Climate change and ecosystem composition across large landscapes

Jennings, Michael D.; Harris, Grant

doi:10.1007/s10980-016-0435-1

Cited by 29 publications

(20 citation statements)

References 24 publications

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“…Accelerating rates of climate change are predicted to have an enormous impact on the relationships between organisms [5], including those established by causal agents of plant infectious diseases [7]. In this context, understanding how environmental conditions affect parasite transmission is key to understand the emergence of plant disease epidemics, as the ability to spread to new susceptible hosts is a major determinant of parasite fitness [37,47].…”

Section: Discussionmentioning

confidence: 99%

“…This global warming has been predicted to reduce cloud coverage, increasing light intensity [3], and promoting drought events [1]. Since these climatic factors influence most (if not all) biological processes, climate change is expected to have a huge impact in the reproductive success of living organisms and in the relationships that they establish e.g., [4,5]. Plant–virus interactions are not an exception [6,7], and therefore investigating the effect of climatic conditions in plant and viral fitness components is central to understand their outcome [7].…”

Section: Introductionmentioning

confidence: 99%

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Light Intensity Modulates the Efficiency of Virus Seed Transmission through Modifications of Plant Tolerance

Montés

Pagán

2019

Plants

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Increased light intensity has been predicted as a major consequence of climate change. Light intensity is a critical resource involved in many plant processes, including the interaction with viruses. A central question to plant–virus interactions is understanding the determinants of virus dispersal among plants. However, very little is known on the effect of environmental factors on virus transmission, particularly through seeds. The fitness of seed-transmitted viruses is highly dependent on host reproductive potential, and requires higher virus multiplication in reproductive organs. Thus, environmental conditions that favor reduced virus virulence without controlling its level of within-plant multiplication (i.e., tolerance) may enhance seed transmission. We tested the hypothesis that light intensity conditions that enhance plant tolerance promote virus seed transmission. To do so, we challenged 18 Arabidopsis thaliana accessions with Turnip mosaic virus (TuMV) and Cucumber mosaic virus (CMV) under high and low light intensity. Results indicated that higher light intensity increased TuMV multiplication and/or plant tolerance, which was associated with more efficient seed transmission. Conversely, higher light intensity reduced plant tolerance and CMV multiplication, and had no effect on seed transmission. This work provides novel insights on how environmental factors modulate plant virus transmission and contributes to understand the underlying processes.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Light Intensity Modulates the Efficiency of Virus Seed Transmission through Modifications of Plant Tolerance

Montés

Pagán

2019

Plants

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“…SDMs are regularly used to interpret species' distribution patterns in relation to environmental variables, particularly climate (Elith & Leathwick, 2009;Franklin, 2010), and they have been applied in studies on turnover of vegetation composition across landscape (Jennings & Harris, 2017), regional patterns of growth (van der Maaten et al, 2017), community-level responses to experimental drought (Bilton, Metz, & Tielb€ orger, 2016), or projections of tree response to climate change (Cheaib et al, 2012). SDMs (also known as bioclimatic niche models, correlative ecological niche models, or envelope models) consider the species' occurrence in sites across its distribution range as well as the climatic conditions of that range although other nonclimatic environmental variables can also be considered.…”

Section: Introductionmentioning

confidence: 99%

“…SDMs (also known as bioclimatic niche models, correlative ecological niche models, or envelope models) consider the species' occurrence in sites across its distribution range as well as the climatic conditions of that range although other nonclimatic environmental variables can also be considered. SDMs are regularly used to interpret species' distribution patterns in relation to environmental variables, particularly climate (Elith & Leathwick, 2009;Franklin, 2010), and they have been applied in studies on turnover of vegetation composition across landscape (Jennings & Harris, 2017), regional patterns of growth (van der Maaten et al, 2017), community-level responses to experimental drought (Bilton, Metz, & Tielb€ orger, 2016), or projections of tree response to climate change (Cheaib et al, 2012). However, the use of SDMs requires caution since they do not address an explicit analysis of the functional mechanisms involved in the species distribution patterns, particularly ecophysiological performance, and dispersal and biotic interactions (Ara ujo & Luoto, 2007;Elith & Leathwick, 2009;Guisan & Thuiller, 2005).…”

