Contrasting mechanisms underlie short‐ and longer‐term soil respiration responses to experimental warming in a dryland ecosystem

Dacal, Marina; García‐Palacios, Pablo; Asensio, Sergio; Cano‐Díaz, Concha; Gozalo, Beatriz; Ochoa, Victoria; Maestre, Fernando T.

doi:10.1111/gcb.15209

Cited by 37 publications

(29 citation statements)

References 73 publications

(141 reference statements)

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“…δ 13 C in soil organic matter (SOM) is c. −26, while in atmospheric CO 2 it is c. −8; Lakatos et al, 2007). Increased soil respiration in biocrust-dominated soils has been reported during the first years of simulated warming and rainfall reduction (Maestre et al, 2013;Escolar et al, 2015;Dacal et al, 2020). However, it would then be expected that P. decipiens, characterized by discontinuous darker squamules (small, scale-like thallus units), should also have higher evaporation rates under these experimental conditions and, simultaneously, capture more water from nonliquid precipitation than more continuous species because of its higher surface area (Raggio et al, 2014).…”

Section: New Phytologistmentioning

confidence: 99%

“…total C and N) of both biocrust‐forming lichens and mosses is expected to be reduced with increased temperature and altered rainfall regimes as a result of reduced physiological performance (Reed et al ., 2012), as has been shown along climatic gradients in the field (Concostrina‐Zubiri et al ., 2018). Thus, lichens are expected to play an important role in modulating climate change effects on soil diversity and functioning (Maestre et al ., 2015; Liu et al ., 2016; Dacal et al ., 2020). Understanding how climate change will differentially impact dominant biocrust‐forming lichen species is critical to better forecasting how climate change will impact ecosystem functioning in drylands.…”

Section: Introductionmentioning

confidence: 99%

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Species‐specific effects of biocrust‐forming lichens on soil properties under simulated climate change are driven by functional traits

et al. 2021

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Summary Biocrusts are key drivers of ecosystem functioning in drylands, yet our understanding of how climate change will affect the chemistry of biocrust‐forming species and their impacts on carbon (C) and nitrogen (N) cycling is still very limited. Using a manipulative experiment conducted with common biocrust‐forming lichens with distinct morphology and chemistry (Buellia zoharyi, Diploschistes diacapsis, Psora decipiens and Squamarina lentigera), we evaluated changes in lichen total and isotopic C and N and several soil C and N variables after 50 months of simulated warming and rainfall reduction. Climate change treatments reduced δ13C and the C : N ratio in B. zoharyi, and increased δ15N in S. lentigera. Lichens had species‐specific effects on soil dissolved organic N (DON), NH4+, β‐glucosidase and acid phosphatase activity regardless of climate change treatments, while these treatments changed how lichens affected several soil properties regardless of biocrust species. Changes in thallus δ13C, N and C : N drove species‐specific effects on dissolved organic nitrogen (DON), NH4+, β‐glucosidase and acid phosphatase activity. Our findings indicate that warmer and drier conditions will alter the chemistry of biocrust‐forming lichens, affecting soil nutrient cycling, and emphasize their key role as modulators of climate change impacts in dryland soils.

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Section: New Phytologistmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Species‐specific effects of biocrust‐forming lichens on soil properties under simulated climate change are driven by functional traits

et al. 2021

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“…The first one (hereafter Experiment 1) in El Cautivo, where we assessed the sensitivity of lichen physiological processes and cover towards systematic changes in single and combined climate variables. The second experiment (hereafter Experiment 2) mimicked and extended an ongoing climate change experiment in Aranjuez (Dacal et al, 2020;Maestre et al, 2013) to determine the mechanisms leading to the observed changes in biocrust cover and to see how well the model can be transferred to other sites despite the intra-specific physiological variability of D. diacapsis (Lange et al, 1997;Pintado et al, 2005).…”

Section: Simulation Experimentsmentioning

confidence: 99%

“…Considering the temporal and spatial scales at which climate change is operating, experiments and field studies have some major limitations. First, they are restricted to relatively small research areas and short time-scales: all experiments conducted to date have been running for 15 years or less (Dacal et al, 2020;Ferrenberg et al, 2015). Second, manipulative climate change treatments potentially introduce unintended side effects that can influence the results (Carlyle et al, 2011) and different manipulation methods can hamper the comparison between studies (Bokhorst et al, 2013;Klein et al, 2005;Ladrón de Guevara et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

