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| Identification and Analysis of Differentially-expressed Genes Under Salt Stress in Leaves of Southern Type Alfalfa (Medicago sativa 'Millennium') Salt Tolerant Mutant |
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Abstract Alfalfa (Medicago sativa) is widely grown and is one of the most important forage crops in the world, but its growth and biomass production are markedly reduced under salt stress. The objective of this study is to identify the inner molecular mechanisms of southern type alfalfa in response to salt stress, and mine these genes closely related to salt responsiveness. Illumina HiSeqTM 2000, a high-through transcriptome sequencing technology, was used to obtain the anscriptome differential expression data of southern type alfalfa (Medicago sativa 'Millenium') leaves under 72 h treatment at 250 mmol/L NaCl. Function and pathway of those different expression genes were also investigated using Gene Ontology (GO) database and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway biological analysis in order to obtain some of the potential target genes to salt stress. Eight randomly selected DEGs (differentially expressed genes) were used to validate the reliability of sequencing results. The results showed that after filtration of reads, a total of 60 395 324 control (CK) and 60 303 692 salt stress (ST) reads were acquired, among these reads, 54.18% and 53.77% could be precisely compared to the reference sequence of M. truncatula. After 250 mmol/L NaCl stressed for 72 h, in total, 30 900 DEGs were authenticated among which 4 187 and 3 507 were regarded as raise-and lower-regulated genes. GO analysis showed that these DEGs were mainly referred to binding, catalytic activity, cell part and cell. KEGG pathway analysis showed that these DEGs were mainly referred to biosynthesis of secondary metabolites, metabolic pathways and phenylpropanoid biosynthesis. Besides, we discovered many candidate genes, like glutathione S-transferase, superoxide dismutase [Cu-Zn] protein, L-ascorbate peroxidase, receptor-like kinase, stress-induced receptor-like kinase, sucrose nonfermenting 1(SNF1)-related kinase, Calmodulin-like protein, choline monooxygenase, delta-1-pyrroline-5-carboxylate synthetase 3, 2Ccatalytic/protein phosphatase type 2C and Trehalose-phosphate phosphatase, and many transcription factors were identified, to be related to salt tolerance, like ANTAP2-like ethylene-responsive, Transcription factor bHLH36, Transcription factor NAI1, bZIP transcription factor, Zinc finger C-x8-C-x5-C-x3-H type family protein, Nucleic acid binding transcription factor activity, Myb transcription factor, NAC transcription factor-like protein, Sequence-specific DNA-binding and WRKY family transcription factor, This study affords the initial value for the molecular mechanisms of salt tolerance in alfalfa.
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Received: 19 April 2017
Published: 30 October 2017
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| [1]戴高兴, 彭克勤, 皮灿辉. 钙对植物耐盐性的影响[J]. 中国农学通报, 2003, 19(3): 97-101[2]郭鹏, 邢鑫, 张万筠, 等. 紫花苜蓿盐诱导类受体蛋白激酶基因MsSIK1的克隆及功能分析[J]. 中国农业科学, 2014, 47(23): 4573-4581[3]金宏滨, 刘东辉, 左开井, 等. 植物ABC转运蛋白与次生代谢产物的跨膜转运[J]. 中国农业科技导报, 2007, 9(3): 32-37[4]李剑, 赵常玉, 张富生, 等. LEA蛋白与植物抗逆性[J].植物生理学报, 2010, 46 (11): 1101-1108[5]李明娜, 龙瑞才, 杨青川. 紫花苜蓿盐诱导HD-Zip类转录因子MsHB2的克隆及功能分析[J]. 中国农业科学, 2014, 47(4): 622-632[6]马进, 刘志高, 郑刚. 南方型紫花苜蓿耐盐细胞系的筛选及生理特性分析[J]. 中国草地学报, 2011, 33(4): 68-7[7]马进, 郑刚. 南方型紫花苜蓿叶片盐胁迫应答基因鉴定与分析[J]. 农业生物技术学报, 2015, 23(12): 1531-1541[8]师恭曜, 王玉美, 华金平. 水通道蛋白与高等植物的耐盐性[J]. 中国农业科技导报,2012, 14(4): 31-38[9]薛鑫, 张芊, 吴金霞. 植物体内活性氧的研究及其在植物抗逆方面的应用[J]. 生物技术通报, 2013, 2013(10): 6-11[10]许祥明, 叶和春, 李国凤. 植物抗盐机理的研究进展[J]. 