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1. Legacy effects of precipitation and land use impact maize growth and microbiome assembly under drought stress

Author

Joel F. Swift, Matthew R. Kolp, Amanda Carmichael, Natalie E. Ford, Paige M. Hansen, Benjamin A. Sikes, Manuel Kleiner, and Maggie R. Wagner

Abstract

As the climate changes, plants and their associated microbiomes face greater water limitation and increased frequency of drought. Historical precipitation patterns can leave a legacy effect on soil and root-associated microbiomes, but the impact of this conditioning on future drought performance is poorly understood. Moreover, agricultural practices, like tilling and fertilization, may override precipitation legacies in natural systems. Precipitation gradients provide a means to assess these legacy effects. We collected six soil microbiomes across a Kansas precipitation gradient from both agricultural fields and native prairies. Seedlings of twoZea maysgenotypes were inoculated with each soil microbiome in a factorial drought experiment. Droughted plants exhibited decreased shoot mass accumulation rates and greater root mass relative to shoot mass. Restructuring of the bacterial root-associated microbiome was apparent, with depletion observed in Pseudomonadota and enrichment in Actinomycetota, while the fungal microbiome was largely unaffected by drought. A historical precipitation legacy effect on soil microbiomes interacted with plants during drought treatment, but only among prairie soils. Prairie soils from historically wetter locations increased maize shoot biomass under drought more so than agricultural or historically drier prairie soils. We demonstrate links between legacy effects and drought performance, suggesting that future drying climates may condition soils to negatively impact plant performance.

Published
2023
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3. Substrate and low intensity fires influence bacterial communities in longleaf pine savanna

Author

Viet Q. Dao, Stephen E. Potts, Crystal N. Johnson, Benjamin A. Sikes, and William J. Platt

Subjects
Multidisciplinary
Abstract

Bacterial communities associated with vegetation-soil interfaces have important roles in terrestrial ecosystems. These bacterial communities, studied almost exclusively in unburnt ecosystems or those affected by rare, high-intensity wildfires, have been understudied in fire-frequented grasslands and savannas. The composition of ground-level bacterial communities was explored in an old-growth pine savanna with a centuries-long management history of prescribed fires every 1–2 years. Using 16S metabarcoding, hypotheses were tested regarding differences in bacterial families of litter and soil surface substrates in patches of ground layer vegetation that were naturally burnt or unburnt during landscape-level prescribed fires. Litter/soil substrates and fire/no fire treatments explained 67.5% of bacterial community variation and differences, driven by relative abundance shifts of specific bacterial families. Fires did not strongly affect plant or soil variables, which were not linked to bacterial community differences. Litter/soil substrates and the naturally patchy frequent fires appear to generate microhabitat heterogeneity in this pine savanna, driving responses of bacterial families. Prescribed fire management may benefit from considering how fire-altered substrate heterogeneity influences and maintains microbial diversity and function, especially in these fiery ecosystems. Frequent, low-intensity fires appear ecologically important in maintaining the diverse microbial foundation that underlie ecosystem processes and services in fire-frequented habitats.

Published
2022
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5. Substrate and low intensity fires influence bacterial communities in longleaf pine savanna

Author

Viet Q, Dao, Stephen E, Potts, Crystal N, Johnson, Benjamin A, Sikes, and William J, Platt

Subjects
Soil, Pinus, Grassland, Ecosystem, Fires
Abstract

Bacterial communities associated with vegetation-soil interfaces have important roles in terrestrial ecosystems. These bacterial communities, studied almost exclusively in unburnt ecosystems or those affected by rare, high-intensity wildfires, have been understudied in fire-frequented grasslands and savannas. The composition of ground-level bacterial communities was explored in an old-growth pine savanna with a centuries-long management history of prescribed fires every 1-2 years. Using 16S metabarcoding, hypotheses were tested regarding differences in bacterial families of litter and soil surface substrates in patches of ground layer vegetation that were naturally burnt or unburnt during landscape-level prescribed fires. Litter/soil substrates and fire/no fire treatments explained 67.5% of bacterial community variation and differences, driven by relative abundance shifts of specific bacterial families. Fires did not strongly affect plant or soil variables, which were not linked to bacterial community differences. Litter/soil substrates and the naturally patchy frequent fires appear to generate microhabitat heterogeneity in this pine savanna, driving responses of bacterial families. Prescribed fire management may benefit from considering how fire-altered substrate heterogeneity influences and maintains microbial diversity and function, especially in these fiery ecosystems. Frequent, low-intensity fires appear ecologically important in maintaining the diverse microbial foundation that underlie ecosystem processes and services in fire-frequented habitats.

Published
2022

6. Quantifying ecological variation across jurisdictional boundaries in a management mosaic landscape

Author

Benjamin A. Sikes, Clare E. Aslan, Sam Veloz, Meredith L. McClure, Rebecca S. Epanchin-Niell, Brett G. Dickson, Luke J. Zachmann, and Mark W. Brunson

Subjects
0106 biological sciences, Ecology, National park, 010604 marine biology & hydrobiology, media_common.quotation_subject, Geography, Planning and Development, Land management, Vegetation, 010603 evolutionary biology, 01 natural sciences, Geography, Habitat, Vegetation type, Ecosystem, Landscape ecology, Wilderness, Nature and Landscape Conservation, media_common
Abstract

