융합정보논문지 (Journal of Convergence for Information Technology)

중소기업융합학회 (Convergence Society for SMB)
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Vitexin에 의한 HDF 세포에서 UVB 유도 DRAM1-오토파지 단백질

Regulation of UVB-induced DRAM1-Autophagy protein in HDF Cells by the Vitexin

  • Byun, Seo-Jung (Division of Biological Engineering, Konkuk University) ;
  • Kang, Sang-Mo (Division of Biological Engineering, Konkuk University) ;
  • Cho, Young Jae (Division of Biological Engineering, Konkuk University)
  • 투고 : 2021.01.13
  • 심사 : 2021.02.20
  • 발행 : 2021.02.28
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초록

본 연구는 메밀 추출물과 비텍신을 이용하여 UVB 손상 개선에 대한 효과를 알아보기 위해 Microarray 분석, 세포의 증식, 세포 상처 회복, 세포주기, 마이크로파지의 생성 양상, 단백질 분석 등을 실시하였다. Microarray 분석 결과는 DRAM1, Atg2a 및 Atg13 유전자에서 UVB에 의해 증가 된 양상을 메밀 에탄올추출물과 비텍신에서 감소시켰다. 세포의 증식, 상처 회복, 주기 및 마이크로파지 양상에서는 메밀 에탄올추출물과 비텍신에서 정상 세포와 유사하게 개선되었으며, 단백질 분석에서 DRAM1, Beclin-1 및 LC3 I/II 모두 비텍신 처리군에서 감소하였고, p-mTOR 및 Survivin은 모두 증가 되었다. UVB에 의한 손상에서 메밀 에탄올추출물과 비텍신은 DRAM1, Atg2a 및 Atg13을 같이 컨트롤 하고 세포 증식, 상처 회복 및 주기를 정상으로 회복하며 UVB에 의한 세포 노화 발생원인 중 하나인 오토파지를 조절하여 세포의 사멸억제 및 재생하므로 기능성 화장품 성분으로 활용가능할 것으로 사료 된다.

This study was carried out to investigate the Fagopyrum esculentum (F. esculentum) extracts and vitexin are as the results of microarray, cell proliferation, cell wound recovery, cell cycle, microphage pattern and protein analysis for damage improvement caused by UVB-induced damage. Microarray results showed that UVB-induced increase in DRAM1, Atg2a and Atg13 genes was reduced in F. esculentum ethanol extract and vitexin. Cell proliferation, wound repair, cell cycle, and microphage patterns were improved in F. esculentum ethanol extract and vitexin, while buckwheat ethanol extract and vitexin decreased in both DRAM1, Beclin-1, and LC3 I/II in the vitexin treatment group and p-mTOR and survivin were all increased in protein analysis. It is thought that it can recover to normal and control autophagy, one of the causes of cell aging caused by UVB, to inhibit and regenerate cell death. F. esculentum ethanol extract and vitexin can be used as a functional cosmetic ingredient.

키워드

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