Your search keyword '"Waldrop, Mark P."' showing total 32 results

1. Biological and mineralogical controls over cycling of low molecular weight organic compounds along a soil chronosequence.

Author

McFarland, Jack W., Waldrop, Mark P., Strawn, Daniel G., Creamer, Courtney A., Lawrence, Corey R., and Haw, Monica P.

Subjects

*SOIL chronosequences, *ORGANIC compounds, *MOLECULAR weights, *MICROBIAL growth, *HYDROXYBENZOIC acid

Abstract

Abstract Low molecular weight organic compounds (LMWOC) represent a small but critical component of soil organic matter (SOM) for microbial growth and metabolism. The fate of these compounds is largely under microbial control, yet outside the cell, intrinsic soil properties can also significantly influence their turnover and retention. Using a chronosequence representing 1200 ka of pedogenic development, we compared physicochemical vs biological controls on the turnover and retention of fast-cycling carbon (C), e.g. glucose (GLU) and p -hydroxybenzoic acid (PHBA). Along the chronosequence, we observed mineralogical gradients whereby amorphous constituents were greatest in intermediate-aged sites, while older sites demonstrated soils with more ordered and less reactive mineralogy. Soil microbial community composition varied along the soil chronosequence and we observed reductions in total biomass and fungal biomass from younger to older sites, but this did not affect the turnover of LMWOC. Microbial utilization of LMWOC was substrate- and soil-dependent; amorphous Fe and Al oxides reduced the respiration of PHBA but respiration from glucose remained less affected. Variation in soil mineralogy did not significantly alter recovery of PHBA within microbial biomass or fungal vs. bacterial biomarkers, suggesting that reduced respiration of the phenolic resulted from direct mineral interaction with ionizable functional groups rather than changes to microbial allocation of PHBA. We conclude patterns of soil carbon storage observed across chronosequences are moderated by mineralogical effects on microbial access to LMWOC, independent of variation in microbial community composition. Graphical abstract Along the Cowlitz River soil chronosequence (∼1200 ka) clear chronological transformations in mineralogical (e.g., pedogenic Fe and Al) and textural properties result in a gradient of surface soils with comparatively higher abundance of amorphous constituents (active Fe and Al) among intermediate-aged sites, and more ordered and less reactive mineralogy (crystalline Fe oxide) among older sites. Soil microbial community composition varied (depicted as different color and constituency in the graphic) with soil mineralogy and texture, but this had little effect on the turnover of low molecular weight organic compounds (LMWOC). Patterns of soil carbon (C) storage observed across the chronosequence are moderated by mineralogical effects on microbial access to LMWOC, independent of variation in microbial community composition. Metabolization of glucose to CO 2 was low (high C assimilation efficiency) regardless of edaphic properties. In contrast, p -hydroxybenzoic acid, a substrate with variable charge capacity, and typically lower C assimilation efficiency, demonstrated reduced metabolization to CO 2 among soils with higher active Fe and Al. Presumably this is due to direct mineral interaction with ionizable functional groups as opposed to variation in microbial allocation of p -hydroxybenzoic acid. Image 1 Highlights • The Cowlitz River soil chronosequence represents 1200 ka of pedogenic development. • We examined relationships between soil mineralogy, microbes, and rates of C turnover. • Microbial community composition, but not functionality varies with soil age. • Soil mineralogy (especially Al and Fe chemistry) moderates microbial access to LMWOC. • Internal allocation of LMWOC to microbial products drives short-term C retention. [ABSTRACT FROM AUTHOR]

Published

2019

2. Multi-omics of permafrost, active layer and thermokarst bog soil microbiomes.

Author

Hultman, Jenni, Waldrop, Mark P., Mackelprang, Rachel, David, Maude M., McFarland, Jack, Blazewicz, Steven J., Harden, Jennifer, Turetsky, Merritt R., McGuire, A. David, Shah, Manesh B., VerBerkmoes, Nathan C., Lee, Lang Ho, Mavrommatis, Kostas, and Jansson, Janet K.

