Please use this identifier to cite or link to this item: https://dspace.ctu.edu.vn/jspui/handle/123456789/4571
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dc.contributor.authorGou, Wen-Yong-
dc.contributor.authorLambertini, Carla-
dc.contributor.authorNguyễn, Xuân Lộc-
dc.contributor.authorLi, Xiu-Zhen-
dc.contributor.authorBrix, Hans-
dc.date.accessioned2018-09-28T03:57:12Z-
dc.date.available2018-09-28T03:57:12Z-
dc.date.issued2014-
dc.identifier.urihttp://dspace.ctu.edu.vn/jspui/handle/123456789/4571-
dc.description.abstractCompared with non-invasive species, invasive plant species may benefit from certain advantageous traits, for example, higher photosynthesis capacity and resource/energy-use efficiency. These traits can be preadapted prior to introduction, but can also be acquired through evolution following introduction to the new range. Disentangling the origins of these advantageous traits is a fundamental and emerging question in invasion ecology. We conducted a multiple comparative experiment under identical environmental condition with the invasive haplotype M lineage of the wetland grass Phragmites australis and compared the ecophysiological traits of this invasive haplotype M in North America with those of the European ancestor and the conspecific North American native haplotype E lineage, P. australis ssp. americanus. The invasive haplotype M differed significantly from the native North American conspecific haplotype E in several ecophysiological and morphological traits, and the European haplotype M had a more efficient photosynthetic apparatus than the native North American P. australis ssp. americanus. Within the haplotype M lineage, the introduced North American P. australis exhibited different biomass allocation patterns and resource/energy-use strategies compared to its European ancestor group. A discriminant analysis of principal components separated the haplotype M and the haplotype E lineages completely along the first canonical axis, highly related to photosynthetic gas-exchange parameters, photosynthetic energy-use efficiency and payback time. The second canonical axis, highly related to photosynthetic nitrogen use efficiency and construction costs, significantly separated the introduced P. australis in North America from its European ancestor. Synthesis. We conclude that the European P. australis lineage was preadapted to be invasive prior to its introduction, and that the invasion in North America is further stimulated by rapid post-introduction evolution in several advantageous traits. The multicomparison approach used in this study could be an effective approach for distinguishing preadaptation and post-introduction evolution of invasive species. Further research is needed to link the observed changes in invasive traits to the genetic variation and the interaction with the environment.vi_VN
dc.language.isoenvi_VN
dc.relation.ispartofseriesEcology and Evolution;4 .- p.4567-4577-
dc.subjectBiomass allocationvi_VN
dc.subjectCommon reedvi_VN
dc.subjectCommon-environment experimentvi_VN
dc.subjectDiscriminant analysisvi_VN
dc.subjectEcophysiological trade-offvi_VN
dc.subjectFunctional traitsvi_VN
dc.subjectInvasion ecologyvi_VN
dc.subjectLeaf construction costvi_VN
dc.subjectPhotosynthesisvi_VN
dc.subjectStandardized major axis (SMA)vi_VN
dc.titlePreadaptation and post-introduction evolution facilitate the invasion of Phragmites australis in North Americavi_VN
dc.typeArticlevi_VN
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