Section: Introductionmentioning

confidence: 99%

Historical and event‐based bioclimatic suitability predicts regional forest vulnerability to compound effects of severe drought and bark beetle infestation

Lloret

Kitzberger

2018

Global Change Biology

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Vulnerability to climate change, and particularly to climate extreme events, is expected to vary across species ranges. Thus, we need tools to standardize the variability in regional climatic legacy and extreme climate across populations and species. Extreme climate events (e.g., droughts) can erode populations close to the limits of species' climatic tolerance. Populations in climatic-core locations may also become vulnerable because they have developed a greater demand for resources (i.e., water) that cannot be enough satisfied during the periods of scarcity. These mechanisms can become exacerbated in tree populations when combined with antagonistic biotic interactions, such as insect infestation. We used climatic suitability indices derived from Species Distribution Models (SDMs) to standardize the climatic conditions experienced across Pinus edulis populations in southwestern North America, during a historical period (1972-2000) and during an extreme event (2001-2007), when the compound effect of hot drought and bark beetle infestation caused widespread die-off and mortality. Pinus edulis climatic suitability diminished dramatically during the die-off period, with remarkable variation between years. P. edulis die-off occurred mainly not just in sites that experienced lower climatic suitability during the drought but also where climatic suitability was higher during the historical period. The combined effect of historically high climatic suitability and a marked decrease in the climatic suitability during the drought best explained the range-wide mortality. Lagged effects of climatic suitability loss in previous years and co-occurrence of Juniperus monosperma also explained P. edulis die-off in particular years. Overall, the study shows that past climatic legacy, likely determining acclimation, together with competitive interactions plays a major role in responses to extreme drought. It also provides a new approach to standardize the magnitude of climatic variability across populations using SDMs, improving our capacity to predict population's or species' vulnerability to climatic change.

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“…The www.nature.com/scientificdata www.nature.com/scientificdata/ tree provides moisture to a wide variety of mammals, birds and insects, and its conservation is critical to maintaining the local ecosystem in the future. Jennings and Harris 74 used DC data to identify specific climate and vegetation parameters for anticipating how, where and when ecosystem vegetation may transform with climate change across the southwestern USA. CCAFS-Climate portal data were used in conjunction with a weather generator to map environmental suitability for the Zika virus, showing that over 2.17 billion people in the tropics and sub-tropics live in areas suitable for the virus and its vector 75 .…”

Section: Usage Notesmentioning

confidence: 99%

High-resolution and bias-corrected CMIP5 projections for climate change impact assessments

et al. 2020

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Projections of climate change are available at coarse scales (70-400 km). But agricultural and species models typically require finer scale climate data to model climate change impacts. Here, we present a global database of future climates developed by applying the delta method -a method for climate model bias correction. We performed a technical evaluation of the bias-correction method using a 'perfect sibling' framework and show that it reduces climate model bias by 50-70%. The data include monthly maximum and minimum temperatures and monthly total precipitation, and a set of bioclimatic indices, and can be used for assessing impacts of climate change on agriculture and biodiversity. The data are publicly available in the World Data Center for Climate (WDCC; cera-www. dkrz.de), as well as in the CCAFS-Climate data portal (http://ccafs-climate.org). The database has been used up to date in more than 350 studies of ecosystem and agricultural impact assessment. 1 international center for tropical Agriculture (ciAt), cali, colombia. 2 cGiAR Research Program on climate change, Agriculture and food Security (ccAfS), c/o ciAt, cali, colombia. 3 international Livestock Research institute (iLRi), nairobi, Kenya. 4 School of earth and environment, University of Leeds, Leeds, UK. *email: j.r.villegas@cgiar.org DATA DeSCrIPTor oPeN Scientific Data | (2020) 7:7 | https://doi.

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Climate change and ecosystem composition across large landscapes

Cited by 29 publications

References 24 publications

Light Intensity Modulates the Efficiency of Virus Seed Transmission through Modifications of Plant Tolerance

Light Intensity Modulates the Efficiency of Virus Seed Transmission through Modifications of Plant Tolerance

Historical and event‐based bioclimatic suitability predicts regional forest vulnerability to compound effects of severe drought and bark beetle infestation

High-resolution and bias-corrected CMIP5 projections for climate change impact assessments

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