Large landscapes exhibit natural heterogeneity. Land management can impose additional variation, altering ecosystem patterns. Habitat characteristics may reflect these management factors, potentially resulting in habitat differences that manifest along jurisdictional boundaries. We characterized the patchwork of habitats across a case study landscape, the Grand Canyon Protected Area-Centered Ecosystem. We asked: how do ecological conditions vary across different types of jurisdictional boundaries on public lands? We hypothesized that differences in fire and grazing, because they respond to differences in management over time, contribute to ecological differences by jurisdiction. We collected plot-scale vegetation and soils data along boundaries between public lands units surrounding the Grand Canyon. We compared locations across boundaries of units managed differently, accounting for vegetation type and elevation differences that pre-date management unit designations. We used generalized mixed effects models to evaluate differences in disturbance and ecology across boundaries. Jurisdictions varied in evidence of grazing and fire. After accounting for these differences, some measured vegetation and soil properties also differed among jurisdictions. The greatest differences were between US Forest Service wilderness and Bureau of Land Management units. For most measured variables, US Forest Service non-wilderness units and National Park Service units were intermediate. In this study, several ecological properties tracked jurisdictional boundaries, forming a predictable patchwork of habitats. These patterns likely reflect site differences that pre-date jurisdictions as well as those resulting from different management histories. Understanding how ecosystem differences manifest at jurisdictional boundaries can inform resource management, conservation, and cross-boundary collaborations.

Published
2021
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7. Frequent fire slows microbial decomposition of newly deposited fine fuels in a pyrophilic ecosystem

Author

Jean M. Huffman, William J. Platt, Jacob R. Hopkins, and Benjamin A. Sikes

Subjects
0106 biological sciences, 010604 marine biology & hydrobiology, Soil chemistry, 15. Life on land, Biology, Pinus, Fuel dynamics, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Decomposition, Fires, Soil, Nutrient, Microbial ecology, 13. Climate action, Terrestrial ecosystem, Ecosystem, Fire history, Ecology, Evolution, Behavior and Systematics
Abstract

Frequent fires maintain nearly 50% of terrestrial ecosystems, and drive ecosystem changes that govern future fires. Since fires are dependent on available plant or fine fuels, ecosystem processes that alter fine fuel loads like microbial decomposition are particularly important and could modify future fires. We hypothesized that variation in short-term fire history would influence fuel dynamics in such ecosystems. We predicted that frequent fires within a short-time period would slow microbial decomposition of new fine fuels. We expected that fire effects would differ based on dominant substrates and that fire history would also alter soil nutrient availability, indirectly slowing decomposition. We measured decomposition of newly deposited fine fuels in a Longleaf pine savanna, comparing plots that burned 0, 1, 2, or 3 times between 2014 and 2016, and which were located in either close proximity to or away from overstory pines (Longleaf pine, Pinus palustris). Microbial decomposition was slower in plots near longleaf pines and, as the numbers of fires increased, decomposition slowed. We then used structural equation modeling to assess pathways for these effects (number of fires, 2016 fuel/fire characteristics, and soil chemistry). Increased fire frequency was directly associated with decreased microbial decomposition. While increased fires decreased nutrient availability, changes in nutrients were not associated with decomposition. Our findings indicate that increasing numbers of fires over short-time intervals can slow microbial decomposition of newly deposited fine fuels. This could favor fine fuel accumulation and drive positive feedbacks on future fires.

Published
2020
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8. Fire as a driver of fungal diversity - A synthesis of current knowledge

Author

Sam Fox, Benjamin A. Sikes, Shawn P. Brown, Cathy L. Cripps, Sydney I. Glassman, Karen Hughes, Tatiana Semenova-Nelsen, and Ari Jumpponen

Subjects
Physiology, Genetics, Cell Biology, General Medicine, Plants, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecosystem, Fires, Mycobiome, Wildfires
Abstract

Fires occur in most terrestrial ecosystems where they drive changes in the traits, composition, and diversity of fungal communities. Fires range from rare, stand-replacing wildfires to frequent, prescribed fires used to mimic natural fire regimes. Fire regime factors, including burn severity, fire intensity, and timing, vary widely and likely determine how fungi respond to fires. Despite the importance of fungi to post-fire plant communities and ecosystem functioning, attempts to identify common fungal responses and their major drivers are lacking. This synthesis addresses this knowledge gap and ranges from fire adaptations of specific fungi to succession and assembly fungal communities as they respond to spatially heterogenous burning within the landscape. Fires impact fungi directly and indirectly through their effects on fungal survival, substrate and habitat modifications, changes in environmental conditions, and/or physiological responses of the hosts with which fungi interact. Some specific pyrophilous, or "fire-loving," fungi often appear after fire. Our synthesis explores whether such taxa can be considered cosmopolitan, and whether they are truly fire-adapted or simply opportunists adapted to rapidly occupy substrates and habitats made available by fires. We also discuss the possible inoculum sources of post-fire fungi and explore existing conceptual models and ecological frameworks that may be useful in generalizing fungal fire responses. We conclude with identifying research gaps and areas that may best transform the current knowledge and understanding of fungal responses to fire.

Published
2022

11. Root pathogen diversity and composition varies with climate in undisturbed grasslands, but less so in anthropogenically disturbed grasslands

Author

Alice G. Tipton, Josh L. Schemanski, Benjamin A. Sikes, Geoffrey L. House, James D. Bever, and Camille S. Delavaux

Subjects
0106 biological sciences, Grassland ecology, Climate change, Biology, 010603 evolutionary biology, 01 natural sciences, Microbiology, Article, 03 medical and health sciences, Soil, Precipitation, Fungal ecology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Oomycete, 0303 health sciences, Ecology, Community structure, Fungi, food and beverages, Plant community, Biodiversity, Native plant, Plants, biology.organism_classification, Grassland, Soil microbiology, Disturbance (ecology), Species richness
Abstract

