Your search keyword '"Stephen C. Hart"' showing total 218 results

1. Standardized Data to Improve Understanding and Modeling of Soil Nitrogen at Continental Scale

Author

Samantha R. Weintraub‐Leff, Steven J. Hall, Matthew E. Craig, Debjani Sihi, Zhuonan Wang, and Stephen C. Hart

Subjects

nitrogen mineralization, soil, nitrification, NEON, CESM2, Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

Abstract Nitrogen (N) is a key limiting nutrient in terrestrial ecosystems, but there remain critical gaps in our ability to predict and model controls on soil N cycling. This may be in part due to lack of standardized sampling across broad spatial–temporal scales. Here, we introduce a continentally distributed, publicly available data set collected by the National Ecological Observatory Network (NEON) that can help fill these gaps. First, we detail the sampling design and methods used to collect and analyze soil inorganic N pool and net flux rate data from 47 terrestrial sites. We address methodological challenges in generating a standardized data set, even for a network using uniform protocols. Then, we evaluate sources of variation within the sampling design and compare measured net N mineralization to simulated fluxes from the Community Earth System Model 2 (CESM2). We observed wide spatiotemporal variation in inorganic N pool sizes and net transformation rates. Site explained the most variation in NEON’s stratified sampling design, followed by plots within sites. Organic horizons had larger pools and net N transformation rates than mineral horizons on a sample weight basis. The majority of sites showed some degree of seasonality in N dynamics, but overall these temporal patterns were not matched by CESM2, leading to poor correspondence between observed and modeled data. Looking forward, these data can reveal new insights into controls on soil N cycling, especially in the context of other environmental data sets provided by NEON, and should be leveraged to improve predictive modeling of the soil N cycle.

Published

2023

2. Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile

Author

Nicholas C. Dove, Margaret S. Torn, Stephen C. Hart, and Neslihan Taş

Subjects

Science

Abstract

There is much uncertainty on the response of soil microbial communities to warming, particularly in the subsoil. Here, the authors investigate microbial community and metabolism response to 4.5 years of whole-profile soil warming, finding depth-dependent effects and elevated subsoil microbial respiration.

Published

2021

3. Landscape Topography and Regional Drought Alters Dust Microbiomes in the Sierra Nevada of California

Author

Mia R. Maltz, Chelsea J. Carey, Hannah L. Freund, Jon K. Botthoff, Stephen C. Hart, Jason E. Stajich, Sarah M. Aarons, Sarah M. Aciego, Molly Blakowski, Nicholas C. Dove, Morgan E. Barnes, Nuttapon Pombubpa, and Emma L. Aronson

Subjects

aeolian processes, Asian desert, bacteria, biogeochemistry, dispersal, fungi, Microbiology, QR1-502

Abstract

Dust provides an ecologically significant input of nutrients, especially in slowly eroding ecosystems where chemical weathering intensity limits nutrient inputs from underlying bedrock. In addition to nutrient inputs, incoming dust is a vector for dispersing dust-associated microorganisms. While little is known about dust-microbial dispersal, dust deposits may have transformative effects on ecosystems far from where the dust was emitted. Using molecular analyses, we examined spatiotemporal variation in incoming dust microbiomes along an elevational gradient within the Sierra Nevada of California. We sampled throughout two dry seasons and found that dust microbiomes differed by elevation across two summer dry seasons (2014 and 2015), which corresponded to competing droughts in dust source areas. Dust microbial taxa richness decreased with elevation and was inversely proportional to dust heterogeneity. Likewise, dust phosphorus content increased with elevation. At lower elevations, early season dust microbiomes were more diverse than those found later in the year. The relative abundances of microbial groups shifted during the summer dry season. Furthermore, mutualistic fungal diversity increased with elevation, which may have corresponded with the biogeography of their plant hosts. Although dust fungal pathogen diversity was equivalent across elevations, elevation and sampling month interactions for the relative abundance, diversity, and richness of fungal pathogens suggest that these pathogens differed temporally across elevations, with potential implications for humans and wildlife. This study shows that landscape topography and droughts in source locations may alter the composition and diversity of ecologically relevant dust-associated microorganisms.

Published

2022

4. The influence of soil age on ecosystem structure and function across biomes

Author

Manuel Delgado-Baquerizo, Peter B. Reich, Richard D. Bardgett, David J. Eldridge, Hans Lambers, David A. Wardle, Sasha C. Reed, César Plaza, G. Kenny Png, Sigrid Neuhauser, Asmeret Asefaw Berhe, Stephen C. Hart, Hang-Wei Hu, Ji-Zheng He, Felipe Bastida, Sebastián Abades, Fernando D. Alfaro, Nick A. Cutler, Antonio Gallardo, Laura García-Velázquez, Patrick E. Hayes, Zeng-Yei Hseu, Cecilia A. Pérez, Fernanda Santos, Christina Siebe, Pankaj Trivedi, Benjamin W. Sullivan, Luis Weber-Grullon, Mark A. Williams, and Noah Fierer

Subjects

Science

Abstract

Soil age is thought to be an important driver of ecosystem development. Here, the authors perform a global survey of soil chronosequences and meta-analysis to show that, contrary to expectations, soil age is a relatively minor ecosystem driver at the biome scale once other drivers such as parent material, climate, and vegetation type are accounted for.

Published

2020

5. Soil microbial communities associated with giant sequoia: How does the world's largest tree affect some of the world's smallest organisms?

Author

Chelsea J. Carey, Sydney I. Glassman, Thomas D. Bruns, Emma L. Aronson, and Stephen C. Hart

Subjects

bacteria, fungi, next‐generation amplicon sequencing, Pinus lambertiana, Sequoiadendron giganteum, Sierra Nevada, Ecology, QH540-549.5

Abstract

Abstract Giant sequoia (Sequoiadendron giganteum) is an iconic conifer that lives in relict populations on the western slopes of the California Sierra Nevada. In these settings, it is unusual among the dominant trees in that it associates with arbuscular mycorrhizal fungi rather than ectomycorrhizal fungi. However, it is unclear whether differences in microbial associations extend more broadly to nonmycorrhizal components of the soil microbial community. To address this question, we used next‐generation amplicon sequencing to characterize bacterial/archaeal and fungal microbiomes in bulk soil (0–5 cm) beneath giant sequoia and co‐occurring sugar pine (Pinus lambertiana) individuals. We did this across two groves with distinct parent material in Yosemite National Park, USA. We found tree‐associated differences were apparent despite a strong grove effect. Bacterial/archaeal richness was greater beneath giant sequoia than sugar pine, with a core community double the size. The tree species also harbored compositionally distinct fungal communities. This pattern depended on grove but was associated with a consistently elevated relative abundance of Hygrocybe species beneath giant sequoia. Compositional differences between host trees correlated with soil pH and soil moisture. We conclude that the effects of giant sequoia extend beyond mycorrhizal mutualists to include the broader community and that some but not all host tree differences are grove‐dependent.

Published

2020

6. Multi-scale drivers of soil resistance predict vulnerability of seasonally wet meadows to trampling by pack stock animals in the Sierra Nevada, USA

Author

Joy S. Baccei, Mitchel P. McClaran, Tim J. Kuhn, and Stephen C. Hart

Subjects

Hydrogeomorphic classification, Hydrologic regime, Pack stock, Plant communities, Soil properties, Soil strength, Ecology, QH540-549.5

Abstract

Abstract Background Meadow ecosystems have important ecological functions and support socioeconomic services, yet are subject to multiple stressors that can lead to rapid degradation. In the Sierra Nevada of the western USA, recreational pack stock (horses and mules) use in seasonally wet mountain meadows may lead to soil trampling and meadow degradation, especially when soil water content is high and vegetation is developing. Methods In order to improve the ability to predict meadow vulnerability to soil disturbance from pack stock use, we measured soil resistance (SR), which is an index of vulnerability to trampling disturbance, at two spatial scales using a stratified-random sampling design. We then compared SR to several soil and vegetation explanatory variables that were also measured at the two spatial scales: plant community type (local scale) and topographic gradient class (meadow scale). Results We found that local-scale differences in drivers of SR were contingent on the meadow scale, which is important because multiple spatial scale evaluation of ecological metrics provides a broader understanding of the potential controls on ecological processes than assessments conducted at a single spatial scale. We also found two contrasting explanatory models for drivers of SR at the local scale: (1) soil gravimetric water content effects on soil disaggregation and (2) soil bulk density and root mass influence on soil cohesion. Soil resistance was insufficient to sustain pack stock use without incurring soil deformation in wet plant communities, even when plant cover was maximal during a major drought. Conclusions Our study provides new information on seasonally wet meadow vulnerability to trampling by pack stock animals using multi-scale drivers of SR, including the contrasting roles of soil disaggregation, friction, and cohesion. Our work aims to inform meadow management efforts in the Sierra Nevada and herbaceous ecosystems in similar regions that are subject to seasonal soil saturation and livestock use.

Published

2020

7. Characterization of Erwinia gerundensis A4, an Almond-Derived Plant Growth-Promoting Endophyte

Author

J. Paola Saldierna Guzmán, Mariana Reyes-Prieto, and Stephen C. Hart

Subjects

Erwinia gerundensis, endophyte, Prunus dulcis, plant growth promotion, spermidine, siderophore, Microbiology, QR1-502

Abstract

The rapidly increasing global population and anthropogenic climate change have created intense pressure on agricultural systems to produce increasingly more food under steadily challenging environmental conditions. Simultaneously, industrial agriculture is negatively affecting natural and agricultural ecosystems because of intensive irrigation and fertilization to fully utilize the potential of high-yielding cultivars. Growth-promoting microbes that increase stress tolerance and crop yield could be a useful tool for helping mitigate these problems. We investigated if commercially grown almonds might be a resource for plant colonizing bacteria with growth promotional traits that could be used to foster more productive and sustainable agricultural ecosystems. We isolated an endophytic bacterium from almond leaves that promotes growth of the model plant Arabidopsis thaliana. Genome sequencing revealed a novel Erwinia gerundensis strain (A4) that exhibits the ability to increase access to plant nutrients and to produce the stress-mitigating polyamine spermidine. Because E. gerundensis is known to be able to colonize diverse plant species including cereals and fruit trees, A4 may have the potential to be applied to a wide variety of crop systems.

Published

2021

8. Global ecological predictors of the soil priming effect

Author

Felipe Bastida, Carlos García, Noah Fierer, David J. Eldridge, Matthew A. Bowker, Sebastián Abades, Fernando D. Alfaro, Asmeret Asefaw Berhe, Nick A. Cutler, Antonio Gallardo, Laura García-Velázquez, Stephen C. Hart, Patrick E. Hayes, Teresa Hernández, Zeng-Yei Hseu, Nico Jehmlich, Martin Kirchmair, Hans Lambers, Sigrid Neuhauser, Víctor M. Peña-Ramírez, Cecilia A. Pérez, Sasha C. Reed, Fernanda Santos, Christina Siebe, Benjamin W. Sullivan, Pankaj Trivedi, Alfonso Vera, Mark A. Williams, José Luis Moreno, and Manuel Delgado-Baquerizo

Subjects

Science

Abstract

The global ecological predictors of soil priming remain unclear. Here the authors conducted a global survey of soils from 86 global locations using an isotopic approach and find that in more mesic sites with high SOC concentrations, soil priming effects are more likely to be negative.

