[1]周克琴,孟英,张秋英,等.磷胁迫下豆科作物的基因调控[J].大豆科学,2009,28(02):332-336.[doi:10.11861/j.issn.1000-9841.2009.02.0332]
 ZHOU Ke-qin,MENG Ying,ZHANG Qiu-ying,et al.Genetic Control of Phosphate Stress in Legumes[J].Soybean Science,2009,28(02):332-336.[doi:10.11861/j.issn.1000-9841.2009.02.0332]
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磷胁迫下豆科作物的基因调控

《大豆科学》[ISSN:1000-9841/CN:23-1227/S] 卷: 第28卷 期数: 2009年02期 页码: 332-336 栏目: 出版日期: 2009-04-25
Title:
Genetic Control of Phosphate Stress in Legumes
文章编号:
1000-9841(2009)02-0332-05
作者:
周克琴1孟英2张秋英1刘洪家1金剑1刘居东1王光华1
1中国科学院东北地理与农业生态研究所,黑龙江 哈尔滨 150081;
2黑龙江省农业科学院耕作栽培研究所,黑龙江 哈尔滨 150086
Author(s):
ZHOU Ke-qin1MENG Ying2ZHANG Qiu-ying1LIU Hong-jia1JIN Jian1LIU Ju-dong1WANG Guang-hua1
1Northeast Institute of Geography and Agroecology,Chinese Academy of Science,Harbin 150081,Heilonhjiang;
2Crop Tillage and Cultivation Institute of Heilongjiang Academy of Agricultural Sciences,Harbin 150086,Heilongjiang,China
关键词:
磷胁迫豆科作物基因调控
Keywords:
P-stressLegumesGenetic control
分类号:
S565.1
DOI:
10.11861/j.issn.1000-9841.2009.02.0332
文献标志码:
A
摘要:
磷胁迫是全球耕地面临的共性问题。自然资源的局限限制了磷肥的生产,因此植物如何高效利用磷素已经成为研究热点。从基因调控的角度,包括磷胁迫诱导的EST、磷胁迫响应的转录因子、磷胁迫响应的MICRORNA以及植物激素等,综述了植物高效吸收利用磷素的机制。
Abstract:
The world′s arable land is lack of phosphorus.Because of resource limitation,the manufacture of P fertilizer becomes more costly and less available.Currently,studying the mechanism of adaptive strategies that make plants highly effectively utilize P is a popular issue.Here we reported P-responsive genes improving acquisition,use,and remobilization of P,including P stress-induced ESTs,P stress-responsive transcription factors,P stress-responsive MICRORNAs,sugar signals and phytohormones.It will be useful for advanced research.

参考文献/References:

[1] Vance C P,Uhde Stone C,Allan D L.Phosphorus acquisition and use:critical adaptations by plants for securing a nonrenewable resource[J].New Phytologist,2003,157:423-447.

