論文 - 詳細
| RRC ID | 77395 |
|---|---|
| 著者 | Borrie MS, Kraycer PM, Gartenberg MR. |
| タイトル | Transcription-Driven Translocation of Cohesive and Non-Cohesive Cohesin In Vivo. |
| ジャーナル | Mol Cell Biol |
| Abstract |
INTRODUCTION:Fetal hypoxia has long-term effects on postnatal reproductive functions and the mitochondrial impairments of ovarian granulosa cells may be one of the causes. Melatonin applied to mitigate mitochondrial dysfunction and autophagy in mammalian cells has been reported. However, the potential mechanisms by which fetal hypoxia damages reproductive function in neonatal female mice and the melatonin effects on this problem remain unclear. OBJECTIVES:This research aimed to explore the mechanism that fetal hypoxia damages reproductive function in neonatal female mice and attempt to improve the reproductive function by treating with melatonin in vivo and in vitro. METHODS:We established a fetal hypoxia model and confirmed that fetal hypoxia affects ovarian function by inducing GC excessive autophagy. Transcriptomic analysis, gene interference, cell immunofluorescence, immunohistochemistry and western blot were conducted to explore and verify the underlying mechanisms in mice GCs and KGN cells. Finally, melatonin treatment was executed on hypoxia-treated mice GCs and KGN cells and melatonin injection to fetal-hypoxia-treated mice to determine its effect. RESULTS:The results of in vitro experiments found that fetal hypoxia led to mitochondrial dysfunction in ovarian GCs causing autophagic cell death. And the PI3K/Akt/FoxO pathway mediated the occurrence of this process by transcriptome analysis of ovarian GCs from normal and fetal hypoxia mice, which was further verified in mice GCs and KGN cells. Additionally, melatonin administration prevented autophagic injuries and mitochondrial impairments in hypoxia-treated mice GCs and KGN cells. Meanwhile, in vivo experiments by melatonin injection ameliorated oxidative stress of ovary in fetal-hypoxia-treated mice and improved their low fertility. CONCLUSION:Our data found that fetal hypoxia causes ovarian GCs excessive autophagy leading to low fertility in neonatal female mice and mitigated by melatonin. These results provide a potential therapy for hypoxic stress-related reproductive disorders. |
| 巻・号 | 43(6) |
| ページ | 254-268 |
| 公開日 | 2023-1-1 |
| DOI | 10.1080/10985549.2023.2199660 |
| PMID | 37178128 |
| PMC | PMC10251789 |
| MeSH | Adenosine Triphosphate Cell Cycle Proteins / genetics Chromatids Chromosomal Proteins, Non-Histone* / genetics DNA Saccharomyces cerevisiae / genetics Saccharomyces cerevisiae Proteins* / genetics |
| IF | 3.611 |
| リソース情報 | |
| 酵母 | BYP8880, BYP7569 |