Abstract Detail

Stress-tolerant mosses: adaptations to life on the edge, from genes to ecosystems

Stuart, Julia [1], Mack, Michelle C [2].

Tundra moss transplants reveal host species-specific response of associated N₂ fixation rates to environmental change.

Rapid warming in Arctic and boreal ecosystems is expected to alter moss biomass and diversity. Process rates of moss associated N₂ fixation, the largest source of new N to a nutrient-limited environment, are also expected to change directly with the environment and indirectly through changes in host moss assemblages. Understanding the interaction between moss identity and environmental change in determining rates of N₂ fixation can improve future N input predictions in vulnerable regions which store vast amounts of C. We measured vascular and non-vascular community composition and moss species-specific rates of N₂ fixation in a reciprocal tundra transplant experiment between Healy (63°N, 149°W) and Toolik Lake (68°N,149°W), Alaska, sites which have similar moist acidic tussock plant communities but differ by over 5°C in mean annual temperature. We hypothesized that transplanted mosses would not differ in N₂ fixation rates from their home environment within a moss species one year after transplantation due to the key role of host identity in determining associated N₂ fixation rates. We found that the magnitude of response to transplantation varied greatly among mosses. While Hylocomium splendens showed no change associated with transplantation, A. turgidum varied moderately by location and P. schreberi had a strong increase in N₂ fixation rates associated with movement to a colder environment. Overall, N₂ fixation rates were lower in our warmer site both for native and transplanted mosses. We saw no change in vascular or non-vascular species composition with transplantation, though both communities were distinct between home locations. We conclude that moss-associated N₂ fixation responses to climate changes are host-dependent. Previous experiments have frequently seen a decline in moss biomass and moss diversity over time in response to warming. The host-specific responses of N₂ fixation to changing temperature could precede or contribute to these observed declines.

1 - Michigan Technological University, College of Forest Resources and Environmental Science, Houghton, MI, 49931, USA
2 - Northern Arizona University, Center for Ecosystem Science and Society, Flagstaff, AZ, 86001, USA

Keywords:
transplant study
bryophytes
stable isotopes
nitrogen fixation.

Presentation Type: Colloquium Presentations
Number: C5007
Abstract ID:221
Candidate for Awards:None