Your search keyword '"Nina Wurzburger"' showing total 26 results

1. Exploring the Role of Cryptic Nitrogen Fixers in Terrestrial Ecosystems: A Frontier in Nitrogen Cycling Research

Author

Cory C. Cleveland, Carla R. G. Reis, Steven S. Perakis, Katherine A. Dynarski, Sarah A. Batterman, Timothy E. Crews, Maga Gei, Michael J. Gundale, Duncan N. L. Menge, Mark B. Peoples, Sasha C. Reed, Verity G. Salmon, Fiona M. Soper, Benton N. Taylor, Monica G. Turner, and Nina Wurzburger

Subjects

Ecology, Environmental Chemistry, Ecology, Evolution, Behavior and Systematics

Published

2022

2. Differences in soil organic matter between <scp>EcM</scp> ‐ and <scp>AM</scp> ‐dominated forests depend on tree and fungal identity

Author

Caitlin E. Hicks Pries, Richard Lankau, Grace Anne Ingham, Eva Legge, Owen Krol, Jodi Forrester, Amelia Fitch, and Nina Wurzburger

Subjects

Ecology, Evolution, Behavior and Systematics

Abstract

As global change shifts the species composition of forests, we need to understand which species characteristics affect soil organic matter cycling to predict future soil carbon (C) storage. Recently, whether a tree species forms a symbiosis with arbuscular (AM) versus ectomycorrhizal (EcM) fungi has been suggested as a strong predictor of soil carbon storage, but there is wide variability within EcM systems. In this study, we investigated how mycorrhizal associations and the species composition of canopy trees and mycorrhizal fungi relate to the proportion of soil C and nitrogen (N) in mineral-associations and soil C:N across four sites representing distinct climates and tree communities in the Eastern U.S. broadleaf forest biome. In two of our sites, we found the expected relationship of declining mineral-associated C and N and increasing soil C:N ratios as the basal area of EcM-associating trees increased. However, across all sites these soil properties strongly correlated with canopy tree and fungal species composition. Sites where the expected pattern with EcM basal area was observed were 1) dominated by trees with lower quality litter in the Pinaceae and Fagaceae families and 2) dominated by EcM fungi with medium distance exploration type hyphae, melanized tissues, and the potential to produce peroxidases. This observational study demonstrates that differences in soil organic matter between AM andEcM systems are dependent on the taxa of trees and EcM fungi involved. Important information is lost when the rich mycorrhizal symbiosis is reduced to two categories. This article is protected by copyright. All rights reserved.

Published

2023

3. A framework for scaling symbiotic nitrogen fixation using the most widespread nitrogen fixer in eastern deciduous forests of the United States

Author

Jessie I. Motes, Chelcy Ford Miniat, and Nina Wurzburger

Subjects

Nitrogen deposition, Ecology, chemistry.chemical_element, Biogeochemistry, Global change, Plant Science, Nitrogen, Deciduous, chemistry, Nitrogen fixation, Environmental science, Land use, land-use change and forestry, Ecosystem ecology, Ecology, Evolution, Behavior and Systematics

Published

2021

4. Benefit or Liability? The Ectomycorrhizal Association May Undermine Tree Adaptations to Fire After Long-term Fire Exclusion

Author

E. Louise Loudermilk, J. Kevin Hiers, Joseph J. O'Brien, Melanie K. Taylor, Mac A. Callaham, Nina Wurzburger, and Dana O. Carpenter

Subjects

0106 biological sciences, Biomass (ecology), 010504 meteorology & atmospheric sciences, Ecology, Resistance (ecology), Crown (botany), 010603 evolutionary biology, 01 natural sciences, Disturbance (ecology), Abundance (ecology), Litter, Environmental Chemistry, Environmental science, Ecosystem, Relative species abundance, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Long-term fire exclusion may weaken ecosystem resistance to the return of fire. We investigated how a surface wildfire that occurred after several decades of fire exclusion affected a southern Appalachian forest transitioning from a fire-adapted to a fire-intolerant state. Tree traits associated with fire adaptation often co-occur with traits for nutrient conservation, including the ectomycorrhizal (ECM) association. In the absence of fire, the ECM association may facilitate the accumulation of organic matter, which becomes colonized by fine roots that then become vulnerable to consumption or damage by fire. Therefore, a deeper organic horizon might make stands of fire-adapted, ECM trees less resistant to a surface wildfire than stands of arbuscular mycorrhizal (AM), fire-intolerant trees. To test this hypothesis, we established plots in stands that fall along a gradient of mycorrhizal tree relative abundance both inside and outside the perimeter of the 2016 Rock Mountain wildfire. With increasing relative abundance of ECM trees, we found increasing organic horizon depth and mass and slower rates of decay, even for litter of ECM tree species. We calculated a major (73–83%) reduction in fine root biomass and length in the organic horizon following the wildfire. Over three years post-fire, we observed a higher probability of crown decline, basal sprouting and aboveground biomass mortality with increasing abundance of ECM trees. We propose that the biogeochemistry of mycorrhizal associations can help explain why fire exclusion makes stands of fire-adapted trees less resistant to a surface wildfire than those with fire-intolerant trees.

