大豆耐铝毒候选基因GmSTOP1的克隆与表达分析

doi:10.3724/SP.J.1006.2015.01802

Abstract

Abstract:

Aluminum toxicity is one of the major factors that limits the growth and production of crops in acid soils. AtSTOP1 transcription factors can regulate the expression of genes related to aluminum-toxicity tolerance mechanisms, which plays an important role in aluminum-toxicity tolerance in Arabidopsis. To study the expression features of the STOP1-like gene in soybean, we cloned a STOP1 gene located on chromosome 16 from the aluminum-toxicity tolerant soybean cultivar (Kefeng-1) using RT-PCR, and designated as GmSTOP1. The length of GmSTOP1 coding DNA sequence was 1566 bp, which encoded 521 amino acid residues. Diverse cis-acting promoter elements involved in hormone, heat and stress responses were discovered in the 1500 bp upstream region of GmSTOP1, such as ABRE, HSE, TC-rich repeats, and other elements. Protein structure prediction showed that it did not have any signal-peptide or transmembrane region, but contained four conservative Cys-2-His-2 zinc-finger domains. Phylogenetic analysis demonstrated that GmSTOP1 was similar to the putative STOP1-like protein from Phaseolus vulgaris. Results of subcellular localization showed that GmSTOP1 protein is located in the cell nucleus. The transcripts of GmSTOP1 were detected in all organs tested including root, shoot apical meristem, stem, leaf, flower, pod and seed, with the highest level in seed. GmSTOP1 was up-regulated in soybean roots by 25 μmol L^–¹ AlCl₃ treatment, and reached the highest relative expression level at 24 hours, which was about 9.2 times of the level in control (0 μmol L^–¹ AlCl₃). In addition, Real-time PCR analysis showed that the expression of GmSTOP1 in soybean leaf and root was also up-regulated by ABA, NaCl, and PEG, respectively. These results indicated that GmSTOP1 might participate in soybean response to abiotic stresses including aluminum-toxicity, high salinity and osmosis stress, which provides the basis for further studying the functions of GmSTOP1.

Key words: Acid soil, Aluminum toxicity, Soybean, STOP1, Subcellular location, Real-time PCR

CONG Ya-Hui,WANG Ting-Ting,LIU Ju-Ge,WANG Ning,GAO Meng-Meng,LI Yan,GAI Jun-Yi. Cloning and Expression Analysis of Tolerance to Aluminum-toxicity Candidate Gene GmSTOP1 in Soybean[J].Acta Agron Sin, 2015, 41(12): 1802-1809.

References

[1]王利群, 赵政文, 李立. 浅谈我国南方大豆产业的发展策略. 湖南农业科学, 2009, (5): 117–119

Wang L Q, Zhao Z W, Li L. Introduction to the development strategy of soybean industry in southern China. Hunan Agric Sci, 2009, (5): 117–119 (in Chinese)

[2]金婷婷, 刘鹏, 黄朝表, 王芳, 徐根娣, 朱申龙. 铝胁迫下大豆根系分泌物对根际土壤的影响. 中国油料作物学报, 2007, 29: 42–48

Jin T T, Liu P, Huang C B, Wang F, Xun G D, Zhu S L. Root exudates of soybean (Glycine max) under aluminum stress and their effect on rhizosphere soils. Chin J Oil Crop Sci, 2007, 29: 42–48 (in Chinese with English abstract)

[3]Ma J F, Furukawa J. Recent progress in the research of external Al detoxification in higher plants: a minireview. J Inorg Biochem, 2003, 97: 46–51

[4]陈奇, 陈丽梅, 武孔焕, 李昆志, 玉永雄. 植物铝胁迫响应基因的研究进展. 植物遗传资源学报, 2012, 13: 858–864

Chen Q, Chen L M, Wu K H, Li Z K, Yu Y X. Research progresses in plant Aluminum-responsive genes. J Plant Genet Resour, 2012, 13: 858–864 (in Chinese with English abstract)

[5]俞慧娜, 刘鹏, 徐根娣. 红壤地区大豆根系的耐酸铝生理特性. 生态环境, 2008, 17: 1483–1490

Yu H N, Liu P, Xu G D. The physiological characteristics of soybean root system in tolerance to acid-aluminum in red soil region. Ecol & Environ, 2008, 17: 1483–1490 (in Chinese with English abstract)

[6]Gunse B, Poschenrieder C, Barcelo J. Water transport properties of roots and root cortical cells in proton- and Al-stressed maize varieties. Plant Physiol, 1997, 113: 595–602