Subjects

*PERMAFROST, *THERMOKARST, *FROZEN ground, *THAWING, *MICROBIAL ecology, *MICROORGANISMS, *PHYLOGENY

Abstract

Over 20% of Earth's terrestrial surface is underlain by permafrost with vast stores of carbon that, once thawed, may represent the largest future transfer of carbon from the biosphere to the atmosphere. This process is largely dependent on microbial responses, but we know little about microbial activity in intact, let alone in thawing, permafrost. Molecular approaches have recently revealed the identities and functional gene composition of microorganisms in some permafrost soils and a rapid shift in functional gene composition during short-term thaw experiments. However, the fate of permafrost carbon depends on climatic, hydrological and microbial responses to thaw at decadal scales. Here we use the combination of several molecular 'omics' approaches to determine the phylogenetic composition of the microbial communities, including several draft genomes of novel species, their functional potential and activity in soils representing different states of thaw: intact permafrost, seasonally thawed active layer and thermokarst bog. The multi-omics strategy reveals a good correlation of process rates to omics data for dominant processes, such as methanogenesis in the bog, as well as novel survival strategies for potentially active microbes in permafrost. [ABSTRACT FROM AUTHOR]

Published

2015

3. Extreme CO2 disturbance and the resilience of soil microbial communities.

Author

McFarland, Jack W., Waldrop, Mark P., and Haw, Monica

Subjects

*SOIL microbiology, *CARBON dioxide, *ECOLOGICAL resilience, *CARBON sequestration, *ECOSYSTEMS, *CARBON in soils

Abstract

Abstract: Carbon capture and storage (CSS) technology has the potential to inadvertently release large quantities of CO2 through geologic substrates and into surrounding soils and ecosystems. Such a disturbance has the potential to not only alter the structure and function of plant and animal communities, but also soils, soil microbial communities, and the biogeochemical processes they mediate. At Mammoth Mountain, we assessed the soil microbial community response to CO2 disturbance (derived from volcanic ‘cold’ CO2) that resulted in localized tree kill; soil CO2 concentrations in our study area ranged from 0.6% to 60%. Our objectives were to examine how microbial communities and their activities are restructured by extreme CO2 disturbance, and assess the response of major microbial taxa to the reintroduction of limited plant communities following an extensive period (15–20 years) with no plants. We found that CO2-induced tree kill reduced soil carbon (C) availability along our sampling transect. In response, soil microbial biomass decreased by an order of magnitude from healthy forest to impacted areas. Soil microorganisms were most sensitive to changes in soil organic C, which explained almost 60% of the variation for microbial biomass C (MBC) along the CO2 gradient. We employed phospholipid fatty acid analysis and quantitative PCR (qPCR) to determine compositional changes among microbial communities in affected areas and found substantial reductions in microbial biomass linked to the loss of soil fungi. In contrast, archaeal populations responded positively to the CO2 disturbance, presumably due to reduced competition of bacteria and fungi, and perhaps unique adaptations to energy stress. Enzyme activities important in the cycling of soil C, nitrogen (N), and phosphorus (P) declined with increasing CO2, though specific activities (per unit MBC) remained stable or increased suggesting functional redundancy among restructured communities. We conclude that both the direct (microaerobiosis) and indirect (loss of plant C inputs) effects of elevated soil CO2 flux have significant impacts on the composition and overall structural trajectory of soil microbial populations within disturbed areas. [Copyright &y& Elsevier]

Published

2013

4. Metagenomic analysis of a permafrost microbial community reveals a rapid response to thaw.

Author

Mackelprang, Rachel, Waldrop, Mark P., DeAngelis, Kristen M., David, Maude M., Chavarria, Krystle L., Blazewicz, Steven J., Rubin, Edward M., and Jansson, Janet K.

Subjects

*PERMAFROST, *METHANE, *NITROGEN, *CARBON, *THAWING, *GLOBAL temperature changes, ENVIRONMENTAL aspects

Abstract

Permafrost contains an estimated 1672?Pg carbon (C), an amount roughly equivalent to the total currently contained within land plants and the atmosphere. This reservoir of C is vulnerable to decomposition as rising global temperatures cause the permafrost to thaw. During thaw, trapped organic matter may become more accessible for microbial degradation and result in greenhouse gas emissions. Despite recent advances in the use of molecular tools to study permafrost microbial communities, their response to thaw remains unclear. Here we use deep metagenomic sequencing to determine the impact of thaw on microbial phylogenetic and functional genes, and relate these data to measurements of methane emissions. Metagenomics, the direct sequencing of DNA from the environment, allows the examination of whole biochemical pathways and associated processes, as opposed to individual pieces of the metabolic puzzle. Our metagenome analyses reveal that during transition from a frozen to a thawed state there are rapid shifts in many microbial, phylogenetic and functional gene abundances and pathways. After one week of incubation at 5?°C, permafrost metagenomes converge to be more similar to each other than while they are frozen. We find that multiple genes involved in cycling of C and nitrogen shift rapidly during thaw. We also construct the first draft genome from a complex soil metagenome, which corresponds to a novel methanogen. Methane previously accumulated in permafrost is released during thaw and subsequently consumed by methanotrophic bacteria. Together these data point towards the importance of rapid cycling of methane and nitrogen in thawing permafrost. [ABSTRACT FROM AUTHOR]

Published

2011

5. Interactive effects of wildfire and permafrost on microbial communities and soil processes in an Alaskan black spruce forest.