Soil-borne pathogens structure plant communities, shaping their diversity, and through these effects may mediate plant responses to climate change and disturbance. Little is known, however, about the environmental determinants of plant pathogen communities. Therefore, we explored the impact of climate gradients and anthropogenic disturbance on root-associated pathogens in grasslands. We examined the community structure of two pathogenic groups—fungal pathogens and oomycetes—in undisturbed and anthropogenically disturbed grasslands across a natural precipitation and temperature gradient in the Midwestern USA. In undisturbed grasslands, precipitation and temperature gradients were important predictors of pathogen community richness and composition. Oomycete richness increased with precipitation, while fungal pathogen richness depended on an interaction of precipitation and temperature, with precipitation increasing richness most with higher temperatures. Disturbance altered plant pathogen composition and precipitation and temperature had a reduced effect on pathogen richness and composition in disturbed grasslands. Because pathogens can mediate plant community diversity and structure, the sensitivity of pathogens to disturbance and climate suggests that degradation of the pathogen community may mediate loss, or limit restoration of, native plant diversity in disturbed grasslands, and may modify plant community response to climate change.

Published
2020

12. Fungal community structure and seasonal trajectories respond similarly to fire across pyrophilic ecosystems

Author

Tatiana A. Semenova-Nelsen, Jacob R. Hopkins, and Benjamin A. Sikes

Subjects
0106 biological sciences, 0301 basic medicine, Soil nutrients, Climate change, Biology, 010603 evolutionary biology, 01 natural sciences, Applied Microbiology and Biotechnology, Microbiology, Fires, 03 medical and health sciences, Soil, Microbial ecology, Ecosystem, Fire ecology, Ecology, Community structure, 15. Life on land, 030104 developmental biology, Microbial population biology, Disturbance (ecology), 13. Climate action, sense organs, Seasons, Mycobiome
Abstract

Fire alters microbial community composition, and is expected to increase in frequency due to climate change. Testing whether microbes in different ecosystems will respond similarly to increased fire disturbance is difficult though, because fires are often unpredictable and hard to manage. Fire recurrent or pyrophilic ecosystems, however, may be useful models for testing the effects of frequent disturbance on microbes. We hypothesized that across pyrophilic ecosystems, fire would drive similar alterations to fungal communities, including altering seasonal community dynamics. We tested fire's effects on fungal communities in two pyrophilic ecosystems, a longleaf pine savanna and tallgrass prairie. Fire caused similar fungal community shifts, including (i) driving immediate changes that favored taxa able to survive fire and take advantage of post-fire environments and (ii) altering seasonal trajectories due to fire-associated changes to soil nutrient availability. This suggests that fire has predictable effects on fungal community structure and intra-annual community dynamics in pyrophilic ecosystems, and that these changes could significantly alter fungal function. Parallel fire responses in these key microbes may also suggest that recurrent fires drive convergent changes across ecosystems, including less fire-frequented systems that may start burning more often due to climate change.

Published
2020

13. Pine savanna restoration on agricultural landscapes: The path back to native savanna ecosystem services

Author

Michael D. Ulyshen, Cinnamon M. Dixon, Kevin M. Robertson, and Benjamin A. Sikes

Subjects
Environmental Engineering, Chronosequence, Ecological succession, complex mixtures, Fires, Trees, Ecosystem services, Abundance (ecology), Mycorrhizae, parasitic diseases, Animals, Environmental Chemistry, Ecosystem, Waste Management and Disposal, Biomass (ecology), Agroforestry, fungi, food and beverages, Agriculture, Soil carbon, Vegetation, Bees, Pinus, Grassland, Pollution, Environmental science
Abstract

Restoration of savanna ecosystems within their historic range is expected to increase provision of ecosystem services to resident human populations. However, the benefits of restoration depend on the degree to which ecosystems and their services can be restored, the rate of restoration of particular services, and tradeoffs in services between restored ecosystems and other common land uses. We use a chronosequence approach to infer multi-decadal changes in ecosystem services under management aimed at restoring fire-dependent pine savannas, including the use of frequent prescribed fire, following abandonment of row-crop agriculture in the southeastern U.S. We compare ecosystem services between restored pine savannas of different ages and reference pine savannas as well as other common land uses (row-crop agriculture, improved pasture, pine plantation, unmanaged forest). Our results suggest that restoring pine savannas results in many improvements to ecosystem services, including increases in plant species richness, perennial grass cover, tree biomass, total ecosystem carbon, soil carbon and C:N, reductions in soil bulk density and predicted erosion and sedimentation, shifts from soil fungal pathogens to fungal symbionts, and changes in soil chemistry toward reference pine savanna conditions. However, the rate of improvement varies widely among services from a few years to decades. Compared to row-crop agriculture and improved pasture, restored savannas have lower erosion, soil bulk density, and soil pathogens and a higher percentage of mycorrhizal fungi and ecosystem carbon storage. Compared to pine plantations and unmanaged forests, restored pine savannas have lower fire-prone fuel loads and higher water yield and bee pollinator abundance. Our results indicate that restoration of pine savanna using frequent fire provides a broad suite of ecosystem services that increase the landscape's overall resilience to climate change. These results are likely relevant to other savannas dominated by perennial vegetation and maintained with frequent fire.

