水平回转培养对斑马鱼血管发育的影响

doi:10.3724/SP.J.1005.2013.00502

遗传 ›› 2013, Vol. 35 ›› Issue (4): 502-510.doi: 10.3724/SP.J.1005.2013.00502

水平回转培养对斑马鱼血管发育的影响

孙婷¹, 谢翔¹, 张剑卿¹, 包静¹, 汤川政¹, 雷道希¹, 邱菊辉^1,2, 王贵学¹

1. 重庆大学生物工程学院力-发育生物学研究室, 生物流变科学与技术教育部重点实验室, 重庆市血管植入物工程实验室, 重庆 400044 2. 清华大学生命科学学院, 生物膜与膜工程国家重点实验室, 北京 100084

收稿日期:2012-11-01 修回日期:2013-01-01 出版日期:2013-04-20 发布日期:2013-04-25
通讯作者: 王贵学 E-mail:wanggx@cqu.edu.cn
基金资助:
国家重大科学研究计划项目(编号：2012CB945101)和重庆国家生物产业基地公共实验中心建设项目(编号：发改办高技【2008】1692号)资助

Effect of horizontal rotary culture on zebrafish vascular development

SUN Ting¹, XIE Xiang¹, ZHANG Jian-Qing¹, BAO Jing¹, TANG Chuan-Zheng¹, LEI Dao-Xi¹, QIU Ju-Hui^1,2, WANG Gui-Xue¹

1. Key Laboratory of Biorheological Science and Technology (Chongqing University), Ministry of Education; Chongqing Engineering Laboratory in Vascular Implants; Laboratory of Mechano-developmental Biology, Bioengineering College of Chongqing University, Chongqing 400044, China 2. The State Key Laboratory of Biomembrane and Membrane Biotechnology, School of Life Sciences, Tsinghua University, Beijing 100084, China

Received:2012-11-01 Revised:2013-01-01 Online:2013-04-20 Published:2013-04-25

摘要/Abstract

摘要： 随着空间生命科学的发展, 微重力对生命体的影响已成为科学家们日益关注的问题。多数研究表明, 微重力对生物体胚胎早期发育有着重要影响, 而血管系统作为胚胎最早行使功能的系统备受关注。目前关于微重力对血管发育影响的研究大多来自对离体培养细胞的体外回转模拟实验, 在体实验相对较少。文章利用斑马鱼作为模式动物, 在体探究水平回转培养环境下斑马鱼胚胎早期发育及水平回转培养对其血管系统发育的影响。在斑马鱼受精后24 h(24 hpf)时进行水平回转培养处理, 至36 hpf时收集胚胎, 通过体视显微镜观察斑马鱼表型变化, 通过半定量RT-PCR、qPCR及全胚原位杂交等手段对比水平回转培养环境下与对照组血管相关因子的表达情况, 并通过BrdU掺入及TUNEL法进行斑马鱼全胚细胞凋亡及增殖检测。结果表明, 在90 r/min水平回转培养环境下, 斑马鱼死亡数量没有差异, 24 hpf时破壳数量显著降低(10.3±0.41 vs. 0.0, P<0.05), 心率显著加快(223.5±2.32 vs. 185.0±3.23, P<0.05), 黑色素明显增加, 动静脉发育紊乱, 且在120 r/min转速下, 胚胎血管特异性表达因子flk1、flt4及 ephrinB2的表达均显著降低, 斑马鱼细胞凋亡明显增加, 而细胞增殖无显著差异, 提示水平回转培养对斑马鱼胚胎发育特别是早期血管发育具有重要影响。

关键词: 斑马鱼, 水平回转培养, 血管发育

Abstract: With the development of space life science, a study on the influence of microgravity on organism has been an increasingly concerned topic. Lots of studies indicate that microgravity plays an important role in the early development of embryos. The vascular system as the first-function system of embryos provides an interesting topic for many researchers. However, those studies were mostly carried out in vitro by rotary cell culture system (RCCS), while few experiments were done in vivo. Using zebrafish as a model, this research investigated the effects of horizontal rotary culture on the vascular development in vivo. Zebrafish embryos at 24 hpf (hour post-fertilization) were selected and divided into two groups. One group was cultured by the shaker, and the other was cultured normally as the control. After 12 h, all the embryos were collected and detected. The phenotype of zebrafish was observed by stereo microscope. Then, the expression of vascular specific expression factor, flk1, flt4, and ephrinB2 was compared by RT-PCR, qPCR, and in situ hybridization, respectively. Cell apoptosis and proliferation in situ were observed using TUNEL assay and bromodeoxyuridine incorporation. The results demonstrated that horizontal rotary culture at 90 r/min decreased the hatching of embryos (10.3±0.41 vs. 0.0, P<0.05), accelerate the heart rate (223.5±2.32 vs. 185.0±3.23, P<0.05) and increased the content of melanin in zebrafish significantly. At the same time, we found some differences in the vascular system of zebrafish after horizontal rotary culture which caused a down regulation of flk1, flt4, and ephrinB2. On the other hand, horizontal rotary culture accelerated the apoptosis of cells in zebrafish, but showed no significance in proliferation. In conclusion, horizontal rotary culture has a significant influence on the vascular development in zebrafish.

