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1. The path from root input to mineral-associated soil carbon is dictated by habitat-specific microbial traits and soil moisture

Author

Sokol, Noah W, Foley, Megan M, Blazewicz, Steven J, Bhattacharyya, Amrita, DiDonato, Nicole, Estera-Molina, Katerina, Firestone, Mary, Greenlon, Alex, Hungate, Bruce A, Kimbrel, Jeffrey, Liquet, Jose, Lafler, Marissa, Marple, Maxwell, Nico, Peter S, Paša-Tolić, Ljiljana, Slessarev, Eric, and Pett-Ridge, Jennifer

Subjects
Environmental Sciences, Soil Sciences, Soil carbon, Microbial traits, Mineral -associated organic carbon, Drought, Carbon cycle, Global change, Stable isotope probing, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture, Soil sciences
Abstract

Soil microorganisms help transform plant inputs into mineral-associated soil organic carbon (SOC) – the largest and slowest-cycling pool of organic carbon on land. However, the microbial traits that influence this process are widely debated. While current theory and biogeochemical models have settled on carbon-use efficiency (CUE) and growth rate as positive predictors of mineral-associated SOC, empirical tests are sparse, with contradictory observations. Using 13C-labeling of an annual grass (Avena barbata) under two moisture regimes, we found that microbial traits associated with formation of 13C-mineral-associated SOC varied by soil habitat, as did active microbial taxa and SOC chemical composition. In the rhizosphere, bacterial-dominated communities with fast growth, high biomass, and high extracellular polymeric substance (EPS) production were positively associated with 13C-mineral-associated SOC. In contrast, the detritusphere held communities dominated by fungi and more filamentous bacteria, and with greater exoenzyme activity; there, 13C-mineral-associated SOC was associated with slower microbial growth and lower microbial biomass. CUE was a negative predictor of 13C-mineral-associated SOC in both habitats. Using 13C-quantitative stable isotope probing, we found that the majority of 13C assimilation in the rhizosphere and detritusphere at week 12 of the experiment was performed by very few bacterial and fungal taxa (3–5% of the total taxa that assimilated 13C). Several complementary chemical analyses (13C-NMR, FTICR-MS, and STXM-NEXAFS) suggested that SOC in the rhizosphere had a more oxidized chemical signature, while SOC in the detritusphere had a less oxidized, more lignin-like chemical signature. Our findings challenge current theory by demonstrating that microbial traits linked with mineral-associated SOC are not universal, but vary with soil habitat and moisture conditions, and are shaped by a small number of active taxa. Emerging SOC models that explicitly reflect these interactions may better predict SOC storage, since climate change causes shifts in soil moisture regimes and the ratio of living versus decaying roots.

Published
2024

2. Plugging the leaks: antibiotic resistance at human-animal interfaces in low-resource settings.

Author

Nadimpalli, Maya, Stegger, Marc, Viau, Roberto, Yith, Vuthy, de Lauzanne, Agathe, Sem, Nita, Borand, Laurence, Huynh, Bich-Tram, Brisse, Sylvain, Passet, Virginie, Overballe-Petersen, Søren, Aziz, Maliha, Gouali, Malika, Jacobs, Jan, Phe, Thong, Hungate, Bruce, Leshyk, Victor, Pickering, Amy, Gravey, François, Liu, Cindy, Johnson, Timothy, Hello, Simon, and Price, Lance

Abstract

Antibiotic resistance is one of the greatest public health challenges of our time. International efforts to curb resistance have largely focused on drug development and limiting unnecessary antibiotic use. However, in areas where water, sanitation, and hygiene infrastructure is lacking, we propose that bacterial flow between humans and animals can exacerbate the emergence and spread of resistant pathogens. Here, we describe the consequences of poor environmental controls by comparing mobile resistance elements among Escherichia coli recovered from humans and meat in Cambodia, a middle-income country with substantial human-animal connectivity and unregulated antibiotic use. We identified identical mobile resistance elements and a conserved transposon region that were widely dispersed in both humans and animals, a phenomenon rarely observed in high-income settings. Our findings indicate that plugging leaks at human-animal interfaces should be a critical part of addressing antibiotic resistance in low- and especially middle-income countries.

Published
2023

3. Microbial carbon use efficiency promotes global soil carbon storage

Author

Tao, Feng, Huang, Yuanyuan, Hungate, Bruce A, Manzoni, Stefano, Frey, Serita D, Schmidt, Michael WI, Reichstein, Markus, Carvalhais, Nuno, Ciais, Philippe, Jiang, Lifen, Lehmann, Johannes, Wang, Ying-Ping, Houlton, Benjamin Z, Ahrens, Bernhard, Mishra, Umakant, Hugelius, Gustaf, Hocking, Toby D, Lu, Xingjie, Shi, Zheng, Viatkin, Kostiantyn, Vargas, Ronald, Yigini, Yusuf, Omuto, Christian, Malik, Ashish A, Peralta, Guillermo, Cuevas-Corona, Rosa, Di Paolo, Luciano E, Luotto, Isabel, Liao, Cuijuan, Liang, Yi-Shuang, Saynes, Vinisa S, Huang, Xiaomeng, and Luo, Yiqi

Subjects
Agricultural, Veterinary and Food Sciences, Biological Sciences, Ecology, Forestry Sciences, Climate Action, Carbon, Carbon Sequestration, Climate Change, Ecosystem, Plants, Soil, Soil Microbiology, Datasets as Topic, Deep Learning, General Science & Technology
Abstract

Soils store more carbon than other terrestrial ecosystems1,2. How soil organic carbon (SOC) forms and persists remains uncertain1,3, which makes it challenging to understand how it will respond to climatic change3,4. It has been suggested that soil microorganisms play an important role in SOC formation, preservation and loss5-7. Although microorganisms affect the accumulation and loss of soil organic matter through many pathways4,6,8-11, microbial carbon use efficiency (CUE) is an integrative metric that can capture the balance of these processes12,13. Although CUE has the potential to act as a predictor of variation in SOC storage, the role of CUE in SOC persistence remains unresolved7,14,15. Here we examine the relationship between CUE and the preservation of SOC, and interactions with climate, vegetation and edaphic properties, using a combination of global-scale datasets, a microbial-process explicit model, data assimilation, deep learning and meta-analysis. We find that CUE is at least four times as important as other evaluated factors, such as carbon input, decomposition or vertical transport, in determining SOC storage and its spatial variation across the globe. In addition, CUE shows a positive correlation with SOC content. Our findings point to microbial CUE as a major determinant of global SOC storage. Understanding the microbial processes underlying CUE and their environmental dependence may help the prediction of SOC feedback to a changing climate.

