Latitudinal variation in the diversity and composition of various organisms associated with an exotic plant: the role of climate and plant invasion

Gao, Lunlun; Chen, Wei; Xu, Hao; Liu, Xiaoyan; Siemann, Evan; Lu, Xinmin

doi:10.1111/nph.17479

Cited by 8 publications

(6 citation statements)

References 46 publications

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“…In 2019, we collected rhizosphere soils (10 cm deep and 5 cm diameter, from five individuals) of the native and invasive plants at each site as described by Gao et al . (2021). Soils were shipped immediately to our laboratory, where we sieved (2 mm) and pooled soils sampled from the same species and site to control for spatial heterogeneity.…”

Section: Methodsmentioning

confidence: 99%

“…Soils were shipped immediately to our laboratory, where we sieved (2 mm) and pooled soils sampled from the same species and site to control for spatial heterogeneity. One-half of each pooled soil sample was stored at À20°C for sequencing soil bacteria and fungi as in Lu et al (2018), while the other half was air-dried for total carbon (TC) and nitrogen (TN) measurements and pH determination (Gao et al, 2021). To link rhizosphere community composition to climatic variability across our latitudinal transect, we used the WorldClim database variables to construct two principal component axes (BioPC1 and BioPC2, explained 57.9% and 30.3% of variance, respectively) explaining the majority of climate New Phytologist variation.…”

Section: Field Surveysmentioning

confidence: 99%

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Aboveground herbivory can promote exotic plant invasion through intra‐ and interspecific aboveground–belowground interactions

Gao

Chen

et al. 2022

New Phytologist

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Summary Aboveground herbivores and soil biota profoundly affect plant invasions. However, how they interactively affect plant invasions through plant–soil feedbacks (PSFs) remains unclear. To explore how herbivory by the introduced beetle Agasicles hygrophila affects Alternanthera philoxeroides invasions in China, we integrated multiyear field surveys and a 2‐yr PSF experiment, in which we examined how herbivory affects PSFs on the performance of native and invasive plants and the introduced beetles. Despite increased herbivory from A. hygrophila, A. philoxeroides dominance over co‐occurring congeneric native Alternanthera sessilis remained constant from 2014 to 2019. While occurring at lower abundances, A. sessilis experienced similar herbivore damage, suggesting apparent competitive effects. Our experiments revealed that herbivory on A. philoxeroides altered soil microbial communities, prolonged its negative PSF on A. sessilis, and decreased A. hygrophila larvae performance on the next‐generation invasive plants. Consequently, A. hygrophila larvae performed better on leaves of natives than those of invasives when grown in soils conditioned by invasive plants defoliated by the introduced beetles. Our findings suggest that aboveground herbivory might promote rather than suppress A. philoxeroides invasion by enhancing its soil‐mediated self‐reinforcement, providing a novel mechanistic understanding of plant invasions. These findings highlight the need to incorporate an aboveground–belowground perspective during the assessment of potential biocontrol agents.

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Section: Methodsmentioning

confidence: 99%

Section: Field Surveysmentioning

confidence: 99%

Aboveground herbivory can promote exotic plant invasion through intra‐ and interspecific aboveground–belowground interactions

Gao

Chen

et al. 2022

New Phytologist

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“…In a laboratory, we sieved (2 mm) and homogenized the soil. We sampled 30 mL soil and divided it into two parts, which we stored at −80°C for DNA extraction or air-dried for measurements of total contents of carbon and nitrogen (TN) and pH (details please see Gao et al, 2021). After that, every 4 L of the topsoil was placed in 5 L experimental pots.…”

Section: Conditioning Phase 1: Rhizo-conditioningmentioning

confidence: 99%

Leaf litter presence in the non‐growing season prolongs plant legacy effects on soil fungal communities and succeeding plant growth

