Decoding Bacterial Motility: From Swimming States to Patterns and Chemotactic Strategies.

The bacterial flagellum serves as a crucial propulsion apparatus for motility and chemotaxis. Bacteria employ complex swimming patterns to perform essential biological tasks. These patterns involve transitions between distinct swimming states, driven by flagellar motor rotation, filament polymorphism, and variations in flagellar arrangement and configuration.

Live-Cell Imaging of the Assembly and Ejection Processes of the Bacterial Flagella by Fluorescence Microscopy.

Bacterial flagella are molecular machines used for motility and chemotaxis. The flagellum consists of a thin extracellular helical filament as a propeller, a short hook as a universal joint, and a basal body as a rotary motor. The filament is made up of more than 20,000 flagellin molecules and can grow to several micrometers long but only 20 nanometers thick.

Probing bacterial cell wall growth by tracing wall-anchored protein complexes.

The dynamic assembly of the cell wall is key to the maintenance of cell shape during bacterial growth. Here, we present a method for the analysis of Escherichia coli cell wall growth at high spatial and temporal resolution, which is achieved by tracing the movement of fluorescently labeled cell wall-anchored flagellar motors. Using this method, we clearly identify the active and inert zones of cell wall growth during bacterial elongation.

Construction and Loss of Bacterial Flagellar Filaments.

The bacterial flagellar filament is an extracellular tubular protein structure that acts as a propeller for bacterial swimming motility. It is connected to the membrane-anchored rotary bacterial flagellar motor through a short hook. The bacterial flagellar filament consists of approximately 20,000 flagellins and can be several micrometers long.

Live-cell fluorescence imaging reveals dynamic production and loss of bacterial flagella.

Bacterial flagella are nanomachines that drive bacteria motility and taxis in response to environmental changes. Whether flagella are permanent cell structures and, if not, the circumstances and timing of their production and loss during the bacterial life cycle remain poorly understood. Here we used the single polar flagellum of Vibrio alginolyticus as our model and implementing in vivo fluorescence imaging revealed that the percentage of flagellated bacteria (PFB) in a population varies substantially across different growth phases.

Frequent pauses in Escherichia coli flagella elongation revealed by single cell real-time fluorescence imaging.

The bacterial flagellum is a large extracellular protein organelle that extrudes from the cell surface. The flagellar filament is assembled from tens of thousands of flagellin subunits that are exported through the flagellar type III secretion system. Here, we measure the growth of Escherichia coli flagella in real time and find that, although the growth rate displays large variations at similar lengths, it decays on average as flagella lengthen.