Published
2023

4. Reply to: Model uncertainty obscures major driver of soil carbon

Author

Tao, Feng, Houlton, Benjamin Z., Frey, Serita D., Lehmann, Johannes, Manzoni, Stefano, Huang, Yuanyuan, Jiang, Lifen, Mishra, Umakant, Hungate, Bruce A., Schmidt, Michael W. I., Reichstein, Markus, Carvalhais, Nuno, Ciais, Philippe, Wang, Ying-Ping, Ahrens, Bernhard, Hugelius, Gustaf, Hocking, Toby D., Lu, Xingjie, Shi, Zheng, Viatkin, Kostiantyn, Vargas, Ronald, Yigini, Yusuf, Omuto, Christian, Malik, Ashish A., Peralta, Guillermo, Cuevas-Corona, Rosa, Di Paolo, Luciano E., Luotto, Isabel, Liao, Cuijuan, Liang, Yi-Shuang, Saynes, Vinisa S., Huang, Xiaomeng, and Luo, Yiqi

Published
2024
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5. Hyperactive nanobacteria with host-dependent traits pervade Omnitrophota

Author

Seymour, Cale O, Palmer, Marike, Becraft, Eric D, Stepanauskas, Ramunas, Friel, Ariel D, Schulz, Frederik, Woyke, Tanja, Eloe-Fadrosh, Emiley, Lai, Dengxun, Jiao, Jian-Yu, Hua, Zheng-Shuang, Liu, Lan, Lian, Zheng-Han, Li, Wen-Jun, Chuvochina, Maria, Finley, Brianna K, Koch, Benjamin J, Schwartz, Egbert, Dijkstra, Paul, Moser, Duane P, Hungate, Bruce A, and Hedlund, Brian P

Subjects
Biological Sciences, Ecology, Humans, Calcifying Nanoparticles, Bacteria, Microbiota, Microbiology, Medical Microbiology
Abstract

Candidate bacterial phylum Omnitrophota has not been isolated and is poorly understood. We analysed 72 newly sequenced and 349 existing Omnitrophota genomes representing 6 classes and 276 species, along with Earth Microbiome Project data to evaluate habitat, metabolic traits and lifestyles. We applied fluorescence-activated cell sorting and differential size filtration, and showed that most Omnitrophota are ultra-small (~0.2 μm) cells that are found in water, sediments and soils. Omnitrophota genomes in 6 classes are reduced, but maintain major biosynthetic and energy conservation pathways, including acetogenesis (with or without the Wood-Ljungdahl pathway) and diverse respirations. At least 64% of Omnitrophota genomes encode gene clusters typical of bacterial symbionts, suggesting host-associated lifestyles. We repurposed quantitative stable-isotope probing data from soils dominated by andesite, basalt or granite weathering and identified 3 families with high isotope uptake consistent with obligate bacterial predators. We propose that most Omnitrophota inhabit various ecosystems as predators or parasites.

Published
2023

7. Quantitative Stable-Isotope Probing (qSIP) with Metagenomics Links Microbial Physiology and Activity to Soil Moisture in Mediterranean-Climate Grassland Ecosystems

Author

Greenlon, Alex, Sieradzki, Ella, Zablocki, Olivier, Koch, Benjamin J, Foley, Megan M, Kimbrel, Jeffrey A, Hungate, Bruce A, Blazewicz, Steven J, Nuccio, Erin E, Sun, Christine L, Chew, Aaron, Mancilla, Cynthia-Jeanette, Sullivan, Matthew B, Firestone, Mary, Pett-Ridge, Jennifer, and Banfield, Jillian F

Subjects
Ecosystem, Soil Microbiology, Grassland, Soil, Carbon, Bacteria, Isotopes, DNA, metagenome-assembled genomes, metagenomics, soil microbiome, soil moisture, stable isotope probing
Abstract

The growth and physiology of soil microorganisms, which play vital roles in biogeochemical cycling, are shaped by both current and historical soil environmental conditions. Here, we developed and applied a genome-resolved metagenomic implementation of quantitative stable isotope probing (qSIP) with an H218O labeling experiment to identify actively growing soil microorganisms and their genomic capacities. qSIP enabled measurement of taxon-specific growth because isotopic incorporation into microbial DNA requires production of new genome copies. We studied three Mediterranean grassland soils across a rainfall gradient to evaluate the hypothesis that historic precipitation levels are an important factor controlling trait selection. We used qSIP-informed genome-resolved metagenomics to resolve the active subset of soil community members and identify their characteristic ecophysiological traits. Higher year-round precipitation levels correlated with higher activity and growth rates of flagellar motile microorganisms. In addition to heavily isotopically labeled bacteria, we identified abundant isotope-labeled phages, suggesting phage-induced cell lysis likely contributed to necromass production at all three sites. Further, there was a positive correlation between phage activity and the activity of putative phage hosts. Contrary to our expectations, the capacity to decompose the diverse complex carbohydrates common in soil organic matter or oxidize methanol and carbon monoxide were broadly distributed across active and inactive bacteria in all three soils, implying that these traits are not highly selected for by historical precipitation. IMPORTANCE Soil moisture is a critical factor that strongly shapes the lifestyle of soil organisms by changing access to nutrients, controlling oxygen diffusion, and regulating the potential for mobility. We identified active microorganisms in three grassland soils with similar mineral contexts, yet different historic rainfall inputs, by adding water labeled with a stable isotope and tracking that isotope in DNA of growing microbes. By examining the genomes of active and inactive microorganisms, we identified functions that are enriched in growing organisms, and showed that different functions were selected for in different soils. Wetter soil had higher activity of motile organisms, but activity of pathways for degradation of soil organic carbon compounds, including simple carbon substrates, were comparable for all three soils. We identified many labeled, and thus active bacteriophages (viruses that infect bacteria), implying that the cells they killed contributed to soil organic matter. The activity of these bacteriophages was significantly correlated with activity of their hosts.

