Abstract
We tested the hypothesis that invasive (IN) species could capture resources more rapidly and efficiently than noninvasive (NIN) species. Two IN alien species, Ageratina adenophora and Chromolaena odorata, and one NIN alien species, Gynura sp. were compared at five irradiances. Photon-saturated photosynthetic rate (P max), leaf mass (LMA) and nitrogen content (NA) per unit area, and photosynthetic nitrogen utilization efficiency (PNUE) increased significantly with irradiance. LMA, NA, and PNUE all contributed to the increased P max, indicating that both morphological and physiological acclimation were important for the three alien species. Under stronger irradiance, PNUE was improved through changes in N allocation. With the increase of irradiance, the amount of N converted into carboxylation and bioenergetics increased, whereas that allocated to light-harvesting components decreased. The three alien species could adequately acclimate to high irradiance by increasing the ability to utilize and dissipate photon energy and decreasing the efficiency of photon capture. The two IN species survived at 4.5 % irradiance while the NIN species Gynura died, representing their different invasiveness. Ageratina generally exhibited higher respiration rate (R D) and NA. However, distinctly higher P max, PNUE, P max/R D, or P max/LMA were not detected in the two invasive species, nor was lower LMA. Hence the abilities to capture and utilize resources were not always associated with invasiveness of the alien species.
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References
Alpert, P., Bone, E., Holzapfel, C.: Invasiveness, invasibility and the role of environmental stress in the spread of non-native plants.-Perspect. Plant Ecol. evol. Syst. 3: 52–66, 2000.
Baruch, Z., Goldstein, G.: Leaf construction cost, nutrient concentration, and net CO2 assimilation of native and invasive species in Hawaii.-Oecologia 121: 183–192, 1999.
Bassman, J., Zwier, J.C.: Gas exchange characteristics of Populus trichocarpa, Populus deltoides and Populus trichocarpa × Populus deltoides clones.-Tree Physiol. 8: 145–159, 1991.
Bilger, W., Björkman, O.: Role of the xanthophyll cycle in photoprotection elucidated by measurements of light-induced absorbance changes, fluorescence and photosynthesis in leaves of Hedera canariensis.-Photosynth. Res. 25: 173–185, 1990.
Callaway, R.M., Ridenour, W.M.: Novel weapons, invasive success and the evolution of increased competitive ability.-Front. Ecol. Environ. 2: 436–443, 2004.
Chapin, F.S.: Effects of multiple environmental stresses on nutrient availability and use.-In: Mooney, H.A., Winner, W.E., Pell, E.J. (ed.): Responses of Plants to Multiple Stresses. Pp. 67–88. Academic Press, New York 1991.
D’Antonio, C.M., Kark, S.: Impacts and extent of biotic invasions in terrestrial ecosystems.-Trends Ecol. Evol. 17: 202–204, 2002.
Davis, M.A., Grime, J.P., Thompson, K.: Fluctuating resources in plant communities, a general theory of invisibility.-J. Ecol. 88: 528–534, 2000.
DeWalt, S.J., Denslow, J.S., Hamrick, J.L.: Biomass allocation, growth, and photosynthesis of genotypes from native and introduced ranges of the tropical shrub Clidemia hirta.-Oecologia 138: 521–531, 2004.
Durand, L.A., Goldstein, G.: Photosynthesis, photoinhibition, and nitrogen use efficiency in native and invasive tree ferns in Hawaii.-Oecologia 126: 345–354, 2001.
Ewe, S.M.L., Sternberg, L.S.L.: Seasonal exchange characteristics of Schinus terebinthifolius in a native and disturbed upland community in Everglade National Park, Florida.-Forest Ecol. Manag. 179: 27–36, 2003.
Farquhar, G.D., Sharkey, T.D.: Stomatal conductance and photosynthesis.-Annu. Rev. Plant Physiol. 33: 317–345, 1982.
Feng, Y.L., Cao, K.F., Feng, Z.L.: Thermal dissipation, leaf rolling and inactivation of PS2 reaction centers in Amomum villosum in diurnal course.-J. trop. Ecol. 18: 865–876, 2002a.
Feng, Y.L., Cao, K.F., Feng, Z.L.: [Effect of growth light regimes on photosynthetic apparatus in four tropical rainforest tree species seedlings.]-J. Plant Physiol. mol. Biol. 28: 153–160, 2002b. [In Chin.]
Feng, Y.-L., Cao, K.-F., Zhang, J.-L.: Photosynthetic characteristics, dark respiration, and leaf mass per unit area in seedlings of four tropical tree species grown under three irradiances.-Photosynthetica 42: 431–437, 2004.
Feng, Y.L., Wang, J.F., Sang, W.G.: Biomass allocation, morphology and physiology of invasive and noninvasive exotic species grown in four irradiance levels.-Acta oecol. doi:10.1016/j.actao.2006.03.009, 2007.
Kitao, M., Lei, T.T., Koike, T., Tobita, H., Maruyama, Y.: Susceptibility to photoinhibition of three deciduous broadleaf tree species with different successional traits raised under various light regimes.-Plant Cell Environ. 23: 81–89, 2000.
Laisk, A.: Kinetics of Photosynthesis and Photorespiration in C3 Plants.-Pp. 113–128. Nauka, Moscow 1977.
Laisk, A., Eichelmann, H., Oja, V., Rasulov, E., Padu, E., Bichele, I., Petatai, H., Kull, O.: Adjustment of leaf photosynthesis to shade in a natural canopy, rate parameters.-Plant Cell Environ. 28: 375–388, 2005.
