Drought Responses of Leaf Tissues from Wheat Cultivars of Differing Drought Tolerance at the Metabolite Level 被引量：25

Drought Responses of Leaf Tissues from Wheat Cultivars of Differing Drought Tolerance at the Metabolite Level

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摘要 Drought has serious effects on the physiology of cereal crops. At the cellular and specifically the metabolite level, many individual compounds are increased to provide osmoprotective functions, prevent the dissociation of enzymes, and to decrease the number of reactive oxygen species present in the cell. We have used a targeted GC-MS approach to identify compounds that differ in three different cultivars of bread wheat characterized by different levels of tolerance to drought under drought stress （Kukri, intolerant; Excalibur and RAC875, tolerant）. Levels of amino acids, most notably proline, tryptophan, and the branched chain amino acids leucine, isoleucine, and valine were increased under drought stress in all cultivars. In the two tolerant cultivars, a small decrease in a large number of organic acids was also evident. Excalibur, a cultivar genotypically related to Kukri, showed a pattern of response that was more similar to Kukri under well-watered conditions. Under drought stress, Excalibur and RAC875 had a similar response; however, Excalibur did not have the same magnitude of response as RAC875. Here, the results are discussed in the context of previous work in physiological and proteomic analyses of these cultivars under drought stress. Drought has serious effects on the physiology of cereal crops. At the cellular and specifically the metabolite level, many individual compounds are increased to provide osmoprotective functions, prevent the dissociation of enzymes, and to decrease the number of reactive oxygen species present in the cell. We have used a targeted GC-MS approach to identify compounds that differ in three different cultivars of bread wheat characterized by different levels of tolerance to drought under drought stress （Kukri, intolerant; Excalibur and RAC875, tolerant）. Levels of amino acids, most notably proline, tryptophan, and the branched chain amino acids leucine, isoleucine, and valine were increased under drought stress in all cultivars. In the two tolerant cultivars, a small decrease in a large number of organic acids was also evident. Excalibur, a cultivar genotypically related to Kukri, showed a pattern of response that was more similar to Kukri under well-watered conditions. Under drought stress, Excalibur and RAC875 had a similar response; however, Excalibur did not have the same magnitude of response as RAC875. Here, the results are discussed in the context of previous work in physiological and proteomic analyses of these cultivars under drought stress.

作者 Jairus B. Bowne Tim A. Erwin Juan Juttner Thorsten Schnurbusch Peter Langridge Antony Bacic Ute Roessner

机构地区 Australian Centre for Plant Functional Genomics Australian Centre for Plant Functional Genomics Metabolomics Australia ARC Centre for Excellence for Plant Cell Walls Metabolomics Australia

出处《Molecular Plant》 SCIE CAS CSCD 2012年第2期418-429,共12页 分子植物（英文版）

关键词 abiotic/environmental stress metabolomics DROUGHT wheat. abiotic/environmental stress metabolomics drought wheat.

分类号 S512.1 [农业科学—作物学] S566.301 [农业科学—作物学]

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参考文献6

1Shujun Yang Barbara Vanderbeld Jiangxin Wan Yafan Huang.Narrowing Down the Targets： Towards Successful Genetic Engineering of Drought-Tolerant Crops[J].Molecular Plant,2010,3(3):469-490. 被引量：49
2Yong-Ling Ruan,Ye Jin,Yue-Jian Yang,Guo-Jing Li,John S. Boyer.Sugar Input, Metabolism, and Signaling Mediated by Invertase： Roles in Development, Yield Potential, and Response to Drought and Heat[J].Molecular Plant,2010,3(6):942-955. 被引量：103
3Sandra Witt,Luis Galicia,Jan Lisec,Jill Cairns,Axel Tiessen,Jose Luis Araus,Natalia Palacios-Rojas,Alisdair R. Fernie.Metabolic and Phenotypic Responses of Greenhouse-Grown Maize Hybrids to Experimentally Controlled Drought Stress[J].Molecular Plant,2012,5(2):401-417. 被引量：12
4Gang-Ping Xue,Heather M. Way,Terese Richardson,Janneke Drenth,Priya A. Joyce,C.Lynne Mclntyre.Overexpression of TaNAC69 Leads to Enhanced Transcript Levels of Stress Up-Regulated Genes and Dehydration Tolerance in Bread Wheat[J].Molecular Plant,2011,4(4):697-712. 被引量：25
5Yong-Chang Liu,Yao-Rong Wu,Xia-He Huang,Jie Sun,Qi Xie.AtPUB19, a U-Box E3 Ubiquitin Ligase, Negatively Regulates Abscisic Acid and Drought Responses in Arabidopsis thaliana[J].Molecular Plant,2011,4(6):938-946. 被引量：17
6Brian D. Keppler Allan M. Showalter.IRX14 and IRX14-LIKE, Two Glycosyl Transferases Involved in Glucuronoxylan Biosynthesis and Drought Tolerance in Arabidopsis[J].Molecular Plant,2010,3(5):834-841. 被引量：9

