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Growth responses, biomass partitioning, and nitrogen isotopes of prairie legumes in response to elevated temperature and varying nitrogen source in a growth chamber experiment
Author(s) -
Whittington Heather R.,
Deede Laura,
Powers Jennifer S.
Publication year - 2012
Publication title -
american journal of botany
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.218
H-Index - 151
eISSN - 1537-2197
pISSN - 0002-9122
DOI - 10.3732/ajb.1100283
Subject(s) - biology , shoot , legume , lespedeza , nitrogen fixation , lupinus , fabaceae , botany , rhizobia , nitrogen , biomass (ecology) , agronomy , seedling , nutrient , ecology , chemistry , genetics , organic chemistry , bacteria
• Premise of the Study: Because legumes can add nitrogen (N) to ecosystems through symbiotic fixation, they play important roles in many plant communities, such as prairies and grasslands. However, very little research has examined the effect of projected climate change on legume growth and function. Our goal was to study the effects of temperature on growth, nodulation, and N chemistry of prairie legumes and determine whether these effects are mediated by source of N. • Methods: We grew seedlings of Amorpha canescens , Dalea purpurea , Lespedeza capitata , and Lupinus perennis at 25/20°C (day/night) or 28/23°C with and without rhizobia and mineral N in controlled‐environment growth chambers. Biomass, leaf area, nodule number and mass, and shoot N concentration and δ 15 N values were measured after 12 wk of growth. • Key Results: Both temperature and N‐source affected responses in a species‐specific manner. Lespedeza showed increased growth and higher shoot N content at 28°C. Lupinus showed decreases in nodulation and lower shoot N concentration at 28°C. The effect of temperature on shoot N concentration occurred only in individuals whose sole N source was N 2 ‐fixation, but there was no effect of temperature on δ 15 N values in these plants. • Conclusions: Elevated temperature enhanced seedling growth of some species, while inhibiting nodulation in another. Temperature‐induced shifts in legume composition or nitrogen dynamics may be another potential mechanism through which climate change affects unmanaged ecosystems.

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