Published
2022

11. Long-term nitrogen deposition enhances microbial capacities in soil carbon stabilization but reduces network complexity

Author

Ma, Xingyu, Wang, Tengxu, Shi, Zhou, Chiariello, Nona R, Docherty, Kathryn, Field, Christopher B, Gutknecht, Jessica, Gao, Qun, Gu, Yunfu, Guo, Xue, Hungate, Bruce A, Lei, Jiesi, Niboyet, Audrey, Le Roux, Xavier, Yuan, Mengting, Yuan, Tong, Zhou, Jizhong, and Yang, Yunfeng

Subjects
Biological Sciences, Ecology, Life on Land, Carbon, Ecosystem, Microbiota, Nitrogen, Soil, Soil Microbiology, Soil microbial community, Nitrogen deposition, High-throughput sequencing, GeoChip, Global change, Microbiology, Medical Microbiology, Evolutionary biology
Abstract

BackgroundAnthropogenic activities have increased the inputs of atmospheric reactive nitrogen (N) into terrestrial ecosystems, affecting soil carbon stability and microbial communities. Previous studies have primarily examined the effects of nitrogen deposition on microbial taxonomy, enzymatic activities, and functional processes. Here, we examined various functional traits of soil microbial communities and how these traits are interrelated in a Mediterranean-type grassland administrated with 14 years of 7 g m-2 year-1 of N amendment, based on estimated atmospheric N deposition in areas within California, USA, by the end of the twenty-first century.ResultsSoil microbial communities were significantly altered by N deposition. Consistent with higher aboveground plant biomass and litter, fast-growing bacteria, assessed by abundance-weighted average rRNA operon copy number, were favored in N deposited soils. The relative abundances of genes associated with labile carbon (C) degradation (e.g., amyA and cda) were also increased. In contrast, the relative abundances of functional genes associated with the degradation of more recalcitrant C (e.g., mannanase and chitinase) were either unchanged or decreased. Compared with the ambient control, N deposition significantly reduced network complexity, such as average degree and connectedness. The network for N deposited samples contained only genes associated with C degradation, suggesting that C degradation genes became more intensely connected under N deposition.ConclusionsWe propose a conceptual model to summarize the mechanisms of how changes in above- and belowground ecosystems by long-term N deposition collectively lead to more soil C accumulation. Video Abstract.

Published
2022

12. Stable-Isotope-Informed, Genome-Resolved Metagenomics Uncovers Potential Cross-Kingdom Interactions in Rhizosphere Soil

Author

Starr, Evan P, Shi, Shengjing, Blazewicz, Steven J, Koch, Benjamin J, Probst, Alexander J, Hungate, Bruce A, Pett-Ridge, Jennifer, Firestone, Mary K, and Banfield, Jillian F

Subjects
Microbiology, Biological Sciences, 2.2 Factors relating to the physical environment, Infection, Bacteria, Carbon, DNA, Bacterial, Genome, Bacterial, Isotope Labeling, Metagenomics, Phylogeny, Plant Roots, RNA, Bacterial, Rhizosphere, Soil Microbiology, bacteriophages, metagenomics, plant-microbe interactions, rhizosphere, stable-isotope probing, Immunology
Abstract

The functioning, health, and productivity of soil are intimately tied to a complex network of interactions, particularly in plant root-associated rhizosphere soil. We conducted a stable-isotope-informed, genome-resolved metagenomic study to trace carbon from Avena fatua grown in a 13CO2 atmosphere into soil. We collected paired rhizosphere and nonrhizosphere soil at 6 and 9 weeks of plant growth and extracted DNA that was then separated by density using ultracentrifugation. Thirty-two fractions from each of five samples were grouped by density, sequenced, assembled, and binned to generate 55 unique bacterial genomes that were ≥70% complete. We also identified complete 18S rRNA sequences of several 13C-enriched microeukaryotic bacterivores and fungi. We generated 10 circularized bacteriophage (phage) genomes, some of which were the most labeled entities in the rhizosphere, suggesting that phage may be important agents of turnover of plant-derived C in soil. CRISPR locus targeting connected one of these phage to a Burkholderiales host predicted to be a plant pathogen. Another highly labeled phage is predicted to replicate in a Catenulispora sp., a possible plant growth-promoting bacterium. We searched the genome bins for traits known to be used in interactions involving bacteria, microeukaryotes, and plant roots and found DNA from heavily 13C-labeled bacterial genes thought to be involved in modulating plant signaling hormones, plant pathogenicity, and defense against microeukaryote grazing. Stable-isotope-informed, genome-resolved metagenomics indicated that phage can be important agents of turnover of plant-derived carbon in soil. IMPORTANCE Plants grow in intimate association with soil microbial communities; these microbes can facilitate the availability of essential resources to plants. Thus, plant productivity commonly depends on interactions with rhizosphere bacteria, viruses, and eukaryotes. Our work is significant because we identified the organisms that took up plant-derived organic C in rhizosphere soil and determined that many of the active bacteria are plant pathogens or can impact plant growth via hormone modulation. Further, by showing that bacteriophage accumulate CO2-derived carbon, we demonstrated their vital roles in redistribution of plant-derived C into the soil environment through bacterial cell lysis. The use of stable-isotope probing (SIP) to identify consumption (or lack thereof) of root-derived C by key microbial community members within highly complex microbial communities opens the way for assessing manipulations of bacteria and phage with potentially beneficial and detrimental traits, ultimately providing a path to improved plant health and soil carbon storage.

Published
2021

13. Life history strategies among soil bacteria—dichotomy for few, continuum for many

Author

Stone, Bram W. G., Dijkstra, Paul, Finley, Brianna K., Fitzpatrick, Raina, Foley, Megan M., Hayer, Michaela, Hofmockel, Kirsten S., Koch, Benjamin J., Li, Junhui, Liu, Xiao Jun A., Martinez, Ayla, Mau, Rebecca L., Marks, Jane, Monsaint-Queeney, Victoria, Morrissey, Ember M., Propster, Jeffrey, Pett-Ridge, Jennifer, Purcell, Alicia M., Schwartz, Egbert, and Hungate, Bruce A.

Published
2023
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14. The Functional Significance of Bacterial Predators.

Author

Hungate, Bruce A, Marks, Jane C, Power, Mary E, Schwartz, Egbert, van Groenigen, Kees Jan, Blazewicz, Steven J, Chuckran, Peter, Dijkstra, Paul, Finley, Brianna K, Firestone, Mary K, Foley, Megan, Greenlon, Alex, Hayer, Michaela, Hofmockel, Kirsten S, Koch, Benjamin J, Mack, Michelle C, Mau, Rebecca L, Miller, Samantha N, Morrissey, Ember M, Propster, Jeffrey R, Purcell, Alicia M, Sieradzki, Ella, Starr, Evan P, Stone, Bram WG, Terrer, César, and Pett-Ridge, Jennifer

Subjects
Animals, Bacteria, Deltaproteobacteria, Bacteriophages, Carbon, DNA, Bacterial, Bacterial Physiological Phenomena, 18O-H2O, Bdellovibrio, food webs, predator, qSIP, stable isotope probing, top-down control, trophic interactions, O-18-H2O, Infectious Diseases, Infection, Microbiology
Abstract