Published

2019

9. Ecological and Genomic Attributes of Novel Bacterial Taxa That Thrive in Subsurface Soil Horizons

Author

Tess E. Brewer, Emma L. Aronson, Keshav Arogyaswamy, Sharon A. Billings, Jon K. Botthoff, Ashley N. Campbell, Nicholas C. Dove, Dawson Fairbanks, Rachel E. Gallery, Stephen C. Hart, Jason Kaye, Gary King, Geoffrey Logan, Kathleen A. Lohse, Mia R. Maltz, Emilio Mayorga, Caitlin O’Neill, Sarah M. Owens, Aaron Packman, Jennifer Pett-Ridge, Alain F. Plante, Daniel D. Richter, Whendee L. Silver, Wendy H. Yang, and Noah Fierer

Subjects

soil microbiology, metagenomics, microbial traits, critical zone, microbial ecology, Microbiology, QR1-502

Abstract

ABSTRACT While most bacterial and archaeal taxa living in surface soils remain undescribed, this problem is exacerbated in deeper soils, owing to the unique oligotrophic conditions found in the subsurface. Additionally, previous studies of soil microbiomes have focused almost exclusively on surface soils, even though the microbes living in deeper soils also play critical roles in a wide range of biogeochemical processes. We examined soils collected from 20 distinct profiles across the United States to characterize the bacterial and archaeal communities that live in subsurface soils and to determine whether there are consistent changes in soil microbial communities with depth across a wide range of soil and environmental conditions. We found that bacterial and archaeal diversity generally decreased with depth, as did the degree of similarity of microbial communities to those found in surface horizons. We observed five phyla that consistently increased in relative abundance with depth across our soil profiles: Chloroflexi, Nitrospirae, Euryarchaeota, and candidate phyla GAL15 and Dormibacteraeota (formerly AD3). Leveraging the unusually high abundance of Dormibacteraeota at depth, we assembled genomes representative of this candidate phylum and identified traits that are likely to be beneficial in low-nutrient environments, including the synthesis and storage of carbohydrates, the potential to use carbon monoxide (CO) as a supplemental energy source, and the ability to form spores. Together these attributes likely allow members of the candidate phylum Dormibacteraeota to flourish in deeper soils and provide insight into the survival and growth strategies employed by the microbes that thrive in oligotrophic soil environments. IMPORTANCE Soil profiles are rarely homogeneous. Resource availability and microbial abundances typically decrease with soil depth, but microbes found in deeper horizons are still important components of terrestrial ecosystems. By studying 20 soil profiles across the United States, we documented consistent changes in soil bacterial and archaeal communities with depth. Deeper soils harbored communities distinct from those of the more commonly studied surface horizons. Most notably, we found that the candidate phylum Dormibacteraeota (formerly AD3) was often dominant in subsurface soils, and we used genomes from uncultivated members of this group to identify why these taxa are able to thrive in such resource-limited environments. Simply digging deeper into soil can reveal a surprising number of novel microbes with unique adaptations to oligotrophic subsurface conditions.

Published

2019

10. Self-Similarity, Leaf Litter Traits, and Neighborhood Predicting Fine Root Dynamics in a Common-Garden Forest

Author

Dylan G. Fischer, Brett G. Dickson, Thomas G. Whitham, and Stephen C. Hart

Subjects

ecosystem genetics, genes-to-ecosystems, root production, Populus, condensed tannins, Environmental sciences, GE1-350

Abstract

While individual tree genotypes are known to differ in their impacts on local soil development, the spatial genetic influence of surrounding neighboring trees is largely unknown. We examine the hypothesis that fine root dynamics of a focal tree is based on the genetics of the focal tree as well as the genetics of neighbor trees that together define litter inputs to soils of the focal tree. We used a common garden environment with clonal replicates of individual tree genotypes to analyze fine root production, turnover and allocation with respect to modeled neighborhood: (1) foliar mass, (2) foliar condensed tannins (CT), (3) genetic identity of trees, and (4) genetic dissimilarity of neighbors. In support of our central hypothesis, we found that the presence of genetically dissimilar trees and high leaf CT contributions to the soil predicted increased fine root production. In fact, the modeled effects of neighbors accounted for ~90% of the explanatory weight of all models predicting root production. Nevertheless, the ultimate fate of those roots in soil (turnover) and the balance of fine roots relative to aboveground tree mass were still more predictable based on the leaf traits and genetics of the individual focal trees (explaining 99% of the variation accounted for by models). Our data provide support for a method allowing a comparison of the relative effects of individuals vs. spatial neighborhood effects on soils in a genetic context. Such comparisons are important for placing plant-soil feedbacks in a genetic and evolutionary framework because neighbors can decouple feedbacks between an individual and the surrounding environment.

Published

2019

11. Genetic variation in tree leaf chemistry predicts the abundance and activity of autotrophic soil microorganisms

Author

Paul C. Selmants, Jennifer A. Schweitzer, Karen L. Adair, Liza M. Holeski, Richard L. Lindroth, Stephen C. Hart, and Thomas G. Whitham

Subjects

ammonia oxidizers, Archaea, autotrophic soil microorganisms, bacteria, community ecosystem phenotypes, condensed tannins, Ecology, QH540-549.5

Abstract

Abstract Genetic variation in the chemistry of plant leaves can have ecosystem‐level consequences. Here, we address the hypothesis that genetic variation in foliar condensed tannins along a Populus hybridization gradient influences soil ammonia oxidizers, a group of autotrophic microorganisms that perform the first step of nitrification and are not dependent on carbon derived from plant photosynthesis. Evidence that genetically based plant traits influence the abundance and activity of autotrophic soil microbes would greatly expand the concept of extended plant phenotypes. We found that increasing foliar condensed tannin concentration reduced rates of soil nitrification potential by ~75%, reduced the abundance of ammonia‐oxidizing archaea by ~66%, but had no effect on ammonia‐oxidizing bacteria. Other indices that often drive nitrification rates, including soil total nitrogen, foliar nitrogen, and soil pH, were not significant predictors of either the activity or the abundance of ammonia oxidizers, suggesting genetic variation in foliar condensed tannins may be the dominant regulating factor. These results demonstrate the condensed tannin phenotypes of two different tree species and their naturally occurring hybrids have extended effects on a key ecosystem process and provide evidence for indirect genetic linkages among autotrophs across at least two domains of life.

Published

2019

12. Long‐term insect herbivory slows soil development in an arid ecosystem

Author

Aimee T. Classen, Samantha K. Chapman, Thomas G. Whitham, Stephen C. Hart, and George W. Koch

Subjects

carbon cycling, insect herbivory, nitrogen cycling, pine, piñon-juniper woodland, primary succession, Ecology, QH540-549.5

Abstract

Although herbivores are well known to alter litter inputs and soil nutrient fluxes, their long‐term influences on soil development are largely unknown because of the difficulty of detecting and attributing changes in carbon and nutrient pools against large background levels. The early phase of primary succession reduces this signal‐to‐noise problem, particularly in arid systems where individual plants can form islands of fertility. We used natural variation in tree‐resistance to herbivory, and a 15 year herbivore‐removal experiment in an Arizona piñon‐juniper woodland that was established on cinder soils following a volcanic eruption, to quantify how herbivory shapes the development of soil carbon (C) and nitrogen (N) over 36–54 years (i.e., the ages of the trees used in our study). In this semi‐arid ecosystem, trees are widely spaced on the landscape, which allows direct examination of herbivore impacts on the nutrient‐poor cinder soils. Although chronic insect herbivory increased annual litterfall N per unit area by 50% in this woodland, it slowed annual tree‐level soil C and N accumulation by 111% and 96%, respectively. Despite the reduction in soil C accumulation, short‐term litterfall‐C inputs and soil C‐efflux rates per unit soil surface were not impacted by herbivory. Our results demonstrate that the effects of herbivores on soil C and N fluxes and soil C and N accumulation are not necessarily congruent: herbivores can increase N in litterfall, but over time their impact on plant growth and development can slow soil development. In sum, because herbivores slow tree growth, they slow soil development on the landscape.

Published

2013

13. Invasive plants decrease microbial capacity to nitrify and denitrify compared to native California grassland communities

Author

Carey, Chelsea J, Joseph C. Blankinship, Valerie T. Eviner, Carolyn M. Malmstrom, and Stephen C. Hart

Subjects

Aegilops triuncialis, Elymus caputmedusae, Exotic plants, Soil nitrogen availability, Plant invasion, Protozoa, Environmental Sciences, Biological Sciences, Ecology

Abstract

Exotic plant invasions are a major driver of global environmental change that can significantly alter the availability of limiting nutrients such as nitrogen (N). Beginning with European colonization of California, native grasslands were replaced almost entirely by annual exotic grasses, many of which are now so ubiquitous that they are considered part of the regional flora (ânaturalizedâ). A new wave of invasive plants, such as Aegilops triuncialis (Barb goatgrass) and Elymus caput-medusae (Medusahead), continue to spread throughout the state today. To determine whether these new-wave invasive plants alter soil N dynamics, we measured inorganic N pools, nitrification and denitrification potentials, and possible mediating factors such as microbial biomass and soil pH in experimental grasslands comprised of A. triuncialis and E. caput-medusae. We compared these measurements with those from experimental grasslands containing: (1) native annuals and perennials and (2) naturalized exotic annuals. We found that A. triuncialis and E. caput-medusae significantly reduced ion-exchange resin estimates of nitrate (NOâ â») availability as well as nitrification and denitrification potentials compared to native communities. Active microbial biomass was also lower in invaded soils. In contrast, potential measurements of nitrification and denitrification were similar between invaded and naturalized communities. These results suggest that invasion by A. triuncialis and E. caput-medusae may significantly alter the capacity for soil microbial communities to nitrify or denitrify, and by extension alter soil N availability and rates of N transformations during invasion of remnant native-dominated sites.

Published

2017

14. Climatic controls on soil and saprock nitrogen distribution and persistence in the Sierra Nevada

Author

Kimber C. Moreland, Morgan E. Barnes, Anthony O'Geen, Nicholas Dove, Stephen C. Hart, and Asmeret Asefaw Berhe

Subjects

Soil Science, Plant Science

Published

2022

15. Impacts of climate and disturbance on nutrient fluxes and stoichiometry in mixed-conifer forests

Author

Yang Yang, Asmeret Asefaw Berhe, Carolyn T. Hunsaker, Dale W. Johnson, Mohammad Safeeq, Morgan E. Barnes, Emma P. McCorkle, Erin M. Stacy, Roger C. Bales, Ryan R. Bart, Michael L. Goulden, and Stephen C. Hart

Subjects

Environmental Chemistry, Earth-Surface Processes, Water Science and Technology

Published

2022

16. Climate Warming Alters Nutrient Storage in Seasonally Dry Forests: Insights From a 2,300 m Elevation Gradient

Author

Yang Yang, Asmeret Asefaw Berhe, Morgan E. Barnes, Kimber C. Moreland, Zhiyuan Tian, Anne E. Kelly, Roger C. Bales, Anthony T. O'Geen, Michael L. Goulden, Peter Hartsough, and Stephen C. Hart

Subjects

Atmospheric Science, Global and Planetary Change, Environmental Chemistry, General Environmental Science

Published

2022

17. Nutrient dynamics from surface‐applied organic matter amendments on no‐till orchard soil

Author

Sat Darshan S. Khalsa, Stephen C. Hart, and Patrick O. Brown

Subjects

chemistry.chemical_classification, Soil organic matter, Soil Science, Pollution, Decomposition, No-till farming, Nutrient, chemistry, Environmental chemistry, Environmental science, Organic matter, Orchard, Ion-exchange resin, Agronomy and Crop Science, Nitrogen cycle

Published

2021

18. Leaf endophytic microbiomes of different almond cultivars grafted to the same rootstock

Author

J. Paola Saldierna Guzmán, Nicholas C. Dove, and Stephen C. Hart

Subjects

Plant Leaves, Bacteria, Microbiota, Endophytes, General Medicine, Applied Microbiology and Biotechnology, Prunus dulcis, Biotechnology

Abstract

Aims We compared the bacterial endophytic communities of three genetically different almond cultivars that were all grafted on the same type of rootstock, growing side by side within a commercial orchard. Methods and Results We examined the diversity of leaf bacterial endophytes using cultivation-independent techniques and assessed the relative abundance of bacterial families. Two of these three cultivars were dominated by Pseudomonadaceae, while the bacterial composition of the third cultivar consisted mainly of Streptococcaceae. Conclusions The experimental set up allowed us to analyse the impact of the shoot cultivar on endophytes, minimizing the influence of rootstock, biogeography, and cultivation status. Our data suggest that the shoot cultivar can shape the leaf endophytic community composition of almond trees. Significance and Impact of the Study Our results suggest that the shoot cultivar controls the composition of the foliar bacterial endophytic community of almonds. Overall, our results could provide a first step to develop strategies for a more sustainable almond agriculture.

