The rhizosphere and hyphosphere differ in their impacts on carbon and nitrogen cycling in forests exposed to elevated CO2

IC Meier, SG Pritchard, ER Brzostek… - New …, 2015 - Wiley Online Library
New Phytologist, 2015Wiley Online Library
While multiple experiments have demonstrated that trees exposed to elevated CO 2 can
stimulate microbes to release nutrients from soil organic matter, the importance of root‐
versus mycorrhizal‐induced changes in soil processes are presently unknown. We analyzed
the contribution of roots and mycorrhizal activities to carbon (C) and nitrogen (N) turnover in
a loblolly pine (Pinus taeda) forest exposed to elevated CO 2 by measuring extracellular
enzyme activities at soil microsites accessed via root windows. Specifically, we quantified …
Summary
  • While multiple experiments have demonstrated that trees exposed to elevated CO2 can stimulate microbes to release nutrients from soil organic matter, the importance of root‐ versus mycorrhizal‐induced changes in soil processes are presently unknown.
  • We analyzed the contribution of roots and mycorrhizal activities to carbon (C) and nitrogen (N) turnover in a loblolly pine (Pinus taeda) forest exposed to elevated CO2 by measuring extracellular enzyme activities at soil microsites accessed via root windows. Specifically, we quantified enzyme activity from soil adjacent to root tips (rhizosphere), soil adjacent to hyphal tips (hyphosphere), and bulk soil.
  • During the peak growing season, CO2 enrichment induced a greater increase of N‐releasing enzymes in the rhizosphere (215% increase) than in the hyphosphere (36% increase), but a greater increase of recalcitrant C‐degrading enzymes in the hyphosphere (118%) than in the rhizosphere (19%). Nitrogen fertilization influenced the magnitude of CO2 effects on enzyme activities in the rhizosphere only. At the ecosystem scale, the rhizosphere accounted for c. 50% and 40% of the total activity of N‐ and C‐releasing enzymes, respectively.
  • Collectively, our results suggest that root exudates may contribute more to accelerated N cycling under elevated CO2 at this site, while mycorrhizal fungi may contribute more to soil C degradation.
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