Abstract
Abstract Non-native aquatic Ludwigia species from a polyploid complex are among the world’s most problematic invasive plants. These emergent, floating-leaved species respond to disturbance through fragmentation of shoots and/or rhizomes, spreading rapidly by hydrochorous dispersal and posing challenges for invasive plant management. While recruitment of clonal aquatic plant species from shoot fragmentation is well documented, regeneration from rhizome bud banks, although common, often is overlooked. It is further unclear how interactions among ploidy and resource availability influence regeneration success of rhizome fragments. We conducted a full factorial experiment in aquatic mesocosms to compare trait responses of Ludwigia congeners differing in ploidy (diploid, decaploid) grown from clonal rhizome fragments under contrasting soil nutrient availability (low, high). Similar to previous work with shoot fragments, the diploid congener had a higher relative growth rate and produced more biomass than the decaploid during this establishment stage of growth. High growth rates and biomass production were associated with greater rhizome N and P and reduced investment in belowground structures. Comparing these results to previous shoot fragment studies with Ludwigia, rhizome fragments appear to have much greater growth potential, suggesting that management strategies should minimize disturbance to prevent fragmentation and dispersal of belowground structures. Furthermore, rapid response to newly colonizing diploid invaders will be essential to minimizing spread, and reductions in nutrient loads to aquatic environments may be more effective toward controlling establishment of the diploid congener than the decaploid.
Highlights
Successful colonization of an invasive plant species is thought to result from biological traits enabling a plant to tolerate stresses, utilize limiting resources and colonize vacant niches in the new environment (Elton 1958)
Understanding how invasive plant functional traits, such as regeneration from rhizome fragments and ploidy, interact with contrasting environmental conditions can provide a foundation for early management intervention
Based on the initial analysis of variance (ANOVA), ploidy (F1, 17 = 7.77, P = 0.0126) and sediment nutrient availability (F1, 17 = 288.53, P < 0.0001; Fig. 1C) were significant factors influencing below-ground biomass allocation of plants regenerated from rhizome fragments
Summary
Successful colonization of an invasive plant species is thought to result from biological traits enabling a plant to tolerate stresses, utilize limiting resources and colonize vacant niches in the new environment (Elton 1958). Plant regeneration from fragments is influenced by life history traits, including clonal propagation and regrowth capacity, combined with species-specific mechanistic traits supporting survival and growth (Klimeš et al 1993; Li et al 2013). Understanding these traits in invasive clonal plants is crucial, as their initial colonization, establishment and spread generally are facilitated by disturbance within plant communities
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