Phase separation drives the folding of recombinant collagen

Abstract

Recombinantly produced collagens present a sustainable, ethical, and safe substitute for collagens derived from natural sources. However, controlling the folding of the recombinant collagens, crucial for replicating the mechanical properties of natural materials, remains a formidable task. Collagen-like proteins from willow sawfly are relatively small and contain no hydroxyprolines, presenting an attractive alternative to the large and post-translationally modified mammalian collagens. Utilizing CD spectroscopy and analytical ultracentrifugation, we demonstrate that recombinant willow sawfly collagen assembles into collagen triple helices in a concentration-dependent manner. Interestingly, we observed that the lower concentration threshold for the folding can be overcome by freezing or adding crowding agents. Microscopy data show that both freezing and the addition of crowding agents induce phase separation. We propose that the increase in local protein concentration during phase separation drives the nucleation-step of collagen folding. Finally, we show that freezing also induces the folding of recombinant human collagen fragments and accelerates the folding of natural bovine collagen, indicating the potential to apply phase separation as a universal mechanism to control the folding of recombinant collagens. We anticipate that the results provide a method to induce the nucleation of collagen folding without any requirements for genetic engineering or crosslinking.