Your search keyword '"Hofmockel, Kirsten"' showing total 75 results

1. The direct and indirect drivers shaping RNA viral communities in grassland soils.

Author

Ruonan Wu, Zimmerman, Amy E., and Hofmockel, Kirsten S.

Published

2024

2. New Workflow Enabling Cryo-EM Analyses of Viruses Natively Isolated from Soil.

Author

Parvate, Amar D, Alfaro, Trinidad, McDearis, Regan, Zimmerman, Amy, Hofmockel, Kirsten, Nelson, Bill, and Evans, James E

Published

2024

3. Hi-C metagenome sequencing reveals soil phage–host interactions.

Author

Wu, Ruonan, Davison, Michelle R., Nelson, William C., Smith, Montana L., Lipton, Mary S., Jansson, Janet K., McClure, Ryan S., McDermott, Jason E., and Hofmockel, Kirsten S.

Subjects

BACTERIAL communities, SOIL drying, SOIL dynamics, SOILS, RNA sequencing, SHOTGUN sequencing, METAGENOMICS

Abstract

Bacteriophages are abundant in soils. However, the majority are uncharacterized, and their hosts are unknown. Here, we apply high-throughput chromosome conformation capture (Hi–C) to directly capture phage-host relationships. Some hosts have high centralities in bacterial community co-occurrence networks, suggesting phage infections have an important impact on the soil bacterial community interactions. We observe increased average viral copies per host (VPH) and decreased viral transcriptional activity following a two-week soil-drying incubation, indicating an increase in lysogenic infections. Soil drying also alters the observed phage host range. A significant negative correlation between VPH and host abundance prior to drying indicates more lytic infections result in more host death and inversely influence host abundance. This study provides empirical evidence of phage-mediated bacterial population dynamics in soil by directly capturing specific phage-host interactions. This study uses high-throughput chromosome conformation capture (Hi-C) to identify phage–host relationships in soil. By coupling Hi-C with DNA and RNA sequencing, the authors demonstrate the impact of soil drying on phage–host interactions and the downstream effects on abundances and interspecies interactions within bacterial communities. [ABSTRACT FROM AUTHOR]

Published

2023

4. Real-Time and Rapid Respiratory Response of the Soil Microbiome to Moisture Shifts.

Author

Smith, Montana L., Weitz, Karl K., Thompson, Allison M., Jansson, Janet K., Hofmockel, Kirsten S., and Lipton, Mary S.

Subjects

SOIL moisture, SOIL respiration, STABLE isotopes, CARBON metabolism, CARBON sequestration, MICROBIAL respiration

Abstract

Microbial response to changing environmental factors influences the fate of soil organic carbon, and drought has been shown to affect microbial metabolism and respiration. We hypothesized that the access of microbes to different carbon pools in response to dry–rewet events occurs sequentially at different rates. We amended desiccated soils with 13C-labeled glucose and measured the rates of 12CO2 and 13CO2 respiration in real time after rewetting. Using these differentiated 12CO2 and 13CO2 respiration rate soils after rewetting, we were able to deduce when microbes are accessing different pools of carbon. Immediately upon rewetting, respiration of 12CO2 occurred first, with negligible 13CO2 respiration. Appreciable metabolism and respiration of the added 13C glucose did not occur until 15 min after rewetting. We conclude that, while all carbon pools are being accessed in the first 9 h after rewetting, the rate and timing at which new and existing carbon pools are being accessed varies. Within this study, using stable isotope-labeled substrates to discern which carbon pools are metabolized first uniquely illustrates how microorganisms access different carbon pools which has implications into understanding how carbon metabolism can further affect climate, carbon sequestration, and soil health. [ABSTRACT FROM AUTHOR]

Published

2023

5. Nutrients strengthen density dependence of per-capita growth and mortality rates in the soil bacterial community.

Author

Stone, Bram W., Blazewicz, Steven J., Koch, Benjamin J., Dijkstra, Paul, Hayer, Michaela, Hofmockel, Kirsten S., Liu, Xiao Jun Allen, Mau, Rebecca L., Pett-Ridge, Jennifer, Schwartz, Egbert, and Hungate, Bruce A.

Subjects

NUTRIENT density, DEATH rate, BACTERIAL communities, BACTERIAL diversity, STABLE isotopes, BIOTIC communities, SOIL microbial ecology, SOILS

Abstract

Density dependence in an ecological community has been observed in many macro-organismal ecosystems and is hypothesized to maintain biodiversity but is poorly understood in microbial ecosystems. Here, we analyze data from an experiment using quantitative stable isotope probing (qSIP) to estimate per-capita growth and mortality rates of bacterial populations in soils from several ecosystems along an elevation gradient which were subject to nutrient addition of either carbon alone (glucose; C) or carbon with nitrogen (glucose + ammonium-sulfate; C + N). Across all ecosystems, we found that higher population densities, quantified by the abundance of genomes per gram of soil, had lower per-capita growth rates in C + N-amended soils. Similarly, bacterial mortality rates in C + N-amended soils increased at a significantly higher rate with increasing population size than mortality rates in control and C-amended soils. In contrast to the hypothesis that density dependence would promote or maintain diversity, we observed significantly lower bacterial diversity in soils with stronger negative density-dependent growth. Here, density dependence was significantly but weakly responsive to nutrients and was not associated with higher bacterial diversity. [ABSTRACT FROM AUTHOR]

Published

2023

6. Interactive effects of depth and differential irrigation on soil microbiome composition and functioning.

Author

Naylor, Dan, Naasko, Katherine, Smith, Montana, Couvillion, Sneha, Nicora, Carrie, Trejo, Jesse, Fransen, Steven, Danczak, Robert, McClure, Ryan, Hofmockel, Kirsten S., and Jansson, Janet K.

Subjects

SOIL composition, IRRIGATION, SOIL depth, DEPTH profiling, SOIL moisture, BIOSPHERE

Abstract

Two factors that are well-known to influence soil microbiomes are the depth of the soil as well as the level of moisture. Previous works have demonstrated that climate change will increase the incidence of drought in soils, but it is unknown how fluctuations in moisture availability affect soil microbiome composition and functioning down the depth profile. Here, we investigated soil and wheatgrass rhizosphere microbiomes in a single common field setting under four different levels of irrigation (100%, 75%, 50%, and 25%) and three depths (0-5 cm, 5-15 cm, and 15-25 cm from the surface). We demonstrated that there is a significant interactive effect between depth and irrigation, where changes in soil moisture more strongly affect soil microbiomes at the surface layer than at deeper layers. This was true for not only microbiome community composition and diversity metrics, but also for functional profiles (transcriptomic and metabolomic datasets). Meanwhile, in rhizosphere communities the influence of irrigation was similar across the different depths. However, for the 'Alkar' wheatgrass cultivar, the rhizosphere microbial communities responded more strongly to changes in irrigation level than did the communities for the 'Jose' cultivar rhizosphere. The lessened response of deeper soil microbiomes to changes in irrigation may be due to higher incidence of slow-growing, stress-resistant microbes. These results demonstrate that the soil microbiome response to moisture content is depthdependent. As such, it will be optimal for soil microbiome studies to incorporate deeper as well as surface soils, to get a more accurate picture of the soil microbiome response to stress. [ABSTRACT FROM AUTHOR]

Published

2023

7. Grassland ecosystem type drives AM fungal diversity and functional guild distribution in North American grasslands.

Author

Kasanke, Christopher P., Zhao, Qian, Alfaro, Trinidad, Walter, Christopher A., Hobbie, Sarah E., Cheeke, Tanya E., and Hofmockel, Kirsten S.

Subjects

GRASSLANDS, PLANT-microbe relationships, FUNGAL communities, BIOGEOCHEMICAL cycles, PRAIRIES, PLANT colonization, ECOSYSTEMS, GRASSLAND soils, FUNGAL colonies

Abstract

Nutrient exchange forms the basis of the ancient symbiotic relationship that occurs between most land plants and arbuscular mycorrhizal (AM) fungi. Plants provide carbon (C) to AM fungi and fungi provide the plant with nutrients such as nitrogen (N) and phosphorous (P). Nutrient addition can alter this symbiotic coupling in key ways, such as reducing AM fungal root colonization and changing the AM fungal community composition. However, environmental parameters that differentiate ecosystems and drive plant distribution patterns (e.g., pH, moisture), are also known to impact AM fungal communities. Identifying the relative contribution of environmental factors impacting AM fungal distribution patterns is important for predicting biogeochemical cycling patterns and plant‐microbe relationships across ecosystems. To evaluate the relative impacts of local environmental conditions and long‐term nutrient addition on AM fungal abundance and composition across grasslands, we studied experimental plots amended for 10 years with N, P, or N and P fertilizer in different grassland ecosystem types, including tallgrass prairie, montane, shortgrass prairie, and desert grasslands. Contrary to our hypothesis, we found ecosystem type, not nutrient treatment, was the main driver of AM fungal root colonization, diversity, and community composition, even when accounting for site‐specific nutrient limitations. We identified several important environmental drivers of grassland ecosystem AM fungal distribution patterns, including aridity, mean annual temperature, root moisture, and soil pH. This work provides empirical evidence for niche partitioning strategies of AM fungal functional guilds and emphasizes the importance of long‐term, large scale research projects to provide ecologically relevant context to nutrient addition studies. [ABSTRACT FROM AUTHOR]

Published

2023

8. Rapid remodeling of the soil lipidome in response to a drying-rewetting event.

Author

Couvillion, Sneha P., Danczak, Robert E., Naylor, Dan, Smith, Montana L., Stratton, Kelly G., Paurus, Vanessa L., Bloodsworth, Kent J., Farris, Yuliya, Schmidt, Darren J., Richardson, Rachel E., Bramer, Lisa M., Fansler, Sarah J., Nakayasu, Ernesto S., McDermott, Jason E., Metz, Thomas O., Lipton, Mary S., Jansson, Janet K., and Hofmockel, Kirsten S.