Key words: zebrafish, horizontal rotary culture, vascular development

孙婷谢翔张剑卿包静汤川政雷道希邱菊辉王贵学. 水平回转培养对斑马鱼血管发育的影响[J]. 遗传, 2013, 35(4): 502-510.

SUN Ting XIE Xiang ZHANG Jian-Qing BAO Jing TANG Chuan-Zheng LEI Dao-Xi QIU Ju-Hui WANG Gui-Xue. Effect of horizontal rotary culture on zebrafish vascular development[J]. HEREDITAS, 2013, 35(4): 502-510.

参考文献

[1] Crawford-Young SJ. Effects of microgravity on cell cy-toskeleton and embryogenesis. Int J Dev Biol, 2006, 50(2-3): 183-191.
[2] Suda T, Abe E, Shinki T, Katagiri T, Yamaguchi A, Yokose S, Yoshiki S, Horikawa H, Cohen GW, Yasugi S, Naito M. The role of gravity in chick embryogenesis. FEBS Lett, 1994, 340(1-2): 34-38.
[3] Jung SY, Bowers SD, Willarda ST. Simulated microgravity influences bovine oocyte in vitro fertilization and preimplantation embryo development. J Anim Vet Adv, 2009, 8(9): 1807-1814.
[4] Wang YL, An LL, Jiang YD, Hang HY. Effects of simu-lated microgravity on embryonic stem cells. PLoS One, 2011, 6(12): e29214.
[5] Kawahara Y, Manabe T, Matsumoto M, Kajiume T, Matsumoto M, Yuge L. LIF-free embryonic stem cell cul-ture in simulated microgravity. PLoS One, 2009, 4(7): e6343.
[6] 刘卫生, 王英杰, 刘涛, 张世昌. 模拟微重力条件下小鼠拟胚体形成及分化的初步观察. 第三军医大学学报, 2008, 30(17): 1594-1597.
[7] Kang CY, Zou L, Yuan M, Wang Y, Li TZ, Zhang Y, Wang JF, Li Y, Deng XW, Liu CT. Impact of simulated micro-gravity on microvascular endothelial cell apoptosis. Eur J Appl Physiol, 2011, 111(9): 2131-2138.
[8] Sanford GL, Ellerson D, Melhado-Gardner C, Sroufe AE, Harris-Hooker S. Three-dimensional growth of endothelial cells in the microgravity-based rotating wall vessel bioreactor. In Vitro Cell Dev Biol Anim, 2002, 38(9): 493-504.
[9] 张华, 王强, 贾秀志, 唐建民, 郭涛, 王丽群, 赵育莹, 张凤蕴. 模拟微重力对人脐静脉内皮细胞微丝骨架的影响. 哈尔滨医科大学学报, 2008, 42(6): 553-555.
[10] Infanger M, Kossmehl P, Shakibaei M, Baatout S, Witzing A, Grosse J, Bauer J, Cogoli A, Faramarzi S, Derradji H, Neefs M, Paul M, Grimm D. Induction of three-dimensional assembly and increase in apoptosis of human endo-thelial cells by simulated microgravity: impact of vascular endothelial growth factor. Apoptosis, 2006, 11(5): 749-764.
[11] Hwang S, Shelkovnikov SA, Purdy RE. Simulated micro-gravity effects on the rat carotid and femoral arteries: role of contractile protein expression and mechanical properties of the vessel wall. J Appl Physiol, 2007, 102(4): 1595-1603.
[12] 全珊珊, 吴新荣. 斑马鱼, 人类疾病研究的理想模式动物. 生命的化学, 2008, 28(3): 260-262.
[13] 张蕊, 黄华. 水平旋转生物反应器的微重力环境分析. 技术与市场, 2009, 19(7): 37-38.
[14] Dutt K, Sanford G, Harris-Hooker S, Brako L, Kumar R, Sroufe A, Melhado C. Three-dimensional model of angio-genesis: coculture of human retinal cells with bovine aortic endothelial cells in the NASA bioreactor. Tissue Eng, 2003, 9(5): 893-908.
[15] Siamwala JH, Majumder S, Tamilarasan KP, Muley A, Reddy SH, Kolluru GK, Sinha S, Chatterjee S. Simulated microgravity promotes nitric oxide-supported angiogenesis via the iNOS-cGMP-PKG pathway in macrovascular endothelial cells. FEBS Lett, 2010, 584(15): 3415-3423.
[16] Infanger M, Ulbrich C, Baatout S, Wehland M, Kreutz R, Bauer J, Grosse J, Vadrucci S, Cogoli A, Derradji H, Neefs M, Küsters S, Spain M, Paul M, Grimm D. Modeled gravitational unloading induced downregulation of endo-thelin-1 in human endothelial cells. J Cell Bio-chem, 2007, 101(6): 1439-1455.
[17] Hargens AR, Richardson S. Cardiovascular adaptations, fluid shifts, and countermeasures related to space flight. Respir Physiol Neurobiol, 2009, 169(Supp 1): S30-S33.
[18] Tank J, Baevsky RM, Funtova II, Diedrich A, Slepchenkova IN, Jordan J. Orthostatic heart rate responses after prolonged space flights. Clin Auton Res, 2011, 21(2): 121-124.
[19] Grimm D, Bauer J, Ulbrich C, Westphal K, Wehland M, Infanger M, Aleshcheva G, Pietsch J, Ghardi M, Beck M, El-Saghire H, de Saint-Georges L, Baatout S. Different responsiveness of endothelial cells to vascular endothelial growth factor and basic fibroblast growth factor added to culture media under gravity and simulated microgravity. Tissue Eng Part A, 2010, 16(5): 1559-1573.
[20] Grosse J, Wehland M, Pietsch J, Ma X, Ulbrich C, Schulz H, Saar K, Hübner N, Hau

