Construction of Two Suppression Subtractive Hybridization Libraries and Identification of Salt-Induced Genes in Soybean 被引量：1

Construction of Two Suppression Subtractive Hybridization Libraries and Identification of Salt-Induced Genes in Soybean

下载PDF

导出

摘要 Soybean is planted worldwide and its productivity is significantly hampered by salinity. Development of salt tolerant cultivars is necessary for promoting soybean production. Despite wealth of information generated on salt tolerance mechanism, its basics still remain elusive. A continued effort is needed to understand the salt tolerance mechanism in soybean using suitable molecular tools. To better understand the molecular basis of the responses of soybean to salt stress and to get an enrichment of critical salt stress responsive genes in soybean, suppression subtractive hybridization libraries （SSH） are constructed for the root tissue of two cultivated soybean genotypes, one was tolerant and the other was sensitive to salt stress. To compare the responses of plants in salt treatment and non-treatment, SSH1 was constructed for the salt-tolerant cultivar Wenfeng 7 and SSH2 was constructed for the salt-sensitive cultivar Union. From the two SSH cDNA libraries, a total of 379 high quality ESTs were obtained. These ESTs were then annotated by performing sequence similarity searches against the NCBI nr （National Center for Biotechnology Information protein non-redundant） database using the BLASTX program. Sixty-three genes from SSH1 and 49 genes from SSH2 could be assigned putative function. On the other hand, 25 ESTs of SSH1 which may be not the salt tolerance-related genes were removed by comparing and analyzing the ESTs from the two S SH libraries, which increased the proportion of the genes related to salt tolerance in S SH 1. These results suggested that the novel way could realize low background of SSH and high level enrichment of target cDNAs to some extent. Soybean is planted worldwide and its productivity is significantly hampered by salinity. Development of salt tolerant cultivars is necessary for promoting soybean production. Despite wealth of information generated on salt tolerance mechanism, its basics still remain elusive. A continued effort is needed to understand the salt tolerance mechanism in soybean using suitable molecular tools. To better understand the molecular basis of the responses of soybean to salt stress and to get an enrichment of critical salt stress responsive genes in soybean, suppression subtractive hybridization libraries （SSH） are constructed for the root tissue of two cultivated soybean genotypes, one was tolerant and the other was sensitive to salt stress. To compare the responses of plants in salt treatment and non-treatment, SSH1 was constructed for the salt-tolerant cultivar Wenfeng 7 and SSH2 was constructed for the salt-sensitive cultivar Union. From the two SSH cDNA libraries, a total of 379 high quality ESTs were obtained. These ESTs were then annotated by performing sequence similarity searches against the NCBI nr （National Center for Biotechnology Information protein non-redundant） database using the BLASTX program. Sixty-three genes from SSH1 and 49 genes from SSH2 could be assigned putative function. On the other hand, 25 ESTs of SSH1 which may be not the salt tolerance-related genes were removed by comparing and analyzing the ESTs from the two S SH libraries, which increased the proportion of the genes related to salt tolerance in S SH 1. These results suggested that the novel way could realize low background of SSH and high level enrichment of target cDNAs to some extent.

作者 LI Liang WANG Wei-qi WU Cun-xiang HAN Tian-fu HOU Wen-sheng

机构地区 National Key Facility for Crop Gene Resources and Genetic Improvement (NFCRI) Daqing Branches

出处《Journal of Integrative Agriculture》 SCIE CAS CSCD 2012年第7期1075-1085,共11页 农业科学学报（英文版）

基金 the National Natural Science Foundation of China (30771358)

关键词 salt stress suppression subtractive hybridization （SSH） SOYBEAN salt stress, suppression subtractive hybridization （SSH）, soybean

分类号 Q781 [生物学—分子生物学] S792.119 [农业科学—林木遗传育种]

引文网络
相关文献

参考文献27

1Zhao M F. The status and research trend of soil pickled in the world[J].Chinese World Forestry Research,1992.84-86.
2He F,Zhu Y,Zhang Y. Identification and characterization of differentially expressed genes involved in pharmacological activities of roots of Panax notoginseng during plant growth[J].Plant Cell Reports,2008.923-930.
3Hubank M,Schatz A D. Identifying differences in mRNA expression by representational difference analysis of cDNA[J].Nucleic Acids Research,1994.5640-5648.
4McGinness K E,Sauer R T. Ribosomal protein S1 binds mRNA and tmRNA similarly but plays distinct roles in translation of these molecules[J].Proceedings of the National Academy of Sciences(USA),2004.13454-13459.
5Wei W H,Chen B,Yah X H,Wang L J,Zhang H F,Cheng J P,Zhou X A,Sha A H,Shen. Identification of differentially expressed genes in soybean seeds differing in oil content[J].Plant Science,2008.663-673.
6Nakagami H,Maeda K,Morishita R,Iguchi S,Nishikawa T,Takami Y,Kikuchi Y,Saito Y,Ta. Novel autologous cell therapy in ischemic limb disease through growth factor secretion by cultured adipose tissue-derived stromal cells[J].Arteriosclerosis,Thrombosis,and Vascular Biology,2005.2542-2547.
7Gomes-Filho E,Lima C R F M,Costa J H,da Silva A C M,da Guia Silva Lima M,de Lacerda C F. Cowpea ribonuclease:properties and effect of NaClsalinity on its activation during seed germination and seedling establishment[J].Plant Cell Reports,2008.147-157.
8Mano Y,Takeda K. Mapping quantitative trait loci for salt tolerance at germination and the seedling stage in barley(Hordeum vulgare L.)[J].Euphytica,1997.263-272.
9Kawasaki S,Borchert C,Deyholos M,Wang H,Brazille S,Kawai K,Galbraith D,Bohnert H J. Gene expression profiles during the initial phase of salt stress in rice[J].The Plant Cell Online,2001.889-906.
10Binod S B,Birendra S P. Isolation,identification and expression analysis of salt-induced genes in Suaeda maritim,a natural halophyte,using PCR-based suppression subtractive hybridization[J].Bmc Plant Biology,2009.69.

