[Expression of oleosin-rhFGF9 fusion protein in Carthamus tinctorius and determination of hair regeneration and wound repair potential in mice].

The expression of fibroblast growth factor 9 (FGF9) recombinant fusion protein in Carthamus tinctorius was used to identify its effect on hair regrowth and wound repair system in mice, providing a basis for C. tinctorius as a plant bioreactor, and establishing a foundation for commercial applications of FGF9 fusion protein in hair regrowth and wound repair. The identified pOTBar-oleosin-rhFGF9 plasmid was transformed into Agrobacterium tumefaciens EHA105 by freeze-thaw method, and the oleosin-rhFGF9 gene was transformed into safflower leaves by A. tumefaciens mediated method. Transgenic safflower seedlings were then obtained by tissue culture. After basta screening, transgenic T3 safflower seeds were obtained by grafting method, PCR verification and propagation. The expression of oleosin-rhFGF9 was detected by Western blot, and the content of oleosin-rhFGF9 fusion protein was 0.09% by using ELISA quantitative method. It was observed that 60 µg·L⁻¹ transgenic safflower oil had better effect on promoting NIH/3T3 cells proliferation in a certain dose-dependent manner. Sixty C57BL/6 mice were used to establish alopecia model and wound model respectively, and then were randomly divided into control group (treated with PBS or saline), negative group (treated with wild type safflower seed oil bodies, 60 g·L⁻¹), positive group (treated with FGF9, 0.054 g·L⁻¹), low dose group (treated with transgenic safflower oil bodies, 10 g·L⁻¹) and high dose group (treated with transgenic safflower oil bodies, 60 g·L⁻¹). The skin of all above-mentioned mice models were coated with soft adhesive manner every other day, 100 µL/time. After 15 days, the mice skin was cut and embedded for histological analysis. The hair regrowth experimental results showed that the hair of mice grew well, and the mice in high dose group had bushy hair, with significant effect on regeneration hair number as compared with the positive group. The healing was obvious in wound experiment, with significant healing effect in positive group, high dose group and low dose group as compared to blank control group. Furthermore, high dose group remarkably showed a better and higher healing effect than the positive group at day 5. Oleosin-rhFGF9 was successfully transformed into safflower, and T3 transgenic safflower oil bodies expressed oleosin-rhFGF9 fusion protein were obtained, with the role of promoting hair regeneration and wound repair in mice.

Oil body bound oleosin-rhFGF9 fusion protein expressed in safflower (Carthamus tinctorius L.) stimulates hair growth and wound healing in mice.

BACKGROUND: Fibroblast growth factor 9 (FGF9) is a heparin-binding growth factor, secreted by both mesothelial and epithelial cells, which participates in hair follicle regeneration, wound healing, and bone development. A suitable source of recombinant human FGF9 (rhFGF9) is needed for research into potential clinical applications. We present that expression of oleosin-rhFGF9 fusion protein in safflower (Carthamus tinctorius L.) seeds stimulates hair growth and wound healing. RESULTS: The oleosin-rhFGF9 expressed in safflower seeds, in which it localizes to the surface of oil bodies. The expression of oleosin-rhFGF9 was confirmed by polyacrylamide gel electrophoresis and western blotting. According to BCA and Enzyme-linked immunosorbent assay (ELISA) assay, the results show that the expression level of oleosin-rhFGF9 was 0.14% of oil body protein. The oil body bound oleosin-rhFGF9 showed mitogenic activity towards NIH3T3 cells in a methylthiazolyldiphenyl-tetrazolium bromide (MTT) assay. The efficacy of oil body bound oleosin-rhFGF9 in promoting hair growth and wound healing was investigated in C57BL/6 mice. In a hair regeneration experiment, 50 µg/µl oil body bound oleosin-rhFGF9 was applied to the dorsal skin of mice in the resting phase of the hair growth cycle. After 15 days, thicker hair and increased number of new hairs were seen compared with controls. Furthermore, the number of new hairs was greater compared with rhFGF9-treated mice. The hair follicles of mice treated with oil body bound oleosin-rhFGF9 expressed ß-catenin more abundantly. In a wound healing experiment, dorsal skin wounds were topically treated with 50 µg/µl oil body bound oleosin-rhFGF9. Wound healing was quicker compared with mice treated with rhFGF9 and controls, especially in the earlier stages of healing. CONCLUSIONS: The oil body bound oleosin-rhFGF9 promotes both hair growth and wound healing. It appears to promote hair growth, at least in part, by up-regulating ß-catenin expression. The potential of oil body bound oleosin-rhFGF9 as an external drug can treat the alopecia and wounds or use in further clinical application.

Novel SA@Ca2+/RCSPs core-shell structure nanofibers by electrospinning for wound dressings.

Therapeutic drugs remain of great significance for the absorption of wound blood, the closure of wounds and rapid wound healing. Hence, we propose a novel composite nanofiber membrane with the above characteristics as a wound healing material. We utilize the reaction of calcium ion and alginate gel, sodium alginate (SA) and Rana chensinensis skin peptides (RCSPs) extracted from discarded Rana chensinensis skin; these two natural substances were successfully used to prepare composite nanofibers by coaxial electrospinning. The composite nanofibers are named SA@Ca2+/RCSPs nanofibers. SA@Ca2+/RCSPs nanofibers exhibited that the nanofibers contact with the liquid is unmelted, instead become gel, when compared to nanofibers of does not contain calcium ions, and the absorption rate reached 179.87%. SA@Ca2+/RCSPs nanofibers conform to the quasi-first-order dynamics model and the Ritger-Peppas release model. In vivo wound healing experiments showed that the wound-healing rate of SA@Ca2+/RCSPs nanofiber-treated wounds was 46.65% and 97.46% on days 5 and 15, respectively. In addition, SA@Ca2+/RCSPs nanofibers promoted collagen deposition and enhanced epidermal regeneration. The present study showed that composite nanofibers could quickly undergo hemostasis and effectively promote wound healing.