Characterisation of the structure and function of the Salmonella flagellar export gate protein, FlhB

Bergen, Paul Michael

January 2017

Flagella, the helical propellers that extend from the bacterial cell surface, illustrate how complex nanomachines assemble outside the cell. The sequential construction of the flagellar rod, hook, and filament requires export of thousands of structural subunits across the cell membrane and this is achieved by a specialised flagellar Type III Secretion System (fT3SS) located at the base of each flagellum. The fT3SS imposes a crude ordering of subunits, with filament subunits only exported once the rod and hook are complete. This “export specificity switch” is controlled by the FlhB component of the fT3SS export gate in response to a signal from the exported molecular ruler FliK, which monitors the length of the growing hook. This study seeks to clarify how rod and hook subunits interact with FlhB, and how FlhB switches export specificity. Rod and hook subunits possess a conserved gate recognition motif (GRM; Fxxxφ, with φ being any hydrophobic residue) that is proposed to bind a surface-exposed hydrophobic patch on the FlhB cytosolic domain. Mutation of the GRM phenylalanine and the final hydrophobic residue resulted in impaired subunit export and decreased cell motility. Isothermal titration calorimetry was performed to assess whether subunit export order is imposed at FlhB. These experiments showed that rod and hook subunits bind to FlhB with micromolar dissociation constants (5-45 μM), suggesting transient interactions. There was no clear correlation between subunit affinity for FlhB and the order of subunit assembly in the nascent flagellum. Solution-state nuclear magnetic resonance (NMR) spectroscopy supported prior data showing that rod and hook subunits interact with FlhB’s surface-exposed hydrophobic patch. NMR also indicated that residues away from the patch undergo a conformational change on subunit binding. FlhB autocleaves rapidly in its cytosolic domain, and the resulting polypeptides (FlhBCN and FlhBCC) are held together by non-covalent interactions between b-strands that encompass the autocleavage site. The autocleavage event is a prerequisite for the export specificity switch, but its function is unclear. Analysis of the cellular localization of FlhBCN and FlhBCC revealed that FlhBCC dissociated from the membrane export machinery, but only in the presence of FliK. Biochemical and biophysical studies of FlhB variants that undergo export specificity switching in the absence of FliK showed that these FlhB “autonomous switchers” were less stable than wildtype FlhB and their FlhBCC domain could dissociate from the export machinery in the absence of FliK. The results suggest that the export specificity switch involves a FliK-dependent loss of FlhBCC from the export machinery, eliminating the binding site for rod and hook subunits.

616.9

Caractérisation fonctionnelle de BamB, protéine impliquée dans la biogénèse de la membrane externe et la virulence de Salmonella / Functional caracterization of BamB, a protein involved in outer-membrane biogenesis and Salmonella virulence

Namdari, Fatémeh

26 March 2013

La protéine BamB est une lipoprotéine de membrane externe appartenant au complexe BAM (β-Barrel Assembly Machinery) et impliquée dans l’assemblage des protéines de membrane externe (PME), la sensibilité aux antibiotiques, le contrôle de l’expression des trois systèmes de sécrétion de type III (T3SS) et la virulence de Salmonella. Chez E. coli, au sein du complexe BAM, elle interagit directement avec la protéine BamA. De plus, chez cette bactérie, BamB présente une activité sérine-thréonine kinase. Afin de mieux caractériser le rôle de BamB, nos objectifs ont été d’étudier (1) l’impact de l’altération de l’interaction de BamB avec le complexe BAM ou de sa séquestration dans le cytoplasme sur l’ensemble des rôles décrits de BamB et (2) l’activité kinase putative de BamB chez Salmonella. Nos résultats montrent que certains rôles de BamB sont dissociables entre eux et que l’interaction BamA/BamB n’est pas requise pour le rôle de BamB dans le contrôle de l’expression des T3SS, la virulence de Salmonella et l’assemblage des PME à la membrane externe. Aucune activité kinase ni aucune activité cytoplasmique de la protéine n’a pu être formellement démontrée. / BamB is an outer-membrane lipoprotein belonging to the BAM complex (β-Barrel Assembly Machinery). In Salmonella, it is involved in the assembly of outer membrane proteins (OMP), in antibiotic susceptibility, in the transcriptional control of the three Type-Three-Secretion-Systems (T3SS) related genes and also in virulence. In E. coli, BamB interacts directly with the BamA protein. Moreover, BamB has been shown to have a serine-threonin kinase activity in this bacterium. In order to better characterize the roles of the BamB protein, our purposes were to study (1) the impact of the alteration of the interaction of BamB with the BAM complex or of its cytoplasmic sequestration and (2) its putative kinase activity in Salmonella. Our results show that some of the BamB roles are dissociable and that the BamA/BamB interaction is not required for T3SS expression, Salmonella virulence or OMP assembly in the outer membrane. Currently, neither a kinase activity nor a cytoplasmic activity has been clearly demonstrated for this protein.

Salmonella

BamB

Complexe BAM

Biogénèse de la membrane externe

Protéines de membrane externe (PME)

Virulence

Salmonella

BamB

BAM complex

Outer-membrane biogenesis

Outer membrane proteins (OMP)

Type III-secretion systems (T3SS)

Virulence