Effects of experimental N addition on plant diversity in an old‐growth temperate forest

Lai, Mengying; He, Shanchuan; Sheng, Yu; Jin, Guangze

doi:10.1002/ece3.4127

Cited by 11 publications

(9 citation statements)

References 44 publications

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“…The csv files and R file have been deposited in Figshare, https://figshare.com/s/d2933788bc55814b47f3 ( 64 ). Previously published data were used for this work ( 8 , 27 , 34 , 43 , 44 , 53 , 65 …”

Section: Data Availabilitymentioning

confidence: 99%

Assessing the roles of nitrogen, biomass, and niche dimensionality as drivers of species loss in grassland communities

Band

Kadmon

Mandel

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Significance Nutrient enrichment of natural ecosystems is a primary characteristic of the Anthropocene and a known cause of biodiversity loss, particularly in grasslands. In a global meta-analysis of 630 resource addition experiments, we conduct a simultaneous test of the three most prominent explanations of this phenomenon. Our results conclusively indicate that nitrogen is the leading cause of species loss. This result is important because of the increase in nitrogen deposition and the frequent use of nitrogen-based fertilizers worldwide. Our findings provide global-scale, experimental evidence that minimizing nitrogen inputs to ecological systems may help to conserve the diversity of grassland ecosystems.

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Section: Data Availabilitymentioning

confidence: 99%

Assessing the roles of nitrogen, biomass, and niche dimensionality as drivers of species loss in grassland communities

Band

Kadmon

Mandel

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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“…Furthermore, Praveen et al (2019) planted wheat with several arsenic (As) accumulators ( Pteris vittata , Phragmites australis , and Vetiveria zizanioides ) in As-contaminated plots to reduce As accumulation in wheat. Consequently, the correlations of ionomic variations in plant species are important for ecological studies to understand how differences in soil mineral status affect elemental compositions in different plant species ( Lai et al, 2018 ; Roeling et al, 2018 ; Pillon et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Ionomic Responses of Local Plant Species to Natural Edaphic Mineral Variations

et al. 2021

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Leaf ionome indicates plant phylogenetic evolution and responses to environmental stress, which is a critical influential factor to the structure of species populations in local edaphic sites. However, little is known about leaf ionomic responses of local plant species to natural edaphic mineral variations. In the present study, all plant species and soil samples from a total of 80 soil sites in Shiozuka Highland were collected for multi-elemental analysis. Ioniomic data of species were used for statistical analysis, representing 24 species and 10 families. Specific preferences to ionomic accumulation in plants were obviously affected by the phylogeny, whereas edaphic impacts were also strong but limited within the phylogenetic preset. Correlations among elements resulted from not only elemental synergy and competition but also the adaptive evolution to withstand environmental stresses. Furthermore, ionomic differences of plant families were mainly derived from non-essential elements. The majority of variations in leaf ionome is undoubtedly regulated by evolutionary factors, but externalities, especially environmental stresses also have an important regulating function for landscape formation, determining that the contributions of each factor to ionomic variations of plant species for adaptation to environmental stress provides a new insight for further research on ionomic responses of ecological speciation to environmental perturbations and their corresponding adaptive evolutions.

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“…The functional ionome is influenced by both environmental and genetic factors (Neugebauer et al ). Differences in soil elemental composition and nutrient supply affect the functional ionome of plants and, thereby, their physiological status (Neumann and Römheld ) and the species composition of plant communities (Roem and Berendse , Lai et al , Roeling et al ). Ultimately, the supply of mineral nutrients in the soil to a plant, which is characteristic for different ecosystems, can drive genetic adaptation of species to particular environments (Grime and Pierce ).…”

Section: Introductionmentioning

confidence: 99%

The influence of phylogeny and ecology on root, shoot and plant ionomes of 14 native Brazilian species

Neugebauer

El‐Serehy

George

et al. 2019

Physiologia Plantarum

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The ionome is the elemental composition of a living organism, its tissues, cells or cell compartments. The ionomes of roots, stems and leaves of 14 native Brazilian forest species were characterised to examine the relationships between plant and organ ionomes and the phylogenetic and ecological affiliations of species. The null hypothesis that ionomes of Brazilian forest species and their organs do not differ was tested. Concentrations of mineral nutrients in roots, stems and leaves were determined for 14 Brazilian forest species, representing seven angiosperm orders, grown hydroponically in a complete nutrient solution. The 14 species could be differentiated by their ionomes and the partitioning of mineral nutrients between organs. The ionomic differences between the 14 species did not reflect their phylogenetic relationships or successional ecology. Differences between shoot ionomes and root ionomes were greater than differences in the ionome of an organ when compared among genotypes. In conclusion, differences in ionomes of species and their organs reflect a combination of ancient phylogenetic and recent environmental adaptations.

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Effects of experimental N addition on plant diversity in an old‐growth temperate forest

Cited by 11 publications

References 44 publications

Assessing the roles of nitrogen, biomass, and niche dimensionality as drivers of species loss in grassland communities

Assessing the roles of nitrogen, biomass, and niche dimensionality as drivers of species loss in grassland communities

Ionomic Responses of Local Plant Species to Natural Edaphic Mineral Variations

The influence of phylogeny and ecology on root, shoot and plant ionomes of 14 native Brazilian species

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