人卵丘细胞的转录组分析揭示缺氧是卵泡衰老的主要决定因素。
Transcriptome analysis of human cumulus cells reveals hypoxia as the main determinant of follicular senescence.
作者信息
Molinari E, Bar H, Pyle A M, Patrizio P
机构信息
Department of Obstetrics, Gynecology and Reproductive Sciences, Yale Fertility Center, Yale University, New Haven, CT 065112, USA.
Department of Statistics, University of Connecticut, Storrs, CT 06269, USA.
出版信息
Mol Hum Reprod. 2016 Aug;22(8):866-76. doi: 10.1093/molehr/gaw038. Epub 2016 Jun 6.
STUDY QUESTION
Can RNA sequencing of human cumulus cells (CC) reveal molecular pathways involved in the physiology of reproductive aging?
STUDY FINDING
Senescent but not young CC activate gene pathways associated with hypoxia and oxidative stress.
WHAT IS KNOWN ALREADY
Shifts in socioeconomic norms are resulting in larger numbers of women postponing childbearing. The reproductive potential is sharply decreased with aging, and the reasons are poorly understood. Since CCs play an integral role in oocyte maturation and direct access to human oocytes is limited, we used whole transcriptome analysis of these somatic cells to gain insights into the molecular mechanisms playing a role in follicular senescence.
STUDY DESIGN, SAMPLES/MATERIALS, METHODS: Twenty CC samples (from a total of 15 patients) were obtained from oocytes of either male factor or egg donor patients. RNA sequencing and bioinformatic tools were used to identify differentially expressed genes between CCs from seven aged and eight young patients (<35 (years old) y.o. vs >40 y.o.). Quantitative-PCR and immunoflourescent staining were used for validation.
MAIN RESULTS AND THE ROLE OF CHANCE
RNA sequencing identified 11 572 genes expressed in CC of both age cohorts, 45 of which were differentially expressed. In CC collected from patients >40 y.o., genes involved in the hypoxia stress response (NOS2, RORA and NR4A3), vasculature development (NR2F2, PTHLH), glycolysis (RALGAPA2 and TBC1D4) and cAMP turnover (PDE4D) were significantly overexpressed when compared with CC of patients younger than 35 y.o.
LIMITATIONS, REASONS FOR CAUTION: This study focused almost exclusively on assessing the genetic differences in CC transcriptome between young and older women. These genetic findings were not fully correlated with embryonic development and clinical outcome.
WIDER IMPLICATIONS OF THE FINDINGS
Our data provide a new hypothesis-follicular hypoxia-as the main mechanism leading to ovarian follicular senescence and suggest a link between cumulus cell aging and oocyte quality decay. If specific molecular findings of hypoxia would be confirmed also in oocytes, genetic platforms could screen CC for hypoxic damage and identify healthier oocytes. Protocols of ovarian stimulation in older patients could also be adjusted to diminish oocyte exposure time to hypoxic follicles.
LARGE SCALE DATA
GEO accession number: GSE81579 STUDY FUNDING AND COMPETING INTERESTS: Funded in part by EMD Serono Grant for Fertility Innovation (GFI).
研究问题
对人卵丘细胞(CC)进行RNA测序能否揭示与生殖衰老生理过程相关的分子途径?
研究发现
衰老而非年轻的卵丘细胞会激活与缺氧和氧化应激相关的基因途径。
已知信息
社会经济规范的转变导致越来越多的女性推迟生育。随着年龄增长,生殖潜力急剧下降,其原因尚不清楚。由于卵丘细胞在卵母细胞成熟过程中起着不可或缺的作用,且直接获取人类卵母细胞存在限制,我们对这些体细胞进行了全转录组分析,以深入了解在卵泡衰老中起作用的分子机制。
研究设计、样本/材料、方法:从男性因素患者或卵子捐赠者患者的卵母细胞中获取了20个卵丘细胞样本(共来自15名患者)。使用RNA测序和生物信息学工具来鉴定7名老年患者和8名年轻患者(<35岁与>40岁)的卵丘细胞之间差异表达的基因。采用定量PCR和免疫荧光染色进行验证。
主要结果及偶然性的作用
RNA测序鉴定出两个年龄组的卵丘细胞中均表达的11572个基因,其中45个基因存在差异表达。与35岁以下患者的卵丘细胞相比,从40岁以上患者收集的卵丘细胞中,参与缺氧应激反应(NOS2、RORA和NR4A3)、血管发育(NR2F2、PTHLH)、糖酵解(RALGAPA2和TBC1D4)和cAMP周转(PDE4D)的基因显著过表达。
局限性、需谨慎的原因:本研究几乎完全集中于评估年轻和老年女性卵丘细胞转录组中的基因差异。这些基因发现与胚胎发育和临床结果并未完全相关。
研究结果的更广泛影响
我们的数据提出了一个新的假设——卵泡缺氧是导致卵巢卵泡衰老的主要机制,并表明卵丘细胞衰老与卵母细胞质量下降之间存在联系。如果在卵母细胞中也能证实缺氧的特定分子发现,基因平台可以筛选卵丘细胞的缺氧损伤并识别更健康的卵母细胞。老年患者的卵巢刺激方案也可以进行调整,以减少卵母细胞暴露于缺氧卵泡的时间。
大规模数据
基因表达综合数据库(GEO)登录号:GSE81579 研究资金与利益冲突:部分由EMD Serono生育创新资助(GFI)。
Zotero 插件