Domain-swap polymerization drives the self-assembly of the bacterial flagellar motor.

Large protein complexes assemble spontaneously, yet their subunits do not prematurely form unwanted aggregates. This paradox is epitomized in the bacterial flagellar motor, a sophisticated rotary motor and sensory switch consisting of hundreds of subunits. Here we demonstrate that Escherichia coli FliG, one of the earliest-assembling flagellar motor proteins, forms ordered ring structures via domain-swap polymerization, which in other proteins has been associated with uncontrolled and deleterious protein aggregation. Solution structural data, in combination with in vivo biochemical cross-linking experiments and evolutionary covariance analysis, revealed that FliG exists predominantly as a monomer in solution but only as domain-swapped polymers in assembled flagellar motors. We propose a general structural and thermodynamic model for self-assembly, in which a structural template controls assembly and shapes polymer formation into rings.

Backbone and sidechain (1)H, (13)C and (15)N chemical shift assignments of the hydrophobin MPG1 from the rice blast fungus Magnaporthe oryzae.

Fungal hydrophobins are secreted proteins that self-assemble at hydrophobic:hydrophilic interfaces. They are essential for a variety of processes in the fungal life cycle, including mediating interactions with surfaces and infection of hosts. The fungus Magnaporthe oryzae, the causative agent of rice blast, relies on the unique properties of hydrophobins to infect cultivated rice as well as over 50 different grass species. The hydrophobin MPG1 is highly expressed during rice blast pathogenesis and has been implicated during host infection. Here we report the backbone and sidechain assignments for the class I hydrophobin MPG1 from the rice blast fungus Magnaporthe oryzae.

Surface functionalization of carbon nanomaterials by self-assembling hydrophobin proteins.

Class I fungal hydrophobins are small surface-active proteins that self-assemble to form amphipathic monolayers composed of amyloid-like rodlets. The monolayers are extremely robust and can adsorb onto both hydrophobic and hydrophilic surfaces to reverse their wettability. This adherence is particularly strong for hydrophobic materials. In this report, we show that the class I hydrophobins EAS and HYD3 can self-assemble to form a single-molecule thick coating on a range of nanomaterials, including single-walled carbon nanotubes (SWCNTs), graphene sheets, highly oriented pyrolytic graphite, and mica. Moreover, coating by class I hydrophobin results in a stable, dispersed preparation of SWCNTs in aqueous solutions. No cytotoxicity is detected when hydrophobin or hydrophobin-coated SWCNTs are incubated with Caco-2 cells in vitro. In addition, we are able to specifically introduce covalently linked chemical moieties to the hydrophilic side of the rodlet monolayer. Hence, class I hydrophobins provide a simple and effective strategy for controlling the surfaces of a range of materials at a molecular level and exhibit strong potential for biomedical applications.