Investigating the role of BN-domains of FlhF involved in flagellar synthesis in Campylobacter jejuni.

FlhF protein is critical for intact flagellar assembly in Campylobacter jejuni. It is a putative GTPase with B-, N- and G-domains. However, the role of the B- and N-domains in flagella biosynthesis remains unclear in C. jejuni. This study demonstrated that both the B- and N-domains are essential for flagellar synthesis, with the absence of B- and/or N-domains showing truncated variants of FlhF by TEM. Point mutations in the B- and N-domains (T13A, K159A, G231A) also induced flagella abnormalities. Furthermore, significant defects in GTPase activity and polar targeting of FlhF were triggered by point mutations of B- and N-domains. Flagella gene expression and transcription were also significantly disrupted in flhF(T13A), flhF(K159A) and flhF(G231A) strains. This study initially explored the effects of B- and N-domains on flagella synthesis. We speculated that B- and N-domains may directly or indirectly cause flagella abnormalities by affecting flagellar gene expression or GTPase activity, which helps us better understand the function of FlhF in flagella synthesis.

Investigating the Role of FlhF Identifies Novel Interactions With Genes Involved in Flagellar Synthesis in Campylobacter jejuni.

FlhF is a key protein required for complete flagellar synthesis, and its deletion results in the complete absence of a flagella and thus motility in Campylobacter jejuni. However, the specific mechanism still remains unknown. In this study, RNA-Seq, EMSAs, ChIP-qPCR and ß-Galactosidase assays were performed to elucidate the novel interactions between FlhF and genes involved in flagellar synthesis. Results showed that FlhF has an overall influence on the transcription of flagellar genes with an flhF mutant displaying down-regulation of most flagellar related genes. FlhF can directly bind to the flgI promoter to regulate its expression, which has significant expression change in an flhF mutant. The possible binding site of FlhF to the flgI promoter was explored by continuously narrowing the flgI promoter region and performing further point mutations. Meanwhile, FlhF can directly bind to the promoters of rpoD, flgS, and fliA encoding early flagellin regulators, thereby directly or indirectly regulating the synthesis of class I, II, and III flagellar genes, respectively. Collectively, this study demonstrates that FlhF may directly regulate the transcription of flagellar genes by binding to their promoters as a transcriptional regulator, which will be helpful in understanding the mechanism of FlhF in flagellar biosynthetic and bacterial flagellation in general.