Mutations in the flhD gene of Escherichia coli K-12 do not cause the reported effect on cell division

Comprehensive mapping of the Escherichia coli flagellar regulatory network

Flagellar synthesis is a highly regulated process in all motile bacteria. In Escherichia coli and related species, the transcription factor FlhDC is the master regulator of a multi-tiered transcription network. FlhDC activates transcription of a number of genes, including some flagellar genes and the gene encoding the alternative Sigma factor FliA. Genes whose expression is required late in flagellar assembly are primarily transcribed by FliA, imparting temporal regulation of transcription and coupling expression to flagellar assembly. In this study, we use ChIP-seq and RNA-seq to comprehensively map the E. coli FlhDC and FliA regulons. We define a surprisingly restricted FlhDC regulon, including two novel regulated targets and two binding sites not associated with detectable regulation of surrounding genes. In contrast, we greatly expand the known FliA regulon. Surprisingly, 30 of the 52 FliA binding sites are located inside genes. Two of these intragenic promoters are associated with detectable noncoding RNAs, while the others either produce highly unstable RNAs or are inactive under these conditions. Together, our data redefine the E. coli flagellar regulatory network, and provide new insight into the temporal orchestration of gene expression that coordinates the flagellar assembly process.

Flagella are surface-associated appendages that propel bacteria and are involved in diverse functions such as chemotaxis, surface attachment, and host cell invasion. Flagella are incredibly complex macromolecular machines that are energetically costly to produce, assemble, and power. Flagellar production is tightly regulated and flagellar components are only synthesized when flagellar motility is advantageous. Regulation also ensures that flagellar components are produced in roughly the same order in which they are needed, increasing efficiency of the assembly process. The transcriptional regulation of flagellar genes has been studied extensively in the model organism Escherichia coli; however, many questions remain. We have used an unbiased, genome-wide approach to comprehensively identify all of the binding sites and regulatory targets for the two key regulators of flagellar synthesis, FlhDC and FliA. Our results redefine the flagellar regulatory network, and suggest that FliA binds many sites that are not associated with productive transcription. This work is important because it suggests possible new functions for FliA outside of the transcription of canonical mRNAs, and it provides new insight into the temporal orchestration of gene expression that coordinates the flagellar assembly process.

FlgM as a secretion moiety for the development of an inducible type III secretion system

Regulation and assembly of the flagellar type III secretion system is one of the most investigated and best understood regulational cascades in molecular biology. Depending on the host organism, flagellar morphogenesis requires the interplay of more than 50 genes. Direct secretion of heterologous proteins to the supernatant is appealing due to protection against cellular proteases and simplified downstream processing. As Escherichia coli currently remains the predominant host organism used for recombinant prokaryotic protein expression, the generation of a strain that exhibits inducible flagellar secretion would be highly desirable for biotechnological applications.

Here, we report the first engineered Escherichia coli mutant strain featuring flagellar morphogenesis upon addition of an external inducer. Using FlgM as a sensor for direct secretion in combination with this novel strain may represent a potent tool for significant improvements in future engineering of an inducible type III secretion for heterologous proteins.