[1] JUENGEL J L, MCNATTY K P. The role of proteins of the transforming growth factor-β superfamily in the intraovarian regulation of follicular development[J]. Hum Reprod Update, 2005, 11(2): 143-160.
[2] ASHRY M, LEE K, MONDAL M, et al. Expression of TGFβ superfamily components and other markers of oocyte quality in oocytes selected by brilliant cresyl blue staining: relevance to early embryonic development[J]. Mol Reprod Dev, 2015, 82(3): 251-264.
[3] CHANG H, BROWN C W, MATZUK M M. Genetic analysis of the mammalian transforming growth factor-β superfamily[J]. Endocr Rev, 2002, 23(6): 787-823.
[4] FINDLAY J K, DRUMMOND A E, DYSON M L, et al. Recruitment and development of the follicle; the roles of the transforming growth factor-β superfamily[J]. Mol Cell Endocrinol, 2002, 191(1): 35-43.
[5] LIN S Y, MORRISON J R, PHILLIPS D J, et al. Regulation of ovarian function by the TGF-beta superfamily and follistatin[J]. Reproduction, 2003, 126(2): 133-148.
[6] HELDIN C H, MIYAZONO K, DIJKE P T. TGF-β signalling from cell membrane to nucleus through SMAD proteins[J]. Nature, 1997, 390(6659): 465-471.
[7] LEE K B, ZHANG K, FOLGER J K, et al. Evidence supporting a functional requirement of SMAD4 for bovine preimplantation embryonic development: a potential link to embryotrophic actions of follistatin[J]. Biol Reprod, 2014, 91(3): 62.
[8] LUUKKO K, YLIKORKALA A, MÄKELÄ T P. Developmentally regulated expression of Smad3, Smad4, Smad6, and Smad7 involved in TGF-beta signaling[J]. Mech Dev, 2001, 101(1-2): 209-212.
[9] WONG C, ROUGIER-CHAPMAN E M, FREDERICK J P, et al. Smad3-Smad4 and AP-1 complexes synergize in transcriptional activation of the c-Jun promoter by transforming growth factor β[J]. Mol Cell Biol, 1999, 19(3): 1821-1830.
[10] ITOH S, TEN DIJKE P. Negative regulation of TGF-β receptor/Smad signal transduction[J]. Curr Opin Cell Biol, 2007, 19(2): 176-184.
[11] BARTEL D P. microRNAs: genomics, biogenesis, mechanism, and function[J]. Cell, 2004, 116(2): 281-297.
[12] AMBROS V. The functions of animal microRNAs[J]. Nature, 2004, 431(7006): 350-355.
[13] 徐 源, 孙铁成, 张爱玲, 等. 卵巢miRNA研究进展[J]. 畜牧兽医学报, 2014, 45(4): 509-516.
XU Y, SUN T C, ZHANG A L, et al. Progress on the research of ovarian miRNA[J]. Acta Veterinaria et Zootechnica Sinica, 2014, 45(4): 509-516. (in Chinese)
[14] YANG X K, ZHOU Y, PENG S, et al. Differentially expressed plasma microRNAs in premature ovarian failure patients and the potential regulatory function of mir-23a in granulosa cell apoptosis[J]. Reproduction, 2012, 144(2): 235-244.
[15] WANG Y, REN J W, GAO Y, et al. microRNA-224 targets SMAD family member 4 to promote cell proliferation and negatively influence patient survival[J]. PLoS One, 2013, 8(7): e68744.
[16] YAO G D, YIN M M, LIAN J, et al. microRNA-224 is involved in transforming growth factor-β-mediated mouse granulosa cell proliferation and granulosa cell function by targeting Smad4[J]. Mol Endocrinol, 2010, 24(3): 540-551.
[17] YIN M M, LV M R, YAO G D, et al. Transactivation of microRNA-383 by steroidogenic factor-1 promotes estradiol release from mouse ovarian granulosa cells by targeting RBMS1[J]. Mol Endocrinol, 2012, 26(7): 1129-1143.
[18] YAN G J, ZHANG L X, FANG T, et al. microRNA-145 suppresses mouse granulosa cell proliferation by targeting activin receptor IB[J]. FEBS Lett, 2012, 586(19): 3263-3270.
[19] LIN F, LI R, PAN Z X, et al. miR-26b promotes granulosa cell apoptosis by targeting ATM during follicular atresia in porcine ovary[J]. PLoS One, 2012, 7(6): e38640.
[20] 张小辉. 牛9个繁殖性状相关基因cDNA克隆、SNPs及组织表达研究[D]. 杨凌: 西北农林科技大学, 2007.
ZHANG X H. cDNA clone, SNPs and tissues expression analysis of 9 genes on cattle reproduction trait[D]. Yangling: Northwest A&F University, 2007. (in Chinese)
[21] SHI R, CHIANG V L. Facile means for quantifying microRNA expression by real-time PCR[J]. BioTechniques, 2005, 39(4): 519-525.
