植物响应重金属胁迫的蛋白质组学研究进展

doi:10.11686/cyxb20130435

摘要/Abstract

摘要： 重金属对生态系统造成的污染已成为全球关注的问题。植物对重金属的摄取不仅影响其正常生长,并能通过食物链来威胁人类及整个生态系统的健康。在mRNA水平上的基因表达分析,增强了人们对植物响应重金属的理解。然而,关于相关功能基因组翻译方面的问题仍未得到有效解决。通过分析鉴定相关响应基因和功能蛋白,获取翻译及翻译后水平上的信息,能为植物响应重金属胁迫提供更深层次的理解。本研究分析比较了近年来重金属胁迫蛋白组学研究技术,综述了植物响应重金属胁迫的蛋白组学研究进展,探讨从亚细胞蛋白组学水平解析植物解毒重金属过程的可能性,并提出未来该研究方向所面临的挑战及应对策略,为揭示植物与重金属相互作用的分子机制提供有效方法。

Abstract: Heavy metal pollution of ecosystems is a global problem. Uptake of heavy metals by plants not only affects the regular growth, but also threatens the health of humans and the whole ecosystem throughout the food chains. Although the analysis of gene expression at the mRNA level has enhanced our understanding of the response of plants to heavy metals, many questions regarding the functional translated portions of plant genomes under metal stress remain unanswered. Acquiring information at the translational and post-translational levels by analyzing and identifying the heavy metal-responsive genes and functional proteins of the plant is needed for a deeper understanding of the response of plants to heavy metal stress. This article analyzes and compares technologies used in studying proteomic responses to heavy metal stress for the past few years and reviews developments in analyzing heavy metal-responsive mechanisms of plants using proteomics. The possibility of illustrating heavy metal detoxification pathways in plants at a sub-cellular proteomic level is discussed. Challenges and strategies encountered in this research field are proposed to provide an effective process in elucidating the molecular mechanism of the interaction between plants and heavy metals.

中图分类号:

Q945.78

薛亮,刘建锋,史胜青,魏远,常二梅,高暝,江泽平. 植物响应重金属胁迫的蛋白质组学研究进展[J]. 草业学报, 2013, 22(4): 300-311.

XUE Liang, LIU Jian-feng, SHI Sheng-qing, WEI Yuan, CHANG Er-mei, GAO Ming, JIANG Ze-ping. A review on the progress of proteomic study on plant responses to heavy metal stress[J]. Acta Prataculturae Sinica, 2013, 22(4): 300-311.