Published

2022

19. Impacts of climate and forest management on suspended sediment source and transport in montane headwater catchments

Author

Yang Yang, Mohammad Safeeq, Joseph W. Wagenbrenner, Asmeret Asefaw Berhe, and Stephen C. Hart

Subjects

forest thinning, Mediterranean-climate, climate change, soil erosion, hysteresis analysis, drought, Sierra Nevada, prescribed fire, Water Science and Technology

Abstract

Suspended sediment transport in montane headwaters is important to water quality and nutrient balances. However, predictions of sediment source and transport can be difficult, in part, because of a changing climate and increasing frequencies of disturbances. We used observations from 10 headwater streams in water year (WY; starting on 1st October ending on 30th September) 2007–2009 and 2013–2018 to determine the potential impacts of climate and forest management on suspended sediment delivery. We analysed hysteretic responses of suspended sediment for 76 events in five headwater catchments within a snow-dominated site and another five within a lower-elevation, rain-snow transition site, in the mixed-conifer zone of California's Sierra Nevada. Hysteresis patterns were predominantly clockwise at both sites, suggesting localized sediment sources such as streambeds and banks. The warmer, transition site exhibited a lower proportion of clockwise-loop events, faster transport speed and higher peak sediment concentrations than the snow-dominated site. This suggests extended sediment sources and increases in transport can occur as currently snow-dominated areas become rain-snow transitional. Over the nine water years, we observed similar hysteresis effects amongst years under drought, near-average, and extremely wet conditions. Hence, fluctuations in precipitation amounts across years may not influence sediment source area substantially. Furthermore, we compared hysteresis metrics between the control, thin only, burn only and thin combined with burn catchments during the posttreatment period (WY 2013– 2018). Hysteresis effects remained unchanged amongst treatments, which may be attributed to the combinations of low-intensity operations implemented with best management practises combined with a four-year drought (WY 2013–2016). Taken together, sediment sources in small headwater catchments will probably remain localized with changing precipitation levels and low-intensity management operations, but it may be extended and potentially lead to higher sediment yields as the main hydrologic input shifts from primarily snow to a mix of rain and snow.

Published

2022

20. Ecological and genomic responses of soil microbiomes to high-severity wildfire: linking community assembly to functional potential

Author

Nicholas C. Dove, Neslihan Taş, and Stephen C. Hart

Subjects

Soil, Technology, Microbiota, Genomics, Biological Sciences, Microbiology, Ecology, Evolution, Behavior and Systematics, Fires, Ecosystem, Environmental Sciences, Wildfires

Abstract

Increasing wildfire severity, which is common throughout the western United States, can have deleterious effects on plant regeneration and large impacts on carbon (C) and nitrogen (N) cycling rates. Soil microbes are pivotal in facilitating these elemental cycles, so understanding the impact of increasing fire severity on soil microbial communities is critical. Here, we assess the long-term impact of high-severity fires on the soil microbiome. We find that high-severity wildfires result in a multi-decadal (>25 y) recovery of the soil microbiome mediated by concomitant differences in aboveground vegetation, soil chemistry, and microbial assembly processes. Our results depict a distinct taxonomic and functional successional pattern of increasing selection in post-fire soil microbial communities. Changes in microbiome composition corresponded with changes in microbial functional potential, specifically altered C metabolism and enhanced N cycling potential, which related to rates of potential decomposition and inorganic N availability, respectively. Based on metagenome-assembled genomes, we show that bacterial genomes enriched in our earliest site (4 y since fire) harbor distinct traits such as a robust stress response and a high potential to degrade pyrogenic, polyaromatic C that allow them to thrive in post-fire environments. Taken together, these results provide a biological basis for previously reported process rate measurements and explain the temporal dynamics of post-fire biogeochemistry, which ultimately constrains ecosystem recovery.

Published

2022

21. Methane dynamics of high-elevation lakes in the Sierra Nevada California: the role of elevation, temperature, and inorganic nutrients

Author

Stephen C. Hart, Elisabet Perez-Coronel, and J. Michael Beman

Subjects

Elevation, Aquatic Science, Seasonality, medicine.disease, Methane, Atmosphere, chemistry.chemical_compound, Oceanography, Nutrient, chemistry, High elevation, medicine, Environmental science, Water Science and Technology

Abstract

Freshwater lakes are important but poorly constrained sources of methane (CH4) to the atmosphere, reflecting high but variable rates of CH4 production as well as limited and inconsistent measuremen...

Published

2021

22. Stream Water Chemistry in Mixed-Conifer Headwater Basins: Role of Water Sources, Seasonality, Watershed Characteristics, and Disturbances

Author

Erin M. Stacy, Dale W. Johnson, Asmeret Asefaw Berhe, Emma P. McCorkle, M. E. Barnes, Yang Yang, Carolyn T. Hunsaker, and Stephen C. Hart

Subjects

0106 biological sciences, Hydrology, Watershed, 010504 meteorology & atmospheric sciences, Ecology, Thinning, Antecedent moisture, Seasonality, medicine.disease, 010603 evolutionary biology, 01 natural sciences, Snowmelt, Dissolved organic carbon, medicine, Environmental Chemistry, Environmental science, Precipitation, Water quality, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Understanding the transport of dissolved organic carbon (DOC) and nitrogen (N) as water flows through headwater basins is important for predicting downstream water quality. With increased recognition of climatic impact on nutrient transport, more studies are needed in headwater basins experiencing a Mediterranean-type climate, such as those of the Sierra Nevada, California. We analyzed water samples collected over 5 years from eight low-order and mixed-conifer watersheds to elucidate the temporal variation of water chemistry and evaluate their responses to prolonged drought and low-intensity forest thinning. We observed higher stream DOC concentrations in October compared to other months within water years prior to drought and thinning, suggesting the importance of antecedent moisture conditions on seasonal C export. In unthinned watersheds, stream DOC concentrations were lower (62%) and DOC aromaticity was higher (68 and 92%, depending on the index used) during drought compared to non-drought years. In thinned watersheds during drought years, stream water had higher DOC concentrations (66–94% in three consecutive years following thinning) and dissolved inorganic N (24%, in the third year following thinning) compared to unthinned watersheds during drought. Additionally, lower stream DOC concentrations were found in watersheds with higher elevations and lower drainage densities in the year with near-average precipitation; however, these correlations were not significant in years with greater or extremely low precipitation. Taken together, our results suggest that stream concentrations of DOC and dissolved N in Mediterranean headwater basins are extremely variable over time due to the high temporal climatic variabilities and periodic management practices.

Published

2021

23. Montane Meadows: A Soil Carbon Sink or Source?

Author

Rachel A. Hutchinson, Stephen C. Hart, Amy G. Merrill, Benjamin W. Sullivan, Levi Keszey, Jim Wilcox, Paul S. J. Verburg, Beth Christman, W. Mark Drew, Melissa Odell, Sherman Swanson, and C. C. Reed

Subjects

geography, Watershed, geography.geographical_feature_category, Ecology, Climate change, Soil carbon, Atmospheric sciences, Sink (geography), Flux (metallurgy), Soil water, Environmental Chemistry, Montane ecology, Environmental science, Ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

As the largest biogeochemically active terrestrial reserve of carbon (C), soils have the potential to either mitigate or amplify rates of climate change. Ecosystems with large C stocks and high rates of soil C sequestration, in particular, may have outsized impacts on regional and global C cycles. Montane meadows have large soil C stocks relative to surrounding ecosystems. However, anthropogenic disturbances in many meadows may have altered the balance of C inputs and outputs, potentially converting these soils from net C sinks to net sources of C to the atmosphere. Here, we quantified ecosystem-level C inputs and outputs to estimate the annual net soil C flux from 13 montane meadows spanning a range of conditions throughout the California Sierra Nevada. Our results suggest that meadow soils can be either large net C sinks (577.6 ± 250.5 g C m−2 y−1) or sources of C to the atmosphere (− 391.6 ± 154.2 g C m−2 y−1). Variation in the direction and magnitude of net soil C flux appears to be driven by belowground C inputs. Vegetation species and functional group composition were not associated with the direction of net C flux, but climate and watershed characteristics were. Our results demonstrate that, per unit area, montane meadows hold a greater potential for C sequestration than the surrounding forest. However, legacies of disturbance have converted some meadows to strong net C sources. Accurate quantification of ecosystem-level C fluxes is critical for the development of regional C budgets and achieving global emissions goals.

Published

2020

24. The expanding role of deep roots during long‐term terrestrial ecosystem development

Author

Ashley A. Coble, Gregory S. Newman, Stephen C. Hart, Andrew L. Kowler, and Kristin E. Haskins

Subjects

Ecology, Earth science, Environmental science, Terrestrial ecosystem, Plant Science, Ecology, Evolution, Behavior and Systematics, Term (time)

Published

2020

25. Soil microbial communities associated with giant sequoia: How does the world's largest tree affect some of the world's smallest organisms?

Author

Thomas D. Bruns, Sydney I. Glassman, Stephen C. Hart, Emma L. Aronson, and Chelsea J. Carey

Subjects

0106 biological sciences, Sequoiadendron giganteum, Sequoia, Bulk soil, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, food, Pinus lambertiana, lcsh:QH540-549.5, next-generation amplicon sequencing, Sequoiadendron, Sierra Nevada, bacteria, Relative species abundance, Ecology, Evolution, Behavior and Systematics, Original Research, 030304 developmental biology, Nature and Landscape Conservation, Evolutionary Biology, 0303 health sciences, Ecology, National park, biology.organism_classification, next‐generation amplicon sequencing, food.food, Hygrocybe, lcsh:Ecology, fungi, Species richness

Abstract

Giant sequoia (Sequoiadendron giganteum) is an iconic conifer that lives in relict populations on the western slopes of the California Sierra Nevada. In these settings, it is unusual among the dominant trees in that it associates with arbuscular mycorrhizal fungi rather than ectomycorrhizal fungi. However, it is unclear whether differences in microbial associations extend more broadly to nonmycorrhizal components of the soil microbial community. To address this question, we used next‐generation amplicon sequencing to characterize bacterial/archaeal and fungal microbiomes in bulk soil (0–5 cm) beneath giant sequoia and co‐occurring sugar pine (Pinus lambertiana) individuals. We did this across two groves with distinct parent material in Yosemite National Park, USA. We found tree‐associated differences were apparent despite a strong grove effect. Bacterial/archaeal richness was greater beneath giant sequoia than sugar pine, with a core community double the size. The tree species also harbored compositionally distinct fungal communities. This pattern depended on grove but was associated with a consistently elevated relative abundance of Hygrocybe species beneath giant sequoia. Compositional differences between host trees correlated with soil pH and soil moisture. We conclude that the effects of giant sequoia extend beyond mycorrhizal mutualists to include the broader community and that some but not all host tree differences are grove‐dependent., Giant sequoia (Sequoiadendron giganteum) is an iconic conifer that lives in relict populations on the western slopes of the California Sierra Nevada. In these settings, it is unusual among the dominant trees in that it associates with arbuscular mycorrhizal fungi rather than ectomycorrhizal fungi. We found that the effects of giant sequoia extend beyond mycorrhizal mutualists to include the broader community and that some but not all host tree differences are grove‐dependent.

