Stretching of Bombyx mori Silk Protein in Flow

The flow-induced self-assembly of entangled Bombyx mori silk proteins is hypothesised to be aided by the 'registration' of aligned protein chains using intermolecularly interacting 'sticky' patches. This suggests that upon chain alignment, a hierarchical network forms that collectively stretches and induces nucleation in a precisely controlled way. Through the lens of polymer physics, we argue that if all chains would stretch to a similar extent, a clear correlation length of the stickers in the direction of the flow emerges, which may indeed favour such a registration effect. Through simulations in both extensional flow and shear, we show that there is, on the other hand, a very broad distribution of protein-chain stretch, which suggests the registration of proteins is not directly coupled to the applied strain, but may be a slow statistical process. This qualitative prediction seems to be consistent with the large strains (i.e., at long time scales) required to induce gelation in our rheological measurements under constant shear. We discuss our perspective of how the flow-induced self-assembly of silk may be addressed by new experiments and model development.

Automated summary

The flow-induced self-assembly of entangled Bombyx mori silk proteins is hypothesized to be aided by the registration of aligned protein chains using intermolecular interacting sticky patches. Despite a clear correlation length of the stickers in the direction of the flow, there is a very broad distribution of protein-chain stretch, suggesting the registration of proteins is not directly coupled to the applied strain but may be a slow statistical process. This qualitative prediction seems to be consistent with the large strains required to induce gelation in rheological measurements under constant shear in the long time scales.