Reproductive efficiency is critically dependent on embryo survival, establishment of a successful pregnancy and placental development. Recent advances in gene editing technology have enabled investigators to use gene knockdown and knockout approaches to better understand the role of hormone signaling in placental function and fetal growth and development. In this review, an overview of ruminant placentation will be provided, including recent data highlighting the role of histone lysine demethylase 1A and androgen signaling in ruminant placenta and pregnancy. Studies in ruminant placenta establish a role for histone lysine demethylase 1A in controlling genetic networks necessary for important cellular events such as cell proliferation and angiogenesis, as well as androgen receptor signaling during early placentation.
The placenta facilitates the transport of nutrients to the fetus, removal of waste products from the fetus, immune protection of the fetus and functions as an endocrine organ, thereby determining the environment for fetal growth and development. Additionally, the placenta is a highly metabolic organ in itself, utilizing a majority of the oxygen and glucose derived from maternal circulation. Consequently, optimal placental function is required for the offspring to reach its genetic potential in utero. Among ruminants, pregnant sheep have been used extensively for investigating pregnancy physiology, in part due to the ability to place indwelling catheters within both maternal and fetal vessels, allowing for steady-state investigation of blood flow, nutrient uptakes and utilization, and hormone secretion, under non-stressed and non-anesthetized conditions. This methodology has been applied to both normal and compromised pregnancies. As such, our understanding of the in vivo physiology of pregnancy in sheep is unrivalled by any other species. However, until recently, a significant deficit existed in determining the specific function or significance of individual genes expressed by the placenta in ruminants. To that end, we developed and have been using in vivo RNA interference (RNAi) within the sheep placenta to examine the function and relative importance of genes involved in conceptus development (PRR15 and LIN28), placental nutrient transport (SLC2A1 and SLC2A3), and placenta-derived hormones (CSH). A lentiviral vector is used to generate virus that is stably integrated into the infected cell’s genome, thereby expressing a short-hairpin RNA (shRNA), that when processed within the cell, combines with the RNA Induced Silencing Complex (RISC) resulting in specific mRNA degradation or translational blockage. To accomplish in vivo RNAi, day 9 hatched and fully expanded blastocysts are infected with the lentivirus for 4 to 5 h, and then surgically transferred to synchronized recipient uteri. Only the trophectoderm cells are infected by the replication deficient virus, leaving the inner cell mass unaltered, and we often obtain ~70% pregnancy rates following transfer of a single blastocyst. In vivo RNAi coupled with steady-state study of blood flow and nutrient uptake, transfer and utilization can now provide new insight into the physiological consequences of modifying the translation of specific genes expressed within the ruminant placenta.
Histone lysine demethylase 1A is a master regulator of genes necessary for trophoblast cell proliferation. A proper functioning placenta is critical for pregnancy, fetal growth and development and postnatal health. Trophoblast cell proliferation and differentiation is critical for placental development and function. Recently we demonstrated that the histone lysine demethylase KDM1A binds to androgen receptor (AR) in human and sheep trophoblast cells, and targets the same promoter region of vascular endothelial growth factor A (VEGFA), suggesting a role for KDM1A and AR in early placental angiogenesis. The goal of this study was to determine the function of KDM1A during early placental development. We hypothesized that KDM1A regulates genes that are necessary for trophoblast cell proliferation, and early placental development. To this end, both in vitro and in vivo approaches were used in this study. ACH-3P cells (human first trimester trophoblast cells (CT and EVT) fused with the choriocarcinoma cell line AC1-1) were used, and a KDM1A knock out (KO) cell line was generated using CRISPR-Cas 9 based genome editing. KDM1A KO in ACH-3P cells led to significant (P<0.05) reduction in AR and VEGFA. Furthermore, factors important for cell proliferation and trophoblast cell development high mobility group AT-hook 1 (HMGA1), LIN28, and MYC protooncogene (cMYC) were significantly (P<0.05) lower in KDM1A KO ACH-3P cells. Cell proliferation assays revealed a significant (P<0.05) reduction in KDM1A KO ACH-3P cells compared to scramble controls. An in vivo experiment was conducted to demonstrate a role for KDM1A in placental development, using the sheep as a model. Day 9 hatched blastocysts were flushed and infected with a Lenti-CRISPRv2 KDM1A target construct (n=4) to knockout KDM1A specifically in the trophectoderm, or with SC (n=5). Infected embryos were transferred to recipient ewes and embryos were collected at gestational day 16. Data suggests that KDM1A KO in trophoblast cells is necessary for conceptus elongation. Current experiments are ongoing to determine the effects of KDM1A and AR knockdown using shRNA lentiviral target vectors on conceptus elongation and pregnancy. Collectively these results indicate that KDM1A plays a central role in regulating genes necessary for trophoblast cell proliferation. This project was supported by Agriculture and Food Research Initiative Competitive Grant no. 2019-67015-29000 from the USDA National Institute of Food and Agriculture.
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