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植物表皮蜡质参与干旱胁迫的反应机制

DOI: 10.13560/j.cnki.biotech.bull.1985.2015.08.001, PP. 1-8

Keywords: 植物表皮,水分胁迫,蜡质代谢,分子生物学

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Abstract:

植物表皮是植物与外部环境直接接触的部位,包括具有立体网状结构的角质和填充其间并覆盖其上的蜡质。植物在适应外界环境的过程中,表皮蜡质形成了特殊的结构和复杂的化学组成。植物表皮蜡质最重要的功能是参与阻止植物非气孔性失水,提高植物对水分的利用效率,以实现对干旱环境的适应。干旱环境会导致植物表皮蜡质代谢的变化,这种变化最终通过调控基因表达来实现。目前已经发现了多个蜡质代谢相关基因参与了植物对干旱环境的适应,部分基因已经成功克隆并且用于改良农作物的抗旱性。但这些基因参与干旱响应的分子机制及其与ABA的关系并不很清楚。就植物适应水分胁迫而发生的包括蜡质组成和含量在内的代谢变化,以及该过程中所涉及的主要基因及其分子生物学研究进行综述。探讨表皮蜡质在植物适应干旱中的重要作用及其分子机制,可为农作物的抗旱育种提供新型的分子标记和重要靶基因,最终服务于农业生产实践。

