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

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

doi:10.1111/gcb.14281

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

Glob Chang Biol. 2018 Sep;24(9):4238-4250. doi: 10.1111/gcb.14281. Epub 2018 May 16.

Authors

Gaël Alvarez¹, Tanvir Shahzad², Laurence Andanson¹, Michael Bahn³, Matthew D Wallenstein⁴, Sébastien Fontaine¹

Affiliations

¹ INRA, VetAgro Sup, UMR Ecosystème Prairial, Clermont-Ferrand, France.
² Department of Environmental Sciences & Engineering, Government College University-Faisalabad, Faisalabad, Pakistan.
³ Institute of Ecology, University of Innsbruck, Innsbruck, Austria.
⁴ Natural Resource Ecology Laboratory and Graduate Degree Program in Ecology, Colorado State University, Fort Collins, Colorado.

PMID: 29682861
DOI: 10.1111/gcb.14281

Abstract

Most current models of soil C dynamics predict that climate warming will accelerate soil C mineralization, resulting in a long-term CO₂ release and positive feedback to global warming. However, ecosystem warming experiments show that CO₂ loss from warmed soils declines to control levels within a few years. Here, we explore the temperature dependence of enzymatic conversion of polymerized soil organic C (SOC) into assimilable compounds, which is presumed the rate-limiting step of SOC mineralization. Combining literature review, modelling and enzyme assays, we studied the effect of temperature on activity of enzymes considering their thermal inactivation and catalytic activity. We defined the catalytic power of enzymes (E_power ) as the cumulative amount of degraded substrate by one unit of enzyme until its complete inactivation. We show a universal pattern of enzyme's thermodynamic properties: activation energy of catalytic activity (EA_cat ) < activation energy of thermal inactivation (EA_inact ). By investing in stable enzymes (high EA_inact ) having high catalytic activity (low EA_cat ), microorganisms may maximize the E_power of their enzymes. The counterpart of such EAs' hierarchical pattern is the higher relative temperature sensitivity of enzyme inactivation than catalysis, resulting in a reduction in E_power under warming. Our findings could explain the decrease with temperature in soil enzyme pools, microbial biomass (MB) and carbon use efficiency (CUE) reported in some warming experiments and studies monitoring the seasonal variation in soil enzymes. They also suggest that a decrease in soil enzyme pools due to their faster inactivation under warming contributes to the observed attenuation of warming effect on soil C mineralization. This testable theory predicts that the ultimate response of SOC degradation to warming can be positive or negative depending on the relative temperature response of E_power and microbial production of enzymes.

Keywords: SOC decomposition under warming; enzymatic activity; enzyme denaturation; enzyme trait; temperature sensitivity.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Bacteria / enzymology
Carbon Cycle*
Catalysis
Enzymes / chemistry*
Fungi / enzymology
Global Warming*
Hot Temperature / adverse effects*
Soil / chemistry*
Soil Microbiology*

Substances

Enzymes
Soil