Subjects

SHORT-chain fatty acids, MICROBIAL lipids, UNSATURATED fatty acids, FISH oils, SATURATED fatty acids, ARID soils, GRASSLAND soils, MEMBRANE lipids

Abstract

Background: Microbiomes contribute to multiple ecosystem services by transforming organic matter in the soil. Extreme shifts in the environment, such as drying-rewetting cycles during drought, can impact the microbial metabolism of organic matter by altering microbial physiology and function. These physiological responses are mediated in part by lipids that are responsible for regulating interactions between cells and the environment. Despite this critical role in regulating the microbial response to stress, little is known about microbial lipids and metabolites in the soil or how they influence phenotypes that are expressed under drying-rewetting cycles. To address this knowledge gap, we conducted a soil incubation experiment to simulate soil drying during a summer drought of an arid grassland, then measured the response of the soil lipidome and metabolome during the first 3 h after wet-up. Results: Reduced nutrient access during soil drying incurred a replacement of membrane phospholipids, resulting in a diminished abundance of multiple phosphorus-rich membrane lipids. The hot and dry conditions increased the prevalence of sphingolipids and lipids containing long-chain polyunsaturated fatty acids, both of which are associated with heat and osmotic stress-mitigating properties in fungi. This novel finding suggests that lipids commonly present in eukaryotes such as fungi may play a significant role in supporting community resilience displayed by arid land soil microbiomes during drought. As early as 10 min after rewetting dry soil, distinct changes were observed in several lipids that had bacterial signatures including a rapid increase in the abundance of glycerophospholipids with saturated and short fatty acid chains, prototypical of bacterial membrane lipids. Polar metabolites including disaccharides, nucleic acids, organic acids, inositols, and amino acids also increased in abundance upon rewetting. This rapid metabolic reactivation and growth after rewetting coincided with an increase in the relative abundance of firmicutes, suggesting that members of this phylum were positively impacted by rewetting. Conclusions: Our study revealed specific changes in lipids and metabolites that are indicative of stress adaptation, substrate use, and cellular recovery during soil drying and subsequent rewetting. The drought-induced nutrient limitation was reflected in the lipidome and polar metabolome, both of which rapidly shifted (within hours) upon rewet. Reduced nutrient access in dry soil caused the replacement of glycerophospholipids with phosphorus-free lipids and impeded resource-expensive osmolyte accumulation. Elevated levels of ceramides and lipids with long-chain polyunsaturated fatty acids in dry soil suggest that lipids likely play an important role in the drought tolerance of microbial taxa capable of synthesizing these lipids. An increasing abundance of bacterial glycerophospholipids and triacylglycerols with fatty acids typical of bacteria and polar metabolites suggest a metabolic recovery in representative bacteria once the environmental conditions are conducive for growth. These results underscore the importance of the soil lipidome as a robust indicator of microbial community responses, especially at the short time scales of cell-environment reactions. A8GGwc64vbJf6mXPFnxxi9 Video Abstract [ABSTRACT FROM AUTHOR]

Published

2023

9. Removal of primary nutrient degraders reduces growth of soil microbial communities with genomic redundancy.

Author

McClure, Ryan, Garcia, Marci, Couvillion, Sneha, Farris, Yuliya, and Hofmockel, Kirsten S.

Abstract

Introduction: Understanding how microorganisms within a soil community interact to support collective respiration and growth remains challenging. Here, we used a model substrate, chitin, and a synthetic Model Soil Consortium (MSC-2) to investigate how individual members of a microbial community contribute to decomposition and community growth. While MSC-2 can grow using chitin as the sole carbon source, we do not yet know how the growth kinetics or final biomass yields of MSC-2 vary when certain chitin degraders, or other important members, are absent. Methods: To characterize specific roles within this synthetic community, we carried out experiments leaving out members of MSC-2 and measuring biomass yields and CO2 production. We chose two members to iteratively leave out (referred to by genus name): Streptomyces, as it is predicted via gene expression analysis to be a major chitin degrader in the community, and Rhodococcus as it is predicted via species co-abundance analysis to interact with several other members. Results: Our results showed that when MSC-2 lacked Streptomyces, growth and respiration of the community was severely reduced. Removal of either Streptomyces or Rhodococcus led to major changes in abundance for several other species, pointing to a comprehensive shifting of the microbial community when important members are removed, as well as alterations in the metabolic profile, especially when Streptomyces was lacking. These results show that when keystone, chitin degrading members are removed, other members, even those with the potential to degrade chitin, do not fill the same metabolic niche to promote community growth. In addition, highly connected members may be removed with similar or even increased levels of growth and respiration. Discussion: Our findings are critical to a better understanding of soil microbiology, specifically in how communities maintain activity when biotic or abiotic factors lead to changes in biodiversity in soil systems. [ABSTRACT FROM AUTHOR]

Published

2023

10. Stronger fertilization effects on aboveground versus belowground plant properties across nine U.S. grasslands.

Author

Keller, Adrienne B., Walter, Christopher A., Blumenthal, Dana M., Borer, Elizabeth T., Collins, Scott L., DeLancey, Lang C., Fay, Philip A., Hofmockel, Kirsten S., Knops, Johannes M. H., Leakey, Andrew D. B., Mayes, Melanie A., Seabloom, Eric W., and Hobbie, Sarah E.

Subjects

GLOBAL environmental change, NITROGEN fertilizers, GRASSLANDS, ATMOSPHERIC deposition, WILDLIFE management areas

Abstract

Increased nutrient inputs due to anthropogenic activity are expected to increase primary productivity across terrestrial ecosystems, but changes in allocation aboveground versus belowground with nutrient addition have different implications for soil carbon (C) storage. Thus, given that roots are major contributors to soil C storage, understanding belowground net primary productivity (BNPP) and biomass responses to changes in nutrient availability is essential to predicting carbon–climate feedbacks in the context of interacting global environmental changes. To address this knowledge gap, we tested whether a decade of nitrogen (N) and phosphorus (P) fertilization consistently influenced aboveground and belowground biomass and productivity at nine grassland sites spanning a wide range of climatic and edaphic conditions in the continental United States. Fertilization effects were strong aboveground, with both N and P addition stimulating aboveground biomass at nearly all sites (by 30% and 36%, respectively, on average). P addition consistently increased root production (by 15% on average), whereas other belowground responses to fertilization were more variable, ranging from positive to negative across sites. Site‐specific responses to P were not predicted by the measured covariates. Atmospheric N deposition mediated the effect of N fertilization on root biomass and turnover. Specifically, atmospheric N deposition was positively correlated with root turnover rates, and this relationship was amplified with N addition. Nitrogen addition increased root biomass at sites with low N deposition but decreased it at sites with high N deposition. Overall, these results suggest that the effects of nutrient supply on belowground plant properties are context dependent, particularly with regard to background N supply rates, demonstrating that site conditions must be considered when predicting how grassland ecosystems will respond to increased nutrient loading from anthropogenic activity. [ABSTRACT FROM AUTHOR]

Published

2023

11. A Mineral-Doped Micromodel Platform Demonstrates Fungal Bridging of Carbon Hot Spots and Hyphal Transport of MineralDerived Nutrients.

Author

Bhattacharjee, Arunima, Qafoku, Odeta, Richardson, Jocelyn A., Anderson, Lindsey N., Schwarz, Kaitlyn, Bramer, Lisa M., Lomas, Gerard X., Orton, Daniel J., Zihua Zhu, Engelhard, Mark H., Bowden, Mark E., Nelson, William C., Jumpponen, Ari, Jansson, Janet K., Hofmockel, Kirsten S., and Anderton, Christopher R.

Published

2022

12. Interaction Networks Are Driven by Community-Responsive Phenotypes in a Chitin-Degrading Consortium of Soil Microbes.

Author

McClure, Ryan, Farris, Yuliya, Danczak, Robert, Nelson, William, Hyun-Seob Song, Kessell, Aimee, Joon-Yong Lee, Couvillion, Sneha, Henry, Christopher, Jansson, Janet K., and Hofmockel, Kirsten S.

Published

2022

13. Nitrogen increases early‐stage and slows late‐stage decomposition across diverse grasslands.

Author

Gill, Allison L., Adler, Peter B., Borer, Elizabeth T., Buyarski, Christopher R., Cleland, Elsa E., D'Antonio, Carla M., Davies, Kendi F., Gruner, Daniel S., Harpole, W. Stanley, Hofmockel, Kirsten S., MacDougall, Andrew S., McCulley, Rebecca L., Melbourne, Brett A., Moore, Joslin L., Morgan, John W., Risch, Anita C., Schütz, Martin, Seabloom, Eric W., Wright, Justin P., and Yang, Louie H.

