四裂红景天与长鳞红景天叶片中抗氧化系统随海拔梯度的变化

doi:10.17521/cjpe.2005.0043

摘要/Abstract

摘要：

以分布于乌鲁木齐河源区天山中段不同海拔高度的四裂红景天 (Rhodiolaquadrifida) (35 0 0~ 380 5m) 及长鳞红景天 (R.gelida) (380 5~ 4 0 10m) 为试材, 通过对比分析两种红景天在一连续的海拔梯度上种内及种间叶片膜脂过氧化及抗氧化保护系统的变化, 初步探讨植物对于高山极端环境的适应机制。结果显示, 分布于海拔较高的长鳞红景天其叶片中膜脂过氧化产物丙二醛 (MDA) 的含量明显高于分布海拔较低的四裂红景天, 而两种红景天种内膜脂过氧化水平则没有随海拔升高呈现出明显差异。此外, 抗氧化保护酶CAT, POD, SOD, GR和ASA_POD 的活性与非酶促抗氧化剂ASA、GSH的含量不仅在种间存在有明显差异, 长鳞红景天中明显高于四裂红景天, 而且在两种红景天种内亦随海拔升高有不同程度地提高。表明当海拔升高时, 虽然环境条件渐趋恶劣, 对植物造成的氧化胁迫增强, 但红景天脂膜保护系统的功能亦相应加强, 从而增强了其抵抗逆境胁迫的能力。其中以过氧化物酶POD的活性变化最为显著 :在 380 5m以下海拔区, 于四裂红景天叶片中均未检测到该酶活性, 而分布海拔较高的长鳞红景天叶片中该酶活性则随海拔升高明显增强, 推测POD可能在红景天适应特殊生境中起着重要的作用, 亦可能与高海拔区长鳞红景天取代四裂红景天有关。

关键词: 海拔高度, 红景天, 抗氧化保护系统, 丙二醛

Abstract:

Alpine environments are characterized by rapid changes in climate, and leaves of alpine plants are routinely exposed to high light intensities at low temperatures. The fact that there seems to be no impairment of photosynthesis by high light and low temperatures under field conditions indicates a very well regulated system of carbohydrate turnover together with a functional system of antioxidants. To study the mechanisms of adaptation of alpine plants, we investigated the antioxidative defense capacity in leaves of two alpine plants, Rhodiola quadrifida and R. gelida. Field investigations were carried out on the slopes of Tianshan Mountain near the Tianshan Glacier NO. 1. Along this slope, R. quadrifida was found between 3 500 and 3 805 m and R. gelida was found between 3 805 and 4 010 m. The two species coexisted at 3 805 m. Plant specimens used in this experiment were collected at 50 m intervals from 3 610 to 3 900 m. Our results showed that the malondialdehyde (MDA) content in leaves of R. gelida was significantly greater than that in R. quadrifida, suggesting that R. gelida might suffer more serious oxidative stress compared to R. quadrifida. The fact that R. gelida can survive and maintain normal metabolism at high elevations suggests that it might be an adaptive mechanisms to endure serious oxidative stress in this harsh environment. The increase in the activities of antioxidative enzymes, such as superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX) and glutathione reductase (GR) as well as the contents of reduced glutathione (GSH) and ascorbic acid (AsA), in the leaves of R. gelida suggested a combined and balanced enhancement of antioxidants to improve stress resistance in alpine plant leaves. Among all the antioxidative enzymes examined, peroxidase (POD) was quite distinct from others. Activity of POD was below the limits of detection in leaves of R. quadrifida collected from elevations lower than 3 805 m, but enhanced activity was observed in leaves of R. gelida as altitude increased implying that POD might play an important role in plant adaptation to alpine environments. Given the inverse relationship between growth rate and peroxidase activity demonstrated in many plant developmental systems, in-depth studies on the role of peroxidases in adaptation of R. gelida to high altitudes are warranted.