Published

2020

26. Phosphorus Speciation in Atmospherically Deposited Particulate Matter and Implications for Terrestrial Ecosystem Productivity

Author

Asmeret Asefaw Berhe, M. E. Barnes, Kenneth H. Williams, John N. Christensen, Ugwumsinachi G. Nwosu, Peggy A. O'Day, and Stephen C. Hart

Subjects

Colorado, Radiogenic nuclide, Isotope, Phosphorus, media_common.quotation_subject, chemistry.chemical_element, Primary production, General Chemistry, 010501 environmental sciences, Particulates, 01 natural sciences, Speciation, Productivity (ecology), chemistry, Environmental chemistry, Environmental Chemistry, Particulate Matter, Terrestrial ecosystem, Particle Size, Ecosystem, Environmental Sciences, 0105 earth and related environmental sciences, media_common

Abstract

Chemical forms of phosphorus (P) in airborne particulate matter (PM) are poorly known and do not correlate with solubility or extraction measurements commonly used to infer speciation. We used P X-ray absorption near-edge structure (XANES) and 31P nuclear magnetic resonance (NMR) spectroscopies to determine P species in PM collected at four mountain sites (Colorado and California). Organic P species dominated samples from high elevations, with organic P estimated at 65-100% of total P in bulk samples by XANES and 79-88% in extracted fractions (62-84% of total P) by NMR regardless of particle size (≥10 or 1-10 μm). Phosphorus monoester and diester organic species were dominant and present in about equal proportions, with low fractions of inorganic P species. By comparison, PM from low elevation contained mixtures of organic and inorganic P, with organic P estimated at 30-60% of total P. Intercontinental PM transport determined from radiogenic lead (Pb) isotopes varied from 0 to 59% (mean 37%) Asian-sourced Pb at high elevation, whereas stronger regional PM inputs were found at low elevation. Airborne flux of bioavailable P to high-elevation ecosystems may be twice as high as estimated by global models, which will disproportionately affect net primary productivity.

Published

2020

27. Tobacco and Cannabis Debris Survey Protocol

Author

Laurie C. Van De Werfhorst, Christopher L. Jerde, Marc W. Beutel, Andrew Brooks, Van Butsic, Srimanti Duttagupta, Michelle E. Gilmore, Thomas C. Harmon, Stephen C. Hart, Eunha Hoh, Liviu Iancu, Timnit Kefela, Thomas E. Novotny, Katelyn Nynas, Becca Reynolds, Ariani C. Wartenberg, and Patricia A. Holden

Abstract

Tobacco and cannabis product use can result in debris (a.k.a. litter) on the landscape, with implications to soil and water quality and thus potential impacts to ecosystems. More information is needed regarding how much debris exists on the landscape, such that the magnitude of potential associated environment problems can be quantified. Such information can raise awareness in the public about environmental hazards from tobacco and cannabis product use. The goal of this protocol is to quantify, via a timed survey approach, the tobacco and cannabis debris load (i.e. cigarette butts, cannabis or e-cigarette waste) at study sites. Multiple sites in a geographical location may be of interest for comparative analysis, for example sites used regularly by humans (e.g. trails, parking lots, around buildings, garbage cans) versus other sites that are suspected to have low human use. In any case, the same survey data sheet would be used (included with this protocol). Each survey will take 15 minutes per site to conduct. In the process of surveying, debris is collected and retained for later sorting, counting, and photographic documentation. The time to sort and count the collected debris will depend on the quantity and diversity of debris collected.

Published

2022

28. Depth dependence of climatic controls on soil microbial community activity and composition

Author

Asmeret Asefaw Berhe, Kimber Moreland, Robert Graham, Stephen C. Hart, M. E. Barnes, and Nicholas C. Dove

Subjects

Microbial population biology, Environmental chemistry, Environmental science, Composition (visual arts), Depth dependence, General Medicine

Abstract

Subsoil microbiomes play important roles in soil carbon and nutrient cycling, yet our understanding of the controls on subsoil microbial communities is limited. Here, we investigated the direct (mean annual temperature and precipitation) and indirect (soil chemistry) effects of climate on microbiome composition and extracellular enzyme activity throughout the soil profile across two elevation-bioclimatic gradients in central California, USA. We found that microbiome composition changes and activity decreases with depth. Across these sites, the direct influence of climate on microbiome composition and activity was relatively lower at depth. Furthermore, we found that certain microbial taxa change in relative abundance over large temperature and precipitation gradients only in specific soil horizons, highlighting the depth dependence of the climatic controls on microbiome composition. Our finding that the direct impacts of climate are muted at depth suggests that deep soil microbiomes may lag in their acclimation to new temperatures with a changing climate.

Published

2021

29. Ecological and genomic responses of soil microbiomes to high-severity wildfire: linking community assembly to functional potential

Author

Nicholas C, Dove, Neslihan, Taş, and Stephen C, Hart

Subjects

Soil, Microbiota, Genomics, Ecosystem, Fires, Wildfires

Abstract

Increasing wildfire severity, which is common throughout the western United States, can have deleterious effects on plant regeneration and large impacts on carbon (C) and nitrogen (N) cycling rates. Soil microbes are pivotal in facilitating these elemental cycles, so understanding the impact of increasing fire severity on soil microbial communities is critical. Here, we assess the long-term impact of high-severity fires on the soil microbiome. We find that high-severity wildfires result in a multi-decadal (25 y) recovery of the soil microbiome mediated by concomitant differences in aboveground vegetation, soil chemistry, and microbial assembly processes. Our results depict a distinct taxonomic and functional successional pattern of increasing selection in post-fire soil microbial communities. Changes in microbiome composition corresponded with changes in microbial functional potential, specifically altered C metabolism and enhanced N cycling potential, which related to rates of potential decomposition and inorganic N availability, respectively. Based on metagenome-assembled genomes, we show that bacterial genomes enriched in our earliest site (4 y since fire) harbor distinct traits such as a robust stress response and a high potential to degrade pyrogenic, polyaromatic C that allow them to thrive in post-fire environments. Taken together, these results provide a biological basis for previously reported process rate measurements and explain the temporal dynamics of post-fire biogeochemistry, which ultimately constrains ecosystem recovery.

Published

2021

30. Organic matter amendments improve soil fertility in almond orchards of contrasting soil texture

Author

Rebecca Ryals, Roger A. Duncan, Yocelyn B. Villa, Sat Darshan S. Khalsa, Patrick O. Brown, and Stephen C. Hart

Subjects

Crop and Pasture Production, Soil texture, Green waste, Soil Science, 010501 environmental sciences, 01 natural sciences, Analytical Chemistry, Cation-exchange capacity, Organic matter, Nutrient dynamics, 0105 earth and related environmental sciences, chemistry.chemical_classification, Decomposition, Agronomy & Agriculture, 04 agricultural and veterinary sciences, Soil carbon, Perennial crops, Cation exchange capacity, Manure, Composted manure, Agronomy, chemistry, Loam, Soil Sciences, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Soil fertility, Agronomy and Crop Science, Mulch

Abstract

The effects of organic matter amendments (OMA) on soil fertility in permanent cropping systems like orchards is under-studied compared to annual cropping systems. We evaluated experimentally the impact of OMAs on soil fertility in almond (Prunus dulcis) orchards over a two-year period with annual applications. Two OMAs, derived from composted green waste (GWC) or composted manure wood chips (MWC), were applied as surface mulch and compared to a control at two sites with different soil textures (sandy loam and loamy sand). OMAs increased soil moisture content (0–0.1 m depth) at both sites by 27–37%. Both amendments increased soil inorganic N at the sandy loam (GWC: 194%; MWC: 114%) and loamy sand (GWC: 277%; MWC: 114%) sites the month following application, but soil inorganic N concentrations quickly decreased to values similar to those of control plots. After two-years, the GWC and the MWC amendments increased the soil cation exchange capacity (CEC) by 112% and 29%, respectively, in the sandy loam site, but no change was observed in the loamy sand site. The greatest increase in soil extractable K occurred in the GWC-amended plots at the sandy loam site even though the initial K concentration of MWC was higher. Both OMAs increased soil organic carbon (SOC) after two years, but the SOC increase in the GWC-amended plots was greater. Our results suggest that OMAs can significantly improve soil fertility after one or two annual applications, and that fertility gains appear to be dependent on soil texture than the nutrient concentrations of the OMA.

Published

2021

31. Climatic vulnerabilities and ecological preferences of soil invertebrates across biomes

Author

Felipe Bastida, Antonio Gallardo, Carmen García, Stephen C. Hart, Sebastián Abades, Fernando D. Alfaro, Pankaj Trivedi, Manuel Delgado-Baquerizo, Laura García-Velázquez, Fernanda Santos, Mark A. Williams, Cecilia A. Pérez, and David J. Eldridge

Subjects

0106 biological sciences, 0301 basic medicine, Nematoda, Environmental change, Biogeography, Biome, Rotifera, Climate change, Forests, Biology, 010603 evolutionary biology, 01 natural sciences, Soil, 03 medical and health sciences, Arachnida, Genetics, Animals, Ecosystem, Ecology, Evolution, Behavior and Systematics, Invertebrate, Ecology, Vegetation, respiratory system, Invertebrates, 030104 developmental biology, Soil water, Terrestrial ecosystem, human activities

Abstract

Unlike plants and vertebrates, the ecological preferences, and potential vulnerabilities of soil invertebrates to environmental change, remain poorly understood in terrestrial ecosystems globally. We conducted a cross-biome survey including 83 locations across six continents to advance our understanding of the ecological preferences and vulnerabilities of the diversity of dominant and functionally important soil invertebrate taxa, including nematodes, arachnids and rotifers. The diversity of invertebrates was analyzed through amplicon sequencing. Vegetation and climate drove the diversity and dominant taxa of soil invertebrates. Our results suggest that declines in forest cover and plant diversity, and reductions in plant production associated with increases in aridity, can result in reductions of the diversity of soil invertebrates in a drier and more managed world. We further developed global atlases of the diversity of these important soil invertebrates, which were cross-validated using an independent database. Our study advances the current knowledge of the ecological preferences and vulnerabilities of the diversity and presence of functionally important soil invertebrates in soils from across the globe. This information is fundamental for improving and prioritizing conservation efforts of soil genetic resources and management policies.

