论文
论文题目: Catalytic efficiency of soil enzymes explains temperature sensitivity: Insights from physiological theory
第一作者: Liu Chaoyang, Tian Haixia, Gu Xiaoyue, Li Ni etc.
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发表年度: 2022
摘  要: Soil enzymes are crucial for carbon and nutrient cycling and are highly sensitive to warming. Biochemical reaction rates increase with temperature according to the Arrhenius law, but changes in microbial physiology may partially counteract this warming-induced acceleration that leads enzymatic rates to deviate from Arrhenius law. Here, we attempt to reconcile disparate views on the enzyme responses to warming based on the Arrhenius law and physiological theory by enzyme catalytic efficiency. In this study, we tested the kinetic parameters of five key enzymes of C, N, and P cycling to warming (from 0 to 40 degrees C) in cropland soils originating from 5 different temperate zones. The soils were incubated for one month at 0, 10, 20, 30, and 40 degrees C (+/- 0.5 degrees C) with 60% water holding capacity (WHC). The kinetic parameters were calculated and measured at a range of 4-methyumbelliferone (MUB)-substrate concentrations. We found that catalytic efficiency (V-max/K-m) of individual enzymes ranged from 0.05 to 27 s(-1) between 0 and 40 degrees C. Maximum reaction rate (V-max) increased with warming, while V-max/K-m of most enzymes remained stable by warming at low temperatures (up to 10 degrees C), and it raised from 20 to 40 degrees C. Most enzymes had lower substrate affinities (K-m) and increased their efficiency with warming. Consistent with studies considering Arrhenius law solely, the temperature sensitivity (Q(10)) of V-max decreased with warming. However, the Q(10) of V-max/K-m displayed a lower value in the cold but a higher value in warmer temperature, which confirmed microbial adaptation based on physiological theory, consequently encouraging its linking with the Arrhenius law. Therefore, Arrhenius linked with physiological theory could correct explanation of enzyme activities by warming. Considering the microbial adaptation to temperature, the present predicted warming-induced acceleration of soil organic matter decomposition might be overestimated in cold and underestimated in warm environments.
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刊物名称: SCIENCE OF THE TOTAL ENVIRONMENT
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论文类别: SCI