Key words: Altitudes, Rhodiola quadrifida, Rhodiola gelida, Antioxidants, Adaptation

汪晓峰, 任红旭, 孙国钧. 四裂红景天与长鳞红景天叶片中抗氧化系统随海拔梯度的变化. 植物生态学报, 2005, 29(2): 331-337. DOI: 10.17521/cjpe.2005.0043

WANG Xiao-Feng, REN Hong-Xu, SUN Guo-Jun. ALTITUDINAL VARIATION OF ANTIOXIDATIVE SYSTEM IN LEAVES OF RHODIOLA QUADRIFIDA AND R. GELIDA. Chinese Journal of Plant Ecology, 2005, 29(2): 331-337. DOI: 10.17521/cjpe.2005.0043

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2005.0043

https://www.plant-ecology.com/CN/Y2005/V29/I2/331

图/表 8

图1 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片MDA含量变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.1 Content of MDA in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图2 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片SOD活性变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.2 Activity of SOD in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图3 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片CAT活性变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.3 Activity of CAT in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图4 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片POD活性变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.4 Activity of POD in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图5 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片ASA-POD活性变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.5 Activity of ASA-POD in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图6 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片GR活性变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.6 Activity of GR in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图7 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片GSH含量变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.7 Content of GSH in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

图8 不同海拔高度四裂红景天 (空心) 和长鳞红景天 (实心) 叶片ASA含量变化具有相同字母的柱体间差异不显著 (p=0.05)

Fig.8 Content of ASA in leaves of Rhodiola quadrifida (open) and R. gelida (solid) grown at different altitudes Bars sharing the same letter are not different at p=0.05

