新疆伊犁河岸小叶白蜡复叶构件生物量分配

doi:10.13866/j.azr.2016.01.14

Abstract

Abstract: The compound leaf of Fraxinus sogdiana are imparipinnate,consists of 5-13 leaflets in common.By large sampling measurement,the relationship between the phenotypic plasticity on component biomass of different compound leaves of various number leaflets and the component biomass were analyzed.The results showed that compound leaves biomass of all samples of F.sogdiana were 0.146-1.663 g,the average biomass of compound leaves with 7 leaflets was the maximum (0.781±0.366) g and significantly higher than the others,with 5 leaflets was the lowest (0.260±0.060) g and significantly lower than the others.Rachis biomass was 0.016-0.179 g,and the average maximum and minimum were compound leaves with 13 and 5 leaflets,respectively,and both the others difference reached the significant level.Leaflets biomass was 0.006-0.886 g,the average maximum 7 leaflets and significantly higher than the others.Plasticity was greater and the variation coefficient was 22.8%-138% on component biomass of different compound leaves.Biomass allocation to the opposite leaflets of different compound leaves was symmetrical,biomass allocation of the top leaflets and the same phyllotaxis decreased with the increase of the leaflets number.The relationship among component biomass of different compound leaves included isomeric growth type of the linear function and algometric growth type of the exponent function.The relative growth rate of each component biomass during the process of growth could be described specifically by the parameters of correlation equation.

Key words: Fraxinus sogdiana, compound leaf, component biomass, biomass allocation, growth model, Yili, Xinjiang

ZHANG Wei, YANG Xiao-rong, Jianaer Ahan, YANG Yun-fei. Biomass Allocation among Components of Compound Leaves of Fraxinus sogdiana in Yili River Reaches,Xinjiang[J].Arid Zone Research, 2016, 33(1): 114-119.

