. To identify other genes necessary for biofilm formation, we screened for mutants that failed to form wrinkled colonies, a type of biofilm. We obtained several with defects in genes required for cysteine metabolism, including cysH, cysJ, cysK, and cysN. The cysK mutant exhibited the most severe wrinkling defect. It could be complemented with a wild-type copy of the cysK gene, which encodes O-acetylserine sulfhydrolase, or by supplementing the medium with additional cysteine. None of a number of other mutants defective for biosynthetic genes negatively impacted wrinkled colony formation, suggesting a specific role for CysK. CysK did not appear to control activation of Syp regulators or transcription of the syp locus, but it did influence production of the Syp polysaccharide. Under biofilm-inducing conditions, the cysK mutant retained the same ability as that of the parent strain to adhere to the agar surface. The cysK mutant also exhibited a defect in pellicle production that could be complemented by the cysK gene but not by cysteine, suggesting that, under these conditions, CysK is important for more than the production of cysteine. Finally, our data reveal a role for cysK in symbiotic colonization by V. fischeri. Although many questions remain, this work provides insights into additional factors required for biofilm formation and colonization by V. fischeri.
The ability of bacteria to grow in biofilms, or communities of cells embedded in a surface-associated, self-produced matrix, permits them to survive environmental assaults and colonize a variety of biotic and abiotic surfaces (1, 2). The biofilm matrix typically contains polysaccharides, proteins, and environmental DNA (eDNA), which together provide a protected environment and permit adherence to surfaces. Production of a biofilm depends on the ability of bacteria to recognize and respond to appropriate environmental cues and produce and export a variety of substances that are assembled to permit a three-dimensional (3D) community architecture from which bacteria can ultimately depart.The complex nature of this process is apparent from the study of numerous bacteria, including the facultative symbiont Vibrio fischeri. This marine microbe forms a transient biofilm on the surface of a specialized organ of its host, the squid Euprymna scolopes (3). V. fischeri cells disperse from this transient biofilm to migrate into pores leading to the internal sites where they multiply to a high cell density and establish a long-term association with the squid (reviewed in reference 4). Mutants defective for the production of this transient biofilm fail to efficiently colonize their squid host (5-8).Some components of the V. fischeri matrix have been identified (Fig. 1). Notably, the 18-gene symbiosis polysaccharide loc...
