西藏虎头兰和墨兰对强光的生理响应

doi:10.7677/ynzwyj201514046

摘要/Abstract

摘要：

兰属植物 (Cymbidium) 是重要的观赏花卉。该属大多数种类生长在适度荫蔽的环境中，但附生型的西藏虎头兰 (Ctracyanum) 却能在阳光直射的环境下良好生长。为了探究西藏虎头兰适应强光的生理机制，研究选取同属的地生型墨兰 (Csinense) 与其进行对照实验，测定了这两种植物在不同光照强度下的叶绿素荧光参数和P700氧化还原态。结果表明，在强光下，西藏虎头兰光系统I和II活性的下降程度比墨兰小，而环式电子传递的激发程度更高。环式电子传递的激发有助于增强西藏虎头兰在强光下的光保护，而墨兰因环式电子激发程度较低,使其不能适应强光。由于附生环境更容易出现间歇性的直射光，西藏虎头兰的这种适应强光的能力可能有助于它更充分地利用附生环境中的光照资源。

关键词: 兰属, 光合特性, 环式电子传递, 叶绿素荧光, 光照强度

Abstract:

The members of the genus Cymbidium are important ornamental flowers. Most species of this genus prefer to grow on the shady places of the forest floor, while epiphytic Ctracyanum can grow well in the presence of direct sunlight. To explore the physiological mechanism underlying the adaptation of Ctracyanum to high light, we used terrestrial Csinense as the control, and measured the chlorophyll fluorescence and P700 redox state in those two species grown at two different light regimes. Our results showed that the activities of photosystem I and II in Csinense under high light decreased more strongly than those in Ctracyanum. The activation of cyclic electron flow (CEF) in Ctracyanum under high light could serve as a main mechanism of photoprotection. However, the weak of CEF in Csinense limited its adaptation to high light. Since epiphytic habitats may suffer more intermittent direct sunlight than understory, the strong adaptability of Ctracyanum to high light may contribute to its utilization of light energy in epiphytic habitats.

Key words: Cymbidium, Photosynthetic characteristics, Cyclic electron flow, Chlorophyll fluorescence, Light intensity

中图分类号:

Q 945

匡美龄, 张石宝. 西藏虎头兰和墨兰对强光的生理响应[J]. Plant Diversity, 2015, 37(01): 55-62.

KUANG Mei-Ling, ZHANG Shi-Bao. Physiological Response to High Light in Cymbidium tracyanum and C.sinense[J]. Plant Diversity, 2015, 37(01): 55-62.

