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Signals controlling tissues homeostasis in the ovary

控制卵巢组织稳态的信号

基本信息

批准号：
10509395
负责人：
JOHN S DAVIS
金额：
--
依托单位：
OMAHA VA MEDICAL CENTER
依托单位国家：
美国
项目类别：
财政年份：
2019
资助国家：
美国
起止时间：
2019-10-01 至 2023-09-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10509395
关键词：
Affect Age Apoptosis Biological Models Cattle Cell Cycle Cell Differentiation process Cell Nucleus Cell Proliferation Cell Survival Cells Complex Cyclic AMP-Dependent Protein Kinases Data Development Diagnosis Disease Embryo Embryonic Development Endocrine Enrollment Environment Estrogens Event Failure Female Fertility Gene Expression Goals Gonadal Steroid Hormones Granulosa-Lutein Cells Growth Health Healthcare Homeostasis Homologous Gene Hormone imbalance In Vitro Infertility Inhibition of Cell Proliferation Knowledge Length Life Longevity Luteal Cells Luteal Phase Membrane Menopause Menstruation Disturbances Modeling Molecular Mus Nature Nuclear Nuclear Export Organ Organ Size Osteoporosis Ovarian Ovarian Follicle Ovarian Granulosa Cell Ovarian hormone Ovary Ovulation Pathway interactions Pattern Phosphorylation Phosphotransferases Play Population Pregnancy Pregnancy Maintenance Premature Ovarian Failure Primordial Follicle Process Production Progesterone Proliferating Protein-Serine-Threonine Kinases Quality of life Regulation Reproduction Reproductive Biology Reproductive Health Research Research Proposals Research Support Role Serine Signal Pathway Signal Transduction Signaling Protein Steroids Testing Theca-Lutein Cells Tissue Recombination Tissues Transcription Coactivator Translating Tumor Suppression Tumor Suppressor Proteins Uterus Veterans Woman Women&apos s Health aged care seeking cell growth cell transformation child bearing corpus luteum endometriosis extracellular fascinate fetal folliculogenesis genetic regulatory protein granulosa cell human disease improved in vivo knock-down men mouse model natural Blastocyst Implantation novel oocyte maturation ovarian dysfunction pharmacologic rapid testing receptor reproductive response stem cell self renewal steroid hormone theca cell transcription factor transmission process tumor

项目摘要

Recent developments in other fields of research have shed light on an evolutionarily conserved pathway that controls organ size by regulating cell proliferation, apoptosis, and stem cell self-renewal. This pathway is called the Hippo signaling pathway and disrupting the Hippo pathway results in the loss of tissue homeostasis and contributes to many human diseases. Despite extensive study of the Hippo pathway in the past decade, the exact nature of extracellular signals and membrane receptors regulating the Hippo pathway remains elusive. Recent studies and our preliminary data demonstrate that YAP and TAZ, the effectors of the Hippo pathway, play an important role in the ovary. The ovary is a fascinating organ that contributes the maturation of oocytes and the production of sex hormones, which are important for successful reproduction and quality-of-life. The ovarian follicle is the functional unit of the ovary. The formation of primordial follicles is a critical cellular transition process; and the failure of folliculogenesis during fetal life leads to ovarian dysgenesis and premature ovarian failure. In women the early loss of ovarian function not only causes infertility but also contributes to the onset of menopause-related complications. The granulosa and theca cells of the follicle proliferate as the follicle develops and secrete sex hormones and local factors that are critical for successful oocyte maturation. In women and cattle multiple waves of follicle growth and atresia occur during each reproductive cycle. Follicle development terminates at ovulation when the granulosa and theca cells differentiate into progesterone secreting luteal cells. Progesterone is essential for development of the embryo, implantation of the embryo into the uterus and maintenance of pregnancy. Disruption of folliculogenesis and luteal formation or function results in imbalanced hormone production, early embryonic failure, and possibly the transformation of cells leading to the development of tumors. Considering the number of women who suffer from infertility associated with ovarian dysfunction, understanding mechanisms that regulate the development of follicles, proliferation and differentiation of follicles, and the function of luteal cells holds great potential to positively impact women's health. There is a gap in our knowledge of the contributions of the Hippo pathway to follicle development and cellular differentiation of ovarian granulosa and theca cells which ultimately form the corpus luteum. This proposal will test the hypothesis that YAP and TAZ are required for follicle development but active Hippo signaling contributes to the differentiation of granulosa and theca cells. In this proposal we will utilize a tractable in vivo mouse model to study follicle development and an in vitro cow model to study proliferation and differentiation of follicle cells and luteal function. Cows are an excellent model for women because cows, like women, are mono-ovulatory, the endocrine profile and waves of folliculogenesis are remarkably similar, the length of the luteal phase and pregnancy are similar and adequate amounts of tissue and purified cell populations can be obtained from cows. This research supports our long-term objectives to fully understand the mechanisms controlling follicle development and corpus luteum function. The short-term goals of this research are to discover how Hippo signaling events contribute to follicle development and cellular differentiation. The proposed studies are expected to provide new information about the role played by the Hippo pathway in regulation of ovarian function, including follicle development, oocyte maturation, and ovarian hormone production. This research proposal centers on the identification of the molecular mechanisms responsible for transmitting signals from the outside environment to the nucleus, initiating gene expression and replication, and then translating molecular responses into changes in function and differentiation. There are over 2.2 million women Veterans and 32% are enrolled to receive VA health care. Female Veterans of childbearing age are seeking care at VA facilities in record numbers. Understanding reproductive health and biology for both men and women is crucial to improving health and quality-of-life.

