The response of stocks of C, N, and P to plant invasion in the coastal wetlands of China

Wang, Weiqi; Sardans, Jordi; Wang, Chun; Zeng, Chen; Tong, Chuan; Chen, Guixiang; Huang, Jiafang; Pan, Haoran; Peguero, Guille; Vallicrosa, Helena; Peñuelas, Josep

doi:10.1111/gcb.14491

Cited by 90 publications

(58 citation statements)

References 75 publications

(101 reference statements)

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“…Grasses in the genus Spartina have been aggressive invaders of coastal habitats worldwide (Strong & Ayres, 2013). In these new habitats, S. alterniflora typically transforms intertidal mudflats into high‐intertidal salt marshes, with profound consequences for above‐ground plant communities (Biswas et al, 2018; Li et al, 2009), migratory shorebirds (Ma, Gan, Choi, & Li, 2014), macroinvertebrate communities (Neira, Levin, Grosholz, & Mendoza, 2007), hydrologic and edaphic parameters (Adams et al, 2012), and soil biochemistry (Wang et al, 2019). Our work has shown that the geographic structure of nematode communities is also affected (Zhang, Pennings, et al, 2019; this paper), emphasizing both the importance of examining the soil food web and the importance of taking a geographic approach to studying species invasions.…”

Section: Discussionmentioning

confidence: 99%

Contrasting latitudinal clines of nematode diversity in Spartina alterniflora salt marshes between native and introduced ranges

Zhang

et al. 2020

Diversity and Distributions

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Aim Introduced species may display or foster novel latitudinal clines because they are not well adapted to their new habitats. We tested the hypothesis that the latitudinal cline in nematode diversity in salt marshes would differ between the native (United States) and introduced (China) ranges of Spartina alterniflora. Location East Coasts of the United States (30.32–43.33°N) and China (30.36–39.14°N). Methods We extracted nematodes from soil samples collected at 32 sites along the United States East Coast and 41 sites along the Chinese coast. We compared latitudinal patterns in nematode diversity and composition between the native and introduced ranges. Results In the native range of S. alterniflora, nematode richness at lower latitudes was almost twice as high as that at higher latitudes. In contrast, we found no latitudinal pattern in nematode richness or diversity in the introduced range of S. alterniflora. Nematode genus richness at all sites in China was about half that at lower latitudes in the United States. Beta diversity of nematodes increased with geographic distance in the United States, but not China. Main conclusions Nematode diversity did not show latitudinal clines in salt marshes dominated by introduced S. alterniflora in China. A likely explanation is that the recently introduced populations are still relatively genetically homogenous, whereas in the native range, genetic variation in plant populations across latitude drives different nematode communities. We suggest that future studies of introduced species will gain additional insights by taking an explicitly geographic perspective.

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Section: Discussionmentioning

confidence: 99%

Contrasting latitudinal clines of nematode diversity in Spartina alterniflora salt marshes between native and introduced ranges

Zhang

et al. 2020

Diversity and Distributions

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“…The impacts of invasive species on N and P cycles and stoichiometry on the plant–soil system may vary between nutrient‐rich and nutrient‐poor ecosystems (Gonzalez et al, ; Matzek, ; Sardans, Bartrons, et al, ). For example, successful invasive species have higher capacities to take up and efficiently use nutrients that are limited (Aragon, Sardans, & Penuelas, ; Sardans, Bartrons, et al, ; Ulm et al, ; Wang, Sardans, et al, ; Wang, Wang, et al, ), so the concentrations of N and P in photosynthetic tissues tend to be higher in invasive than native species. Total soil N concentrations and availabilities of N and P correlated with higher mineralization capacity are higher for invasive species, particularly in nutrient‐poor environments (Sardans, Bartrons, et al, ).…”

Section: Shifts In N:p Ratios Mediated By Anthropogenic Drivers Of Glmentioning

confidence: 99%

Anthropogenic global shifts in biospheric N and P concentrations and ratios and their impacts on biodiversity, ecosystem productivity, food security, and human health

