China Animal Husbandry and Veterinary Medicine ›› 2023, Vol. 50 ›› Issue (6): 2185-2195.doi: 10.16431/j.cnki.1671-7236.2023.06.002
• Biotechnology • Previous Articles Next Articles
CHEN Kaiwen, ZHAO Yunjiao, WANG Lei, ZHANG Jianbo, MA Yuhong, WU Guofang
Received:
2023-01-04
Online:
2023-06-05
Published:
2023-05-30
CLC Number:
CHEN Kaiwen, ZHAO Yunjiao, WANG Lei, ZHANG Jianbo, MA Yuhong, WU Guofang. Transcriptome Analysis of Porcine Leydig Cells Under Different Oxygen Concentrations[J]. China Animal Husbandry and Veterinary Medicine, 2023, 50(6): 2185-2195.
[1] RICH P R.The molecular machinery of Keilin's respiratory chain[J].Biochemical Society Transactions, 2003, 31(6):1095-1105. [2] LOPEZ-BARNEO J, PARDAL R, ORTEGA-SÁENZ P.Cellular mechanism of oxygen sensing[J].Annual Review of Physiology, 2001, 63:259-287. [3] HARDIE D G.Minireview:The AMP-activated protein kinase cascade:The key sensor of cellular energy status[J].Endocrinology, 2003, 144(12):5179-5183. [4] BOMHARD E M, GELBKE H P.Hypoxaemia affects male reproduction:A case study of how to differentiate between primary and secondary hypoxic testicular toxicity due to chemical exposure[J].Archives of Toxicology, 2013, 87(7):1201-1218. [5] KONSTADINA G, JAN S, WILSON M H, et al.Caudwell Xtreme Everest:A prospective study of the effects of environmental hypoxia on cognitive functioning[J].PLoS One, 2017, 12(3):e0174277. [6] SCHOLS A M, BROEKHUIZEN R, WELING-SCHEEPERS C A, et al.Body composition and mortality in chronic obstructive pulmonary disease[J].American Journal of Clinical Nutrition, 2005, 82(1):53-59. [7] HOPPELER H, KLEINERT E, SCHLEGEL C, et al.Morphological adaptations of human skeletal muscle to chronic hypoxia[J].International Journal of Sports Medicine, 1990, 11(Suppl 1):S3-S9. [8] MACDOUGALL J D, GREEN H J, SUTTON J R, et al.Operation Everest Ⅱ:Structural adaptations in skeletal muscle in response to extreme simulated altitude[J].Acta Physiologica Scandinavica, 2010, 142(3):421-427. [9] MIZUNO M, SAVARD G K, ARESKOG N H, et al.Skeletal muscle adaptations to prolonged exposure to extreme altitude:A role of physical activity?[J].High Altitude Medicine & Biology, 2008, 9(4):311-317. [10] ARIAS-STELLA J, SALDANA M.The terminal portion of the pulmonary arterial tree in people native to high altitudes[J].Circulation, 1963, 28:915-925. [11] OYEDOKUN P A, AKHIGBE R E, AJAYI L O, et al.Impact of hypoxia on male reproductive functions[J].Molecular and Cellular Biochemistry, 2022, 478(4):875-885. [12] 廖卫公.缺氧对雄性大鼠生殖机能的影响[D].重庆:第三军医大学, 2003. LIAO W G.Effects of hypoxia on reproduction in male rats[D].Chongqing:Army Medical University, 2003.(in Chinese) [13] ATA-ABADI N S, MOWLA S J, ABOUTALEBI F, et al.Hypoxia-related long noncoding RNAs are associated with varicocele-related male infertilit[J].PLoS One, 2020, 15(4):e0232357. [14] WANG J, GONG X, MENG F, et al.Biological network model of effect of chronic intermittent hypoxia on spermatogenesis in rats[J].Medical Science Monitor:International Medical Journal of Experimental and Clinical Research, 2020, 26:e925579. [15] 邓琛耀, 刘娜娜, 范媛媛, 等.高原低氧环境对男性精液质量影响及其机制的研究进展[J].中国男科学杂志, 2020, 34(3):5. DENG C Y, LIU N N, FAN Y Y, et al.Advances in research on the effect of plateau hypoxic environment on the quality of male semen and its mechanism[J].Chinese Journal of Andrology, 2020, 34(3):5.