Published

2020

5. Comparison of decay rates between native and non-native wood species in invaded forests of the southeastern U.S.: a rapid assessment

Author

Amy E. Zanne, Cavell Brownie, Michael D. Ulyshen, Nina Wurzburger, Scott Horn, and Michael S. Strickland

Subjects

0106 biological sciences, Ecology, biology, ved/biology, 010604 marine biology & hydrobiology, ved/biology.organism_classification_rank.species, Context (language use), Introduced species, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Novel ecosystem, Shrub, Invasive species, Microstegium, Microstegium vimineum, Ligustrum sinense, Ecology, Evolution, Behavior and Systematics

Abstract

Invasive plants have the potential to affect decomposition both directly, by introducing novel substrates that may differ from native species in key structural or chemical properties, and indirectly through changes to soil properties and microbial communities. The relative importance of these two mechanisms is unclear, especially with regard to wood decomposition. To explore these questions, we used a novel method to rapidly assess the wood decay rates of 11 native and 11 invasive non-native angiosperm species. The study was repeated at three pairs of sites, each consisting of an invaded and a relatively uninvaded forest. The invaded sites had either been colonized by a non-native grass (Microstegium vimineum (Trin.) A. Camus), a non-native woody shrub (Ligustrum sinense Lour.) or by multiple invasive species. After one year in the field, mass loss varied more than two-fold among the 22 wood species (24.2–52.3%). Wood origin (i.e., native or non-native) was only important at the Microstegium sites, with non-native species decomposing marginally faster than native species. Wood decomposed faster at both the Ligustrum-invaded and multiply-invaded sites than in their respective uninvaded sites but there were no differences between sites invaded or not by Microstegium. We detected positive relationships overall between mass loss and pH, K, P and NO3−, but invasion had no consistent effects on these soil properties. The results from this study show that the differences in wood decay rates between native and non-native species and the effects of invasion are highly idiosyncratic, with effects depending greatly on species and ecological context.

Published

2020

6. Elevated rates of heterotrophic respiration in shrub-conditioned arctic tundra soils

Author

Nina Wurzburger and Carly A. Phillips

Subjects

0106 biological sciences, Betula nana, biology, ved/biology, ved/biology.organism_classification_rank.species, food and beverages, Soil Science, Soil classification, 04 agricultural and veterinary sciences, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Shrub, Tundra, Soil respiration, Nutrient, Agronomy, Soil water, 040103 agronomy & agriculture, Litter, 0401 agriculture, forestry, and fisheries, Environmental science, Ecology, Evolution, Behavior and Systematics

Abstract

The response of arctic ecosystems to global change will be critical for future climate, due to their vast stores of carbon. Climate warming appears to be linked to the expansion of shrubs across tundra, but it is unclear how shrubs affect the activity of soil microbes. We investigated three potential mechanisms by which shrubs may stimulate soil microbial activity, by 1) increasing the rate of litter inputs, 2) promoting soil microbial adaptation to litter and 3) reducing nutrient limitation. We created microcosms of root-free soils collected from shrub (Alnus fruticosa, Betula nana, and Salix pulchra) and non-shrub plots in arctic Alaska and conducted two experiments. We quantified heterotrophic soil respiration rates in response to litter inputs (experiment 1), or nutrient inputs (nitrogen, phosphorus, or both nutrients together, experiment 2). We found that shrub-conditioned soils maintained higher rates of soil respiration in both experiments. Shrub litter increased respiration in both soil types, but the relative response was greater in non-shrub soils. We found no evidence that shrubs reduce nutrient limitation to heterotrophic respiration, although we observed a short-term increase in respiration after phosphorus addition in both soil types. Collectively, our results suggest that higher rates of respiration in shrub-conditioned soils may be the result of higher litter input rates, but other factors such as organic matter quality or microbial community structure may also contribute to our observed differences in respiration.

