Life has evolved diverse protein machines and bacteria provide many fascinating examples. Despite being unicellular organisms of relatively small size, bacteria produce sophisticated nanomachines with a high degree of self-organization. The motility organelle of bacteria, the flagellum, is a prime example of complex bacterial nanomachines. Flagella are by far the most prominent extracellular structures known in bacteria and made through self-assembly of several dozen different kinds of proteins and thus represents an ideal model system to study sub-cellular compartmentalization and self-organization.
The flagellum can function as a macromolecular motility machine only if its many building blocks assemble in a coordinated manner. However, previous studies have focused on phenotypic and genetic analyses, or the characterization of isolated sub-components. Crucially, how bacteria orchestrate the many different cellular processes in time and space in order to construct a functional motility organelle remains enigmatic. Therefore, the major research aims of the project BacNanoMachine are to understand:
Aim 1: How is the hierarchical gene expression coupled to the assembly of multiple flagella?
Aim 2: What is the minimal genetic regulation required for assembly and function of the flagellum?
Aim 3: How are the flagellar building blocks targeted to the site of assembly?
Aim 4: How is robust protein secretion achieved in the presence of large cellular noise?