What explains variation in the impacts of exotic plant invasions on the nitrogen cycle? A meta‐analysis

Castro‐Díez, Pilar; Godoy, Óscar; Alonso, Álvaro; Gallardo, Antonio; Saldaña, A.

doi:10.1111/ele.12197

Cited by 196 publications

(230 citation statements)

References 82 publications

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“…plants change the abundance, diversity, and structure of plant and animal communities (Hejda et al 2009;Lenda et al 2013), and often considerably modify physicochemical and biological properties of the soil environment, thereby potentially affecting key ecosystem processes (Vilà et al 2011;Castro-Díez et al 2014;Majewska et al 2015;Stefanowicz et al 2016;Zubek et al 2016;Broadbent et al 2017;CastroDíez and Alonso 2017;Lavoie 2017;Rodríguez-Caballero et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Studies based on meta-analysis indicated that plant invasions generally increase nutrient (C, N, P) pools and also enhance the rate of soil processes such as litter decomposition and mineralization, possibly accelerating nutrient cycling (Liao et al 2008;Vilà et al 2011;Castro-Díez et al 2014). This is because invasive species have significantly higher, in comparison to non-invasive ones, values of performancerelated traits such as physiology, leaf-area allocation, shoot allocation, growth rate, size and fitness, which are driving factors in regulating C and N cycles (Liao et al 2008;Van Kleunen et al 2010).…”

Section: Introductionmentioning

confidence: 99%

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Differential influence of four invasive plant species on soil physicochemical properties in a pot experiment

et al. 2017

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Purpose This study compared the effects of four invasive plants, namely Impatiens glandulifera, Reynoutria japonica, Rudbeckia laciniata, and Solidago gigantea, as well as two native species-Artemisia vulgaris, Phalaris arundinacea, and their mixture on soil physicochemical properties in a pot experiment. Materials and methods Plants were planted in pots in two loamy sand soils. The soils were collected from fallows located outside (fallow soil) and within river valley (valley soil) under native plant communities. Aboveground plant biomass, cover, and soil physicochemical properties such as nutrient concentrations, pH, and water holding capacity (WHC) were measured after two growing seasons. Discriminant analysis (DA) was used to identify soil variables responsible for the discrimination between plant treatments. Identified variables were further compared between treatments using one-way ANOVA followed by Tukey's HSD test. Results and discussion Plant biomass, cover, and soil parameters depended on species and soil type. DA effectively separated soils under different plant species.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Differential influence of four invasive plant species on soil physicochemical properties in a pot experiment

et al. 2017

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“…The magnitude and direction of changes in soil characteristics and processes brought about by invasion depend on local habitat conditions, invasive plant species traits, and/or the interaction of both (Meyerson et al 2000;Ehrenfeld 2003;Koutika et al 2007;Dassonville et al 2008;Scharfy et al 2009;Vilà et al 2011;Hulme et al 2013;Castro-Díez et al 2014). Dassonville et al (2008) reported that invasion increased nutrient concentrations of surface soils with initially low nutrient concentrations, while under the opposite conditions, a negative impact was mainly observed.…”

Section: Introductionmentioning

confidence: 99%

Species-specific effects of plant invasions on activity, biomass, and composition of soil microbial communities

et al. 2016

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This study assessed the effects of Reynoutria japonica, Rudbeckia laciniata, and Solidago gigantea invading sites within and outside river valleys on activity, biomass, and composition of soil microbial communities. Microbial properties such as soil respiration, urease and arylsulfatase activities, microbial biomass (based on substrate-induced respiration, or SIR, and phospholipid fatty acids, or PLFA), and community composition (based on PLFA) were determined. R. japonica encroached on sites characterized by the lowest values of microbiological properties and R. laciniata on sites with the highest microbiological quality. The effect of invasion on soil microbial properties depended on the invasive plant species. R. japonica significantly decreased microbial biomass, determined by both SIR and total PLFA, urease activity, fungal PLFA, fungal:bacterial PLFA ratio, gram-negative bacterial PLFA, and soil respiration in comparison to soil under adjacent native plant communities. Microbial community composition also differed between soils under R. japonica and those under native plants. In contrast, R. laciniata and S. gigantea did not influence most microbial properties, though S. gigantea significantly increased fungal PLFA and R. laciniata and S. gigantea increased fungal:bacterial PLFA ratio. The effects of plant invasion on microbial properties were basically similar in soils located within and outside river valleys, probably because initially (i.e., before invasion) soils from the two locations were largely similar in terms of basic properties such as texture, moisture, pH, C:N ratio, and most microbial properties.