参考文献

Nriagu J O, Pacyna J M. Quantitative assessment of worldwide contamination of air, water and soils with trace metals. Nature, 1998, 333: 134-139.
张树金, 李廷轩, 邹同静, 等. 铅锌尾矿区优势草本植物体内铅及氮、磷、钾含量变化特征. 草业学报, 2012, 21(1): 162-169.
Rigola D, Fiers M, Vurro E, et al. The heavy metal hyperaccumulator Thlaspi caerulescens expresses many species-specific genes, as identified by comparative expressed sequence tag analysis. New Phytologist, 2006, 170: 753-766.
Lasat M M. Phytoextraction of toxic metals: A review of biological mechanisms. Journal of Environmental Quality, 2002, 31: 109-120.
Cobbett C S. Phytochelatins and their roles in heavy metal detoxification. Plant Physiology, 2000, 123: 825-832.
Küpper H, Parameswaran A, Leitenmaier B, et al. Cadmium-induced inhibition of photosynthesis and long-term acclimation to cadmium stress in the hyperaccumulator Thlaspi caerulescens. New Phytologist, 2007, 175: 655-674.
Heckathorn S A, Mueller J K, Laquidice S, et al. Chloroplast small heat-shock proteins protect photosynthesis during heavy metal stress. American Journal of Botany, 2004, 91: 1312-1318.
Abercrombie J M, Halfhill M D, Ranjan P, et al. Transcriptional responses of Arabidopsis thaliana plants to As (V) stress. BMC Plant Biology, 2008, 8: 87.
Norton G J, Lou-Hing D E, Meharg A A, et al. Rice-arsenate interactions in hydroponics: whole genome transcriptional analysis. Journal of Experimental Botany, 2008, 59: 2267-2276.
Weber M, Trampczynska A, Clemens S. Comparative transcriptome analysis of toxic metal responses in Arabidopsis thaliana and the Cd²⁺-hypertolerant facultative metallophyte Arabidopsis halleri. Plant Cell and Environment, 2006, 29: 950-963.
Kovalchuk I, Titov V, Hohn B, et al. Transcriptome profiling reveals similarities and differences in plant responses to cadmium and lead. Mutation Research, 2005, 570: 149-161.
Diz A P, Martónez-Fernández M, Rolán-Alvarez E. Proteomics in evolutionary ecology: linking the genotype with the phenotype. Molecular Ecology, 2012, 21: 1060-1080.
Luque-Garcia J L, Cabezas-Sanchez P, Camara C. Proteomics as a tool for examining the toxicity of heavy metals. Trends in Analytical Chemistry, 2011, 30: 703-716.
Saravanan R S, Rose J K. A critical evaluation of sample extraction techniques for enhanced proteomic analysis of recalcitrant plant tissues. Proteomics, 2004, 4: 2522-2532.
Sarry J E, Kuhn L, Ducruix C, et al. The early responses of Arabidopsis thaliana cells to cadmium exposure explored by protein and metabolite profiling analyses. Proteomics, 2006, 6: 2180-2198.
Zhen Y, Qi J L, Wang S S, et al. Comparative proteome analysis of differentially expressed proteins induced by Al toxicity in soybean. Physiologia Plantarum, 2007, 131: 542-554.
Isaure M P, Fraysse A, Devès G, et al. Micro-chemical imaging of cesium distribution in Arabidopsis thaliana plant and its interaction with potassium and essential trace elements. Biochimie, 2006, 88: 1583-1590.
Wang W, Scali M, Vignani R, et al. Protein extraction for two-dimensional electrophoresis from olive leaf, a plant tissue containing high levels of interfering compounds. Electrophoresis, 2003, 24: 2369-2375.
阮松华, 马华升. 蛋白质组分离技术. 植物蛋白质组学. 北京: 中国农业出版社, 2009.
Sobkowiak R, Deckert J. Proteins induced by cadmium in soybean cells. Journal of Plant Physiology, 2006, 163: 1203-1206.
卢国栋, 张克山, 刘永杰,等. 蛋白质组学样品处理方法研究进展. 中国动物检疫, 2011, 28(6): 78-81.
Berggren K, Chernokalskaya E, Steinberg T H, et al.Background-free, high sensitivity staining of proteins in one- and two-dimensional sodium dodecyl sulfate-polyacrylamide gels using a luminescent ruthenium complex. Electrophoresis, 2000, 21: 2509-2521.
Minden J S, Dowd S R, Meyer H E, et al.Difference gel electrophoresis. Electrophoresis, 2009, 30: S156-S161.
Marion F C, Hans-Peter B, Christelle L G, et al. Effect of manganese toxicity on the proteome of the leaf apoplast in cowpea. Plant Physiology, 2003, 133: 1935-1946.
Führs H, Hartwig M, Molina L E, et al. Early manganese-toxicity response in Vigna unguiculata-a proteomic and transcriptomic study. Proteomics, 2008, 8: 149-159.
Fagioni M, D’Amici G M, Timperio A M, et al. Proteomic analysis of multiprotein complexes in the thylakoid membrane upon cadmium treatment. Journal of Proteome Research, 2009, 8: 310-326.
Kung C C, Huang W N, Huang Y C, et al. Proteomic survey of copper-binding proteins in Arabidopsis roots by immobilized metal affinity chromatography and mass spectrometry. Proteomics, 2006, 6: 2746-2758.
Giovanna V, Marta M, Nelson M. Two-dimensional liquid chromatography technique coupled with mass spectrometry analysis to compare the proteomic response to cadmium stress in plants. Journal of Biomedicine and Biotechnology, 2010, doi: 10.1155/2010/567510.
Kennedy S. The role of proteomics in toxicology: identification of biomarkers of toxicity by protein expression analysis. Biomarkers, 2002, 7: 269-290.
