Trade-offs in resource allocation among moss species control decomposition in boreal peatlands

1. We separated the effects of plant species controls on decomposition rates from environmental controls in northern peatlands using a full factorial, reciprocal transplant experiment of eight dominant bryophytes in four distinct peatland types in boreal Alberta, Canada. Standard fractionation techn...

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Bibliographic Details
Published in:The Journal of ecology 2008-11, Vol.96 (6), p.1297-1305
Main Authors: Turetsky, Merritt R., Crow, Susan E., Evans, Robert J., Vitt, Dale H., Wieder, R. Kelman
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
BASIC BIOLOGICAL SCIENCES
Biochemistry
Bioenergy
Biological and medical sciences
Bogs
boreal
CARBOHYDRATES
CARBON
Chemical decomposition
Climate change
CLIMATES
Climatology. Bioclimatology. Climate change
Decomposition
degradation
Earth, ocean, space
Ecosystems
Exact sciences and technology
External geophysics
Fens
FRACTIONATION
Fundamental and applied biological sciences. Psychology
General aspects
Human ecology
INCUBATION
MAINTENANCE
MASS SPECTROSCOPY
METABOLISM
Meteorology
MOLECULAR BEAMS
MOSSES
mosses and liverworts
non-structural carbohydrates
PEAT
Peatlands
Plant-Climate Interactions
Plants
PYROLYSIS
resource allocation
RETENTION
SOILS
Species
Sphagnum
structural carbohydrates
TRANSPLANTS
WATER
Wetland ecology
WETLANDS
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Summary:1. We separated the effects of plant species controls on decomposition rates from environmental controls in northern peatlands using a full factorial, reciprocal transplant experiment of eight dominant bryophytes in four distinct peatland types in boreal Alberta, Canada. Standard fractionation techniques as well as compound-specific pyrolysis molecular beam mass spectrometry were used to identify a biochemical mechanism underlying any interspecific differences in decomposition rates. 2. We found that over a 3-year field incubation, individual moss species and not micro-environmental conditions controlled early stages of decomposition. Across species, Sphagnum mosses exhibited a trade-off in resource partitioning into metabolic and structural carbohydrates, a pattern that served as a strong predictor of litter decomposition. 3. Decomposition rates showed a negative co-variation between species and their microtopographic position, as species that live in hummocks decomposed slowly but hummock microhabitats themselves corresponded to rapid decomposition rates. By forming litter that degrades slowly, hummock mosses appear to promote the maintenance of macropore structure in surface peat hummocks that aid in water retention. 4. Synthesis. Many northern regions are experiencing rapid climate warming that is expected to accelerate the decomposition of large soil carbon pools stored within peatlands. However, our results suggest that some common peatland moss species form tissue that resists decomposition across a range of peatland environments, suggesting that moss resource allocation could stabilize peatland carbon losses under a changing climate.
ISSN:0022-0477
1365-2745
DOI:10.1111/j.1365-2745.2008.01438.x