Published
2022
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14. Regardless of N-substrate, multiple fungal root endophytes isolated from pastures outgrow and outcompete those isolated from undisturbed sites

Author

Neyda E. de Leon, John Paszalek, Benjamin A. Sikes, and Christine V. Hawkes

Subjects
0106 biological sciences, 0301 basic medicine, geography, Biomass (ecology), geography.geographical_feature_category, media_common.quotation_subject, fungi, Soil Science, Edaphic, Fungus, Biology, biology.organism_classification, 01 natural sciences, Pasture, Substrate (marine biology), Competition (biology), 03 medical and health sciences, 030104 developmental biology, Nutrient, Agronomy, High nitrogen, Botany, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, media_common
Abstract

Edaphic properties such as soil nutrients structure belowground fungal communities and alter their intimate interactions with plants. Yet little work has compared the traits of fungal root endophytes and tested if specific soil nutrients determine their growth and competition. We hypothesized that fungi isolated from particular resource environments should grow and compete better when resources matched their “home” environment. We conducted experiments to compare growth rate and competitive ability of eight fungal root endophytes, cultured from either low nutrient undisturbed sites or from sites converted to high nutrient pastures, varying the nutrient environments to match the different sites. In isolation, biomass depended on nutrient limitation and fungal identity. Pasture endophytes all had high biomass in high nitrogen environments while endophytes from undisturbed sites showed greater variation among isolates. In competition, growth differences quantitatively depended on the fungus’s identity, its competitor’s identity and nutrients, yet pasture fungi out-competed “undisturbed” fungi in nearly every case. Rapid growth and competitive ability appears to be a trait of these fungal endophytes isolated from pastures and not solely a product of high nutrients, which may inhibit successful reintroduction of fungi from undisturbed sites.

Published
2017
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15. Suppression of root-endogenous fungi in persistently inundated

Author

Ashley A, Klymiuk and Benjamin A, Sikes

Subjects
Microbiological Techniques, Microscopy, Wetlands, Endophytes, Fungi, Hyphae, Kansas, Spores, Fungal, Typhaceae, Plant Roots, Floods, Mycobiome
Abstract

Wetland soils are defined by anoxic and reducing conditions that impose biogeochemically hostile conditions on plant roots and their endogenous fungal communities. The cosmopolitan wetland plant

Published
2019

16. Frequent fire reorganizes fungal communities and slows decomposition across a heterogeneous pine savanna landscape

Author

Benjamin A. Sikes, William J. Platt, Tatiana A. Semenova-Nelsen, Jean M. Huffman, and Taylor R. Patterson

Subjects
Physiology, Ecology, Fungi, Plant community, Plant Science, Vegetation, Pinus, complex mixtures, Grassland, Decomposer, Wildfires, Soil water, Litter, Environmental science, Ecosystem, Species richness, Relative species abundance
Abstract

Pyrogenic savannas with a tree–grassland ‘matrix’ experience frequent fires (i.e. every 1–3 yr). Aboveground responses to frequent fires have been well studied, but responses of fungal litter decomposers, which directly affect fuels, remain poorly known. We hypothesized that each fire reorganizes belowground communities and slows litter decomposition, thereby influencing savanna fuel dynamics. In a pine savanna, we established patches near and away from pines that were either burned or unburned in that year. Within patches, we assessed fungal communities and microbial decomposition of newly deposited litter. Soil variables and plant communities were also assessed as proximate drivers of fungal communities. Fungal communities, but not soil variables or vegetation, differed substantially between burned and unburned patches. Saprotrophic fungi dominated in unburned patches but decreased in richness and relative abundance after fire. Differences in fungal communities with fire were greater in litter than in soils, but unaffected by pine proximity. Litter decomposed more slowly in burned than in unburned patches. Fires drive shifts between fire‐adapted and sensitive fungal taxa in pine savannas. Slower fuel decomposition in accordance with saprotroph declines should enhance fuel accumulation and could impact future fire characteristics. Thus, fire reorganization of fungal communities may enhance persistence of these fire‐adapted ecosystems.

Published
2019

17. Abiotic and biotic context dependency of perennial crop yield

Author

Liz Koziol, Benjamin A. Sikes, Timothy E. Crews, Thomas P. McKenna, and James D. Bever

Subjects
0106 biological sciences, Perennial plant, Plant Weeds, Plant Science, Pathology and Laboratory Medicine, Plant Roots, 01 natural sciences, Monoculture Cropping, Mycorrhizae, Agricultural Soil Science, Edaphology, Medicago, Medicine and Health Sciences, Soil Microbiology, Flowering Plants, Perennial grain, Fungal Pathogens, Multidisciplinary, Biotic component, Plant Fungal Pathogens, Eukaryota, food and beverages, Agriculture, Fabaceae, Plants, Agricultural Methods, Legumes, Biota, Agricultural soil science, Medical Microbiology, Medicine, Planting, Pathogens, Medicago sativa, Research Article, Crops, Agricultural, Science, Soil biology, Plant Pathogens, Soil Science, Crops, Mycology, Horticulture, Biology, Poaceae, Microbiology, 010603 evolutionary biology, Crop, Stress, Physiological, Symbiosis, Microbial Pathogens, Ecosystem, Alfalfa, Ecology and Environmental Sciences, fungi, Organisms, Fungi, Biology and Life Sciences, Plant Pathology, Agronomy, Monoculture, Edible Grain, Crop Science, 010606 plant biology & botany
Abstract

Perennial crops in agricultural systems can increase sustainability and the magnitude of ecosystem services, but yield may depend upon biotic context, including soil mutualists, pathogens and cropping diversity. These biotic factors themselves may interact with abiotic factors such as drought. We tested whether perennial crop yield depended on soil microbes, water availability and crop diversity by testing monocultures and mixtures of three perennial crop species: a novel perennial grain (intermediate wheatgrass-Thinopyrum intermedium-- that produces the perennial grain Kernza®), a potential perennial oilseed crop (Silphium intregrifolium), and alfalfa (Medicago sativa). Perennial crop performance depended upon both water regime and the presence of living soil, most likely the arbuscular mycorrhizal (AM) fungi in the whole soil inoculum from a long term perennial monoculture and from an undisturbed native remnant prairie. Specifically, both Silphium and alfalfa strongly benefited from AM fungi. The presence of native prairie AM fungi had a greater benefit to Silphium in dry pots and alfalfa in wet pots than AM fungi present in the perennial monoculture soil. Kernza did not benefit from AM fungi. Crop mixtures that included Kernza overyielded, but overyielding depended upon inoculation. Specifically, mixtures with Kernza overyielded most strongly in sterile soil as Kernza compensated for poor growth of Silphium and alfalfa. This study identifies the importance of soil biota and the context dependence of benefits of native microbes and the overyielding of mixtures in perennial crops.

