Effect of Morphology and Physiology of Wetland Plants on Plateaus at Different Altitudes

LI Juan; LIN Ping; DONG Yu; GUO Xu-Hu

doi:10.3724/SP.J.1142.2013.40370

Plant Science Journal > 2013 > 31(4): 370-377. > DOI: 10.3724/SP.J.1142.2013.40370 CSTR: 32231.14.SP.J.1142.2013.40370

LI Juan, LIN Ping, DONG Yu, GUO Xu-Hu. Effect of Morphology and Physiology of Wetland Plants on Plateaus at Different Altitudes[J]. Plant Science Journal, 2013, 31(4): 370-377. DOI: 10.3724/SP.J.1142.2013.40370

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Effect of Morphology and Physiology of Wetland Plants on Plateaus at Different Altitudes

1.
College of Landscape Architecture, Southwest Forestry University, Kunming 650224, China
2. College of Environmental Science and Engineering, Southwest Forestry University, Kunming 650224, China

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Received Date: December 04, 2012
Revised Date: May 07, 2013
Published Date: August 29, 2013

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Abstract

Abstract

The growth status, chlorophyll content,soluble sugar and free proline content,and superoxide dismutase(POD)activities in four species of common perennial wetland plants transplanted to different altitude levels on the Napahai plateau wetland,and the physiological characteristics of the plants during growth were studied.The results showed that the growth status of Scirpus validus,Heleocharis dulcis,Sparganium stoloniferum and Zizania latifolia were improved as altitude decreased.Plant heights of the four wetland plant species tended to increase as altitude decreased.Both S.validus and H.dulcis exhibited widening stem length as altitude decreased.The leaf widths of S.stoloniferum and Z.latifolia tended to increase as altitude decreased.The chlorophyll(a+b) contents of these wetland plants tended to decline as altitude decreased,as did soluble sugar and free proline content.POD activity in H.dulcis,S.stoloniferum and Z.latifolia decreased with decreasing altitude but showed no significant change in S.validus;POD activity in S.stoloniferum and Z.latifolia were much higher than the other two species.Therefore,the adaptive morphological and physiological characteristics of the four species to habitats at different altitudes had many approaches,such as variations in morphology,photosynthesis,metabolisms of cold-resisting substances and systems of anti-oxidative enzymes at different altitudes.The different adaptive approaches between the plants not only exhibited common rules,but also possessed their own characteristics.
- Altitudinal gradient,
- Hydrophytes,
- Plateau wetland,
- Physiological index