[22] LEWIS B P, SHIH I H, JONES-RHOADES M W, et al. Prediction of mammalian microRNA targets[J]. Cell, 2003, 115(7): 787-798.
[23] LEWIS B P, BURGE C B, BARTEL D P. Conserved seed pairing, often flanked by adenosines, indicates that thousands of human genes are microRNA targets[J]. Cell, 2005, 120(1): 15-20.
[24] 张小辉, 张路培, 许尚忠, 等. 牛Smad4基因cDNA克隆及生物信息学分析[J]. 畜牧兽医学报, 2007, 38(4): 321-325.
ZHANG X H, ZHANG L P, XU S Z, et al. Cloning and bioinformaton analysis of cDNA encoding cattle Smad4 gene[J]. Acta Veterinaria et Zootechnica Sinica, 2007, 38(4): 321-325. (in Chinese)
[25] SIRARD C, DE LA POMPA J L, ELIA A, et al. The tumor suppressor gene Smad4/Dpc4 is required for gastrulation and later for anterior development of the mouse embryo[J]. Genes Dev, 1998, 12(1): 107-119.
[26] HUANG Z, YUAN X, WANG M, et al. Molecular cloning of the SMAD4 gene and its mRNA expression analysis in ovarian follicles of the Yangzhou goose (Anser cygnoides)[J]. Br Poult Sci, 2016, 57(4): 515-521.
[27] XU Y F, LI E L, HAN Y D, et al. Differential expression of mRNAs encoding BMP/Smad pathway molecules in antral follicles of high-and low-fecundity Hu sheep[J]. Anim Reprod Sci, 2010, 120(1-4): 47-55.
[28] MIAO Z L, WANG Z N, CHENG L Q, et al. Expression of Smad4 during rat ovarian development[J]. J First Mil Med Univ, 2005, 25(2): 127-131.
[29] MOSKOWITZ I P, WANG J, PETERSON M A, et al. Transcription factor genes Smad4 and Gata4 cooperatively regulate cardiac valve development[J]. Proc Natl Acad Sci U S A, 2011, 108(10): 4006-4011.
[30] MAO X, DEBENEDITTIS P, SUN Y, et al. Vascular smooth muscle cell Smad4 gene is important for mouse vascular development[J]. Arterioscler Thromb Vasc Biol, 2012, 32(9): 2171-2177.
[31] YANG L L, MAO C M, TENG Y, et al. Targeted disruption of Smad4 in mouse epidermis results in failure of hair follicle cycling and formation of skin tumors[J]. Cancer Res, 2005, 65(19): 8671-8678.
[32] PANGAS S A, LI X H, ROBERTSON E J, et al. Premature luteinization and cumulus cell defects in ovarian-specific Smad4 knockout mice[J]. Mol Endocrinol, 2006, 20(6): 1406-1422.
[33] YU C, ZHANG Y L, FAN H Y. Selective Smad4 knockout in ovarian preovulatory follicles results in multiple defects in ovulation[J]. Mol Endocrinol, 2013, 27(6): 966-978.
[34] LIANG M, YAO G D, YIN M M, et al. Transcriptional cooperation between p53 and NF-κB p65 regulates microRNA-224 transcription in mouse ovarian granulosa cells[J]. Mol Cell Endocrinol, 2013, 370(1-2): 119-129.
[35] YAO G D, LIANG M, LIANG N, et al. microRNA-224 is involved in the regulation of mouse cumulus expansion by targeting Ptx3[J]. Mol Cell Endocrinol, 2014, 382(1): 244-253.
[36] LI X F, WANG H D, SHENG Y, et al. microRNA-224 delays oocyte maturation through targeting Ptx3 in cumulus cells[J]. Mech Dev, 2017, 143: 20-25.
[37] HUSZAR J M, PAYNE C J. microRNA 146 (Mir146) modulates spermatogonial differentiation by retinoic acid in mice[J]. Biol Reprod, 2013, 88(1): 15.
[38] FENG B, DONG T T, WANG L L, et al. Colorectal cancer migration and invasion initiated by microRNA-106a[J]. PLoS One, 2012, 7(8): e43452.
[39] ZHU M, ZHANG N, HE S X, et al. microRNA-106a targets TIMP2 to regulate invasion and metastasis of gastric cancer[J]. FEBS Lett, 2014, 588(4): 600-607.
[40] ZHU M, ZHANG N, HE S X, et al. microRNA-106a functions as an oncogene in human gastric cancer and contributes to proliferation and metastasis in vitro and in vivo[J]. Clin Exp Metastasis, 2016, 33(5): 509-519.
[41] MENG F, ZHANG L, SHAO Y, et al. microRNA-377 inhibits non-small-cell lung cancer through targeting AEG-1[J]. Int J Clin Exp Pathol, 2015, 8(11): 13853-13863. |