Jia

Chen

et al. 2023

Journal of Ecology

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Soil microbes can profoundly affect species coexistence and alien plant invasion via plant–soil feedbacks (PSFs). Theoretically, plants can modify soil biotic communities (e.g. fungal and bacterial communities) sequentially via rhizo‐inputs in the growing season and via litter decomposition in the non‐growing season, and in this way affect the performance of plant individuals that establish in the same soil in the following growing season. However, how plants affect soil microbes via sequential rhizosphere and litter inputs and how these soil microbial legacies feedback to subsequent plants remains unclear. Here, we first explored the sequential effects of living individuals and their leaf litter on soil fungal communities, using 42 common alien and native species in China, and then estimated their PSF effects on three common test species. Our results show that living plants growing in field soil developed distinct rhizosphere fungal communities within one season. After the removal of conditioning plants, the fungal communities in these conditioned soils changed more dramatically in the absence than in the presence of leaf litter, suggesting that leaf litter inputs prolonged the species‐specific legacies that conspecific living individuals exerted in the soil. Moreover, leaf litter induced general negative effects on all test species in the second growing season. Conditioning plant origin (native vs. alien) and life cycle (annual vs. perennial), respectively, had a slight or no impact on fungal community composition, and conditioning plant origin did not affect PSF responses of the test species. Synthesis: These findings show that leaf litter prolongs soil fungal legacies of conspecific living individuals, which can lead to carryover effects on heterospecific plant growth in the next season. Our findings highlight the importance of leaf litter for plant–soil interactions and thereby stress the potential importance of plant litter as a driver of plant community dynamics.

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“…It has been well documented that plant invasions have caused changes in the diversity and productivity of above-ground plants and belowground ecological processes that are closely related to plant-soil relationships (Liao et al, 2008;Sodhi et al, 2019). However, the limited knowledge of responses of microbial diversity and communities to plant invasion hinders our understanding of the link between above-and below-ground biodiversity and the consequences for microbially driven processes (Gao et al, 2021). We proposed and tested the following hypotheses: (i) the change in soil nutrient availability caused by plant invasion drives a succession of microbial communities along the invasion gradient; and…”

Section: Introductionmentioning

confidence: 99%

“…It has been well documented that plant invasions have caused changes in the diversity and productivity of above‐ground plants and below‐ground ecological processes that are closely related to plant–soil relationships (Liao et al, 2008; Sodhi et al, 2019). However, the limited knowledge of responses of microbial diversity and communities to plant invasion hinders our understanding of the link between above‐ and below‐ground biodiversity and the consequences for microbially driven processes (Gao et al, 2021). We proposed and tested the following hypotheses: (i) the change in soil nutrient availability caused by plant invasion drives a succession of microbial communities along the invasion gradient; and (ii) considering the distinct microbial niches that are occupied by bacterial and fungal communities as a consequence of their different cell size, morphology, biology and metabolic preferences, both groups are structured by contrasting ecological processes and therefore exert a distinct role in driving emerging properties (e.g., functional gene composition) of microbial communities under plant invasion.…”

Section: Introductionmentioning

confidence: 99%

Plant invasion reconstructs soil microbial assembly and functionality in coastal salt marshes

et al. 2022

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Microbiologically driven ecosystem processes can be profoundly altered by alien plant invasions. There is limited understanding of the ecological mechanisms orchestrating different microbial constituents and their roles in emerging functional properties under plant invasions. Here, we investigated soil microbial communities and functions using high‐throughput amplicon sequencing and GeoChip technology, respectively, along a chronological gradient of smooth cordgrass invasion in salt marshes located in the Yellow River Estuary, China. We found a positive correlation between microbial diversity and the duration age of invasion, and both bacterial and fungal communities showed consistent changes with invasion. Soil microbial metabolic potential, as indicated by the abundance of microbial functional genes involved in biogeochemical cycling, decreased in response to invasion. As a consequence, declining soil microbial metabolisms as a result of plant invasion facilitated carbon accumulation in invaded salt marshes. Bacteria and fungi exhibited distinct contributions to assembly processes along the invasion gradient: bacterial communities were mainly driven by selection and dispersal limitation, while fungi were dramatically shaped by stochastic processes. Soil microbial‐mediated functions were taxon‐specific, as indicated by community–function relationships. This study demonstrates the distinct contributions of microbial constituents to microbial community assembly and functions and sheds light on the implications of plant invasion on microbiologically driven ecosystem processes in coastal wetlands.

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Latitudinal variation in the diversity and composition of various organisms associated with an exotic plant: the role of climate and plant invasion

Cited by 8 publications

References 46 publications

Aboveground herbivory can promote exotic plant invasion through intra‐ and interspecific aboveground–belowground interactions

Aboveground herbivory can promote exotic plant invasion through intra‐ and interspecific aboveground–belowground interactions

Leaf litter presence in the non‐growing season prolongs plant legacy effects on soil fungal communities and succeeding plant growth

Plant invasion reconstructs soil microbial assembly and functionality in coastal salt marshes

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