编辑推荐

Metrics

www.chinagene.cn
备案号：京ICP备09063187号-4
总访问:,今日访问:,当前在线:

水平回转培养对斑马鱼血管发育的影响

Effect of horizontal rotary culture on zebrafish vascular development

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

[1]	李凯伦, 卢荆奥, 陈小辉, 张文清, 刘伟. 尿囊素促进破骨细胞缺陷斑马鱼骨折修复[J]. 遗传, 2023, 45(4): 341-353.
[2]	卢荆澳, 黄春燕, 林芷茵, 唐政, 马宁, 黄志斌. cd99l2基因调控斑马鱼白细胞组织间的迁移机制[J]. 遗传, 2022, 44(9): 798-809.
[3]	郑鹏飞, 谢海波, 朱盼盼, 赵呈天. 斑马鱼神经底板处神经元的分布及特征[J]. 遗传, 2022, 44(6): 510-520.
[4]	张婷婷, 刘峰. 斑马鱼蛋白酪氨酸硫酸化修饰的检测方法研究[J]. 遗传, 2022, 44(2): 178-186.
[5]	贾婷婷, 雷蕾, 吴歆媛, 蔡顺有, 陈艺璇, 薛钰. 二甲双胍对斑马鱼骨骼发育及损伤修复的机制研究[J]. 遗传, 2022, 44(1): 68-79.
[6]	郭佳妮, 刘帆, 王璐. 斑马鱼血液疾病模型及应用[J]. 遗传, 2020, 42(8): 725-738.
[7]	熊凤,谢训卫,潘鲁媛,李阔宇,柳力月,张昀,李玲璐,孙永华. 国家斑马鱼资源中心的资源、技术和服务建设[J]. 遗传, 2018, 40(8): 683-692.
[8]	许璟瑾, 张文娟, 王静怡, 姚丽云, 潘裕添, 欧一新, 薛钰, . 金线莲抑制斑马鱼黑色素形成的活性组分筛选及机理研究[J]. 遗传, 2017, 39(12): 1178-1187.
[9]	刘姗姗, 张翠珍, 彭刚. 饥饿对幼年斑马鱼下丘脑摄食相关性神经肽表达的影响[J]. 遗传, 2016, 38(9): 821-830.
[10]	张峰华,王厚鹏,黄思雨,熊凤,朱作言,孙永华. 两种密码子优化的Cas9编码基因在斑马鱼胚胎中基因敲除效率的比较[J]. 遗传, 2016, 38(2): 144-154.
[11]	顾爱华严丽锋. 斑马鱼在再生医学研究中的应用及进展[J]. 遗传, 2013, 35(7): 856-866.
[12]	李礼，罗凌飞. 以斑马鱼为模式动物研究器官的发育与再生[J]. 遗传, 2013, 35(4): 421-432.
[13]	徐冉冉张从伟曹羽王强. 缺失mir122抑制斑马鱼肝脏前体细胞向肝细胞分化[J]. 遗传, 2013, 35(4): 488-494.
[14]	沈延黄鹏张博. TALEN构建与斑马鱼基因组定点突变的实验方法与流程[J]. 遗传, 2013, 35(4): 533-544.
[15]	李辉辉黄萍董巍朱作言刘东. 斑马鱼研究走向生物医学[J]. 遗传, 2013, 35(4): 410-420.