二级参考文献142

1Andersson, S., Samuelson, O., Ishihara, M., and Shimizu, K. (1983). Structure of the reducing end-groups in spruce xylan. Carbohydr. Res. 111,283-288.
2Brown, D.M., Goubet, F., Vicky, W.W.A., Goodacre, R., Stephens, E., Dupree, R, and Turner, S.R. (2007). Comparison of five xylan synthesis mutants reveals new insight into the mechanisms of xylan synthesis. Plant J. 52, 1154-1168.
3Brown, D.M., Zeef, L.A.H., Ellis, J., Goodacre, R., and Turner, S.R. (2005). Identification of novel genes in Arabidopsis involved in secondary cell wall formation using expression profiling and reverse genetics. Plant Cell. 17, 2281-2295.
4Brown, D.M., Zhang, Z., Stephens, E., Dupree, R, and Turner, S.R. (2009). Characterization of IRX10 and IRX10-like reveals an essential role in glucuronoxylan biosynthesis in Arabidopsis. Plant J. 57, 732-746.
5Cantarel, B.L., Coutinho, RM., Rancurel, C., Bernard, T., Lombard, V., and Henrissat, B. (2009). The Carbohydrate-Active EnZymes database (CAZy): an expert resource for Glycogenomics. Nucl. Acids Res. 37, D233-D238.
6Chen, Z.Z., Hong, X.H., Zhang, H.R., Wang, Y.Q., Li, X., Zhu, J.K., and Gong, Z.Z. (2005). Disruption of the cellulose synthase gene, AtCesA8/IRX1, enhances drought and osmotic stress tolerance in Arab/dopsis. Plant J. 43, 273-283.
7Ebringerova, A., and Heinze, T. (2000). Xylan and xylan derivatives: biopolymers with valuable properties. 1. Naturally occurring xylans structures, isolation procedures and properties. Macromolecular Rapid Communications. 21, 542-556.
8Grennan, A.K. (2006). Genevestigator: facilitating web-based geneexpression analysis. Plant Physiol. 141, 1164-1166.
9Johansson, M.H., and Samuelson, O. (1977). Reducing end groups in brich xylan and their alkaline degradation. Wood Sci. Technol. 11,251-263.
10Lee, C., O'Neill, M.A., Tsumuraya, Y., Darvill, A.G., and Ye, Z. (2007a). The irregular xylem9 mutant is deficient in xylan xylosyltransferase activity. Plant Cell Physiol. 48, 1624-1634.