Author

WALDROP, MARK P. and HARDEN, JENNIFER W.

Subjects

*CARBON, *RESPIRATION, *MOISTURE, *BIOTIC communities, *LIGHT elements, *VITAL signs, *PHYSIOLOGY, *BREATHING exercises, *RESPIROMETERS

Abstract

Boreal forests contain significant quantities of soil carbon that may be oxidized to CO2 given future increases in climate warming and wildfire behavior. At the ecosystem scale, decomposition and heterotrophic respiration are strongly controlled by temperature and moisture, but we questioned whether changes in microbial biomass, activity, or community structure induced by fire might also affect these processes. We particularly wanted to understand whether postfire reductions in microbial biomass could affect rates of decomposition. Additionally, we compared the short-term effects of wildfire to the long-term effects of climate warming and permafrost decline. We compared soil microbial communities between control and recently burned soils that were located in areas with and without permafrost near Delta Junction, AK. In addition to soil physical variables, we quantified changes in microbial biomass, fungal biomass, fungal community composition, and C cycling processes (phenol oxidase enzyme activity, lignin decomposition, and microbial respiration). Five years following fire, organic surface horizons had lower microbial biomass, fungal biomass, and dissolved organic carbon (DOC) concentrations compared with control soils. Reductions in soil fungi were associated with reductions in phenol oxidase activity and lignin decomposition. Effects of wildfire on microbial biomass and activity in the mineral soil were minor. Microbial community composition was affected by wildfire, but the effect was greater in nonpermafrost soils. Although the presence of permafrost increased soil moisture contents, effects on microbial biomass and activity were limited to mineral soils that showed lower fungal biomass but higher activity compared with soils without permafrost. Fungal abundance and moisture were strong predictors of phenol oxidase enzyme activity in soil. Phenol oxidase enzyme activity, in turn, was linearly related to both 13C lignin decomposition and microbial respiration in incubation studies. Taken together, these results indicate that reductions in fungal biomass in postfire soils and lower soil moisture in nonpermafrost soils reduced the potential of soil heterotrophs to decompose soil carbon. Although in the field increased rates of microbial respiration can be observed in postfire soils due to warmer soil conditions, reductions in fungal biomass and activity may limit rates of decomposition. [ABSTRACT FROM AUTHOR]

Published

2008

6. Molecular analysis of fungal communities and laccase genes in decomposing litter reveals differences among forest types but no impact of nitrogen deposition.

Author

Blackwood, Christopher B., Waldrop, Mark P., Zak, Donald R., and Sinsabaugh, Robert L.

Subjects

*BIOTIC communities, *BASIDIOMYCETES, *FUNGI, *ECOLOGY, *ENVIRONMENTAL sciences

Abstract

The fungal community of the forest floor was examined as the cause of previously reported increases in soil organic matter due to experimental N deposition in ecosystems producing predominantly high-lignin litter, and the opposite response in ecosystems producing low-lignin litter. The mechanism proposed to explain this phenomenon was that white-rot basidiomycetes are more important in the degradation of high-lignin litter than of low-lignin litter, and that their activity is suppressed by N deposition. We found that forest floor mass in the low-lignin sugar-maple dominated system decreased in October due to experimental N deposition, whereas forest floor mass of high-lignin oak-dominated ecosystems was unaffected by N deposition. Increased relative abundance of basidiomycetes in high-lignin forest floor was confirmed by denaturing gradient gel electrophoresis (DGGE) and sequencing. Abundance of basidiomycete laccase genes, encoding an enzyme used by white-rot basidiomycetes in the degradation of lignin, was 5–10 times greater in high-lignin forest floor than in low-lignin forest floor. While the differences between the fungal communities in different ecosystems were consistent with the proposed mechanism, no significant effects of N deposition were detected on DGGE profiles, laccase gene abundance, laccase length heterogeneity profiles, or phenol oxidase activity. Our observations indicate that the previously detected accumulation of soil organic matter in the high-lignin system may be driven by effects of N deposition on organisms in the mineral soil, rather than on organisms residing in the forest floor. However, studies of in situ gene expression and temporal and spatial variability within forest floor communities will be necessary to further relate the ecosystem dynamics of organic carbon to microbial communities and atmospheric N deposition. [ABSTRACT FROM AUTHOR]

