In this study, knock-out mutations in rcsB and ompR yielded an impressive increase in flhD expression in the ompR and rcsB mutants (Figures 2 and 4). Additionally, expression of CBL0137 cost flhD was not anymore dependent upon the biofilm phase, after the biofilm had formed (Figure 2) or the location of the individual bacterium within the biofilm (Figure 4). The temporal expression profile of flhD in the ompR mutant is similar to the one that was observed previously in planktonic bacteria [29]. However, in planktonic bacteria, we never observed more than 2 or 3 fold increases in flhD expression
in the ompR mutant, relative to the parent. Considering the fact that the images for flhD in the ompR mutant had been obtained
at a much reduced excitation intensity (10% versus 90% in the parent strain), the difference in flhD expression between the two strains must be much higher in biofilm than in planktonic see more bacteria. Intriguingly, the ompR and rcsB mutants are also our first two mechanisms to reduce biofilm amounts by elevating the expression levels of FlhD/FlhC. This observation provides confidence in our conclusion that impacting the signal transduction cascade, consisting of multiple two-component response regulators and FlhD/FlhC can be used to control biofilm amounts. Since the number of two-component systems in E. coli is rather large [28] and response regulators respond to a broad range of environmental signals, the two-component signal transduction mechanism offers ample opportunity at controlling bacterial phenotypes and behaviors by deliberately changing the bacterial environment. Conclusions The bacterial species E. coli includes many pathogens, in particular biofilm formation [52, 53] and prevention [54] in uropathogenic E. coli (UPEC) have been researched
intensively over the past few years. PLEKHM2 The goal of this study was to use an E. coli K-12 strain as a model to show that the study of temporal and spatial gene expression can lead to the identification of targets for the development of novel biofilm prevention and treatment options. We propose FlhD/FlhC as the first of such targets and OmpR and RcsB as two mechanisms to control this target. Our intention is to identify more of these targets/target mechanisms, using the temporal/spatial gene expression approach on a selection of biofilm associated genes. With respect to FlhD/FlhC, we believe that a gene that is this highly regulated by so many environmental and genetic factors is ideally suited to be controlled by deliberate changes to the environment, through a signal transduction cascade that may involve additional two-component response regulators beyond OmpR and RcsB, ultimately impacting biofilm amounts.