References

[1]  Samuels L, Kunst L, Jetter R. Sealing plant surfaces:Cuticular wax formation by epidermal cells[J]. Annual Review of Plant Biology, 2008, 59:683-707.
[2]  Macherius A, Kuschk P, Haertig C, et al. Composition changes in the cuticular surface lipids of the helophytes Phragmites australis and Juncus effuses as result of pollutant exposure[J]. Environmental Science and Pollution Research, 2011, 18(5):727-733.
[3]  Post-Beittenmiller D. Biochemistry and molecular biology of wax production plants[J]. Annual Review of Plant Physiology and Plant Molecular Biology, 1996, 147:405-430.
[4]  Hansjakob A, Bischof S, Bringmann G, et al. Very-long-chain aldehydes promote in vitro prepenetration processes of Blumeria graminis in a dose-and chain length-dependent manner[J]. New Phytology, 2010, 188(4):1039-1054.
[5]  Barnes JD, Percy KE, Paul ND, et al. The influence of UV-B radiation on the physicochemical nature of tobacco(Nicotiana tabacum L. )leaf surfaces[J]. Journal of Experimental Botany, 1996, 47(1):99-109.
[6]  Schreiber L, Riederer M. Ecophysiology of cuticular transpiration:comparative investigation of cuticular water permeability of plant species from different habitats[J]. Oecologia, 1996, 107:426-432.
[7]  Chen G, Komatsuda T, Ma JF, et al. An ATP-binding cassette subfamily G full transporter is essential for the retention of leaf water in both wild barley and rice[J]. Proceedings of the National Academy of Sciences USA, 2011, 108:12354-12359.
[8]  郭彦军, 韩龙, 唐华, 等. 水热胁迫对紫花苜蓿叶表皮蜡质组分及生理指标的影响[J]. 作物学报, 2011, 37(5):911-917.
[9]  张志飞, 饶力群, 胡晓敏, 等. 高羊茅叶片表皮蜡质含量与其抗旱性的关系[J]. 西北植物学报, 2007, 27(7):1417-1421.
[10]  Jenks MA. Critical issues with the plant cuticle’s function in drought tolerance[M]//Biochemical and molecular responses of plants to the environment. KeralaInd:Research Signposts, 2002.
[11]  Schreiber L. Polar paths of diffusion across plant cuticles:New evidence for an old hypothesis[J]. Annals of Botany, 2005, 95:1069-1073.
[12]  Burghardt M, Riederer M. Cuticular transpiration[M]//Riederer M, Müller C, eds. Biology of the plant cuticle. Oxford:Blackwell Publishing, 2002.
[13]  Burow GB, Franks CD, Xin Z. Genetic and physiological analysis of an irradiated bloomless mutant(epicuticular wax mutant)of sorghum[J]. Crop Science, 2008, 48(1):41-48.
[14]  Park JJ, Jin P, Yoon J, et al. Mutation in Wilted Dwarf and Lethal 1(WDL1)causes abnormal cuticle formation and rapid water loss in rice[J]. Plant Molecular Biology, 2010, 74(1-2):91-103.
[15]  Yang M, Yang QY, Fu TD, et al. Overexpression of the Brassica napus BnLAS gene in Arabidopsis affects plant development and increases drought tolerance[J]. Plant Cell Report, 2011, 30(3):373-388.
[16]  Oliveira AF, Meirelles ST, Salatino A. Epicuticular waxes from caatinga and cerrado species and their efficiency against water loss[J]. Anais da Academia Brasileira de Ciencias, 2003, 75(4):431-439.
[17]  Seo PJ, Lee SB, Suh MC, et al. The MYB96 transcription factor regulates cuticular wax biosynthesis under drought conditions in Arabidopsis[J]. Plant Cell, 2011, 23(3):1138-1152.
[18]  Bourdenx B, Bernard A, Domergue F, et al. Overexpression of Arabidopsis ECERIFERUM1 promotes wax Very-Long-Chain alkane biosynthesis and influences plant response to biotic and abiotic stresses[J]. Plant Physiology, 2011, 156(1):29-45.
[19]  Vogg G, Fischer S, Leide J, et al. Tomato fruit cuticular waxes and their effects on transpiration barrier properties:functional characterization of amutant deficient in a very-long-chain fatty acidβ-ketoacyl-CoA synthase[J]. Journal of Experimental Botany, 2004, 55(401):1401-1410.
[20]  Koornneef M, Hanhart CJ, Thiel F. A genetic and phenotypic description of eceriferum(cer)mutants in Arabidopsis thaliana [J]. Journal of Heredity, 1989, 80:118-122.
[21]  Xia YJ, Nicolau BJ, Schnable PS. Cloning and characterization of CER2, an Arabidopsis gene that affects cuticular wax accumulation[J]. Plant Cell, 1996, 8:1291-1304.
[22]  James DW Jr, Lim E, Keller J, et al. Directed tagging of the Arabidopsis FATTY ACID ELONGATION1(FAE1)gene with the maize transposon activator[J]. Plant Cell, 1995, 7(3):309-319.
[23]  Paul S, Gable K, Beaudoin F, et al. Members of the Arabidopsis FAE1-like 3-ketoacyl-coA synthase gene family substitute for the elop proteins of Saccharomyces cerevisiae[J]. Jounal of Biological Chemistry, 2006, 281(14):9018-9029.
[24]  Xu X, Dietrich CR, Lessire R, et al. The endoplasmic reticulum-associated maize GL8 protein is a component of the acyl-coenzyme A elongase ivolved in the production of cuticular waxes[J]. Plant Physiology, 2002, 128(3):924-934.
[25]  Qin BX, Tang D, Huang J, et al. Rice OsGL1-1 is involved in leaf cuticular wax and cuticle membrane[J]. Molecular Plant, 2011, 4(6):985-995.
[26]  Shinozaki K, Yamaguchi-Shinozaki K. Gene networks involved in drought stress response and tolerance[J]. Journal of Experimental Botany, 2007, 58:221-227.
[27]  Hooker TS, Millar AA, Kunst L, et al. Significance of the expression of the CER6 condensing enzyme for cuticular wax production in Arabidopsis[J]. Plant Physiology, 2002, 129:1568-1580.
[28]  Zhang JY, Broeckling CD, Bancaflor EB, et al. Overexpression of WXP1, a putative Medicago truncatula AP2 domain-containing transcription factor gene, increases cuticular wax accumulation and enhances drought tolerance in transgenic alfalfa(Medicago sativa)[J]. Plant Journal, 2005, 42:689-707.
[29]  Kosma DK, Bourdenx B, Bernard A, et al. The impact of water deficiency on leaf cuticle lipids of Arabidopsis[J]. Plant Physiology, 2009, 151(4):1918-1929.
[30]  Waisely. Biology of halophytes[M]. New York:Academic Press, 1972:127.