Published

2007

7. Resource availability controls fungal diversity across a plant diversity gradient.

Author

Waldrop, Mark P., Zak, Donald R., Blackwood, Christopher B., Curtis, Casey D., and Tilman, David

Subjects

*BIODIVERSITY, *MARINE biodiversity, *FUNGI, *PLANT diversity, *BIOMASS, *BIOTIC communities

Abstract

Despite decades of research, the ecological determinants of microbial diversity remain poorly understood. Here, we test two alternative hypotheses concerning the factors regulating fungal diversity in soil. The first states that higher levels of plant detritus production increase the supply of limiting resources (i.e. organic substrates) thereby increasing fungal diversity. Alternatively, greater plant diversity increases the range of organic substrates entering soil, thereby increasing the number of niches to be filled by a greater array of heterotrophic fungi. These two hypotheses were simultaneously examined in experimental plant communities consisting of one to 16 species that have been maintained for a decade. We used ribosomal intergenic spacer analysis (RISA), in combination with cloning and sequencing, to quantify fungal community composition and diversity within the experimental plant communities. We used soil microbial biomass as a temporally integrated measure of resource supply. Plant diversity was unrelated to fungal diversity, but fungal diversity was a unimodal function of resource supply. Canonical correspondence analysis (CCA) indicated that plant diversity showed a relationship to fungal community composition, although the occurrence of RISA bands and operational taxonomic units (OTUs) did not differ among the treatments. The relationship between fungal diversity and resource availability parallels similar relationships reported for grasslands, tropical forests, coral reefs, and other biotic communities, strongly suggesting that the same underlying mechanisms determine the diversity of organisms at multiple scales. [ABSTRACT FROM AUTHOR]

Published

2006

8. Response of Oxidative Enzyme Activities to Nitrogen Deposition Affects Soil Concentrations of Dissolved Organic Carbon.

Author

Waldrop, Mark P. and Zak, Donald R.

Subjects

*ATMOSPHERIC nitrogen compounds, *CARBON compounds, *MICROBIAL ecology, *PHENOLS, *SOIL enzymology, *BIOTIC communities

Abstract

Recent evidence suggests that atmospheric nitrate (NO) deposition can alter soil carbon (C) storage by directly affecting the activity of lignin-degrading soil fungi. In a laboratory experiment, we studied the direct influence of increasing soil NO concentration on microbial C cycling in three different ecosystems: black oak–white oak (BOWO), sugar maple–red oak (SMRO), and sugar maple–basswood (SMBW). These ecosystems span a broad range of litter biochemistry and recalcitrance; the BOWO ecosystem contains the highest litter lignin content, SMRO had intermediate lignin content, and SMBW leaf litter has the lowest lignin content. We hypothesized that increasing soil solution NO would reduce lignolytic activity in the BOWO ecosystem, due to a high abundance of white-rot fungi and lignin-rich leaf litter. Due to the low lignin content of litter in the SMBW, we further reasoned that the NO repression of lignolytic activity would be less dramatic due to a lower relative abundance of white-rot basidiomycetes; the response in the SMRO ecosystem should be intermediate. We increased soil solution NO concentrations in a 73-day laboratory incubation and measured microbial respiration and soil solution dissolved organic carbon (DOC) and phenolics concentrations. At the end of the incubation, we measured the activity of β-glucosidase, N-acetyl-glucosaminidase, phenol oxidase, and peroxidase, which are extracellular enzymes involved with cellulose and lignin degradation. We quantified the fungal biomass, and we also used fungal ribosomal intergenic spacer analysis (RISA) to gain insight into fungal community composition. In the BOWO ecosystem, increasing NO significantly decreased oxidative enzyme activities (−30% to −54%) and increased DOC (+32% upper limit) and phenolic (+77% upper limit) concentrations. In the SMRO ecosystem, we observed a significant decrease in phenol oxidase activity (−73% lower limit) and an increase in soluble phenolic concentrations (+57% upper limit) in response to increasing NO in soil solution, but there was no significant change in DOC concentration. In contrast to these patterns, increasing soil solution NO in the SMBW soil resulted in significantly greater phenol oxidase activity (+700% upper limit) and a trend toward lower DOC production (−52% lower limit). Nitrate concentration had no effect on microbial respiration or β-glucosidase or N-acetyl-glucosaminidase activities. Fungal abundance and basidiomycete diversity tended to be highest in the BOWO soil and lowest in the SMBW, but neither displayed a consistent response to NO additions. Taken together, our results demonstrate that oxidative enzyme production by microbial communities responds directly to NO deposition, controlling extracellular enzyme activity and DOC flux. The regulation of oxidative enzymes by different microbial communities in response to NO deposition highlights the fact that the composition and function of soil microbial communities directly control ecosystem-level responses to environmental change. [ABSTRACT FROM AUTHOR]

