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| Expression of YAP and TEAD1 in the Formation, Development and Degeneration of Yak (Bos grunniens) Corpus Luteum |
| ZHOU Ying-Cong1, WANG Jing-Lei1, ZHANG Tong-Xiang1, DU Pei-Yan1, LI Yi-Juan1, YAO Ying1, QIAN Wen-Jie1, CUI Yan1,2, YU Si-Jiu1,2, FAN Jiang-Feng1,2,* |
1 College of Veterinary Medicine, Gansu Agricultural University, Lanzhou 730070, China;
2 Technology and Research Center of Gansu Province for Embryonic Engineering of Bovine and Sheep & Goat, Gansu Agricultural University, Lanzhou 730070, China |
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Abstract Yes-associated protein (YAP) and TEA domain transcription factor 1 (TEAD1) are downstream transcriptional co-activators of the Hippo signaling pathway that play important roles in female reproduction. Thus, in order to investigate the relationship between YAP and TEAD1 and corpora lutea (CL) formation, development and degeneration in yaks (Bos grunniens), the female yak corpus luteum (CL) tissues were collected, and divided into 5 groups according to the process of corpus luteum formation (corpus rubrum stage and lacunose luteum stage), development (pregnancy luteal phase), and degeneration (degenerative luteal phase and white corpus stage). The relative expression of YAP and TEAD1 genes and proteins in luteal formation, development and degeneration were examined by qPCR and Western blot, and the localization of YAP and TEAD1 in corpus luteum formation, development and degeneration were analyzed by immunohistochemistry. The results showed that YAP and TEAD1 were abundantly expressed in luteal tissues, and there were significantly difference in different stages of luteal tissues, especially the relative expressions of YAP and TEAD1 were the highest in the lacunose luteum stage and significantly difference from the other stages (P<0.05). However, YAP and TEAD1 expressions were the lowest in the degenerated luteal tissues. Immunohistochemical results showed that YAP and TEAD1 were expressed mainly in yak granulosa luteal cells, vascular endothelial cells and fibroblasts. The results suggested that the Hippo signaling pathway mediated by YAP and TEAD1 was involved in the formation, development and function of luteal tissue in female yaks by stimulating the proliferation of luteal cells, and was associated with angiogenesis during this process. The results of this study provide a reference for further exploration the role played by Hippo pathway in the regulation of ovarian function and maintenance of pregnancy in yaks.
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Received: 23 May 2022
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Corresponding Authors:
* fanjf@gsau.edu.cn
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[1] 何春波. 2017. Hippo/YAP信号通路调节卵巢细胞的老化[D]. 硕士学位论文, 华中农业大, 导师: 姜勋平, 王诚, pp. 50-66.
(He C B.2017. Hippo/YAP signal pathway regulates ovarian cell aging[D]. Thesis for M.S, Huazhong Agricultural University, Suppervisor: Jiang X P, Wang C, pp. 50-66.)
[2] 胡燎燎. 2016. HIPPO信号通路在小鼠原始卵泡启动中的作用及调控机制[D]. 硕士学位论文, 南昌大学, 导师: 郑莉萍, pp.35-39.
(Hu L L.2016. Role and regulatory mechanism of HIPPO signal pathway in primordial follicle initiation in mice[D]. Thesis for M.S, Nanchang University, Suppervisor: Zheng L P, pp. 35-39.)
[3] 李佳, 周芳月, 黄健, 等. 2014. Hippo信号通路在雌性生殖系统中的研究进展[J]. 中国细胞生物学学报, 36(12): 1689-1694.
(Li J, Zhou F Y, Huang J, et al.2014. Research progress of Hippo signal pathway in female reproductive system[J]. Chinese Journal of Cell Biology, 36(12): 1689-1694.)
[4] 李楠, 沙丽. 2016. Hippo-YAP信号通路与多种疾病的研究进展[J]. 中国继续医学教育, 8(20): 50-51.
(Li N, Sha L.2016. Hippo-YAP signal pathway and the research progress of many diseases[J]. Continuing Medical Education in China, 8(20): 50-51.)
