E. Blanc‐Betes scite author profile

Soils are warming as air temperatures rise across the Arctic and Boreal region concurrent with the expansion of tall-statured shrubs and trees in the tundra. Changes in vegetation structure and function are expected to alter soil thermal regimes, thereby modifying climate feedbacks related to permafrost thaw and carbon cycling. However, current understanding of vegetation impacts on soil temperature is limited to local or regional scales and lacks the generality necessary to predict soil warming and permafrost stability on a pan-Arctic scale. Here we synthesize shallow soil and air temperature observations with broad spatial and temporal coverage collected across 106 sites representing nine different vegetation types in the permafrost region. We showed ecosystems with tall-statured shrubs and trees (>40 cm) have warmer shallow soils than those with short-statured tundra vegetation when normalized to a constant air temperature. In tree and tall shrub vegetation types, cooler temperatures in the warm season do not lead to cooler mean annual soil temperature indicating that ground thermal regimes in the cold-season rather than the warm-season are most critical for predicting soil warming in ecosystems underlain by permafrost. Our results suggest that the expansion of tall shrubs and trees into tundra regions can amplify shallow soil warming, and could increase the potential for increased seasonal thaw depth and increase soil carbon cycling rates and lead to increased carbon dioxide loss and further permafrost thaw.

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Winter precipitation and snow accumulation drive the methane sink or source strength of Arctic tussock tundra

Blanc‐Betes

Welker

Sturchio

et al. 2016

Global Change Biology

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Arctic winter precipitation is projected to increase with global warming, but some areas will experience decreases in snow accumulation. Although Arctic CH4 emissions may represent a significant climate forcing feedback, long-term impacts of changes in snow accumulation on CH4 fluxes remain uncertain. We measured ecosystem CH4 fluxes and soil CH4 and CO2 concentrations and (13) C composition to investigate the metabolic pathways and transport mechanisms driving moist acidic tundra CH4 flux over the growing season (Jun-Aug) after 18 years of experimental snow depth increases and decreases. Deeper snow increased soil wetness and warming, reducing soil %O2 levels and increasing thaw depth. Soil moisture, through changes in soil %O2 saturation, determined predominance of methanotrophy or methanogenesis, with soil temperature regulating the ecosystem CH4 sink or source strength. Reduced snow (RS) increased the fraction of oxidized CH4 (Fox) by 75-120% compared to Ambient, switching the system from a small source to a net CH4 sink (21 ± 2 and -31 ± 1 mg CH4 m(-2) season(-1) at Ambient and RS). Deeper snow reduced Fox by 35-40% and 90-100% in medium- (MS) and high- (HS) snow additions relative to Ambient, contributing to increasing the CH4 source strength of moist acidic tundra (464 ± 15 and 3561 ± 97 mg CH4 m(-2) season(-1) at MS and HS). Decreases in Fox with deeper snow were partly due to increases in plant-mediated CH4 transport associated with the expansion of tall graminoids. Deeper snow enhanced CH4 production within newly thawed soils, responding mainly to soil warming rather than to increases in acetate fermentation expected from thaw-induced increases in SOC availability. Our results suggest that increased winter precipitation will increase the CH4 source strength of Arctic tundra, but the resulting positive feedback on climate change will depend on the balance between areas with more or less snow accumulation than they are currently facing.

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Changes in Respiratory Mitochondrial Machinery and Cytochrome and Alternative Pathway Activities in Response to Energy Demand Underlie the Acclimation of Respiration to Elevated CO₂ in the Invasive Opuntia ficus-indica

Gomez‐Casanovas¹,

Blanc‐Betes²,

Gonzàlez-Meler³

et al. 2007

Plant Physiol.