Published

2006

9. Microbial community response to nitrogen deposition in northern forest ecosystems

Author

Waldrop, Mark P., Zak, Donald R., and Sinsabaugh, Robert L.

Subjects

*MICROBIAL respiration, *NITROGEN fixation, *BIOTIC communities, *FORESTS & forestry

Abstract

The productivity of temperate forests is often limited by soil N availability, suggesting that elevated atmospheric N deposition could increase ecosystem C storage. However, the magnitude of this increase is dependent on rates of soil organic matter formation as well as rates of plant production. Nonetheless, we have a limited understanding of the potential for atmospheric N deposition to alter microbial activity in soil, and hence rates of soil organic matter formation. Because high levels of inorganic N suppress lignin oxidation by white rot basidiomycetes and generally enhance cellulose hydrolysis, we hypothesized that atmospheric N deposition would alter microbial decomposition in a manner that was consistent with changes in enzyme activity and shift decomposition from fungi to less efficient bacteria. To test our idea, we experimentally manipulated atmospheric N deposition (0, 30 and 80 kg NO3−-N) in three northern temperate forests (black oak/white oak (BOWO), sugar maple/red oak (SMRO), and sugar maple/basswood (SMBW)). After one year, we measured the activity of ligninolytic and cellulolytic soil enzymes, and traced the fate of lignin and cellulose breakdown products (13C-vanillin, catechol and cellobiose). In the BOWO ecosystem, the highest level of N deposition tended to reduce phenol oxidase activity (131±13 versus 104±5 μmol h−1 g−1) and peroxidase activity (210±26 versus 190±21 μmol h−1 g−1) and it reduced 13C-vanillin and 13C-catechol degradation and the incorporation of 13C into fungal phospholipids (p<0.05). Conversely, in the SMRO and SMBW ecosystems, N deposition tended to increase phenol oxidase and peroxidase activities and increased vanillin and catechol degradation and the incorporation of isotope into fungal phospholipids (p<0.05). We observed no effect of experimental N deposition on the degradation of 13C-cellulose, although cellulase activity showed a small and marginally significant increase (p<0.10). The ecosystem-specific response of microbial activity and soil C cycling to experimental N addition indicates that accurate prediction of soil C storage requires a better understanding of the physiological response of microbial communities to atmospheric N deposition. [Copyright &y& Elsevier]

Published

2004

10. Microbial community utilization of recalcitrant and simple carbon compounds: impact of oak-woodland plant communities.

Author

Waldrop, Mark P. and Firestone, Mary K.

Subjects

*MICROBIAL ecology, *FOREST plants, *CARBON compounds, *PLANT communities, *FATTY acids, *PHOSPHOLIPIDS

Abstract

Little is known about how the structure of microbial communities impacts carbon cycling or how soil microbial community composition mediates plant effects on C-decomposition processes. We examined the degradation of four 13C-labeled compounds (starch, xylose, vanillin, and pine litter), quantified rates of associated enzyme activities, and identified microbial groups utilizing the 13C-labeled substrates in soils under oaks and in adjacent open grasslands. By quantifying increases in non-13C-labeled carbon in microbial biomarkers, we were also able to identify functional groups responsible for the metabolism of indigenous soil organic matter. Although microbial community composition differed between oak and grassland soils, the microbial groups responsible for starch, xylose, and vanillin degradation, as defined by 13C-PLFA, did not differ significantly between oak and grassland soils. Microbial groups responsible for pine litter and SOM-C degradation did differ between the two soils. Enhanced degradation of SOM resulting from substrate addition (priming) was greater in grassland soils, particularly in response to pine litter addition; under these conditions, fungal and Gram + biomarkers showed more incorporation of SOM-C than did Gram – biomarkers. In contrast, the oak soil microbial community primarily incorporated C from the added substrates. More 13C (from both simple and recalcitrant sources) was incorporated into the Gram – biomarkers than Gram + biomarkers despite the fact that the Gram + group generally comprised a greater portion of the bacterial biomass than did markers for the Gram – group. These experiments begin to identify components of the soil microbial community responsible for decomposition of different types of C-substrates. The results demonstrate that the presence of distinctly different plant communities did not alter the microbial community profile responsible for decomposition of relatively labile C-substrates but did alter the profiles of microbial communities responsible for decomposition of the more recalcitrant substrates, pine litter and indigenous soil organic matter. [ABSTRACT FROM AUTHOR]