Published

2019

32. Changes in belowground biodiversity during ecosystem development

Author

Luis Weber-Grullon, Sasha C. Reed, Víctor M. Peña-Ramírez, Osvaldo E. Sala, Antonio Gallardo, Christina Siebe, Peter M. Vitousek, Mark A. Williams, Fernando T. Maestre, Manuel Delgado-Baquerizo, Richard D. Bardgett, Asmeret Asefaw Berhe, Fernando D. Alfaro, Patrick E. Hayes, Nick A. Cutler, Hans Lambers, Cecilia A. Pérez, Matthew A. Bowker, Martin Kirchmair, Courtney M. Currier, Stephen C. Hart, Sebastián Abades, Noah Fierer, Benjamin W. Sullivan, Zeng-Yei Hseu, Sigrid Neuhauser, Fernanda Santos, Laura García-Velázquez, and David J. Eldridge

Subjects

Nutrient cycle, Life on Land, Soil biodiversity, Soil acidification, Biodiversity, soil biodiversity, Biology, Models, Biological, soil chronosequences, acidification, 03 medical and health sciences, Models, Ecosystem, 030304 developmental biology, ecosystem development, 2. Zero hunger, Abiotic component, 0303 health sciences, Multidisciplinary, Ecology, 04 agricultural and veterinary sciences, Biological Sciences, 15. Life on land, Biological, Pedogenesis, 13. Climate action, global scale, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Plant cover

Abstract

Belowground organisms play critical roles in maintaining multiple ecosystem processes, including plant productivity, decomposition, and nutrient cycling. Despite their importance, however, we have a limited understanding of how and why belowground biodiversity (bacteria, fungi, protists, and invertebrates) may change as soils develop over centuries to millennia (pedogenesis). Moreover, it is unclear whether belowground biodiversity changes during pedogenesis are similar to the patterns observed for aboveground plant diversity. Here we evaluated the roles of resource availability, nutrient stoichiometry, and soil abiotic factors in driving belowground biodiversity across 16 soil chronosequences (from centuries to millennia) spanning a wide range of globally distributed ecosystem types. Changes in belowground biodiversity during pedogenesis followed two main patterns. In lower-productivity ecosystems (i.e., drier and colder), increases in belowground biodiversity tracked increases in plant cover. In more productive ecosystems (i.e., wetter and warmer), increased acidification during pedogenesis was associated with declines in belowground biodiversity. Changes in the diversity of bacteria, fungi, protists, and invertebrates with pedogenesis were strongly and positively correlated worldwide, highlighting that belowground biodiversity shares similar ecological drivers as soils and ecosystems develop. In general, temporal changes in aboveground plant diversity and belowground biodiversity were not correlated, challenging the common perception that belowground biodiversity should follow similar patterns to those of plant diversity during ecosystem development. Taken together, our findings provide evidence that ecological patterns in belowground biodiversity are predictable across major globally distributed ecosystem types and suggest that shifts in plant cover and soil acidification during ecosystem development are associated with changes in belowground biodiversity over centuries to millennia. European Union's Horizon 2020 research and innovation program under Marie Sklodowska-Curie Grant [702057]; US National Science FoundationNational Science Foundation (NSF) [EAR1331828, DEB 1556090] This project received funding from the European Union's Horizon 2020 research and innovation program under Marie Sklodowska-Curie Grant Agreement 702057. N.F. was supported through grants from the US National Science Foundation (EAR1331828, DEB 1556090). Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the US Government. An extended version of the acknowledgments is provided in SI Appendix. Public domain – authored by a U.S. government employee

Published

2019

33. Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile

Author

Margaret S. Torn, Stephen C. Hart, Neslihan Taş, and Nicholas C. Dove

Subjects

0301 basic medicine, 16S, Nitrogen, Science, General Physics and Astronomy, Forests, Global Warming, Article, General Biochemistry, Genetics and Molecular Biology, California, Microbial ecology, 03 medical and health sciences, Soil, RNA, Ribosomal, 16S, Nitrogen cycle, Subsoil, Soil Microbiology, Ribosomal, Multidisciplinary, Bacteria, Ecology, Microbiota, Climate-change ecology, Global warming, Temperature, Soil chemistry, Carbon cycle, 04 agricultural and veterinary sciences, General Chemistry, Carbon, Soil microbiology, 030104 developmental biology, Microbial population biology, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Soil horizon, RNA, Metagenome

Abstract

Increasing global temperatures are predicted to stimulate soil microbial respiration. The direct and indirect impacts of warming on soil microbes, nevertheless, remain unclear. This is particularly true for understudied subsoil microbes. Here, we show that 4.5 years of whole-profile soil warming in a temperate mixed forest results in altered microbial community composition and metabolism in surface soils, partly due to carbon limitation. However, microbial communities in the subsoil responded differently to warming than in the surface. Throughout the soil profile—but to a greater extent in the subsoil—physiologic and genomic measurements show that phylogenetically different microbes could utilize complex organic compounds, dampening the effect of altered resource availability induced by warming. We find subsoil microbes had 20% lower carbon use efficiencies and 47% lower growth rates compared to surface soils, which constrain microbial communities. Collectively, our results show that unlike in surface soils, elevated microbial respiration in subsoils may continue without microbial community change in the near-term., There is much uncertainty on the response of soil microbial communities to warming, particularly in the subsoil. Here, the authors investigate microbial community and metabolism response to 4.5 years of whole-profile soil warming, finding depth-dependent effects and elevated subsoil microbial respiration.

Published

2021

34. Characterization of

Author

J Paola, Saldierna Guzmán, Mariana, Reyes-Prieto, and Stephen C, Hart

Subjects

plant growth promotion, siderophore, phosphate solubilization, spermidine, Erwinia gerundensis, food and beverages, endophyte, Microbiology, Prunus dulcis, Original Research

Abstract

The rapidly increasing global population and anthropogenic climate change have created intense pressure on agricultural systems to produce increasingly more food under steadily challenging environmental conditions. Simultaneously, industrial agriculture is negatively affecting natural and agricultural ecosystems because of intensive irrigation and fertilization to fully utilize the potential of high-yielding cultivars. Growth-promoting microbes that increase stress tolerance and crop yield could be a useful tool for helping mitigate these problems. We investigated if commercially grown almonds might be a resource for plant colonizing bacteria with growth promotional traits that could be used to foster more productive and sustainable agricultural ecosystems. We isolated an endophytic bacterium from almond leaves that promotes growth of the model plant Arabidopsis thaliana. Genome sequencing revealed a novel Erwinia gerundensis strain (A4) that exhibits the ability to increase access to plant nutrients and to produce the stress-mitigating polyamine spermidine. Because E. gerundensis is known to be able to colonize diverse plant species including cereals and fruit trees, A4 may have the potential to be applied to a wide variety of crop systems.

Published

2021

35. Cannabis and the Environment: What Science Tells Us and What We Still Need to Know

Author

Ariani C. Wartenberg, Thomas E. Novotny, Thomas C. Harmon, Patricia A. Holden, Hekia Bodwitch, Eunha Hoh, Michelle E. Gilmore, Marc W. Beutel, Van Butsic, Stephen C. Hart, and Phoebe Parker-Shames

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Ecology, biology, Cannabinoid Research, Environmental Science and Management, Health, Toxicology and Mutagenesis, Philosophy, 010501 environmental sciences, biology.organism_classification, 01 natural sciences, Pollution, Substance Misuse, Environmental Biotechnology, Need to know, Environmental Chemistry, Cannabis, Religious studies, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Riding the global waves of decriminalization, medical or recreational use of cannabis (Cannabis sativa spp.) is now legal in more than 50 countries and U.S. states. As governments regulate this formerly illegal crop, there is an urgent need to understand how cannabis may impact the environment. Due to the challenges of researching quasi-legal commodities, peer-reviewed studies documenting environmental impacts of cannabis are limited, slowing the development of policies and agricultural extension guidelines needed to minimize adverse environmental outcomes. Here we review peer-reviewed research on relationships between cannabis and environmental outcomes, and identify six documented impact pathways from cannabis cultivation (land-cover change, water use, pesticide use, energy use, and air pollution) and consumption (water pollution). On the basis of reviewed findings, we suggest policy directions for these pathways. We further highlight the need to formalize existing traditional and gray literature knowledge, expand research partnerships with cannabis cultivators, and ease research restrictions on cannabis. Finally, we discuss how science might contribute to minimize environmental risks and inform the development of regulations for a growing global cannabis industry.

Published

2021

36. High‐severity wildfire leads to multi‐decadal impacts on soil biogeochemistry in mixed‐conifer forests

Author

Hugh D. Safford, Gabrielle N. Bohlman, Nicholas C. Dove, Stephen C. Hart, and Becky L. Estes

Subjects

0106 biological sciences, Wildfire suppression, Ecology, Fire regime, 010604 marine biology & hydrobiology, Chronosequence, Biogeochemistry, Soil carbon, Forests, 010603 evolutionary biology, 01 natural sciences, Carbon, Wildfires, Soil, Tracheophyta, Fire protection, Plant cover, Environmental science, Nitrogen cycle, Ecosystem

Abstract

During the past century, systematic wildfire suppression has decreased fire frequency and increased fire severity in the western United States of America. While this has resulted in large ecological changes aboveground such as altered tree species composition and increased forest density, little is known about the long-term, belowground implications of altered, ecologically novel, fire regimes, especially on soil biological processes. To better understand the long-term implications of ecologically novel, high-severity fire, we used a 44-yr high-severity fire chronosequence in the Sierra Nevada where forests were historically adapted to frequent, low-severity fire, but were fire suppressed for at least 70 yr. High-severity fire in the Sierra Nevada resulted in a long-term (44 +yr) decrease (50%, P 0.05) in soil extracellular enzyme activities, basal microbial respiration (56-72%, P 0.05), and organic carbon (50%, P 0.05) in the upper 5 cm compared to sites that had not been burned for at least 115 yr. However, nitrogen (N) processes were only affected in the most recent fire site (4 yr post-fire). Net nitrification increased by over 600% in the most recent fire site (P 0.001), but returned to similar levels as the unburned control in the 13-yr site. Contrary to previous studies, we did not find a consistent effect of plant cover type on soil biogeochemical processes in mid-successional (10-50 yr) forest soils. Rather, the 44-yr reduction in soil organic carbon (C) quantity correlated positively with dampened C cycling processes. Our results show the drastic and long-term implication of ecologically novel, high-severity fire on soil biogeochemistry and underscore the need for long-term fire ecological experiments.

