B43H-0648
Weak leaf photosynthesis and nutrient content relationships from tropical vegetation
Thursday, 17 December 2015
Poster Hall (Moscone South)
Tomas Ferreira Domingues, USP University of Sao Paulo, São Paulo, Brazil, F. Yoko Ishida, James Cook University, Cape Tribulation, MN, Australia, Ted Feldpaush, University of Exeter, Exeter, United Kingdom, Gustavo Saiz, imk-ifu, Karlsruhe, Germany, John Grace, University of Edinburgh, School of GeoSciences, Edinburgh, United Kingdom, Patrick Meir, Australian National University, Research School of Biology, Canberra, Australia, Jon Lloyd, Imperial College London, London, United Kingdom and The TROBIT Team
Abstract:
Evergreen rain forests and savannas are the two major vegetations of tropical land ecosystems, in terms of land area, biomass, biodiversity, biogeochemical cycles and rates of land use change. Mechanistically understanding ecosystem functioning on such ecosystems is still far from complete, but important for generation of future vegetation scenarios in response to global changes. Leaf photosynthetic rates is a key processes usually represented on land surface-atmosphere models, although data from tropical ecosystems is scarce, considering the high biodiversity they contain. As a shortcut, models usually recur to relationships between leaf nutrient concentration and photosynthetic rates. Such strategy is convenient, given the possibility of global datasets on leave nutrients derived from hyperspectral remote sensing data. Given the importance of Nitrogen on enzyme composition, this nutrient is usually used to infer photosynthetic capacity of leaves. Our experience, based on individual measurements on 1809 individual leaves from 428 species of trees and shrubs naturally occurring on tropical forests and savannas from South America, Africa and Australia, indicates that the relationship between leaf nitrogen and its assimilation capacity is weak. Therefore, leaf Nitrogen alone is a poor predictor of photosynthetic rates of tropical vegetation. Phosphorus concentrations from tropical soils are usually low and is often implied that this nutrient limits primary productivity of tropical vegetation. Still, phosphorus (or other nutrients) did not exerted large influence over photosynthetic capacity, although potassium influenced vegetation structure and function. Such results draw attention to the risks of applying universal nitrogen-photosynthesis relationships on biogeochemical models. Moreover, our data suggests that affiliation of plant species within phylogenetic hierarchy is an important aspect in understanding leaf trait variation. The lack of a strong single predictor of leaf photosynthesis indicates that the importance of other factors such as secondary compounds, mesophyll conductance, Rubisco activation state, etc might be more influential than anticipated.