Woody plant encroachment intensifies under climate change across tundra and savanna biomes

Criado, Mariana García; Myers‐Smith, Isla H.; Bjorkman, Anne D.; Lehmann, Caroline E. R.; Stevens, Nicola

doi:10.1111/geb.13072

Cited by 141 publications

(104 citation statements)

References 142 publications

(247 reference statements)

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“…The ongoing expansion of erect shrub communities in arctic–alpine regions (Myers‐Smith et al 2011, Elmendorf et al 2012, García Criado et al 2020) may modify competitive interactions compared to those occurring in low‐growing vegetation types such as meadows and heaths. Previous work suggests that the net effect of erect shrub expansion on plant recruitment in tundra depends on the shrub species composition and extent of shrub cover, as well as the recruitment phase in question (Jumpponen et al 1998, Dona and Galen 2007, Dufour‐Tremblay et al 2012, Cranston and Hermanutz 2013).…”

Section: Introductionmentioning

confidence: 99%

Herbivores reduce seedling recruitment in alpine plant communities

Opedal

Nystuen

Hagen

et al. 2021

Nordic Journal of Botany

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Through changes in climate and other environmental factors, alpine tundra ecosystems are subject to increased cover of erect shrubs, reduced predictability of rodent dynamics and changes in wild and domesticated herbivore densities. To predict the dynamics of these ecosystems, we need to understand how these simultaneous changes affect alpine vegetation. In the long term, vegetation dynamics may depend critically on seedling recruitment. To study drivers of alpine plant seedling recruitment, we set up a field experiment where we manipulated the opportunity for plant–plant interactions through vegetation removal and introduction of willow transplants, the occurrence of herbivory through caging of plots, and then sowed 14 species into the plots. We replicated the experiment in three common alpine vegetation types (heath, meadow and Salix shrubland) and recorded seedling emergence and survival over five years. Strong effects of vegetation removal and substantial differences in recruitment among dominant vegetation types suggested important effects of local vegetation on the recruitment success of vascular‐plant seedlings. Similarly, herbivore exclusion had strong positive effects on recruitment success. This effect arose primarily via reduced seedling mortality in plots from which herbivores had been experimentally excluded and became noticeably stronger over time. In contrast, we detected no consistent effects of experimental willow shrub introduction on seedling recruitment. These results demonstrate that large and small herbivores can affect alpine plant seedling recruitment negatively by trampling and feeding on seedlings. Importantly, the effects became stronger over time, suggesting that effects of herbivory on seedling recruitment accumulates over time and may relate to recruitment phases beyond initial seedling emergence.

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Section: Introductionmentioning

confidence: 99%

Herbivores reduce seedling recruitment in alpine plant communities

Opedal

Nystuen

Hagen

et al. 2021

Nordic Journal of Botany

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“…Hence, late Quaternary and contemporary climates could contribute to patterns of EPD across forest biomes. Two factors may lead to the particularly strong effects of climates on the EPD of Temperate Grasslands, Savannas & Shrublands: 1) disturbance by wildfire and growth responses to changing CO2 levels may increase grass dominance in some shrublands under late Quaternary to contemporary climate change (Midgley and Bond, 2015;Li et al, 2020); and 2) the climatic spaces of Temperate Grasslands, Savannas & Shrublands could be particularly closely related to annual mean temperature and total precipitation (Jiang et al, 2017;García Criado et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

Isolation and Molecular Characterization of a Gene Coding for Defensin From an Egyptian Maize Hybrid (Sc 168)

2020

THE JAPS

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Large-scale patterns of plant diversity and their determinants are central issues in macroecology and biodiversity conservation. Previous studies have shown that late Quaternary and contemporary climates can affect plant diversity at large scale. The main objective of our study was to explore the effects of late Quaternary and contemporary climates on ecoregional plant diversity (EPD). Here, we used global ecoregions to examine characteristic and geographically distinct features of plant diversity and quantified the joint and independent explanatory power of late Quaternary and contemporary climates to account for EPD across different biomes. Then, we tested environmental mean and heterogeneity hypotheses and found that both late Quaternary and contemporary climates (temperature and precipitation) can affect plant diversity at ecoregional scales. Furthermore, environmental heterogeneity (i.e., the heterogeneity of late Quaternary and contemporary climates) may have stronger explanatory power than environmental mean for EPD. However, climatic effects on EPD may depend on biome variation. The effects of late Quaternary and contemporary climates on EPD can persist widely in forest biomes and Temperate Grasslands, Savannas & Shrublands. The results of the current study inform the prediction of plant diversity under future climate change, and support long-term monitoring of plant diversity at ecoregional scales.

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“…In summary, current widespread high‐latitude vegetation transitions and land‐cover changes are expected to accelerate under projected climate warming (e.g. Young et al ., 2017; García‐Criado et al ., 2020). The associated aboveground changes in composition and structure of canopy‐forming species might have profound belowground consequences by altering soil and thus ecosystem respiration.…”

Section: Figmentioning

confidence: 99%