Effects of Atmospheric CO2 and Temperature on Wheat and Corn Susceptibility to Fusarium graminearum and Deoxynivalenol Contamination

This work details the impact of atmospheric CO2 and temperature conditions on two strains of Fusarium graminearum, their disease damage, pathogen growth, mycotoxin accumulation, and production per unit fungal biomass in wheat and corn. An elevated atmospheric CO2 concentration, 1000 ppm CO2, significantly increased the accumulation of deoxynivalenol in infected plants. Furthermore, growth in cool growing conditions, 20 °C/18 °C, day and night, respectively, resulted in the highest amounts of pathogen biomass and toxin accumulation in both inoculated wheat and corn. Warm temperatures, 25 °C/23 °C, day and night, respectively, suppressed pathogen growth and toxin accumulation, with reductions as great as 99% in corn. In wheat, despite reduced pathogen biomass and toxin accumulation at warm temperatures, the fungal pathogen was more aggressive with greater disease damage and toxin production per unit biomass. Disease outcomes were also pathogen strain specific, with complex interactions between host, strain, and growth conditions. However, we found that atmospheric CO2 and temperature had essentially no significant interactions, except for greatly increased deoxynivalenol accumulation in corn at cool temperatures and elevated CO2. Plants were most susceptible to disease damage at warm and cold temperatures for wheat and corn, respectively. This work helps elucidate the complex interaction between the abiotic stresses and biotic susceptibility of wheat and corn to Fusarium graminearum infection to better understand the potential impact global climate change poses to future food security.

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Climate change and agroecosystems: the effect of elevated atmospheric CO2 and temperature on crop growth, development, and yield

Ciência Rural ◽

10.1590/s0103-84782005000300041 ◽

2005 ◽

Vol 35 (3) ◽

pp. 730-740 ◽

Cited By ~ 56

Author(s):

Nereu Augusto Streck

Keyword(s):

Climate Change ◽

Crop Yield ◽

Co2 Concentration ◽

Crop Growth ◽

Atmospheric Co2 ◽

C3 Plants ◽

Elevated Atmospheric Co2 ◽

Growth Development ◽

Carbon Dioxide Co2 ◽

The Impact

The amount of carbon dioxide (CO2) of the Earth´s atmosphere is increasing, which has the potential of increasing greenhouse effect and air temperature in the future. Plants respond to environment CO2 and temperature. Therefore, climate change may affect agriculture. The purpose of this paper was to review the literature about the impact of a possible increase in atmospheric CO2 concentration and temperature on crop growth, development, and yield. Increasing CO2 concentration increases crop yield once the substrate for photosynthesis and the gradient of CO2 concentration between atmosphere and leaf increase. C3 plants will benefit more than C4 plants at elevated CO2. However, if global warming will take place, an increase in temperature may offset the benefits of increasing CO2 on crop yield.

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Improving ecophysiological simulation models to predict the impact of elevated atmospheric CO2 concentration on crop productivity

Annals of Botany ◽

10.1093/aob/mct016 ◽

2013 ◽

Vol 112 (3) ◽

pp. 465-475 ◽

Cited By ~ 49

Author(s):

Xinyou Yin

Keyword(s):

Simulation Models ◽

Co2 Concentration ◽

Crop Productivity ◽

Atmospheric Co2 ◽

Elevated Atmospheric Co2 ◽

Atmospheric Co2 Concentration ◽

The Impact

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The effects of elevated atmospheric CO2 concentration on the biological control of invasive aquatic weeds

Aquatic Botany ◽

10.1016/j.aquabot.2020.103348 ◽

2020 ◽

pp. 103348

Author(s):

Nompumelelo C. Baso ◽

Julie A. Coetzee ◽

Brad S. Ripley ◽

Martin P. Hill

Keyword(s):

Biological Control ◽

Co2 Concentration ◽

Atmospheric Co2 ◽

Aquatic Weeds ◽

Elevated Atmospheric Co2 ◽

Atmospheric Co2 Concentration

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Response of simulated burned area to historical changes in environmental and anthropogenic factors: a comparison of seven fire models

Biogeosciences ◽

10.5194/bg-16-3883-2019 ◽

2019 ◽

Vol 16 (19) ◽

pp. 3883-3910 ◽

Cited By ~ 5

Author(s):

Lina Teckentrup ◽

Sandy P. Harrison ◽

Stijn Hantson ◽

Angelika Heil ◽

Joe R. Melton ◽

...