(in Chinese) [16] OYOLA M G, HANDA R J.Hypothalamic-pituitary-adrenal and hypothalamic-pituitary-gonadal axes:Sex differences in regulation of stress responsivity[J]. Stress, 2017, 20(5):476-494. [17] PAYNE A H, YOUNGBLOOD G L.Regulation of expression of steroidogenic enzymes in Leydig cells[J].Biology of Reproduction, 1995, 52(2):217-225. [18] ZIRKIN B R, PAPADOPOULOS V.Leydig cells:Formation, function and regulation[J].Biology of Reproduction, 2018, 99(1):101-111. [19] 徐奎, 黄文强, 洪岭, 等.雄激素治疗男性不育的研究进展[J].世界临床药物, 2019, 40(8):538-541. XU K, HUANG W Q, HONG L, et al.Progress of androgen therapy for male infertility[J].World Clinical Drugs, 2019, 40(8):538-541.(in Chinese) [20] 张阳海, 李永, 曹迪, 等.睾酮对动物生殖和生长发育影响的研究进展[J].家畜生态学报, 2018, 39(1):1-7. ZHANG Y H, LI Y, CAO D, et al.Research progress on effect of testosterone on the animal reproduction and growth[J].Journal of Domestic Animal Ecology, 2018, 39(1):1-7.(in Chinese) [21] 赵健, 桂士良, 崔腾腾, 等.睾酮的生理作用及临床应用进展[J].中国性科学, 2020, 29(1):20-24. ZHAO J, GUI S L, CUI T T, et al.Progress in the physiological role and clinical application of testosterone[J].Chinese Journal of Human Sexuality, 2020, 29(1):20-24.(in Chinese) [22] WANG Y, PAN Y, WANG M, et al.Transcriptome sequencing reveals differences between Leydig cells and sertoli cells of yak[J].Frontiers in Veterinary Science, 2022, 9:960250. [23] 龚未, 潘林林, 林强, 等.基于新一代测序方法的小鼠睾丸出生后发育的转录组研究[J].中国科学(生命科学), 2013, 43(2):137-150. GONG W, PAN L L, LIN Q, et al.Transcriptome analysis of postnatal development of mouse testes based on next-generation sequencing methods[J].Scientia Sinica(Vitae), 2013, 43(2):137-150.(in Chinese) [24] HE Q, ZHAO Z, DAI Z, et al.Transcriptome sequencing analysis of goat testicular tissue[J].IAFOR Journal of Arts & Humanities, 2019, 58(1):45-62. [25] SUN F, LIU S, GAO X, et al.Male-biased genes in catfish as revealed by RNA-Seq analysis of the testis transcriptome[J].PLoS One, 2013, 8(7):e68452. [26] BO D, JIANG X, LIU G, et al.RNA-Seq implies divergent regulation patterns of lncRNA on spermatogenesis and testis growth in goats[J].Animals, 2021, 11(3):625. [27] CAI X, WU S, MIPAM T, et al.Testis transcriptome profiling identified lncRNAs involved in spermatogenic arrest of cattleyak[J].Functional & Integrative Genomics, 2021, 21(5):665-678. [28] 王大瑛, 王宗兰.西宁地区32例婴儿重症肺炎临床分析[J].河北医学, 1998, 4(2):3. WANG D Y, WANG Z L.Clinical analysis of 32 infants with severe pneumonia in Xining area[J].Hebei Medicine, 1998, 4(2):3.(in Chinese) [29] GLEADLE J, RATCLIFFE P.Hypoxia[M].UK:Encyclopedia of Life Sciences, 2001. [30] SIWICKA-GIEROBA D, ROBBA C, GOŁACKI J, et al.Cerebral oxygen delivery and consumption in brain-injured patients[J].Personalized Medicine, 2022, 12(11):1763. [31] WANG X, ZOU Z, YANG Z, et al.HIF1 inhibits StAR transcription and testosterone synthesis in murine Leydig cells[J].Journal of Molecular Endocrinology, 2019, 62:1-13. [32] WILSON E N, ANDERSON M, SNYDER B, et al.Chronic intermittent hypoxia induces hormonal and male sexual behavioral changes:Hypoxia as an advancer of aging[J]. Physiology & Behavior, 2018, 189:64-73. [33] WANG X, PAN L, ZOU Z, et al.Hypoxia reduces testosterone synthesis in mouse Leydig cells by inhibiting NRF1-activated StAR expression[J].Oncotarget, 2017, 8(10):16401-16413. [34] WANG X, JIN L, JIANG S, et al.Transcription regulation of NRF1 on StAR reduces testosterone synthesis in hypoxemic murine[J].The Journal of Steroid Biochemistry and Molecular Biology, 2019, 191:105370. [35] HWANG G S, CHEN S T, CHEN T J, et al.Effects of hypoxia on testosterone release in rat Leydig cells[J].American Journal of Physiology-Endocrinology and Metabolism, 2009, 297(5):E1039-E1045. [36] FOLORUNSHO A A, AKHIGBE R E.Codeine-induced sperm DNA damage is mediated predominantly