[31]  邓彦斌, 姜彦成, 刘健. 新疆10种藜科植物叶片和同化枝的旱生和盐生结构的研究[J]. 植物生态学报, 1998, 22(2):164-170.
[32]  Ristic Z, Jenks MA. Leaf cuticle and water loss in maize lines differing in dehydration avoidance[J]. Journal of Plant Physiology, 2002, 159:645-651.
[33]  祖元刚. 喜树高温和干旱逆境生态适应的分子机理[M]. 北京:科学出版社, 2010.
[34]  Parsons EP, Popopvsky S, Lohrey GT, et al. Fruit cuticle lipid composition and water loss in a diverse collection of pepper(Capsicum)[J]. Physiologia Plantarum, 2013, 149(2):160-174.
[35]  Kosma DK, Jenks MA. Eco-physiological and molecular-genetic determinants of plant cuticle function in drought and salt stress tolerance[M]//Jenks MA, Hasegawa PM, Jain sm, eds, Advances in molecular breeding toward drought and salt tolerant crops. The Dordrecht:Netherlands Springer, 2007.
[36]  Zhu L, Guo JS, Zhu J, et al. Enhanced expression of EsWAX1 improves drought tolerance with increased accumulation of cuticular wax and ascorbic acid in transgenic Arabidopsis[J]. Plant Physiology and Biochemistry, 2014, 75:24-35.
[37]  Zhu XY, Xiong LZ. Putative megaenzyme DWA1 plays essential roles in drought resistance by regulating stress-induced wax deposition in rice[J]. Proceedings of the National Academy of Sciences USA, 2013, 29:17790-17795.
[38]  Wang Y, Wan L, Zhang L, et al. An ethylene response factor OsWR1 responsive to drought stress transcriptionally activates wax synthesis related genes and increases wax production in rice[J]. Plant Molecular Biology, 2012, 78(3):275-288.
[39]  Zhu JK. Salt and drought stress signal transduction in plants[J]. Annual Review of Plant Biology, 2002, 53:247-273.
[40]  Rowland O, Zheng H, Hepworth SR, et al. CER4 encodes an alcoholforming fatty acyl-Coenzyme A reductase involved in cuticular wax production in Arabidopsis[J]. Plant Physiology, 2006, 142:866-877.
[41]  周波. 罗布麻解剖结构的研究[J]. 贵州工业大学学报, 2005, 34(6):97-99.
[42]  韦存虚, 王建波, 陈义芳, 等. 盐生植物星星草叶表皮具有泌盐功能的蜡质层[J]. 生态学报, 2004, 24(11):2451-2456.
[43]  章英才. 不同盐浓度环境中几种植物叶的比较解剖研究[J]. 安徽农业科学, 2006, 34(21):5374-5473.
[44]  Kimbara J, Yoshida M, Ito H, et al. Inhibition of CUTIN DEFICIENT 2 causes defects in cuticle function and structure and metabolite changes in tomato fruit[J]. Plant Cell Physiology, 2013, 54(9):1535-1548.
[45]  Goodwin SM, Jenks MA. Plant cuticle function as a barrier to water loss[M]// Jenks M, Hasegawa PM, eds. Plant Abiotic Stress. Oxford:Blackwell Publishing, 2005.
[46]  Mamrutha HM, Mogili T, Lakshmi KJ, et al. Leaf cuticular wax amount and crystal morphology regulate post-harvest water loss in mulberry(Morus species)[J]. Plant Physiology and Biochemistry, 2010, 48:690-696.
[47]  Kunst L, Samuels AL. Biosynthesis and secretion of plant cuticular wax[J]. Progress in Lipid Research, 2003, 42:51-80.
[48]  Barthlott W, Neinhuis C, Cutler D, et al. Classification and terminology of plant epicuticular waxes[J]. Botanical Journal of the Linnean Society, 1998, 126:237-260.
[49]  Valenti HH, Pitty A, Owen M. Environmental effects on vel-vetleaf(Abutilon theophrasti)epicuticular wax deposition and herbicide absorption[J]. Weed Sci, 2011, 59(1):14-21.
[50]  Castillo L, Díaz M, González-Coloma A, et al. Clytostoma callistegioides(Bignoniaceae)wax extract with activity on aphid settling[J]. Phytochemistry, 2010, 71(17-18):2052-2057.
[51]  Shepherd T, Griffithsd W. The effects of stress on plant cuticular waxes[J]. New Phytology, 2006, 171:469-499.
[52]  Kosma DK, Parsons UP, Isaacson T, et al. Fruit cuticle lipid composition during development in tomato ripening mutants[J]. Physiologia Plantarum, 2010, 139:107-117.
[53]  Niederl S, Kirsch T, Riederer M, et al. Co-permeability of 3 H-labeled water and 14 C-labeld organic acids across isolated plant cuticles:investigating cuticular paths of diffusion and predicting cuticular transpiration[J]. Plant Physiology, 1998, 116:117-123.
[54]  Schreiber L, Elshatshat S, Koch K, et al. AgCl precipitates in isolated cuticular membranes reduce rates of cuticular transpiration[J]. Planta, 2006, 223:283-290.
[55]  Premachandra GS, Saneoka H, Fujita K, et al. Leaf water relations, osmotic adjustment, cell membrane stability, epicuticular wax load and growth as affected by increasing water deficits in Sorghum[J]. Journal of Experimental Botany, 43(12):1569-1576.
[56]  Broun P, Poindexter P, Osborne E, et al. WIN1, a transcriptional activator of epidermal wax accumulation in Arabidopsis[J]. Proceedings of the National Academy of Sciences USA, 2004, 101:4706-4711.
[57]  Weng H, Molina I, Shockey J, et al. Organ fusion and defective cuticle function in a lacs1 lacs2 double mutant of Arabidopsis[J]. Planta, 2010, 231(5):1089-1100.
[58]  Xu X, Feng J, Lü S, et al. Leaf cuticular lipids on the Shandong and Yukon ecotypes of saltwater cress, Eutrema salsugineum, and their response to water deficiency and impact on cuticle permeability[J]. Physiologia Plantarum, 2014, 151(4):446-458.
[59]  Aarts MG, Keijzer CJ, Stiekema WJ, et al. Molecular characteriza-tion of the CER1 gene of Arabidopsis involved in epicuticular wax biosynthesis and pollen fertility[J]. Plant Cell, 1995, 7:2115-2127.
[60]  Hannoufa A, Negruk V, Eisner G, et al. The CER3 gene of Arabidopsis thaliana is expressed in leaves, stems, roots, flowers and apical meristems[J]. Plant Journal, 1996, 10(3):459-467.
[61]  Fiebig A, Mayfield JA, Miley NL, et al. Alterations in CER6, a gene identical to CUT1, differentially affect long-chain lipid content on the surface of pollen and stems[J]. Plant Cell, 2000, 12:2001-2008.
[62]  Kunst L, Samuels L. Plant cuticles shine:advances in wax biosynthesis and export[J]. Current Opinin of Plant Biololy, 2009, 12:721-727.

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