利用实验生态学方法, 对攀缘生长与伏地生长的薇甘菊(Mikania micrantha)的形态特征、生物量分配和繁殖特征进行了比较研究。结果表明: 在潮湿生境条件下, 攀缘生长的植株与伏地生长的植株相比对主茎的生物量投资较大, 而对分枝茎的生物量投资则相对较小; 但在干旱生境条件下, 攀缘生长的植株对主茎和分枝茎的生物量投资均较伏地生长的植株小。在潮湿与干旱生境中, 攀缘植株的繁殖投资分别为0.429 g·g–1和0.342 g·g–1, 显著高于相同生境中的伏地植株。在薇甘菊种群的补充与更新过程中, 攀缘生长的植株以有性生殖占主导地位, 在潮湿与干旱生境中产生的个体分别占种群数量的84.7%和62.6%; 伏地生长的植株则主要以无性(克隆)繁殖为主, 在潮湿与干旱生境中有性生殖产生的个体仅占种群数量的40.4%和35.9%。生长方式与土壤水分二因子互作效应对薇甘菊的生物量分配和繁殖指标影响均达到显著水平(P<0.05)。通过研究得出以下结论: 不同生长方式的薇甘菊对环境条件具有不同的生长与繁殖适应对策。
Mikania micrantha is a highly invasive plant species in tropical and subtropical regions. To analyze the adaptability and plasticity of climbing and prostrating M. micrantha plants, we here performed field experiments on morphological characteristics, biomass allocation and reproduction of growth patterns under different environmental moisture conditions. Under moist conditions, climbing plants showed more biomass in the main stem and less in the branches than
did prostrating plants. Under dry conditions, climbing plants invested less biomass in the main stem and branch than did prostrating plants. Under both wet and dry conditions, climbing plants had a reproductive investment of 0.429 and 0.342 g·g–1, respectively, which was significantly higher than that of prostrating plants under the same conditions. Sexual reproduction was the most important approach for climbing plants to produce offspring, which in wet and dry habitats accounted for 84.7% and 62.6%, respectively, of the population. Prostrating plants relied mainly on asexual reproduction to increase their population, with only 40.4% and 35.9% of the population produced by sexual reproduction in wet and dry habitats, respectively. Growth patterns and soil moisture had a significant impact on the biomass and reproduction allocation in plants. Climbing and prostrating M. micrantha plants use different reproductive strategies to adapt to environmental moisture conditions.
参考文献:
Brooks SJ, Panetta, FD, Galway K E (2008). Progress towards the eradication of mikania vine (Mikania micrantha) and limnocharis (limnocharisflava) in northern Australia. Invasive Plant Science andManagement, 1 (3), 296-303.
Caol EL (2002). Evolutionary genetics of invasive species. Trends Eco Evol, 17(8), 386-391.
Cai YL(蔡永立), Song YC(宋永昌)(2001). Adaptive ecology of lianas in Tiantong evergreen broad-leaved forest, Zhejiang, China 1. Leaf anatomical characters. Acta Phytoecologica Sinica (植物生态学报), 25(1), 90–98. (in Chinese with English abstract)
Cai YL(蔡永立), Guo J(郭佳)(2000). Progress and problem of vine adaptive ecology. Chinese Journal of Ecology (生态学杂志), 19(6):28-33
Den Dubbelden KC(1995). The availability of external support affects allocation patterns and morphology in herbaceous climbing individuals. Functional Ecology, 9(4): 628-634
Du F (杜凡), Yang YM(杨宇明), Li JQ (李均清)et al. (2006). A Review of Mikania and the impact of M. micrantha (Asteraceae) in Yunnan. Act BOTANICA Yunnanica (云南植物研究), 28(5), 505-508. (in Chinese with English abstract)
During HJ, Kwant RA, Werger MJA(1994). Effect of light quantity on above-ground biomass investment patterns in the vine Lonicera periclymenum and the shrub Lonicera xyloseum. Phytocoenologia, 24: 597-607
Guo QX, Qiang S, Lin JC et al. (2005). The biological characteristics and integrated management of Mikania micrantha. WUYI Science Journal (武夷科学), 21:72-76. . (in Chinese with English abstract)
He WM(何维明), Zhong ZC(钟章成) (2001). Effects of external support on the foraging behavior and reproductive strategies in Gynostemma pentaphyllum populations. Acta Ecologica Sinica (生态学报), 21(1): 47-50. (in Chinese with English abstract)
Hu YJ (胡玉佳), Bi PX (毕培曦) (1994). A study on life cycle and response to hebicides of Mikania micrantha. ACTA CSI NAT Univ Sunyatsni (中山大学学报), 33(4),88-95. (in Chinese with English abstract)
Huang ZL (黄忠良), Cao HL (曹洪麟), Liang XD (梁晓东) et al.(2000). The growth and damaging effect of Mikania micrantha in different habitats. Trop Subtrop Bo t(热带亚热带植物学报), 8(2), 131-138. (in Chinese with English abstract)
Kusaka M, Ohta M & Fuji Mura T(2005). Contribution of inorganic components to osmotic adjustment and leaf folding for drought tolerance in Pearl millet. Physiologia Plantsarum, 125, 474-489.