Mann M. Functional and quantitative proteomics using SILAC. Nature Review Molecular Cell Biology, 2006, 7: 952-958.
Zieske L R. A perspective on the use of iTRAQ reagent technology for protein complex and profiling studies. Journal of Experimental Botany, 2006, 57: 1501-1508.
Kellermann J. ICPL——isotope-coded protein label. Methods in Molecular Biology, 2008, 424: 113-123.
Wildes D, Wells J A. Sampling the N-terminal proteome of human blood. Proceeding of the National Academy of Sciences of the United States of America, 2010, 107: 4561-4566.
Patterson J, Ford K, Cassin A, et al. Increased abundance of proteins involved in phytosiderophore production in boron-tolerant barley. Plant Physiology, 2007, 144: 1612-1631.
Aina R, Labra M, Fumagalli P, et al. Thiol-peptide level and proteomic changes in response to cadmium toxicity in Oryza sativa L. roots. Environmental and Experimental Botany, 2007, 59: 381-392.
Ahsan N, Lee S H, Lee D G, et al. Physiological and protein profiles alternation of germinating rice seed- lings exposed to acute cadmium toxicity. Comptes Rendus Biologies, 2007, 330: 735-746.
Kieffer P, Planchon S, Oufir M, et al. Combining proteomics and metabolite analyses to unravel cadmium stress-response in poplar leaves. Journal of Proteome Research, 2009, 8: 400-417.
翁兆霞. 镉胁迫下秋茄(Kandelia candel)根系蛋白质组变化及差异表达蛋白功能研究. 福建: 福建农林大学, 2011.
Gillet S, Decottignies P, Chardonnet S, et al. Cadmium response and redoxin targets in Chlamydomonas reinhardtii: A proteomic approach. Photosynthesis Research, 2006, 89: 201-211.
Tuomainen M H, Nunan N, Lehesranta S J, et al. Multivariate analysis of protein profiles of metal hyperaccumulator Thlaspi caerulescens accessions. Proteomics, 2006, 6: 3696-3706.
Zhao L, Sun Y L, Cui S X, et al. Cd-induced changes in leaf proteome of the hyperaccumulator plant Phytolacca americana. Chemosphere, 2011, 85: 56-66.
金晓芬. 镉超积累植物东南景天(Sedum alfredii)谷胱甘肽代谢特征及比较蛋白质组学研究. 浙江: 浙江大学, 2008.
Requejo R, Tena M. Maize response to acute arsenic toxicity as revealed by proteome analysis of plant shoots. Proteomics, 2006, 6: S156-S162.
Ahsan N, Lee D G, Alam I, et al. Comparative proteomic study of arsenic-induced differentially expressed proteins in rice roots reveals glutathione plays a central role during As stress. Proteomics, 2008, 8: 3561-3576.
Duquesnoy I, Goupil P, Nadaud I, et al. Identification of Agrostis tenuis leaf proteins in response to As(V) and As(III) induced stress using a proteomics approach. Plant Science, 2009, 176: 206-213.
Labra M, Gianazza E, Waitt R, et al. Zea mays protein changes in response to potassium dichromate treatments. Chemosphere, 2006, 62: 1234-1244.
Vannini C, Marsoni M, Domingo G, et al. Proteomic analysis of chromate-induced modifications in Pseudokirchneriella subcapitata. Chemosphere, 2009, 76: 1372-1379.
Sharmin S A, Alam I, Kim K H, et al. Chromium-induced physiological and proteomic alterations in roots of Miscanthus sinensis. Plant Science, 2012, 187: 113-126.
Vannini C, Domingo G, Marsoni M, et al. Proteomic changes and molecular effects associated with Cr(III) and Cr(VI) treatments on germinating kiwifruit pollen. Phytochemistry, 2011, 72: 1786-1795.
Hajduch M, Rakwal R, Agrawal G K, et al. High-resolution two-dimensional electrophoresis separation of proteins from metal-stressed rice (Oryza sativa) leaves: drastic reductions/fragmentation of ribulose-1, 5-bisphosphate carboxylase/oxygenase and induction of stress-related proteins. Electrophoresis, 2001, 22: 2824-2831.
Smith A P, DeRidder B P, Guo W J, et al. Proteomic analysis of Arabidopsis glutathione S-transferases from Benoxacor- and copper-treated seedlings. Journal of Biological Chemistry, 2004, 279: 26098-26104.
Li F, Shi J, Shen C, et al. Proteomic characterization of copper stress response in Elsholtzia splendens roots and leaves. Plant Molecular Biology, 2009, 71: 251-263.
Zhou S P, Sauvé R, Thannhauser T W. Proteome changes induced by aluminium stress in tomato roots. Journal of Experimental Botany, 2009, 60: 1849-1857.
Kumar S P, Varrman P A M, Kumari B D R. Identification of differentially expressed proteins in response to Pb stress in Catharanthus roseus. African Journal of Environmental Science and Technology, 2011, 5: 689-699.
Nicolardi V, Cai G, Parrotta L, et al. The adaptive response of lichens to mercury exposure involves changes in the photosynthetic machinery. Environmental Pollution, 2012, 160: 1-10.
John P, Kris F, Andrew C, et al. Increased abundance of proteins involved in phytosiderophore production in Boron-tolerant Barley. Plant Physiology, 2007, 144: 1612-1631.
Ingle R A, Smith J A C, Sweetlove L J. Responses to nickel in the proteome of the hyperaccumulator plant Alyssum lesbiacum. Biometals, 2005, 18: 627-641.
刘俊祥, 孙振元, 勾萍, 等. 镉胁迫下多年生黑麦草的光合生理响应. 草业学报, 2012, 26(3):191-197.
Liu X, Zhang S, Shan X, et al. Toxicity of arsenate and arsenite on germination seedling growth and amylolytic activity of wheat. Chemosphere, 2005, 61: 293-301.