应用与环境生物学报, 2000, 6(4): 379-387[11]Abdel-Gaber A M, Abd-El-Nabey b a, Sidahmed I M, et al. Inhibitive action of some plant extracts on the corrosion of steel in acidic media [J]. Corrosion Science, 2006, 48(9): 2765-2779[12]Borsics T, Lados M. cDNA cloning of a mechanical/abiotic stress-inducible calmodulin-related geneform dodder-infected alfalfa [J]. Plant Cell and Environment, 2001, 24(6):649-656[13]Bricker T M, Roose J L, Fagerlund R D, et al. The extrinsic proteins of Photosystem II [J]. Biochimica Et Biophysica Acta, 2012, 1817(1): 369-387[14]Deutch C E, Winicov I. Post-transcriptional regulation of a salt-inducible alfaIfa gene encoding a putative chimeric proline-richcell wall protein [J]. Plant Molecula Biology, 1995, 27(2): 41l-418[15]Gao Z X, He X L, Zhao B C, et al. Overexpressing a putative aquaporin gene from wheat, TaNIP, enhances salt tolerance in transgenic Arabidopsis [J]. Plant and Cell Physiology, 2010, 51(5): 767-775[16]Hong J K, Hwang B K. Induction by pathogen, salt and drought of a basic class II chitinase mRNA and its in situ localization in pepper (Capsicum annuum) [J]. Physiologia Plantarum, 2002, 114(4): 549-558[17]Katsuharam M, Koshiok, Shibasaka M, et al. Over-expression of a barley aquaporin increased the shoot/root ratio and raised salt sensitivity in transgenic rice plants [J]. Plant and Cell Physiology, 2003, 44(44): 1378-1383[18]Kinoshita A, Betsuyaku S, Osakabe Y,et al. RPK2 is an essential receptor-like kinase that transmits the CLV3 signal in Arabidopsis [J]. Development, 2010, 137(22) : 3911-3920[19]Long R C, Yang Q C, Kang J M, et al. Overexpression of a novel salt stress-induced glycine-rich protein gene from alfalfa causes salt and ABA sensitivity in Arabidopsis [J]. Plant Cell Reports, 2013, 32(8): 1289-1298[20]Luo Y, Liu Y B, Dong Y X, et al. Expression of a putative alfalfa helicase increases tolerance to abiotic stress in Arabidopsis by enhancing the capacities for ROS scavenging and osmotic adjustment [J]. Journal of Plant Physiology, 2009, 166(4): 385-394[21]Ma L C, Wang Y R, Liu W X, et al. Overexpression of an alfalfa GDP-mannose 3,5-epimerase gene enhances acid,drought and salt tolerance in transgenic Arabidopsis by increasing ascorbate accumulation [J]. Biotechnology Letters, 2014, 36(11): 2331-2341[22]Manohar M, Shigaki T, Hirschi H D. Plant cation/H+ exchangers (CAXs): biological functions and genetic manipulations [J]. Plant Biology, 2011, 13(4):561-569[23]Miller G, Stein H, Honig A, et al. Responsive modes of Medicago sativa proline dehydrogenase genes during salt stress and recovery dictate free proline accumulation [J]. Planta, 2005, 222(1): 70-79[24]Miller G, Suzuki N, Ciftci-Yilmaz S, et al. Reactive oxygen species homeostasis and signalling during drought and salinity stresses [J]. Plant Cell and Environment, 2010, 33(4): 453-467[25]Prashanth S R, Sadhasivam V, Parida A. Over expression of cytosolic copper/zinc superoxide dismutase from a mangrove plant Avicennia marina in indica rice var Pusa Basmati-1 confers abiotic stress tolerance [J]. Transgenic Research, 2008, 17(2): 281-291[26]Schneider-Mller S, Kurosaki F, Nishi A. Role of salicylic acid and intracellular Ca2+ in the induction of chitinase activity in carrot suspension culture [J]. Physiological and Molecular Plant Pathology, 1994, 45(2): 101-109[27]Shou-Qiang Oy, Liu Y F, Liu P, et al. Receptor-like kinase OsSIK1 improves drought and salt stress tolerance in rice (Oryza sativa) plants [J]. Plant Journal, 2010, 62(2): 316-329[28]Wang X, Li Y, Ji W, et al. A novel Glycine soja tonoplast intrinsic protein gene responds to abiotic stress and depresses salt and dehydration tolerance in transgenic Arabidopsis thaliana [J]. Journal of Plant Physiology, 2011, 168(11): 1241-1248[29]Xu H N, Li K Z, Yang F J, et al. Overexpression of CsNMAPK in tobacco enhanced seed germination under salt and osmotic stresses [J]. Molecular Biology Reports, 2010, 37(7): 3157-3163[30]Yang L, Ji W, Zhu Y M, et al. GsCBRLK, a calcium/calmodulin-binding receptor-like kinase, is a positive regulator of plant tolerance to salt and ABA stress [J]. Journal of Experimental Botany, 2010, 61( 9 ) : 2519-2533[31]Zahaf O, Blanchet S, Zelicourt A, et al. Comparative transcriptomic analysis of salt adaptation in roots of contrasting Medicago truncatula genotypes [J]. Molecular Plant, 2012, 5(5):1068-1081[32]Zhang Z G, Zhang Q A, Wu J X, et al. Gene knockout study reveals that cytosolic ascorbate peroxidase 2(OsAPX2) plays a critical role in growth and reproduction in rice under drought, salt and cold stresses [J]. Plos One, 2013, 8(2): e57472[33]Zhao F Y, Zhang H. Salt and paraquat stress tolerance results from co-expression of the Suaeda salsa glutathione S-transferase and catalase in transgenic rice [J]. Plant Cell Tissue and Organ Culture, 2006, 86(3): 349-358 |
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