Li WH, Zhang CP, Jiang HB et al.( 2006). Changes in soil microbial community associated with invasion of the exotic weed, Mikania micrantha H.B.K.Plants and Soill, 28(1), 309-324
Lin CX, Liao QW, Zeng LM(2003). A Review on the study of Miknia micrantha. Guangxi For Sci, 32(2)60-65.
Liu ZJ (刘左军), Du GZ (杜国祯), Chen JK (陈家宽)(2002). Size-dependent reproductive allocation of Ligularia virgaura in different habitats. Acta Phytoecologica Sinica (植物生态学报), 26, 44–50. (in Chinese with English abstract)
Mini A, Abraham CT(2005 a). Mile-a-minute weed effects on crop plants. Indian Farming, 55(2), 9-10.
Mini A, Abraham CT(2005 b).Biology of mile-a minute weed (Mikania micrantha H.B.K), an alien invasive weeds in kerala. ndian journal of weeds science, 37(2), 153-154.
Mittler R (2006). Abiotic stress, the field environment and stress combination. Trends in Plants Science, 11,15-19.
Obeso JR (2002). The costs of reproduction in plants. New Phytologist, 155, 321–348.
Pasternak T, Rudas V, Potters G (2005). Morphogenic effects of abiotic stress: reorientation of growth in Arabidopsis thaliana seedling. Environmental and Experimental Botany, 53, 299-314
Reznick DN and Chalambor CK(2001). The population ecology of contemporary adaptions whatempirical studies reveal abort the conditions that promote adaptive evolution. Genetica,112, 183-198.
Strauss SY, & Murch P(2004). Towards an understanding of the mechanisms of tolerance: compensating for herbivore damage by enhancing a mutualism. Ecological Entomology, 29, 234-239.
Tao JP, Zhong ZC, Huang L (2003).The responses of momordica charantia at different modular levels to the changes of support diameter. Acta Phytoecologica Sinica (植物生态学报), 27(1), 86-92. (in Chinese with English abstract)
Tsutsui ND, Suarez AV, Hollway DA, et al.(2001). Reduced genetic variation and success of an invasive spiecies. Proc Natl Acad Sci USA, 97, 5948-5958.
Wen ZD(温志达), Ye WH(叶万辉), Feng HL(冯惠玲)(2000). Comparison of photosynthetic characteristics between exotic invader weed mikania micrantha and its companion species. Journal of Tropic and Subtropic Botany(热带亚热带植物学报), 8,139-146. (in Chinese with English abstract)
Wu HJ (吴卉晶), Zan QJ (昝启杰), Zeng H (曾辉) (2009). Factors influencing mikania micrantha invasion and distribution at regional scale. Acta Phatoecologican Snica (生态学报), 29(10), 5442-5449. (in Chinese with English abstract)
Zan QJ (昝启杰), Wang YJ (王勇军), Wang BS (王伯荪) et al. (2000). The distribution and harm of the exotic weed Mikania micrantha. Chinese Journal of Ecology (生态学杂志), 19 (6), 58-61. (in Chinese with English abstract)
Zhao H, Peng S (2009). Activity of Mikania micrantha h.b.k. allelochemicals released In soil. Allelopathy Journal, 24 (2), 405-412.
Zhang LL, Wen DZ (2009). Structural and physiological responses of two invasive weeds, Mikania micrantha and Chromolaena odorata, to contrasting light and soil water conditions. Journal of Plant Research, 122 (1), 69-79.
Zhang WY(张炜银), Li MG(李鸣光), Zang RG(臧润国) et al.(2005).Dynamics of seeds bank of Mikania micrantha populations. Wuhan Botanical Research(武汉植物学研究), 23(1),49-52. (in Chinese with English abstract)
Zhong ZC(钟成章), Tao JP(陶建平), Liu Y(刘芸) et al.(2004). Theories and research methode on the behavioural ecology of climbing individuals. Science Press (in Chinese)
Zu YG (祖元刚), Zhang ZH (张衷化), Wang WJ (王文杰 ), et al. (2006). Different chargcteristics of photosynthesis in stems and leaves of Miknia micranth. Acta Phytoecologica Sinica (植物生态学报),30 (6), 998-1004. (in Chinese with English abstract)