Belowground advantages in construction cost facilitate a cryptic plant invasion

Caplan, Joshua S.; Wheaton, Christine.; Mozdzer, Thomas J.

doi:10.1093/aobpla/plu020

Cited by 27 publications

(23 citation statements)

References 60 publications

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“…We found contrasting results between morphological traits and leaf‐level physiological traits in response to interacting global change factors. As expected, P. australis displayed strong trait responses to both eCO 2 and N in our field experiment, some of which have been observed previously in containerized settings (Caplan et al., ; Eller et al., ; Mozdzer et al., 2012). However, because this study was based on mature clones grown in a field setting, it provides a more realistic assessment of the magnitude of morphological and physiological responses to these interacting global change factors.…”

Section: Discussionsupporting

confidence: 89%

“…Furthermore, many studies typically identify one or a few functional traits that are highly responsive to global change factors and speculate how changes in those traits may facilitate invasion without empirically evaluating longer‐term or larger‐scale effects (e.g. Caplan, Wheaton, & Mozdzer, ; Sullivan, Wildova, Goldberg, & Vogel, ). Moreover, short‐term, containerized studies only modestly predict field‐scale responses (Poorter et al., ).…”

Section: Introductionmentioning

confidence: 99%

“…As a C 3 facultative halophyte, it invades freshwater, brackish and saline wetlands, but its distribution is thought to be limited by high salinity (Chambers, Osgood, Bart, & Montalto, ; Mozdzer, Brisson, & Hazelton, ). Because it has responded strongly to eCO 2 and N in containerized experimental conditions (Caplan et al., ; Eller, Lambertini, Nguyen, & Brix, ; Mozdzer & Megonigal ) and is among the most well‐studied organisms globally (Meyerson et al., ), it is an appropriate species for investigating C 3 plant responses to the interactive effects of eCO 2 and N on plant functional traits.…”

Section: Introductionmentioning

confidence: 99%

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Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Mozdzer

Caplan

2018

Functional Ecology

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Elevated atmospheric carbon dioxide (eCO2) concentrations and nitrogen (N) enrichment are known to enhance plant productivity and invasion. However, the implications of their interactive effects for plant productivity are not well understood, especially at the stand scale, presumably because morphological and physiological responses to these global change factors are rarely studied together in the field or assessed at the stand level. We first determined how leaf‐level morphological and physiological traits responded to factorial combinations of ambient and elevated CO2 and N. We collected trait data from the model invasive species Phragmites australis (common reed) that were measured over 3 years in a long‐term global change field experiment. We then combined the trait data and additional descriptions of P. australis canopies in a simulation model of carbon assimilation to determine how morphology and physiology contribute to P. australis’ stand‐scale productivity. At the leaf level, we found that light‐saturated rates of photosynthesis were strongly stimulated by eCO2 (37%) and that this effect was enhanced by increasing salinity. N had a smaller effect (17% stimulation) on physiological responses than eCO2, but leaf morphological traits responded primarily to N; plant height increased by 27% and leaf area increased by 47%. Stand‐scale simulations demonstrated that that morphological and physiological adjustments induced approximately additive responses when P. australis experienced both eCO2 and N enrichment. The simulations also indicated that morphological changes (which were primarily associated with canopy size) influenced stand‐scale carbon assimilation more than physiological changes. Moreover, 97% of the N response was due to changes in morphology, whereas 62% of the eCO2 response was caused by physiological shifts. Our analysis indicates that morphological and physiological trait responses to elevated CO2 and nitrogen are likely to enhance the productivity of P. australis in complementary ways, potentially accelerating its invasion in North America. Furthermore, our data suggest that changes in morphological traits may have a greater influence on carbon gain than leaf‐level physiology under near‐future environmental conditions. Our study also highlights the importance of accounting for both morphological and physiological responses when attempting to infer global change responses from leaf‐level data. A http://onlinelibrary.wiley.com/doi/10.1111/1365-2435.13106/suppinfo is available for this article.

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Section: Discussionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Mozdzer

Caplan

2018

Functional Ecology

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“…For the root traits examined here, natives typically exhibited a broader range of trait values than exotics, perhaps constraining the potential for changes in traits with successional position seen within the exotics. While the invasion of exotic species is often considered to be derived from unique or extreme trait values (Tecco et al 2010, van Kleunen et al 2010, Caplan et al 2014, Lee et al 2017, the successful exotic species in the BSS appear to utilize a subset of the same root trait space occupied by native species rather than any ecologically novel part of that trait space. However, while this study and others identify categorical differences in functional traits between native and exotic plant species, it is important to note that there is substantial variation within each group (Dawson et al 2012a, Flores-Moreno et al 2013); many native species express acquisitive traits and many exotic species express conservative traits, with broad ranges for each.…”

Section: Differences By Originmentioning

confidence: 99%

Fine‐root traits are linked to species dynamics in a successional plant community

Caplan

Meiners

Flores‐Moreno

et al. 2019

Ecology

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Despite the importance of fine roots for the acquisition of soil resources such as nitrogen and water, the study of linkages between traits and both population and community dynamics remains focused on aboveground traits. We address this gap by investigating associations between belowground traits and metrics of species dynamics. Our analysis included 85 species from a long‐term data set on the transition from old field to forest in eastern North America (the Buell‐Small Succession Study) and the new Fine‐Root Ecology Database. Given the prominent roles of life form (woody vs. non‐woody) and species origin (native vs. exotic) in defining functional relationships, we also assessed whether traits or their relationships with species dynamics differed for these groups. Species that reached their peak abundance early in succession had fine‐root traits corresponding to resource acquisitive strategies (i.e., they were thinner, less dense, and had higher nitrogen concentrations) while species that peaked progressively later had increasingly conservative strategies. In addition to having more acquisitive root traits than native species, exotics diverged from the above successional trend, having consistently thinner fine roots regardless of the community context. Species with more acquisitive fine‐root morphologies typically had faster rates of abundance increase and achieved their maximal rates in fewer years. Decreasing soil nutrient availability and increasing belowground competition may become increasingly strong filters in successional communities, acting on root traits to promote a transition from acquisitive to conservative foraging. However, disturbances that increase light and soil resource availability at local scales may allow acquisitive species, especially invasive exotics, to continue colonizing late into the community transition to forest.

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“…Collectively, these findings suggest that lianas create fine roots with limited structural integrity, which as a result are likely to turn over more quickly relative to the roots of trees (Eissenstat and Yanai 1997;Reich and Hall 2013). Rapid turnover may allow liana roots to explore the soil volume efficiently and may be less costly to the plant via low C construction costs, especially under elevated atmospheric CO 2 conditions (Caplan et al 2014). …”

Section: Root Traitsmentioning

confidence: 99%

Root and leaf traits reflect distinct resource acquisition strategies in tropical lianas and trees

2015

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Belowground advantages in construction cost facilitate a cryptic plant invasion

Cited by 27 publications

References 60 publications

Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Fine‐root traits are linked to species dynamics in a successional plant community

Root and leaf traits reflect distinct resource acquisition strategies in tropical lianas and trees

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Belowground advantages in construction cost facilitate a cryptic plant invasion

Cited by 27 publications

References 60 publications

Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO2 and nitrogen

Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO2 and nitrogen

Fine‐root traits are linked to species dynamics in a successional plant community

Root and leaf traits reflect distinct resource acquisition strategies in tropical lianas and trees

Contact Info

Product

Resources

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Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen

Complementary responses of morphology and physiology enhance the stand‐scale production of a model invasive species under elevated CO₂ and nitrogen