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Studies on long-term effects of plants grown at elevated CO 2 are scarce and mechanisms of such responses are largely unknown. To gain mechanistic understanding on respiratory acclimation to elevated CO 2 , the Crassulacean acid metabolism Mediterranean invasive Opuntia ficus-indica Miller was grown at various CO 2 concentrations. Respiration rates, maximum activity of cytochrome c oxidase, and active mitochondrial number consistently decreased in plants grown at elevated CO 2 during the 9 months of the study when compared to ambient plants. Plant growth at elevated CO 2 also reduced cytochrome pathway activity, but increased the activity of the alternative pathway. Despite all these effects seen in plants grown at high CO 2 , the specific oxygen uptake rate per unit of active mitochondria was the same for plants grown at ambient and elevated CO 2 . Although decreases in photorespiration activity have been pointed out as a factor contributing to the long-term acclimation of plant respiration to growth at elevated CO 2 , the homeostatic maintenance of specific respiratory rate per unit of mitochondria in response to high CO 2 suggests that photorespiratory activity may play a small role on the long-term acclimation of respiration to elevated CO 2 . However, despite growth enhancement and as a result of the inhibition in cytochrome pathway activity by elevated CO 2 , total mitochondrial ATP production was decreased by plant growth at elevated CO 2 when compared to ambient-grown plants. Because plant growth at elevated CO 2 increased biomass but reduced respiratory machinery, activity, and ATP yields while maintaining O 2 consumption rates per unit of mitochondria, we suggest that acclimation to elevated CO 2 results from physiological adjustment of respiration to tissue ATP demand, which may not be entirely driven by nitrogen metabolism as previously suggested.

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The carbon and nitrogen cycle impacts of reverting perennial bioenergy switchgrass to an annual maize crop rotation

et al. 2020

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In the age of biofuel innovation, bioenergy crop sustainability assessment has determined how candidate systems alter the carbon (C) and nitrogen (N) cycle. These research efforts revealed how perennial crops, such as switchgrass, increase belowground soil organic carbon (SOC) and lose less N than annual crops, like maize. As demand for bioenergy increases, land managers will need to choose whether to invest in food or fuel cropping systems. However, little research has focused on the C and N cycle impacts of reverting purpose-grown perennial bioenergy crops back to annual cropping systems. We investigated this knowledge gap by measuring C and N pools and fluxes over 2 years following reversion of a mature switchgrass stand to an annual maize rotation. The most striking treatment difference was in ecosystem respiration (ER), with the maize-converted treatment showing the highest respiration flux of 2,073.63 (± 367.20) g C m −2 year −1 compared to the switchgrass 1,412.70 (± 28.72) g C m −2 year −1 and maize-control treatments 1,699.16 (± 234.79) g C m −2 year −1. This difference was likely driven by increased heterotrophic respiration of belowground This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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In silico assessment of the potential of basalt amendments to reduce N₂O emissions from bioenergy crops

et al. 2020

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E. Blanc‐Betes

Shallow soils are warmer under trees and tall shrubs across Arctic and Boreal ecosystems

Winter precipitation and snow accumulation drive the methane sink or source strength of Arctic tussock tundra

Changes in Respiratory Mitochondrial Machinery and Cytochrome and Alternative Pathway Activities in Response to Energy Demand Underlie the Acclimation of Respiration to Elevated CO₂ in the Invasive Opuntia ficus-indica

The carbon and nitrogen cycle impacts of reverting perennial bioenergy switchgrass to an annual maize crop rotation

In silico assessment of the potential of basalt amendments to reduce N₂O emissions from bioenergy crops

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E. Blanc‐Betes

Shallow soils are warmer under trees and tall shrubs across Arctic and Boreal ecosystems

Winter precipitation and snow accumulation drive the methane sink or source strength of Arctic tussock tundra

Changes in Respiratory Mitochondrial Machinery and Cytochrome and Alternative Pathway Activities in Response to Energy Demand Underlie the Acclimation of Respiration to Elevated CO2 in the Invasive Opuntia ficus-indica

The carbon and nitrogen cycle impacts of reverting perennial bioenergy switchgrass to an annual maize crop rotation

In silico assessment of the potential of basalt amendments to reduce N2O emissions from bioenergy crops

Contact Info

Product

Resources

About

Changes in Respiratory Mitochondrial Machinery and Cytochrome and Alternative Pathway Activities in Response to Energy Demand Underlie the Acclimation of Respiration to Elevated CO₂ in the Invasive Opuntia ficus-indica

In silico assessment of the potential of basalt amendments to reduce N₂O emissions from bioenergy crops