Subjects

FOREST litter, PLANT litter decomposition, GRASSLANDS, NITROGEN, CARBON cycle, MOLECULES

Abstract

To evaluate how increased anthropogenic nutrient inputs alter carbon cycling in grasslands, we conducted a litter decomposition study across 20 temperate grasslands on three continents within the Nutrient Network, a globally distributed nutrient enrichment experimentWe determined the effects of addition of experimental nitrogen (N), phosphorus (P) and potassium plus micronutrient (Kμ) on decomposition of a common tree leaf litter in a long‐term study (maximum of 7 years; exact deployment period varied across sites). The use of higher order decomposition models allowed us to distinguish between the effects of nutrients on early‐ versus late‐stage decomposition.Across continents, the addition of N (but not other nutrients) accelerated early‐stage decomposition and slowed late‐stage decomposition, increasing the slowly decomposing fraction by 28% and the overall litter mean residence time by 58%.Synthesis. Using a novel, long‐term cross‐site experiment, we found widespread evidence that N enhances the early stages of above‐ground plant litter decomposition across diverse and widespread temperate grassland sites but slows late‐stage decomposition. These findings were corroborated by fitting the data to multiple decomposition models and have implications for N effects on soil organic matter formation. For example, following N enrichment, increased microbial processing of litter substrates early in decomposition could promote the production and transfer of low molecular weight compounds to soils and potentially enhance the stabilization of mineral‐associated organic matter. By contrast, by slowing late‐stage decomposition, N enrichment could promote particulate organic matter (POM) accumulation. Such hypotheses deserve further testing. [ABSTRACT FROM AUTHOR]

Published

2022

14. Synthetic Soil Aggregates: Bioprinted Habitats for High-Throughput Microbial Metaphenomics.

Author

Smercina, Darian, Zambare, Neerja, Hofmockel, Kirsten, Sadler, Natalie, Bredeweg, Erin L., Nicora, Carrie, Markillie, Lye Meng, and Aufrecht, Jayde

Subjects

SOIL structure, HABITATS, MICROBIAL ecology, SOIL microbiology, NATURAL resources

Abstract

The dynamics of microbial processes are difficult to study in natural soil, owing to the small spatial scales on which microorganisms operate and to the opacity and chemical complexity of the soil habitat. To circumvent these challenges, we have created a 3D-bioprinted habitat that mimics aspects of natural soil aggregates while providing a chemically defined and translucent alternative culturing method for soil microorganisms. Our Synthetic Soil Aggregates (SSAs) retain the porosity, permeability, and patchy resource distribution of natural soil aggregates—parameters that are expected to influence emergent microbial community interactions. We demonstrate the printability and viability of several different microorganisms within SSAs and show how the SSAs can be integrated into a multi-omics workflow for single SSA resolution genomics, metabolomics, proteomics, lipidomics, and biogeochemical assays. We study the impact of the structured habitat on the distribution of a model co-culture microbial community and find that it is significantly different from the spatial organization of the same community in liquid culture, indicating a potential for SSAs to reproduce naturally occurring emergent community phenotypes. The SSAs have the potential as a tool to help researchers quantify microbial scale processes in situ and achieve high-resolution data from the interplay between environmental properties and microbial ecology. [ABSTRACT FROM AUTHOR]

Published

2022

15. Soil carbon stocks in temperate grasslands differ strongly across sites but are insensitive to decade‐long fertilization.

Author

Keller, Adrienne B., Borer, Elizabeth T., Collins, Scott L., DeLancey, Lang C., Fay, Philip A., Hofmockel, Kirsten S., Leakey, Andrew D.B., Mayes, Melanie A., Seabloom, Eric W., Walter, Christopher A., Wang, Yong, Zhao, Qian, and Hobbie, Sarah E.

Subjects

GRASSLAND soils, CARBON in soils, ATMOSPHERIC carbon dioxide, GRASSLANDS, SOIL mineralogy, PLANT biomass

Abstract

Enhancing soil carbon (C) storage has the potential to offset human‐caused increases in atmospheric CO2. Rising CO2 has occurred concurrently with increasing supply rates of biologically limiting nutrients such as nitrogen (N) and phosphorus (P). However, it is unclear how increased supplies of N and P will alter soil C sequestration, particularly in grasslands, which make up nearly a third of non‐agricultural land worldwide. Here, we leverage a globally distributed nutrient addition experiment (the Nutrient Network) to examine how a decade of N and P fertilization (alone and in combination) influenced soil C and N stocks at nine grassland sites spanning the continental United States. We measured changes in bulk soil C and N stocks and in three soil C fractions (light and heavy particulate organic matter, and mineral‐associated organic matter fractions). Nutrient amendment had variable effects on soil C and N pools that ranged from strongly positive to strongly negative, while soil C and N pool sizes varied by more than an order of magnitude across sites. Piecewise SEM clarified that small increases in plant C inputs with fertilization did not translate to greater soil C storage. Nevertheless, peak season aboveground plant biomass (but not root biomass or production) was strongly positively related to soil C storage at seven of the nine sites, and across all nine sites, soil C covaried with moisture index and soil mineralogy, regardless of fertilization. Overall, we show that site factors such as moisture index, plant productivity, soil texture, and mineralogy were key predictors of cross‐site soil C, while nutrient amendment had weaker and site‐specific effects on C sequestration. This suggests that prioritizing the protection of highly productive temperate grasslands is critical for reducing future greenhouse gas losses arising from land use change. [ABSTRACT FROM AUTHOR]

Published

2022

16. Ecological stoichiometry as a foundation for omics-enabled biogeochemical models of soil organic matter decomposition.

Author

Graham, Emily B. and Hofmockel, Kirsten S.

Subjects

ORGANIC compounds, METABOLIC models, STOICHIOMETRY, MODELS & modelmaking, INFORMATION sharing, NITROGEN cycle

Abstract

Coupled biogeochemical cycles drive ecosystem ecology by influencing individual-to-community scale behaviors; yet the development of process-based models that accurately capture these dynamics remains elusive. Soil organic matter (SOM) decomposition in particular is influenced by resource stoichiometry that dictates microbial nutrient acquisition ('ecological stoichiometry'). Despite its basis in biogeochemical modeling, ecological stoichiometry is only implicitly considered in high-resolution microbial investigations and the metabolic models they inform. State-of-science SOM decomposition models in both fields have advanced largely separately, but they agree on a need to move beyond seminal pool-based models. This presents an opportunity and a challenge to maximize the strengths of various models across different scales and environmental contexts. To address this challenge, we contend that ecological stoichiometry provides a framework for merging biogeochemical and microbiological models, as both explicitly consider substrate chemistries that are the basis of ecological stoichiometry as applied to SOM decomposition. We highlight two gaps that limit our understanding of SOM decomposition: (1) understanding how individual microorganisms alter metabolic strategies in response to substrate stoichiometry and (2) translating this knowledge to the scale of biogeochemical models. We suggest iterative information exchange to refine the objectives of high-resolution investigations and to specify limited dynamics for representation in large-scale models, resulting in a new class of omics-enabled biogeochemical models. Assimilating theoretical and modelling frameworks from different scientific domains is the next frontier in SOM decomposition modelling; advancing technologies in the context of stoichiometric theory provides a consistent framework for interpreting molecular data, and further distilling this information into tractable SOM decomposition models. [ABSTRACT FROM AUTHOR]

Published

2022

17. Site and Bioenergy Cropping System Similarly Affect Distinct Live and Total Soil Microbial Communities.

Author

Leichty, Sarah I., Kasanke, Christopher P., Bell, Sheryl L., and Hofmockel, Kirsten S.

Subjects

CROPPING systems, MICROBIAL communities, SOIL dynamics, ALTERNATIVE fuels, FOSSIL fuels, SOIL composition, SOIL texture, FUNGAL communities

Abstract

Bioenergy crops are a promising energy alternative to fossil fuels. During bioenergy feedstock production, crop inputs shape the composition of soil microbial communities, which in turn influences nutrient cycling and plant productivity. In addition to cropping inputs, site characteristics (e.g., soil texture, climate) influence bacterial and fungal communities. We explored the response of soil microorganisms to bioenergy cropping system (switchgrass vs. maize) and site (sandy loam vs. silty loam) within two long-term experimental research stations. The live and total microbial community membership was investigated using 16S and ITS amplicon sequencing of soil RNA and DNA. For both nucleic acid types, we expected fungi and prokaryotes to be differentially impacted by crop and site due their dissimilar life strategies. We also expected live communities to be more strongly affected by site and crop than the total communities due to a sensitivity to recent stimuli. Instead, we found that prokaryotic and fungal community composition was primarily driven by site with a secondary crop effect, highlighting the importance of soil texture and fertility in shaping both communities. Specific highly abundant prokaryotic and fungal taxa within live communities were indicative of site and cropping systems, providing insight into treatment-specific, agriculturally relevant microbial taxa that were obscured within total community profiles. Within live prokaryote communities, predatory Myxobacteria spp. were largely indicative of silty and switchgrass communities. Within live fungal communities, Glomeromycota spp. were solely indicative of switchgrass soils, while a few very abundant Mortierellomycota spp. were indicative of silty soils. Site and cropping system had distinct effects on the live and total communities reflecting selection forces of plant inputs and environmental conditions over time. Comparisons between RNA and DNA communities uncovered live members obscured within the total community as well as members of the relic DNA pool. The associations between live communities and relic DNA are a product of the intimate relationship between the ephemeral responses of the live community and the accumulation of DNA within necromass that contributes to soil organic matter, and in turn shapes soil microbial dynamics. [ABSTRACT FROM AUTHOR]

Published

2021

18. Agricultural Management Affects the Active Rhizosphere Bacterial Community Composition and Nitrification.

Author

Bay, Guillaume, Lee, Conard, Chiliang Chen, Mahal, Navreet K., Castellano, Michael J., Hofmockel, Kirsten S., and Halverson, Larry J.