Published

2020

37. Multiple elements of soil biodiversity drive ecosystem functions across biomes

Author

Jun-Tao Wang, Martin Kirchmair, Mark A. Williams, Peter B. Reich, Ji-Zheng He, Nick A. Cutler, Patrick E. Hayes, Zeng-Yei Hseu, Sasha C. Reed, Hang-Wei Hu, Felipe Bastida, David J. Eldridge, Benjamin W. Sullivan, Chanda Trivedi, Brajesh K. Singh, Luis Weber-Grullon, Sigrid Neuhauser, Fernanda Santos, Manuel Delgado-Baquerizo, Sebastián Abades, Asmeret Asefaw Berhe, Cecilia A. Pérez, Stephen C. Hart, Laura García-Velázquez, Antonio Gallardo, Pankaj Trivedi, and Fernando D. Alfaro

Subjects

Nutrient cycle, Soil biodiversity, Life on Land, Biome, Biodiversity, Context (language use), 03 medical and health sciences, Soil, Humans, Ecosystem, Ecology, Evolution, Behavior and Systematics, Soil Microbiology, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, Ecology, Fungi, 04 agricultural and veterinary sciences, 15. Life on land, 13. Climate action, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Microcosm, Soil microbiology

Abstract

The role of soil biodiversity in regulating multiple ecosystem functions is poorly understood, limiting our ability to predict how soil biodiversity loss might affect human wellbeing and ecosystem sustainability. Here, combining a global observational study with an experimental microcosm study, we provide evidence that soil biodiversity (bacteria, fungi, protists and invertebrates) is significantly and positively associated with multiple ecosystem functions. These functions include nutrient cycling, decomposition, plant production, and reduced potential for pathogenicity and belowground biological warfare. Our findings also reveal the context dependency of such relationships and the importance of the connectedness, biodiversity and nature of the globally distributed dominant phylotypes within the soil network in maintaining multiple functions. Moreover, our results suggest that the positive association between plant diversity and multifunctionality across biomes is indirectly driven by soil biodiversity. Together, our results provide insights into the importance of soil biodiversity for maintaining soil functionality locally and across biomes, as well as providing strong support for the inclusion of soil biodiversity in conservation and management programmes. Combining field data from 83 sites on five continents, together with microcosm experiments, the authors show that nutrient cycling, decomposition, plant production and other ecosystem functions are positively associated with a higher diversity of a wide range of soil organisms. Marie Sklodowska-Curie We thank N. Fierer, M. Gebert, J. Henley, V. Ochoa, F. T. Maestre and B. Gozalo for their help with laboratory analyses; O. Sala, C. Siebe, C. Currier, M. A. Bowker, V. Parry, H. Lambers, P. Vitousek, V. M. Pena-Ramirez, L. Riedel, J. Larson, K. Waechter, W. Williams, S. Williams, B. Sulman, D. Buckner and B. Anacker for their help with soil sampling in Colorado, Hawaii, Iceland, New Mexico, Arizona, Mexico and Australia; the City of Boulder Open Space and Mountain Parks for allowing us to conduct these samplings; C. Cano-Diaz for her advice about R analyses; S. K. Travers for her help with mapping. This project has received funding from the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement no. 702057. M.D.-B. is supported by the Spanish Government under a Ramon y Cajal contract RYC2018-025483-I. This research is supported by the Australian Research Council projects (DP170104634; DP190103714). S.A. and F.D.A. are funded by FONDECYT 1170995, IAI-CRN 3005, PFB-23 (from CONICYT) and P05-002 (from Millennium Scientific Initiative). N.A.C. acknowledges support from Churchill College, University of Cambridge; and M.A.W. from the Wilderness State Park, Michigan for access to sample soil and conduct ecosystem survey. B.K.S. acknowledges a research award from the Humboldt Foundation. J.-Z.H. acknowledges support from the Australia Research Council (project DP170103628); and A.G. from the Spanish Ministry (project CGL2017-88124-R). F.B. thanks the Spanish Ministry and FEDER funds for the CICYT project AGL2017-85755-R, the CSIC project 201740I008 and funds from 'Fundacion Seneca' from Murcia Province (19896/GERM/15). P.T. thanks K. Little for her help with laboratory analyses. S.C.R. was supported by the US Geological Survey Ecosystems Mission Area. Any use of trade, firm or product names is for descriptive purposes only and does not imply endorsement by the US Government. S.N. was funded by the Austrian Science Fund (grant Y801-B16). Public domain – authored by a U.S. government employee

Published

2020

38. Quantifying Uncertainties in Sequential Chemical Extraction of Soil Phosphorus Using XANES Spectroscopy

Author

Oliver A. Chadwick, Benjamin L. Turner, Chunhao Gu, Mengqiang Zhu, Than T.N. Dam, Asmeret Asefaw Berhe, Stephen C. Hart, and Yongfeng Hu

Subjects

Minerals, Soil test, Nutrient management, Extraction (chemistry), Edaphic, Phosphorus, General Chemistry, 010501 environmental sciences, Phosphate, 01 natural sciences, XANES, Phosphates, chemistry.chemical_compound, Soil, X-Ray Absorption Spectroscopy, chemistry, Environmental chemistry, Soil water, Environmental Chemistry, Soil Pollutants, Dissolution, Environmental Sciences, 0105 earth and related environmental sciences

Abstract

Sequential chemical extraction has been widely used to study soil phosphorus (P) dynamics and inform nutrient management, but its efficacy for assigning P into biologically meaningful pools remains unknown. Here, we evaluated the accuracy of the modified Hedley extraction scheme using P K-edge X-ray absorption near-edge structure (XANES) spectroscopy for nine carbonate-free soil samples with diverse chemical and mineralogical properties resulting from different degrees of soil development. For most samples, the extraction markedly overestimated the pool size of calcium-bound P (Ca-P, extracted by 1 M HCl) due to (1) P redistribution during the alkaline extractions (0.5 M NaHCO3 and then 0.1 M NaOH), creating new Ca-P via formation of Ca phosphates between NaOH-desorbed phosphate and exchangeable Ca2+ and/or (2) dissolution of poorly crystalline Fe and Al oxides by 1 M HCl, releasing P occluded by these oxides into solution. The first mechanism may occur in soils rich in well-crystallized minerals and exchangeable Ca2+ regardless of the presence or absence of CaCO3, whereas the second mechanism likely operates in soils rich in poorly crystalline Fe and Al minerals. The overestimation of Ca-P simultaneously caused underestimation of the pools extracted by the alkaline solutions. Our findings identify key edaphic parameters that remarkably influenced the extractions, which will strengthen our understanding of soil P dynamics using this widely accepted procedure.

Published

2020

39. Simple methods to remove microbes from leaf surfaces

Author

Kennedy Nguyen, Stephen C. Hart, and J. Paola Saldierna Guzmán

Subjects

Pinus contorta, Microorganism, Biology, Microbiology, Applied Microbiology and Biotechnology, Endophyte, Populus fremontii, 03 medical and health sciences, Gymnosperm, Botany, Tissue damage, Endophytes, 030304 developmental biology, 0303 health sciences, 030306 microbiology, food and beverages, Sterilization, General Medicine, Sterilization (microbiology), biology.organism_classification, Pinus, Plant Leaves, Populus, Plant cuticle, leaf surface sterilization, Medical Microbiology, Microscopy, Electron, Scanning, Epiphyte, endophyte, Tree species, scanning electron microscopy

Abstract

Endophytes have been defined as microorganisms living inside plant tissues without causing negative effects on their hosts. Endophytic microbes have been extensively studied for their plant growth-promoting traits. However, analyses of endophytes require complete removal of epiphytic microorganisms. We found that the established tests to evaluate surface sterility, polymerase chain reaction, and leaf imprints, are unreliable. Therefore, we used scanning electron microscopy (SEM) as an additional assessment of epiphyte removal. We used a diverse suite of sterilization protocols to remove epiphytic microorganisms from the leaves of a gymnosperm and an angiosperm tree to test the influence of leaf morphology on the efficacy of these methods. Additionally, leaf tissue damage was also evaluated by SEM, as damaging the leaves might have an impact on endophytes and could lead to inaccurate assessment of endophytic communities. Our study indicates, that complete removal of the leaf cuticle by the sterilization technique assures loss of epiphytic microbes, and that leaves of different tree species may require different sterilization protocols. Furthermore, our study demonstrates the importance of choosing the appropriate sterilization protocol to prevent erroneous interpretation of host-endophyte interactions. Moreover, it shows the utility of SEM for evaluating the effectiveness of surface sterilization methods and their impact on leaf tissue integrity.

Published

2020

40. Nature Communications

Author

Sebastián Abades, Fernando D. Alfaro, Pankaj Trivedi, Patrick E. Hayes, G. Kenny Png, David A. Wardle, Laura García-Velázquez, Hang-Wei Hu, Peter B. Reich, Manuel Delgado-Baquerizo, Christina Siebe, Antonio Gallardo, Asmeret Asefaw Berhe, Richard D. Bardgett, Sasha C. Reed, César Plaza, Cecilia A. Pérez, Benjamin W. Sullivan, Stephen C. Hart, Noah Fierer, Mark A. Williams, Hans Lambers, Zeng-Yei Hseu, David J. Eldridge, Ji-Zheng He, Felipe Bastida, Sigrid Neuhauser, Fernanda Santos, Nick A. Cutler, Luis Weber-Grullon, European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Fundación Séneca, U.S. Geological Survey, Ministerio de Economía y Competitividad (España), Fondo Nacional de Desarrollo Científico y Tecnológico (Chile), Environmental Protection Agency (US), Asian School of the Environment, and School of Plant and Environmental Sciences

Subjects

0301 basic medicine, Time Factors, 010504 meteorology & atmospheric sciences, Life on Land, Climate, Science, Ecosystem ecology, Biome, Biodiversity, General Physics and Astronomy, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Ecosystem services, Soil, 03 medical and health sciences, Ecosystem, Biomass, lcsh:Science, Macroecology, 0105 earth and related environmental sciences, Biomass (ecology), Multidisciplinary, Ecology, Bacteria, Microbiota, Fungi, Soil chemistry, General Chemistry, Plants, 15. Life on land, Biogeochemistry, Biota, Environmental engineering [Engineering], 030104 developmental biology, 13. Climate action, Environmental science, lcsh:Q, Terrestrial ecosystem

Abstract

The importance of soil age as an ecosystem driver across biomes remains largely unresolved. By combining a cross-biome global field survey, including data for 32 soil, plant, and microbial properties in 16 soil chronosequences, with a global meta-analysis, we show that soil age is a significant ecosystem driver, but only accounts for a relatively small proportion of the cross-biome variation in multiple ecosystem properties. Parent material, climate, vegetation and topography predict, collectively, 24 times more variation in ecosystem properties than soil age alone. Soil age is an important local-scale ecosystem driver; however, environmental context, rather than soil age, determines the rates and trajectories of ecosystem development in structure and function across biomes. Our work provides insights into the natural history of terrestrial ecosystems. We propose that, regardless of soil age, changes in the environmental context, such as those associated with global climatic and land-use changes, will have important long-term impacts on the structure and function of terrestrial ecosystems across biomes., This project received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Sklodowska-Curie Grant Agreement No. 702057 (CLIMIFUN). M.D.-B. is supported by a Ramón y Cajal grant from the Spanish Ministry of Science and Innovation (RYC2018-025483-I), and by the BES Grant Agreement No. LRB17\1019 (MUSGONET). F.B. is grateful to the Spanish Ministry and FEDER funds for the project AGL2017–85755-R, the i-LINK+2018 (LINKA20069) from CSIC, and received funds from “Fundación Séneca” from Murcia Province (19896/GERM/15). S.R. was supported by the US Geological Survey Ecosystems Mission Area. C.P. acknowledges support from the Spanish State Plan for Scientific and Technical Research and Innovation (2013–2016), award ref. AGL201675762-R (AEI/FEDER, UE). A.G. acknowledges support from the Spanish Ministry of Science (CGL2017-88124-R). F.A. is supported by FONDECYT 11180538 and S.A. by FONDECYT 1170995. We would like to thank Peter Vitousek for his comments on a previous draft of this paper. Moreover, we thank Matt Gebert, Jessica Henley, Fernando T. Maestre, Victoria Ochoa, and Beatriz Gozalo for their help with lab analyses, and Emilio Guirado for his advice with topographic analyses. We also want to thank Osvaldo Sala, Matthew A. Bowker, Peter Vitousek, Courtney Currier, Martin Kirchmair, Victor M. Peña-Ramírez, Lynn Riedel, Julie Larson, Katy Waechter, David Buckner, and Brian Anacker for their help with soil sampling, and to the City of Boulder Open Space and Mountain Parks for allowing us to conduct these samplings. We are also grateful to the Division of Forestry and Wildlife of the State of Hawai’i and Koke’e State Park for their logistical assistance and for allowing us access to the HA sites. The Arizona research sites were established with the support of an EPA‐STAR Graduate Fellowship (U‐916251), a Merriam‐Powell Center for Environmental Research Graduate Fellowship, an Achievement Rewards for College Scientists (ARCS) Foundation of Arizona Scholarship, and McIntire‐Stennis appropriations to Northern Arizona University and the State of Arizona. Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the U.S. Government.