共引文献207

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2Zhuanfang Hao,Xinhai Li,Chuanxiao Xie,Jianfeng Weng,Mingshun Li,Degui Zhang,Xiaoling Liang,Lingling Liu,Sisi Liu,Shihuang Zhang.Identification of Functional Genetic Variations Underlying Drought Tolerance in Maize Using SNP Markers[J].Journal of Integrative Plant Biology,2011,53(8):641-652. 被引量：5
3Thomas L. Slewinski.Diverse Functional Roles of Monosaccharide Transporters and their Homologs in Vascular Plants： A Physiological Perspective[J].Molecular Plant,2011,4(4):641-662. 被引量：33
4Gang-Ping Xue,Heather M. Way,Terese Richardson,Janneke Drenth,Priya A. Joyce,C.Lynne Mclntyre.Overexpression of TaNAC69 Leads to Enhanced Transcript Levels of Stress Up-Regulated Genes and Dehydration Tolerance in Bread Wheat[J].Molecular Plant,2011,4(4):697-712. 被引量：25
5Chanhui Lee,Quincy Teng,Ruiqin Zhong,Zheng-Hua Ye.Molecular Dissection of Xylan Biosynthesis during Wood Formation in Poplar[J].Molecular Plant,2011,4(4):730-747. 被引量：10
6张楠,朱维宁,苏君艺,张林生.扁穗冰草转录因子基因的克隆和表达特性的分析[J].草业科学,2011,28(9):1618-1622. 被引量：3
7秦丽霞,张德静,李龙,李学宝,许文亮.参与植物细胞壁半纤维素木聚糖合成的糖基转移酶[J].植物生理学报,2011,47(9):831-839. 被引量：9
8宁约瑟,王国梁,谢旗.泛素连接酶E3介导的植物干旱胁迫反应[J].植物学报,2011,46(6):606-616. 被引量：18
9Yong-Chang Liu,Yao-Rong Wu,Xia-He Huang,Jie Sun,Qi Xie.AtPUB19, a U-Box E3 Ubiquitin Ligase, Negatively Regulates Abscisic Acid and Drought Responses in Arabidopsis thaliana[J].Molecular Plant,2011,4(6):938-946. 被引量：17
10Bao-Xiang Qin,Ding Tang,Jian Huang,Ming Li,Xin-Ru Wu,Li-Li LU,Ke-Jian Wang,Heng-Xiu Yu,Jian-Min Chen,Ming-Hong Gu,Zhu-Kuan Cheng.Rice OsGL 1-1 Is Involved in Leaf Cuticular Wax and Cuticle Membrane[J].Molecular Plant,2011,4(6):985-995. 被引量：10

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1陈花,吴俊林,李晓军,鲁百佐.电场处理荞麦种子对其幼苗抗旱性的影响[J].陕西师范大学学报（自然科学版）,2009,37(1):78-82. 被引量：7
2王玉平,李仕贵,黎汉云,高克铭.高配合力优质水稻恢复系蜀恢527的选育与利用[J].杂交水稻,2004,19(4):12-14. 被引量：69
3冯佰利,姚爱华,高金峰,高小丽,柴岩.中国荞麦优势区域布局与发展研究[J].中国农学通报,2005,21(3):375-377. 被引量：83
4李仰锐,隋方功,徐卫红,葛体达.水分胁迫对夏玉米(收获期)中微量元素含量的影响[J].莱阳农学院学报,2005,22(2):115-117. 被引量：6
5王宝山,赵可夫.小麦叶片中Na、K提取方法的比较[J].植物生理学通讯,1995,31(1):50-52. 被引量：193
6钮福祥,华希新,郭小丁,邬景禹,李洪民,丁成伟.甘薯品种抗旱性生理指标及其综合评价初探[J].作物学报,1996,22(4):392-398. 被引量：153
7程建峰,潘晓云,刘宜柏,戴廷波,曹卫星.快速鉴定稻种资源抗旱性的生理指标筛选及其遗传背景[J].西南农业学报,2005,18(5):529-533. 被引量：14
8GAO Shiqing,XU Huijun,CHENG Xianguo,CHEN Ming,XU Zhaoshi,LI Liancheng,YE Xingguo,DU Lipu,HAO Xiaoyan,MA Youzhi.Improvement of wheat drought and salt tolerance by expression of a stress- inducible transcription factorGmDREB of soybean (Glycinemax)[J].Chinese Science Bulletin,2005,50(23):2714-2723. 被引量：30
9沈文飚,徐朗莱,叶茂炳,张荣铣.氮蓝四唑光化还原法测定超氧化物歧化酶活性的适宜条件[J].南京农业大学学报,1996,19(2):101-102. 被引量：109
10邵宏波,梁宗锁,邵明安.小麦抗旱生理生化和分子生物学研究进展与趋势[J].草业学报,2006,15(3):5-17. 被引量：46

