玉米ZmHsf04基因的克隆和特性及其对耐热性的调控

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摘要摘要植物热激转录因子(heat shock transcription factor, Hsf)能够与热激蛋白基因启动子区域的热激元件结合而直接启动热激反应，因此成为热胁迫下基因转录激活信号转导通路中重要的调控因子。前人推测玉米(Zea mays)中至少有30个Hsf家族成员，其中A族18个，A2亚族4个。本实验室在前期对A1亚族ZmHsf06结构、特性及其抗旱耐热性功能研究的基础上，采用同源克隆技术，从玉米幼叶中克隆获得A2亚族基因ZmHsf04(GenBank登录号: GRMZM2G010871_P01)的完整编码序列，序列全长1 074 bp，编码357个氨基酸残基。蛋白质结构包含Hsf家族DNA结合结构域，含有核定位信号(KRKELEDTISKKRRR)、核输出信号(LAQQLGYL)和激活结构域(LKMFESGVLN)等完整的功能结构域。蛋白序列与高粱(Sorghum bicolor) SORBIDRAFT_01g021490的同源性最高，达90%。荧光定量分析表明，正常生长条件下ZmHsf04在玉米多个组织器官中表达，幼嫩花粉中表达较高，约为幼嫩根系对照的16倍；ZmHsf04的表达水平受42 ℃热胁迫和外源脱落酸(abscisic acid, ABA)显著上调，最高表达量达正常对照的340倍，叶片峰值出现的时间分别为30 min和24 h；ZmHsf04也受水杨酸(SA)和H2O2上调表达，上调幅度低于热处理，最高表达量不超过12倍，显著低于热激或ABA处理，峰值出现相对滞后；用SA和H2O2分别预处理再热激，ZmHsf04的表达水平无明显差异。通过在洋葱(Allium cepa)表皮细胞中瞬时表达并观察绿色荧光蛋白(green fluorescence protein, GFP)荧光发现，ZmHsf04定位于细胞核。通过将ZmHsf04转化酵母(Saccharomyces cerevisiae)并进行50 ℃水浴热胁迫处理发现，ZmHsf04在酵母中可被半乳糖诱导蛋白表达，热胁迫同时降低正常和转ZmHsf04酵母的生长势，但与转空载体对照相比，转ZmHsf04基因酵母表现更强的耐热性。研究结果表明，ZmHsf04在植株花粉发育和热胁迫响应过程中可能发挥重要的调控功能。该研究为进一步解析ZmHsf04的功能及其调控机制提供理论和技术依据。

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	赵立娜
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关键词 ：玉米, 热激转录因子ZmHsf04, 亚细胞定位, 耐热性

Abstract：Abstract Heat shock transcription factors (Hsfs) are the central regulators of the heat shock responsive genes that encode Hsps, and can specifically bind to heat shock elements (HSE) in the upstream promoter region of heat shock protein genes to realize the regulation to these genes. There are at least 30 Hsf members in maize(Zea mays) Hsf family which includes 18 members of class A, among which there are 4 Hsfs of subclass A2. In our previous work, the structure, characteristics and regulating roles in thermotolerance and drought-stress tolerance of ZmHsf06 have been investigated. In present study, ZmHsf04 was cloned from maize young leaves treated by heat shock at 42 ℃ for 1 h using homologous cloning methods. The coding sequence (CDS) of ZmHsf04 was 1 074 bp encoding a protein of 357 amino acids. Protein sequence of ZmHsf04 contained DNA-binding domain (DBD) and other functional domains such as a nuclear localization signal(NLS)of KRKELEDTISKKRRR, NES(LAQQLGYL) and AHA(LKMFESGVLN). Homologous analysis showed that ZmHsf04 protein sequence shared 90%, 86% and 78% identities with the hypothetical protein SORBIDRAFT_01g021490(XP_002467215.1) of Sorghum bicolor, SiHsfA2c-like(XP_012698415.1) of Setaria italic and OsHsfA2c-like(XP_006661780.2) of Oryza brachyantha, respectively. qRT-PCR results showed that ZmHsf04 was expressed in multiple tissues and organs of maize. Compared with young leaf, young root, stem, functional leave, immature embryo and ear, transcriptional expression level of ZmHsf04 was the highest in pollens with the value of 16 times of the control. ZmHsf04 expression was up-regulated significantly by both 42 ℃ heat shock and abscisic acid (ABA), the highest value reached 340 times of the control, and the peak values appeared at 30 min and 24 h, respectively. Meanwhile, ZmHsf04 expression was up-regulated by both salicylic acid(SA) and H2O2, and the highest value was 12 times of the control, and was significantly lower than that treated by HS or ABA. If pretreated with SA or H2O2 and then heat shock (HS), the ZmHsf04 expression was similar to that treated with HS. Through transient reporter assay with onion (Allium cepa) epidermal cells, it was found that ZmHsf04 was located in nuclei. ZmHsf04 protein could be induced by Gal in yeast (Saccharomyces cerevisiae), and yeast overexpressing pYES2-ZmHsf04 showed stronger growth potential than the controls expressing pYES2 after HS, though yeast growth potential was decreased by HS. The results revealed that ZmHsf04 perhaps played a key role in regulating pollen development and the response to heat stress. These results will provide theoretical basis for analysis biological functions and regulating mechanism of ZmHsf04 further.