[2]Vance C P.Symbiotic nitrogen fixation and phosphorus acquisition:plant nutrition in a world of declining renewable resources[J].Plant Physiology,2001,127:390-397.
[3] Steen I.Phosphorus availability in the 21st century.Management of a non-renewable resource[J].Phosphorus and Potassium,1997,217:25-31.
[4]Hammond J P,Broadly M R,White P J.Genetic responses to phosphorus deficiency[J].Annals Botany(Lond),2004,94:323-332.
[5] Lambers H Y,ShaneM W,CramerM D,et al.Root structure and functioning for efficient acquisition of phosphorus:matching morphological and physiological traits[J].Annals Botany(Lond),2006,98:693-713.
[6] Lynch J P.Root architecture and plant productivity[J].Plant Physiology,1995,109:7-13.
[7] Liao H,Rubio G,Yan X,et al.Effect of phosphorus availability on basal root shallowness in common bean[J].Plant and Soil,2001,232:69-79.
[8] Lynch J P,Brown K M.Topsoil foraging:an architectural adaptation of plants to low phosphorus availability[J].Plant and Soil,2001,237:225-237.
[9] Yan X,Liao H,Beebe S E,et al.QTL mapping of root hair and acid exudation traits and their relationship to phosphorus uptake in common bean[J].Plant and Soil,2004,265:17-29.
[10] Beebe S E,Rojas Pierce M,Yan X,et al.Quantitative trait loci for root architecture traits correlated with phosphorus acquisition in common bean[J].Crop Science,2006,46:413-423.
[11] Hill J O,Simpson R J,Moore A D,et al.Morphology and response of roots of pasture species to phosphorus and nitrogen nutrition[J].Plant and Soil,2006,286:7-19.
[12] Ochoa I E,Blair M W,Lynch J P.QTL analysis of adventitious root formation in common bean under contrasting phosphorus availability[J].Crop Science,2006,46:1609-1621.
[13] Bucciarelli B,Hanan J,Palmquist D,et al.A standardized method for analysis of Medicago truncatula phenotype development[J].Plant Physiology,2006,142:207-219.
[14] Uhde-Stone C,Gilbert G,Johnson J M F,et al.Acclimation of white lupin to phosphorus deficiency involves enhanced expression of genes related to organic acid metabolism[J].Plant and Soil,2003a,248:99d116.
[15] Uhde Stone C,Zinn K E,Ramirez Yáez M,et al.Nylon filter arrays reveal differential gene expression in proteoid roots of white lupin in response to phosphorus deficiency[J].Plant Physiology,2003,131:1064-1079.
[16] Broughton W J ,Hernández G,Blair M,et al.Beans(Phaseolus spp.):model food legumes[J].Plant and Soil,2003,252:55-128.
[17]Ramírez M,Graham M A,Blanco López L,et al.Sequencing and analysis of common bean ESTs.Building a foundation for functional genomics[J].Plant Physiology,2005,137:1211-1227.
[18Hernández G,Ramírez M,Valdés-López O,et al.Phosphorus stress in common bean:root transcript and metabolic responses[J].Plant Physiology,2007,144:752-767.
[19] López Bucio J,Hernández Abreu E,Sánchez Calderón L,et al.Phosphate availability alters architecture and causes changes in hormone sensitivity in the Arabidopsis root system[J].Plant Physiology,2002,129:244-256.
[20] López-Bucio J,Cruiz-Ramirez A,Herrera-Estrella L.The role of nutrient availability in regulating root architecture[J].Current Opinion in Plant Biology,2003,6:280-287.
[21] Raghothama K G,Karthikeyan A S.Phosphate acquisition[J].Plant and Soil,2005,274:37-49.
[22] Hammond J P,Bennett M J,Bowen H C,et al.Changes in gene expression in Arabidopsis shoots during phosphate starvation and the potential for developing smart plants[J].Plant Physiology,2003,132:578-596.
[23] Yi K,Wu Z,Zhou J,et al.OsPTF1,a novel transcription factor involved in tolerance to phosphate starvation in rice[J].Plant Physiology,2005,138:2087-2096.
[24] Aung K,Lin S I,Wu C C,et al.Pho2,a phosphate overaccumulator,is caused by a nonsense mutation in a microRNA399 target gene[J].Plant Physiology,2006,141:1000-1011.
[25]Bari R,Pant B D,Stitt M,et al.Pho2,microRNA399,and PHR1 define a phosphate-signaling pathway in plants[J].Plant Physiology,2006,141:988-999.
[26] Müller,Morant M,Jarmer H,et al.Genomewide analysis of the Arabidopsis leaf transcriptome reveals interaction of phosphate and sugar metabolism [J].Plant Physiology,2007,143:156-171.
[27] Wu P,Ma L,Hou X,et al.Phosphate starvation triggers distinct alternations of genome expression in Arabidopsis roots and leaves[J].Plant Physiology,2003,132:1260-1271.
[28] Mission J,Raghothama K G,Jain A,et al.A genome wide transcriptional analysis using Arabidopsis thaliana Affymetrix gene chips determined plant responses to phosphate deprivation[J].Proceedings of the National Academy of Science of the United States of America,2005,102:11934-1139.
[29] Graham M A,Ramirez M,Valdes López O,et al.Identification of candidate phosphorus stress induced genes in Phaseolus vulgaris through clustering analysis across several plant species[J].Functional Plant Biology,2006,33:789-797.
[30] Chen W,Provart N J,Glazebrook J,et al.Expression profilematrix of Arabidopsis transcription factor genes suggest their putative function in response to environmental stresses[J].The Plant Cell,2002,14:559-574.
[31] Rubio V,Linhares F,Solano R,et al.A conserved MYB transcription factor involved in phosphate starvation signaling both in vascular plants and in unicellular algae[J].Genes ﹠ Development,2001,15:2122-2133.