Lambers, H., Poorter, H.: Inherent variation in growth rate between higher plants: A search for physiological causes and ecological consequences.-Adv. ecol. Res. 23: 187–261, 1992.
Le Roux, X., Walcroft, A.S., Daudet, F.A., Sinoquet, H., Chaves, M.M., Rodrigues, A., Osorio, L.: Photosynthetic light acclimation in peach leaves, importance of changes in mass, area ratio, nitrogen concentration, and leaf nitrogen partitioning.-Tree Physiol. 21: 377–386, 2001.
Lichtenthaler, H.K., Wellburn, A.R.: Determinations of total carotenoids and chlorophylls a and b of leaf extracts in different solvents.-Biochem. Soc. Trans. 603: 591–592, 1983.
Lodge, D.: Biological invasions, lessons from ecology.-Trends Ecol. Evol. 8: 133–137, 1993.
Loustau, D., Brahim, M.B., Gaudillère, J.-P., Dreyer, E.: Photosynthetic responses to phosphorus nutrition in two-year-old maritime pine seedlings.-Tree Physiol. 19: 707–715, 1999.
Mack, R.N.: Predicting the identity and fate of plant invaders, emergent and emerging approaches.-Biol. Conserv. 78: 107–121, 1996.
Maron, J.L., Vilà, M.: Do herbivores affect plant invasion? Evidence for the natural enemies and biotic resistance hypotheses.-Oikos 95: 363–373, 2001.
McDowell, S.C.L.: Photosynthetic characteristics of invasive and noninvasive species of Rubus (Rosaceae).-Amer. J. Bot. 89: 1431–1438, 2002.
Niinemets, Ü., Tenhunen, J.D.: A model separating leaf structural and physiological effects on carbon gain along light gradients for the shade-tolerant species Acer saccharum.-Plant Cell Environ. 20: 845–866, 1997.
Niinemets, Ü., Valladares, F., Ceulemans, R.: Leaf-level phenotypic variability and plasticity of invasive Rhododendron ponticum and non-invasive Ilex aquifolium co-occurring at two contrasting European sites.-Plant Cell Environ. 26: 941–956, 2003.
Nijs, I., Milbau, A., Seidlova, L.: New methodologies for analyzing and predicting alien plant invasion from species and ecosystem traits.-Weed Technol. 18: 1240–1245, 2004.
Normile, D.: Expanding trade with China creates ecological backlash.-Science 306: 968–969, 2004.
Pattison, R.R., Goldstein, G., Ares, A.: Growth, biomass allocation and photosynthesis of invasive and native Hawaiian rainforest species.-Oecologia 117: 449–459, 1998.
Radford, I.J., Cousens, R.D.: Invasiveness and comparative life-history traits of exotic and indigenous Senecio species in Australia.-Oecologia 125: 531–542, 2000.
Reich, P.B., Oleksyn, J.: Global patterns of plant leaf N and P in relation to temperature and latitude.-Proc. nat. Acad. Sci. USA 101: 11001–11006, 2004.
Reich, P.B., Walters, M.B., Ellsworth, D.: From tropics to tundra, global convergence in plant functioning.-Proc. nat. Acad. Sci. USA 94: 13730–13734, 1997.
Rejmanek, M.: Invasive plants, approaches and prediction.-Aust. J. Ecol. 25: 497–506, 2000.
Rosati, A., Esparza, G., DeJong, T.M., Pearcy, R.W.: Influence of canopy light environment and nitrogen availability on leaf photosynthetic characteristics and photosynthetic nitrogen-use efficiency of field-grown nectarine trees.-Tree Physiol. 19: 173–180, 1999.
Scholes, J.D., Press, M.C., Zipperlen, S.W.: Differences in light energy utilization and dissipation between dipterocarp rain forest tree seedlings.-Oecologia 109: 41–48, 1997.
Smith, M.D., Knapp, A.K.: Physiological and morphological traits of exotic, invasive exotic and native species in tallgrass prairie.-Int. J. Plant Sci. 162: 785–792, 2001.
Vincent, G.: Leaf photosynthetic capacity and nitrogen content adjustment to canopy openness in tropical forest tree seedlings.-J. trop. Ecol. 17: 495–509, 2001.
Vitousek, P.M.: Biological invasions and ecosystem properties, can species make a difference?-Ecol. Stud. 58: 163–176, 1986.
Vitousek, P.M., Mooney, H.A., Lubchenco, J., Melillo, J.M.: Human domination of Earth’s ecosystems.-Science 277: 494–499, 1997.
Walcroft, A., Le Roux, X., Diaz-Espejo, A., Dones, N., Sinoquet, H.: Effects of crown development on leaf irradiance, leaf morphology and photosynthetic capacity in a peach tree.-Tree Physiol. 22: 929–938, 2002.
Warren, C.R., Adams, M.A.: Distribution of N, Rubisco and photosynthesis in Pinus pinaster and acclimation to light.-Plant Cell Environ. 24: 597–609, 2001.
Williamson, M., Fitter, A.: The varying success of invaders.-Ecology 77: 1661–1666, 1996.
Zhang, Y.J., Feng, Y.L.: [The relationships between photosynthetic capacity and lamina mass per unit area, nitrogen content and partitioning in seedlings of two Ficus species grown under different irradiance.]-J. Plant Physiol. mol. Biol. 30: 269–276, 2004. [In Chin.]
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Feng, YL., Wang, JF. & Sang, WG. Irradiance acclimation, capture ability, and efficiency in invasive and non-invasive alien plant species. Photosynthetica 45, 245–253 (2007). https://doi.org/10.1007/s11099-007-0040-2
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DOI: https://doi.org/10.1007/s11099-007-0040-2