Keyword(s):

Land Use ◽

Co2 Concentration ◽

Fire Regimes ◽

Atmospheric Co2 ◽

Anthropogenic Factors ◽

Burned Area ◽

Earth System ◽

Atmospheric Co2 Concentration ◽

Fire Models ◽

The Impact

Abstract. Understanding how fire regimes change over time is of major importance for understanding their future impact on the Earth system, including society. Large differences in simulated burned area between fire models show that there is substantial uncertainty associated with modelling global change impacts on fire regimes. We draw here on sensitivity simulations made by seven global dynamic vegetation models participating in the Fire Model Intercomparison Project (FireMIP) to understand how differences in models translate into differences in fire regime projections. The sensitivity experiments isolate the impact of the individual drivers on simulated burned area, which are prescribed in the simulations. Specifically these drivers are atmospheric CO2 concentration, population density, land-use change, lightning and climate. The seven models capture spatial patterns in burned area. However, they show considerable differences in the burned area trends since 1921. We analyse the trajectories of differences between the sensitivity and reference simulation to improve our understanding of what drives the global trends in burned area. Where it is possible, we link the inter-model differences to model assumptions. Overall, these analyses reveal that the largest uncertainties in simulating global historical burned area are related to the representation of anthropogenic ignitions and suppression and effects of land use on vegetation and fire. In line with previous studies this highlights the need to improve our understanding and model representation of the relationship between human activities and fire to improve our abilities to model fire within Earth system model applications. Only two models show a strong response to atmospheric CO2 concentration. The effects of changes in atmospheric CO2 concentration on fire are complex and quantitative information of how fuel loads and how flammability changes due to this factor is missing. The response to lightning on global scale is low. The response of burned area to climate is spatially heterogeneous and has a strong inter-annual variation. Climate is therefore likely more important than the other factors for short-term variations and extremes in burned area. This study provides a basis to understand the uncertainties in global fire modelling. Both improvements in process understanding and observational constraints reduce uncertainties in modelling burned area trends.

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On the multi-century Southern Hemisphere response to changes in atmospheric CO2-concentration in a Global Climate Model

Meteorology and Atmospheric Physics ◽

10.1007/s00703-005-0119-x ◽

2005 ◽

Vol 89 (1-4) ◽

pp. 17-36 ◽

Cited By ~ 4

Author(s):

M. L. Bates ◽

M. H. England ◽

W. P. Sijp

Keyword(s):

Southern Hemisphere ◽

Climate Model ◽

Global Climate ◽

Global Climate Model ◽

Co2 Concentration ◽

Atmospheric Co2 ◽

Atmospheric Co2 Concentration

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Root growth and function of three Mojave Desert grasses in response to elevated atmospheric CO2 concentration

New Phytologist ◽

10.1046/j.1469-8137.2000.00576.x ◽

2000 ◽

Vol 145 (2) ◽

pp. 245-256 ◽

Cited By ~ 19

Author(s):

C. K. YODER ◽

P. VIVIN ◽

L. A. DEFALCO ◽

J. R. SEEMANN ◽

R. S. NOWAK

Keyword(s):

Root Growth ◽

Mojave Desert ◽

Co2 Concentration ◽

Atmospheric Co2 ◽

Elevated Atmospheric Co2 ◽

Atmospheric Co2 Concentration ◽

And Function ◽

Desert Grasses

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The impact of elevated atmospheric CO2 and nitrate supply on growth, biomass allocation, nitrogen partitioning and N2 fixation of Acacia melanoxylon

Functional Plant Biology ◽

10.1071/pp99062 ◽

1999 ◽

Vol 26 (8) ◽

pp. 737 ◽

Cited By ~ 20

Author(s):

Marcus Schortemeyer ◽

Owen K. Atkin ◽

Nola McFarlane ◽

John R. Evans

Keyword(s):

Elevated Co2 ◽

N2 Fixation ◽

Dry Matter ◽

Co2 Concentration ◽

Dry Mass ◽

Nitrogen Partitioning ◽

Atmospheric Co2 ◽

Acacia Melanoxylon ◽

Nitrate Supply ◽

The Impact

The interactive effects of nitrate supply and atmospheric CO2 concentration on growth, N2 fixation, dry matter and nitrogen partitioning in the leguminous tree Acacia melanoxylon R.Br. were studied. Seedlings were grown hydroponically in controlled-environment cabinets for 5 weeks at seven 15N-labelled nitrate levels, ranging from 3 to 6400 mmol m–3. Plants were exposed to ambient (~350 µmol mol–1) or elevated (~700 µmol mol–1) atmospheric CO2 for 6 weeks. Total plant dry mass increased strongly with nitrate supply. The proportion of nitrogen derived from air decreased with increasing nitrate supply. Plants grown under either ambient or elevated CO2 fixed the same amount of nitrogen per unit nodule dry mass (16.6 mmol N per g nodule dry mass) regardless of the nitrogen treatment. CO2 concentration had no effect on the relative contribution of N2 fixation to the nitrogen yield of plants. Plants grown with ≥50 mmol m–3 N and elevated CO2 had approximately twice the dry mass of those grown with ambient CO2 after 42 days. The rates of net CO2 assimilation under growth conditions were higher per unit leaf area for plants grown under elevated CO2. Elevated CO2 also decreased specific foliage area, due to an increase in foliage thickness and density. Dry matter partitioning between plant organs was affected by ontogeny and nitrogen status of the plants, but not by CO2 concentration. In contrast, plants grown under elevated CO2 partitioned more of their nitrogen to roots. This could be attributed to reduced nitrogen concentrations in foliage grown under elevated CO2.

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