et al. 2020

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1. Manipulative experiments typically show a decrease in dryland biocrust cover and altered species composition under climate change. Biocrust-forming lichens, such as the globally distributed Diploschistes diacapsis, are particularly affected and show a decrease in cover with simulated climate change. However, the underlying mechanisms are not fully understood, and long-term interacting effects of different drivers are largely unknown due to the short-term nature of the experimental studies conducted so far. 2. We addressed this gap and successfully parameterised a process-based model for D. diacapsis to quantify how changing atmospheric CO 2 , temperature, rainfall amount and relative humidity affect its photosynthetic activity and cover. We also mimicked a long-term manipulative climate change experiment to understand the mechanisms underlying observed patterns in the field. 3. The model reproduced observed experimental findings: warming reduced lichen cover, whereas less rainfall had no effect on lichen performance. This warming effect was caused by the associated decrease in relative humidity and nonrainfall water inputs, which are major water sources for biocrust-forming lichens. Warming alone, however, increased cover because higher temperatures promoted photosynthesis during early morning hours with high lichen activity. When combined, climate variables showed non-additive effects on lichen cover, and effects of increased CO 2 levelled off with decreasing levels of relative humidity. 4. Synthesis. Our results show that a decrease in relative humidity, rather than an increase in temperature, may be the key factor for the survival of the lichen D. diacapsis under climate change and that effects of increased CO 2 levels might be offset by a reduction in non-rainfall water inputs in the future. Because of a global trend towards warmer and drier air and the widespread global distribution of D. diacapsis, this will affect lichen-dominated dryland biocrust communities and their role in regulating ecosystem functions worldwide. This is an open access article under the terms of the Creat ive Commo ns Attri butio n-NonCo mmercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes.

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“…To adequately explore the potential mechanisms shaping the responses of autotrophic and heterotrophic respiration to N input, we also evaluated the effects of other environmental (soil temperature, pH, etc. ; Dacal et al., 2020; Luo & Zhou, 2006), plant (gross primary productivity, root biomass, plant functional traits, etc. ; Bardgett et al., 2014) and microbial (soil total phospholipid fatty acids [PLFAs], extracellular enzyme activity, etc.…”

Section: Introductionmentioning

confidence: 99%

Changes in above‐/below‐ground biodiversity and plant functional composition mediate soil respiration response to nitrogen input

Zhang

Peng

et al. 2021

Functional Ecology

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Biodiversity loss and changes in plant community composition induced by anthropogenic nitrogen (N) deposition exert profound effects on ecosystem functions. However, limited studies have considered the joint effects of plant community composition, plant species richness, plant functional diversity and soil biodiversity on the dynamics of soil autotrophic and heterotrophic respiration under extra N input. We addressed this issue by conducting a multilevel N‐manipulation experiment in a Tibetan alpine steppe. Based on soil respiration observations as well as biotic and abiotic measurements under this N addition experiment, we quantified the relative and interactive effects of above‐/below‐ground biodiversity, plant community composition and other explanatory variables (environmental factors, plant and microbial properties) on autotrophic and heterotrophic respiration. Our results showed that the effects of N enrichment via plant productivity, root amount, the proportion of sedge biomass and plant functional diversity explained 71% of the N‐induced variations in autotrophic respiration. With regard to heterotrophic respiration, the combination of N addition, soil pH, plant functional diversity and soil biota diversity accounted for 78% of its variations along the N addition gradient. Further analyses showed that above‐/below‐ground diversity loss and changes in plant community composition explained similar variation to that contributed by other factors in both autotrophic and heterotrophic respiration. The declined plant functional diversity and the increased proportion of sedge biomass promoted autotrophic respiration. Conversely, the loss of soil biodiversity together with the decreased plant functional diversity led to the decline of heterotrophic respiration along the experimental N gradient. Our results highlight that the indirect regulation of N input on ecosystem function through changes in plant community composition and above‐/below‐ground biodiversity loss should be considered for better understanding the responses of terrestrial ecosystems to atmospheric N deposition. A free Plain Language Summary can be found within the Supporting Information of this article.

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Contrasting mechanisms underlie short‐ and longer‐term soil respiration responses to experimental warming in a dryland ecosystem

Cited by 37 publications

References 73 publications

Species‐specific effects of biocrust‐forming lichens on soil properties under simulated climate change are driven by functional traits

Species‐specific effects of biocrust‐forming lichens on soil properties under simulated climate change are driven by functional traits

Relative humidity predominantly determines long‐term biocrust‐forming lichen cover in drylands under climate change

Changes in above‐/below‐ground biodiversity and plant functional composition mediate soil respiration response to nitrogen input

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