[5] Baumgartner R, Poernbacher I, Buser N, et al.2010. The WW domain protein kibra acts upstream of Hippo in Drosophila[J]. Developmental Cell, 18(2): 309-316.
[6] Berisha B, Schams D, Rodler D, et al.2016. Angiogenesis in the ovary-the most important regulatory event for follicle and corpus luteum development and function in cow-an overview[J]. Anatomia Histologia Embryologia, 45(2): 124-130.
[7] Chai J, Xu S, Guo F.2017. TEAD1 mediates the oncogenic activities of Hippo-YAP1 signaling in osteosarcoma[J]. Biochemical and Biophysical Research Communications, 488(2): 297-302.
[8] Chang J H, Lee Y L, Laiman V, et al.2022. Air pollution-regulated E-cadherin mediates contact inhibition of proliferation via the hippo signaling pathways in emphysema[J]. Chemico-biological Interactions, 351(2022): 109763-109763.
[9] Chen Q, Zhang N, Gray R S, et al.2014. A temporal requirement for Hippo signaling in mammary gland differentiation, growth, and tumorigenesis[J]. Genes & Development, 28(5): 432-437.
[10] Chen Z, Friedrich G A, Soriano P.1994. Transcriptional enhancer factor 1 disruption by a retroviral gene trap leads to heart defects and embryonic lethality in mice[J]. Genes & Development, 8(1994): 2293-301.
[11] Flores R, Ramirez M, Ayala L, et al.2022. Adiponectin influences FGF2 in the developing porcine corpus luteum[J]. Veterinary Sciences, 9(2): 77.
[12] Genevet A, Wehr M C, Brain R, et al.2010. Kibra is a regulator of the Salvador/Warts/Hippo signaling network[J]. Developmental Cell, 18(2): 300-308.
[13] Halder G, Johnson R L.2011. Hippo signaling: Growth control and beyond[J]. Development, 138(1): 9-22.
[14] Hong W, Guan K L.2012. The YAP and TAZ transcription co-activators: Key downstream effectors of the mammalian Hippo pathway[J]. Seminars in Cell & Developmental Biology, 23(7): 785-793.
[15] Huang J, Wu S, Barrera J, et al.2005. The Hippo signaling pathway coordinately regulates cell proliferation and apoptosis by inactivating Yorkie, the Drosophila homolog of YAP[J]. Cell, 122(3): 421-434.
[16] Ishiji T, Lace M J, Parkkinen S, et al.1992. Transcriptional enhancer factor (TEF)-1 and its cell-specific co-activator activate human papillomavirus-16 E6 and E7 oncogene transcription in keratinocytes and cervical carcinoma cells[J]. The EMBO Journal, 11(6): 2271-2281.
[17] Jacquemin P, Hwang J J, Martial J A, et al.1996. A novel family of developmentally regulated mammalian transcription factors containing the TEA/ATTS DNA binding domain[J]. The Journal of Biological Chemistry, 271(36): 21775-21785.
[18] Ji S Y, Liu X M, Li B T, et al.2017. The polycystic ovary syndrome-associated gene Yap1 is regulated by gonadotropins and sex steroid hormones in hyperandrogenism-induced oligo-ovulation in mouse[J]. Molecular Human Reproduction, 23(10): 698-707.
[19] Jonczyk A W, Piotrowska-Tomala K K, Skarzynski D J.2019. Effects of prostaglandin F-2α (PGF(2α)) on cell-death pathways in the bovine corpus luteum (CL)[J]. BMC Veterinary Research, 15(1): 416.
[20] Kaneko K J, Cullinan E B, Latham K E, et al.1997. Transcription factor mTEAD-2 is selectively expressed at the beginning of zygotic gene expression in the mouse[J]. Development (Cambridge, England), 124(10): 1963-1973.
[21] Kaneko K J, DePamphilis M L.1998. Regulation of gene expression at the beginning of mammalian development and the TEAD family of transcription factors[J]. Developmental Genetics, 22(1): 43-55.
[22] Kim N G, Koh E, Chen X, et al.2011. E-cadherin mediates contact inhibition of proliferation through Hippo signaling-pathway components[J]. Proceedings of the National Academy of Sciences of the USA, 108(29): 11930-11935.