Published
2020
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18. Mammalian Soil Disturbance, Plant Cover, and Soil Nitrogen in a Prairie Restoration

Author

Helen M. Alexander, Courtney Barnes, Benjamin A. Sikes, and Robert M. Timm

Subjects
geography, Disturbance (geology), geography.geographical_feature_category, Prairie restoration, Ecology, food and beverages, Forb, Plant cover, Environmental science, Plant community, Ecosystem, Species richness, Grassland
Abstract

Small mammal disturbances in tallgrass prairies are known to influence a variety of ecosystem properties, including plant establishment, plant diversity, and soil nutrient dynamics. We explored direct and indirect effects of mammalian soil disturbance on a newly established grassland restoration site. In 2016–2017, we measured variation in small mammal soil disturbance, plant cover, and total inorganic nitrogen, all within the same plots. Within our site, interior plots had greater disturbance than plots located near site edges. On average, plots with high soil disturbance in 2016 had high disturbance in 2017, and disturbance in the first year was greater than in the second year. Soil disturbance was associated with an overall decline in grass cover and an increase in forb cover (especially Asteraceae). However, there were no associations between soil disturbance and either inorganic nitrogen or plant species richness/diversity on the new restoration site. Our study supports the important link between prairie plant communities and small mammal soil disturbance, potentially creating heterogeneity that is important for tallgrass prairie restoration and conservation.

Published
2020
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19. Mycorrhizal fungal growth responds to soil characteristics, but not host plant identity, during a primary lacustrine dune succession

Author

Benjamin A. Sikes, John N. Klironomos, and Hafiz Maherali

Subjects
Hypha, Hyphae, Plant Development, Plant Science, Ecological succession, Biology, Plant Roots, Sand dune stabilization, Soil, Mycorrhizae, Botany, Genetics, Molecular Biology, Primary succession, Soil Microbiology, Ecology, Evolution, Behavior and Systematics, Host (biology), Ecology, fungi, Fungi, food and beverages, Plant community, General Medicine, Plants, Soil type, Soil microbiology
Abstract

Soil factors and host plant identity can both affect the growth and functioning of mycorrhizal fungi. Both components change during primary succession, but it is unknown if their relative importance to mycorrhizas also changes. This research tested how soil type and host plant differences among primary successional stages determine the growth and plant effects of arbuscular mycorrhizal (AM) fungal communities. Mycorrhizal fungal community, plant identity, and soil conditions were manipulated among three stages of a lacustrine sand dune successional series in a fully factorial greenhouse experiment. Late succession AM fungi produced more arbuscules and soil hyphae when grown in late succession soils, although the community was from the same narrow phylogenetic group as those in intermediate succession. AM fungal growth did not differ between host species, and plant growth was similarly unaffected by different AM fungal communities. These results indicate that though ecological filtering and/or adaptation of AM fungi occurs during this primary dune succession, it more strongly reflects matching between fungi and soils, rather than interactions between fungi and host plants. Thus, AM fungal performance during this succession may not depend directly on the sequence of plant community succession.

Published
2013
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20. Plant and root endophyte assembly history: interactive effects on native and exotic plants

Author

Tadashi Fukami, Benjamin A. Sikes, and Christine V. Hawkes

Subjects
0106 biological sciences, Time Factors, Introduced species, 010603 evolutionary biology, 01 natural sciences, Endophyte, Plant Roots, Invasive species, Shrubland, Species Specificity, Endophytes, Ecology, Evolution, Behavior and Systematics, Biomass (ecology), Melinis repens, geography, geography.geographical_feature_category, biology, Ecology, fungi, Fungi, food and beverages, Species diversity, Plant community, Plants, biology.organism_classification, Introduced Species, 010606 plant biology & botany
Abstract

Differences in the arrival timing of plants and soil biota may result in different plant communities through priority effects, potentially affecting the success of native vs. exotic plants, but experimental evidence is largely lacking. We conducted a greenhouse experiment to investigate whether the assembly history of plants and fungal root endophytes could interact to influence plant emergence and biomass. We introduced a grass species and eight fungal species from one of three land-use types (undisturbed, disturbed, or pasture sites in a Florida scrubland) in factorial combinations. We then introduced all plants and fungi from the other land-use types 2 weeks later. Plant emergence was monitored for 6 months, and final plant biomass and fungal species composition assessed. The emergence and growth of the exotic Melinis repens and the native Schizacharyium niveum were affected negatively when introduced early with their "home" fungi, but early introduction of a different plant species or fungi from a different site type eliminated these negative effects, providing evidence for interactive priority effects. Interactive effects of plant and fungal arrival history may be an overlooked determinant of plant community structure and may provide an effective management tool to inhibit biological invasion and aid ecosystem restoration.