Published

2019

7. Plant–soil feedbacks and the introduction of Castanea (chestnut) hybrids to eastern North American forests

Author

Erin M. Coughlin, Richard P. Shefferson, Stacy L. Clark, and Nina Wurzburger

Subjects

Ecology, Soil biology, Niche, Castanea dentata, Sowing, Species diversity, Native plant, Biology, food.food, food, Ecology, Evolution, Behavior and Systematics, Species reintroduction, Nature and Landscape Conservation, Hybrid

Abstract

The reintroduction of disease‐resistant hybrids is a commonly proposed solution to the introduction of pathogens and pests that weaken or eliminate native plant species. Plant interactions with soil biota result in plant–soil feedbacks (PSFs), which have consequences for individual plant growth and survival as well as broader community‐level processes, such as species diversity and coexistence. Because of their importance, species reintroduction should consider these interactions, yet little work has integrated this perspective. Here, we investigate the effects of hybrid Castanea (chestnut) reintroduction on PSFs and how these mechanisms may influence the recruitment of other species in contemporary forests. We also examine how blight‐resistant Castanea hybrids perform in the soil conditions of contemporary forests and we compare their belowground interactions with those of Castanea dentata. We conducted a reciprocal greenhouse experiment testing the effect of species‐specific soil inoculum on the growth and survival of C. dentata, Castanea hybrids, and other forest dominants. Our results suggest that C. dentata and hybrids had similar belowground interactions and were regulated by negative PSFs, meaning soil microbial communities reduced conspecific growth and survival. These negative PSFs may involve the presence of the non‐native pathogen Phytophthera cinnamomi. Soil inoculum of C. dentata and Castanea hybrids had similar effects on heterospecific growth, suggesting Castanea restoration will have neutral effects on natural regeneration in restoration plantings. We conclude that Castanea hybrids may fill a similar belowground niche to their parent species, and that site selection, screening for soil pathogens, and site planting density will be important to restoration.

Published

2021

8. Relationships between plant diversity and soil microbial diversity vary across taxonomic groups and spatial scales

Author

Kai Zhu, Nina Wurzburger, Lan Liu, and Jian Zhang

Subjects

spatial scale, above–belowground interactions, Ecology, regional effect, Microbial diversity, Biodiversity, Biology, lcsh:QH540-549.5, Spatial ecology, Taxonomic rank, lcsh:Ecology, microbial biogeography, Ecology, Evolution, Behavior and Systematics, Plant diversity, biodiversity

Abstract

Plant diversity has long been assumed to predict soil microbial diversity. However, contradictory results have been found when examining their relationships, particularly at broad spatial scales. To address this issue, we conducted a meta‐analysis to evaluate the patterns in the correlation between plant diversity and soil microbial diversity and the underlying factors driving the relationship. We collected correlation data from 84 studies covering more than 3900 natural terrestrial samples globally. Using the hierarchical mixed‐effects model, we investigated factors including targeted taxonomic group, microbial examination method, sampling extent, biome type, soil type, and environmental factors to assess the patterns of the plant–microbial correlation and the determinants of their variations. We found that microbial richness displayed a modest but positive correlation with plant diversity (r = 0.333, CI = 0.220–0.437). In spite of variability among taxonomic groups and their relationship with plant diversity, positive correlations were more pronounced in the intermediate sampling extent of latitude and elevation coverage, and tropical forests. Among examined environmental factors, soil pH was negatively associated with the plant and soil microbial relationships at large spatial scales. The plant–microbial correlation appears more sensitive to edaphic factor variation in the poor nutrients and soil less compact systems. Collectively, our results point to key differences across taxonomic groups, spatial scales and biomes, and the modulating effects of climate and soil. The findings shed light on our deep understanding in plant–microbial diversity relationships at broad spatial scales and ecosystem sensitivity to biodiversity loss and environmental change.

Published

2020

9. 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

10. From mycorrhizal fungal traits to ecosystem properties – and back again

Author

Karina E. Clemmensen and Nina Wurzburger

Subjects

0106 biological sciences, Ecology, Global change, Plant Science, Biology, Carbon sequestration, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Ecosystem, Mycorrhiza, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany

Published

2018

11. Association of ectomycorrhizal trees with high carbon-to-nitrogen ratio soils across temperate forests is driven by smaller nitrogen not larger carbon stocks

Author

Kai Zhu, J. Franklin Egan, Richard A. Lankau, Nina Wurzburger, and M. Luke McCormack

Subjects

0106 biological sciences, Ecology, Biogeography, chemistry.chemical_element, Plant Science, Soil carbon, 010603 evolutionary biology, 01 natural sciences, Nitrogen, High carbon, Carbon cycle, chemistry, Agronomy, Soil water, Environmental science, Temperate rainforest, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany

Published

2018

12. Experimental evidence that mycorrhizal nitrogen strategies affect soil carbon

Author

Nina Wurzburger and E. N. Jack Brookshire

Subjects

0106 biological sciences, Nitrogen, Plant Roots, complex mixtures, 010603 evolutionary biology, 01 natural sciences, Decomposer, Mesocosm, Soil, Mycorrhizae, Organic matter, Soil Microbiology, Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, biology, Chemistry, Ecology, Soil organic matter, fungi, food and beverages, 04 agricultural and veterinary sciences, Soil carbon, biology.organism_classification, Carbon, Agronomy, Seedling, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Soil microbiology