Published

2021

19. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change.

Author

Salmon, Verity G., Brice, Deanne J., Bridgham, Scott, Childs, Joanne, Graham, Jake, Griffiths, Natalie A., Hofmockel, Kirsten, Iversen, Colleen M., Jicha, Terri M., Kolka, Randy K., Kostka, Joel E., Malhotra, Avni, Norby, Richard J., Phillips, Jana R., Ricciuto, Daniel, Schadt, Christopher W., Sebestyen, Stephen D., Shi, Xiaoying, Walker, Anthony P., and Warren, Jeffrey M.

Subjects

NITROGEN cycle, BOGS, PEAT mosses, NUTRIENT cycles, PEATLANDS, TWENTY-first century

Abstract

Aims: Slow decomposition and isolation from groundwater mean that ombrotrophic peatlands store a large amount of soil carbon (C) but have low availability of nitrogen (N) and phosphorus (P). To better understand the role these limiting nutrients play in determining the C balance of peatland ecosystems, we compile comprehensive N and P budgets for a forested bog in northern Minnesota, USA. Methods: N and P within plants, soils, and water are quantified based on field measurements. The resulting empirical dataset are then compared to modern-day, site-level simulations from the peatland land surface version of the Energy Exascale Earth System Model (ELM-SPRUCE). Results: Our results reveal N is accumulating in the ecosystem at 0.2 ± 0.1 g N m−2 year−1 but annual P inputs to this ecosystem are balanced by losses. Biomass stoichiometry indicates that plant functional types differ in N versus P limitation, with trees exhibiting a stronger N limitation than ericaceous shrubs or Sphagnum moss. High biomass and productivity of Sphagnum results in the moss layer storing and cycling a large proportion of plant N and P. Comparing our empirically-derived nutrient budgets to ELM-SPRUCE shows the model captures N cycling within dominant plant functional types well. Conclusions: The nutrient budgets and stoichiometry presented serve as a baseline for quantifying the nutrient cycling response of peatland ecosystems to both observed and simulated climate change. Our analysis improves our understanding of N and P dynamics within nutrient-limited peatlands and represents a crucial step toward improving C-cycle projections into the twenty-first century. [ABSTRACT FROM AUTHOR]

Published

2021

20. Moisture modulates soil reservoirs of active DNA and RNA viruses.

Author

Wu, Ruonan, Davison, Michelle R., Gao, Yuqian, Nicora, Carrie D., Mcdermott, Jason E., Burnum-Johnson, Kristin E., Hofmockel, Kirsten S., and Jansson, Janet K.

Subjects

RNA viruses, SOIL moisture, METAGENOMICS, BACTERIOPHAGES, DNA viruses

Abstract

Soil is known to harbor viruses, but the majority are uncharacterized and their responses to environmental changes are unknown. Here, we used a multi-omics approach (metagenomics, metatranscriptomics and metaproteomics) to detect active DNA viruses and RNA viruses in a native prairie soil and to determine their responses to extremes in soil moisture. The majority of transcribed DNA viruses were bacteriophage, but some were assigned to eukaryotic hosts, mainly insects. We also demonstrated that higher soil moisture increased transcription of a subset of DNA viruses. Metaproteome data validated that the specific viral transcripts were translated into proteins, including chaperonins known to be essential for virion replication and assembly. The soil viral chaperonins were phylogenetically distinct from previously described marine viral chaperonins. The soil also had a high abundance of RNA viruses, with highest representation of Reoviridae. Leviviridae were the most diverse RNA viruses in the samples, with higher amounts in wet soil. This study demonstrates that extreme shifts in soil moisture have dramatic impacts on the composition, activity and potential functions of both DNA and RNA soil viruses. Wu et al. use a multi-omics approach (metagenomics, metatranscriptomics, and metaproteomics) to characterize soil viral responses to soil moisture. The results indicate that extreme shifts in soil moisture have dramatic impacts on the composition, activity and potential functions of both DNA and RNA soil viruses. [ABSTRACT FROM AUTHOR]

Published

2021

21. Micro on a macroscale: relating microbial-scale soil processes to global ecosystem function.

Author

Smercina, Darian N, Bailey, Vanessa L, and Hofmockel, Kirsten S

Subjects

SOIL ecology, BIOGEOCHEMICAL cycles, STATISTICAL sampling, MICROBIAL ecology, SOIL sampling, CLIMATE change, SOIL microbial ecology, ECOSYSTEMS

Abstract

Soil microorganisms play a key role in driving major biogeochemical cycles and in global responses to climate change. However, understanding and predicting the behavior and function of these microorganisms remains a grand challenge for soil ecology due in part to the microscale complexity of soils. It is becoming increasingly clear that understanding the microbial perspective is vital to accurately predicting global processes. Here, we discuss the microbial perspective including the microbial habitat as it relates to measurement and modeling of ecosystem processes. We argue that clearly defining and quantifying the size, distribution and sphere of influence of microhabitats is crucial to managing microbial activity at the ecosystem scale. This can be achieved using controlled and hierarchical sampling designs. Model microbial systems can provide key data needed to integrate microhabitats into ecosystem models, while adapting soil sampling schemes and statistical methods can allow us to collect microbially-focused data. Quantifying soil processes, like biogeochemical cycles, from a microbial perspective will allow us to more accurately predict soil functions and address long-standing unknowns in soil ecology. [ABSTRACT FROM AUTHOR]

Published

2021

22. Nutrients cause consolidation of soil carbon flux to small proportion of bacterial community.

Author

Stone, Bram W., Li, Junhui, Koch, Benjamin J., Blazewicz, Steven J., Dijkstra, Paul, Hayer, Michaela, Hofmockel, Kirsten S., Liu, Xiao-Jun Allen, Mau, Rebecca L., Morrissey, Ember M., Pett-Ridge, Jennifer, Schwartz, Egbert, and Hungate, Bruce A.

Subjects

SOIL consolidation, CARBON in soils, BACTERIAL communities, MICROBIAL respiration, BACTERIAL diversity, TUNDRAS

Abstract

Nutrient amendment diminished bacterial functional diversity, consolidating carbon flow through fewer bacterial taxa. Here, we show strong differences in the bacterial taxa responsible for respiration from four ecosystems, indicating the potential for taxon-specific control over soil carbon cycling. Trends in functional diversity, defined as the richness of bacteria contributing to carbon flux and their equitability of carbon use, paralleled trends in taxonomic diversity although functional diversity was lower overall. Among genera common to all ecosystems, Bradyrhizobium, the Acidobacteria genus RB41, and Streptomyces together composed 45–57% of carbon flow through bacterial productivity and respiration. Bacteria that utilized the most carbon amendment (glucose) were also those that utilized the most native soil carbon, suggesting that the behavior of key soil taxa may influence carbon balance. Mapping carbon flow through different microbial taxa as demonstrated here is crucial in developing taxon-sensitive soil carbon models that may reduce the uncertainty in climate change projections. The fate of soil carbon depends on microbial processes, but whether different microbial taxa have individualistic effects on carbon fluxes is unknown. Here the authors use 16 S amplicon sequencing and stable isotopes to show how taxonomic differences influence bacterial respiration and carbon cycling across four ecosystems. [ABSTRACT FROM AUTHOR]

Published

2021

23. Activity‐Based Protein Profiling of Chitin Catabolism.

Author

Zegeye, Elias K., Sadler, Natalie C., Lomas, Gerard X., Attah, Isaac K., Jansson, Janet K., Hofmockel, Kirsten S., Anderton, Christopher R., and Wright, Aaron T.

Published

2021

24. Can switchgrass increase carbon accrual in marginal soils? The importance of site selection.

Author

Kasanke, Christopher P., Zhao, Qian, Bell, Sheryl, Thompson, Allison M., and Hofmockel, Kirsten S.

Subjects

SWITCHGRASS, ENERGY crops, HUMUS, CROPPING systems, SOIL chemistry, PLANT-microbe relationships

Abstract

Most soil carbon (C) is in the form of soil organic matter (SOM), the composition of which is controlled by the plant–microbe–soil continuum. The extent to which plant and microbial inputs contribute to persistent SOM has been linked to edaphic properties such as mineralogy and aggregation. However, it is unknown how variation in plant inputs, microbial community structure, and soil physical and chemical attributes interact to influence the chemical classes that comprise SOM pools. We used two long‐term biofuel feedstock field experiments to test the influence of cropping systems (corn and switchgrass) and soil characteristics (sandy and silty loams) on microbial selection and SOM chemistry. Cropping system had a strong influence on water‐extractable organic C chemistry with perennial switchgrass generally having a higher chemical richness than the annual corn cropping system. Nonetheless, cropping system was a less influential driver of soil microbial community structure and overall C chemistry than soil type. Soil type was especially influential on fungal community structure and the chemical composition of the chloroform‐extractable C. Although plant inputs strongly influence the substrates available for decomposition and SOM formation, total C and nitrogen (N) did not differ between cropping systems within either site. We conclude this is likely due to enhanced microbial activity under the perennial cropping system. Silty soils also had a higher activity of phosphate and C liberating enzymes. After 8 years, silty loams still contained twice the total C and N as sandy loams, with no significant response to biofuel cropping system inputs. Together, these results demonstrate that initial site selection is critical to plant–microbe interactions and substantially impacts the potential for long‐term C accrual in soils under biofuel feedstock production. [ABSTRACT FROM AUTHOR]

Published

2021

25. Soil Microbiomes Under Climate Change and Implications for Carbon Cycling.

Author

Naylor, Dan, Sadler, Natalie, Bhattacharjee, Arunima, Graham, Emily B., Anderton, Christopher R., McClure, Ryan, Lipton, Mary, Hofmockel, Kirsten S., and Jansson, Janet K.

