Variation in symbiotic N2 fixation rates among Sphagnum mosses

• Published in: PloS one Vol. 15; no. 2; p. e0228383
• Main Authors: van den Elzen, Eva, Bengtsson, Fia, Fritz, Christian, Rydin, Håkan, Lamers, Leon P M
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 2020; Public Library of Science (PLoS)
• Subjects: Agricultural production; Aquatic ecology; Biology and Life Sciences; Boreal forests; Bryophyta; Cyanobacteria; Decomposition; Earth Sciences; Ecology and Environmental Sciences; Ecosystem; Ecosystem biology; Ecosystems; Evolutionary biology; Forests; Habitats; Microorganisms; Models, Theoretical; Mosses; Nitrogen; Nitrogen - analysis; Nitrogen Fixation; Nitrogenation; Nutrient concentrations; Peat; Peatlands; Phosphorus - analysis; Photosynthesis; Physical Sciences; Plant ecology; Primary production; Species; Sphagnopsida - classification; Sphagnopsida - growth & development; Sphagnopsida - metabolism; Sphagnum; Sweden; Symbiosis; Taiga; Variation; Vegetation; Wetlands; Sweden; Netherlands
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0228383

Biological nitrogen (N) fixation is an important process supporting primary production in ecosystems, especially in those where N availability is limiting growth, such as peatlands and boreal forests. In many peatlands, peat mosses (genus Sphagnum) are the prime ecosystem engineers, and like feather mosses in boreal forests, they are associated with a diverse community of diazotrophs (N2-fixing microorganisms) that live in and on their tissue. The large variation in N2 fixation rates reported in literature remains, however, to be explained. To assess the potential roles of habitat (including nutrient concentration) and species traits (in particular litter decomposability and photosynthetic capacity) on the variability in N2 fixation rates, we compared rates associated with various Sphagnum moss species in a bog, the surrounding forest and a fen in Sweden. We found appreciable variation in N2 fixation rates among moss species and habitats, and showed that both species and habitat conditions strongly influenced N2 fixation. We here show that higher decomposition rates, as explained by lower levels of decomposition-inhibiting compounds, and higher phosphorous (P) levels, are related with higher diazotrophic activity. Combining our findings with those of other studies, we propose a conceptual model in which both species-specific traits of mosses (as related to the trade-off between rapid photosynthesis and resistance to decomposition) and P availability, explain N2 fixation rates. This is expected to result in a tight coupling between P and N cycling in peatlands.