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“…Modifying effects of invasive woody species on habitat was also reported from several biomes across the world (e.g., Vitousek 1990; Ehrenfeld 2003;Stohlgren and Rejmánek 2014;Castro-Díez et al 2014;Menge and Chazdon 2016). Among woody species, some guilds are especially responsible for ecosystem change, e.g., nitrogenfixing species (e.g., Ehrenfeld 2003; Rice et al 2004;Castro-Díez et al 2014;Jo et al 2015) or coniferous trees planted on sites typical to broadleaved trees (e.g., Binkley and Valentine 1991;Augusto et al 2002;Zerbe and Wirth 2006;Jagodziński et al 2015).…”

Section: Introductionmentioning

confidence: 84%

“…Tree species (both alien and native) influence light availability (Knight et al 2008;Niinemets 2010), mineral nutrient cycling (Augusto et al 2002;Reich et al 2005;Dauer et al 2007;Mueller et al 2012), soil acidity (Binkley and Valentine 1991;Binkley and Giardina 1998;Mueller et al 2012), decomposition rate (Hobbie et al 2006(Hobbie et al , 2010, fine root and leaf lifespans (Withington et al 2006), ectomycorrhizal infections (Dickie et al 2006;Trocha et al 2012), and soil biota (Mueller et al 2015(Mueller et al , 2016. Modifying effects of invasive woody species on habitat was also reported from several biomes across the world (e.g., Vitousek 1990; Ehrenfeld 2003;Stohlgren and Rejmánek 2014;Castro-Díez et al 2014;Menge and Chazdon 2016). Among woody species, some guilds are especially responsible for ecosystem change, e.g., nitrogenfixing species (e.g., Ehrenfeld 2003; Rice et al 2004;Castro-Díez et al 2014;Jo et al 2015) or coniferous trees planted on sites typical to broadleaved trees (e.g., Binkley and Valentine 1991;Augusto et al 2002;Zerbe and Wirth 2006;Jagodziński et al 2015).…”

Section: Introductionmentioning

confidence: 92%

Interaction between invasive and potentially invasive shrub species does not influence relationships between their ecological success and distance from propagule sources

et al. 2017

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Although interactions between alien and native plant species are well studied, data on interactions between two co-existing alien species with respect to their invasibility are scarce. The aims of this study were (1) to evaluate three factors shaping abundance of the alien shrub species Cornus alternifolia: abundance of another alien (invasive) shrub species (Prunus serotina), type of tree stand (coniferous vs. broadleaved) and distance to propagule sources and (2) to assess the potential dispersal distance of the species studied. Densities of both species were assessed within 194 experimental plots (located in experimental plantations of trees) in Rogów Arboretum (Central Poland). P. serotina occurred on 79 and C. alternifolia on 33 of the 194 plots. The furthest distance of C. alternifolia from the propagule source was 338 m. C. alternifolia reached higher densities in coniferous than broadleaved tree stands. Density of C. alternifolia depended on tree stand type and distance from the propagule source, but did not depend on density of P. serotina. Density of C. alternifolia decreased with increasing distance from the propagule source; however, this relationship was modified by the type of tree stand: densities were lower in broadleaved than in coniferous stands. The presence of the invasive species seems to neither facilitate nor limit the dispersal distance of C. alternifolia, as these two species differ in shade tolerance. The study also provided the first information about C. alternifolia potential invasiveness, because earlier this species was noticed only as casually escaping from cultivation in Slovakia.

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What explains variation in the impacts of exotic plant invasions on the nitrogen cycle? A meta‐analysis

Cited by 196 publications

References 82 publications

Differential influence of four invasive plant species on soil physicochemical properties in a pot experiment

Differential influence of four invasive plant species on soil physicochemical properties in a pot experiment

Species-specific effects of plant invasions on activity, biomass, and composition of soil microbial communities

Interaction between invasive and potentially invasive shrub species does not influence relationships between their ecological success and distance from propagule sources

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