FliZ Is a posttranslational activator of FlhD4C2-dependent flagellar gene expression

Flagellar assembly proceeds in a sequential manner, beginning at the base and concluding with the filament. A critical aspect of assembly is that gene expression is coupled to assembly. When cells transition from a nonflagellated to a flagellated state, gene expression is sequential, reflecting the manner in which the flagellum is made. A key mechanism for establishing this temporal hierarchy is the sigma(28)-FlgM checkpoint, which couples the expression of late flagellar (P(class3)) genes to the completion of the hook-basal body. In this work, we investigated the role of FliZ in coupling middle flagellar (P(class2)) gene expression to assembly in Salmonella enterica serovar Typhimurium. We demonstrate that FliZ is an FlhD(4)C(2)-dependent activator of P(class2)/middle gene expression. Our results suggest that FliZ regulates the concentration of FlhD(4)C(2) posttranslationally. We also demonstrate that FliZ functions independently of the flagellum-specific sigma factor sigma(28) and the filament-cap chaperone/FlhD(4)C(2) inhibitor FliT. Furthermore, we show that the previously described ability of sigma(28) to activate P(class2)/middle gene expression is, in fact, due to FliZ, as both are expressed from the same overlapping P(class2) and P(class3) promoters at the fliAZY locus. We conclude by discussing the role of FliZ regulation with respect to flagellar biosynthesis based on our characterization of gene expression and FliZ's role in swimming and swarming motility.     

The Multifunctional Protein YdiV Represses P Fimbria-Mediated Adherence in Uropathogenic Escherichia coli

YdiV, a degenerate EAL domain protein, represses motility by interacting with FlhD to abolish FlhDC interaction with DNA. Here, we demonstrate that deletion of ydiV dysregulates coordinate control of motility and adherence by increasing adherence of Escherichia coli CFT073 to a bladder epithelial cell line by specifically increasing production of P fimbriae. Interestingly, only one of the two P fimbrial operons, pap_2, present in the genome of E. coli CFT073 was upregulated. This derepression of the pap_2 operon is abolished following deletion of either cya or crp, demonstrating cyclic AMP (cAMP)-dependent activation of the P fimbrial operon. However, the absence of YdiV does not affect the gene expression of cya and crp, and loss of SdiA in the ydiV mutant does not affect the derepression of the pap_2 operon, suggesting that YdiV control of adherence acts in response to cAMP levels. Deletion of ydiV increases motility by increasing expression of fliA, suggesting that in E. coli CFT073, YdiV regulates motility by the same mechanism as that described previously for commensal E. coli strains. Furthermore, analysis of site-directed mutations found two putative Mg²⁺-binding residues of four conserved YdiV residues (E29 and Q219) that were involved in regulation of motility and FliC production, while two conserved c-di-GMP-binding residues (D156 and D165) only affected motility. None of the four conserved YdiV residues appeared to affect regulation of adherence. Therefore, we propose a model in which a degenerate EAL, YdiV, utilizes different domains to regulate motility through interaction with FlhD and adherence to epithelial cells through cAMP-dependent effects on the pap_2 promoter.     

A novel gene involved in regulating the flagellar gene cascade in Proteus mirabilis

In this study, we identified a transposon insertion in a novel gene, designated disA, that restored swarming motility to a putrescine-deficient speA mutant of Proteus mirabilis. A null allele in disA also increased swarming in a wild-type background. The DisA gene product was homologous to amino acid decarboxylases, and its role in regulating swarming was investigated by examining the expression of genes in the flagellar cascade. In a disA mutant background, we observed a 1.4-fold increase in the expression of flhDC, which encodes FlhD(2)C(2), the master regulator of the flagellar gene cascade. However, the expressions of class 2 (fliA, flgM) and class 3 (flaA) genes were at least 16-fold higher in the disA background during swarmer cell differentiation. Overexpression of DisA on a high-copy-number plasmid did not significantly decrease flhDC mRNA accumulation but resulted in a complete block in mRNA accumulation for both fliA and flaA. DisA overexpression also blocked swarmer cell differentiation. The disA gene was regulated during the swarming cycle, and a single-copy disA::lacZ fusion exhibited a threefold increase in expression in swarmer cells. Given that DisA was similar to amino acid decarboxylases, a panel of decarboxylated amino acids was tested for effects similar to DisA overexpression, and phenethylamine, the product of phenylalanine decarboxylation, was capable of inhibiting both swarming and the expression of class 2 and class 3 genes in the flagellar regulon. A DisA-dependent decarboxylated amino acid may inhibit the formation of active FlhD(2)C(2) heterotetramers or inhibit FlhD(2)C(2) binding to DNA.