by oxidative stress rather than apoptosis[J].Redox Report:Communications in Free Radical Research, 2020, 25(1):33-40. [37] RAFF H, HONG J J, OAKS M K, et al.Adrenocortical responses to ACTH in neonatal rats:Effect of hypoxia from birth on corticosterone, StAR, and PBR[J].American Journal of Physiology-Regulatory, Integrative and Comparative Physiology, 2003, 284(1):R78-R85. [38] MA Y, ZHOU Y, ZHU Y C, et al.Lipophagy contributes to testosterone biosynthesis in male rat Leydig cells[J].Endocrinology, 2018, 159(2):1119-1129. [39] SEMENZA G L.HIF-1 and mechanisms of hypoxia sensing[J].Current Opinion in Cell Biology, 2001, 13(2):167-171. [40] SEMENZA G L, SHIMODA L A, PRABHAKAR N R.Regulation of gene expression by HIF-1[J].Novartis Foundation Symposium, 2006, 272:2-8. [41] ERGUR B U, KIRAY M, PEKCETIN C, et al.Protective effect of erythropoietin pretreatment in testicular ischemia-reperfusion injury in rats[J].Journal of Pediatric Surgery, 2008, 43(4):722-728. [42] TAHOON N, ELKHOLY R, ELSAWY S, et al.Effect of erythropoietin on unilateral testicular ischemia/reperfusion injury after torsion/detorsion in rats[J].Bulletin of Egyptian Society for Physiological Sciences, 2014, 34(2):345-356. [43] PENG B, KONG G, YANG C, et al.Erythropoietin and its derivatives:From tissue protection to immune regulation[J].Cell Death & Disease, 2020, 11(2):79. [44] ABLE A A, BURRELL J A, STEPHENS J M.STAT5-interacting proteins:A synopsis of proteins that regulate STAT5 activity[J].Biology (Basel), 2017, 6(1):20. [45] MULLEN M, GONZALEZ-PEREZ R R.Leptin-induced JAK/STAT signaling and cancer growth[J].Vaccines (Basel), 2016, 4(3):26. [46] JOUNG Y H, PARK J H, PARK T, et al.Hypoxia activates signal transducers and activators of transcription 5(STAT5) and increases its binding activity to the GAS element in mammary epithelial cells[J].Experimental & Molecular Medicine, 2003, 35(5):350-357. [47] FATRAI S, WIERENGA A T J, DAENEN S M G J, et al.Identification of HIF2α as an important STAT5 target gene in human hematopoietic stem cells[J].Blood, 2011, 117(12):3320-3330. [48] WAN J, MA J, MEI J, et al.The effects of HIF-1alpha on gene expression profiles of NCI-H446 human small cell lung cancer cells[J]. Journal of Experimental & Clinical Cancer Research, 2009, 28(1):150. [49] MINTER M R, ZHANG M, ATES R C, et al.Type-1 interferons contribute to oxygen glucose deprivation induced neuro-inflammation in BE(2)M17 human neuroblastoma cells[J].Journal of Neuroinflammation, 2014, 11(1):43. [50] CHEN J H, LIN X, BU C, et al.Role of advanced glycation end products in mobility and considerations in possible dietary and nutritional intervention strategies[J].Nutrition & Metabolism, 2018, 15:72. [51] RAMASAMY R, YAN S F, SCHMIDT A M.Receptor for AGE (RAGE):Signaling mechanisms in the pathogenesis of diabetes and its complications[J].Annals of the New York Academy of Sciences, 2011, 1243(1):88-102. [52] SENATUS L M, SCHMIDT A M.The AGE-RAGE axis:Implications for age-associated arterial diseases[J].Frontiers in Genetics, 2017, 8:187. [53] SOMAN S, RAJU R, SANDHYA V K, et al.A multicellular signal transduction network of AGE/RAGE signaling[J].Journal of Cell Communication and Signaling, 2013, 7(1):19-23. [54] LANDER H M, TAURAS J M, OGISTE J S, et al.Activation of the receptor for advanced glycation end products triggers a p21(ras)-dependent mitogen-activated protein kinase pathway regulated by oxidant stress[J].Journal of Biological Chemistry, 1997, 272(28):17810-17814. [55] RUSSO R C, GARCIA C C, TEIXEIRA M M, et al.The