Published

2004

11. Persistent net release of carbon dioxide and methane from an Alaskan lowland boreal peatland complex.

Author

Euskirchen, Eugénie S., Edgar, Colin W., Kane, Evan S., Waldrop, Mark P., Neumann, Rebecca B., Manies, Kristen L., Douglas, Thomas A., Dieleman, Catherine, Jones, Miriam C., and Turetsky, Merritt R.

Subjects

*CARBON dioxide, *GLOBAL warming, *ATMOSPHERIC methane, *CARBON cycle, *METHANE, *RAINFALL, *SALT marshes, *BOGS

Abstract

Permafrost degradation in peatlands is altering vegetation and soil properties and impacting net carbon storage. We studied four adjacent sites in Alaska with varied permafrost regimes, including a black spruce forest on a peat plateau with permafrost, two collapse scar bogs of different ages formed following thermokarst, and a rich fen without permafrost. Measurements included year‐round eddy covariance estimates of net carbon dioxide (CO2), mid‐April to October methane (CH4) emissions, and environmental variables. From 2011 to 2022, annual rainfall was above the historical average, snow water equivalent increased, and snow‐season duration shortened due to later snow return. Seasonally thawed active layer depths also increased. During this period, all ecosystems acted as slight annual sources of CO2 (13–59 g C m−2 year−1) and stronger sources of CH4 (11–14 g CH4 m−2 from ~April to October). The interannual variability of net ecosystem exchange was high, approximately ±100 g C m−2 year−1, or twice what has been previously reported across other boreal sites. Net CO2 release was positively related to increased summer rainfall and winter snow water equivalent and later snow return. Controls over CH4 emissions were related to increased soil moisture and inundation status. The dominant emitter of carbon was the rich fen, which, in addition to being a source of CO2, was also the largest CH4 emitter. These results suggest that the future carbon‐source strength of boreal lowlands in Interior Alaska may be determined by the area occupied by minerotrophic fens, which are expected to become more abundant as permafrost thaw increases hydrologic connectivity. Since our measurements occur within close proximity of each other (≤1 km2), this study also has implications for the spatial scale and data used in benchmarking carbon cycle models and emphasizes the necessity of long‐term measurements to identify carbon cycle process changes in a warming climate. [ABSTRACT FROM AUTHOR]

Published

2024

12. Changes in the Active, Dead, and Dormant Microbial Community Structure across a Pleistocene Permafrost Chronosequence.

Author

Burkert, Alexander, Douglas, Thomas A., Waldrop, Mark P., and Mackelprang, Rachel

Subjects

*PERMAFROST ecosystems, *MICROBIAL communities, *PERMAFROST, *COMMUNITY organization, *GEOLOGICAL time scales, *STAINS & staining (Microscopy)

Abstract

Permafrost hosts a community of microorganisms that survive and reproduce for millennia despite extreme environmental conditions, such as water stress, subzero temperatures, high salinity, and low nutrient availability. Many studies focused on permafrost microbial community composition use DNA-based methods, such as metagenomics and 16S rRNA gene sequencing. However, these methods do not distinguish among active, dead, and dormant cells. This is of particular concern in ancient permafrost, where constant subzero temperatures preserve DNA from dead organisms and dormancy may be a common survival strategy. To circumvent this, we applied (i) LIVE/DEAD differential staining coupled with microscopy, (ii) endospore enrichment, and (iii) selective depletion of DNA from dead cells to permafrost microbial communities across a Pleistocene permafrost chronosequence (19,000, 27,000, and 33,000 years old). Cell counts and analysis of 16S rRNA gene amplicons from live, dead, and dormant cells revealed how communities differ between these pools, how they are influenced by soil physicochemical properties, and whether they change over geologic time. We found evidence that cells capable of forming endospores are not necessarily dormant and that members of the class Bacilli were more likely to form endospores in response to long-term stressors associated with permafrost environmental conditions than members of the Clostridia, which were more likely to persist as vegetative cells in our older samples. We also found that removing exogenous "relic" DNA preserved within permafrost did not significantly alter microbial community composition. These results link the live, dead, and dormant microbial communities to physicochemical characteristics and provide insights into the survival of microbial communities in ancient permafrost. [ABSTRACT FROM AUTHOR]

