Abstract
Web spiders synthesize silk fibers of unique strength and extensibility through the controlled self-assembly of protein building blocks, so-called spidroins. The spidroin C-terminal domain is highly conserved and connects two polypeptide chains through formation of an all-helical, intertwined dimer. Here we use contact-induced fluorescence self-quenching and resonance energy transfer in combination with far-UV circular dichroism spectroscopy as three orthogonal structural probes to dissect the mechanism of folding and dimerization of a spidroin C-terminal domain from the major ampullate gland of the nursery web spider Euprosthenops australis. We show that helices forming the dimer core assemble very rapidly and fold on association. Subsequently, peripheral helices fold and dock slowly onto the preformed core. Lability of outer helices facilitates formation of a highly expanded, partially folded dimer. The high end-to-end distance of chain termini in the partially folded dimer suggests an extensibility module that contributes to elasticity of spider silk.
Highlights
Web spiders synthesize silk fibers of unique strength and extensibility through the controlled self-assembly of protein building blocks, so-called spidroins
Spider silk is characterized by a unique combination of strength and extensibility, which results in toughness that supersedes that of man-made threads[2,3,4]
MaSp1 CTD from E. australis through heterologous overexpression in Escherichia coli bacterial cells followed by chromatographic purification
Summary
Web spiders synthesize silk fibers of unique strength and extensibility through the controlled self-assembly of protein building blocks, so-called spidroins. We use contact-induced fluorescence self-quenching and resonance energy transfer in combination with far-UV circular dichroism spectroscopy as three orthogonal structural probes to dissect the mechanism of folding and dimerization of a spidroin Cterminal domain from the major ampullate gland of the nursery web spider Euprosthenops australis. The N- and C-terminal domains (NTD and CTD) flank the repetitive core domain and are highly conserved across glands and species Conservation underscores their important functional roles in silk. Sequences from the pyriform and aggregate glands differ from those of other glands, which may reflect the fact that pyriform and aggregate silk has adhesive rather than fiber-forming function[5] Both NTD and CTD are regularly folded five-helix bundles that provide solubility and connectivity of spidroins[6,7,8]. Lability of peripheral helices facilitates formation of a highly expanded structure that may contribute to elasticity of spider silk
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