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Article

How do enzymes catalysing soil nitrogen transformations respond to changing temperatures?

Details

Citation

Fraser F, Hallett PD, Wookey P, Hartley I & Hopkins D (2013) How do enzymes catalysing soil nitrogen transformations respond to changing temperatures?. Biology and Fertility of Soils, 49 (1), pp. 99-103. https://doi.org/10.1007/s00374-012-0722-1

Abstract
Biological processes in soils are regulated in part by soil temperature, and there is currently considerable interest in obtaining robust information on the temperature sensitivity of carbon cycling process. However, very little comparable information exists on the temperature regulation of specific nitrogen cycling processes. This paper addresses this problem by measuring the temperature sensitivity of nitrogen cycling enzymes in soil. A grassland soil was incubated over a range of temperatures (-2 to 21 °C) reflecting 99 % of the soil temperature range during the previous 50 years at the site. After 7 and 14 days of incubation, potential activities of protease, amidase and urease were determined. Activities of protease and urease were positively related to temperature (activation energy; Ea = 49. 7 and 73. 4 kJ mol-1, respectively, and Q10 = 2. 97 and 2. 78, respectively). By contrast, amidase activity was relatively insensitive to temperature, but the activity was significantly increased after the addition of glucose. This indicated that there was a stoichiometric imbalance with amidase activity only being triggered when there was a supply of exogenous carbon. Thus, carbon supply was a greater constraint to amidase activity than temperature was in this particular soil. © 2012 Springer-Verlag.

Keywords
Nitrogen mineralisation; temperature; response; Protease; Urease; Amidase;

Journal
Biology and Fertility of Soils: Volume 49, Issue 1

StatusPublished
Publication date31/01/2013
Publication date online29/07/2012
Date accepted by journal16/07/2012
URL
PublisherSpringer
ISSN0178-2762
eISSN1432-0789

People (1)

Professor Philip Wookey

Professor Philip Wookey

Professor, Biological and Environmental Sciences