Shanker A K, Cervantes C, Loza-Tavera H, et al. Chromium toxicity in plants. Environment International, 2005, 31: 739-753.
Bona E, Marsano F, Cavaletto M, et al. Proteomic characterization of copper stress response in Cannabis sativa roots. Proteomics, 2007, 7: 1121-1130.
Hall J L. Cellular mechanisms for heavy metal detoxification and tolerance. Journal of Experimental Botany, 2002, 53: 1-11.
Jamet E, Albenne C, Boudart G, et al. Recent advances in plant cell wall proteomics. Proteomics, 2008, 8: 893-908.
Jiang W S, Liu D H. Pb-induced cellular defense system in the root meristematic cells of Allium sativum. BMC Plant Biology, 2010, 10: 40.
Ma J F, Ryan P R, Delhaize E. Aluminium tolerance in plants and the complexing role of organic acids. Trends in Plant Science, 2001, 6: 273-278.
Douchiche O, Driouich A, Morvan C. Spatial regulation of cell-wall structure in response to heavy metal stress: cadmium-induced alteration of the methyl-esterification pattern of homogalacturonans. Annals of Botany, 2010, 105: 481-491.
Xiong J, An L, Lu H, et al. Exogenous nitric oxide enhances cadmium tolerance of rice by increasing pectin and hemicellulose contents in root cell wall. Planta, 2009, 230: 755-765.
Zhu J, Alvarez S, Marsh E L, et al. Cell wall proteome in the maize primary root elongation zone. II. Region-specific changes in water soluble and lightly ionically bound proteins under water deficit. Plant Physiology, 2007, 145: 1533-1548.
Kong F J, Oyanagi A, Komatsu S. Cell wall proteome of wheat roots under flooding stress using gel-based and LC MS/MS-based proteomics approaches. Biochimica Biophysica Acta, 2010, 1804: 124-136.
Komatsu S, Kobayashi Y, Nishizawa K, et al. Comparative proteomics analysis of differentially expressed proteins in soybean cell wall during flooding stress. Amino Acids, 2010, 39: 1435-1449.
Cobbett C S, Hussain D, Haydon M J. Structural and functional relationships between type 1_B heavy metal-transporting P-type ATPases in Arabidopsis. New Phytologist, 2003, 159: 315-321.
Delhaize E, Kataoka T, Hebb D M, et al. Genes encoding proteins of the cation diffusion facilitator family that confer manganese tolerance. Plant Cell, 2003, 15: 1131-1142.
Clemens S. Toxic metal accumulation, responses to exposure and mechanisms of tolerance in plants. Biochimie, 2006, 88: 1707-1719.
Kovácik J, Klejdus B. Dynamics of phenolic acids and lignin accumulation in metal-treated Matricaria chamomilla roots. Plant Cell Reports, 2008, 27: 605-615.
Sarry J E, Kuhn L, Ducruix C, et al. The early responses of Arabidopsis thaliana cells to cadmium exposure explored by protein and metabolite profiling analyses. Proteomics, 2006, 6: 2180-2198.
Yang Q, Wang Y, Zhang J, et al. Identification of aluminum-responsive proteins in rice roots by a proteomic approach: cysteine synthase as a key player in Al response. Proteomics, 2007, 7: 737-749.
Rodríguez-Serrano M, Romero-Puertas M C, Zabalza A, et al. Cadmium effect on oxidative metabolism of pea (Pisum sativum) roots. Imaging of reactive oxygen species and nitric oxide accumulation in vivo. Plant Cell and Environment, 2006, 8: 1532-1544.
Ahsan N, Renaut J, Komatsu S. Recent developments in the application of proteomics to the analysis of plant responses to heavy metals. Proteomics, 2009, 9: 2602-2621.
Tong Y P, Kneer R, Zhu Y G. Vacuolar compartmentalization: a second-generation approach to engineering plants for phytoremediation. Trends in Plant Science, 2004, 9: 7-9.
Krmer U, Pickering I J, Prince R C, et al. Subcellular localization and speciation of nickel in hyperaccumulator and non-accumulator Thlaspi species. Plant Physiology, 2000, 122: 1343-1353.
Morel M, Crouzet J, Gravot A, et al. AtHMA3, a P1B-ATPase allowing Cd/ Zn/ Co/ Pb vacuolar storage in Arabidopsis. Plant Physiology, 2009, 149: 894-904.
Schneider T, Schellenberg M, Meyer S, et al. Quantitative detection of changes in the leaf-mesophyll tonoplast proteome in dependency of a cadmium exposure of barley (Hordeum vulgare) plants. Proteomics, 2009, 9: 2668-2677.
Martinoia E, Maeshima M, Neuhaus H E. Vacuolar transporters and their essential role in plant metabolism. Journal of Experimental Botany, 2007, 58: 83-102.
Jaquinod M, Villiers F, Kieffer-Jaquinod S, et al. A proteomics dissection of Arabidopsis thaliana vacuoles isolated from cell culture. Molecular & Cellular Proteomics, 2007, 6: 394-412.
Konishi H, Maeshima M, Komatsu S. Characterization of vacuolar membrane proteins changed in rice root treated with gibberellin. Journal of Proteome Research, 2005, 4: 1775-1780.
Endler A, Meyer S, Schelbert S, et al. Identification of a vacuolar sucrose transporter in barley and Arabidopsis mesophyll cells by a tonoplast proteomic approach. Plant Physiology, 2006, 141: 196-207.
Schmidt U G, Endler A, Schelbert S, et al. Novel tonoplast transporters identified using a proteomic approach with vacuoles isolated from caulifiower buds. Plant Physiology, 2007, 145: 216-229.

