TY - JOUR
T1 - Trenching reduces soil heterotrophic activity in a loblolly pine (Pinus taeda) forest exposed to elevated atmospheric [CO2] and N fertilization
AU - Drake, J. E.
AU - Oishi, A. C.
AU - Giasson, M.-A.
AU - Oren, R.
AU - Johnsen, K. H.
AU - Finzi, A. C.
PY - 2012
Y1 - 2012
N2 - Forests return large quantities of C to the atmosphere through soil respiration (R soil), which is often conceptually separated into autotrophic C respired by living roots (R root) and heterotrophic decomposition (R het) of soil organic matter (SOM). Live roots provide C sources for microbial metabolism via exudation, allocation to fungal associates, sloughed-off cells, and secretions such as mucilage production, suggesting a coupling between the activity of roots and heterotrophs. We addressed the strength of root effects on the activity of microbes and exo-enzymes by removing live-root-C inputs to areas of soil with a trenching experiment. We examined the extent to which trenching affected metrics of soil heterotrophic activity (proteolytic enzyme activity, microbial respiration, potential net N mineralization and nitrification, and exo-enzyme activities) in a forest exposed to elevated atmospheric [CO 2] and N fertilization, and used automated measurements of R soil in trenched and un-trenched plots to estimate R root and R het components. Trenching decreased many metrics of heterotrophic activity and increased net N mineralization and nitrification, suggesting that the removal of root-C inputs reduced R het by exacerbating microbial C limitation and stimulating waste-N excretion. This trenching effect was muted by N fertilization alone but not when N fertilization was combined with elevated CO 2, consistent with known patterns of belowground C allocation at this site. Live-root-C inputs to soils and heterotrophic activity are tightly coupled, so root severing techniques like trenching are not likely to achieve robust quantitative estimates of R root or R het.
AB - Forests return large quantities of C to the atmosphere through soil respiration (R soil), which is often conceptually separated into autotrophic C respired by living roots (R root) and heterotrophic decomposition (R het) of soil organic matter (SOM). Live roots provide C sources for microbial metabolism via exudation, allocation to fungal associates, sloughed-off cells, and secretions such as mucilage production, suggesting a coupling between the activity of roots and heterotrophs. We addressed the strength of root effects on the activity of microbes and exo-enzymes by removing live-root-C inputs to areas of soil with a trenching experiment. We examined the extent to which trenching affected metrics of soil heterotrophic activity (proteolytic enzyme activity, microbial respiration, potential net N mineralization and nitrification, and exo-enzyme activities) in a forest exposed to elevated atmospheric [CO 2] and N fertilization, and used automated measurements of R soil in trenched and un-trenched plots to estimate R root and R het components. Trenching decreased many metrics of heterotrophic activity and increased net N mineralization and nitrification, suggesting that the removal of root-C inputs reduced R het by exacerbating microbial C limitation and stimulating waste-N excretion. This trenching effect was muted by N fertilization alone but not when N fertilization was combined with elevated CO 2, consistent with known patterns of belowground C allocation at this site. Live-root-C inputs to soils and heterotrophic activity are tightly coupled, so root severing techniques like trenching are not likely to achieve robust quantitative estimates of R root or R het.
UR - http://handle.uws.edu.au:8081/1959.7/528348
U2 - 10.1016/j.agrformet.2012.05.017
DO - 10.1016/j.agrformet.2012.05.017
M3 - Article
SN - 0168-1923
VL - 165
SP - 43
EP - 52
JO - Agricultural and Forest Meteorology
JF - Agricultural and Forest Meteorology
ER -