Key words： Maize Zea mays heat shock transcription factor 04 gene (ZmHsf04) Subcelullar-location Thermotolerance

收稿日期: 2017-03-02 出版日期: 2017-08-06

基金资助:河北省自然科学基金项目;河北省财政厅高层次人才项目

通讯作者: 郭秀林 E-mail: myhf2002@163.com

引用本文:

赵立娜张华宁段硕楠郭秀林李国良. 玉米ZmHsf04基因的克隆和特性及其对耐热性的调控[J]. , 2017, 25(9): 1411-1422.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/ 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2017/V25/I9/1411

[1]Ayarpadikannan S, Chung E, Cho C W, et al. Exploration for the salt stress tolerance genes from a salt-treated halophyte, Suaeda asparagoides[J]. Plant Cell Report, 2012, 31(1): 35-48.
[2]Aranda M A, Escaler M, Thomas C L, et al. A heat shock transcription factor in pea is differentially controlled by heat and virus replication[J]. The Plant Journal, 1999, 20(2): 153-161.
[3]Brameier M, Krings A, MacCallum R M. NucPredpredicting nuclear localization of proteins[J]. Bioinformatics, 2007, 23(9): 1159-1160.
[4]Busch W, Wunderlich M, Sch?ffl F. Identification of novel heat shock factor-dependent genes and biochemical pathways in Arabidopsis thaliana[J]. The Plant Journal, 2005, 41(1): 1-14.
[5]Charng Y Y, Liu H C, Liu N Y, et al. A heat-induced transcription factor, HsfA2, is required for extension of acquired thermotolerance in Arabidopsis[J]. Plant Physiology, 2007, 143(1): 251-262.
[6]党姣, 蒋明义, 林凡. ABA上调水稻叶片OsHSF 基因的表达[J]. 南京农业大学学报, 2010, 33(1): 11-15.
[7]Gaffney T, Friedrich L, Vernooij B, et al. Requirement of salicylic acid for the induction of systemic acquired resistance[J]. Science, 1993, 261(5122): 754-756.
[8]Gagliardi D, Breton C, Chaboud A, et al. Expression of heat shock factor and heat shock protein 70 genes during maize pollen development[J]. Plant Molecular and Biology, 1995, 29(4): 841-856.
[9]Gietz D, Jean A S, Woods R A, et al. Improved method for high transformation of intact yeast cells[J]. Nucleic Acids Research, 1992, 20(6): 1425-1425.
[10]Guo M, Liu H J. Ma X. The plant heat stress transcription factors(HSFs): structure, regulation and function in response to aboitic stresses[J]. Frontier Plant Science, 2016, 7(273): 1-14.
[11]Heerklotz D, D?ring P, Bonzelius F. The balance of nuclear import and export determines the intrancellular distribution and function of tomato heat stress transcription factor HsfA2[J]. Molecular and Cellular Biology, 2001, 21(5): 1759-1768.
[12]Huang X Y, Tao P, Li B Y, et al. Genome-wide identification, classification, and analysis of heat shock transcription factor family in Chinese cabbage (Brassica rapa pekinensis) [J]. Genetics and Molecular Research, 2015, 14(1): 2189-2204.
[13]La Cour T, Kiemer L, Molgaard A, et al. Analysis and prediction of leucine-rich nuclear export signals[J]. Protein Engineering Design and Selection, 2004, 17(6): 527-536.
[14]Larkindale J, Hall J D, Knight M R, et al. Heat stress phenotypes of Arabidopsis mutants implicate multiple signaling pathways in the acquisition of thermotolerance[J]. Plant Physiology, 2005, 138(2): 882-897.
[15]李春光, 陈其军, 高新起, 等. 拟南芥热激转录因子AtHsfA2调节胁迫反应基因的表达并提高热和氧化胁迫耐性[J]. 中国科学C辑: 生命科学, 2005, 35(5): 398-407.
[16]李慧聪, 李国良, 郭秀林. 玉米热激转录因子基因ZmHsf-Like对逆境胁迫响应的信号途径[J]. 作物学报, 2014, 40(4): 622-628.
[17]李慧聪, 李国良, 郭秀林. 玉米热激转录因子基因(ZmHsf06)的克隆表达和定位分析[J]. 农业生物技术学报, 2015, 23(1): 41-51.
[18]Liu H C, Charng Y Y. Common and distinct functions of Arabidopsis Class A1 and A2 heat shock factors in diverse abiotic stress responses and development[J]. Plant Physiology, 2013, 163(1): 276-290.
[19]Li H C, Li G L, Liu Z H, et al. Cloning, localization and expression of ZmHsf-Like in Zea mays[J]. Journal of Integrative Agriculture, 2014, 13(6): 1230-1238.
[20]Li H C, Zhang H N, Li G L, et al. Expression of maize heat shock transcription factor gene ZmHsf06 enhances the thermotolerance and drought-stress tolerance of transgenic Arabidopsis [J]. Functional Plant Biology, 2015, 42(11): 1080-1090.
[21]Li H X, Fan R C, Li L B, et al. Identification and characterization of a novel copper transporter gene family TaCT1 in common wheat[J]. Plant Cell and Environment, 2013, 37(7): 1561-1573.