Published

2020

41. Quantifying the legacy of snowmelt timing on soil greenhouse gas emissions in a seasonally dry montane forest

Author

Stephen C. Hart, Joseph C. Blankinship, Emma P. McCorkle, and M. W. Meadows

Subjects

Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Nitrous Oxide, Microclimate, Forests, Atmospheric sciences, soil respiration, 01 natural sciences, California, Soil respiration, Greenhouse Gases, Soil, Snow, Environmental Chemistry, Ecosystem, Precipitation, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, nitrous oxide, Ecology, methane oxidation, 04 agricultural and veterinary sciences, Biological Sciences, Carbon Dioxide, Greenhouse gas, Snowmelt, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, snow manipulation, Seasons, Methane, Environmental Sciences, Southern Sierra Critical Zone Observatory

Abstract

The release of water during snowmelt orchestrates a variety of important belowground biogeochemical processes in seasonally snow-covered ecosystems, including the production and consumption of greenhouse gases (GHGs) by soil microorganisms. Snowmelt timing is advancing rapidly in these ecosystems, but there is still a need to isolate the effects of earlier snowmelt on soil GHG fluxes. For an improved mechanistic understanding of the biogeochemical effects of snowmelt timing during the snow-free period, we manipulated a high-elevation forest that typically receives over two meters of snowfall but little summer precipitation to influence legacy effects of snowmelt timing. We altered snowmelt rates for two years using black sand to accelerate snowmelt and white fabric to postpone snowmelt, thus creating a two- to three-week disparity in snowmelt timing. Soil microclimate and fluxes of carbon dioxide (CO2 ), methane (CH4 ), and nitrous oxide (N2 O) were monitored weekly to monthly during the snow-free period. Microbial abundances were estimated by potential assays near the end of each snow-free period. Although earlier snowmelt caused soil drying, we found no statistically significant effects (p

Published

2018

42. Deep in the Sierra Nevada critical zone: saprock represents a large terrestrial organic carbon stock

Author

Kimber Moreland, Zhiyuan Tian, Asmeret Asefaw Berhe, Karis J McFarlane, Peter Hartsough, Stephen C Hart, Roger Bales, and Anthony T O’Geen

Subjects

Climate Action, critical zone, deep soil carbon, Renewable Energy, Sustainability and the Environment, Public Health, Environmental and Occupational Health, Meteorology & Atmospheric Sciences, weathered bedrock, saprock, soil carbon, carbon storage, carbon biogeochemistry, General Environmental Science

Abstract

Large uncertainty remains in the spatial distribution of deep soil organic carbon (OC) storage and how climate controls belowground OC. This research aims to quantify OC stocks, characterize soil OC age and chemical composition, and evaluate climatic impacts on OC storage from the soil surface through the deep critical zone to bedrock. These objectives were carried out at four sites along a bio-climosequence in the Sierra Nevada, California. On average, 74% of OC was stored below the A horizon, and up to 30% of OC was stored in saprock (friable weakly weathered bedrock). Radiocarbon, spectroscopic, and isotopic analyses revealed the coexistence of very old organic matter (OM) (mean radiocarbon age = 20 300 years) with relatively recent OM (mean radiocarbon age = 4800 years) and highly decomposed organic compounds with relatively less decomposed material in deep soil and saprock. This co-mingling of OM suggests OC is prone to both active cycling and long-term protection from degradation. In addition to having direct effects on OC cycling, climate indirectly controls deep OC storage through its impact on the degree of regolith weathering (e.g. thickening). Although deep OC concentrations are low relative to soil, thick saprock represents a large, previously unrealized OC pool.

Published

2021

43. A Review of Environmental Pollution from the Use and Disposal of Cigarettes and Electronic Cigarettes: Contaminants, Sources, and Impacts

Author

Patricia A. Holden, Ariani C. Wartenberg, Thomas E. Novotny, Srimanti Duttagupta, Eunha Hoh, Christopher L. Jerde, Michelle E. Gilmore, Andrew Brooks, Jeremiah Mock, Laurie C. Van De Werfhorst, Van Butsic, Thomas C. Harmon, Marc W. Beutel, Stephen C. Hart, and Samuel J. Traina

Subjects

Pollution, Microplastics, environmental contamination, microplastics, media_common.quotation_subject, Geography, Planning and Development, TJ807-830, Context (language use), Environmental pollution, Management, Monitoring, Policy and Law, TD194-195, Renewable energy sources, law.invention, law, tobacco product waste, GE1-350, cotinine, media_common, Environmental effects of industries and plants, Waste management, Renewable Energy, Sustainability and the Environment, Aquatic ecosystem, fungi, Contamination, Environmental sciences, Wastewater, cigarette butts, Environmental science, Electronic cigarette, nicotine

Abstract

While the impacts of cigarette smoking on human health are widely known, a less recognized impact of tobacco product use and disposal is environmental pollution. This review discusses the current literature related to cigarette and e-cigarette contamination in the context of environmental sources and impacts, with a focus on the documented influences on biota, ranging from bacteria to mammals. Cigarette butts and electronic cigarette components can leach contaminants into soil, water, and air. Cellulose acetate cigarette filters comprising the butts are minimally degradable and are a source of bulk plastic and microplastic pollution, especially in aquatic ecosystems where they tend to accumulate. Cigarette combustion and aerosol production during e-cigarette use result in air contamination from sidestream, exhaled, and thirdhand pathways. The chemical byproducts of tobacco product use contaminate wastewater effluents, landfill leachates, and urban storm drains. The widespread detection of nicotine and cotinine in the environment illustrates the potential for large-scale environmental impacts of tobacco product waste. Studies show that cigarette butt leachate and nicotine are toxic to microbes, plants, benthic organisms, bivalves, zooplankton, fish, and mammals; however, there remain critical knowledge gaps related to the environmental impacts of tobacco product waste on environmental health and ecosystem functioning.

Published

2021

44. Competing droughts affect dust delivery to Sierra Nevada

Author

M. A. Blakowski, Jon K Botthoff, Kathleen R. Johnson, S. M. Aarons, Nicholas C. Dove, Emma L. Aronson, Janne M. Koornneef, L. Arvin, S. M. Aciego, Mia R. Maltz, M. E. Barnes, Stephen C. Hart, Clifford S. Riebe, and Geology and Geochemistry

Subjects

Dust supply, 010504 meteorology & atmospheric sciences, Drought, Biogeochemistry, Growing season, Geology, Nutrient delivery, Mineral dust, 010502 geochemistry & geophysics, 01 natural sciences, complex mixtures, respiratory tract diseases, Disturbance (ecology), Dry season, Earth Sciences, Environmental science, Ecosystem, Terrestrial ecosystem, Physical geography, Transect, Environmental Sciences, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

The generation and transport of mineral dust is strongly related to climate on seasonal, year-to-year, and glacial-interglacial timescales. The modern dust cycle is influenced by soil moisture, which is partly a function of drought duration and severity. The production and transport of dust can therefore be amplified by global and regional droughts, thereby moderating ecosystem vulnerability to disturbance through the influence of dust on nutrient delivery to ecosystems. In this work, we use strontium and neodymium isotopes in combination with trace element concentrations in modern dust samples collected in 2015 to quantify the role of regionally versus globally supplied dust in nutrient delivery to a montane ecosystem. The study sites lie along an elevational transect in the southern Sierra Nevada, USA, with samples spanning the dry seasons of 2014 (Aciego et al., 2017) and 2015 (this study), when the region was experiencing a historic drought. The goal of our research was to quantify the spatial and temporal variability and sensitivity of the dust cycle to short term changes at nutrient-limited sites. We find that, during the dry season of 2015, Asian sources contributed between 10 and 40% of dust to sites located along this elevational transect, and importantly increased in importance during the summer growing season compared to regional dust sources. These changes are likely related to the prolonged drought in Asia in 2015, highlighting both the sensitivity of dust production and transport to drought and the teleconnections of dust transport in terrestrial ecosystems.

Published

2019

45. HIV drug resistance in a cohort of HIV-infected MSM in the United States

Author

Jason E. Farley, Vanessa Cummings, Oliver Laeyendecker, Chris Beyrer, Jessica M. Fogel, James P. Hughes, Reinaldo E Fernandez, Laura McKinstry, Ethan Wilson, Susan H. Eshleman, Stephen C. Hart, Kenneth H. Mayer, Robert H. Remien, D. Scott Batey, Theresa Gamble, Carlos del Rio, and Mariya V. Sivay

Subjects

0301 basic medicine, Adult, Male, Immunology, HIV Infections, Drug resistance, Emtricitabine, Article, Cohort Studies, 03 medical and health sciences, Pre-exposure prophylaxis, Sexual and Gender Minorities, 0302 clinical medicine, Hiv infected, Environmental health, Drug Resistance, Viral, medicine, Immunology and Allergy, Humans, 030212 general & internal medicine, Viral suppression, HIV Integrase Inhibitors, Homosexuality, Male, Tenofovir, health care economics and organizations, Phylogeny, business.industry, virus diseases, Viral Load, United States, 030104 developmental biology, Infectious Diseases, Cohort, HIV-1, Pre-Exposure Prophylaxis, business, HIV drug resistance, medicine.drug, Cohort study

Abstract

OBJECTIVE: To analyze HIV drug resistance among men who have sex with men (MSM) recruited for participation in the HPTN 078 study, which evaluated methods for achieving and maintaining viral suppression in HIV-infected MSM. METHODS: Individuals were recruited at four study sites in the United States (Atlanta, Georgia; Baltimore, Maryland; Birmingham, Alabama; and Boston, Massachusetts; 2016–2017). HIV genotyping was performed using samples collected at study screening or enrollment. HIV drug resistance was evaluated using the Stanford v8.7 algorithm. A multi-assay algorithm was used to identify individuals with recent HIV infection. Clustering of HIV sequences was evaluated using phylogenetic methods. RESULTS: High-level HIV drug resistance was detected in 44 (31%) of 142 individuals (Atlanta: 21%, Baltimore: 29%, Birmingham: 53%, Boston: 26%); 12% had multi-class resistance, 16% had resistance to tenofovir or emtricitabine, and 8% had resistance to integrase strand transfer inhibitors (INSTIs); 3% had intermediate-level resistance to second-generation INSTIs. In a multivariate model, self-report of ever having been on antiretroviral therapy (ART) was associated with resistance (p=0.005). One of six recently-infected individuals had drug resistance. Phylogenetic analysis identified five clusters of study sequences; two clusters had shared resistance mutations. CONCLUSIONS: High prevalence of drug resistance was observed among MSM. Some had multi-class resistance, resistance to drugs used for pre-exposure prophylaxis (PrEP), and INSTI resistance. These findings highlight the need for improved HIV care in this high-risk population, identification of alternative regimens for PrEP, and inclusion of integrase resistance testing when selecting ART regimens for MSM in the US.

Published

2019

46. Soil microbial communities associated with giant sequoia: How does the world’s largest tree affect some of the world’s smallest organisms?