Abstract

Most land plants acquire nitrogen (N) through associations with arbuscular (AM) and ectomycorrhizal (ECM) fungi, but these symbionts employ contrasting strategies for N acquisition, which may lead to different stocks of soil carbon (C). We experimentally test this hypothesis with a mesocosm system where AM and ECM tree seedling roots, or their hyphae only, could access mineral soils with 13 C- and 15 N-enriched organic matter. We quantified loss of soil C and N, plant uptake of N and new inputs of plant C to soil. We found that AM, but not ECM, seedlings reduced soil C relative to controls. Soil C loss was greater in the presence of roots relative to hyphae only for both AM and ECM seedlings, but was correlated with plant N uptake for AM seedlings only. While new plant C inputs stimulated soil C loss in both symbioses, we detected plant C inputs more frequently and measured higher rates of decomposer activity in soils colonized by AM relative to ECM seedlings. Our study experimentally demonstrates how mycorrhizal strategies for N can affect soil C and C:N, even at the scale of an individual plant. Such effects may contribute to broad patterns in soil C across terrestrial ecosystems.

Published

2017

13. Drought sensitivity of an N 2 ‐fixing tree may slow temperate deciduous forest recovery from disturbance

Author

Jeffrey M. Minucci, Nina Wurzburger, and Chelcy Ford Miniat

Subjects

0106 biological sciences, Biomass (ecology), Ecology, 010604 marine biology & hydrobiology, Growing season, Temperate deciduous forest, 010603 evolutionary biology, 01 natural sciences, Deciduous, Productivity (ecology), Agronomy, Environmental science, Ecosystem, Terrestrial ecosystem, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics

Abstract

Increased drought intensity and frequency due to climate change may reduce the abundance and activity of nitrogen (N2 )-fixing plants, which supply new N to terrestrial ecosystems. As a result, drought may indirectly reduce ecosystem productivity through its effect on the N cycle. Here, we manipulated growing season net rainfall across a series of plots in an early successional mesic deciduous forest to understand how drought affects the aboveground productivity of the N2 -fixing tree Robinia pseudoacacia and three co-occurring nonfixing tree species. We found that lower soil moisture was associated with reduced productivity of R. pseudoacacia but not of nonfixing trees. As a result, the relative biomass and density of R. pseudoacacia declined in drier soils over time. Greater aboveground biomass of R. pseudoacacia was also associated with greater total soil N, extractable inorganic N, N mineralization rates, and productivity of nonfixing trees. These soil N effects may reflect current N2 fixation by R. pseudoacacia saplings, or the legacy effect of former trees in the same location. Our results suggest that R. pseudoacacia promotes the growth of nonfixing trees in early succession through its effect on the N cycle. However, the sensitivity of R. pseudoacacia to dry soils may reduce N2 fixation under scenarios of increasing drought intensity and frequency, demonstrating a mechanism by which drought may indirectly diminish potential forest productivity and recovery rate from disturbance.

Published

2019

14. Nitrogen fixation does not balance fire-induced nitrogen losses in longleaf pine savannas

Author

Lars O. Hedin, Nina Wurzburger, and Julie A. Tierney

Subjects

0106 biological sciences, Nitrogen balance, Plant growth, Ecology, Nitrogen, 010604 marine biology & hydrobiology, chemistry.chemical_element, Herbaceous plant, 010603 evolutionary biology, 01 natural sciences, Grassland, Fires, Soil, chemistry, Nitrogen Fixation, Nitrogen fixation, Temperate climate, Environmental science, Ecosystem, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics

Abstract

Fire is a critical force in structuring ecosystems, but it also removes substantial amounts of nitrogen (N), which can limit plant growth. Biological N fixation (BNF) may alleviate fire-induced N deficiencies that inhibit ecosystem recovery, yet if and how BNF achieves this under frequent fire is unclear. This problem is further complicated in the context of modern human influences (such as land-use history and atmospheric N deposition), which may confound the relationship between fire and fixation. Here, we investigate whether BNF supplies the N necessary to replace fire-induced N losses in restored longleaf pine savannas, and, if so, what factors control fixation. We established 54 1-ha plots of longleaf pine capturing 227 yr of forest recovery and a broad gradient of fire return interval (1.5-20 yr) at two sites in the southeastern United States. We quantified N fixation from three functional groups (herbaceous legumes, soil crusts, and asymbiotic N fixing bacteria), N losses from individual fire events and ecosystem dynamics of N supply and demand. We found that BNF rates were low but sustained over stand age but were substantially below estimated rates of atmospheric N deposition. While fire temporarily stimulated BNF from herbaceous legumes, neither BNF nor atmospheric N deposition were sufficient to balance N losses from fire and soil N stocks declined over stand age. However, rates of N mineralization were surprisingly high and tree productivity was unrelated to N availability, questioning the importance of N limitation in these temperate savannas. While it is possible that progressive N losses signal a decline in ecosystem resiliency, N enrichment from multiple land-use transitions and anthropogenic N deposition may suppress rates of BNF or diminish its importance as a long-term N balancing source in these pyrogenic ecosystems. In this case, fire may be acting as relief mechanism, critical for returning the modern longleaf pine landscape to its historical oligotrophic condition.

