Abstract
Spider silk is protein fibers with extraordinary mechanical properties. Up to now, it is still poorly understood how silk proteins are kept in a soluble form before spinning into fibers and how the protein molecules are aligned orderly to form fibers. Minor ampullate spidroin is one of the seven types of silk proteins, which consists of four types of domains: N-terminal domain, C-terminal domain (CTD), repetitive domain (RP) and linker domain (LK). Here we report the tertiary structure of CTD and secondary structures of RP and LK in aqueous solution, and their roles in protein stability, solubility and fiber formation. The stability and solubility of individual domains are dramatically different and can be explained by their distinct structures. For the tri-domain miniature fibroin, RP-LK-CTDMi, the three domains have no or weak interactions with one another at low protein concentrations (<1 mg/ml). The CTD in RP-LK-CTDMi is very stable and soluble, but it cannot stabilize the entire protein against chemical and thermal denaturation while it can keep the entire tri-domain in a highly water-soluble state. In the presence of shear force, protein aggregation is greatly accelerated and the aggregation rate is determined by the stability of folded domains and solubility of the disordered domains. Only the tri-domain RP-LK-CTDMi could form silk-like fibers, indicating that all three domains play distinct roles in fiber formation: LK as a nucleation site for assembly of protein molecules, RP for assistance of the assembly and CTD for regulating alignment of the assembled molecules.
Highlights
Spider silk is an ideal super material due to its extraordinary mechanical properties compared to other available materials [1,2,3]
Our results suggest that CTDMi and repetitive domain (RP)-LKMi play distinct roles in maintaining minor ampullate spidroin (MiSp) proteins in a highly water soluble form, i.e., RP-LKMi initiates the oligomerization through weak hydrophobic interactions among LKMi and RPMi domains and forms the core region of the oligomers, while CTDMi prevents MiSp from forming precipitate by staying outside the oligomer core
CTDMi, RPMi and LKMi have very distinct stability and solubility, which can be explained by their different structures, and each play specific roles in conferring the stable storage of MiSp fragments in vitro or full length MiSp in the silk gland
Summary
Spider silk is an ideal super material due to its extraordinary mechanical properties compared to other available materials [1,2,3]. Producing spider silk by recombinant biotechnology is one of the most promising alternatives [3,5,6,7] Before achieving this goal, one needs to understand the molecular structures, self-assembly mechanism and fiber formation of spider silk proteins, which are affected by solvent environment and shear and elongational forces [3]. Different from MaSp and MiSp, the repetitive units of aciniform and tubuliform silk proteins are complex and lack of the short motifs [11,12,13,14,15]. At present it is clear that the composition of the repetitive units varies from one type of silk protein to another, which is suggested to determine the mechanical properties of a given type of silk
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