其他研究领域的最新进展揭示了一个进化上保守的途径，通过调节细胞增殖、凋亡和干细胞自我更新来控制器官大小。这条路径被称为 Hippo信号传导途径和破坏Hippo途径导致组织稳态的丧失，导致许多人类疾病。尽管在过去十年中对Hippo途径进行了广泛的研究，调节Hippo通路的细胞外信号和膜受体的确切性质仍然难以捉摸。最近的研究和我们的初步数据表明，雅普和TAZ，Hippo通路的效应子，在卵巢中发挥重要作用。卵巢是一个迷人的器官，有助于卵母细胞的成熟以及性激素的产生，这对成功的生殖和生活质量很重要。的卵泡是卵巢的功能单位。原始卵泡的形成是一个关键的细胞转变胎儿期卵泡发育的失败导致卵巢发育不全和卵巢早衰。失败在女性中，卵巢功能的早期丧失不仅会导致不孕，而且会导致不孕症的发生。更年期相关并发症。卵泡的颗粒细胞和卵泡膜细胞随着卵泡的发育而增殖并分泌对卵母细胞成功成熟至关重要的性激素和局部因子。妇女和牛在每个生殖周期中出现多波卵泡生长和闭锁。卵泡发育当颗粒细胞和卵泡膜细胞分化为分泌孕酮的黄体细胞时，排卵终止。孕激素对于胚胎的发育、胚胎植入子宫以及维持怀孕。卵泡发生和黄体形成或功能的破坏导致失衡激素产生，早期胚胎失败，以及可能导致发育的细胞转化肿瘤。考虑到患有与卵巢功能障碍有关的不孕症的妇女人数，了解调控卵泡发育、增殖和分化的机制，黄体细胞的功能对女性健康有着巨大的积极影响。在我们的世界里，了解Hippo通路对卵泡发育和卵巢上皮细胞分化的贡献，最终形成黄体的颗粒细胞和卵泡膜细胞。这一提议将检验以下假设：雅普和TAZ是卵泡发育所必需的，但活跃的Hippo信号传导有助于卵泡的分化。颗粒细胞和卵泡膜细胞。在这个建议中，我们将利用一个易于处理的在体小鼠模型来研究卵泡发育和体外奶牛模型，以研究卵泡细胞的增殖和分化以及黄体功能。奶牛是女性的绝佳典范，因为奶牛和女性一样，都是单排卵的，卵泡发生的周期和波形非常相似，黄体期和妊娠期的长度相似并且可以从奶牛获得足够量的组织和纯化的细胞群。这项研究支持我们的长期目标是充分了解控制卵泡发育和黄体的机制，功能这项研究的短期目标是发现Hippo信号事件如何促进卵泡发育。发育和细胞分化。预计拟议的研究将提供有关以下方面的新信息： Hippo通路在调节卵巢功能中的作用，包括卵泡发育、卵母细胞成熟和卵巢激素的产生。这项研究的重点是确定负责将信号从外部环境传递到细胞核的分子机制，基因表达和复制，然后将分子反应转化为功能的变化，分化有超过220万女性退伍军人，32%的人注册接受VA医疗保健。育龄女性退伍军人在VA设施寻求护理的人数创纪录。理解男子和妇女的生殖健康和生物学对改善健康和生活质量至关重要。