Predation structures food webs, influences energy flow, and alters rates and pathways of nutrient cycling through ecosystems, effects that are well documented for macroscopic predators. In the microbial world, predatory bacteria are common, yet little is known about their rates of growth and roles in energy flows through microbial food webs, in part because these are difficult to quantify. Here, we show that growth and carbon uptake were higher in predatory bacteria compared to nonpredatory bacteria, a finding across 15 sites, synthesizing 82 experiments and over 100,000 taxon-specific measurements of element flow into newly synthesized bacterial DNA. Obligate predatory bacteria grew 36% faster and assimilated carbon at rates 211% higher than nonpredatory bacteria. These differences were less pronounced for facultative predators (6% higher growth rates, 17% higher carbon assimilation rates), though high growth and carbon assimilation rates were observed for some facultative predators, such as members of the genera Lysobacter and Cytophaga, both capable of gliding motility and wolf-pack hunting behavior. Added carbon substrates disproportionately stimulated growth of obligate predators, with responses 63% higher than those of nonpredators for the Bdellovibrionales and 81% higher for the Vampirovibrionales, whereas responses of facultative predators to substrate addition were no different from those of nonpredators. This finding supports the ecological theory that higher productivity increases predator control of lower trophic levels. These findings also indicate that the functional significance of bacterial predators increases with energy flow and that predatory bacteria influence element flow through microbial food webs.IMPORTANCE The word "predator" may conjure images of leopards killing and eating impala on the African savannah or of great white sharks attacking elephant seals off the coast of California. But microorganisms are also predators, including bacteria that kill and eat other bacteria. While predatory bacteria have been found in many environments, it has been challenging to document their importance in nature. This study quantified the growth of predatory and nonpredatory bacteria in soils (and one stream) by tracking isotopically labeled substrates into newly synthesized DNA. Predatory bacteria were more active than nonpredators, and obligate predators, such as Bdellovibrionales and Vampirovibrionales, increased in growth rate in response to added substrates at the base of the food chain, strong evidence of trophic control. This work provides quantitative measures of predator activity and suggests that predatory bacteria-along with protists, nematodes, and phages-are active and important in microbial food webs.

Published
2021

15. Using source-associated mobile genetic elements to identify zoonotic extraintestinal E. coli infections

Author

Liu, Cindy M., Aziz, Maliha, Park, Daniel E., Wu, Zhenke, Stegger, Marc, Li, Mengbing, Wang, Yashan, Schmidlin, Kara, Johnson, Timothy J., Koch, Benjamin J., Hungate, Bruce A., Nordstrom, Lora, Gauld, Lori, Weaver, Brett, Rolland, Diana, Statham, Sally, Hall, Brantley, Sariya, Sanjeev, Davis, Gregg S., Keim, Paul S., Johnson, James R., and Price, Lance B.

Published
2023
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16. Metagenomes and Metatranscriptomes of a Glucose-Amended Agricultural Soil

Author

Chuckran, Peter F, Huntemann, Marcel, Clum, Alicia, Foster, Brian, Foster, Bryce, Roux, Simon, Palaniappan, Krishnaveni, Varghese, Neha, Mukherjee, Supratim, Reddy, TBK, Daum, Chris, Copeland, Alex, Ivanova, Natalia N, Kyrpides, Nikos C, del Rio, Tijana Glavina, Eloe-Fadrosh, Emiley A, Morrissey, Ember M, Schwartz, Egbert, Fofanov, Viacheslav, Hungate, Bruce, and Dijkstra, Paul

Subjects
Microbiology, Biological Sciences, Infectious Diseases
Abstract

The addition of glucose to soil has long been used to study the metabolic activity of microbes in soil; however, the response of the microbial ecophysiology remains poorly characterized. To address this, we sequenced the metagenomes and metatranscriptomes of glucose-amended soil microbial communities in a laboratory incubation.

Published
2020

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

Author

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

Subjects
Biological Sciences, Ecology, Bioengineering, Generic health relevance, stable isotope probing, environmental microbiology, experimental design, metagenomics, microbial communities, microbial ecology, qSIP, statistical power
Abstract

Quantitative stable isotope probing (qSIP) estimates isotope tracer incorporation into DNA of individual microbes and can link microbial biodiversity and biogeochemistry in complex communities. As with any quantitative estimation technique, qSIP involves measurement error, and a fuller understanding of error, precision, and statistical power benefits qSIP experimental design and data interpretation. We used several qSIP data sets-from soil and seawater microbiomes-to evaluate how variance in isotope incorporation estimates depends on organism abundance and resolution of the density fractionation scheme. We assessed statistical power for replicated qSIP studies, plus sensitivity and specificity for unreplicated designs. As a taxon's abundance increases, the variance of its weighted mean density declines. Nine fractions appear to be a reasonable trade-off between cost and precision for most qSIP applications. Increasing the number of density fractions beyond that reduces variance, although the magnitude of this benefit declines with additional fractions. Our analysis suggests that, if a taxon has an isotope enrichment of 10 atom% excess, there is a 60% chance that this will be detected as significantly different from zero (with alpha 0.1). With five replicates, isotope enrichment of 5 atom% could be detected with power (0.6) and alpha (0.1). Finally, we illustrate the importance of internal standards, which can help to calibrate per sample conversions of %GC to mean weighted density. These results should benefit researchers designing future SIP experiments and provide a useful reference for metagenomic SIP applications where both financial and computational limitations constrain experimental scope.IMPORTANCE One of the biggest challenges in microbial ecology is correlating the identity of microorganisms with the roles they fulfill in natural environmental systems. Studies of microbes in pure culture reveal much about their genomic content and potential functions but may not reflect an organism's activity within its natural community. Culture-independent studies supply a community-wide view of composition and function in the context of community interactions but often fail to link the two. Quantitative stable isotope probing (qSIP) is a method that can link the identity and functional activity of specific microbes within a naturally occurring community. Here, we explore how the resolution of density gradient fractionation affects the error and precision of qSIP results, how they may be improved via additional experimental replication, and discuss cost-benefit balanced scenarios for SIP experimental design.

Published
2020

18. Taxon-specific microbial growth and mortality patterns reveal distinct temporal population responses to rewetting in a California grassland soil.

