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三维回转模拟微重力对拟南芥根尖基因表达谱的影响 被引量:1

Effects of 3-D Clinostat Induced Microgravity on Gene Expression of Arabidopsis Root Tip
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摘要 目的从分子水平上分析和阐述植物根尖对模拟微重力效应的反应。方法以三维回转仪模拟微重力效应,回转处理7 d大小的拟南芥幼苗15 min。利用基因芯片技术,分析模拟微重力下拟南芥mR-NA表达谱的变化。结果拟南芥根尖细胞有392个基因的表达发生了显著变化,其中347个基因表达上调,45个基因表达发生下调。结论模拟微重力效应可以影响拟南芥根尖基因的表达,这些差异表达基因的功能涉及到植物的许多生命过程,包括抗逆反应、细胞壁物质合成、基因转录和信号转导等。 Objective To analyze the responses of Arabidopsis root tip to microgravity stimulation from the cellu- lar level. Methods Seven-day old Arabidiosis seedlings were treated with the 3-D elinostat for 15 min to simu- late the microgravity. The mRNA expression profile of Arabidopsis root tip after simulated mierogravity was an- alyzed with microarray. Results Three hundred and thirty-two gene expressions changed signifieantly including 347 up-regulated genes and 45 down-regulated genes. Conclusion Microgravity ean affect the gene expression of Arabidopsis root tip. The function of these genes involve in many life proeesses of plants ineluding stress re- sistance response, cell wall material synthesis, gene transcription, protein synthesis and signal transduetion. Key words : simulated microgravity ;Arabidopsis ; root tip ; microarray ; gene expression
作者 李华盛 鹿金颖 刘敏 袁辉
机构地区 中国空间技术研究院空间分子生物学实验室 中国科学院遗传与发育生物学研究所
出处 《航天医学与医学工程》 CAS CSCD 北大核心 2012年第5期330-334,共5页 Space Medicine & Medical Engineering
基金 国家自然科学基金资助项目(31070769) 国家重点基础研究发展计划(2011CB710902) 中国载人航天工程资助项目
关键词 模拟微重力 拟南芥 根尖 芯片 基因表达 simulated microgravity Arabidopsis root tip microarray gene expression
分类号 Q693 [生物学—生物物理学]
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参考文献14

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同被引文献15

  • 1潘毅,薛淮,鹿金颖,张纯花,刘敏.空间环境与模拟微重力环境对高等植物试管苗的影响[J].科技导报,2007,25(19):36-42. 被引量:12
  • 2Paul AL, Dangherty CJ, Bihn EA, et al. Transgene expres- sion patterns indicate that spaceflight affects stress signal per- ception and transduction in Arabidopsis [ J ]. Plant Physiolo- bY, 2001, 126(2) : 613-621.
  • 3Kiss JZ, Kumar P, Millar KDL, et al. Operations of a space- flight experiment to investigate plant tropisms [ J ]. Advances in Space Research, 2009, 44(8) : 879-886.
  • 4Ferl RJ, Paul AL. Lunar plant biology-A review of the Apollo Era[J]. Astrobiology, 2010, 10(3) : 261-274.
  • 5Millar KDL, Johnson CM, Edelmann RE, et al. An endoge- nous growth pattern of roots Is revealed in seedlings grown in microgravity [J]. Astrobiology, 2011, 11(8) : 787-797.
  • 6Musgrave ME, Kuang AX, Brown CS, et al. Changes in Ara- bidopsis leaf ultrastructure, chlorophyll and carbohydrate con- tent during spaceflight depend on ventilation [ J ]. Annals of Botany, 1998, 81 (4): 503-512.
  • 7Dutcher FR,Hess EL, Halstead TW. Progress in plant re- search in-space[C]. In: Cogali A, Cogoli GM, Gruener R, et al. (cds). Life Sciences and Space Research Xxv. Vol- ume 14. Oxford: Pergamon Press Ltd, 1994:159-171.
  • 8Stutte GW,Monje O, Haffield RD, et al. Microgravity effects on leaf morphology, cell structure, carbon metabolism and mRNA expression of dwarf wheat [ J]. Planta, 2006, 224 (5) : 1038-1049.
  • 9Merkys AJ, Lanrinavichius RS, Rupainene OJ, et al. The state of gravity sensors and peculiarities of plant growth during different gravitational loads[ J]. Advances in space research : the official journal of the Committee on Space Research ( COS- PAR), 1983, 3(9): 211-219.
  • 10Musgrave ME,Kuang AX, Xiao Y, et al. Gravity independ- ence of seed-to-seed cycling in Brassica rapa [ J ]. Planta, 2000, 210(3): 400-406.

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航天医学与医学工程
2012年 第5期

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