Abstract
It has been suggested that in plant invasions, species may develop intrinsically higher gas exchange and growth rates, and greater nitrogen uptake and allocation to shoots, in their invasive range than in their native habitat under excess nutrients. In this study, native populations of two old world Phragmites australis phylogeographic groups (EU and MED) were compared with their invasive populations in North America [NAint (M) and NAint (Delta)] under unlimited nutrient availability and identical environmental conditions in a common garden. We expected that both introduced groups would have higher growth, nitrogen uptake and allocation, and gas exchange rates than their native groups, but that these enhanced traits would have evolved in different ways in the two introduced ranges, because of different evolutionary histories. Biomass, leaf area, leaf nitrogen concentrations (NH4 + and NO3 −) and transpiration rates increased in introduced versus native groups, whereas differences in SLA, leaf pigment concentrations and assimilation rates were due to phylogeographic origins. Despite intrinsic differences in the allocation of C and N in leaves, shoots and rhizome due to phylogeographic origin, the introduced groups invested more biomass in above-ground tissues than roots and rhizomes. Our results support the concept that invasive populations develop enhanced morphological, physiological and biomass traits in their new ranges that may assist their competiveness under nutrient-enriched conditions, however the ecophysiological processes leading to these changes can be different and depend on the evolutionary history of the genotypes.
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References
Alpert P, Maron JL (2000) Carbon addition as a countermeasure against biological invasion by plants. Biol Invasions 2:33–40
Blossey B, Notzold R (1995) Evolution of increased competitive ability in invasive nonindigenous plants—a hypothesis. J Ecol 83:887–889. doi:10.2307/2261425
Boardman NK (1977) Comparative photosynthesis of sun and shade plants. Plant Physiol 28:355–377
Brix H (1999) Genetic diversity, ecophysiology and growth dynamics of reed (Phragmites australis)—introduction. Aquat Bot 64:179–184
Brooks ML (2003) Effects of increased soil nitrogen on the dominance of alien annual plants in the Mojave Desert. J Appl Ecol 40:344–353
Caplan JS, Wheaton CN, Mozdzer TJ (2014) Belowground advantages in construction cost facilitate a cryptic plant invasion. AoB Plants. doi:10.1093/aobpla/plu020
Clevering OA (1998) An investigation into the effects of nitrogen on growth and morphology of stable and die-back populations of Phragmites australis. Aquat Bot 60:11–25. doi:10.1016/S0304-3770(97)00069-7
Clevering OA, Lissner J (1999) Taxonomy, chromosome numbers, clonal diversity and population dynamics of Phragmites australis. Aquat Bot 64:185–208. doi:10.1016/S0304-3770(99)00059-5
Davis MA, Grime JP, Thompson K (2000) Fluctuating resources in plant communities: a general theory of invasibility. J Ecol 88:528–534
Eller F, Brix H (2012) Different genotypes of Phragmites australis show distinct phenotypic plasticity in response to nutrient availability and temperature. Aquat Bot 103:89–97. doi:10.1016/j.aquabot.2012.07.001
Eller F, Lambertini C, Nguyen LX, Achenbach L, Brix H (2013) Interactive effects of elevated temperature and CO2 on two phylogeographically distinct clones of common reed (Phragmites australis). AoB Plants. doi:10.1093/aobpla/pls051
Eller F, Lambertini C, Nguyen LX, Brix H (2014) Increased invasive potential of non-native Phragmites australis: elevated CO2 and temperature alleviate salinity effects on photosynthesis and growth. Glob Chang Biol 20:531–543. doi:10.1111/gcb.12346
Emery NC, Ewanchuk PJ, Bertness MD (2001) Competition and salt-marsh plant zonation: stress tolerators may be dominant competitors. Ecology 82:2471–2485