[32]Tang Z,Sadka A,Morishige D T,et al.Homeodomain leucine zipper proteins bind to the phosphate response domain of the soybean VspB tripartite promoter[J].Plant Physiology,2001,125:797-809.
[33] Singh K B,Foley R C,Ońate Sánchez L.Transcription factors in plant defense and stress responses[J].Current Opinion in Plant Biology,2002,5:430-436.
[34] Eulgem T,Rushton PJ,Robatzek S,et al.The WRKY superfamily of plant transcription factors[J].Trends in Plant Science,2000,5:199-206.
[35] Riechmann J L,Heard J,Martin G,et al.Arabidopsis transcription factors:genome wide comparative analysis among eukaryotes[J].Science,2000,290:2105-2110.
[36] Stracke R,Werber M,Weisshaar B.The R2R3-MYB gene family in Arabidopsis thaliana[J].Current Opinion in Plant Biology,2001,4:447-456.
[37] Guo A,He K,Liu D,et al.DATF:a database of Arabidopsis transcription factors[J].Bioinformatic,2005,21:2568-2569.
[38]Devaiah B N,Karthikeyan A S,Raghothama K G.WRKY75 transcription factor is a modulator by phosphate acquisition and root development in Arabidopsis[J].Plant Physiology,2007,143:1789-1801.
[39] Bartel D P.MicroRNAs:genomics,biogenesis,mechanism and function[J].Cell,2004,116:281-297.
[40]Jones-Rhodes M W,Bartel D P.Computational identification of plant microRNAs and their targets,including a stress induced miRNA[J].Molecular Cell,2004,14:787-799.
[41]Xie Z,Allen E,Fahlgren N,et al.Expression of Arabidopsis MIRNA genes[J].Plant Physiology,2005,138:2145-2154.
[42] Chen Z,Zhang J,Kong J,et al.Diversity of endogenous small non-coding RNAs in Oryza sativa[J].Genetica,2006,128:21-31.
[43] Reinhart B J,Weinstein E G,Rhoades M W,et al.MicroRNAs in plants[J].Genes ﹠ Development,2002,16:1616-1626.
[44] Rhoades M W,Reinhart B J,Lim L P,et al.Prediction of plant microRNA targets[J].Cell,2002,110:513-520.
[45] Sunkar R,Zhu J K.Novel and stress regulated microRNAs and other small RNAs from Arabidopsis[J].The Plant Cell,2004 16:2001-2019.
[46] Fujii H,Chiou T J,Lin S I,et al.A miRNA involved in phosphate-starvation response in Arabidopsis[J].Current Biolpgy,2005,15:2038-2043.
[47]Chiou T J,Aung K,Lin S L,et al.Regulation of phosphate homeostasis by microRNA in Arabidopsis[J].The Plant Cell,2006,18:412-421.
[48] Liu J,Uhde-Stone C,Li A,et al.A phosphate transporter with enhanced expression in proteoid roots of white lupin(Lupinus albus L.)[J].Plant and Soil,2001,237:257-266.
[49] Liu J,Samac D A,Bucciarelli B,et al.Signaling of phosphorus deficiency-induced gene expression in white lupin requires sugar and phloem transport[J].The The Plant Journalournal,2005,41:257-268.
[50] Uhde Stone C,Liu J,Zinn K E,et al.Transgenic proteoid roots of white lupin:a vehicle for characterizing and silencing root genes involved in adaptation to P stress[J].The Plant Journal,2005,44:840-853.
[51]Karthikeyan A S,Varadarajan D K,Jain A,et al.Phosphate starvation responses are mediated by sugar signaling in Arabidopsis[J].Planta,2006,doi/10.1007/s00425-006-0408-8.
[52] Nacry P,Canivenc G,Muller B,et al.A role for auxin redistribution in the responses of the root system architecture to phosphate starvation in Arabidopsis[J].Plant Physiology,2005,138:2061-2074.
[53]Gilbert G A,Knight J D,Vance C P,et al.Proteoid root development of phosphorus-deficient lupin is mimicked by auxin and phosphonate[J].Annals Botany(Lond),2000,85:921-928.
[54] Xie Q,Frugis G,Colgan D,et al.Arabidopsis NAC1 transduces auxin signal downstream of TIR1 to promote lateral root development[J].Genes ﹠ Development,2000,14:3024-3036.
[55] Borch K,Bouma T J,Lynch J P,et al.Ethylene:a regulator of root architectural responses to soil phosphorus availability[J].The Plant Cell Environ,1999,22:425-431.
[56] Ma Z,Baskin T I,Brown K M,et al.Regulation of root elongation under phosphorus stress involves changes in ethylene responsiveness[J].Plant Physiology 2003,131:1381-1390.
[57] Grierson C S,Parker J S,Kemp A C. Arabidopsis genes with roles in root hair development[J].Journal of Plant Nutrition and Soil Science,164:2001,131-140.
[58] Werner T,Motyka V,Laucou V,et al.Cytokinin-deficient transgenic Arabidopsis plants show multiple developmental alterations indicating opposite functions of cytokinins in the regulation of shoot and root meristem activity[J].The Plant Cell,2003,15:2532-2550.
[59]Aloni R,Aloni E,Langhans M,et al.Role of cytokinin and auxin shaping root architecture:regulating vascular differentiation,lateral root initiation,root apical dominance and root gravitropism[J].Annals Botany(Lond),2006,97:883-893.
[60] Lohar D P,Schaff J E,Laskey J G,et al.Cytokinins play opposite roles in lateral root formation,and nematode and rhizobial symbioses[J].The Plant Journal,2004,38:203-214.
[61]Martin A C,del Pozo J C,Iglesias J,et al.Influence of cytokinins on the expression of phosphate starvation responsive genes in Arabidopsis[J].The Plant Journal,2000,24:559-567.
[62] Neumann G,Massonneau A,Langlade N,et al.Physiological aspects of cluster root function and development in phosphorus deficient white lupin(Lupinus albus L.)[J].Annals Botany(Lond),2000,85:909-919.

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备注/Memo

作者简介:中国科学院东北地理与农业生态研究所青年博士研究基金项目(KZCX3-SW-NA3-28)。

通讯作者:周克琴(1970-),女,副研究员,博士,现从事作物营养胁迫生理研究。E-mail:keqinzhou1@hotmail.com。

更新日期/Last Update: 2014-10-04