Subjects

CLIMATE change, BIOGEOCHEMICAL cycles, SOILS, HISTOSOLS, CARBON in soils, CARBON cycle

Abstract

Communities of soil microorganisms (soil microbiomes) play a major role in biogeochemical cycles and support of plant growth. Here we focus primarily on the roles that the soil microbiome plays in cycling soil organic carbon and the impact of climate change on the soil carbon cycle. We first discuss current challenges in understanding the roles carried out by highly diverse and heterogeneous soil microbiomes and review existing knowledge gaps in understanding how climate change will impact soil carbon cycling by the soil microbiome. Because soil microbiome stability is a key metric to understand as the climate changes, we discuss different aspects of stability, including resistance, resilience, and functional redundancy.We then review recent research pertaining to the impact of major climate perturbations on the soil microbiome and the functions that they carry out. Finally, we review new experimental methodologies and modeling approaches under development that should facilitate our understanding of the complex nature of the soil microbiome to better predict its future responses to climate change. [ABSTRACT FROM AUTHOR]

Published

2020

26. Development and Analysis of a Stable, Reduced Complexity Model Soil Microbiome.

Author

McClure, Ryan, Naylor, Dan, Farris, Yuliya, Davison, Michelle, Fansler, Sarah J., Hofmockel, Kirsten S., and Jansson, Janet K.

Subjects

GRASSLAND soils, ARID soils, SOIL microbial ecology, SOILS, KEYSTONE species, SOIL testing, MICROBIAL communities

Abstract

The soil microbiome is central to the cycling of carbon and other nutrients and to the promotion of plant growth. Despite its importance, analysis of the soil microbiome is difficult due to its sheer complexity, with thousands of interacting species. Here, we reduced this complexity by developing model soil microbial consortia that are simpler and more amenable to experimental analysis but still represent important microbial functions of the native soil ecosystem. Samples were collected from an arid grassland soil and microbial communities (consisting mainly of bacterial species) were enriched on agar plates containing chitin as the main carbon source. Chitin was chosen because it is an abundant carbon and nitrogen polymer in soil that often requires the coordinated action of several microorganisms for complete metabolic degradation. Several soil consortia were derived that had tractable richness (30–50 OTUs) with diverse phyla representative of the native soil, including Actinobacteria, Bacteroidetes, Firmicutes, Proteobacteria, and Verrucomicrobia. The resulting consortia could be stored as glycerol or lyophilized stocks at −80°C and revived while retaining community composition, greatly increasing their use as tools for the research community at large. One of the consortia that was particularly stable was chosen as a model soil consortium (MSC-1) for further analysis. MSC-1 species interactions were studied using both pairwise co-cultivation in liquid media and during growth in soil under several perturbations. Co-abundance analyses highlighted interspecies interactions and helped to define keystone species, including Mycobacterium, Rhodococcus, and Rhizobiales taxa. These experiments demonstrate the success of an approach based on naturally enriching a community of interacting species that can be stored, revived, and shared. The knowledge gained from querying these communities and their interactions will enable better understanding of the soil microbiome and the roles these interactions play in this environment. [ABSTRACT FROM AUTHOR]

Published

2020

27. Photo-production of reactive oxygen species and degradation of dissolved organic matter by hematite nanoplates functionalized by adsorbed oxalate.

Author

Huang, Xiaopeng, Zhao, Qian, Young, Robert P., Zhang, Xin, Walter, Eric D., Chen, Ying, Nakouzi, Elias, Taylor, Sandra D., Loring, John S., Wang, Zheming, Hofmockel, Kirsten S., and Rosso, Kevin M.

Published

2020

28. Microbial processing of plant remains is co‐limited by multiple nutrients in global grasslands.

Author

Ochoa‐Hueso, Raúl, Borer, Elizabeth T., Seabloom, Eric W., Hobbie, Sarah E., Risch, Anita C., Collins, Scott L., Alberti, Juan, Bahamonde, Héctor A., Brown, Cynthia S., Caldeira, Maria C., Daleo, Pedro, Dickman, Chris R., Ebeling, Anne, Eisenhauer, Nico, Esch, Ellen H., Eskelinen, Anu, Fernández, Victoria, Güsewell, Sabine, Gutierrez‐Larruga, Blanca, and Hofmockel, Kirsten

Subjects

PLANT genetic transformation, CARBON sequestration, GRASSLANDS, SUSTAINABLE agriculture, SOIL fertility, GRASSLAND soils

Abstract

Microbial processing of aggregate‐unprotected organic matter inputs is key for soil fertility, long‐term ecosystem carbon and nutrient sequestration and sustainable agriculture. We investigated the effects of adding multiple nutrients (nitrogen, phosphorus and potassium plus nine essential macro‐ and micro‐nutrients) on decomposition and biochemical transformation of standard plant materials buried in 21 grasslands from four continents. Addition of multiple nutrients weakly but consistently increased decomposition and biochemical transformation of plant remains during the peak‐season, concurrent with changes in microbial exoenzymatic activity. Higher mean annual precipitation and lower mean annual temperature were the main climatic drivers of higher decomposition rates, while biochemical transformation of plant remains was negatively related to temperature of the wettest quarter. Nutrients enhanced decomposition most at cool, high rainfall sites, indicating that in a warmer and drier future fertilized grassland soils will have an even more limited potential for microbial processing of plant remains. [ABSTRACT FROM AUTHOR]

Published

2020

29. Measurement Error and Resolution in Quantitative Stable Isotope Probing: Implications for Experimental Design.

Author

Sieradzki, Ella T., Koch, Benjamin J., Greenlon, Alex, Sachdeva, Rohan, Malmstrom, Rex R., Mau, Rebecca L., Blazewicz, Steven J., Firestone, Mary K., Hofmockel, Kirsten S., Schwartz, Egbert, Hungate, Bruce A., and Pett-Ridge, Jennifer

Published

2020

30. Lower soil carbon stocks in exotic vs. native grasslands are driven by carbonate losses.

Author

Wilsey, Brian, Xu, Xia, Polley, H. Wayne, Hofmockel, Kirsten, and Hall, Steven J.

Subjects

CARBON in soils, GRASSLAND soils, GRASSLANDS, SOIL depth, GRASSLAND plants, SOIL sampling

Abstract

Global change includes invasion by exotic (nonnative) plant species and altered precipitation patterns, and these factors may affect terrestrial carbon (C) storage. We measured soil C changes in experimental mixtures of all exotic or all native grassland plant species under two levels of summer drought stress (0 and +128 mm). After 8 yr, soils were sampled in 10‐cm increments to 100‐cm depth to determine if soil C differed among treatments in deeper soils. Total soil C (organic + inorganic) content was significantly higher under native than exotic plantings, and differences increased with depth. Surprisingly, differences after 8 yr in C were due to carbonate and not organic C fractions, where carbonate was ~250 g C/m2 lower to 1‐m soil depth under exotic than native plantings. Our results indicate that soil carbonate is an active pool and can respond to differences in plant species traits over timescales of years. Significant losses of inorganic C might be avoided by conserving native grasslands in subhumid ecosystems. [ABSTRACT FROM AUTHOR]

Published

2020

31. Integrated network modeling approach defines key metabolic responses of soil microbiomes to perturbations.

Author

McClure, Ryan S., Lee, Joon-Yong, Chowdhury, Taniya Roy, Bottos, Eric M., White III, Richard Allen, Kim, Young-Mo, Nicora, Carrie D., Metz, Thomas O., Hofmockel, Kirsten S., Jansson, Janet K., and Song, Hyun-Seob

Subjects

METABOLISM, HUMAN microbiota, SOIL moisture, GLYCINE, PHENOTYPES

Abstract

The soil environment is constantly changing due to shifts in soil moisture, nutrient availability and other conditions. To contend with these changes, soil microorganisms have evolved a variety of ways to adapt to environmental perturbations, including regulation of gene expression. However, it is challenging to untangle the complex phenotypic response of the soil to environmental change, partly due to the absence of predictive modeling frameworks that can mechanistically link molecular-level changes in soil microorganisms to a community's functional phenotypes (or metaphenome). Towards filling this gap, we performed a combined analysis of metabolic and gene co-expression networks to explore how the soil microbiome responded to changes in soil moisture and nutrient conditions and to determine which genes were expressed under a given condition. Our integrated modeling approach revealed previously unknown, but critically important aspects of the soil microbiomes' response to environmental perturbations. Incorporation of metabolomic and transcriptomic data into metabolic reaction networks identified condition-specific signature genes that are uniquely associated with dry, wet, and glycine-amended conditions. A subsequent gene co-expression network analysis revealed that drought-associated genes occupied more central positions in a network model of the soil community, compared to the genes associated with wet, and glycine-amended conditions. These results indicate the occurrence of system-wide metabolic coordination when soil microbiomes cope with moisture or nutrient perturbations. Importantly, the approach that we demonstrate here to analyze large-scale multi-omics data from a natural soil environment is applicable to other microbiome systems for which multi-omics data are available. [ABSTRACT FROM AUTHOR]

Published

2020

32. Nitrogen Source Governs Community Carbon Metabolism in a Model Hypersaline Benthic Phototrophic Biofilm.

Author

Anderton, Christopher R., Mobberley, Jennifer M., Cole, Jessica K., Nunez, Jamie R., Starke, Robert, Boaro, Amy A., Yesiltepe, Yasemin, Morton, Beau R., Cory, Alexandra B., Cardamone, Hayley C., Hofmockel, Kirsten S., Lipton, Mary S., Moran, James J., Renslow, Ryan S., Fredrickson, James K., and Lindemann, Stephen R.

