Abstract
The parallel βhelix is a common fold among extracellular proteins, however its mechanical properties remain unexplored. In Gram-negative bacteria, extracellular proteins of diverse functions of the large ‘TpsA’ family all fold into long βhelices. Here, single-molecule atomic force microscopy and steered molecular dynamics simulations were combined to investigate the mechanical properties of a prototypic TpsA protein, FHA, the major adhesin of Bordetella pertussis. Strong extension forces were required to fully unfold this highly repetitive protein, and unfolding occurred along a stepwise, hierarchical process. Our analyses showed that the extremities of the βhelix unfold early, while central regions of the helix are more resistant to mechanical unfolding. In particular, a mechanically resistant subdomain conserved among TpsA proteins and critical for secretion was identified. This nucleus harbors structural elements packed against the βhelix that might contribute to stabilizing the N-terminal region of FHA. Hierarchical unfolding of the βhelix in response to a mechanical stress may maintain β-helical portions that can serve as templates for regaining the native structure after stress. The mechanical properties uncovered here might apply to many proteins with β-helical or related folds, both in prokaryotes and in eukaryotes, and play key roles in their structural integrity and functions.
Highlights
The specific functions of extracellular proteins impose constraints on their structural properties
Because the Two-Partner secretion (TPS) domain is essential for secretion, only N-terminal Filamentous haemagglutinin (FHA) derivatives with the TPS domain can be prepared in a native form
Mechanical resistance is important for extracellular proteins involved in interactions with other organisms or with organic or inorganic surfaces
Summary
The specific functions of extracellular proteins impose constraints on their structural properties. Extracellular proteins have evolved to withstand various forms of stress in order to maintain function in non-controllable conditions. Those proteins adopt folds that are compatible with their transport across membranes. Those constraints probably account for the large proportion of repetitive extracellular proteins. Bhelices are such repetitive proteins, composed of coils formed of three short, amphipathic bstrands connected by variable-length turn regions [1,2,3]. The bhelix and related solenoid folds – e.g. beta rolls, leucine-rich repeat proteins and spiral folds - have been adopted throughout the phylogenetic tree, from microbial and phage proteins to insulin-like growth factor receptors in higher eukaryotes and antifreeze proteins in insects [1,2]
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