Author

Blazewicz, Steven J, Hungate, Bruce A, Koch, Benjamin J, Nuccio, Erin E, Morrissey, Ember, Brodie, Eoin L, Schwartz, Egbert, Pett-Ridge, Jennifer, and Firestone, Mary K

Subjects
Proteobacteria, Carbon, RNA, Ribosomal, 16S, Soil, Soil Microbiology, Ecosystem, Phylogeny, California, Microbiota, Grassland, Environmental Sciences, Biological Sciences, Technology, Microbiology
Abstract

Microbial activity increases after rewetting dry soil, resulting in a pulse of carbon mineralization and nutrient availability. The biogeochemical responses to wet-up are reasonably well understood and known to be microbially mediated. Yet, the population level dynamics, and the resulting changes in microbial community patterns, are not well understood as ecological phenomena. Here, we used sequencing of 16S rRNA genes coupled with heavy water (H218O) DNA quantitative stable isotope probing to estimate population-specific rates of growth and mortality in response to a simulated wet-up event in a California annual grassland soil. Bacterial growth and mortality responded rapidly to wet-up, within 3 h, and continued throughout the 168 h incubation, with patterns of sequential growth observed at the phylum level. Of the 37 phyla detected in the prewet community, growth was found in 18 phyla while mortality was measured in 26 phyla. Rapid growth and mortality rates were measurable within 3 h of wet-up but had contrasting characteristics; growth at 3 h was dominated by select taxa within the Proteobacteria and Firmicutes, whereas mortality was taxonomically widespread. Furthermore, across the community, mortality exhibited density-independence, consistent with the indiscriminate shock resulting from dry-down and wet-up, whereas growth was density-dependent, consistent with control by competition or predation. Total aggregated growth across the community was highly correlated with total soil CO2 production. Together, these results illustrate how previously "invisible" population responses can translate quantitatively to emergent observations of ecosystem-scale biogeochemistry.

Published
2020

19. Fire affects the taxonomic and functional composition of soil microbial communities, with cascading effects on grassland ecosystem functioning

Author

Yang, Sihang, Zheng, Qiaoshu, Yang, Yunfeng, Yuan, Mengting, Ma, Xingyu, Chiariello, Nona R, Docherty, Kathryn M, Field, Christopher B, Gutknecht, Jessica LM, Hungate, Bruce A, Niboyet, Audrey, Le Roux, Xavier, and Zhou, Jizhong

Subjects
Biological Sciences, Ecology, California, Ecosystem, Grassland, Microbiota, Soil, Soil Microbiology, Californian grasslands, climate change, fire, GeoChip, high-throughput sequencing, microbial communities, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences
Abstract

Fire is a crucial event regulating the structure and functioning of many ecosystems. Yet few studies have focused on how fire affects taxonomic and functional diversities of soil microbial communities, along with changes in plant communities and soil carbon (C) and nitrogen (N) dynamics. Here, we analyze these effects in a grassland ecosystem 9 months after an experimental fire at the Jasper Ridge Global Change Experiment site in California, USA. Fire altered soil microbial communities considerably, with community assembly process analysis showing that environmental selection pressure was higher in burned sites. However, a small subset of highly connected taxa was able to withstand the disturbance. In addition, fire decreased the relative abundances of most functional genes associated with C degradation and N cycling, implicating a slowdown of microbial processes linked to soil C and N dynamics. In contrast, fire stimulated above- and belowground plant growth, likely enhancing plant-microbe competition for soil inorganic N, which was reduced by a factor of about 2. To synthesize those findings, we performed structural equation modeling, which showed that plants but not microbial communities were responsible for significantly higher soil respiration rates in burned sites. Together, our results demonstrate that fire 'reboots' the grassland ecosystem by differentially regulating plant and soil microbial communities, leading to significant changes in soil C and N dynamics.

Published
2020

20. Nitrogen and phosphorus constrain the CO2 fertilization of global plant biomass

Author

Terrer, César, Jackson, Robert B, Prentice, I Colin, Keenan, Trevor F, Kaiser, Christina, Vicca, Sara, Fisher, Joshua B, Reich, Peter B, Stocker, Benjamin D, Hungate, Bruce A, Peñuelas, Josep, McCallum, Ian, Soudzilovskaia, Nadejda A, Cernusak, Lucas A, Talhelm, Alan F, Van Sundert, Kevin, Piao, Shilong, Newton, Paul CD, Hovenden, Mark J, Blumenthal, Dana M, Liu, Yi Y, Müller, Christoph, Winter, Klaus, Field, Christopher B, Viechtbauer, Wolfgang, Van Lissa, Caspar J, Hoosbeek, Marcel R, Watanabe, Makoto, Koike, Takayoshi, Leshyk, Victor O, Polley, H Wayne, and Franklin, Oskar

Subjects
Plant Biology, Biological Sciences, Ecology, Climate Action, Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management
Abstract

Elevated CO2 (eCO2) experiments provide critical information to quantify the effects of rising CO2 on vegetation1–6. Many eCO2 experiments suggest that nutrient limitations modulate the local magnitude of the eCO2 effect on plant biomass1,3,5, but the global extent of these limitations has not been empirically quantified, complicating projections of the capacity of plants to take up CO27,8. Here, we present a data-driven global quantification of the eCO2 effect on biomass based on 138 eCO2 experiments. The strength of CO2 fertilization is primarily driven by nitrogen (N) in ~65% of global vegetation and by phosphorus (P) in ~25% of global vegetation, with N- or P-limitation modulated by mycorrhizal association. Our approach suggests that CO2 levels expected by 2100 can potentially enhance plant biomass by 12 ± 3% above current values, equivalent to 59 ± 13 PgC. The global-scale response to eCO2 we derive from experiments is similar to past changes in greenness9 and biomass10 with rising CO2, suggesting that CO2 will continue to stimulate plant biomass in the future despite the constraining effect of soil nutrients. Our research reconciles conflicting evidence on CO2 fertilization across scales and provides an empirical estimate of the biomass sensitivity to eCO2 that may help to constrain climate projections.

Published
2019

21. Decadal biomass increment in early secondary succession woody ecosystems is increased by CO2 enrichment.

Author

Walker, Anthony P, De Kauwe, Martin G, Medlyn, Belinda E, Zaehle, Sönke, Iversen, Colleen M, Asao, Shinichi, Guenet, Bertrand, Harper, Anna, Hickler, Thomas, Hungate, Bruce A, Jain, Atul K, Luo, Yiqi, Lu, Xingjie, Lu, Meng, Luus, Kristina, Megonigal, J Patrick, Oren, Ram, Ryan, Edmund, Shu, Shijie, Talhelm, Alan, Wang, Ying-Ping, Warren, Jeffrey M, Werner, Christian, Xia, Jianyang, Yang, Bai, Zak, Donald R, and Norby, Richard J

Subjects
Trees, Carbon Dioxide, Ecosystem, Biomass, Climate, Photosynthesis, Wood
Abstract

Increasing atmospheric CO2 stimulates photosynthesis which can increase net primary production (NPP), but at longer timescales may not necessarily increase plant biomass. Here we analyse the four decade-long CO2-enrichment experiments in woody ecosystems that measured total NPP and biomass. CO2 enrichment increased biomass increment by 1.05 ± 0.26 kg C m-2 over a full decade, a 29.1 ± 11.7% stimulation of biomass gain in these early-secondary-succession temperate ecosystems. This response is predictable by combining the CO2 response of NPP (0.16 ± 0.03 kg C m-2 y-1) and the CO2-independent, linear slope between biomass increment and cumulative NPP (0.55 ± 0.17). An ensemble of terrestrial ecosystem models fail to predict both terms correctly. Allocation to wood was a driver of across-site, and across-model, response variability and together with CO2-independence of biomass retention highlights the value of understanding drivers of wood allocation under ambient conditions to correctly interpret and predict CO2 responses.

