Linda L. McCarter scite author profile

Polar flagella of Vibrio species can rotate at speeds as high as 100,000 rpm and effectively propel the bacteria in liquid as fast as 60 μm/s. The sodium motive force powers rotation of the filament, which acts as a propeller. The filament is complex, composed of multiple subunits, and sheathed by an extension of the cell outer membrane. The regulatory circuitry controlling expression of the polar flagellar genes of members of the Vibrionaceae is different from the peritrichous system of enteric bacteria or the polar system of Caulobacter crescentus. The scheme of gene control is also pertinent to other members of the gamma purple bacteria, in particular to Pseudomonas species. This review uses the framework of the polar flagellar system of Vibrio parahaemolyticus to provide a synthesis of what is known about polar motility systems of the Vibrionaceae. In addition to its propulsive role, the single polar flagellum of V. parahaemolyticus is believed to act as a tactile sensor controlling surface-induced gene expression. Under conditions that impede rotation of the polar flagellum, an alternate, lateral flagellar motility system is induced that enables movement through viscous environments and over surfaces. Although the dual flagellar systems possess no shared structural components and although distinct type III secretion systems direct the simultaneous placement and assembly of polar and lateral organelles, movement is coordinated by shared chemotaxis machinery

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Flagellar dynamometer controls swarmer cell differentiation of V. parahaemolyticus

McCarter

Hilmen

Silverman

1988

Cell

265

278

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Dual Flagellar Systems Enable Motility under Different Circumstances

2004

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Flagella are extremely effective organelles of locomotion used by a variety of bacteria and archaea. Some bacteria, including Aeromonas, Azospirillum, Rhodospirillum, and Vibrio species, possess dual flagellar systems that are suited for movement under different circumstances. Swimming in liquid is promoted by a single polar flagellum. Swarming over surfaces or in viscous environments is enabled by the production of numerous peritrichous, or lateral, flagella. The polar flagellum is produced continuously, while the lateral flagella are produced under conditions that disable polar flagellar function. Thus at times, two types of flagellar organelles are assembled simultaneously. This review focuses on the polar and lateral flagellar systems of Vibrio parahaemolyticus. Approximately 50 polar and 40 lateral flagellar genes have been identified encoding distinct structural, motor, export/assembly, and regulatory elements. The sodium motive force drives polar flagellar rotation, and the proton motive force powers lateral translocation. Polar genes are found exclusively on the large chromosome, and lateral genes reside entirely on the small chromosome of the organism. The timing of gene expression corresponds to the temporal demand for components during assembly of the organelle: RpoN and lateral- and polar-specific σ⁵⁴-dependent transcription factors control early/intermediate gene transcription; lateral- and polar-specific σ²⁸ factors direct late flagellar gene expression. Although a different gene set encodes each flagellar system, the constituents of a central navigation system (i.e., chemotaxis signal transduction) are shared.

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Surface sensing in Vibrio parahaemolyticus triggers a programme of gene expression that promotes colonization and virulence

Gode-Potratz¹,

Kustusch

Breheny

et al. 2010

Molecular Microbiology

177

214

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SummaryVibrio parahaemolyticus senses surfaces via impeded rotation of its polar flagellum. We have exploited this surface-sensing mechanism to trick the organism into thinking it is on a surface when it is growing in liquid. This facilitated studies of global gene expression in a way that avoided many of the complications of surface-to-liquid comparisons, and illuminated~70 genes that respond to surface sensing per se. Almost all are surface-induced (not repressed) and encode swarming motility proteins, virulence factors or sensory enzymes involved with chemoreception and c-di-GMP signalling. Follow-up studies were performed to place the surfaceresponsive genes in a regulatory hierarchy. Mapping the hierarchy revealed two surprises about LafK, a transcriptional activator that until now has been considered to be the master regulator for the lateral flagellar system. First, LafK controls a more diverse set of genes than previously appreciated. Second, some laf genes are not under LafK control, which means LafK is not the master regulator after all. Additional experiments motivated by the transcriptome analyses revealed that growth on a surface lowers c-di-GMP levels and enhances cytotoxicity. Thus, we demonstrate that V. parahaemolyticus can invoke a programme of gene control upon encountering a surface and the specific identities of the surfaceresponsive genes are pertinent to colonization and pathogenesis.

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Genetic determinants of biofilm development of opaque and translucent Vibrio parahaemolyticus

Enos-Berlage

Güvener

Keenan

et al. 2005

Molecular Microbiology

207

193

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SummaryVibrio parahaemolyticus isolates display variation in colony morphology, alternating between opaque (OP) and translucent (TR) cell types. Phase variation is the consequence of genetic alterations in the locus encoding the quorum sensing output regulator OpaR. Here, we show that both cell types form stable, but distinguishable biofilms that differ with respect to attachment and detachment profiles to polystyrene, pellicle formation and stability at the air/medium interface, and submerged biofilm architecture and dispersion at a solid/liquid interface. The pellicle, which is a cohesive mat of cells, was exploited to identify mutants having altered or defective biofilm formation. Transposon insertion mutants were obtained with defects in genes affecting multiple cell surface characteristics, including extracellular polysaccharide, mannose-sensitive haemagglutinin type 4 pili and polar (but not lateral) flagella. Other insertions disrupted genes coding for potential secreted proteins or transporters of secreted proteins, specifically haemolysin co-regulated protein and an RTX toxin-like membrane fusion transporter, as well as potential modifiers of cell surface molecules ( nagAC operon). The pellicle screen also identified mutants with lesions in regulatory genes encoding H-NS, a CsgD-like repressor and an AraC-like protein. This work initiates the characterization of V. parahaemolyticus biofilm formation in the OP and TR cell types and identifies a diverse repertoire of cell surface elements that participate in determining multicellular architecture.

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Linda L. McCarter

Polar Flagellar Motility of the Vibrionaceae

Flagellar dynamometer controls swarmer cell differentiation of V. parahaemolyticus

Dual Flagellar Systems Enable Motility under Different Circumstances

Surface sensing in Vibrio parahaemolyticus triggers a programme of gene expression that promotes colonization and virulence

Genetic determinants of biofilm development of opaque and translucent Vibrio parahaemolyticus

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