Published
2016

21. Taxonomic similarity, more than contact opportunity, explains novel plant-pathogen associations between native and alien taxa

Author

Jennifer L. Bufford, Philip E. Hulme, Peter R. Johnston, Jerry A. Cooper, Benjamin A. Sikes, and Richard P. Duncan

Subjects
0106 biological sciences, Flora, biology, Physiology, Ecology, Host (biology), fungi, Biosecurity, food and beverages, Plant Science, Alien, Native plant, Plants, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Phylogeography, Taxon, Species Specificity, Host-Pathogen Interactions, Confidence Intervals, Phytophthora, Pathogen, Phylogeny, 010606 plant biology & botany
Abstract

Novel associations between plants and pathogens can have serious impacts on managed and natural ecosystems world-wide. The introduction of alien plants increases the potential for biogeographically novel plant-pathogen associations to arise when pathogens are transmitted from native to alien plant species and vice versa. We quantified biogeographically novel associations recorded in New Zealand over the last 150 yr between plant pathogens (fungi, oomycetes and plasmodiophorids) and vascular plants. We examined the extent to which taxonomic similarity, pathogen traits, contact opportunity and sampling effort could explain the number of novel associates for host and pathogen species. Novel associations were common; approximately one-third of surveyed plants and pathogens were recorded with at least one biogeographically novel associate. Native plants had more alien pathogens than vice versa. Taxonomic similarity between the native and alien flora and the total number of recorded associations (a measure of sampling effort) best explained the number of novel associates among species. The frequency of novel associations and the importance of sampling effort as an explanatory variable emphasize the need for effective monitoring and risk assessment tools to mitigate the potential environmental and economic impact of novel pathogen associations.

Published
2016

22. Arbuscular mycorrhizal fungal communities change among three stages of primary sand dune succession but do not alter plant growth

Author

John N. Klironomos, Hafiz Maherali, and Benjamin A. Sikes

Subjects
Biomass (ecology), Plant growth, Hypha, Inoculation, Ecology, Soil biology, fungi, food and beverages, Ecological succession, Biology, Sand dune stabilization, Fungal Structures, Botany, Ecology, Evolution, Behavior and Systematics
Abstract

Plant interactions with soil biota could have a significant impact on plant successional trajectory by benefiting plants in a particular successional stage over others. The influence of soil mutualists such as mycorrhizal fungi is thought to be an important feedback component, yet they have shown benefits to both early and late successional plants that could either retard or accelerate succession. Here we first determine if arbuscular mycorrhizal (AM) fungi differ among three stages of primary sand dune succession and then if they alter growth of plants from particular successional stages. We isolated AM fungal inoculum from early, intermediate or late stages of a primary dune succession and compared them using cloning and sequencing. We then grew eight plant species that dominate within each of these successional stages with each AM fungal inoculum. We measured fungal growth to assess potential AM functional differences and plant growth to determine if AM fungi positively or negatively affect plants. AM fungi isolated from early succession were more phylogenetically diverse relative to intermediate and late succession while late successional fungi consistently produced more soil hyphae and arbuscules. Despite these differences, inocula from different successional stages had similar effects on the growth of all plant species. Host plant biomass was not affected by mycorrhizal inoculation relative to un-inoculated controls. Although mycorrhizal communities differ among primary dune successional stages and formed different fungal structures, these differences did not directly affect the growth of plants from different dune successional stages in our experiment and therefore may be less likely to directly contribute to plant succession in sand dunes.

Published
2012
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23. Determining a minimum detection threshold in terminal restriction fragment length polymorphism analysis

Author

Benjamin A. Sikes, Alexander M. Koch, Miranda M. Hart, John N. Klironomos, Kevin C. Courtney, Luke D. Bainard, and Hafiz Maherali

Subjects
Microbiology (medical), biology, Detection threshold, Fungi, Fungal genetics, Data interpretation, Biodiversity, Spores, Fungal, biology.organism_classification, Microbiology, Electropherogram, Terminal restriction fragment length polymorphism, Polymorphism (computer science), Mycorrhizae, Botany, Amplified Fragment Length Polymorphism Analysis, DNA, Fungal, Arbuscular mycorrhizal, Biological system, Molecular Biology, Phylogeny, Polymorphism, Restriction Fragment Length, Glomus
Abstract

Terminal restriction fragment length polymorphism (T-RFLP) analysis is a common technique used to characterize soil microbial diversity. The fidelity of this technique in accurately reporting diversity has not been thoroughly evaluated. Here we determine if rare fungal species can be reliably detected by T-RFLP analysis. Spores from three arbuscular mycorrhizal fungal species were each mixed at a range of concentrations (1%, 10%, 50%, and 100%) with Glomus irregulare to establish a minimum detection threshold. T-RFLP analysis was capable of detecting diagnostic peaks of rare taxa at concentrations as low as 1%. The relative proportion of the target taxa in the sample and DNA concentration influenced peak detection reliability. However, low concentrations produced small, inconsistent electropherogram peaks contributing to difficulty in differentiating true peaks from signal noise. The results of this experiment suggest T-RFLP is a reproducible and high fidelity procedure, which requires careful data interpretation in order to accurately characterize sample diversity.

Published
2012
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24. Field-based effects of allelopathy in invaded tallgrass prairie

Author

Andrew S. MacDougall, Jesse Harnden, and Benjamin A. Sikes

Subjects
education.field_of_study, Ecology, biology, Propagule pressure, Population, Plant Science, biology.organism_classification, Invasive species, Mesocosm, Agronomy, Seedling, Germination, Botany, Festuca rubra, education, Ecology, Evolution, Behavior and Systematics, Allelopathy
Abstract

