Biofilm Formation by Campylobacter jejuni Is Increased under Aerobic Conditions

The microaerophilic human pathogen Campylobacter jejuni is the leading cause of food-borne bacterial gastroenteritis in the developed world. During transmission through the food chain and the environment, the organism must survive stressful environmental conditions, particularly high oxygen levels. Biofilm formation has been suggested to play a role in the environmental survival of this organism. In this work we show that C. jejuni NCTC 11168 biofilms developed more rapidly under environmental and food-chain-relevant aerobic conditions (20% O₂) than under microaerobic conditions (5% O₂, 10% CO₂), although final levels of biofilms were comparable after 3 days. Staining of biofilms with Congo red gave results similar to those obtained with the commonly used crystal violet staining. The level of biofilm formation by nonmotile aflagellate strains was lower than that observed for the motile flagellated strain but nonetheless increased under aerobic conditions, suggesting the presence of flagellum-dependent and flagellum-independent mechanisms of biofilm formation in C. jejuni. Moreover, preformed biofilms shed high numbers of viable C. jejuni cells into the culture supernatant independently of the oxygen concentration, suggesting a continuous passive release of cells into the medium rather than a condition-specific active mechanism of dispersal. We conclude that under aerobic or stressful conditions, C. jejuni adapts to a biofilm lifestyle, allowing survival under detrimental conditions, and that such a biofilm can function as a reservoir of viable planktonic cells. The increased level of biofilm formation under aerobic conditions is likely to be an adaptation contributing to the zoonotic lifestyle of C. jejuni.Infection with Campylobacter jejuni is the leading cause of food-borne bacterial gastroenteritis in the developed world and is often associated with the consumption of undercooked poultry products (19). The United Kingdom Health Protection Agency reported more than 45,000 laboratory-confirmed cases for England and Wales in 2006 alone, although this is thought to be a 5- to 10-fold underestimation of the total number of community incidents (20, 43). The symptoms associated with C. jejuni infection usually last between 2 and 5 days and include diarrhea, vomiting, and stomach pains. Sequelae of C. jejuni infection include more-serious autoimmune diseases, such as Guillain-Barré syndrome, Miller-Fisher syndrome (18), and reactive arthritis (15).Poultry represents a major natural reservoir for C. jejuni, since the organism is usually considered to be a commensal and can reach densities as high as 1 × 10⁸ CFU g of cecal contents⁻¹ (35). As a result, large numbers of bacteria are shed via feces into the environment, and consequently, C. jejuni can spread rapidly through a flock of birds in a broiler house (1). While well adapted to life in the avian host, C. jejuni must survive during transit between hosts and on food products under stressful storage conditions, including high and low temperatures and atmospheric oxygen levels. The organism must therefore have mechanisms to protect itself from unfavorable conditions.Biofilm formation is a well-characterized bacterial mode of growth and survival, where the surface-attached and matrix-encased bacteria are protected from stressful environmental conditions, such as UV radiation, predation, and desiccation (7, 8, 28). Bacteria in biofilms are also known to be >1,000-fold more resistant to disinfectants and antimicrobials than their planktonic counterparts (11). Several reports have now shown that Campylobacter species are capable of forming a monospecies biofilm (21, 22) and can colonize a preexisting biofilm (14). Biofilm formation can be demonstrated under laboratory conditions, and environmental biofilms, from poultry-rearing facilities, have been shown to contain Campylobacter (5, 32, 44). Campylobacter biofilms allow the organism to survive up to twice as long under atmospheric conditions (2, 21) and in water systems (27).Molecular understanding of biofilm formation by Campylobacter is still in its infancy, although there is evidence for the role of flagella and gene regulation in biofilm formation. Indeed, a flaAB mutant shows reduced biofilm formation (34); mutants defective in flagellar modification (cj1337) and assembly (fliS) are defective in adhering to glass surfaces (21); and a proteomic study of biofilm-grown cells shows increased levels of motility-associated proteins, including FlaA, FlaB, FliD, FlgG, and FlgG2 (22). Flagella are also implicated in adhesion and in biofilm formation and development in other bacterial species, including Aeromonas, Vibrio, Yersinia, and Pseudomonas species (3, 23, 24, 31, 42).Previous studies of Campylobacter biofilms have focused mostly on biofilm formation under standard microaerobic laboratory conditions. In this work we have examined the formation of biofilms by motile and nonmotile C. jejuni strains under atmospheric conditions that are relevant to the survival of this organism in a commercial context of environmental and food-based transmission.