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1Xiao-Ya Chen,Lai-Geng Li,Ji-Rong Huang,Yong-Ling Ruan,Xue-Min Wang,Li Li.Translate Plant Metabolism into Modern Agriculture： A Starting Point[J].Molecular Plant,2012,5(2):291-293.
2Sandra Witt,Luis Galicia,Jan Lisec,Jill Cairns,Axel Tiessen,Jose Luis Araus,Natalia Palacios-Rojas,Alisdair R. Fernie.Metabolic and Phenotypic Responses of Greenhouse-Grown Maize Hybrids to Experimentally Controlled Drought Stress[J].Molecular Plant,2012,5(2):401-417. 被引量：12
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3Xiao-Ya Chen,Lai-Geng Li,Ji-Rong Huang,Yong-Ling Ruan,Xue-Min Wang,Li Li.Translate Plant Metabolism into Modern Agriculture： A Starting Point[J].Molecular Plant,2012,5(2):291-293.
4Andrej Kochevenko,Wagner L. Araujo,Gregory S. Maloney,Denise M. Tieman,Phuc Thi Do,Mark G. Taylor,Harry J. Klee,Alisdair R. Fernie.Catabolism of Branched Chain Amino Acids Supports Respiration but Not Volatile Synthesis in Tomato Fruits[J].Molecular Plant,2012,5(2):366-375. 被引量：4
5Jairus B. Bowne,Tim A. Erwin,Juan Juttner,Thorsten Schnurbusch,Peter Langridge,Antony Bacic,Ute Roessner.Drought Responses of Leaf Tissues from Wheat Cultivars of Differing Drought Tolerance at the Metabolite Level[J].Molecular Plant,2012,5(2):418-429. 被引量：25
6孙果忠.超低温保存花粉技术在温室玉米加代育种上的应用[J].河北农业科学,2013,17(1):65-67. 被引量：9
7莫新春.禾草模式植物二穗短柄草的研究进展(英文)[J].植物分类与资源学报,2014,36(2):197-207. 被引量：1
8Pil Joon Seo.Recent advances in plant membrane-bound transcription factor research: Emphasis on intracellular movement[J].Journal of Integrative Plant Biology,2014,56(4):334-342. 被引量：10
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10温贝贝,罗勇,李娟,王坤波,黄建安.组学技术应用于茶树物质代谢研究中的进展[J].分子植物育种,2019,17(3):862-868. 被引量：2

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2N.K.HOWES,S.E.SMITH,ZHUYONGGUAN.Phosphorus Uptake and Utilisation Efficiencies of Different Wheat Cultivars Based on a Sand-Culture Screening System[J].Pedosphere,2002,12(4):329-337. 被引量：12
3LIUYong,HEGuang-Yuan,ZHANGJin-Rui,LINTao,CHANGQi-Chang,P.R.Shewry.Genetic Diversity at the Glu-1 Loci Among Hubei Bred Wheat Cultivars[J].Acta Genetica Sinica,2004,31(9):1014-1014.
4XIE Wen-Jun,ZHOU Jian-Min,WANG Huo-Yan,CHEN Xiao-Qin.Effect of Nitrogen on the Degradation of Cypermethrin and Its Metabolite 3-Phenoxybenzoic Acid in Soil[J].Pedosphere,2008,18(5):638-644. 被引量：20
5马欣荣,Sun Zhenyuan,Jiang Changshun,Dong Zhaoyong,Zhang Yizheng.Transfer DREB into Lolium perenne L. to improve its drought tolerance[J].High Technology Letters,2006,12(4):427-433. 被引量：8
6罗云波.我们如何面对转基因(上)——说说转基因作物近期这点事[J].中国食品,2013(1):12-15. 被引量：1
7P.G. Guo　,M. Baum　,R.H. Li 　,S. Grando,R.K. Varshney　,J. Valkoun　,S. Ceccarelli　,A. Grane.Differentially Expressed Genes between Two Barley Cultivars Contrasting in Drought Tolerance[J].分子植物育种,2007,5(2):181-183.
8LI Ming-ju,FENG Jing,CAo Shi-qin,LIN Rui-ming,CHENG Geng,CHEN Wan-quan,XU Shi-chang.Postulation of Seedlings Resistance Genes to Yellow Rust in Commercial Wheat Cultivars from Yunnan Province in China[J].Agricultural Sciences in China,2011,10(11):1723-1731. 被引量：9
9Joseph Kinyoro Macharia,Ruth Wanyera.Effect of Stem Rust Race Ug99 on Grain Yield and Yield Components of Wheat Cultivars in Kenya[J].Journal of Agricultural Science and Technology(A),2012,2(4):423-431. 被引量：1
10K. Ulaganathan,P.S. Priya,A. Snehalatharani,M. Sashikanth,A.R. Krishna,S. Singh.Physical Integration of Root QTLs with the japonica Genome and Prediction of Probable Candidate Genes for Drought Tolerance in Rice[J].分子植物育种,2007,5(2):213-214.

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