CXCL8/IL-8 chemokine family and its receptors in inflammatory diseases[J].Expert Review of Clinical Immunology, 2014, 10(5):593-619. [56] HA H, DEBNATH B, NEAMATI N.Role of the CXCL8-CXCR1/2 axis in cancer and inflammatory diseases[J].Theranostics, 2017, 7(6):1543-1588. [57] BAIRD A M, GRAY S G, O'BYRNE K J.Epigenetics underpinning the regulation of the CXC (ELR+) chemokines in non-small cell lung cancer[J].PLoS One, 2011, 6(1):e14593. [58] PODOLIN P L, BOLOGNESE B J, FOLEY J J, et al.A potent and selective nonpeptide antagonist of CXCR2 inhibits acute and chronic models of arthritis in the rabbit[J].Journal of Immunology, 2002, 169(11):6435-6444. [59] BRAT D J, BELLAIL A C, VAN MEIR E G.The role of interleukin-8 and its receptors in gliomagenesis and tumoral angiogenesis[J].Neuro-Oncology, 2005, 7(2):122-133. [60] XIONG X, LIAO X, QIU S, et al.CXCL8 in tumor biology and its implications for clinical translation[J].Frontiers in Molecular Biosciences, 2022, 9:723846. [61] LI M Q, LUO X Z, MENG Y H, et al.CXCL8 enhances proliferation and growth and reduces apoptosis in endometrial stromal cells in an autocrine manner via a CXCR1-triggered PTEN/Akt signal pathway[J].Human Reproduction, 2012, 27(7):2107-2116. [62] MOJSILOVIC-PETROVIC J, CALLAGHAN D, CUI H, et al.Hypoxia-inducible factor-1(HIF-1) is involved in the regulation of hypoxia-stimulated expression of monocyte chemoattractant protein-1(MCP-1/CCL2) and MCP-5(Ccl12) in astrocytes[J].Journal of Neuroinflammation, 2007, 4:12. [63] MAROTTA D, KARAR J, JENKINS W T, et al.In vivo profiling of hypoxic gene expression in gliomas using the hypoxia marker EF5 and laser-capture microdissection[J].Cancer Research, 2011, 71(3):779-789. [64] HERWARTZ C, CASTILLO-JUÁREZ P, SCHRÖDER L, et al.The transcription factor ZNF395 is required for the maximal hypoxic induction of proinflammatory cytokines in U87-MG cells[J]. Mediators of Inflammation, 2015, 2015:804264. [65] BOSCO M C, PUPPO M, SANTANGELO C, et al.Hypoxia modifies the transcriptome of primary human monocytes:Modulation of novel immune-related genes and identification of CC-chemokine ligand 20 as a new hypoxia-inducible gene[J].Journal of Immunology, 2006, 177(3):1941-1955. [66] HIRANI N, ANTONICELLI F, STRIETER R M, et al.The regulation of interleukin-8 by hypoxia in human macrophages-A potential role in the pathogenesis of the acute respiratory distress syndrome (ARDS)[J].Molecular Medicine, 2001, 7(10):685-697. [67] BOSCO M C, PUPPO M, PASTORINO S, et al.Hypoxia selectively inhibits monocyte chemoattractant protein-1 production by macrophages[J].Journal of Immunology, 2004, 172(3):1681-1690. [68] TRIPATHI C, TEWARI B N, KANCHAN R K, et al.Macrophages are recruited to hypoxic tumor areas and acquire a pro-angiogenic M2-polarized phenotype via hypoxic cancer cell derived cytokines oncostatin M and eotaxin[J].Oncotarget, 2014, 5(14):5350-5368. [69] CHEN X J, DENG Y R, WANG Z C, et al.Hypoxia-induced ZEB1 promotes cervical cancer progression via CCL8-dependent tumour-associated macrophage recruitment[J].Cell Death & Disease, 2019, 10(7):508. [70] KONISHI H, SHIRABE K, NAKAGAWARA H, et al.Suppression of silent information regulator 1 activity in noncancerous tissues of hepatocellular carcinoma:Possible association with non-B non-C hepatitis pathogenesis[J].Cancer Science, 2015, 106(5):542-549. [71] JIANG Q, MARESCH C C, PETRY S F, et al.Elevated CCL2 causes Leydig cell malfunction in metabolic syndrome[J].JCI Insight, 2020, 5(21):e134882. |
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