Direct conversion of human fibroblasts into adipocytes using a novel small molecular compound: Implications for regenerative therapy for adipose tissue defects

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Abstract

There is a need in plastic surgery to prepare autologous adipocytes that can be trans-planted in patients to reconstruct soft tissue defects caused by tumor resection, including breast cancer, and by trauma and other diseases. Direct conversion of somatic cells into adipocytes may allow sufficient functional adipocytes to be obtained for use in regeneration therapy. Chemical li-braries of 10,800 molecules were screened for the ability to induce lipid accumulation in human dermal fibroblasts (HDFs) in culture. Chemical compound-mediated directly converted adipocytes (CCCAs) were characterized by lipid staining, immunostaining, and qRT-PCR, and were also tested for adipokine secretion and glucose uptake. CCCAs were also implanted into mice to examine their distribution in vivo. STK287794 was identified as a small molecule that induced the accumulation of lipid droplets in HDFs. CCCAs expressed adipocyte-related genes, secreted adiponectin and lep-tin, and abundantly incorporated glucose. After implantation in mice, CCCAs resided in granula-tion tissue and remained adipose-like. HDFs were successfully converted into adipocytes by adding a single chemical compound, STK287794. C/EBPα and PPARγ were upregulated in STK287794-treated cells, which strongly suggests involvement of these adipocyte-related transcription factors in the chemical direct conversion. Our method may be useful for the preparation of autogenous adipocytes for transplantation therapy for soft tissue defects and fat tissue atrophy.

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Sowa, Y., Kishida, T., Louis, F., Sawai, S., Seki, M., Numajiri, T., … Mazda, O. (2021). Direct conversion of human fibroblasts into adipocytes using a novel small molecular compound: Implications for regenerative therapy for adipose tissue defects. Cells, 10(3), 1–15. https://doi.org/10.3390/cells10030605

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