Published

2020

33. ftmsRanalysis: An R package for exploratory data analysis and interactive visualization of FT-MS data.

Author

Bramer, Lisa M., White, Amanda M., Stratton, Kelly G., Thompson, Allison M., Claborne, Daniel, Hofmockel, Kirsten, and McCue, Lee Ann

Subjects

DATA visualization, LIGNINS, DATA analysis, SOIL microbiology, SOIL composition, COMPUTER software, PROTEIN content of food

Abstract

The high-resolution and mass accuracy of Fourier transform mass spectrometry (FT-MS) has made it an increasingly popular technique for discerning the composition of soil, plant and aquatic samples containing complex mixtures of proteins, carbohydrates, lipids, lignins, hydrocarbons, phytochemicals and other compounds. Thus, there is a growing demand for informatics tools to analyze FT-MS data that will aid investigators seeking to understand the availability of carbon compounds to biotic and abiotic oxidation and to compare fundamental chemical properties of complex samples across groups. We present ftmsRanalysis, an R package which provides an extensive collection of data formatting and processing, filtering, visualization, and sample and group comparison functionalities. The package provides a suite of plotting methods and enables expedient, flexible and interactive visualization of complex datasets through functions which link to a powerful and interactive visualization user interface, Trelliscope. Example analysis using FT-MS data from a soil microbiology study demonstrates the core functionality of the package and highlights the capabilities for producing interactive visualizations. Author summary: High-resolution mass spectrometry instruments provide a mechanism for researchers to better understand the fundamental chemical composition of materials such as soil, plants, petroleum, and beverages. The large and complex data generated by analysis of these materials has led to a growing demand for software tools to aid researchers in processing, analyzing, and creating informative visualizations of these data. To move beyond existing software tools designed for specific purposes and visualizations of data from an individual sample, we present a software package, ftmsRanalysis, that provides researchers with a large collection of methods for streamlining the downstream processing high-resolution mass spectrometry data.ftmsRanalysis provides methods to compute useful chemical properties, filter data, define groups of samples, statistically compare sample groups, and make visualizations for many samples simultaneously. In this paper, we give an overview of ftmsRanalysis' general structure and capabilities. We then apply ftmsRanalysis to a soil microbiology dataset and present some of the results and visualizations generated by using the software package. [ABSTRACT FROM AUTHOR]

Published

2020

34. Soil depth and grassland origin cooperatively shape microbial community co-occurrence and function.

Author

UPTON, RACHEAL N., SIELAFF, ALEKSANDRA CHECINSKA, HOFMOCKEL, KIRSTEN S., XIA XU, POLLEY, H. WAYNE, and WILSEY, BRIAN J.

Subjects

SOIL depth, MICROBIAL communities, FUNGAL communities, GRASSLAND soils, PLANT communities, BACTERIAL communities

Abstract

Many soils are deep, yet soil below 20 cm remains largely unexplored. Exotic plants can have shallower roots than native species, so their impact on microorganisms is anticipated to change with depth. Using environmental DNA and extracellular enzymatic activities, we studied fungal and bacterial community composition, diversity, function, and co-occurrence networks between native and exotic grasslands at soil depths up to 1 m. We hypothesized (1) the composition and network structure of both fungal and bacterial communities will change with increasing depth, and diversity and enzymatic function will decrease; (2) microbial enzymatic function and network connectedness will be lower in exotic grasslands; and (3) irrigation will alter microbial networks, increasing the overall connectedness. Microbial diversity decreased with depth, and community composition was distinctly different between shallow and deeper soil depths with higher numbers of unknown taxa in lower soil depths. Fungal communities differed between native and exotic plant communities. Microbial community networks were strongly shaped by biotic and abiotic factors concurrently and were the only microbial measurement affected by irrigation. In general, fungal communities were more connected in native plant communities than exotic, especially below 10 cm. Fungal networks were also more connected at lower soil depths albeit with fewer nodes. Bacterial communities demonstrated higher complexity, and greater connectedness and nodes, at lower soil depths for native plant communities. Exotic plant communities’ bacterial network connectedness altered at lower soil depths dependent on irrigation treatments. Microbial extracellular enzyme activity for carbon cycling enzymes significantly declined with soil depth, but enzymes associated with nitrogen and phosphorus cycling continued to have similar activities up to 1 m deep. Our results indicate that native and exotic grasslands have significantly different fungal communities in depths up to 1 m and that both fungal and bacterial networks are strongly shaped jointly by plant communities and abiotic factors. Soil depth is independently a major determinant of both fungal and bacterial community structures, functions, and co-occurrence networks and demonstrates further the importance of including soil itself when investigating plant–microbe interactions. [ABSTRACT FROM AUTHOR]

Published

2020

35. Belowground Biomass Response to Nutrient Enrichment Depends on Light Limitation Across Globally Distributed Grasslands.

Author

Cleland, Elsa E., Lind, Eric M., DeCrappeo, Nicole M., DeLorenze, Elizabeth, Wilkins, Rachel Abbott, Adler, Peter B., Bakker, Jonathan D., Brown, Cynthia S., Davies, Kendi F., Esch, Ellen, Firn, Jennifer, Gressard, Scott, Gruner, Daniel S., Hagenah, Nicole, Harpole, W. Stanley, Hautier, Yann, Hobbie, Sarah E., Hofmockel, Kirsten S., Kirkman, Kevin, and Knops, Johannes

Subjects

PLANT biomass, BIOMASS, CARBON cycle, GRASSLAND soils, GRASSLANDS, NUTRIENT cycles, CARBON sequestration

Abstract

Anthropogenic activities are increasing nutrient inputs to ecosystems worldwide, with consequences for global carbon and nutrient cycles. Recent meta-analyses show that aboveground primary production is often co-limited by multiple nutrients; however, little is known about how root production responds to changes in nutrient availability. At twenty-nine grassland sites on four continents, we quantified shallow root biomass responses to nitrogen (N), phosphorus (P) and potassium plus micronutrient enrichment and compared below- and aboveground responses. We hypothesized that optimal allocation theory would predict context dependence in root biomass responses to nutrient enrichment, given variation among sites in the resources limiting to plant growth (specifically light versus nutrients). Consistent with the predictions of optimal allocation theory, the proportion of total biomass belowground declined with N or P addition, due to increased biomass aboveground (for N and P) and decreased biomass belowground (N, particularly in sites with low canopy light penetration). Absolute root biomass increased with N addition where light was abundant at the soil surface, but declined in sites where the grassland canopy intercepted a large proportion of incoming light. These results demonstrate that belowground responses to changes in resource supply can differ strongly from aboveground responses, which could significantly modify predictions of future rates of nutrient cycling and carbon sequestration. Our results also highlight how optimal allocation theory developed for individual plants may help predict belowground biomass responses to nutrient enrichment at the ecosystem scale across wide climatic and environmental gradients. [ABSTRACT FROM AUTHOR]

Published

2019

36. Evolutionary history constrains microbial traits across environmental variation.

Author

Morrissey, Ember M., Mau, Rebecca L., Hayer, Michaela, Liu, Xiao-Jun Allen, Schwartz, Egbert, Dijkstra, Paul, Koch, Benjamin J., Allen, Kara, Blazewicz, Steven J., Hofmockel, Kirsten, Pett-Ridge, Jennifer, and Hungate, Bruce A.

Published

2019

37. Selection, Succession, and Stabilization of Soil Microbial Consortia.

Author

Zegeye, Elias K., Brislawn, Colin J., Farris, Yuliya, Fansler, Sarah J., Hofmockel, Kirsten S., Jansson, Janet K., Wright, Aaron T., Graham, Emily B., Naylor, Dan, McClure, Ryan S., and Bernstein, Hans C.

Published

2019

38. Mycorrhizal colonization and its relationship with plant performance differs between exotic and native grassland plant species.

Author

Sielaff, Aleksandra Checinska, Wilsey, Brian J., Fuentes-Ramirez, Andres, Hofmockel, Kirsten, and Polley, H. Wayne

Abstract

Many grasslands have been transformed by exotic species with potentially novel ecological interactions. We hypothesized that exotic and native plant species differ, on average, in their percentage mycorrhizal colonization, and that mycorrhizal colonization is positively related to plant performance in the field. We compared colonization by arbuscular mycorrhizae (AM) fungi in perennial native and exotic species that were paired phylogenetically and by functional groups and grown under a common environment in field plots in Central Texas, USA. Roots were collected from plants in monoculture plots, stained, and percent colonization was assessed with a microscope. Aboveground biomass and dominance in mixture were used as measures of plant performance. Exotic species had significantly higher colonization of AM than native species, and this result was consistent across functional groups. Percent colonization was positively correlated with biomass and dominance in mixture across native species, but not across exotic species. Our results indicate that mycorrhizal dependence is a more important predictor of competitive balance among native than exotic plant species in the subhumid grasslands of the USA. [ABSTRACT FROM AUTHOR]

Published

2019

39. Globally consistent influences of seasonal precipitation limit grassland biomass response to elevated CO2.

Author

Hovenden, Mark J., Leuzinger, Sebastian, Newton, Paul C. D., Fletcher, Andrew, Fatichi, Simone, Lüscher, Andreas, Reich, Peter B., Andresen, Louise C., Beier, Claus, Blumenthal, Dana M., Chiariello, Nona R., Dukes, Jeffrey S., Kellner, Juliane, Hofmockel, Kirsten, Niklaus, Pascal A., Song, Jian, Wan, Shiqiang, Classen, Aimée T., and Langley, J. Adam

Published

2019

40. Microbial community structure and functions differ between native and novel (exotic-dominated) grassland ecosystems in an 8-year experiment.