二级参考文献111

1Preston GM, Carroll TP, Guggino WB, Arge E Appearance of water channels in Xenopus oocytes expressing red cell CHIP28 protein. Science 1992; 256:385-387.
2Johansson U, Karlsson M, Johansson I, et al. The complete set of genes encoding major intrinsic proteins in Arabidopsis provides a framework for a new nomenclature for major intrinsic proteinsin plants. Plant Physiol 2001; 126:1358-1369.
3Johansson I, Karlsson M, Johanson U, et al. The role of aquaporins in cellular and whole plant water balance. BBA-Biomembranes 2000; 1465:324-342.
4Jang JY, Kim DG, Kim YO, Kim JS, Kang HS. An expression analysis of a gene family encoding plasma membrane aquaporins in response to abiotic stresses in Arabidopsis thaliana. Plant Mol Biol 2004; 54:713-725.
5Kaldenhoff R, Grote K, Zhu J J, Zimmermann U. Significance of plasmalemma aquaporins for water-transport in Arabidopsis thaliana. Plant J 1998; 14:121-128.
6Kaldenhoff R, Kolling A, Richter G. Regulation of the Arabidopsis thaliana aquaporin gene Athll2 (PIP1b). J Photochem Photobiol B 1996; 36:351-354,
7Katsuhara M, Koshio K, Shibasaka M, et al. Over-expression of a barley aquaporin increased the shoot/root Ratio and raised salt sensitivity in transgenic rice plants. Plant Cell Physiol 2003;44:1378-1383.
8Mariaux JB, Bockel C, Salamini F, Barrels D. Desiccation- and abscisic acid-responsive genes encoding major intrinsic proteins(MIPs) from the resurrection plant Craterostigmaplantagmeum.Plant Mol Biol 1998; 38:1089-1099.
9O'Brien M, Bertrand C, Matton DP. Characterization or a fertilization-induced and developmentally regulated plasma-membrane aquaporin expressed in reproductive tissues, in the wild potato Solanum chacoense Bitt. Planta 2002; 215:485-493.
10Yang L, Zheng BS, Mao CZ, et al. cDNA-AFLP analysis of inducible gene expression in rice seminal root tips under a water deficit. Gene 2003; 314:141-148.

共引文献121

1姚鹏飞.如何理解对于变系数波方程控制为必要工具的黎曼几何(英文)[J].山西大学学报（自然科学版）,2012,35(2):174-180.
2何光涛.清代三种亡佚屈原戏考论[J].民族艺术研究,2012,25(2):33-41.
3胡中为,史建春,赵海斌,林启生.彗星的反常尘埃彗尾[J].南京大学学报（自然科学版）,2011,47(1):1-12.
4Genji Qin,Zhiqiang Ma,Li Zhang,Shufan Xing,Xianhui Hou,Jie Deng,Jingjing Liu,Zhangliang Chen,Li-Jia Qu,Hongya Gu.Arabidopsis AtBECLIN 1/AtAtg6/AtVps30 is essential for pollen germination and plant development[J].Cell Research,2007,17(3):249-263. 被引量：17
5Hong-Yan Liu,Xin Yu,Da-Yong Cui,Mei-Hao Sun,Wei-Ning Sun,Zhang-Cheng Tang,Sang-Soo Kwak,Wei-Ai Su.The role of water channel proteins and nitric oxide signaling in rice seed germination[J].Cell Research,2007,17(7):638-649. 被引量：13
6Zhiqiang Lin,Kangquan Yin,Danling Zhu,Zhangliang Chen,Hongya Gu,Li-Jia Qu.AtCDC5 regulates the G2 to M transition of the cell cycle and is critical for the function of Arabidopsis shoot apical meristem[J].Cell Research,2007,17(9):815-828. 被引量：14
7Tsui-Hung Phang,Hon-Ming Lam.Salt Tolerance in Soybean[J].Journal of Integrative Plant Biology,2008,50(10):1196-1212. 被引量：54
8朱华国,涂礼莉,金双侠,徐理,谭家福,邓锋林,张献龙.棉花细胞初始脱分化的基因差异表达分析[J].科学通报,2008,53(20):2483-2492. 被引量：1
9王垠,刘关君,阎秀峰,杨传平,刘明坤,曲春浦.西伯利亚蓼PsPIP1基因的克隆及其在NaHCO_3胁迫下的表达[J].遗传,2008,30(12):1621-1628. 被引量：1
10Hua Guan,Dingming Kang,Min Fan,Zhangliang Chen,Li-Jia Qu.Overexpression of a New Putative Membrane Protein Gene AtMRB1 Results in Organ Size Enlargement in Arabidopsis[J].Journal of Integrative Plant Biology,2009,51(2):130-139. 被引量：1

