The mechanisms by which environmental carbon sources regulate biofilm formation are poorly understood. This study investigates the roles of glucose and the catabolite repression system in Serratia marcescens biofilm formation. The abilities of this opportunistic pathogen to proliferate in a wide range of environments, to cause disease, and to resist antimicrobials are linked to its ability to form biofilms. We observed that growth of S. marcescens in glucose-rich medium strongly stimulated biofilm formation, which contrasts with previous studies showing that biofilm formation is inhibited by glucose in Escherichia coli and other enteric bacteria. Glucose uptake is known to inversely mediate intracellular cyclic AMP (cAMP) synthesis through regulation of adenylate cyclase (cyaA) activity, which in turn controls fundamental processes such as motility, carbon utilization and storage, pathogenesis, and cell division in many bacteria. Here, we demonstrate that mutation of catabolite repression genes that regulate cAMP levels (crr and cyaA) or the ability to respond to cAMP (crp) confers a large increase in biofilm formation. Suppressor analysis revealed that phenotypes of a cAMP receptor protein (crp) mutant require the fimABCD operon, which is responsible for type 1 fimbria production. Consistently, fimA transcription and fimbria production were determined to be upregulated in a cyaA mutant background by using quantitative real-time reverse transcription-PCR and transmission electron microscopy analysis. The regulatory pathway by which environmental carbon sources influence cAMP concentrations to alter production of type 1 fimbrial adhesins establishes a novel mechanism by which bacteria control biofilm development.Serratia marcescens is a ubiquitous gram-negative bacterium capable of causing disease in diverse organisms, including humans, coral, insects, and plants (2,11,43,44,52). The abilities of S. marcescens to cause nosocomial infections and survive in the environment are attributed to its ability to form biofilms, its broad metabolic capacity, and its high natural resistance to antimicrobials and cleaning agents (18,21,28,47). Biofilms are surface-attached microbial communities that afford resistance to biocides and antibiotics and are commonly involved in medical-device-associated infections (14,20,37).S. marcescens readily adheres to diverse substrates, such as contact lenses and epithelial cells (23). Such interactions can be mediated through type 1 fimbriae; these large surface pili are important virulence factors in many bacteria (29). Fimbriae are versatile adhesins capable of mediating attachment to eukaryotic cell surfaces, interactions with biotic and abiotic substrates, and bacterium-bacterium interactions (4,11,27,29,41,46,58,65). Previous studies of S. marcescens have indicated that biofilms are regulated by quorum sensing, require type 1 fimbriae, and differ in morphology with respect to carbon and nitrogen sources (31, 58). However, little is known about the regulation of S. marcescens biofilm f...