参考文献

陈心启, 吉占和, 1998. 中国兰花全书［M］. 北京: 中国林业出版社
许大全, 2013. 光合作用学［M］ . 北京: 科学出版社
Adibah MSR, Ainuddin AN, 2011. Epiphytic plants responses to light and water Stress［J］. Asian Journal of Plant Sciences, 10: 97—107
Asada K, 1999. The waterwater cycle in chloroplasts: Scavenging of active oxygens and dissipation of excess photons［J］. Annual Review of Plant Physiology and Plant Molecular Biology, 50: 601—639
Barth C, Krause GH, Winter K, 2001. Responses of photosystem I compared with photosystem II to highlight stress in tropical shade and sun leaves［J］. Plant Cell and Environment, 24: 163—176
Benzing DH, 1990. Vascular Epiphytes［M］. Cambridge: Cambridge University Press
Casano LM, Gomez LD, Lascano HR et al., 1997. Inactivation and degradation of CuZnSOD by active oxygen species in wheat chloroplasts exposed to photo oxidative stress［J］. Plant and Cell Physiology, 38: 433—440
Genty B, Briantais JM, Baker NR, 1989. The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence［J］. Biochimica et Biophysica Acta, 990: 87—92
Golding AJ, Johnson GN, 2003. Downregulation of linear and activation of cyclic electron transport during drought［J］. Planta, 218: 107—114
Gullo MAL, Raimondo F, Crisafulli A et al., 2010. Leaf hydraulic architecture and water relations of three ferns from contrasting light habitats［J］. Functional Plant Biology, 37: 566—574
Hendrickson L, Furbank RT, Chow WS, 2004. A simple alternative approach to assessing the fate of absorbed light energy using chlorophyll fluorescence［J］. Photosynthesis Research, 82: 73—81
Huang W, Zhang SB, Cao KF, 2010a. The different effects of chilling stress under moderate illumination on photosystem II compared with photosystem I and subsequent recovery in tropical tree species［J］. Photosynthesis Research, 103: 175—182
Huang W, Zhang SB, Cao KF, 2010b. Stimulation of cyclic electron flow during recovery after chillinginduced photoinhibition of PSII［J］. Plant and Cell Physiology, 51: 1922—1928
Huang W, Fu PL, Jiang YJ et al., 2013. Differences in the responses of photosystem I and photosystem II of three tree species Cleistanthus sumatranus, Celtis philippensis and Pistacia weinmannifolia exposed to a prolonged drought in a tropical limestone forest［J］. Tree Physiology, 33: 211—220
Hwang HJ, Kim JH, Eu YJ et al., 2004. Photoinhibition of photosystem I is accelerated by dimethyldithiocarbamate, an inhibitor of superoxide dismutase, during lightchilling of spinach leaves［J］. Journal of Photochemistry and Photobiology B: Biology, 73: 79—85
Kramer DM, Johnson G, Kiirats O et al., 2004. New fluorescence parameters for the determination of QA redox state and excitation energy fluxes［J］. Photosynthesis Research, 79: 209—218
Liu ZJ (刘仲健), Chen LJ (陈利君), Liu KW (刘可为) et al., 2009. Climate warming brings about extinction tendency in wild population of Cymbidium sinense［J］. Acta Ecologica Sinica (生态学报), 29: 3443—3455
Maxwell K, Johnson GN, 2000. Chlorophyll fluorescence-a practical guide［J］. Journal of Experimental Botany, 51: 659—668
Maxwell C, Griffiths H, Young AJ, 1994. Photosynthetic acclimation to light regime and water stress by the C3CAM epiphyte Guzmania monostachia: gas exchange characteristics, photochemical efficiency and the xanthophyll cycle［J］. Functional Ecology, 8: 746—754
Miyake C, Horiguchi S, Makino A et al., 2005. Effects of light intensity on cyclic electron flow around PSI and its relationship to nonphotochemical quenching of chlorophyll fluorescence in tobacco leaves［J］. Plant and Cell Physiology, 46: 1819—1830
Munekage Y, Hojo M, Meurer J et al., 2002. PGR5 is involved in cyclic electron flow around photosystem I and is essential for photoprotection in Arabidopsis［J］. Cell, 110: 361—371
Munekage Y, Hashimoto M, Miyake C et al., 2004. Cyclic electron flow around photosystem I is essential for photosynthesis［J］. Nature, 429: 579—582
Murata N, Takahashi S, Nishiyama Y et al., 2007. Photoinhibition of photosystem II under environmental stress［J］. Biochimica et Biophysica Acta, 1767: 414—421
Nishiyama Y, Allakhverdiev SI, Murata N, 2011. Protein synthesis is the primary target of reactive oxygen species in the photoinhibition of photosystem II［J］. Physiologia Plantarum, 142: 35—46
Nishiyama Y, Allakhverdiev SI, Yamamoto H et al., 2004. Singlet oxygen inhibits the repair of photosystem II by suppressing the translation elongation of the D1 protein in Synechocystis sp. PCC 6803［J］. Biochemistry, 43: 11321—11330
Nishiyama Y, Yamamoto H, Allakhverdiev SI et al., 2001. Oxidative stress inhibits the repair of photodamage to the photosynthetic machinery［J］. European Molecular Biology Organization Journal, 20: 5587—5594
Niyogi KK, Bjorkman O, Grossman AR, 1997.Chlamydomonas xanthophyll cycle mutants identified by video imaging of chlorophyll fluorescence quenching［J］. The Plant Cell, 9: 1369—1380
Niyogi KK, Grossman AR, Bjorkman O, 1998. Arabidopsis mutants define a central role for the xanthophyll cycle in regulation of photosynthetic energy conversion［J］. The Plant Cell, 10: 1121—1134
Peng L, Shikanai T, 2011. Supercomplex formation with photosystem I is required for the stabilization of the chloroplast NADH dehydrogenaselike complex in Arabidopsis［J］. Plant Physiology, 155: 1629—1639
Shikanai T, 2007. Cyclic electron transport around photosystem I: genetic approaches［J］. Annual Review of Plant Biology, 58: 199—217
Silvera K, Santiago LS, Cushman JC et al., 2009. Crassulacean acid metabolism and epiphytism linked to adaptive radiations in the Orchidaceae［J］. Plant Physiology, 149: 1838—1847
Sonoike K, 2006. Photoinhibition and protection of photosystem I［A］. // Golbeck JH ed., Photosystem I: the LightDriven Plastocyanin: Ferredoxin Oxidoreductase, Series Advances in Photosynthesis and Respiration［M］. Dordrecht: Springer, 657—668
Sonoike K, Kamo M, Hihara Y et al., 1997. The mechanism of the degradation of psaB gene product, one of the photosynthetic reaction center subunits of photosystem I, upon photoinhibition［J］. Photosynthesis Research, 53: 55—63
Suorsa M, Jrvia S, Griecoa M et al., 2012. PROTON GRADIENT REGULATION5 is essential for proper acclimation of Arabidopsis photosystem I to naturally and artificially fluctuating light conditions［J］. The Plant Cell, 24: 2934—2948
Stancato GC, Mazzafera P, Buckeridge MS, 2002. Effects of light stress on the growth of the epiphytic orchid Cattleya forbesii Lindl. X Laelia tenebrosa Rolfe［J］. Revista Brasileira de Botanica, 25: 229—235
Takahashi S, Milward SE, Fan DY et al., 2009. How does cyclic electron flow alleviate photoinhibition in Arabidopsis?［J］. Plant Physiology, 149: 1560—1567
Tyystjrvi E, Aro EM, 1996. The rate constant of photoinhibition, measured in lincomycintreated leaves, is directly proportional to light intensity［J］. Proceedings of the National Academy of Sciences of the United States of America, 93: 2213—2218
Wang JH, Li SC, Sun M et al., 2013. Differences in the stimulation of cyclic electron flow in two tropical ferns under water stress are related to leaf anatomy［J］. Physiologia Plantarum, 147: 283—295
Yamori W, Evans JR, von Caemmerer S, 2010. Effects of growth and measurement light intensities on temperature dependence of CO2 assimilation rate in tobacco leaves［J］. Plant, Cell and Environment, 33: 332—343
Zhang JL, Meng LZ, Cao KF, 2009. Sustained diurnal photosynthetic depression in uppermostcanopy leaves of four dipterocarp species in the rainy and dry seasons: does photorespiration play a role in photoprotection? ［J］. Tree Physiology, 29: 217—228

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