Fenn ME et al (1998) Nitrogen excess in North American ecosystems: predisposing factors, ecosystem responses and management implications. Ecol Appl 8:706–733
Funk JL, Vitousek PM (2007) Resource-use efficiency and plant invasion in low-resource systems. Nature 446:1079–1081
Galatowitsch SM, Anderson NO, Ascher PD (1999) Invasiveness in wetland plants in temperate North America. Wetlands 19:733–755
Givnish TJ (1988) Adaptation to sun and shade: a whole-plant perspective. Aust J Plant Physiol 15:63–92
Grotkopp E, Rejmanék M (2007) High seedling relative growth rate and specific leaf area are traits of invasive species: phylogenetically independent contrasts of woody angiosperms. Am J Bot 94:526–532
Gulías J, Flexas J, Mus M, Cifre J, Lefi E, Medrano H (2003) Relationship between maximum leaf photosynthesis, nitrogen content and specific leaf area in Balearic endemic and non-endemic Mediterranean species. Ann Bot 92:215–222
Guo WY, Lambertini C, Nguyen LX, Li XZ, Brix H (2014) Preadaptation and post-introduction evolution facilitate the invasion of Phragmites australis in North America. Ecol Evol 4:4567–4577. doi:10.1002/ece3.1286
Haslam SM (1972) Phragmites Communis Trin. (Arundo Phragmites L.,? Phragmites Australis (Cav.) Trin. ex Steudel). J Ecol 60:585–610. doi:10.2307/2258363
Horchani F, R’Bia O, Hajri R, Aschi-Smiti S (2011) Nitrogen nutrition and ammonium toxicity in higher plants. Int J Bot 7:1–16
Knapp AK, Smith MD (2001) Variation among biomes in temporal dynamics of aboveground primary production. Science 291:481–484
Konnerup D, Brix H (2010) Nitrogen nutrition of Canna indica: effects of ammonium versus nitrate on growth, biomass allocation, photosynthesis, nitrate reductase activity and N uptake rates. Aquat Bot 92:142–148. doi:10.1016/j.aquabot.2009.11.004
Lambers H, Poorter H (2004) Inherent variation in growth rate between higher plants: a search for physiological causes and ecological consequences. In: Begon M, Fitter AH (eds) Advances in ecological research, vol 34. Academic Press, pp 283–362. doi:10.1016/S0065-2504(03)34004-8
Lambertini C, Gustafsson MHG, Frydenberg J, Lissner J, Speranza M, Brix H (2006) A phylogeographic study of the cosmopolitan genus Phragmites (Poaceae) based on AFLPs. Plant Syst Evol 258:161–182. doi:10.1007/s00606-006-0412-2
Lambertini C, Mendelssohn IA, Gustafsson MH, Olesen B, Riis T, Sorrell BK, Brix H (2012a) Tracing the origin of Gulf Coast Phragmites (Poaceae): a story of long-distance dispersal and hybridization. Am J Bot 99:538–551. doi:10.3732/ajb.1100396
Lambertini C, Sorrell BK, Riis T, Olesen B, Brix H (2012b) Exploring the borders of European Phragmites within a cosmopolitan genus. AoB Plants 2012:pls020. doi:10.1093/aobpla/pls020
Leishman MR, Cooke J, Richardson DM, Newman J (2014) Evidence for shifts to faster growth strategies in the new ranges of invasive alien plants. J Ecol 102:1451–1461. doi:10.1111/1365-2745.12318
Lessmann JM, Brix H, Bauer V, Clevering OA, Comín FA (2001) Effect of climatic gradients on the photosynthetic responses of four Phragmites australis populations. Aquat Bot 69:109–126
Levine JM, Brewer JS, Bertness MD (1998) Nutrients, competition and plant zonation in a New England salt marsh. J Ecol 86:285–292
Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. Methods Enzymol 148:350–382. doi:10.1016/0076-6879(87)48036-1
Lobo FdA et al (2013) Fitting net photosynthetic light-response curves with Microsoft Excel—a critical look at the models. Photosynthetica 51:445–456. doi:10.1007/s11099-013-0045-y
Lu Z, Percy RG, Qualset CO, Zeiger E (1998) Stomatal conductance predicts yields in irrigated Pima cotton and bread wheat grown at high temperatures. J Exp Bot 49:453–460. doi:10.1093/jxb/49.Special_Issue.453
Maron JL, Marler M (2008) Field-based competitive impacts between invaders and natives at varying resource supply. J Ecol 96:1187–1197. doi:10.1111/j.1365-2745.2008.01440.x