Published

2018

15. Corrigendum for Wurzburger and Hedin (2016)

Author

Nina Wurzburger and Lars O. Hedin

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Ecology, 010604 marine biology & hydrobiology, Published Erratum, MEDLINE, Library science, Environmental science, 01 natural sciences, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Published

2016

16. 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

17. Fine-root responses to fertilization reveal multiple nutrient limitation in a lowland tropical forest

Author

S. Joseph Wright and Nina Wurzburger

Subjects

Tropical Climate, Biomass (ecology), Nitrogen, Panama, Ecology, Phosphorus, Plant Development, chemistry.chemical_element, Rainforest, Forests, Biology, Plant Roots, Human fertilization, Nutrient, chemistry, Agronomy, Mycorrhizae, Tropical climate, Potassium, Litter, Fertilizers, Soil microbiology, Soil Microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

Questions remain as to which soil nutrients limit primary production in tropical forests. Phosphorus (P) has long been considered the primary limiting element in lowland forests, but recent evidence demonstrates substantial heterogeneity in response to nutrient addition, highlighting a need to understand and diagnose nutrient limitation across diverse forests. Fine-root characteristics including their abundance, functional traits, and mycorrhizal symbionts can be highly responsive to changes in soil nutrients and may help to diagnose nutrient limitation. Here, we document the response of fine roots to long-term nitrogen (N), P, and potassium (K) fertilization in a lowland forest in Panama. Because this experiment has demonstrated that N and K together limit tree growth and P limits fine litter production, we hypothesized that fine roots would also respond to nutrient addition. Specifically we hypothesized that N, P, and K addition would reduce the biomass, diameter, tissue density, and mycorrhizal colonization of fine roots, and increase nutrient concentration in root tissue. Most morphological root traits responded to the single addition of K and the paired addition of N and P, with the greatest response to all three nutrients combined. The addition of N, P, and K together reduced fine-root biomass, length, and tissue density, and increased specific root length, whereas root diameter remained unchanged. Nitrogen addition did not alter root N concentration, but P and K addition increased root P and K concentration, respectively. Mycorrhizal colonization of fine roots declined with N, increased with P, and was unresponsive to K addition. Although plant species composition remains unchanged after 14 years of fertilization, fine-root characteristics responded to N, P, and K addition, providing some of the strongest stand-level responses in this experiment. Multiple soil nutrients regulate fine-root abundance, morphological and chemical traits, and their association with mycorrhizal fungi in a species-rich lowland tropical forest.

Published

2015

18. Nitrogen and phosphorus interact to control tropical symbiotic N2fixation: a test inInga punctata

Author

Sarah A. Batterman, Nina Wurzburger, and Lars O. Hedin

Subjects

Biomass (ecology), Biogeochemical cycle, Facultative, Ecology, Phosphorus, chemistry.chemical_element, Plant Science, Biology, Fixation (population genetics), Nutrient, Symbiosis, Agronomy, chemistry, Terrestrial ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

Summary Symbiotic di-nitrogen (N2) fixation is a critical biogeochemical process in tropical forests, yet it remains unresolved how fixation is controlled by the availability of soil nitrogen and phosphorus, two nutrients often considered limiting in terrestrial ecosystems. We examine whether individual N2-fixing trees can overcome nitrogen and phosphorus constraints by employing different strategies of nutrient acquisition and use: N2 fixation, phosphatase exudation, mycorrhizal symbiosis and changes in root–shoot ratio or tissue stoichiometry. We grew a common and widespread N2 fixer, Inga punctata, in a full factorial nitrogen and phosphorus addition experiment (each nutrient at three levels) and evaluated whether trees adjusted their strategies of nutrient acquisition to overcome limitation. N2 fixation was controlled by nitrogen availability in phosphorus-sufficient soils, but both fixation and plant growth were constrained by phosphorus in the unamended native phosphorus-poor soils. Despite the investment in both extracellular phosphatases and mycorrhizal symbionts, plants were unable to overcome phosphorus limitation. Our findings support the hypotheses that: (i) N2 fixation is proximately controlled by nitrogen availability, consistent with a facultative fixation strategy, and (ii) N2 fixation and N2 fixer biomass growth are ultimately constrained by soil phosphorus. We found no support for the hypothesis that fixers can overcome phosphorus limitation by trading fixed N2 for soil phosphorus. Synthesis. This study provides new knowledge about how nitrogen and phosphorus interact to regulate tropical N2 fixation by examining a suite of strategies that plants may employ to overcome nutrient limitation. These findings, focused at the organismal level, have broader implications for biogeochemical controls at the ecosystem level in tropical forests.