Published

2019

13. The biogeography of relative abundance of soil fungi versus bacteria in surface topsoil.

Author

Yu, Kailiang, van den Hoogen, Johan, Wang, Zhiqiang, Averill, Colin, Routh, Devin, Smith, Gabriel Reuben, Drenovsky, Rebecca E., Scow, Kate M., Mo, Fei, Waldrop, Mark P., Yang, Yuanhe, Tang, Weize, De Vries, Franciska T., Bardgett, Richard D., Manning, Peter, Bastida, Felipe, Baer, Sara G., Bach, Elizabeth M., García, Carlos, and Wang, Qingkui

Subjects

*SOIL fungi, *SOIL air, *SOIL ecology, *BIOGEOGRAPHY, *FUNCTIONAL groups, *TOPSOIL

Abstract

Fungi and bacteria are the two dominant groups of soil microbial communities worldwide. By controlling the turnover of soil organic matter, these organisms directly regulate the cycling of carbon between the soil and the atmosphere. Fundamental differences in the physiology and life history of bacteria and fungi suggest that variation in the biogeography of relative abundance of soil fungi versus bacteria could drive striking differences in carbon decomposition and soil organic matter formation between different biomes. However, a lack of global and predictive information on the distribution of these organisms in terrestrial ecosystems has prevented the inclusion of relative abundance of soil fungi versus bacteria and the associated processes in global biogeochemical models. Here, we used a global-scale dataset of >3000 distinct observations of abundance of soil fungi versus bacteria in the surface topsoil (up to 15 cm) to generate the first quantitative and high-spatial-resolution (1 km 2) explicit map of soil fungal proportion, defined as fungi/fungi + bacteria, across terrestrial ecosystems. We reveal striking latitudinal trends where fungal dominance increases in cold and high-latitude environments with large soil carbon stocks. There was a strong nonlinear response of fungal dominance to the environmental gradient, i.e., mean annual temperature (MAT) and net primary productivity (NPP). Fungi dominated in regions with low MAT and NPP and bacteria dominated in regions with high MAT and NPP, thus representing slow vs. fast soil energy channels, respectively, a concept with a long history in soil ecology. These high-resolution models provide the first steps towards representing the major soil microbial groups and their functional differences in global biogeochemical models to improve predictions of soil organic matter turnover under current and future climate scenarios. Raw datasets and global maps generated in this study are available at 10.6084/m9.figshare.19556419 (Yu, 2022). [ABSTRACT FROM AUTHOR]

Published

2022

14. A molecular dawn for biogeochemistry

Author

Zak, Donald R., Blackwood, Christopher B., and Waldrop, Mark P.

Subjects

*BIOCHEMISTRY, *BIOGEOCHEMISTRY, *MICROBIOLOGY, *GENES

Abstract

Biogeochemistry is at the dawn of an era in which molecular advances enable the discovery of novel microorganisms having unforeseen metabolic capabilities, revealing new insight into the underlying processes regulating elemental cycles at local to global scales. Traditionally, biogeochemical inquiry began by studying a process of interest, and then focusing downward to uncover the microorganisms and metabolic pathways mediating that process. With the ability to sequence functional genes from the environment, molecular approaches now enable the flow of inquiry in the opposite direction. Here, we argue that a focus on functional genes, the microorganisms in which they reside, and the interaction of those organisms with the broader microbial community could transform our understanding of many globally important biogeochemical processes. [Copyright &y& Elsevier]

Published

2006

15. Permafrost Mapping with Electrical Resistivity Tomography: A Case Study in Two Wetland Systems in Interior Alaska.

Author

Conaway, Christopher H., Johnson, Cordell D., Lorenson, Thomas D., Turetsky, Merritt, Euskirchen, Eugénie, Waldrop, Mark P., and Swarzenski, Peter W.