同被引文献4

1胡守忠,乔冬梅,史海滨.油料向日葵根系生态与生理特性分析[J].干旱区资源与环境,2006,20(6):192-197. 被引量：7
2CHEN Hai-sheng,LIU Guo-shun,YANG Yong-feng,YE Xie-feng,SHI Zhou.Comprehensive Evaluation of Tobacco Ecological Suitability of Henan Province Based on GIS[J].Agricultural Sciences in China,2010,9(4):583-592. 被引量：19
3杨丽雯,张永清.4种旱作谷类作物根系发育规律的研究[J].中国农业科学,2011,44(11):2244-2251. 被引量：35
4GAO Shang,YUAN Li,ZHAI Hong,LIU Cheng-long,HE Shao-zhen,LIU Qing-chang.Overexpression of SOS Genes Enhanced Salt Tolerance in Sweetpotato[J].Journal of Integrative Agriculture,2012,11(3):378-386. 被引量：7

引证文献1

1TONG Wen-jie,CHEN Xiao-li,WEN Xin-ya,CHEN Fu,ZHANG Hai-lin,CHU Qing-quan,Shadrack Batsile Dikgwatlhe.Applying a salinity response function and zoning saline land for three fi eld crops: a case study in the Hetao Irrigation District, Inner Mongolia, China[J].Journal of Integrative Agriculture,2015,14(1):178-189. 被引量：3

二级引证文献3

1黄晓博,刘国勇.阿拉尔市十四团节水灌溉项目效益评价[J].广西质量监督导报,2020(12):51-52.
2WEN Xin-ya,Eric Dubinsky,WU Yao,YU Rong,CHEN Fu.Wheat, maize and sunflower cropping systems selectively influence bacteria community structure and diversity in their and succeeding crop's rhizosphere[J].Journal of Integrative Agriculture,2016,15(8):1892-1902. 被引量：24
3LI Cheng,WANG Qingsong,LUO Shuai,QUAN Hao,WANG Naijiang,LUO Xiaoqi,ZHANG Tibin,DING Dianyuan,DONG Qin'ge,FENG Hao.Reducing water and nitrogen inputs combined with plastic mulched ridge-furrow irrigation improves soil water and salt status in arid saline areas,China[J].Journal of Arid Land,2021,13(8):761-776. 被引量：2

1何新建,陈建权,张志刚,张劲松,陈受宜.通过cDNA微阵列鉴定水稻(Oryza sativa L.)盐胁迫应答基因[J].中国科学（C辑）,2002,32(6):488-493. 被引量：3
2郭蓓,邱丽娟,李向华.植物盐诱导基因的研究进展[J].农业生物技术学报,1999,7(4):401-408. 被引量：29
3卢青.植物耐盐性的分子生物学研究进展[J].生物学杂志,2000,17(4):9-11. 被引量：30
4赵成,杨昊,刘志斌,杨毅.拟南芥中一个参与盐胁迫应答基因的T-DNA插入纯合突变体的鉴定及表型分析[J].四川大学学报（自然科学版）,2014,51(3):615-620. 被引量：1
5卢泳全,吴为人.应用SRAP技术从大米草根中分离盐胁迫应答基因(英文)[J].浙江大学学报（农业与生命科学版）,2006,32(5):511-514. 被引量：17
6柏永军.大豆种植管理技术的分析与探讨[J].农业开发与装备,2014(6):123-123. 被引量：1
7美国饲料作物种植放缓,真的影响产量吗?[J].饲料与畜牧（新饲料）,2016(7):35-35.
8白根本,沈昕,王沙生.胡杨盐诱导基因与盐抑制基因的差减杂交显示研究[J].林业科学,2003,39(2):168-170. 被引量：4
9钟林光,王朝晖,彭友林,洪叶.菜用大豆(Soybean)引种试验研究[J].安徽农业科学,2008,36(33):14495-14497. 被引量：2
10龚亚明,胡齐赞,张古文,王新斌,丁桔,徐盛春.菜用大豆浙农8号[J].上海蔬菜,2010(1):23-23. 被引量：2

Journal of Integrative Agriculture

2012年第7期

浏览历史

内容加载中请稍等...