Published

2013

19. Ericoid mycorrhizal root fungi and their multicopper oxidases from a temperate forest shrub

Author

Brian P. Higgins, Nina Wurzburger, and Ronald L. Hendrick

Subjects

Chaetothyriales, Nutrient cycle, Genetic diversity, Ecology, biology, Host (biology), Sebacinales, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Helotiales, Botany, Internal transcribed spacer, Ribosomal DNA, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Ericoid mycorrhizal fungi (ERM) may specialize in capturing nutrients from their host's litter as a strategy for regulating nutrient cycles in terrestrial ecosystems. In spite of their potential significance, we know little about the structure of ERM fungal communities and the genetic basis of their saprotrophic traits (e.g., genes encoding extracellular enzymes). Rhododendron maximum is a model ERM understory shrub that influences the nutrient cycles of montane hardwood forests in the southern Appalachians (North Carolina, USA). We sampled ERM roots of R. maximum from organic and mineral soil horizons and identified root fungi by amplifying and sequencing internal transcribed spacer (ITS) ribosomal DNA (rDNA) collected from cultures and clones. We observed 71 fungal taxa on ERM roots, including known symbionts Rhizoscyphus ericae and Oidiodendron maius, putative symbionts from the Helotiales, Chaetothyriales, and Sebacinales, ectomycorrhizal symbionts, and saprotrophs. Supporting the idea that ERM fungi are adept saprotrophs, richness of root-fungi was greater in organic than in mineral soil horizons. To study the genetic diversity of oxidative enzymes that contribute to decomposition, we amplified and sequenced a portion of genes encoding multicopper oxidases (MCOs) from ERM ascomycetes. Most fungi possessed multiple copies of MCO sequences with strong similarities to known ferroxidases and laccases. Our findings indicate that R. maximum associates with a taxonomically and ecologically diverse fungal community. The study of MCO gene diversity and expression may be useful for understanding how ERM root fungi regulate the cycling of nutrients between the host plant and the soil environment.

Published

2011

20. Plant litter chemistry and mycorrhizal roots promote a nitrogen feedback in a temperate forest

Author

Ronald L. Hendrick and Nina Wurzburger

Subjects

Ecology, Soil organic matter, Plant Science, Microsite, Biology, Plant litter, biology.organism_classification, Ericaceae, Botany, Litter, Mycorrhiza, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, Woody plant

Abstract

Summary 1. Relationships between mycorrhizal plants and soil nitrogen (N) have led to the speculation that the chemistry of plant litter and the saprotrophy of mycorrhizal symbionts can function together to closely couple the N cycle between plants and soils. We hypothesized that a tannin-rich, ericoid mycorrhizal (ERM) plant promotes the retention of protein‐tannin N in soil, and that this N source is accessible to saprotrophic ERM symbionts and their hosts, but remains less available to co-occurring ectomycorrhizal (ECM) and arbuscular mycorrhizal (AM) symbionts and their hosts. 2. We tested this feedback hypothesis in a southern Appalachian forest community composed of two microsites: a hardwood microsite with ECM and AM trees in the overstorey and understorey, and an AM herb layer; and a rhododendron microsite where the understorey and herb layer are replaced by ERM rhododendron. We synthesized 15 N-enriched protein‐tannin complexes from leaf litter extracts representing each forest microsite and examined the fate of 15 N in soil volumes 3 months and 1 year after the complexes were placed in the field. 3. Protein‐tannin complexes derived from the rhododendron microsite led to a higher retention of 15 N in soil organic matter and a lower recovery in dissolved N pools than those from the hardwood microsite, supporting the hypothesis that rhododendron tannins create stable complexes that increase organic N retention in soils. 4. Rhododendron complexes led to greater 15 N-enrichment in ERM roots than in AM and ECM roots, supporting the hypothesis that rhododendron can better access the N complexed by its own litter tannins than can co-occurring forest trees and plants. Our results suggest that both fungal saprotrophy and a high specific root length contribute to the ability of ERM roots to acquire N from complex organic sources. 5. Synthesis. This study provides evidence of an intricate N feedback where plant litter chemistry influences the cycle of N to maximize N acquisition by the host’s mycorrhizal roots, while hindering N acquisition by mycorrhizal roots of co-occurring plants. Feedback processes such as these have the potential to drive patterns in nitrogen cycling and productivity in many terrestrial ecosystems.

