Catalytic power of enzymes decreases with temperature: New insights for understanding soil C cycling and microbial ecology under warming

Alvarez, Gaël; Shahzad, Tanvir; Andanson, Laurence; Bahn, Michael; Wallenstein, Matthew D.; Fontaine, Sébastien

doi:10.1111/gcb.14281

Cited by 69 publications

(52 citation statements)

References 78 publications

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“…However, the lower NNmin at warming than at the ambient was in agreement with the results of the earlier findings showing that both net and gross nitrification rates declined with increasing temperature from 15 to 20ºC [58]. These negative responses in NNmin to warming may be caused by the limited availability of soluble organic C in their soils [57], and the catalytic power of enzyme decreases with warming may also be a necessary reason [59]. The ANmin decreases with increasing soil temperature were also observed in [49], and were attributed to the lack of positive response in ammonification to increasing temperature to the accelerated immobilization of NH4 + -N by microbes [49,60].…”

Section: Net N Mineralization Decreased With Warmingsupporting

confidence: 91%

Effects of <i>Solidago canadensis</i> Invasion and Climate Warming on Soil Net N Mineralization

Ren¹,

He²,

Li³

et al. 2020

Pol. J. Environ. Stud.

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The rapid expansion of Solidago canadensis and climate warming in southeastern China may interactively affect soil net nitrogen (N) mineralization, which may lead to plant invasion. A greenhouse simulated experiment was conducted with invasion, warming, and their interaction to investigate these changes' effects on soil net N mineralization in an ecological system. Our results indicated that the average rate of net mineralization, nitrification, and ammonification decreased with invasion, warming, and their interaction. The enzyme activities and pH showed more sensitivity in warming than invasion, and have a similar decreased trend with net N mineralization response to environmental changes, except sucrase. At the same time, enzyme and pH may play a key role in the process of net N mineralization from Pearson's correlation and redundancy analysis, especially for sucrase and urease. In addition, the lower produced of litter biomass by plants growing in pots was also an important reason for the decrease of net N mineralization rate. These results indicated that the significant decrease in substrate quality (N availability) by the increase in invasion and warming may cause the deterioration of species production in soil, which will have important consequences for soil ecology, N-cycles, and plant invasion.

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Section: Net N Mineralization Decreased With Warmingsupporting

confidence: 91%

Effects of <i>Solidago canadensis</i> Invasion and Climate Warming on Soil Net N Mineralization

Ren¹,

He²,

Li³

et al. 2020

Pol. J. Environ. Stud.

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“…This reversal effect was irrespective of atmospheric CO 2 concentration. The negative response of microbial activity to warming in July suggests that other environmental factors might have masked the inherent temperature sensitivity of microbial activity, as previously proposed 44,51 . Particularly, lower soil moisture might have been the leading cause of decreased biomass-specific growth and respiration and might have dampened the positive temperature response.…”

Section: Discussionmentioning

confidence: 54%

“…Field studies investigating climate change effects on microbial growth and CUE are scarce and have mostly focused on effects of warming. Studies on the response of microbial CUE to warming reported contradictory findings: some authors reported no effects of warming on microbial CUE 39,40 , while others observed reduced CUE [5][6][7]34,[41][42][43][44][45] , or increased microbial CUE 12 . However, these studies used a range of different approaches to estimate CUE 5 , which may not allow direct comparisons 6,8,46 .…”

mentioning

confidence: 99%

Microbial growth and carbon use efficiency show seasonal responses in a multifactorial climate change experiment

et al. 2020

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Microbial growth and carbon use efficiency (CUE) are central to the global carbon cycle, as microbial remains form soil organic matter. We investigated how future global changes may affect soil microbial growth, respiration, and CUE. We aimed to elucidate the soil microbial response to multiple climate change drivers across the growing season and whether effects of multiple global change drivers on soil microbial physiology are additive or interactive. We measured soil microbial growth, CUE, and respiration at three time points in a field experiment combining three levels of temperature and atmospheric CO2, and a summer drought. Here we show that climate change-driven effects on soil microbial physiology are interactive and season-specific, while the coupled response of growth and respiration lead to stable microbial CUE (average CUE = 0.39). These results suggest that future research should focus on microbial growth across different seasons to understand and predict effects of global changes on soil carbon dynamics.

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“…This may be linked to several factors. First, underdegraded lignin in the subsoil (indicated by lignin Ad/Al ratios) may be more susceptible to degradation in the warmed soils with an extended period of microbial activity (Lin et al, ) and a potentially increased size of enzyme pools (Alvarez et al, ), highlighting the vulnerability of relatively fresh lignin partially “cryo‐locked” in the deep horizons of alpine soils. Second, microbial degradation of millennia‐old SOC was found to be fueled by increased inputs of labile carbon via root penetration to the deep layers of a temperate grassland (Shahzad et al, ).…”

Section: Discussionmentioning

confidence: 99%

Climate warming alters subsoil but not topsoil carbon dynamics in alpine grassland

Jia

Cao

Liu

et al. 2019

Global Change Biology

106

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Subsoil contains more than half of soil organic carbon (SOC) globally and is conventionally assumed to be relatively unresponsive to warming compared to the topsoil. Here, we show substantial changes in carbon allocation and dynamics of the subsoil but not topsoil in the Qinghai-Tibetan alpine grasslands over 5 years of warming. Specifically, warming enhanced the accumulation of newly synthesized ( 14 C-enriched) carbon in the subsoil slow-cycling pool (silt-clay fraction) but promoted the decomposition of plant-derived lignin in the fastcycling pool (macroaggregates). These changes mirrored an accumulation of lipids and sugars at the expense of lignin in the warmed bulk subsoil, likely associated with shortened soil freezing period and a deepening root system. As warming is accompanied by deepening roots in a wide range of ecosystems, root-driven accrual of slow-cycling pool may represent an important and overlooked mechanism for a potential long-term carbon sink at depth. Moreover, given the contrasting sensitivity of SOC dynamics at varied depths, warming studies focusing only on surface soils may vastly misrepresent shifts in ecosystem carbon storage under climate change.

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Catalytic power of enzymes decreases with temperature: New insights for understanding soil C cycling and microbial ecology under warming

Cited by 69 publications

References 78 publications

Effects of <i>Solidago canadensis</i> Invasion and Climate Warming on Soil Net N Mineralization

Effects of <i>Solidago canadensis</i> Invasion and Climate Warming on Soil Net N Mineralization

Microbial growth and carbon use efficiency show seasonal responses in a multifactorial climate change experiment

Climate warming alters subsoil but not topsoil carbon dynamics in alpine grassland

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