参考文献 24

[1]	Bailly C, Benamar A, Corbineau F (1996). Changesinmalon dialdehydecontentandinsuperoxidedismutase, catalaseglu tathionereductaseactivitiesinsunflowerseedsasrelatedtodeteriorationduringacceleratedaging. PhysiologiaPlan tarum, 97,104-110.
[2]	Chen X (陈雄), Wang ZL (王宗灵), Ren HX (任红旭) (1999). EffectsofaltitudeonantioxidativesysteminleavesandrootsofPlantagomajor. ActaBotanicaSinica (植物学报), 41,846-850. (inChinesewithEnglishabstract).
[3]	deSouzaI RP, MacAdam JW (1998). AtransientincreaseinapoplasticperoxidaseactivityprecedesdecreaseinelongationrateofB73maize (Zeamays) leafblades. PhysiologiaPlan tarum, 104,556-562.
[4]	Hodges DM, Andrews CJ, Johson DA (1997). Antioxidantenzymeresponsestochillingstressindifferentiallysensitiveinbredmaizeline. JournalofExperimentalBotany, 48,1105-1113.
[5]	Kang HM, Saltveit ME (2002). Chillingtoleranceofmaize, cucumberandriceseedlingleavesandrootsaredifferentiallyaffectedbysalicylicacid. PhysiologiaPlantarum, 115,571-576.
[6]	Kellogg EW, Fridovich I (1975). Superoxide, hydrogenperox ide, andsingleoxygeninlipidperoxidationbyaxanthineox idasesystem. JournalofBiologicalChemistry, 250,8812-8817.
[7]	Knorzer OC, Durner J, Boger P (1996). Alterationsinthean tioxidativesystemofsuspension-culturedsoybeancells (Glycinemax) inducedbyoxidativestress. PhysiologiaPlantarum, 97,388-396.
[8]	Li HS (李合生) (2001). PrinciplesandTechniquesofPlantPhysiologicalBiochemicalExperiment (植物生理生化实验技术与方法). HigherEducationPress, Beijing,164-167. (inChinese).
[9]	Li W (李伟), Huang QN (黄勤妮) (2003). TheresearchesandutilizationsofRhodiolaplants. JournalofCapitalNor malUniversity (首都师范大学学报), 24 (1),55-59. (inChinesewithEnglishabstract).
[10]	Lin ZF (林植芳), Li SS (李双顺), Lin GZ (林桂珠), Sun GC (孙谷畴), Guo JY (郭俊彦) (1984). Superoxidedismu taseandlipid peroxidationinrelationtosenescenceofriceleaves. ActaBotanicaSinica (植物学报), 26,605-615. (inChinesewithEnglishabstract).
[11]	Niki E, Yamamoto Y, Kamuro E (1991). Membranedamageduetolipidoxidation. TheAmericanJournalofClinicalNutrition, 53,2015-2055.
[12]	Polle A, Rennenberg H (1992). FieldstudiesonNorwaysprucetreesathighaltitude:Ⅱ.Defencesystemsagainstoxidativestressinneedles. NewPhytologist, 121,635-642.
[13]	Ramanjulu S, Bartels D (2002). Drought-anddesiccation-in ducedmodulationofgeneexpressioninplants. Plant, Cell&Environment, 25,141-150.
[14]	Siegel SM (1953). Onthebiosynthesisoflignins. PhysiologiaPlantarum, 6,134-139.
[15]	Stephane H, Catherine L, Denis T (2003). Transcriptsofun flowerantioxidantscavengersoftheSODandGPXfamiliesaccumulatedifferentiallyinresponsetodownymildewinfec tion, phytohormones, reactiveoxygenspecies, nitricoxide, proteinkinaseandphosphataseinhibitors. Physiologiaplan tarum, 119,418-428.
[16]	Tan DY (谭敦炎), Zhu JW (朱建雯), Tian RW (田允温) (1997). ThestudyonreproductionecologyinRhodiolacoc cineaⅠEcologyfactorsandtheanalysisonbotanicandphynologicalcharacters. JournalofXinjiangAgriculturalUniversity (新疆农业大学学报), 20 (3),1-4. (inChi nesewithEnglishabstract).
[17]	Wildi B, Lütz C (1996). Antioxidantcompositionofselectedhighalpineplantspeciesfromdifferentaltitudes. Plant, Cell&Environment, 19,138-146.
[18]	Willekens HS, Chamnongpol MD, Schraudner M, Langebartels C (1997). CatalaseisasinkforH2O2 andisindispens ableforstressdefenseinC3 plant. TheEuropenMoelcularBiologyOrgnisationJournal, 14,4806-4816.
[19]	Yan TF (颜廷芬), Yan XF (阎秀峰), Zu YG (祖元刚) (1999a). A primarilydiscussontheadaptivemechanismatdifferentaltitudelevelofPhodiolasachalinensispopulation. BulletinofBotanicalResearch (植物研究), 4,202-206. (inChinesewithEnglishabstract).
[20]	Yan TF (颜廷芬), Zhou FJ (周福军), Yan XF (阎秀峰), Zu YG (祖元刚) (1999b). GeneticdiversityandpopulationdifferentiationofRhodiolaangusta. BulletinofBotanicalResearch (植物研究), 4,189-193. (inChinesewithEng lishabstract).
[21]	Zeng SX (曾韶西), Wang YR (王以柔), Liu HX (刘鸿先) (1987). EffectoflowtemperatureonthecontentofASAinriceseedling. ActaPhytophysiologicaSinica (植物生理学报), 13,365-370. (inChinesewithEnglishabstract).
[22]	Zeng SX (曾韶西), Wang YR (王以柔), Liu HX (刘鸿先) (1991). Someenzymaticreactionsrelatedtochlorophylldegradationincucumbercotyledonsunderchillinginthelight. ActaPhytophysiologicaSinica (植物生理学报), 17,177-182. (inChinesewithEnglishabstract).
[23]	Zhao HJ (赵会杰) (1999). GuideforCurrentPlantPhysio logicalExperiment, ShanghaiInstituteofPlantPhysiology, ChineseAcademyofSciences (中国科学院上海植物生理研究所植物生理实验指南) SciencPress, Beijing,315-317. (inChinese).
[24]	Zhou DW (周党卫), Zhu WY (朱文琰), Teng ZH (腾中华), Shi SB (师生波), Liu JQ (刘健全), Han F (韩发) (2003). AntioxidativecompoundsofPolygonumviviparumL.fromdifferentaltitudes. ChineseJournalofApplied&Environ mentalBiology (应用与环境生物学报), 9,489-492. (inChinesewithEnglishabstract).