Published

2009

21. Hemlock Declines Rapidly with Hemlock Woolly Adelgid Infestation: Impacts on the Carbon Cycle of Southern Appalachian Forests

Author

Ronald L. Hendrick, Chelcy R. Ford, April E. Nuckolls, Brian D. Kloeppel, Nina Wurzburger, and James M. Vose

Subjects

Biomass (ecology), Ecology, biology, biology.organism_classification, medicine.disease_cause, Invasive species, Basal area, Soil respiration, Agronomy, Girdling, Infestation, medicine, Environmental Chemistry, Adelgidae, Hemlock woolly adelgid, Ecology, Evolution, Behavior and Systematics

Abstract

The recent infestation of southern Appalachian eastern hemlock stands by hemlock woolly adelgid (HWA) is expected to have dramatic and lasting effects on forest structure and function. We studied the short-term changes to the carbon cycle in a mixed stand of hemlock and hardwoods, where hemlock was declining due to either girdling or HWA infestation. We expected that hemlock would decline more rapidly from girdling than from HWA infestation. Unexpectedly, in response to both girdling and HWA infestation, hemlock basal area increment (BAI) reduced substantially compared to reference hardwoods in 3 years. This decline was concurrent with moderate increases in the BAI of co-occurring hardwoods. Although the girdling treatment resulted in an initial pulse of hemlock needle inputs, cumulative litter inputs and O horizon mass did not differ between treatments over the study period. Following girdling and HWA infestation, very fine root biomass declined by 20–40% in 2 years, which suggests hemlock root mortality in the girdling treatment, and a reduction in hemlock root production in the HWA treatment. Soil CO2 efflux (Esoil) declined by approximately 20% in 1 year after both girdling and HWA infestation, even after accounting for the intra-annual variability of soil temperature and moisture. The reduction in Esoil and the concurrent declines in BAI and standing very fine root biomass suggest rapid declines in hemlock productivity from HWA infestation. The accelerated inputs of detritus resulting from hemlock mortality are likely to influence carbon and nutrient fluxes, and dictate future patterns of species regeneration in these forest ecosystems.

Published

2008

22. Rhododendron thickets alter N cycling and soil extracellular enzyme activities in southern Appalachian hardwood forests

Author

Ronald L. Hendrick and Nina Wurzburger

Subjects

biology, ved/biology, Soil organic matter, ved/biology.organism_classification_rank.species, food and beverages, Soil Science, Growing season, Understory, Plant litter, biology.organism_classification, Shrub, Agronomy, Botany, Ericoid mycorrhiza, Hardwood, Litter, Ecology, Evolution, Behavior and Systematics

Abstract

Summary Rhododendron maximum L., a spreading understory shrub, inhibits overstory regeneration and alters forest community structure in southern Appalachian hardwood forests. Using paired plots and reciprocal litter transplants in forests with and without R. maximum cover, we examined the influence of R. maximum on litter mass and quality, N cycling and soil extracellular enzymes. Standing stocks of soil organic matter, soil N, leaf litter mass and fine root biomass were greater in forests with R. maximum than those without. Tannin extracts from R. maximum foliage, and leaf litter and fine roots collected under R. maximum had a relatively high capacity to precipitate protein compared to extracts from trees. Across the growing season, soil inorganic N availability was generally lower under R. maximum , mostly due to reduced NO 3 − availability. Our data suggest that R. maximum litter alters N cycling through the formation of recalcitrant polyphenol–organic N complexes. Soil extracellular enzymes indicate the potential processing rates of organic substrates. Between forest types, polyphenol oxidase activity was greatest in R. maximum O horizons, regardless of litter type, suggesting that the local microbial community can better degrade and access protein–tannin-complexed N. Protease activity did not differ between forest types, but was greater on R. maximum leaf litter than hardwood leaf litter. The alteration of the N cycle via the formation of polyphenol–organic N complexes may contribute to hardwood seedling suppression, while the enzymatic release of these complexes by ericoid mycorrhizal fungi may increase N acquisition for R. maximum and contribute to its expansion in southern Appalachian forests.

Published

2007

23. Taxonomic identity determines N2 fixation by canopy trees across lowland tropical forests

Author

Lars O. Hedin and Nina Wurzburger

Subjects

0106 biological sciences, Canopy, Nitrogen, Biome, Biodiversity, Biology, Forests, 010603 evolutionary biology, 01 natural sciences, Trees, Soil, Phylogenetics, Mycorrhizae, Nitrogen Fixation, Tropical climate, Ecology, Evolution, Behavior and Systematics, Phylogeny, Molybdenum, Tropical Climate, Ecology, Fabaceae, Phosphorus, Nitrogen fixation, Taxonomy (biology), 010606 plant biology & botany

Abstract

Legumes capable of fixing atmospheric N2 are abundant and diverse in many tropical forests, but the factors determining ecological patterns in fixation are unresolved. A long-standing idea is that fixation depends on soil nutrients (N, P or Mo), but recent evidence shows that fixation may also differ among N2-fixing species. We sampled canopy-height trees across five species and one species group of N2-fixers along a landscape P gradient, and manipulated P and Mo to seedlings in a shadehouse. Our results identify taxonomy as the major determinant of fixation, with P (and possibly Mo) only influencing fixation following tree-fall disturbances. While 44% of trees did not fix N2, other trees fixed at high rates, with two species functioning as superfixers across the landscape. Our results raise the possibility that fixation is determined by biodiversity, evolutionary history and species-specific traits (tree growth rate, canopy stature and response to disturbance) in the tropical biome.