Peñuelas

Janssens

Ciais

et al. 2020

Global Change Biology

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The availability of carbon (C) from high levels of atmospheric carbon dioxide (CO2) and anthropogenic release of nitrogen (N) is increasing, but these increases are not paralleled by increases in levels of phosphorus (P). The current unstoppable changes in the stoichiometries of C and N relative to P have no historical precedent. We describe changes in P and N fluxes over the last five decades that have led to asymmetrical increases in P and N inputs to the biosphere. We identified widespread and rapid changes in N:P ratios in air, soil, water, and organisms and important consequences to the structure, function, and biodiversity of ecosystems. A mass‐balance approach found that the combined limited availability of P and N was likely to reduce C storage by natural ecosystems during the remainder of the 21st Century, and projected crop yields of the Millennium Ecosystem Assessment indicated an increase in nutrient deficiency in developing regions if access to P fertilizer is limited. Imbalances of the N:P ratio would likely negatively affect human health, food security, and global economic and geopolitical stability, with feedbacks and synergistic effects on drivers of global environmental change, such as increasing levels of CO2, climatic warming, and increasing pollution. We summarize potential solutions for avoiding the negative impacts of global imbalances of N:P ratios on the environment, biodiversity, climate change, food security, and human health.

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“…Since its initial appearance on the Chongming Dongtan salt marsh during the 1990s, S. alterniflora has gradually colonized the bare mudflats and invaded the habitat historically occupied by native P. australis and S. mariqueter communities (Li et al, ; Tang et al, ). The S. alterniflora was therefore identified as a coastal invasive plant by the State Environmental Protection Administration of China in 2003 (Li et al, ; Wang et al, ). The distribution area of S. alterniflora reached about 1,500 ha in the Chongming Dongtan salt marsh and more than 6,000 ha in the Yangtze River Estuary in 2012 (Ge et al, ).…”

Section: Methodsmentioning

confidence: 99%

Salinity Affects Topsoil Organic Carbon Concentrations Through Regulating Vegetation Structure and Productivity

Xue

Jiang

et al. 2020

JGR Biogeosciences

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Estuarine salt marshes have been recognized as one of the most efficient carbon sinks in the biosphere, with considerable potential for climate change mitigation. However, there are still uncertainties about the response of soil carbon stocks to enhanced soil salinization caused by accelerated sea-level rises and aggravated saltwater intrusion. We therefore conducted both field investigations in the Chongming Dongtan salt marsh of the Yangtze River Estuary, China, and manipulative experiments on marsh soils occupied, respectively, by the invasive Spartina alterniflora, and the native Phragmites australis and Scirpus mariqueter, to identify the effects of elevated soil salinity on top soil organic carbon (SOC) concentration. Our field data showed that SOC concentrations were significantly positively associated with soil salinity concentrations, annual net primary productivity, and marsh surface elevation but showed a significant negative relationship with median grain size. Compared with the two native species, S. alterniflora preferred more saline conditions and had a higher SOC concentration. Although raised flooding salinities (0-35 ppt) did not strongly affect SOC concentrations, elevated soil salinities significantly corresponded with low SOC concentrations and plant biomass in manipulative experiments. These findings indicated that soil salinity, plant species, and soil texture were key factors controlling SOC concentrations in the studied salt marsh. Moreover, soil salinity could affect SOC concentrations through regulating vegetation spatial structure and plant biomass production. The further invasion of the S. alterniflora community will exert a positive influence on SOC concentrations in the Chongming Dongtan salt marsh.Plain Language Summary Estuarine salt marshes are sedimentary environments that are among the most productive ecosystems on Earth and can continuously sequester carbon through plant production and sedimentary processes. Although sea-level rises and saltwater intrusion may cause widespread soil salinization in estuarine ecosystems, its impact on top soil organic carbon (SOC) concentrations is highly uncertain. We therefore conducted field investigations that revealed the variation in SOC concentrations along a natural salinity gradient and manipulative experiments that raised flooding salinities from freshwater (0 ppt) to seawater (35 ppt) to identify the independent impacts of soil salinity on SOC concentrations. Our findings indicated that soil salinity was an important factor controlling SOC concentrations through indirectly regulating vegetation spatial structure and plant biomass production.

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The response of stocks of C, N, and P to plant invasion in the coastal wetlands of China

Cited by 90 publications

References 75 publications

Contrasting latitudinal clines of nematode diversity in Spartina alterniflora salt marshes between native and introduced ranges

Contrasting latitudinal clines of nematode diversity in Spartina alterniflora salt marshes between native and introduced ranges

Anthropogenic global shifts in biospheric N and P concentrations and ratios and their impacts on biodiversity, ecosystem productivity, food security, and human health

Salinity Affects Topsoil Organic Carbon Concentrations Through Regulating Vegetation Structure and Productivity

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