Published
2019

22. Glucose addition increases the magnitude and decreases the age of soil respired carbon in a long-term permafrost incubation study

Author

Pegoraro, Elaine, Mauritz, Marguerite, Bracho, Rosvel, Ebert, Chris, Dijkstra, Paul, Hungate, Bruce A, Konstantinidis, Konstantinos T, Luo, Yiqi, Schädel, Christina, Tiedje, James M, Zhou, Jizhong, and Schuur, Edward AG

Subjects
Aging, Priming, Permafrost, Carbon, Radiocarbon, Organic matter decomposition, Environmental Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture
Abstract

Higher temperatures in northern latitudes will increase permafrost thaw and stimulate above- and belowground plant biomass growth in tundra ecosystems. Higher plant productivity increases the input of easily decomposable carbon (C) to soil, which can stimulate microbial activity and increase soil organic matter decomposition rates. This phenomenon, known as the priming effect, is particularly interesting in permafrost because an increase in C supply to deep, previously frozen soil may accelerate decomposition of C stored for hundreds to thousands of years. The sensitivity of old permafrost C to priming is not well known; most incubation studies last less than one year, and so focus on fast-cycling C pools. Furthermore, the age of respired soil C is rarely measured, even though old C may be vulnerable to labile C inputs. We incubated soil from a moist acidic tundra site in Eight Mile Lake, Alaska for 409 days at 15 °C. Soil from surface (0–25 cm), transition (45–55 cm), and permafrost (65–85 cm) layers were amended with three pulses of uniformly ¹³C-labeled glucose or cellulose every 152 days. Glucose addition resulted in positive priming in the permafrost layer 7 days after each substrate addition, eliciting a two-fold increase in cumulative soil C loss relative to unamended soils with consistent effects across all three pulses. In the transition and permafrost layers, glucose addition significantly decreased the age of soil-respired CO₂-C with Δ¹⁴C values that were 115‰ higher. Previous field studies that measured the age of respired C in permafrost regions have attributed younger Δ¹⁴C ecosystem respiration values to higher plant contributions. However, the results from this study suggest that positive priming, due to an increase in fresh C supply to deeply thawed soil layers, can also explain the respiration of younger C observed at the ecosystem scale. We must consider priming effects to fully understand permafrost C dynamics, or we risk underestimating the contribution of soil C to ecosystem respiration.

Published
2019

26. Predicting soil carbon loss with warming

Author

van Gestel, Natasja, Shi, Zheng, van Groenigen, Kees Jan, Osenberg, Craig W, Andresen, Louise C, Dukes, Jeffrey S, Hovenden, Mark J, Luo, Yiqi, Michelsen, Anders, Pendall, Elise, Reich, Peter B, Schuur, Edward AG, and Hungate, Bruce A

Subjects
Climate Action, Atmosphere, Carbon, Carbon Cycle, Databases, Factual, Ecosystem, Feedback, Geography, Global Warming, Models, Statistical, Reproducibility of Results, Soil, Temperature, General Science & Technology
Abstract

The majority of the Earth's terrestrial carbon is stored in the soil. If anthropogenic warming stimulates the loss of this carbon to the atmosphere, it could drive further planetary warming. Despite evidence that warming enhances carbon fluxes to and from the soil, the net global balance between these responses remains uncertain. Here we present a comprehensive analysis of warming-induced changes in soil carbon stocks by assembling data from 49 field experiments located across North America, Europe and Asia. We find that the effects of warming are contingent on the size of the initial soil carbon stock, with considerable losses occurring in high-latitude areas. By extrapolating this empirical relationship to the global scale, we provide estimates of soil carbon sensitivity to warming that may help to constrain Earth system model projections. Our empirical relationship suggests that global soil carbon stocks in the upper soil horizons will fall by 30 ± 30 petagrams of carbon to 203 ± 161 petagrams of carbon under one degree of warming, depending on the rate at which the effects of warming are realized. Under the conservative assumption that the response of soil carbon to warming occurs within a year, a business-as-usual climate scenario would drive the loss of 55 ± 50 petagrams of carbon from the upper soil horizons by 2050. This value is around 12-17 per cent of the expected anthropogenic emissions over this period. Despite the considerable uncertainty in our estimates, the direction of the global soil carbon response is consistent across all scenarios. This provides strong empirical support for the idea that rising temperatures will stimulate the net loss of soil carbon to the atmosphere, driving a positive land carbon-climate feedback that could accelerate climate change.

Published
2018

30. Shifts in soil ammonia-oxidizing community maintain the nitrogen stimulation of nitrification across climatic conditions

Author

National Natural Science Foundation of China, European Commission, Aarhus University Research Foundation, Independent Research Fund Denmark, Nordic Joint Committee for Agricultural and Food Research, Natural Environment Research Council (UK), Danish National Research Foundation, García-Palacios, Pablo [0000-0002-6367-4761], Zhang, Yong, Cheng, Xiaoli, van Groenigen, Kees Jan, García-Palacios, Pablo, Cao, Junji, Zheng, Xunhua, Luo, Yiqi, Hungate, Bruce A., Terrer, Cesar, Butterbach-Bahl, Klaus, Olesen, Jørgen Eivind, Chen, Ji, National Natural Science Foundation of China, European Commission, Aarhus University Research Foundation, Independent Research Fund Denmark, Nordic Joint Committee for Agricultural and Food Research, Natural Environment Research Council (UK), Danish National Research Foundation, García-Palacios, Pablo [0000-0002-6367-4761], Zhang, Yong, Cheng, Xiaoli, van Groenigen, Kees Jan, García-Palacios, Pablo, Cao, Junji, Zheng, Xunhua, Luo, Yiqi, Hungate, Bruce A., Terrer, Cesar, Butterbach-Bahl, Klaus, Olesen, Jørgen Eivind, and Chen, Ji

Abstract

Anthropogenic nitrogen (N) loading alters soil ammonia-oxidizing archaea (AOA) and bacteria (AOB) abundances, likely leading to substantial changes in soil nitrification. However, the factors and mechanisms determining the responses of soil AOA:AOB and nitrification to N loading are still unclear, making it difficult to predict future changes in soil nitrification. Herein, we synthesize 68 field studies around the world to evaluate the impacts of N loading on soil ammonia oxidizers and nitrification. Across a wide range of biotic and abiotic factors, climate is the most important driver of the responses of AOA:AOB to N loading. Climate does not directly affect the N-stimulation of nitrification, but does so via climate-related shifts in AOA:AOB. Specifically, climate modulates the responses of AOA:AOB to N loading by affecting soil pH, N-availability and moisture. AOB play a dominant role in affecting nitrification in dry climates, while the impacts from AOA can exceed AOB in humid climates. Together, these results suggest that climate-related shifts in soil ammonia-oxidizing community maintain the N-stimulation of nitrification, highlighting the importance of microbial community composition in mediating the responses of the soil N cycle to N loading.