Author

Checinska Sielaff, Aleksandra, Upton, Racheal N., Hofmockel, Kirsten S., Xu, Xia, Polley, H. Wayne, and Wilsey, Brian J.

Subjects

INTRODUCED species, GRASSLANDS, ECOSYSTEMS, PRECIPITATION (Chemistry), IRRIGATION

Abstract

Aims: Grasslands dominated by non-native (exotic) species have replaced purely native-dominated areas in many parts of the world forming 'novel' ecosystems. Altered precipitation patterns are predicted to exacerbate this trend. It is still poorly understood how soil microbial communities and their functions differ between high diversity native- and low diversity exotic-dominated sites and how altered precipitation will impact this difference.Methods: We sampled 64 experimental grassland plots in central Texas with plant species mixtures of either all native or all exotic species; half with summer irrigation. We tested how native vs. exotic plant species mixtures and summer irrigation affected bacterial and fungal community composition and structure, the influence of niche vs. neutral processes for microbial phylotype co-occurrence (C-score analysis), and rates of phosphorus and nitrogen mineralization across an 8-year experiment.Results: Native and exotic-dominated plots had significantly different fungal community composition and structure, but not diversity, throughout the length of the study, while changes in bacterial communities were limited to certain wet and cool years. Nitrogen and phosphorus mineralization rates were higher under native plant mixtures and correlated with the abundance of particular fungal species. Microbial communities were more structured in exotic than native grassland plots, especially for the fungal community.Conclusions: The results indicate that conversion of native to exotic C4 dominated grasslands will more strongly impact fungal than bacterial community structure. Furthermore, these impacts can alter ecosystem functioning belowground via changes in nitrogen and phosphorus cycling. [ABSTRACT FROM AUTHOR]

Published

2018

41. Portable Automation of Static Chamber Sample Collection for Quantifying Soil Gas Flux.

Author

Davis, Morgan P., Groh, Tyler A., Parkin, Timothy B., Williams, Ryan J., Isenhart, Thomas M., and Hofmockel, Kirsten S.

Published

2018

42. Differences in soil biological activity by terrain types at the sub-field scale in central Iowa US.

Author

Kaleita, Amy L., Schott, Linda R., Hargreaves, Sarah K., and Hofmockel, Kirsten S.

Subjects

SOIL microbial ecology, SOIL fertility, NUTRIENT cycles, SOIL sampling, MINERALIZATION

Abstract

Soil microbial communities are structured by biogeochemical processes that occur at many different spatial scales, which makes soil sampling difficult. Because soil microbial communities are important in nutrient cycling and soil fertility, it is important to understand how microbial communities function within the heterogeneous soil landscape. In this study, a self-organizing map was used to determine whether landscape data can be used to characterize the distribution of microbial biomass and activity in order to provide an improved understanding of soil microbial community function. Points within a row crop field in south-central Iowa were clustered via a self-organizing map using six landscape properties into three separate landscape clusters. Twelve sampling locations per cluster were chosen for a total of 36 locations. After the soil samples were collected, the samples were then analysed for various metabolic indicators, such as nitrogen and carbon mineralization, extractable organic carbon, microbial biomass, etc. It was found that sampling locations located in the potholes and toe slope positions had significantly greater microbial biomass nitrogen and carbon, total carbon, total nitrogen and extractable organic carbon than the other two landscape position clusters, while locations located on the upslope did not differ significantly from the other landscape clusters. However, factors such as nitrate, ammonia, and nitrogen and carbon mineralization did not differ significantly across the landscape. Overall, this research demonstrates the effectiveness of a terrain-based clustering method for guiding soil sampling of microbial communities. [ABSTRACT FROM AUTHOR]

Published

2017

43. Long-term carbon and nitrogen dynamics at SPRUCE revealed through stable isotopes in peat profiles.

Author

Hobbie, Erik A., Chen, Janet, Hanson, Paul J., Iversen, Colleen M., McFarlane, Karis J., Thorp, Nathan R., and Hofmockel, Kirsten S.

Subjects

PEATLANDS, PLANTS, CLIMATOLOGY, BIOGEOCHEMISTRY, VARIANCES

Abstract

Peatlands encode information about past vegetation dynamics, climate, and microbial processes. Here, we used γ15N and γ 13C patterns from 16 peat profiles to deduce how the biogeochemistry of the Marcell S1 forested bog in northern Minnesota responded to environmental and vegetation change over the past -10 000 years. In multiple regression analyses, γ 15N and γ 13C correlated strongly with depth, plot location, C = N, %N, and each other. Correlations with %N, %C, C = N, and the other isotope accounted for 80% of variance for γ 15N and 38% of variance for γ 13C, reflecting N and C losses. In contrast, correlations with depth and topography (hummock or hollow) reflected peatland successional history and climate. Higher γ 15N in plots closer to uplands may reflect upland-derived DON inputs and accompanying shifts in N dynamics in the lagg drainage area surrounding the bog. The Suess effect (declining γ 13CO2 since the Industrial Revolution) lowered γ 13C in recent surficial samples. High γ 15N from -35 to -55 cm probably indicated the depth of ectomycorrhizal activity after tree colonization of the peatland over the last 400 years, as confirmed by the occasional presence of wood down to -35 cm depth. High γ 13C at -4000 years BP (-65 to -105 cm) could re- flect a transition at that time to slower rates of peat accumulation, when 13C discrimination during peat decomposition may increase in importance. Low γ 13C and high γ 15N at -213 and -225 cm (-8500 years BP) corresponded to a warm period during a sedge-dominated rich fen stage. The above processes appear to be the primary drivers of the observed isotopic patterns, whereas there was no clear evidence for methane dynamics influencing γ 13C patterns. [ABSTRACT FROM AUTHOR]

Published

2017

44. Species composition but not diversity explains recovery from the 2011 drought in Texas grasslands.

Author

Xu, Xia, Polley, H. Wayne, Hofmockel, Kirsten, and Wilsey, Brian J.

Subjects

SYMPATRIC speciation, ORGANISMS, SPECIES hybridization, ENDOPHYTES, PLANT diversity

Abstract

Extreme droughts can have profound direct consequences for grassland ecosystems, but it is poorly known how ecosystems recover from drought and what ecological factors are associated with recovery. Recovery occurs when ecosystem functioning returns to values observed prior to a perturbation. Here, we tested for ecosystem recovery after an extreme drought in 2011 in previously established native and exotic experimental communities in Central Texas. Planted mixtures of all native and all exotic species were crossed with a summer irrigation treatment, with eight community compositions (random draws) per treatment. Prior to the drought, native plots had higher diversity than exotic plots, which sets up the prediction that the high-diversity native plots will recover more quickly than exotics. The extreme drought decreased rain-use efficiency ([RUE], annual biomass production per unit of rainfall) by 82%. Rain-use efficiency remained well below pre-drought levels during the growing season after the drought. However, on average, RUE recovered to pre-drought levels by the second growing season following drought. Exotic communities showed higher RUE than native communities, and irrigation significantly reduced RUE in both exotic and native communities across years. Interestingly, not all of the mixtures recovered from the drought, and recovery was associated with species composition, but not diversity. Rain-use efficiency recovery from drought was greatest in native communities in which the proportion of C3 forb biomass increased during and following drought and in exotic communities with a low proportion of short grass biomass. Extreme droughts can exert differential impacts on plant functional groups, leading to a drought legacy effect that reduces recovery with possible long-term repercussions. [ABSTRACT FROM AUTHOR]

Published

2017

45. Isotopic Analysis of Sporocarp Protein and Structural Material Improves Resolution of Fungal Carbon Sources.

Author

Chen, Janet, Hofmockel, Kirsten S., and Hobbie, Erik A.

Subjects

PHOTOSYNTHATES, ECTOMYCORRHIZAS, FUNGI

Abstract

Fungal acquisition of resources is difficult to assess in the field. To determine whether fungi received carbon from recent plant photosynthate, litter or soil-derived organic (C:N bonded) nitrogen, we examined differences in δ13C among bulk tissue, structural carbon, and protein extracts of sporocarps of three fungal types: saprotrophic fungi, fungi with hydrophobic ectomycorrhizae, or fungi with hydrophilic ectomycorrhizae. Sporocarps were collected from experimental plots of the Duke Free-air CO2enrichment experiment during and after CO2enrichment. The differential 13C labeling of ecosystem pools in CO2enrichment experiments was tracked into fungi and provided novel insights into organic nitrogen use. Specifically, sporocarp δ13C as well as δ15N of protein and structural material indicated that fungi with hydrophobic ectomycorrhizae used soil-derived organic nitrogen sources for protein carbon, fungi with hydrophilic ectomycorrhizae used recent plant photosynthates for protein carbon and both fungal groups used photosynthates for structural carbon. Saprotrophic fungi depended on litter produced during fumigation for both protein and structural material. [ABSTRACT FROM AUTHOR]

Published

2016

46. Identification of the Core Set of Carbon-Associated Genes in a Bioenergy Grassland Soil.

Author

Howe, Adina, Yang, Fan, Williams, Ryan J., Meyer, Folker, and Hofmockel, Kirsten S.

