Biodiversity explains maximum variation in productivity under experimental warming, nitrogen addition, and grazing in mountain grasslands

Li, Jiajia; Liu, Detuan; Xu, Kun; Gao, Lian‐Ming; Ge, Xue‐Jun; Burgess, Kevin S.; Cadotte, Marc W.

doi:10.1002/ece3.4483

Cited by 19 publications

(17 citation statements)

References 67 publications

(102 reference statements)

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“…In contrast to the branch length‐based metrics, several phylogenetic diversity metrics (e.g., PAE, the relationship between species evolutionary distinctiveness and abundance; IAC, the imbalance of abundances at higher clades) have been developed to capture information on both the topology and branch lengths of phylogenies connecting the species of a community (Cadotte et al, ; Krajewski, ; Vanewright, Humphries, & Williams, ). These topology‐based metrics have also been shown to be valuable for predicting patterns of abundance, community composition, and ecosystem functioning (Cadotte et al, ; Liu et al, ; Liu, Zhang, et al, ), but are seldomly evaluated in terms of how the branch lengths and topologies of community phylogenies may affect estimates of community phylogenetic diversity. Here, we predict that the use of a backbone phylogeny will have a strong influence on topology‐based metrics.…”

Section: Introductionmentioning

confidence: 99%

The use of DNA barcodes to estimate phylogenetic diversity in forest communities of southern China

Liu

Shan

et al. 2019

Ecology and Evolution

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To elucidate potential ecological and evolutionary processes associated with the assembly of plant communities, there is now widespread use of estimates of phylogenetic diversity that are based on a variety of DNA barcode regions and phylogenetic construction methods. However, relatively few studies consider how estimates of phylogenetic diversity may be influenced by single DNA barcodes incorporated into a sequence matrix (conservative regions vs. hypervariable regions) and the use of a backbone family‐level phylogeny. Here, we use general linear mixed‐effects models to examine the influence of different combinations of core DNA barcodes ( rbcL , matK , ITS, and ITS2) and phylogeny construction methods on a series of estimates of community phylogenetic diversity for two subtropical forest plots in Guangdong, southern China. We ask: (a) What are the relative influences of single DNA barcodes on estimates phylogenetic diversity metrics? and (b) What is the effect of using a backbone family‐level phylogeny to estimate topology‐based phylogenetic diversity metrics? The combination of more than one barcode (i.e., rbcL + matK + ITS) and the use of a backbone family‐level phylogeny provided the most parsimonious explanation of variation in estimates of phylogenetic diversity. The use of a backbone family‐level phylogeny showed a stronger effect on phylogenetic diversity metrics that are based on tree topology compared to those that are based on branch lengths. In addition, the variation in the estimates of phylogenetic diversity that was explained by the top‐rank models ranged from 0.1% to 31% and was dependent on the type of phylogenetic community structure metric. Our study underscores the importance of incorporating a multilocus DNA barcode and the use of a backbone family‐level phylogeny to infer phylogenetic diversity, where the type of DNA barcode employed and the phylogenetic construction method used can serve as a significant source of variation in estimates of phylogenetic community structure.

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Section: Introductionmentioning

confidence: 99%

The use of DNA barcodes to estimate phylogenetic diversity in forest communities of southern China

Liu

Shan

et al. 2019

Ecology and Evolution

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“…Intraspecific trait variation captures phenotypic plasticity and is increasingly recognized as important for coexistence dynamics (Violle et al, 2012). Several studies have shown that intraspecific trait variation may be more important for short‐term responses than species turnover (Jung et al, 2014; Liu et al, 2018b). As experimental treatments were applied only two years prior to this study, it is thus possible that we were not able to detect functional responses to treatments because we did not measure intraspecific trait variation at the whole‐community level.…”

Section: Discussionmentioning

confidence: 99%

“…Interestingly, the two focal species at White Gum (the lower site) did not experience a change in the net effect of neighbours. These were the only annual species ( Trifolium subterraneum ) and the focal species with a “climber” growth form ( Convolvulus erubescens ), suggesting that plants of certain functional types or life histories may be differentially impacted by warming (Liu et al, 2018). A more likely explanation, however, is that current environmental conditions mediate the effect of future climate changes.…”

