Center for Reproductive Medicine, Ren Ji Hospital, School of Medicine, Shanghai Jiao Tong University, Shanghai, China.
Shanghai Key Laboratory for Assisted Reproduction and Reproductive Genetics, Shanghai, China.
J Clin Endocrinol Metab. 2021 Jun 16;106(7):2077-2091. doi: 10.1210/clinem/dgab119.
Previous work has demonstrated the role of the circadian clock in ovarian steroid hormone synthesis and attributed embryo implantation failure associated with arrhythmic circadian clock genes to insufficient ovarian-derived progesterone synthesis. Research on expression of core circadian clock genes in the endometrium itself and possible roles in compromised endometrial receptivity and recurrent implantation failure (RIF) are limited.
We aimed to assess the core circadian clock gene profiling in human endometrium across the menstrual cycle and the possible gene interaction networks in the endometrial receptivity of window of implantation (WOI) as well as RIF.
The study was initially an in silico study, with confirmatory lab-based data from primary human endometrial stromal cells (hESCs) as well as endometrial biopsies obtained from 60 women undergoing gynecological surgery in a clinical research center. The study included 30 RIF women and 30 age-matched and body mass index-matched controls.
Initial data mining and bioinformatics analysis of human endometrial microarray datasets across the menstrual cycle and between RIF women versus controls demonstrated the varied expression of core circadian clock genes across menstrual cycle, including the key role of PER2 in WOI and RIF. A PER2-centered network was investigated in the regulation of endometrial receptivity. We also confirmed the evidently increased mRNA expression of SHTN1, RXFP1, KLF5, and STEAP4 in the endometrium of RIF women, displaying the same trend as PER2 did, without any changes in MT1E and FKBP5. Treatment of PER2 siRNA in hESCs verified the positive regulation of PER2 to SHTN1, KLF5, and STEAP4.
Aberrant expression of endometrial PER2 might contribute to impaired endometrial receptivity and development of RIF via regulating SHTN1, KLF5, and STEAP4.
先前的研究已经证明了生物钟在卵巢甾体激素合成中的作用,并将与心律失常生物钟基因相关的胚胎着床失败归因于卵巢源性孕酮合成不足。目前对子宫内膜本身核心生物钟基因的表达及其在子宫内膜容受性和复发性植入失败(RIF)中的可能作用的研究有限。
我们旨在评估人类子宫内膜在整个月经周期中的核心生物钟基因谱,并研究在着床窗口期(WOI)和 RIF 中子宫内膜容受性的可能基因相互作用网络。
该研究最初是一项基于计算机的研究,通过对来自 60 名在临床研究中心接受妇科手术的女性的原发性人子宫内膜基质细胞(hESC)和子宫内膜活检进行基于实验室的确认性数据,对其进行补充。研究包括 30 名 RIF 女性和 30 名年龄和体重指数匹配的对照组。
对人类子宫内膜微阵列数据集在整个月经周期内以及 RIF 女性与对照组之间的初步数据挖掘和生物信息学分析表明,核心生物钟基因在月经周期中的表达存在差异,包括 PER2 在 WOI 和 RIF 中的关键作用。研究还调查了以 PER2 为中心的网络在调节子宫内膜容受性中的作用。我们还证实,RIF 女性的子宫内膜中 SHTN1、RXFP1、KLF5 和 STEAP4 的 mRNA 表达明显增加,其趋势与 PER2 相同,而 MT1E 和 FKBP5 没有任何变化。PER2 siRNA 在 hESC 中的处理验证了 PER2 对 SHTN1、KLF5 和 STEAP4 的正向调节。
PER2 子宫内膜表达异常可能通过调节 SHTN1、KLF5 和 STEAP4 导致子宫内膜容受性受损和 RIF 的发展。