Allelopathic phytochemicals have been linked to invasion success, but their role in the invasion process remains unclear. Toxicity effects demonstrated with lab bioassays may be neutralized in soils, and their role in population expansion can be intertwined with nonallelopathic processes that also influence dispersal and establishment. Here, we use greenhouse experiments to test the soil-based impacts of invasive fine fescue ( Festuca rubra L.) on recruitment in tallgrass prairie. Fescue roots release the growth inhibitor m-tyrosine. Using root washes and fescue-conditioned soils to mimic field potency, we determined allelopathic impacts on recruitment, including intraspecific limitation. We also tested whether nonallelopathic factors (propagule pressure, disturbance, and fertility) influence invasion into constructed fescue and prairie mesocosms, and whether root washes inhibit arbuscular mycorrhizal (AM) fungi. We observed significant negative effects of fescue soils and root washes on germination and seedling survival, including on fescue itself. Mesocosm invasion, however, was determined more by nonallelopathic mechanisms (propagule pressure and rapid growth). In prairie mesocosms, fescue invasion was higher than its own understory, with no effects of disturbance or fertility. Tallgrass species had difficulty establishing in all environments, regardless of propagule pressure. Impacts on AM fungal hyphal length and spore production were insignificant. Our results suggest that nonallelopathic traits may be sufficient to explain fescue invasion, with allelopathy likely emerging as a final "coup de grâce" for recruiting native grasses once dominance has been attained. Allelopathic species, including fine fescue, may thus not necessarily be invasive unless nonallelopathic traits facilitate establishment prior to the accumulation of soil-based toxins.

Published
2011
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26. Plant and fungal identity determines pathogen protection of plant roots by arbuscular mycorrhizas

Author

Benjamin A. Sikes, Karl Cottenie, and John N. Klironomos

Subjects
Ecology, Plant roots, media_common.quotation_subject, Plant Science, Biology, biology.organism_classification, Glomeromycota, Symbiosis, Identity (philosophy), Fusarium oxysporum, Botany, Natural enemies, Mycorrhiza, Pathogen, Ecology, Evolution, Behavior and Systematics, media_common
Abstract

This is the peer reviewed version of the following article: BA Sikes, K Cottenie and JN Klironomos. (2009) Plant and fungal identity determines pathogen protection of plant roots by arbuscular mycorrhizas. Journal of Ecology 97: 1274-1280. http://dx.doi.org/10.1111/j.1365-2745.2009.01557.x, which has been published in final form at http://doi.org/10.1111/j.1365-2745.2009.01557.x This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Self-Archiving.

Published
2009
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27. Rapid growth of a Eurasian haplotype of Phragmites australis in a restored brackish marsh in Louisiana, USA

Author

Rebecca J. Howard, Benjamin A. Sikes, and Steven E. Travis

Subjects
Genetic diversity, geography, geography.geographical_feature_category, Ecology, Haplotype, food and beverages, Introduced species, Biology, Invasive species, Phragmites, Brackish marsh, Genetic variation, Amplified fragment length polymorphism, geographic locations, Ecology, Evolution, Behavior and Systematics
Abstract

While numerous studies have documented patterns of invasion by non-indigenous plant species, few have considered the invasive properties of non-native genotypes of native species. Characteristics associated with specific genotypes, such as tolerance to disturbance, may mistakenly be applied to an entire species in the absence of genetic information, which consequently may affect management decisions. We report here on the incidence and growth of an introduced lineage of Phragmites australis in the Gulf of Mexico coastal zone of Louisiana. P. australis was collected from nine separate locations for inclusion in a series of growth experiments. Chloroplast DNA analysis indicated that specimens collected from four locations in the Mississippi River Delta represented the introduced Eurasian haplotype; the remainder represented the gulf coast haplotype. Three distinct genotypes, or clones, were identified within each haplotype via analysis using amplified fragment length polymorphisms, which also revealed reduced genetic diversity of the gulf coast clones compared to the Eurasian clones. Clones of each haplotype were planted along with three other native macrophytes at similar densities in a restored brackish marsh and monitored for growth. After 14 months, the Eurasian haplotype had spread vegetatively to cover about 82% of the experimental plots, more than four times the coverage (18%) of the gulf coast haplotype. Thus, the use of P. australis plantings for wetland restoration should consider the genetic lineage of plants used since our results indicate the potential of the Eurasian haplotype to grow rapidly at newly restored sites. This rapid growth may limit the establishment of more slowly growing native species.

Published
2007
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28. When do arbuscular mycorrhizal fungi protect plant roots from pathogens?

Author

Benjamin A. Sikes

Subjects
Setaria, biology, Plant roots, fungi, food and beverages, Plant Science, Arbuscular mycorrhizal fungi, biology.organism_classification, Glomeraceae, Plant morphology, Fusarium oxysporum, Botany, Allium, Pathogen
Abstract

Arbuscular mycorrhizal (AM) fungi are mainly thought to facilitate phosphorus uptake in plants, but they can also perform several other functions that are equally beneficial. Our recent study sheds light on the factors determining one such function, enhanced plant protection from root pathogens. Root infection by the fungal pathogen Fusarium oxysporum was determined by both plant susceptibility and the ability of an AM fungal partner to suppress the pathogen. The non-susceptible plant species (Allium cepa) had limited F. oxysporum infection even without AM fungi. In contrast, the susceptible plant species (Setaria glauca) was heavily infected and only AM fungi in the family Glomeraceae limited pathogen abundance. Plant susceptibility to pathogens was likely determined by contrasting root architectures between plants, with the simple rooted plant (A. cepa) presenting fewer sites for infection.AM fungal colonization, however, was not limited in the same way in part because plants with fewer, simple roots are more mycorrhizal dependent. Protection only by Glomus species also indicates that whatever the mechanism(s) of this function, it responds to AM fungal families differently. While poor at pathogen protection, AM fungal species in the family Gigasporaceae most benefited the growth of the simple rooted plant species. Our research indicates that plant trait differences, such as root architecture can determine how important each mycorrhizal function is to plant growth but the ability to provide these functions differs among AM fungi.