[7]刘鹏, 应小芳, 徐根娣. 大豆对铝毒抗逆性的研究. 农业环境科学学报, 2004, 23: 649–652

Liu P, Ying X F, Xu G D. Stress resistance of soybean to Aluminum toxicity. J Agro-Environ Sci, 2004, 23: 649–652 (in Chinese with English abstract)

[8]Iuchi S, Koyama H, Luchi A, Kobayashi Y, Kitabayashi S, Kobayashi Y, Ikka T, Hirayama T, Shinozaki K, Kobayashi M. Zinc finger protein STOP1 is critical for proton tolerance in Arabidopsis and coregulates a key gene in aluminum tolerance. Proc Natl Acad Sci USA, 2007, 104: 9900–9905

[9]Iuchi S, Kobayashi Y, Koyama H, Kobayashi M. STOP1, a Cys2/His2 type zinc-finger protein, plays critical role in acid soil tolerance in Arabidopsis. Plant Signal Behav, 2008, 3: 128–130

[10]Hoekenga O A, Maron L G, Piñeros M A, Cançado G M, Shaff J, Kobayashi Y, Ryan P R, Dong B, Delhaize E, Sasaki T, Matsumoto H, Yamamoto Y, Koyama H, Kochian L V. AtALMT1, which encodes a malate transporter, is identified as one of several genes critical for aluminum tolerance in Arabidopsis. Proc Natl Acad Sci USA, 2006, 103: 9738–9743

[11]Magalhaes J V, Liu J, Guimarães C T, Lana U G, Alves V M, Wang Y H, Schaffert R E, Hoekenga O A, Piñeros M A, Shaff J E, Klein P E, Carneiro N P, Coelho C M, Trick H N, Kochian L V. A gene in the multidrug and toxic compound extrusion (MATE) family confers aluminum tolerance in sorghum. Nat Genet, 2007, 39: 1156–1161

[12]Larsen P B, Geisler M J, Jones C A, Williams K M, Cancel J D. ALS3 encodes a phloem-localized ABC transporter-like protein that is required for aluminum tolerance in Arabidopsis. Plant J, 2005, 41: 353–363

[13]Liu J, Magalhaes J V, Shaff J, Kochian L V. Aluminum-activated citrate and malate transporters from the MATE and ALMT families function independently to confer Arabidopsis aluminum tolerance. Plant J, 2009, 57: 389–399

[14]Sawaki Y, Iuchi S, Kobayashi Y, Kobayashi Y, Ikka T, Sakurai N, Fujita M, Shinozaki K, Shibata D, Kobayashi M, Koyama H. STOP1 regulates multiple genes that protect Arabidopsis from proton and aluminum toxicities. Plant Physiol, 2009, 150: 281–294

[15]Yamaji N, Huang C F, Nagao S, Yano M, Sato Y, Nagamura Y, Ma J F. A zinc finger transcription factor ART1 regulates multiple genes implicated in aluminum tolerance in rice. Plant Cell, 2009, 21: 3339–3349

[16]Ohyama Y, Ito H, Kobayashi Y, Ikka T, Morita A, Kobayashi M, Imaizumi R, Aoki T, Komatsu K, Sakata Y, Iuchi S, Koyama H. Characterization of AtSTOP1 orthologous genes in tobacco and other plant species. Plant Physiol, 2013, 162: 1937–1946

[17]Sawaki Y, Kobayashi Y, Kihara-Doi T, Nishikubo N, Kawazu T, Kobayashi M, Kobayashi Y, Iuchi S, Koyama H, Sato S. Identification of a STOP1-like protein in Eucalyptus that regulates transcription of Al tolerance genes. Plant Sci, 2014, 223: 8–15

[18]Yoo S D, Cho Y H, Sheen J. Arabidopsis mesophyll protoplasts: a versatile cell system for transient gene expression analysis. Nat Protoc, 2007, 2: 1565–1572

[19]Le D T, Aldrich D L, Valliyodan B, Watanabe Y, Ha C V, Nishiyama R, Guttikonda S K, Quach T N, Gutierrez-Gonzalez J J, Tran L S, Nguyen H T. Evaluation of candidate reference genes for normalization of quantitative RT-PCR in soybean tissues under various abiotic stress conditions. PLoS One, 2012, 7(9): e46487

[20]Livak K J, Schmittgen T D. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method. Methods, 2001, 25: 402–408

[21]Libault M, Farmer A, Joshi T, Takahashi K, Langley R J, Franklin L D, He J, Xu D, May G, Stacey G. An integrated transcriptome atlas of the crop model Glycine max, and its use in comparative analyses in plants. Plant J, 2010, 63: 86–99

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Cloning and Expression Analysis of Tolerance to Aluminum-toxicity Candidate Gene GmSTOP1 in Soybean

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