Your search keyword '"Nina Wurzburger"' showing total 3 results

1. Phosphorus and species regulate N2 fixation by herbaceous legumes in longleaf pine savannas

Author

Julie A. Tierney, Lars O. Hedin, Erik A. Hobbie, Michael R. Ament, and Nina Wurzburger

Subjects

0106 biological sciences, Facultative, Obligate, Biodiversity, chemistry.chemical_element, Herbaceous plant, Biology, 010603 evolutionary biology, 01 natural sciences, Nitrogen, Agronomy, chemistry, Ecosystem, Growth rate, Ecology, Evolution, Behavior and Systematics, Legume, 010606 plant biology & botany

Abstract

Longleaf pine savannas house a diverse community of herbaceous N2-fixing legume species that have the potential to replenish nitrogen (N) losses from fire. Whether legumes fill this role depends on the factors that regulate symbiotic fixation, including soil nutrients such as phosphorus (P) and molybdenum (Mo) and the growth and fixation strategies of different species. In greenhouse experiments, we determined how these factors influence fixation for seven species of legumes grown in pure field soil from two different regions of the southeastern US longleaf pine ecosystem. We first added P and Mo individually and in combination, and found that P alone constrained fixation. Phosphorus primarily influenced fixation by regulating legume growth. Second, we added N to plants and found that species either downregulated fixation (facultative strategy) or maintained fixation at a constant rate (obligate strategy). Species varied nearly fourfold in fixation rate, reflecting differences in growth rate, taxonomy and fixation strategy. However, fixation responded strongly to P addition across all species in our study, suggesting that the P cycle regulates N inputs by herbaceous legumes.

Published

2018

2. Root and leaf traits reflect distinct resource acquisition strategies in tropical lianas and trees

Author

Courtney G. Collins, S. Joseph Wright, and Nina Wurzburger

Subjects

0106 biological sciences, Specific leaf area, Nitrogen, Environment, Forests, Plant Roots, 010603 evolutionary biology, 01 natural sciences, Trees, Abundance (ecology), Mycorrhizae, Botany, Dominance (ecology), Ecosystem, Mycorrhiza, Ecology, Evolution, Behavior and Systematics, Tropical Climate, Habitat fragmentation, biology, Ecology, Phosphorus, Plants, biology.organism_classification, Carbon, Plant Leaves, Phenotype, Liana, Species richness, 010606 plant biology & botany

Abstract

In Neotropical forests, lianas are increasing in abundance relative to trees. This increased species richness may reflect a positive response to global change factors including increased temperature, atmospheric CO2, habitat fragmentation, and drought severity; however, questions remain as to the specific mechanisms facilitating the response. Previous work suggests that lianas may gain an ecological advantage over trees through leaf functional traits that offer a quick return on investment of resources, although it is unknown whether this pattern extends to root traits and relationships with fungal or bacterial symbionts belowground. We sampled confamilial pairs of liana and tree species and quantified morphological and chemical traits of leaves and fine roots, as well as root symbiont abundance, to determine whether functional traits associated with resource acquisition differed between the two. Compared to trees, lianas possessed higher specific leaf area, specific root length, root branching intensity, and root nitrogen (N) and phosphorus (P) concentrations, and lower leaf and root tissue density, leaf and root carbon (C), root diameter, root C:P and N:P, and mycorrhizal colonization. Our study provides new evidence that liana leaf and root traits are characterized by a rapid resource acquisition strategy relative to trees. These liana functional traits may facilitate their response to global change, raising questions about how increased liana dominance might affect ecosystem processes of Neotropical forests.

Published

2015

3. Drought enhances symbiotic dinitrogen fixation and competitive ability of a temperate forest tree

Author

Nina Wurzburger and Chelcy Ford Miniat

Subjects

Stomatal conductance, Liriodendron, media_common.quotation_subject, Drought tolerance, Acer, Biology, Competition (biology), Trees, Quercus, Soil, Xylem, Nitrogen Fixation, Ecosystem, Biomass, Water-use efficiency, Ecology, Evolution, Behavior and Systematics, media_common, Biomass (ecology), Ecology, fungi, food and beverages, Temperate forest, Robinia, Water, Droughts, Plant ecology

Abstract

General circulation models project more intense and frequent droughts over the next century, but many questions remain about how terrestrial ecosystems will respond. Of particular importance, is to understand how drought will alter the species composition of regenerating temperate forests wherein symbiotic dinitrogen (N2)-fixing plants play a critical role. In experimental mesocosms we manipulated soil moisture to study the effect of drought on the physiology, growth and competitive interactions of four co-occurring North American tree species, one of which (Robinia pseudoacacia) is a symbiotic N2-fixer. We hypothesized that drought would reduce growth by decreasing stomatal conductance, hydraulic conductance and increasing the water use efficiency of species with larger diameter xylem vessel elements (Quercus rubra, R. pseudoacacia) relative to those with smaller elements (Acer rubrum and Liriodendron tulipifera). We further hypothesized that N2 fixation by R. pseudoacacia would decline with drought, reducing its competitive ability. Under drought, growth declined across all species; but, growth and physiological responses did not correspond to species' hydraulic architecture. Drought triggered an 80% increase in nodule biomass and N accrual for R. pseudoacacia, improving its growth relative to other species. These results suggest that drought intensified soil N deficiency and that R. pseudoacacia's ability to fix N2 facilitated competition with non-fixing species when both water and N were limiting. Under scenarios of moderate drought, N2 fixation may alleviate the N constraints resulting from low soil moisture and improve competitive ability of N2-fixing species, and as a result, supply more new N to the ecosystem.

Published

2013