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References

[1]	云南省林业调查规划院主编.云南自然保护区[M].北京:中国林业出版社,1989:272-274.
[2]	徐守国,郭辉军,田昆.高原湿地纳帕海水生植被调查与分析[J].山东林业科技,2006,165(4):48-50.
[3]	Friend A D,Woodward F I.Evolutionary and eco-physiological responses of mountain plants to the growing season environment[J].Ad Ecol Res,1990,20:59-124.
[4]	潘红丽,李迈和.海拔梯度上的植物生长与生理生态特性[J].生态环境学报,2009,18(2):722-730.
[5]	王勋陵,王静.植物的形态结构与环境[M].兰州:兰州大学出版社,1989.
[6]	康华靖,刘鹏,徐根娣.大盘山自然保护区香果树对不同海拔生境的生理生态响应[J].植物生态学报,2008,32(4):865-872.
[7]	Rada F,García-Nú ez C, Boero C. Low-temperature resistance in Polylepis tara-pacana,a tree growing at the highest altitudes in the world[J].Plant,Cell Environ,2001,24:377-381.
[8]	韩发,周党卫.青藏高原不同海拔矮蒿草抗氧化系统的比较[J].西北植物学报,2003,23(9):1491-1496.
[9]	张志良,瞿伟菁.植物生理学实验指导[M].第3版.北京:高等教育出版社,2004:67-70.
[10]	李合生,孙群,赵世杰.植物生理生化试验原理和技术[M].北京:高等教育出版社,2000.
[11]	张殿忠,汪沛洪,赵会贤.测定小麦叶片游离脯氨酸含量的方法[J].植物生理学通讯,1990,26(4):62-65.
[12]	邹奇.植物生理学实验指导[M].北京:中国农业出版社,2000:129-174.
[13]	张治安,陈展宇.植物生理学实验技术[M].长春:吉林大学出版社,2008:192.
[14]	卢存福,贲桂英.高海拔地区植物的光合特性[J].植物学通报,1995,12(2):38-42.
[15]	苏春江,刘俊,何锦峰.海拔梯度对大马士革Ⅲ玫瑰叶绿素(a+b)含量的影响[J].安徽农业科学,2009,37(9):3945-3946.
[16]	刘志民,杨甲定,刘新民.青藏高原几个主要环境因子对植物的生理效应[J].中国沙漠,2000,20(3):309-313.
[17]	韩发.青藏高原的夜间低温对麦苗和牧草的生理意义[J].中国农业气象,1989,10(1):7-10.
[18]	韩发,贲桂英,师生波.青藏高原不同海拔矮蒿草抗逆性的比较研究[J].生态学报,1998,18(6):654-659.
[19]	张树源,白雪芳,马占英.三种草甸植物抗寒生理特性的比较研究[J].高原生物学集刊,1987(6):165-169.
[20]	Hendershot K L,Volenec J J.Nitrogen pools in roots of Medicago sativa L.after defoliation[J].J Plant Physiol,1993,141(2):129-135.
[21]	Rajashekevar C.Frost damage in hardy herbaceous species[M]//Lyons J M,ed.Low Temperature Stress in Crop Plants—the Role of Membrane.New York:Academic Press,1979:255-274.
[22]	Anchorodoguy T J,Rudolph A S,Carpenter J F.Modes of interaction of cryopretectants with membrane phospholids during freezing [J].Cryobio-logy,1987,24:324-331.
[23]	张基德,李玉梅.梨品种枝条可溶性糖、脯氨酸含量变化规律与抗寒性的关系[J].延边大学农学报,2004(12):281-285.
[24]	Li M H,Yang J,Krauchi N.Growth responses of Picea abies and Lanrix deciduas to elevation in the sub alpine areas of Tyrol Austral[J].Can J For Res,2003,33:653-662.
[25]	Li M H,Yang J.Effects of micro site on growth Pinus cembra in the subalpine zone of the Austrian Alps[J].Ann For Sci,2004,61:319-325.
[26]	Li M H,Xiao W F,Wang S G.Mobile carbohydrates in Himalayan tree line trees I.evidence for carbon gain limitation but not for growth limitation[J].Tree Physiology,2008,28:1287-1296.
[27]	Li M H,Xiao W F,Shi P L.Nitrogen and carbon source-sink relationships in trees at the Himalayan tree lines compared with lower elevations[J].Plant,Cell Environ,2008,31:1377-1387.
[28]	Li M H,Hoch G,Korner C.Spatial variability of mobile carbohydrates within Pinus cembra trees at the Alpine tree line[J].Phyton,2001,41(2):203-213.
[29]	Li M H,Hoch G,Korner C.Source/sink removal affects mobile carbohydrates in Pinus cembra at the Swiss tree line[J].Trees,2002,16:331-337.
[30]	Hoch G,Popp M,Korner C.Altitudinal increase of mobile carbon pools in Pinus cembra suggests sink limitation of growth at the Swiss tree line[J].Oikos,2002,98:361-374.
[31]	Hoch G,Korner C.The carbon charging of pines at the climatic tree line:a global comparison[J].Oecologia,2003,135:10-21.
[32]	Shi P L,Korner C,Hoch G.End of season carbon supply status of woody species near the tree line in western China[J].Bas App Ecol,2006,7:370-377.
[33]	Shi P L,Korner C,Hoch G.A test of the growth-limitation theory for alpine tree line formation in evergreen and deciduous taxa of the eastern Himalayas[J].Functional Ecology,2008,22:213-220.
[34]	Larcher W,Bauer H.Physiological Plant Ecology[M].New York:Springer-Verlag,1981.
[35]	汤章城,王育启,吴亚华,王洪春.不同抗旱品种高梁苗中脯氨酸积累的差异[J].植物生理学报,1986,12(2):154-162.
[36]	马兰涛,陈双林,李迎春.低温胁迫对Guadua amplexfolia耐寒性生理指标的影响[J].林业科学研究,2008,21(2):235-238.
[37]	朱进.低温胁迫下不同西葫芦品种耐寒性生理指标的比较[J].湖北农学院学报,2004,24(2):106-108.
[38]	刘祖祺,张石诚.植物抗性生理学[M].北京:中国农业出版社,1994:8-80.
[39]	赵福庚,刘友良.胁迫条件下高等植物体内脯氨酸代谢及调节的研究进展[J].植物学通报,1999,16(5):540-546.
[40]	王敏,陈秋芳,石美娟,马碧虎.低温胁迫对甜樱桃品种枝条SOD、POD活性和脯氨酸含量的影响[J].山西果树,2011(6):3.
[41]	李海林,殷绪明,龙小军.低温胁迫对水稻幼苗耐寒性生理生化指标的影响[J].安徽农学通报,2006,12(11):50-53.
[42]	马艳青,戴雄泽.低温胁迫对辣椒耐寒性相关生理指标的影响[J].湖南农业大学学报:自然科学版,2000,26(6):461-462.
[43]	陈雄,王宗灵,任红旭.海拔梯度对大车前叶片和根的抗氧化系统的影响[J].植物学报,1999,41(8):846-850.

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