Section: Discussionmentioning

confidence: 99%

“…However, many metrics of species diversity may not capture nuanced changes to the structure and functioning of specific communities, which may start in initial stages of change but drive more substantial changes over time. As such, studies exploring community responses to climate change increasingly focus on community composition and functional traits (Soudzilovskaia et al, 2013; Liu et al, 2018b) as well as species diversity. Because traits are linked to specific functions and processes (Westoby et al, 2002), trait‐based studies can increase our understanding of how plant communities respond to environmental changes.…”

Section: Introductionmentioning

confidence: 99%

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Plant communities, populations and individuals have distinct responses to short‐term warming and neighbour biomass removal in two montane grasslands

Britton

Hovenden

Porter

et al. 2021

Applied Vegetation Science

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Aims: Climate change will impact plant communities and populations but also individual plant performance. Most predictive models of community responses to climate change ignore individual-level biotic interactions despite their known importance for community diversity and functioning. Here, we consider plant fitness and diversity responses to climate change associated factors at three organisational levels: communities, populations and individual plants, to increase our understanding of how plant communities respond to climate change.

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“…This is in contrast with our expectation that the functional/phylogenetic diversity-productivity relationship would be more robust and more consistent than the taxonomic diversity-productivity relationship at both local and regional scales. A number of studies have reported the signi cance of functional/phylogenetic diversity over taxonomic diversity in explaining variation in plant productivity (Cadotte et al 2009;Flynn et al 2011;Liu et al 2015Liu et al , 2018). Our results showed that the top-ranked single models for all local scales that included either functional diversity or phylogenetic diversity generally agree with previous studies.…”

Section: Scale-dependency Of Explaining the Variation In Plant Producmentioning

confidence: 99%

Evaluating the Scale Dependence of Biodiversity-productivity Relationships: A Case Study in Mountain Meadow Habitat

2021

Preprint

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Ecological scale has been widely assumed to influence various biodiversity-productivity relationships in ecological communities; however, its robustness has not been extensively studied. In this study, we tested the scale dependency of biodiversity-productivity relationships by evaluating their direct linkages while considering other confounders, and simultaneously incorporating functional traits and interspecific phylogenetic relationships. We surveyed sixty quadrats each with an area of 0.25 m2 in three different meadows located along an elevational gradient in Yulong Mountain, China. We calculated different biodiversity parameters (richness, evenness, functionality, and phylogeny), and evaluated the chemical properties of soil from all quadrats, correlating their relationships with plant productivity at the local and regional scale. The direct and indirect relationships of biodiversity and productivity were evaluated using structural equation modeling. The biodiversity-productivity relationships were weak and inconsistent at the local scale, whereas some biodiversity metrics (richness, functional, and phylogenetic) showed either strong positive or negative relationships with productivity at the regional scale. However, a direct correlation between productivity and variables such as soil pH and community-weighted mean leaf carbon content was observed in the structural equation model reconstructed. Our study indicates that the scale dependency of biodiversity-productivity relationships in natural habitats may not be as strong as it may have been previously perceived, in case of taxonomic, functional, and phylogenetic diversity, respectively. Our study emphasizes the necessity to account for the confounding effects of abiotic factors when evaluating biodiversity-productivity relationship in natural habitats at regional or even worldwide scales.

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Biodiversity explains maximum variation in productivity under experimental warming, nitrogen addition, and grazing in mountain grasslands

Cited by 19 publications

References 67 publications

The use of DNA barcodes to estimate phylogenetic diversity in forest communities of southern China

The use of DNA barcodes to estimate phylogenetic diversity in forest communities of southern China

Plant communities, populations and individuals have distinct responses to short‐term warming and neighbour biomass removal in two montane grasslands

Evaluating the Scale Dependence of Biodiversity-productivity Relationships: A Case Study in Mountain Meadow Habitat

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