Published
2024

31. Shifts in soil ammonia-oxidizing community maintain the nitrogen stimulation of nitrification across climatic conditions

Author

Zhang, Yong; https://orcid.org/0000-0002-1181-032X, Cheng, Xiaoli; https://orcid.org/0000-0002-0346-675X, van Groenigen, Kees Jan; https://orcid.org/0000-0002-9165-3925, García-Palacios, Pablo; https://orcid.org/0000-0002-6367-4761, Cao, Junji; https://orcid.org/0000-0003-1000-7241, Zheng, Xunhua; https://orcid.org/0000-0002-4138-7470, Luo, Yiqi; https://orcid.org/0000-0002-4556-0218, Hungate, Bruce A; https://orcid.org/0000-0002-7337-1887, Terrer, Cesar; https://orcid.org/0000-0002-5479-3486, Butterbach-Bahl, Klaus; https://orcid.org/0000-0001-9499-6598, Olesen, Jørgen Eivind; https://orcid.org/0000-0002-6639-1273, Chen, Ji; https://orcid.org/0000-0001-7026-6312, Zhang, Yong; https://orcid.org/0000-0002-1181-032X, Cheng, Xiaoli; https://orcid.org/0000-0002-0346-675X, van Groenigen, Kees Jan; https://orcid.org/0000-0002-9165-3925, García-Palacios, Pablo; https://orcid.org/0000-0002-6367-4761, Cao, Junji; https://orcid.org/0000-0003-1000-7241, Zheng, Xunhua; https://orcid.org/0000-0002-4138-7470, Luo, Yiqi; https://orcid.org/0000-0002-4556-0218, Hungate, Bruce A; https://orcid.org/0000-0002-7337-1887, Terrer, Cesar; https://orcid.org/0000-0002-5479-3486, Butterbach-Bahl, Klaus; https://orcid.org/0000-0001-9499-6598, Olesen, Jørgen Eivind; https://orcid.org/0000-0002-6639-1273, and Chen, Ji; https://orcid.org/0000-0001-7026-6312

Abstract

Anthropogenic nitrogen (N) loading alters soil ammonia-oxidizing archaea (AOA) and bacteria (AOB) abundances, likely leading to substantial changes in soil nitrification. However, the factors and mechanisms determining the responses of soil AOA:AOB and nitrification to N loading are still unclear, making it difficult to predict future changes in soil nitrification. Herein, we synthesize 68 field studies around the world to evaluate the impacts of N loading on soil ammonia oxidizers and nitrification. Across a wide range of biotic and abiotic factors, climate is the most important driver of the responses of AOA:AOB to N loading. Climate does not directly affect the N-stimulation of nitrification, but does so via climate-related shifts in AOA:AOB. Specifically, climate modulates the responses of AOA:AOB to N loading by affecting soil pH, N-availability and moisture. AOB play a dominant role in affecting nitrification in dry climates, while the impacts from AOA can exceed AOB in humid climates. Together, these results suggest that climate-related shifts in soil ammonia-oxidizing community maintain the N-stimulation of nitrification, highlighting the importance of microbial community composition in mediating the responses of the soil N cycle to N loading.

Published
2024

32. Predicting the Responses of Soil Nitrite-Oxidizers to Multi-Factorial Global Change: A Trait-Based Approach

Author

Le Roux, Xavier, Bouskill, Nicholas J, Niboyet, Audrey, Barthes, Laure, Dijkstra, Paul, Field, Chris B, Hungate, Bruce A, Lerondelle, Catherine, Pommier, Thomas, Tang, Jinyun, Terada, Akihiko, Tourna, Maria, and Poly, Franck

Subjects
Biological Sciences, Ecology, Life Below Water, bacterial functional traits, elevated CO2, nitrifiers, nitrogen fertilisation, trait-based modeling, Environmental Science and Management, Soil Sciences, Microbiology, Medical microbiology
Abstract

Soil microbial diversity is huge and a few grams of soil contain more bacterial taxa than there are bird species on Earth. This high diversity often makes predicting the responses of soil bacteria to environmental change intractable and restricts our capacity to predict the responses of soil functions to global change. Here, using a long-term field experiment in a California grassland, we studied the main and interactive effects of three global change factors (increased atmospheric CO2 concentration, precipitation and nitrogen addition, and all their factorial combinations, based on global change scenarios for central California) on the potential activity, abundance and dominant taxa of soil nitrite-oxidizing bacteria (NOB). Using a trait-based model, we then tested whether categorizing NOB into a few functional groups unified by physiological traits enables understanding and predicting how soil NOB respond to global environmental change. Contrasted responses to global change treatments were observed between three main NOB functional types. In particular, putatively mixotrophic Nitrobacter, rare under most treatments, became dominant under the 'High CO2+Nitrogen+Precipitation' treatment. The mechanistic trait-based model, which simulated ecological niches of NOB types consistent with previous ecophysiological reports, helped predicting the observed effects of global change on NOB and elucidating the underlying biotic and abiotic controls. Our results are a starting point for representing the overwhelming diversity of soil bacteria by a few functional types that can be incorporated into models of terrestrial ecosystems and biogeochemical processes.

Published
2016

38. Proximate controls on semiarid soil greenhouse gas fluxes across 3 million years of soil development

Author

Sullivan, Benjamin W, Nasto, Megan K, Hart, Stephen C, and Hungate, Bruce A

Subjects
Carbon dioxide, Methane, Nitrous oxide, Nutrient addition, Seasonality, Substrate age gradient, Other Chemical Sciences, Geochemistry, Environmental Science and Management, Agronomy & Agriculture
Abstract

© 2015 Springer International Publishing Switzerland Soils are important sources and sinks of three greenhouse gases (GHGs): carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O). However, it is unknown whether semiarid landscapes are important contributors to global fluxes of these gases, partly because our mechanistic understanding of soil GHG fluxes is largely derived from more humid ecosystems. We designed this study with the objective of identifying the important soil physical and biogeochemical controls on soil GHG fluxes in semiarid soils by observing seasonal changes in soil GHG fluxes across a three million year substrate age gradient in northern Arizona. We also manipulated soil nitrogen (N) and phosphorus availability with 7 years of fertilization and used regression tree analysis to identify drivers of unfertilized and fertilized soil GHG fluxes. Similar to humid ecosystems, soil N2O flux was correlated with changes in N and water availability and soil CO2 efflux was correlated with changes in water availability and temperature. Soil CH4 uptake was greatest in relatively colder and wetter soils. While fertilization had few direct effects on soil CH4 flux, soil nitrate was an important predictor of soil CH4 uptake in unfertilized soils and soil ammonium was an important predictor of soil CH4 uptake in fertilized soil. Like in humid ecosystems, N gas loss via nitrification or denitrification appears to increase with increases in N and water availability during ecosystem development. Our results suggest that, with some exceptions, the drivers of soil GHG fluxes in semiarid ecosystems are often similar to those observed in more humid ecosystems.