Author

Chelsea J. Carey, Stephen C. Hart, Thomas D. Bruns, Emma L. Aronson, and Sydney I. Glassman

Subjects

0106 biological sciences, 0303 health sciences, biology, Ecology, Sequoia, Bulk soil, 15. Life on land, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, food.food, 03 medical and health sciences, food, Pinus lambertiana, Soil pH, Hygrocybe, Sequoiadendron, Species richness, Relative species abundance, 030304 developmental biology

Abstract

Giant sequoia (Sequoiadendron giganteum) is an iconic conifer that lives in relic populations on the western slopes of the California Sierra Nevada. In these settings it is unusual among the dominant trees in that it associates with arbuscular mycorrhizal fungi rather than ectomycorrhizal fungi. However, it is unclear whether differences in microbial associations extends more broadly to non-mycorrhizal components of the soil microbial community. To address this question we characterized microbiomes associated with giant sequoia and co-occurring sugar pine (Pinus lambertiana) by sequencing 16S and ITS1 of the bulk soil community at two groves with distinct parent material. We found tree-associated differences were apparent despite a strong grove effect. Bacterial/archaeal richness was greater beneath giant sequoia than sugar pine, with a unique core community that was double the size. The tree species also harbored compositionally distinct fungal communities. This pattern depended on grove but was associated with a consistently elevated relative abundance ofHygrocybespecies beneath giant sequoia. Compositional differences between host trees correlated with soil pH, calcium availability, and soil moisture. We conclude that the effects of giant sequoia extend beyond mycorrhizal mutualists to include the broader community, and that some but not all host tree differences are grove-dependent.

Published

2019

47. Ecological and Genomic Attributes of Novel Bacterial Taxa That Thrive in Subsurface Soil Horizons

Author

Nicholas C. Dove, Keshav Arogyaswamy, Jennifer Pett-Ridge, Tess E. Brewer, Gary M. King, Wendy H. Yang, Whendee L. Silver, Stephen C. Hart, Geoffrey D. Logan, Sharon A. Billings, Caitlin O'Neill, Emma L. Aronson, Noah Fierer, A. Campbell, Emilio Mayorga, Kathleen A. Lohse, Daniel Richter, D. Fairbanks, Jon K Botthoff, Mia R. Maltz, Sarah M. Owens, Jason P. Kaye, Alain F. Plante, Aaron I. Packman, Rachel E. Gallery, and Martiny, Jennifer

Subjects

microbial traits, Ecological and Evolutionary Science, microbial ecology, complex mixtures, Microbiology, Nitrospirae, 03 medical and health sciences, Nutrient, Microbial ecology, Abundance (ecology), Virology, 030304 developmental biology, 2. Zero hunger, critical zone, 0303 health sciences, metagenomics, biology, Bacteria, 030306 microbiology, Ecology, Phylum, 04 agricultural and veterinary sciences, 15. Life on land, Editor's Pick, biology.organism_classification, Archaea, soil microbiology, QR1-502, Metagenomics, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Soil horizon, Terrestrial ecosystem, Energy source, Soil microbiology, Research Article

Abstract

Soil profiles are rarely homogeneous. Resource availability and microbial abundances typically decrease with soil depth, but microbes found in deeper horizons are still important components of terrestrial ecosystems. By studying 20 soil profiles across the United States, we documented consistent changes in soil bacterial and archaeal communities with depth. Deeper soils harbored communities distinct from those of the more commonly studied surface horizons. Most notably, we found that the candidate phylum Dormibacteraeota (formerly AD3) was often dominant in subsurface soils, and we used genomes from uncultivated members of this group to identify why these taxa are able to thrive in such resource-limited environments. Simply digging deeper into soil can reveal a surprising number of novel microbes with unique adaptations to oligotrophic subsurface conditions., While most bacterial and archaeal taxa living in surface soils remain undescribed, this problem is exacerbated in deeper soils, owing to the unique oligotrophic conditions found in the subsurface. Additionally, previous studies of soil microbiomes have focused almost exclusively on surface soils, even though the microbes living in deeper soils also play critical roles in a wide range of biogeochemical processes. We examined soils collected from 20 distinct profiles across the United States to characterize the bacterial and archaeal communities that live in subsurface soils and to determine whether there are consistent changes in soil microbial communities with depth across a wide range of soil and environmental conditions. We found that bacterial and archaeal diversity generally decreased with depth, as did the degree of similarity of microbial communities to those found in surface horizons. We observed five phyla that consistently increased in relative abundance with depth across our soil profiles: Chloroflexi, Nitrospirae, Euryarchaeota, and candidate phyla GAL15 and Dormibacteraeota (formerly AD3). Leveraging the unusually high abundance of Dormibacteraeota at depth, we assembled genomes representative of this candidate phylum and identified traits that are likely to be beneficial in low-nutrient environments, including the synthesis and storage of carbohydrates, the potential to use carbon monoxide (CO) as a supplemental energy source, and the ability to form spores. Together these attributes likely allow members of the candidate phylum Dormibacteraeota to flourish in deeper soils and provide insight into the survival and growth strategies employed by the microbes that thrive in oligotrophic soil environments.

Published

2019

48. Nature Communications

Author

Sasha C. Reed, Sebastián Abades, José L. Moreno, Carmen García, Antonio Gallardo, Patrick E. Hayes, Teresa Hernández, Alfonso Vera, Víctor M. Peña-Ramírez, Christina Siebe, Hans Lambers, Laura García-Velázquez, Stephen C. Hart, Felipe Bastida, Nick A. Cutler, Noah Fierer, Pankaj Trivedi, Matthew A. Bowker, Martin Kirchmair, Fernando D. Alfaro, Sigrid Neuhauser, Asmeret Asefaw Berhe, Fernanda Santos, Mark A. Williams, Zeng-Yei Hseu, David J. Eldridge, Nico Jehmlich, Cecilia A. Pérez, Manuel Delgado-Baquerizo, Benjamin W. Sullivan, and School of Plant and Environmental Sciences

Subjects

0301 basic medicine, Science, General Physics and Astronomy, 02 engineering and technology, complex mixtures, General Biochemistry, Genetics and Molecular Biology, Article, Carbon cycle, 03 medical and health sciences, lcsh:Science, Multidisciplinary, Ecology, Soil organic matter, Global change, General Chemistry, Biodiversity, 15. Life on land, 021001 nanoscience & nanotechnology, Arid, 030104 developmental biology, Soil water, Environmental science, Terrestrial ecosystem, lcsh:Q, 0210 nano-technology, Cycling, Priming (psychology)

Abstract

Identifying the global drivers of soil priming is essential to understanding C cycling in terrestrial ecosystems. We conducted a survey of soils across 86 globally-distributed locations, spanning a wide range of climates, biotic communities, and soil conditions, and evaluated the apparent soil priming effect using 13C-glucose labeling. Here we show that the magnitude of the positive apparent priming effect (increase in CO2 release through accelerated microbial biomass turnover) was negatively associated with SOC content and microbial respiration rates. Our statistical modeling suggests that apparent priming effects tend to be negative in more mesic sites associated with higher SOC contents. In contrast, a single-input of labile C causes positive apparent priming effects in more arid locations with low SOC contents. Our results provide solid evidence that SOC content plays a critical role in regulating apparent priming effects, with important implications for the improvement of C cycling models under global change scenarios., The global ecological predictors of soil priming remain unclear. Here the authors conducted a global survey of soils from 86 global locations using an isotopic approach and find that in more mesic sites with high SOC concentrations, soil priming effects are more likely to be negative.

Published

2019

49. Fight or flight? Potential tradeoffs between drought defense and reproduction in conifers

Author

Emily V. Moran, Stephen C. Hart, Jeffrey Lauder, and Polle, Andrea

Subjects

0106 biological sciences, Drought stress, Physiology, Offspring, ecophysiology, Reproduction (economics), Plant Biology & Botany, Plant Biology, Plant Science, Biology, Forests, 010603 evolutionary biology, 01 natural sciences, Life history theory, Trees, Fight-or-flight response, Xylem, Behavioral and Social Science, ecological tradeoffs, life history traits, Ecology, Forestry Sciences, fungi, food and beverages, Stress defense, Droughts, Tracheophyta, Good Health and Well Being, carbon allocation, Resource allocation, xylem anatomy, hydraulic architecture, 010606 plant biology & botany

Abstract

Plants frequently exhibit tradeoffs between reproduction and growth when resources are limited, and often change these allocation patterns in response to stress. Shorter-lived plants such as annuals tend to allocate relatively more resources toward reproduction when stressed, while longer-lived plants tend to invest more heavily in survival and stress defense. However, severe stress may affect the fitness implications of allocating relatively more resources to reproduction versus stress defense. Increased drought intensity and duration have led to widespread mortality events in coniferous forests. In this review, we ask how potential tradeoffs between reproduction and survival influence the likelihood of drought-induced mortality and species persistence. We propose that trees may exhibit what we call ‘fight or flight’ behaviors under stress. ‘Fight’ behaviors involve greater resource allocation toward survival (e.g., growth, drought-resistant xylem and pest defense). ‘Flight’ consists of higher relative allocation of resources to reproduction, potentially increasing both offspring production and mortality risk for the adult. We hypothesize that flight behaviors increase as drought stress escalates the likelihood of mortality in a given location.

Published

2019

50. Carbon Control on Terrestrial Ecosystem Function Across Contrasting Site Productivities: The Carbon Connection Revisited

Author

Stephen C. Hart, Gregory S. Newman, Nicholas C. Dove, John M. Stark, and John Wiley & Sons, Inc.

Subjects

0106 biological sciences, Life on Land, Nitrogen, Ecology and Evolutionary Biology, microbial ecology, 010603 evolutionary biology, 01 natural sciences, soil carbon availability, Oregon, Soil, Microbial ecology, Affordable and Clean Energy, gross N mineralization, microbial respiration, Forest ecology, nitrogen cycle, Ecosystem, Biomass, 15N pool dilution, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, Soil Microbiology, Evolutionary Biology, Ecology, Chemistry, 010604 marine biology & hydrobiology, phospholipid fatty acid analysis, Soil carbon, Mineralization (soil science), extracellular enzyme activity, N-15 pool dilution, Carbon, meta-analysis, Microbial population biology, Agronomy, Ecological Applications, carbon-use efficiency, Terrestrial ecosystem, gross N immobilization

Abstract

Understanding how altered soil organic carbon (SOC) availability affects microbial communities and their function is imperative in predicting impacts of global change on soil carbon (C) storage and ecosystem function. However, the response of soil microbial communities and their function to depleted C availability insitu is unclear. We evaluated the role of soil C inputs in controlling microbial biomass, community composition, physiology, and function by (1) experimentally excluding plant C inputs insitu for 9 yr in four temperate forest ecosystems along a productivity gradient in Oregon, USA; and (2) integrating these findings with published data from similar C-exclusion studies into a global meta-analysis. Excluding plant C inputs for 9 yr resulted in a 13% decrease in SOC across the four Oregon sites and an overall shift in the microbial community composition, with a 45% decrease in the fungal:bacterial ratio and a 13% increase in Gram-positive:Gram-negative bacterial ratio. Although gross N mineralization decreased under C exclusion, decreases in gross N immobilization were greater, resulting in increased net N mineralization rates in all but the lowest-productivity site. Microbial biomass showed a variable response to C exclusion that was method dependent; however, we detected a 29% decrease in C-use efficiency across the sites, with greater declines occurring in less-productive sites. Although extracellular enzyme activity increased with C exclusion, C exclusion resulted in a 31% decrease in microbial respiration across all sites. Our meta-analyses of published data with similar C-exclusion treatments were largely consistent with our experimental results, showing decreased SOC, fungal:bacterial ratios, and microbial respiration, and increased Gram-positive:Gram-negative bacterial ratio following exclusion of C inputs to soil. Effect sizes of SOC and respiration correlated negatively with the duration of C exclusion; however, there were immediate effects of C exclusion on microbial community composition and biomass that were unaltered by duration of treatment. Our field-based experimental results and analyses demonstrate unequivocally the dominant control of C availability on soil microbial biomass, community composition, and function, and provide additional insight into the mechanisms for these effects in forest ecosystems.

Published

2019