Aggregation and self-assembly of hydrophobins from Trichoderma reesei: low-resolution structural models.

Hydrophobins are secreted fungal proteins, which have diverse roles in fungal growth and development. They lower the surface tension of water, work as adhesive agents and coatings, and function through self-assembly. One of the characteristic properties of hydrophobins is their tendency to form fibrillar or rod-like aggregates at interfaces. Their structure is still poorly known. In a step to elucidate the structure/function relation of hydrophobin self-assembly, we present the low-resolution structure of self-assembled fibrils of the class II hydrophobin HFBII from Trichoderma reesei based on small and wide-angle x-ray scattering. We first studied the solution state (10 mg/mL) of both HFBI and HFBII and showed that they formed assemblages in aqueous solution, which have a radius of gyration of ~24 A and maximum dimension of ~65 A, corresponding to the size of a tetramer. This result was supported by size-exclusion chromatography. Undried samples of HFBII fibrils had a monoclinic crystalline structure, which changed to hexagonal when the material was dried. A low-resolution structure for the HFBII fibrils is suggested. There are data in the literature based on staining properties suggesting that hydrophobins of class I form assemblies with an amyloid structure. Comparison of the HFBII data (x-ray results, staining with thioflavin T) to published data showed that the HFBII assemblages are not amyloid.

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