Published

2015

24. 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

25. Potassium, phosphorus, or nitrogen limit root allocation, tree growth, or litter production in a lowland tropical forest

Author

Louis S. Santiago, Kyle E. Harms, Edmund V. J. Tanner, Milton N. Garcia, Nina Wurzburger, Emma J. Sayer, Benjamin L. Turner, Michael Kaspari, S. Joseph Wright, Joseph B. Yavitt, Marife D. Corre, and Lars O. Hedin

Subjects

0106 biological sciences, Barro Colorado Nature Monument, 010504 meteorology & atmospheric sciences, Nitrogen, Panama, tree growth, chemistry.chemical_element, fine roots, Biology, 010603 evolutionary biology, 01 natural sciences, Plant Roots, Trees, tropics, Soil, Nutrient, Ecology, Evolution, Behavior and Systematics, Ecosystem, 0105 earth and related environmental sciences, 2. Zero hunger, Biomass (ecology), Tropical Climate, nutrient limitation, Evolutionary Biology, fine litter, Ecology, Phosphorus, potassium, Diameter at breast height, Tropics, food and beverages, 15. Life on land, chemistry, fertilization, Ecological Applications, Litter, Potassium, Soil fertility

Abstract

We maintained a factorial nitrogen (N), phosphorus (P), and potassium (K) addition experiment for 11 years in a humid lowland forest growing on a relatively fertile soil in Panama to evaluate potential nutrient limitation of tree growth rates, fine-litter production, and fine-root biomass. We replicated the eight factorial treatments four times using 32 plots of 40×40 m each. The addition of K was associated with significant decreases in stand-level fineroot biomass and, in a companion study of seedlings, decreases in allocation to roots and increases in height growth rates. The addition of K and N together was associated with significant increases in growth rates of saplings and poles (1-10 cm in diameter at breast height) and a further marginally significant decrease in stand-level fine-root biomass. The addition of P was associated with a marginally significant (P = 0.058) increase in fine-litter production that was consistent across all litter fractions. Our experiment provides evidence that N, P, and K all limit forest plants growing on a relatively fertile soil in the lowland tropics, with the strongest evidence for limitation by K among seedlings, saplings, and poles. © 2011 by the Ecological Society of America.

Published

2011

26. Ectomycorrhizal fungal community structure across a bog-forest ecotone in southeastern Alaska

Author

Nina Wurzburger, Ronald L. Hendrick, and Anthony S. Hartshorn

Subjects

Pinus contorta, Plant Science, Biology, Plant Roots, Trees, Tsuga, Cenococcum geophilum, Mycorrhizae, Botany, Genetics, Molecular Biology, Bog, Ecology, Evolution, Behavior and Systematics, Ecosystem, geography, geography.geographical_feature_category, Ecology, fungi, Plant community, General Medicine, Ecotone, Biodiversity, biology.organism_classification, Western Hemlock, Species richness, Alaska

Abstract

We examined the ectomycorrhizal (ECM) fungal community across a bog-forest ecotone in southeastern Alaska. The bog and edge were both characterized by poorly drained Histosols and a continuous layer of Sphagnum species, ericaceous shrubs, Carex species, and shore pine [Pinus contorta Dougl. ex Loud. var. contorta]. The forest had better-drained Inceptisols and Spodosols, a tree community comprised of western hemlock [Tsuga heterophylla (Raf.) Sarg.], yellow cedar (Thuja plicata Donn ex D. Don.), Sitka spruce [Picea sitchensis (Bong.) Carr.] and shore pine, and an understorey of ericaceous shrubs and herbs. ECM root tip density (tips cm(-3) soil) was significantly greater in the forest than the edge or bog and ECM colonization was significantly different in all three plant communities. The below ground ECM fungal taxa were analyzed using molecular techniques (PCR-RFLP and DNA sequencing). Three ECM fungal taxa, Suillus tomentosus (Kauffman) Singer, Cenococcum geophilum Fr.:Fr, and a Russula species, differed in relative frequency, yet were among the four most frequent in all three plant communities. Although differences in ECM fungal richness were observed across plant communities, unequal sampling of ECM roots due to root density and colonization differences confounded richness comparisons. Using resampling procedures for creating taxon-accumulation curves as a function of sampled ECM roots revealed similarities in cumulative ECM fungal taxa richness across the ecotone.

Published

2003