Published
2015

39. Closely Related Tree Species Differentially Influence the Transfer of Carbon and Nitrogen from Leaf Litter Up the Aquatic Food Web

Author

Compson, Zacchaeus G, Hungate, Bruce A, Koch, George W, Hart, Steve C, Maestas, Jesse M, Adams, Kenneth J, Whitham, Thomas G, and Marks, Jane C

Subjects
stable isotope tracers, functional food webs, trophic structure, nutrient cycling, decomposition, cottonwood, aquatic insect community, Environmental Sciences, Biological Sciences, Ecology
Abstract

Decomposing leaf litter in streams provides habitat and nutrition for aquatic insects. Despite large differences in the nutritional qualities of litter among different plant species, their effects on aquatic insects are often difficult to detect. We evaluated how leaf litter of two dominant riparian species (Populus fremontii and P. angustifolia) influenced carbon and nitrogen assimilation by aquatic insect communities, quantifying assimilation rates using stable isotope tracers (13C, 15N). We tested the hypothesis that element fluxes from litter of different plant species better define aquatic insect community structure than insect relative abundances, which often fail. We found that (1) functional communities (defined by fluxes of carbon and nitrogen from leaf litter to insects) were different between leaf litter species, whereas more traditional insect communities (defined by relativized taxa abundances) were not different between leaf litter species, (2) insects assimilated N, but not C, at a higher rate from P. angustifolia litter compared to P. fremontii, even though P. angustifolia decomposes more slowly, and (3) the C:N ratio of material assimilated by aquatic insects was lower for P. angustifolia compared to P. fremontii, indicating higher nutritional quality, despite similar initial litter C:N ratios. These findings provide new evidence for the effects of terrestrial plant species on aquatic ecosystems via their direct influence on the transfer of elements up the food web. We demonstrate how isotopically labeled leaf litter can be used to assess the functioning of insect communities, uncovering patterns undetected by traditional approaches and improving our understanding of the association between food web structure and element cycling.

Published
2015

40. Accelerated microbial turnover but constant growth efficiency with warming in soil

Author

Hagerty, Shannon B, van Groenigen, Kees Jan, Allison, Steven D, Hungate, Bruce A, Schwartz, Egbert, Koch, George W, Kolka, Randall K, and Dijkstra, Paul

Subjects
Climate Action, Atmospheric Sciences, Physical Geography and Environmental Geoscience, Environmental Science and Management
Abstract

Rising temperatures are expected to reduce global soil carbon (C) stocks, driving a positive feedback to climate change1-3. However, the mechanisms underlying this prediction are not well understood, including how temperature affects microbial enzyme kinetics, growth efficiency (MGE), and turnover4,5. Here, in a laboratory study, we show that microbial turnover accelerates with warming and, along with enzyme kinetics, determines the response of microbial respiration to temperature change. In contrast, MGE, which is generally thought to decline with warming6-8, showed no temperature sensitivity. A microbial-enzyme model suggests that such temperature sensitive microbial turnover would promote soil C accumulation with warming, in contrast to reduced soil C predicted by traditional biogeochemical models. Furthermore, the effect of increased microbial turnover differs from the effects of reduced MGE, causing larger increases in soil C stocks. Our results demonstrate that the response of soil C to warming is affected by changes in microbial turnover. This control should be included in the next generation of models to improve prediction of soil C feedbacks to warming.

Published
2014

44. A positive relationship between the abundance of ammonia oxidizing archaea and natural abundance δ15N of ecosystems

Author

Adair, Karen, Blazewicz, Steven J, Hungate, Bruce A, Hart, Stephen C, Dijkstra, Paul, and Schwartz, Egbert

Subjects
Environmental Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture
Abstract

We present a significant relationship between the natural abundance isotopic composition of ecosystem pools and the abundance of a microbial gene. Natural abundance 15N of soils and soil DNA were analysed and compared with archaeal ammonia oxidizer abundance along an elevation gradient in northern Arizona and along a substrate age gradient in Hawai'i. There was a significant positive correlation between the abundance of archaeal amoA genes and natural abundance δ15N of total soil or DNA suggesting that ammonia oxidizing archaea play an important role in ecosystem N release. © 2013 Elsevier Ltd.

Published
2013

46. Biophysical considerations in forestry for climate protection

Author

Anderson, Ray G, Canadell, Josep G, Randerson, James T, Jackson, Robert B, Hungate, Bruce A, Baldocchi, Dennis D, Ban-Weiss, George A, Bonan, Gordon B, Caldeira, Ken, Cao, Long, Diffenbaugh, Noah S, Gurney, Kevin R, Kueppers, Lara M, Law, Beverly E, Luyssaert, Sebastiaan, and O'Halloran, Thomas L

Subjects
afforestation, albedo, biophysics, carbon dioxide, carbon sequestration, climate change, deforestation, energy flux, environmental protection, evapotranspiration, feedback mechanism, forest management, reforestation, temperature profile
Abstract

Forestry – including afforestation (the planting of trees on land where they have not recently existed), reforestation, avoided deforestation, and forest management – can lead to increased sequestration of atmospheric carbon dioxide and has therefore been proposed as a strategy to mitigate climate change. However, forestry also influences land-surface properties, including albedo (the fraction of incident sunlight reflected back to space), surface roughness, and evapotranspiration, all of which affect the amount and forms of energy transfer to the atmosphere. In some circumstances, these biophysical feedbacks can result in local climate warming, thereby counteracting the effects of carbon sequestration on global mean temperature and reducing or eliminating the net value of climate-change mitigation projects. Here, we review published and emerging research that suggests ways in which forestry projects can counteract the consequences associated with biophysical interactions, and highlight knowledge gaps in managing forests for climate protection. We also outline several ways in which biophysical effects can be incorporated into frameworks that use the maintenance of forests as a climate protection strategy.

Published
2011

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