References

〔1〕 Bradshaw A D.Evolutionary significance of phenotypic plasticity in plant〔J〕.Advances in Genetics,1965,13:115-155.
〔2〕 Pigliucci M,Kolodyska A.Phenotypic plasticity and integration in response to flood conditions in natural accessions of Arabidopsis thaliana(L.) Heynh (Brassicaceae)〔J〕.Annals of Botany,2005,90:1-9.
〔3〕 Sultan S E.Phenotypic plasticity and plant adaptation〔J〕.Acta Botanica Neerlandica,1995,44:363-383.
〔4〕 Odum E P.Fundamentals of Ecology〔M〕.Philadelphia:W B Saunders Company,1971.
〔5〕杨婷婷,高永,吴新宏,等.小针茅草原植被地下与地上生物量季节动态及根冠比变化规律〔J〕.干旱区研究,2013,30(1):109-114.〔Yang Tingting,Gao Yong,Wu Xinhong,et al.Study on seasonal variation of aboveground and underground biomasses of vegetation in the Stipa klemenzii steppe and their ratio〔J〕.Arid Zone Research,2013,30(1):109-114.〕
〔6〕王凯,吴祥云,卢慧,等.阜新市主要园林树种叶片生态化学计量特征〔J〕.干旱区研究,2013,30(2):236-241.〔Wang Kai,Wu Xiangyun,Lu Hui,et al.Leaf stoichiometric properties of garden tree species in Fuxin City〔J〕.Arid Zone Research,2013,30(2):236-241.〕
〔7〕 Abulfaith H A,Bazzaz F A.The biology of Ambrosia trifida LIV.demography of plants and leaves〔J〕.New Phytol,1980,84:107-112.
〔8〕聂志刚,李广.光照和温度对旱地小麦叶面积指数的影响〔J〕.干旱区研究,2013,30(5):894-898.〔Nie Zhigang,Li Guang.Effects of light and temperature on leaf area index of wheat in dryland〔J〕.Arid Zone Research,2013,30(5):894-898.〕
〔9〕王凯,王道涵,魏军,等.辽宁西北部主要园林绿化树种叶片生长规律〔J〕.干旱区研究,2013,30(4):640-645.〔Wang Kai,Wang Daohan,Wei Jun,et al.Growth of leaves of main landscaping tree species in Northwest Liaoning Province〔J〕.Arid Zone Research,2013,30(4):640-645.〕
〔10〕Bell D L,Sultan S E.Dynamic phenotypic plasticity for root growth in Polygonum: A comparative study〔J〕.American Journal of Botany,1999,86:807-819.
〔11〕陆霞梅,周长芳,安树青,等.植物的表型可塑性、异速生长及其入侵能力〔J〕.生态学杂志,2007,26(9):1 438-1 444.〔Lu Xiamei,Zhou Changfang,An Shuqing,et al.Phenotypic plasticity,allometry and invasiveness of plants〔J〕.Chinese Journal of Ecology,2007,26(9):1 438-1 444.〕
〔12〕中国科学院中国植物志编辑委员会.中国植物志:第61卷〔M〕.北京:科学出版社,1992:39.〔Deipublicae Popularis Sinicae Agendae Academiae Sinicae Edita.Flora Reipublicae Popularis Sinicae:Vol.61〔M〕.Beijing:Science Press,1992:39.〕
〔13〕谭向峰,郭霄,杜宁,等.黄栌和小叶白蜡的光合特征研究〔J〕.山东林业科技,2010(6):1-4,14.〔Tan Xiangfeng,Guo Xiao,Du Ning,et al.Photosynthetic characteristics of Cotinus coggygria Scop.and Fraxinus bungeana DC.〔J〕.Shandong Forestry Science and Technology,2010(6):1-4,14.〕
〔14〕蒋永喜,王少山,贺志强.小叶白蜡畸果病〔J〕.新疆农业科学,1994,37(4):159-160.〔Jiang Yongxi,Wang Shaoshan,He Zhiqiang.The abnormal fruit disease of Fraxinus sogdiana〔J〕.Xinjiang Agricultural Sciences,1994,37(4):159-160.〕
〔15〕王炳举,王冬良,杨玲.小叶白蜡种子发芽试验研究〔J〕.石河子大学学报:自然科学版,2002,6(1):31-33.〔Wang Binju,Wang Dongliang,Yang Lin.Studies on seed germinate of Fraxinus sogdiana Bung.〔J〕.Journal of Shihezi University:Natural Science Edition,2002,6(1):31-33.〕
〔16〕阎洁,黄文华,潘鼎元.新疆小叶白蜡的翅果成分分析〔J〕.石河子农学院学报,1996(1):12.〔Yan Jie,Huang Wenhua,Pan Dingyuan.Element analysis on samara Fraxinus sogdiana〔J〕.Journal of Shihezi Agricultural College,1996(1):12.〕
〔17〕郑健,郑勇奇,刘玉艳.野生花卉小叶白蜡引种栽培研究〔J〕.河北农业大学学报,2007,30(6):46-49.〔Zheng Jian,Zheng Yongqi,Liu Yuyan.Study on introduction and cultivation of wild ornamental species Fraxinus bungeana DC.Prodr.〔J〕.Journal of Agricultural University of Hebei,2007,30(6):46-49.〕
〔18〕Bacilieri R,Ducousso A,Kremer A.Genetic,morphological,ecological and phenological differentiation between Quercus petraea (Matt.) Liebl.and Quercus robur L.in a mixed stand of northwest of France〔J〕.Silvae Genetica,1995,44:1-10.
〔19〕Menges E S.Biomass allocation and geometry of the clonal forest herb,Laportea canadensis:Adaptive response to the environment or allometric constraints〔J〕.American Journal of Botany,1987,74:551-563.
〔20〕Primack R B.Relationships among flowers,fruits and seeds〔J〕.Annual Review of Ecology and Systematics,1987,18:409-430.
〔21〕Sun S C,Jin D M,Shi P L.The leaf size-twig size spectrum of temperate woody species along an altitudinal gradient: An invariant allometric scaling relationship〔J〕.Annals of Botany,2006,97:97-107.
〔22〕杨允菲,李建东.松嫩平原不同生境芦苇种群分株的生物量分配与生长分析〔J〕.应用生态学报,2003,14(1):30-34.〔Yang Yunfei,Li Jiandong.Biomass allocation and growth analysis on the ramets of Phragmites communis populations in different habitats in the Songnen Plains of China〔J〕.Chinese Journal of Applied ecology,2003,14(1):30-34.〕
〔23〕张维,赵玉,张相锋,等.新疆伊犁野核桃复叶的表型变异及生长规律〔J〕.东北师大学报:自然科学版,2011,43(1):113-117.〔Zhang Wei,Zhao Yu,Zhang Xiangfeng,et al.Phenotypic variability and growth regulation on the compound leaf of Juglans regian Yili of Xinjiang〔J〕.Joural of Northeast Normal University:Natural Science Edition,2011,43(1):113-117.〕

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Biomass Allocation among Components of Compound Leaves of Fraxinus sogdiana in Yili River Reaches,Xinjiang

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