[22]Lin Y X, Jiang H Y, Chu Z X, et al. Genome-wide identification, classification and analysis of heat shock transcription factor family in maize[J]. BMC Genomics, 2011, 12(1): 76-89.
[23]Liu H C, Charng Y Y. Common and distinct functions of Arabidopsis Class A1 and A2 heat shock factors in diverse abiotic stress responses and development[J]. Plant Physiology, 2013, 163(1): 276-290.
[24]Liu H C, Liao H T, Charng Y Y. The role of class A1 heat shock factors (HSFA1s) in response to heat and other stresses in Arabidopsis[J]. Plant Cell and Environment, 2011, 34(5): 738-751.
[25]Lohmann C, Eggers- Schumacher G, Wunderlich M, et al. Two different heat shock transcription factors regulate immediate early expression of stress genes in Arabidopsis[J]. Molecular Genetics and Genomics, 2004, 271(1): 11-21.
[26]Lyck R, Harmening U, H?hfeld I, et al. Intracellular distribution and identification of the nuclear localization signals of two tomato heat stress transcription factors[J]. Planta, 1997, 202(1): 117-125.
[27]Mittal D, Chakrabarti S, Sarkar A, et al. Heat shock factor gene family in rice: genomic organization and transcript expression profiling in response to high temperature, low temperature and oxidative stresses[J]. Plant Physiology and Biochemistry, 2009, 47(9): 785-795.
[28]Nishizawa A, Yabuta Y, Yoshida E, et al. Arabidopsis heat shock transcription factor A2 as a key regulator in response to several types of environmental stress[J]. Plant Journal, 2006, 48(4): 535-547.
[29]Nishizawa- Yokoi A, Nosaka R, Hayashi H, et al. HsfA1d and HsfA1e involved in the transcriptional regulation of HsfA2 function as key regulators for the Hsf signaling network in response to environmental stress[J]. Plant Cell and Physiology, 2011, 52(5): 933-945.
[30]Nover L, Bharti K, D?ring P, et al. Arabidopsis and the heat stress transcription factor world: How many heat stress transcription factors do we need[J]. Cell Stress Chaperones, 2001, 6(3): 177-189.
[31]Nover L, Scharf K D, Gagliardi D, et al. The Hsf world: Classification and properties of plant heat stress transcription factors[J]. Cell Stress Chaperones, 1996, 1(4): 215-223.
[32]Ogawa D, Yamaguchi K, Nishiuchi T. High-level overexpression of the Arabidopsis HsfA2 gene confers not only increased themotolerance but also salt/osmotic stress tolerance and enhanced callus growth[J]. Journal of Experimental Botany, 2007, 58(12): 3373-3383.
[33]秦伟，赵光耀，曲志才，等. 小麦白粉病诱导的TaWRKY34基因的鉴定与分析[J]. 作物学报, 2010, 36(2): 249–255.
[34]Scharf K D, Heider H, H?hfeld I, et al. The tomato Hsf system: HsfA2 needs interaction with HsfA1 for efficient nuclear import and may be localized in cytoplasmic heat stress granules[J]. Molecular and Cellular Biology, 1998, 18(4): 2240-2251.
[35]Scharf K D, Rose S, Zott W, et al. Three tomato genes code for heat stress transcription factors with a region of remarkable homology to the DNA-binding domain of the yeast HSF[J]. EMBO Journal, 1990, 9(13): 4495-4501.
[36]Schramm F, Ganguli A, Kiehlmann E, et al. The heat stress transcription factor HSFA2 serves as a regulatory amplifier of a subset of genes in the heat stress response in Arabidopsis[J]. Plant Molecular Biology, 2006, 60(5): 759-772.
[37]Snyman M, Cronjé M J. Modulation of heat shock factors accompanies salicylic acid-mediated potentiation of Hsp70 in tomato seedlings[J]. Journal of Experimental Botany, 2008, 59(8): 2125-2132.
[38]Wang J, Sun N, Deng T, et al. Genome-wide cloning, identification, classification and functional analysis of cotton heat shock transcription factors in cotton (Gossypium hirsutum) [J]. BMC Genomics, 2014, 15(1): 1-19.
[39]Xue G P, Sadat S, Drenth J, et al. The heat shock factor family from Triticum aestivum in response to heat and other major abiotic stresses and their role in regulation of heat shock protein genes[J]. Journal of Experimental Botany, 2014, 65(2): 539-557.