Patterns of nitrogen and citric acid induced changes in C-turnover and enzyme activities are different in topsoil and subsoils of a sandy Cambisol

Publication date: 15 April 2017
Source:Geoderma, Volume 292
Author(s): Julian Heitkötter, Jana Niebuhr, Stefanie Heinze, Bernd Marschner
Studies on factors controlling C-stability in subsoils are very scarce. Recent results suggest a lack of labile C substrates and N limitations in subsoils as a reason for suppressed C-turnover. The catalytic activity of soil enzymes plays an important role for the decomposition of organic matter in soils and can be a powerful tool to shed further light on substrate and N-limitation as a hypothesized controlling mechanism for C-stability in subsoils. Therefore, we studied the impacts of ¹⁴C-labelled citric acid and of NH4NO3 on changes in soil organic carbon (SOC)-mineralization and enzyme activities of dehydrogenase and 9 extracellular enzymes involved in C-, N-, P- and S-cycle. For this approach, we sampled a sandy Cambisol at three different depths (2–12, 35–65 and 135–165cm) and conducted a laboratory incubation experiment for 63days at 10°C. N-addition reduced SOC-mineralization in the topsoil layer by 43%, while no N-effect was observed in both subsoil layers. In the topsoil samples, dehydrogenase-activity also decreased after the incubation with N additions. Further, the activity of extracellular enzymes involved in P- and N-cycling was differently affected in top- and subsoils, indicating that microorganisms in different soil depths have different demands for N or P after adding inorganic N. Additions of citric acid increased SOC mineralization by about 1.9- and 2.2-fold in the upper (35–65cm) and lower subsoil (135–165cm) samples, but only by about 32% in the topsoil samples (2-12cm). The observed priming effect in the topsoil samples was not accompanied by an increased enzyme activity which indicates “apparent priming”. In contrast, priming effects in both subsoil layers were rated as “real priming” indicated by increased enzyme activities and continuously higher SOC-mineralization rates throughout the incubation compared to the controls.