Subjects

GRASSLAND soils, BIOMASS energy, SOIL microbiology, CARBOHYDRATES, METAGENOMICS, CARBON cycle

Abstract

Despite the central role of soil microbial communities in global carbon (C) cycling, little is known about soil microbial community structure and even less about their metabolic pathways. Efforts to characterize soil communities often focus on identifying differences in gene content across environmental gradients, but an alternative question is what genes are similar in soils. These genes may indicate critical species or potential functions that are required in all soils. Here we identified the “core” set of C cycling sequences widely present in multiple soil metagenomes from a fertilized prairie (FP). Of 226,887 sequences associated with known enzymes involved in the synthesis, metabolism, and transport of carbohydrates, 843 were identified to be consistently prevalent across four replicate soil metagenomes. This core metagenome was functionally and taxonomically diverse, representing five enzyme classes and 99 enzyme families within the CAZy database. Though it only comprised 0.4% of all CAZy-associated genes identified in FP metagenomes, the core was found to be comprised of functions similar to those within cumulative soils. The FP CAZy-associated core sequences were present in multiple publicly available soil metagenomes and most similar to soils sharing geographic proximity. In soil ecosystems, where high diversity remains a key challenge for metagenomic investigations, these core genes represent a subset of critical functions necessary for carbohydrate metabolism, which can be targeted to evaluate important C fluxes in these and other similar soils. [ABSTRACT FROM AUTHOR]

Published

2016

47. Long-term Carbon and Nitrogen Dynamics at SPRUCE Revealed through Stable Isotopes in Peat Profiles.

Author

Hobbie, Erik A., Chen, Janet, Hanson, Paul J., Iversen, Colleen M., Mcfarlane, Karis J., Thorp, Nathan R., and Hofmockel, Kirsten S.

Subjects

SPRUCE, STABLE isotopes, CARBON cycle, NITROGEN cycle, MULTIPLE regression analysis

Abstract

We used δ15N and δ13C patterns from 16 peat depth profiles to interpret changes in C and N cycling in the Marcell S1 forested bog in northern Minnesota over the past ~ 10 000 years. In multiple regression analyses, δ15N and δ13C correlated strongly with depth, plot location, C / N,%N, and each other. Continuous variables in the regression model mainly reflected 13C and 15N fractionation accompanying N and C losses, with an estimated 40% of fractionations involving C-N bonds. In contrast, nominal variables such as plot, depth, and vegetation cover reflected peatland successional history and climate. Higher δ15N and lower δ13C in plots closer to uplands may reflect distinct hydrology and accompanying shifts in C and N dynamics in the lagg drainage area surrounding the bog. The Suess effect (declining δ13CO2 since the Industrial Revolution) and aerobic decomposition lowered δ13C in recent surficial samples. A decrease of 1 ‰ in the depth coefficient for δ15N from -35 cm to -25 cm probably indicated the depth of ectomycorrhizal activity after tree colonization of the peatland. Low δ13C at -213 cm and -225 cm (~ 8500 years BP) corresponded to a warm period during a sedge-dominated rich fen stage, whereas higher δ13C thereafter reflected subsequent cooling. Because of multiple potential mechanisms influencing δ13C, there was no clear evidence for the influence of methanogenesis or methane oxidation on bulk δ13C. [ABSTRACT FROM AUTHOR]

Published

2016

48. A time for every season: soil aggregate turnover stimulates decomposition and reduces carbon loss in grasslands managed for bioenergy.

Author

Bach, Elizabeth M. and Hofmockel, Kirsten S.

Subjects

SOIL structure, BIODEGRADATION, BIOMASS energy, CARBON in soils, GRASSLANDS

Abstract

A primary goal of many next-generation bioenergy systems is to increase ecosystem services such as soil carbon (C) storage and nutrient retention. Evaluating whether bioenergy management systems are achieving these goals is challenging in part because these processes occur over long periods of time at varying spatial scales. Investigation of microbially mediated soil processes at the microbe scale may provide early insights into the mechanisms driving these long-term ecosystem services. Furthermore, seasonal fluctuations in microbial activity are rarely considered when estimating whole ecosystem functioning, but are central to decomposition, soil structure, and realized C storage. Some studies have characterized extracellular enzyme activity within soil structures (aggregates); however, seasonal variation in decomposition at the microscale remains virtually unknown, particularly in managed ecosystems. As such, we hypothesize that temporal variation in aggregate turnover is a strong regulator of microbial activity, with important implications for decomposition and C and nitrogen (N) storage in bioenergy systems. We address variation in soil microbial extracellular enzyme activity spatially across soil aggregates and temporally across two growing seasons in three ecosystems managed for bioenergy feedstock production: Zea mays L. (corn) agroecosystem, fertilized and unfertilized reconstructed tallgrass prairie. We measured potential N-acetyl-glucosaminidase ( NAG), β-glucosidase ( BG), β-xylosidase ( BX), and cellobiohydrolase ( CB) enzyme activity. Aggregate turnover in prairie systems was driven by precipitation events and seasonal spikes in enzyme activity corresponded with aggregate turnover events. In corn monocultures, soil aggregates turned over early in the growing season, followed by increasing, albeit low, enzyme activity throughout the growing season. Independent of management system or sampling date, NAG activity was greatest in large macroaggregates (>2000 μm) and CB activity was greatest in microaggregates (<250 μm). High microbial activity coupled with greater aggregation in prairie bioenergy systems may reduce loss of soil organic matter through decomposition and increase soil C storage. [ABSTRACT FROM AUTHOR]

Published

2016

49. Plant invasions differentially affected by diversity and dominant species in native- and exotic-dominated grasslands.

Author

Xu, Xia, Polley, H. Wayne, Hofmockel, Kirsten, Daneshgar, Pedram P., and Wilsey, Brian J.

Subjects

SPECIES hybridization, GENETICS, GRASSLANDS, BIOLOGICAL invasions, PLANT succession

Abstract

Plant invasions are an increasingly serious global concern, especially as the climate changes. Here, we explored how plant invasions differed between nativeand novel exotic-dominated grasslands with experimental addition of summer precipitation in Texas in 2009. Exotic species greened up earlier than natives by an average of 18 days. This was associated with a lower invasion rate early in the growing season compared to native communities. However, invasion rate did not differ significantly between native and exotic communities across all sampling times. The predictors of invasion rate differed between native and exotic communities, with invasion being negatively influenced by species richness in natives and by dominant species in exotics. Interestingly, plant invasions matched the bimodal pattern of precipitation in Temple, Texas, and did not respond to the pulse of precipitation during the summer. Our results suggest that we will need to take different approaches in understanding of invasion between native and exotic grasslands. Moreover, with anticipated increasing variability in precipitation under global climate change, plant invasions may be constrained in their response if the precipitation pulses fall outside the normal growing period of invaders. [ABSTRACT FROM AUTHOR]

Published

2015

50. Nonlinear temperature sensitivity of enzyme kinetics explains canceling effect--a case study on loamy haplic Luvisol.

Author

Razavi, Bahar S., Blagodatskaya, Evgenia, Kuzyakov, Yakov, Strickland, Michael S., and Hofmockel, Kirsten

Subjects

LUVISOLS, CARBON cycle, GLOBAL warming & the environment

Abstract

The temperature sensitivity of enzymes responsible for organic matter decomposition in soil is crucial for predicting the effects of global warming on the carbon cycle and sequestration. We tested the hypothesis that differences in temperature sensitivity of enzyme kinetic parameters Vmax and Km will lead to a canceling effect: strong reduction of temperature response of catalytic reactions. Short-term temperature response of Vmax and Km of three hydrolytic enzymes responsible for decomposition of cellulose (b-glucosidase, cellobiohydrolase) and hemicelluloses (xylanase) were analyzed in situ from 0 to 40C. The apparent activation energy varied between enzymes from 20.7 to 35.2 kJ mol-1 corresponding to the Q10 values of the enzyme activities of 1.4-1.9 (with Vmax-Q10 1.0-2.5 and Km-Q10 0.94-2.3). Temperature response of all tested enzymes fitted well to the Arrhenius equation. Despite that, the fitting of Arrhenius model revealed the non-linear increase of two cellulolytic enzymes activities with two distinct thresholds at 10-15C and 25-30C, which were less pronounced for xylanase. The nonlinearity between 10 and 15C was explained by 30-80% increase in Vmax. At 25-30C, however, the abrupt decrease of enzyme-substrate affinity was responsible for non-linear increase of enzyme activities. Our study is the first demonstrating nonlinear response of Vmax and Km to temperature causing canceling effect, which was most strongly pronounced at low substrate concentrations and at temperatures above 15C. Under cold climate, however, the regulation of hydrolytic activity by canceling in response to warming is negligible because canceling was never observed below 10C. The canceling, therefore, can be considered as natural mechanism reducing the effects of global warming on decomposition of soil organics at moderate temperatures. The non-linearity of enzyme responses to warming and the respective thresholds should therefore be investigated for other enzymes, and incorporated into Earth system models to improve the predictions at regional and global levels. [ABSTRACT FROM AUTHOR]

Published

2015