Published
2010
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30. Soil microbes drive the classic plant diversity-productivity pattern

Author

Peter B. Reich, Marten Scheffer, Scott A. Mangan, Kun Xiao, Ragan M. Callaway, Stefan A. Schnitzer, Benjamin A. Sikes, Janneke HilleRisLambers, Linda L. Kinkel, John N. Klironomos, Egbert H. van Nes, and Matthias C. Rillig

Subjects
Ecology, Biodiversity, Species diversity, Plant Development, Biology, Plants, Models, Biological, Plant disease, Plant ecology, Productivity (ecology), Soil water, Ecosystem, Species richness, human activities, Ecology, Evolution, Behavior and Systematics, Soil Microbiology
Abstract

Ecosystem productivity commonly increases asymptotically with plant species diversity, and determining the mechanisms responsible for this well-known pattern is essential to predict potential changes in ecosystem productivity with ongoing species loss. Previous studies attributed the asymptotic diversity-productivity pattern to plant competition and differential resource use (e.g., niche complementarity). Using an analytical model and a series of experiments, we demonstrate theoretically and empirically that host-specific soil microbes can be major determinants of the diversity-productivity relationship in grasslands. In the presence of soil microbes, plant disease decreased with increasing diversity, and productivity increased nearly 500%, primarily because of the strong effect of density-dependent disease on productivity at low diversity. Correspondingly, disease was higher in plants grown in conspecific-trained soils than heterospecific-trained soils (demonstrating host-specificity), and productivity increased and host-specific disease decreased with increasing community diversity, suggesting that disease was the primary cause of reduced productivity in species- poor treatments. In sterilized, microbe-free soils, the increase in productivity with increasing plant species number was markedly lower than the increase measured in the presence of soil microbes, suggesting that niche complementarity was a weaker determinant of the diversity- productivity relationship. Our results demonstrate that soil microbes play an integral role as determinants of the diversity-productivity relationship.

Published
2011

31. Deciphering the relative contributions of multiple functions within plant-microbe symbioses

Author

Mattrhias C Rillig, Benjamin A. Sikes, and Jeff R. Powell

Subjects
Biomass (ecology), biology, Ecology, Microorganism, fungi, food and beverages, Plants, biology.organism_classification, Models, Biological, Article Addendum, Glomeromycota, Symbiosis, Species Specificity, Mycorrhizae, Ecosystem, Biomass, Mycorrhiza, Functional group (ecology), Ecology, Evolution, Behavior and Systematics, Function (biology)
Abstract

Arbuscular mycorrhizal (AM) fungi are mainly thought to facilitate phosphorus uptake in plants, but they can also perform several other functions that are equally beneficial. Our recent study sheds light on the factors determining one such function, enhanced plant protection from root pathogens. Root infection by the fungal pathogen Fusarium oxysporum was determined by both plant susceptibility and the ability of an AM fungal partner to suppress the pathogen. The non-susceptible plant species (Allium cepa) had limited F. oxysporum infection even without AM fungi. In contrast, the susceptible plant species (Setaria glauca) was heavily infected and only AM fungi in the family Glomeraceae limited pathogen abundance. Plant susceptibility to pathogens was likely determined by contrasting root architectures between plants, with the simple rooted plant (A. cepa) presenting fewer sites for infection. AM fungal colonization, however, was not limited in the same way in part because plants with fewer, simple roots are more mycorrhizal dependent. Protection only by Glomus species also indicates that whatever the mechanism(s) of this function, it responds to AM fungal families differently. While poor at pathogen protection, AM fungal species in the family Gigasporaceae most benefited the growth of the simple rooted plant species. Our research indicates that plant trait differences, such as root architecture can determine how important each mycorrhizal function is to plant growth but the ability to provide these functions differs among AM fungi.

Published
2010

32. Spatial Heterogeneity in Mycorrhizal Populations and Communities: Scales and Mechanisms

Author

Alexander M. Koch, Benjamin E. Wolfe, Benjamin A. Sikes, Jeri L. Parrent, John N. Klironomos, and Monique Gardes

Subjects
Abiotic component, Propagule, Ecology, Ecology (disciplines), Spatial ecology, Biological dispersal, Spatial variability, Evolutionary ecology, Biology, Spatial heterogeneity
Abstract

The importance of a spatial context in understanding the ecology and evolution of organisms has become increasingly clear. Although there is a growing awareness of the importance of mycorrhizal fungi in many communities and ecosystems, much of this understanding is based on a spatially homogenized view of these soil fungi. This homogenized approach may limit our understanding of how these organisms interact with plants and other biota in the field. As an attempt to advance a spatial framework for understanding mycorrhizal ecology, we review our current understanding of the spatial structure of communities and populations of ectomycorrhizal and arbuscular mycorrhizal fungi at the scale of landscapes, communities, and individual host root systems. A variety of potential mechanisms such as disturbance, abiotic and biotic dispersal of mycorrhizal propagules, and biotic interactions may be responsible for generating and maintaining this spatial variation of populations and communities, but the links between observed spatial patterns and mechanisms have yet to be formed. Future work assessing the potential functional significance of spatial variation of mycorrhizal fungi for plant communities and ecosystem function, as well as measuring spatial variation in mycorrhizal function, will continue to advance our understanding of the spatial template for mycorrhizal–plant interactions in the field.

Published
2008
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33. Internalizing Conservation through Our Own Microbes

Author

Benjamin A. Sikes

Subjects
Ecology, Library science, Conservation biology, Psychology, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation
Abstract

This is the peer reviewed version of the following article: BA Sikes (2012) Internalizing Conservation through our own Microbes. Conservation Biology, 26(2): 198. http://dx.doi.org/10.1111/j.1523-1739.2012.01834.x, which has been published in final form at http://doi.org/10.1111/j.1523-1739.2012.01834.x. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Self-Archiving.

Published
2012
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