[23] Lan C, Cao N, Chen C, et al.2020. Progesterone, via yes-associated protein, promotes cardiomyocyte proliferation and cardiac repair[J]. Cell Proliferation, 53(11): 12910.
[24] Li N, Xie C, Lu N.2017. Crosstalk between Hippo signalling and miRNAs in tumour progression[J]. FEBS Journal, 284(7): 1045-1055.
[25] Maas K, Mirabal S, Penzias A, et al.2018. Hippo signaling in the ovary and polycystic ovarian syndrome[J]. Journal of Assisted Reproduction and Genetics, 35(10): 1763-1771.
[26] Milewski R C, Chi N C, Li J, et al.2004. Identification of minimal enhancer elements sufficient for Pax3 expression in neural crest and implication of Tead2 as a regulator of Pax3[J]. Development (Cambridge, England), 131(4): 829-837.
[27] Miyamoto A, Shirasuna K, Shimizu T, et al.2010. Regulation of corpus luteum development and maintenance: Specific roles of angiogenesis and action of prostaglandin F2α[J]. Society of Reproduction and Fertility supplement, 67(1): 289-304.
[28] Mlyczynska E, Kiezun M, Kurowska P, et al.2022. New aspects of corpus luteum regulation in physiological and pathological conditions: Involvement of adipokines and neuropeptides[J]. Cells, 11(6): 957.
[29] Moon S, Hwang S, Kim B, et al.2022. Hippo signaling in the endometrium[J]. International Journal of Molecular Sciences, 23(7): 3852.
[30] Pobbati A V, Hong W.2013. Emerging roles of TEAD transcription factors and its coactivators in cancers[J]. Cancer Biology & Therapy, 14(5): 390-398.
[31] Przygrodzka E, Plewes M R, Davis J S.2021. Luteinizing hormone regulation of inter-organelle communication and fate of the corpus luteum[J]. International Journal of Molecular Sciences, 22(18): 9972.
[32] Ren H, Birch N P, Suresh V.2016. An optimised human cell culture model for alveolar epithelial transport[J]. PLOS ONE, 11(10): 0165225.
[33] Reynolds L P, Redmer D A.1999. Growth and development of the corpus luteum[J]. Journal of Reproduction and Fertility. Supplement, 54(1999): 181-191.
[34] Sawada A, Kiyonari H, Ukita K, et al.2008. Redundant roles of Tead1 and Tead2 in notochord development and the regulation of cell proliferation and survival[J]. Molecular and Cellular Biology, 28(10): 3177-3189.
[35] Sawada A, Nishizaki Y, Sato H, et al.2005. Tead proteins activate the Foxa2 enhancer in the node in cooperation with a second factor[J]. Development (Cambridge, England), 132(21): 4719-4729.
[36] Wang X, Valls A F, Schermann G, et al.2017. YAP/TAZ orchestrate VEGF signaling during developmental angiogenesis[J]. Developmental Cell, 42(5): 462-478.
[37] Xiao J H, Davidson I, Matthes H, et al.1991. Cloning, expression, and transcriptional properties of the human enhancer factor TEF-1[J]. Cell, 65(4): 551-568.
[38] Yagi R, Kohn M J, Karavanova I, et al.2007. Transcription factor TEAD4 specifies the trophectoderm lineage at the beginning of mammalian development[J]. Development (Cambridge, England), 134(21): 3827-3836.
[39] Yoshida T.2008. MCAT elements and the TEF-1 family of transcription factors in muscle development and disease[J]. Arteriosclerosis, Thrombosis, and Vascular Biology, 28(1): 8-17.
[40] Yu J, Zheng Y, Dong J, et al.2010. Kibra functions as a tumor suppressor protein that regulates Hippo signaling in conjunction with merlin and expanded[J]. Developmental Cell, 18(2): 288-299.
[41] Zeng Q, Hong W.2008. The emerging role of the hippo pathway in cell contact inhibition, organ size control, and cancer development in mammals[J]. Cancer Cell, 13(3): 188-192.
[42] Zhang L.2015. Control of growth and beyond: A special issue on Hippo signaling[J]. Acta Biochimica Et Biophysica Sinica, 47(1): 1. |
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