COS 128-6 - Seasonal changes in microbial C and N isotope signatures for grasslands and forests along an elevation gradient in Northern Arizona, USA

Friday, August 7, 2009: 9:50 AM
Grand Pavillion IV, Hyatt
Paul Dijkstra1, Corinne M LaViolette2, Bruce A. Hungate2, Egbert Schwartz3 and Stephen C. Hart4, (1)Center of Ecosystem Science and Society, Northern Arizona University, Flagstaff, AZ, (2)Department of Biological Sciences, Northern Arizona University, Flagstaff, AZ, (3)Center for Ecosystem Science and Society, Northern Arizona University, Flagstaff, AZ, (4)Life & Environmental Sciences and Sierra Nevada Research Institute, University of California, Merced, CA
Background/Question/Methods

The isotope composition of the soil microbial biomass is potentially of great importance as it may reflect fractionation during key steps in ecosystem C and N cycling. In the past, we have shown that the relative C and N availability influences the N isotope composition of the microbial biomass in ecosystems as varied as semiarid woodlands, high elevation deserts, temperate grasslands and tropical rainforests. The C isotope composition of microbial biomass seems to reflect mostly the C source. Thus, the natural abundance microbial stable isotope signatures can be useful to track seasonal variation in C and N availability and source of C for microorganisms in C3-C4 mixed vegetations.

We determined the C and N isotope composition of microbial biomass in soils from eight ecosystems (Great Basin desert, cool desert grassland, grass-dominated piñon-juniper interspaces, meadows in the ponderosa pine and mixed conifer forests, and an aspen and ponderosa pine stand) once a month for one year. We compared the isotope composition of microbial biomass with available C and N and net N mineralization in laboratory and field incubations.


Results/Conclusions

We observed significant variability across seasons in microbial C and N signatures, C and N availability, and net N mineralization for most sites. However, there was not a consistent correlation between N mineralization and microbial isotope composition. These results indicate that the relationship between N cycling, C availability and microbial isotope composition is more complex than previously thought.

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