[1]	鲁艳,雷加强,曾凡江,徐立帅,彭守兰,刘国军. NaCl处理对梭梭生长及生理生态特征的影响[J]. 草业学报, 2014, 23(3): 152-159.
[2]	李辉,康健,赵耕毛,尹晓明,梁明祥. 盐胁迫对菊芋干物质和糖分积累分配的影响[J]. 草业学报, 2014, 23(2): 160-170.
[3]	张怀山,赵桂琴,栗孟飞,夏曾润,王春梅. 中型狼尾草幼苗对PEG、低温和盐胁迫的生理应答[J]. 草业学报, 2014, 23(2): 180-188.
[4]	王若梦,董宽虎,李钰莹,李晨,杨静芳. 外源植物激素对NaCl胁迫下苦马豆苗期脯氨酸代谢的影响[J]. 草业学报, 2014, 23(2): 189-195.
[5]	张金政，张起源，孙国峰，何卿，李晓东，刘洪章. 干旱胁迫及复水对玉簪生长和光合作用的影响[J]. 草业学报, 2014, 23(1): 167-176.
[6]	宋以刚，李利，曾歆花，邓敏，张希明. 异子蓬二型性种子萌发对盐胁迫的响应[J]. 草业学报, 2014, 23(1): 192-198.
[7]	吴婧，才华，柏锡，纪巍，魏正巍，唐立郦，赵阳，朱延明. 转GsGST13/SCMRP基因双价苜蓿的耐盐性分析[J]. 草业学报, 2014, 23(1): 257-265.
[8]	李先婷,曹靖,魏晓娟,董利苹,代立兰. NaCl渐进胁迫对啤酒大麦幼苗生长、离子分配和光合特性的影响[J]. 草业学报, 2013, 22(6): 108-116.
[9]	薛秀栋,董晓颖,段艳欣,李培环,王滨. 不同盐浓度下3种结缕草的耐盐性比较研究[J]. 草业学报, 2013, 22(6): 315-311.
[10]	丁继军,潘远智,刘柿良,何杨,王力,李丽. 土壤重金属镉胁迫对石竹幼苗生长的影响及其机理[J]. 草业学报, 2013, 22(6): 77-87.
[11]	徐严,魏小红,李兵兵,曹丽,唐志敏. 外源NO对NaCl胁迫下紫花苜蓿种子萌发及幼苗氧化损伤的影响[J]. 草业学报, 2013, 22(5): 145-154.
[12]	彭燕,李州. 干旱预处理对抗旱性不同的2个草地早熟禾品种耐热性能的影响[J]. 草业学报, 2013, 22(5): 229-238.
[13]	霍平慧, 李剑峰, 师尚礼, 张淑卿. 种子超干贮藏对中性盐胁迫下紫花苜蓿生长和抗性的影响[J]. 草业学报, 2013, 22(5): 175-182.
[14]	贾学静,董立花,丁春邦,李旭,袁明. 干旱胁迫对金心吊兰叶片活性氧及其清除系统的影响[J]. 草业学报, 2013, 22(5): 248-255.
[15]	杨小菊,赵昕,石勇,李新荣 . 盐胁迫对砂蓝刺头不同器官中离子分布的影响[J]. 草业学报, 2013, 22(4): 116-122.