Page 72 - 《广西植物》2022年第12期
P. 72

2 0 6 2                                广  西  植  物                                         42 卷
            较高的繁殖能力和生长率ꎬ在低养分生境中增加                                Resꎬ 31(1): 145-152.
            繁殖比ꎬ保障更多种子的产生( Grimeꎬ 1979)ꎮ 并                     HWANG BCꎬ LAUENROTH WKꎬ 2008. Effect of nitrogenꎬ
            且ꎬ种群间生长和竞争对养分的响应有差异ꎬ如果                               water and neighbor density on the growth of Hesperis
                                                                 matronalis and two native perennials [J]. Biol Invꎬ 10(5):
            发生杂交ꎬ可能会进化出更高的入侵性ꎮ 对大狼
                                                                 771-779.
            耙草的管理不但要密切关注干扰较大的养分较高
                                                               LAVERGNE Sꎬ MOLOFSKY Jꎬ 2007. Increased genetic
            的生境ꎬ还需要控制不同地区间的种群相互传播ꎬ                               variation and evolutionary potential drive the success of an
            以免发生基因流ꎬ进化出更高的入侵性ꎮ 本文研                               invasive grass [J]. PNASꎬ 104(10): 3883-3888.
            究结果为预测大狼耙草的入侵风险和管理提供了                              LIAO ZYꎬ ZHANG Rꎬ BARCLAY GFꎬ et al.ꎬ 2013. Difference

            重要依据ꎮ                                                in competitive ability between plants from nonnative and
                                                                 native populations of a tropical invader relates to adaptive
                                                                 responses in abiotic and biotic environments [ J]. PLoS
            参考文献:                                                ONEꎬ 8(8): e71767.

                                                               LIU Gꎬ YANG YBꎬ ZHU ZHꎬ 2018. Elevated nitrogen allows
            ANNAPURNA Cꎬ SINGH JSꎬ 2003. Variation of Parthenium  the weak invasive plant Galinsoga quadriradiata to become
               hysterophorus in response to soil quality: implications for  more vigorous with respect to inter ̄specific competition
               invasiveness [J]. Weed Resꎬ 43(3): 190-198.       [J]. Sci Repꎬ 8: 3136.
            ARMAS Cꎬ ORDIALES Rꎬ PUGNAIRE FIꎬ 2004. Measuring  LIU Lꎬ QUAN Hꎬ DONG BCꎬ et al.ꎬ 2017. Nutrient
               plant interactions: a new comparative index [J]. Ecologyꎬ  enrichment alters impacts of Hydrocotyle vulgaris invasion on
               85(10): 2682-2686.                                native plant communities [J]. Sci Repꎬ 6(1): 39468.
            BALESTRI Eꎬ VALLERINI Fꎬ MENICAGLI Vꎬ et al.ꎬ      LIU MCꎬ WEI CQꎬ TANG SCꎬ et al.ꎬ 2012. Bionomics of two
               2018. Biotic resistance and vegetative propagule pressure co ̄  invasive weedsꎬ Bidens alba and B. pilosa ꎬ and their native
               regulate the invasion success of a marine clonal macrophyte  congeners grown different nutrient levels [J]. J Biosafetyꎬ 21
               [J]. Sci Repꎬ 8(1): 16621.                        (1): 32-40. [刘明超ꎬ 韦春强ꎬ 唐赛春ꎬ 等ꎬ 2012. 不同
            DAWSON Wꎬ ROHR RPꎬ VAN KLEUNEN Mꎬ et al.ꎬ            土壤养分水平下 2 种外来鬼针草和近缘本地种的比较研
               2012. Alien plant species with a wider global distribution  究 [J]. 生物安全学报ꎬ 21(1): 32-40.]
               arebetter able to capitalize on increased resource availability  LUO Xꎬ XU XYꎬ ZHENG Yꎬ et al.ꎬ 2019. The role of
               [J]. New Phytolꎬ 194(3): 859-867.                 phenotypic plasticity and rapid adaptation in determining
            DROSTE Tꎬ FLORY SLꎬ CLAY Kꎬ 2010. Variation for      invasion success of Plantago virginica [ J ]. Biol Invꎬ
               phenotypic plasticity among populations of an invasive exotic  21(8): 2679-2692.
               grass [J]. Plant Ecolꎬ 207(2): 297-306.         MA JSꎬ 2013. The checklist of the Chinese invasive plants
            GRIME JPꎬ 1979. Plant strategies and vegetation processes  [M]. Beijing: Higher Education Press. [马金双ꎬ 2013. 中
               [M]. New York: John Wiley & Sons.                 国入侵植物名录 [M]. 北京: 高等教育出版社.]
            GUPTA Sꎬ NARAYAN Rꎬ 2012. Phenotypic plasticity of  NACKLEY Lꎬ HOUGH SNꎬ KIM SHꎬ 2017. Competitive traits
               Chenopodium murale across contrasting habitat conditions in  of the invasive grass Arundo donax are enhanced by carbon
               peri ̄urban areas in Indian dry tropics: Is it indicative of its  dioxide and nitrogen enrichment [J]. Weed Resꎬ 57(2):
               invasiveness [J]. Plant Ecolꎬ 213(3): 493-503.    67-71.
            HE WMꎬ MONTESINOS Dꎬ THELEN Gꎬ et al.ꎬ 2012. Growth  PAN YMꎬ TANG SCꎬ WEI CQꎬ et al.ꎬ 2016. Effects of global
               and competitive effects of Centaurea stoebe populations in  risks ̄nitrogen additions on growth and competitive relations
               response to simulated nitrogen deposition [J]. PLoS ONEꎬ  among invasive and native congeneric species—Bidens
               7(4): e36257.                                     frondosa [J]. Pol J Ecolꎬ 64(4): 443-52.
            HUANG QQꎬ FAN ZWꎬ LI XXꎬ et al.ꎬ 2018. Effects of  PAN YMꎬ TANG SCꎬ WEI CQꎬ et al.ꎬ 2017. Growth and
               nutrient addition and clipping on biomass production of  photosynthetic responses of invasive Bidens frondosa to light
               invasive and native annual Asteraceae plants [ J]. Weed  and water availability: A comparison with invasive and
               Resꎬ 58(4): 318-326.                              native congeners [J]. Weed Biol Managꎬ 17(1):36-44.
            HUANG QQꎬ SHEN YDꎬ LI XXꎬ et al.ꎬ 2016. Invasive   POWELL KIꎬ CHASE JMꎬ KNIGHT TMꎬ 2011. A synthesis of
               Eupatorium catarium and Ageratum conyzoides benefit more  plant invasion effects on biodiversity across spatial scales
               than does a common native plant from nutrient addition in  [J]. Am J Botꎬ 98(3): 539-548.
               both competitive and non ̄competitive environments [J]. Ecol  POWER Gꎬ VILAS JSꎬ 2020. Competition between the invasive
   67   68   69   70   71   72   73   74   75   76   77