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LSD1 contributes to programmed oocyte death by regulating the transcription of autophagy adaptor SQSTM1/p62.

Meina HeTuo ZhangZijian ZhuShaogang QinHuarong WangLihua ZhaoXinran ZhangJiayi HuJia WenHan CaiQiliang XinQirui GuoLin LinBo ZhouHua ZhangGuoliang XiaChao Wang
Published in: Aging cell (2020)
In female mammals, the size of the initially established primordial follicle (PF) pool within the ovaries determines the reproductive lifespan of females. Interestingly, the establishment of the PF pool is accompanied by a remarkable programmed oocyte loss for unclear reasons. Although apoptosis and autophagy are involved in the process of oocyte loss, the underlying mechanisms require substantial study. Here, we identify a new role of lysine-specific demethylase 1 (LSD1) in controlling the fate of oocytes in perinatal mice through regulating the level of autophagy. Our results show that the relatively higher level of LSD1 in fetal ovaries sharply reduces from 18.5 postcoitus (dpc). Meanwhile, the level of autophagy increases while oocytes are initiating programmed death. Specific disruption of LSD1 resulted in significantly increased autophagy and obviously decreased oocyte number compared with the control. Conversely, the oocyte number is remarkably increased by the overexpression of Lsd1 in ovaries. We further demonstrated that LSD1 exerts its role by regulating the transcription of p62 and affecting autophagy level through its H3K4me2 demethylase activity. Finally, in physiological conditions, a decrease in LSD1 level leads to an increased level of autophagy in the oocyte when a large number of oocytes are being lost. Collectively, LSD1 may be one of indispensible epigenetic molecules who protects oocytes against preterm death through repressing the autophagy level in a time-specific manner. And epigenetic modulation contributes to programmed oocyte death by regulating autophagy in mice.
Keyphrases
  • endoplasmic reticulum stress
  • cell death
  • oxidative stress
  • signaling pathway
  • gene expression
  • dna methylation
  • transcription factor
  • cell cycle arrest
  • type diabetes