However, the nature and genetic controls of the production of the

However, the nature and genetic controls of the production of these polymeric substances remain poorly understood. In this review different genes and proteins related to the production of EPS are addressed. EPS are an integral part of the survival strategy of the individual cells and well as the entire community (see Fig. 2 for a summary of such molecules and

their functions). In addition to surviving environmental fluctuations, microorganisms in nature also adopt social skills such as communication, organization, compartmentalization, competence and OSI-744 manufacturer defense (Earl et al., 2008). There are many levels of regulation for the production of EPS; some are specific, while others are general, but all are tightly regulated. For example, during the early stages of biofilm formation, only a subpopulation of cells express genes of the eps operon as well as the yqxM gene (involved in the proper localization of TasA) for the entire community (Chai et al., 2008). As the production of the EPS requires copious amounts of energy, regulatory controls are important. It has been proposed that B. subtilis biofilms can be viewed as a multicellular organism (Aguilar et al., 2007). When bacterial biofilms behave LDK378 solubility dmso as multicellular communities, they exhibit various degrees of compartmentalization. For example, during staphylococcal

biofilm formation, at least four distinct cellular states are represented: cells growing aerobically, cells growing fermentatively, dormant cells

and dead cells (Rani et al., 2007). In B. subtilis, motile cells transit to matrix-producing cells and ultimately to sporulating cells localized in distinct regions of the biofilm (Vlamakis et al., 2008). The exopolymeric matrix is shared by the different cells types and complementation of matrix components may take place among bacterial mutants (Branda et al., 2006; Chai et al., 2008). Interestingly, recent findings by López et al. (2009) suggest that the exopolymeric matrix does not serve only to hold different B. subtilis cell types together, but also acts as a timing mechanism. mafosfamide Once cells begin to produce an exopolymeric matrix as a result of surfactin signaling development, the surfactin production stops or is arrested (López et al., 2009). The concept of bacterial multicellularity within B. subtilis biofilms is likely to continue to develop novel insights. As pointed out above, the wide heterogeneity of B. subtilis wild-type strains used to characterize or study EPS (Table S1) and the lack of genetic information concerning such strains complicate understanding of the development, role and function of the exopolymeric matrix. Indeed, a future challenge is to focus studies on a single reference strain, for example B. subtilis strain 3610 as a model organism. The sequencing of its entire genome will be useful for comparisons with the genome of strain 168.

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