Spider dragline silk possesses impressive mechanical and biochemical properties. It is synthesized by a couple of major ampullate glands in spiders and comprises of two major structural proteins--spidroins 1 and 2. The relationship between structure and mechanical properties of spider silk is not well understood. Here, we modeled the complete process of the spider silk assembly using two new recombinant analogs of spidroins 1 and 2. The artificial genes sequence of the hydrophobic core regions of spidroin 1 and 2 have been designed using computer analysis of existing databases and mathematical modeling. Both proteins were expressed in Pichia pastoris and purified using a cation exchange chromatography. Despite the absence of hydrophilic N- and C-termini, both purified proteins spontaneously formed the nanofibrils and round micelles of about 1 microm in aqueous solutions. The electron microscopy study has revealed the helical structure of a nanofibril with a repeating motif of 40 nm. Using the electrospinning, the thin films with an antiparallel beta-sheet structure were produced. In summary, we were able to obtain artificial structures with characteristics that are perspective for further biomedical applications, such as producing three-dimensional matrices for tissue engineering and drug delivery.
The goal of this study was to generate porous scaffolds from the genetically engineered protein, an analogue of Nephila clavipes spidroin 1 (rS1/9) and to assess the properties of new rS1/9 scaffolds essential for bioengineering. The salt leaching technique was used to make the rS1/9 scaffolds of interconnected macroporous structure with spontaneously formed micropores. The tensile strength of scaffolds was 18 ± 5 N/cm(2). Scaffolds were relatively stable in a phosphate buffer but degraded in oxidizing environment after 11 weeks of incubation. Applicability of the recombinant spidroin 1 as a substrate for cell culture was demonstrated by successful 3T3 cells growth on the surface of rS1/9 films (270 ± 20 cells/mm(2) vs. 97 ± 8 cells/mm(2) on the glass surface, p < 0.01). The 3T3 fibroblasts readily proliferated within the rS1/9 scaffold (from initially plated 19 ± 2 cells/mm(3) to 3800 ± 304 cells/mm(3) after 2 weeks). By this time, cells were uniformly distributed between the surface and deeper layers (27% ± 8% and 33% ± 4%, respectively; p > 0.05), whereas the initial distribution was 58% ± 7% and 11% ± 8%, respectively; p < 0.05). The rS1/9 scaffolds implanted subcutaneously into Balb/c mice were well tolerated. Over a 2-month period, the scaffolds promoted an ingrowth of de novo formed vascularized connective tissue elements and nerve fibers. Thus, scaffolds made of the novel recombinant spidroin 1 analogue are potentially applicable in tissue engineering.
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