Matimati I, Verboom GA, Cramer MD (2014) Nitrogen regulation of transpiration controls mass-flow acquisition of nutrients. J Exp Bot 65:159–168. doi:10.1093/jxb/ert367
McDowell SCL (2002) Photosynthetic characteristics of invasive and non invasive species of Rubus (Rosaceae). Am J Bot 89:1431–1438
Meyerson LA, Saltonstall K, Chambers RM (2009) Phragmites australis in eastern North America: a historical and ecological perspective. Salt marshes under global siege. University of California Press, California
Monaco TA, Sheley RL (2012) Invasive plant ecology and management: linking processes to practice. CABI, Wallingford
Mooney HA, Ferrar PJ, Slatyer RO (1978) Photosynthetic capacity and carbon allocation patterns in diverse growth forms of Eucalyptus. Oecologia 36:103–111
Mozdzer TJ, Zieman JC (2010) Ecophysiological differences between genetic lineages facilitate the invasion of non-native Phragmites australis in North American Atlantic coast wetlands. J Ecol 98:451–458. doi:10.1111/j.1365-2745.2009.01625.x
Nguyen LX, Lambertini C, Sorrell BK, Eller F, Achenbach L, Brix H (2013) Photosynthesis of co-existing Phragmites haplotypes in their non-native range: Are characteristics determined by adaptations derived from their native origin? AoB Plants 5:plt016. doi:10.1093/aobpla/plt016
Piwpuan N, Zhai X, Brix H (2013) Nitrogen nutrition of Cyperus laevigatus and Phormium tenax: effects of ammonium versus nitrate on growth, nitrate reductase activity and N uptake kinetics. Aquat Bot 106:42–51. doi:10.1016/j.aquabot.2013.01.002
Poorter H, Remkes C (1990) Leaf area ratio and net assimilation rate of 24 wild species differ-ing in relative growth rate. Oecologia 83:553–559
Prioul JL, Chartier P (1977) Partitioning of transfer and carboxylation components of intracellular resistance to photosynthetic CO2 fixation a critical analysis of the methods used. Ann Bot 41:789–800
Pyšek P, Richardson DM (2006) The biogeography of naturalization in alien plants. J Biogeogr 33:2040–2050
Sheley R, James J, Smith B, Vasquez E (2010) Applying ecologically based invasive-plant management. Rangel Ecol Manag 63:605–613
Sorrell BK, Brix H, Fitridge I, Konnerup D, Lambertini C (2012) Gas exchange and growth responses to nutrient enrichment in invasive Glyceria maxima and native New Zealand Carex species. Aquat Bot 103:37–47. doi:10.1016/j.aquabot.2012.05.008
Suding KN et al (2005) Functional- and abundance-based mechanisms explain diversity loss due to N fertilization. Proc Natl Acad Sci USA 102:4387–4392. doi:10.1073/pnas.0408648102
Tomassen HBM, Smolders AJP, Limpens J, Lamers LPM, Roelofs JGM (2004) Expansion of invasive species on ombrotrophic bogs: desiccation or high N deposition? J Appl Ecol 41:139–150
Tylova-Munzarova E, Lorenzen B, Brix H, Votrubova O (2005) The effects of NH4 + and NO3 − on growth, resource allocation and nitrogen uptake kinetics of Phragmites australis and Glyceria maxima. Aquat Bot 81:326–342. doi:10.1016/j.aquabot.2005.01.006
Acknowledgments
We thank Helge Bulow and staff at the Påskehøjgård research farm for assistance with plant growth and propagation. This study was funded by the European Union ERA-NET Plus on Climate Smart Agriculture project CINDERELLA (Comparative analysis, INtegration anD ExemplaRy implEmentation of cLimate smart LAnd use practices on organic soils: Progressing paludicultures after centuries of peatland destruction and neglect).
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Guest editors: Laura A. Meyerson and Kristin Saltonstall/Phragmites invasion.
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Tho, B.T., Sorrell, B.K., Lambertini, C. et al. Phragmites australis: How do genotypes of different phylogeographic origins differ from their invasive genotypes in growth, nitrogen allocation and gas exchange?. Biol Invasions 18, 2563–2576 (2016). https://doi.org/10.1007/s10530-016-1158-6
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DOI: https://doi.org/10.1007/s10530-016-1158-6