Subjects

*ELECTRICAL resistivity, *PERMAFROST, *TUNDRAS, *WETLANDS, *ALLUVIAL plains, *TOMOGRAPHY, *BOGS

Abstract

Surface-based 2D electrical resistivity tomography (ERT) surveys were used to characterize permafrost distribution at wetland sites on the alluvial plain north of the Tanana River, 20 km southwest of Fairbanks, Alaska, in June and September 2014. The sites were part of an ecologically-sensitive research area characterizing biogeochemical response of this region to warming and permafrost thaw, and the site contained landscape features characteristic of interior Alaska, including thermokarst bog, forested permafrost plateau, and a rich fen. The results show how vegetation reflects shallow (0-10 m depth) permafrost distribution. Additionally, we saw shallow (0-3 m depth) low resistivity areas in forested permafrost plateau potentially indicating the presence of increased unfrozen water content as a precursor to ground instability and thaw. Time-lapse study from June to September suggested a depth of seasonal influence extending several meters below the active layer, potentially as a result of changes in unfrozen water content. A comparison of several electrode geometries (dipole-dipole, extended dipole-dipole, Wenner-Schlumberger) showed that for depths of interest to our study (0-10 m) results were similar, but data acquisition time with dipole-dipole was the shortest, making it our preferred geometry. The results show the utility of ERT surveys to characterize permafrost distribution at these sites, and how vegetation reflects shallow permafrost distribution. These results are valuable information for ecologically sensitive areas where ground-truthing can cause excessive disturbance. ERT data can be used to characterize the exact subsurface geometry of permafrost such that over time an understanding of changing permafrost conditions can be made in great detail. Characterizing the depth of thaw and thermal influence from the surface in these areas also provides important information as an indication of the depth to which carbon storage and microbially-mediated carbon processing may be affected. [ABSTRACT FROM AUTHOR]

Published

2020

16. Mineralogy dictates the initial mechanism of microbial necromass association.

Author

Creamer, Courtney A., Foster, Andrea L., Lawrence, Corey, McFarland, Jack, Schulz, Marjorie, and Waldrop, Mark P.

Subjects

*MINERALOGY, *HUMUS, *SOIL mineralogy, *ALUMINUM hydroxide, *SOIL fertility

Abstract

Soil organic matter (SOM) improves soil fertility and mitigates disturbance related to climate and land use change. Microbial necromass (the accumulated cellular residues of microorganisms) comprises the majority of soil C, yet the formation and persistence of necromass in relation to mineralogy is poorly understood. We tested whether soil minerals had different microbial necromass association mechanisms. Specifically, we tested whether microbial necromass directly sorbed to mineral surfaces or was consumed by live microorganisms prior to mineral association. Applying Raman microspectroscopy with 13C enriched microbial necromass to quantify microbe-mineral interactions, we show that mineralogy alters the initial mechanism of microbial necromass association. In the presence of K-feldspar (lower abiotic C preservation potential), microbial necromass required assimilation by live microorganisms for mineral retention. In contrast, with amorphous aluminum hydroxide (higher abiotic C preservation potential) microbial necromass was retained predominately through abiotic sorption, and was subsequently protected from microbial decomposition. Despite different mechanisms, both minerals retained similar quantities of microbial necromass under biotic conditions. Mineralogy determined not only the quantity of mineral-associated C, but the distinct pathway of microbial necromass association. These findings show the utility of Raman microspectroscopy as a technique to study microbe-mineral interactions, and imply that heterogeneity in mineral-organic interactions could result in gradients of organic matter stability. [ABSTRACT FROM AUTHOR]

Published

2019

17. Effect of permafrost thaw on plant and soil fungal community in a boreal forest: Does fungal community change mediate plant productivity response?

Author

Schütte, Ursel M. E., Henning, Jeremiah A., Ye, Yuzhen, Bowling, Annie, Ford, James, Genet, Hélène, Waldrop, Mark P., Turetsky, Merritt R., White, Jeffrey R., Bever, James D., and Singh, Brajesh

Subjects

*PERMAFROST ecosystems, *FUNGAL communities, *TAIGAS, *PLANT productivity, *COMMUNITY forests, *PERMAFROST

Abstract

Permafrost thaw is leading to rapid shifts in boreal ecosystem function. Permafrost thaw affects soil carbon turnover through changes in soil hydrology; however, the biotic mechanisms regulating plant community response remain elusive.Here, we measured the response of fungal community composition and soil nutrient content in an intact permafrost plateau forest soil and an adjacent thermokarst bog and evaluated their potential to mediate shifts in plant composition.We used barcoded amplicon targeting ITS2 and 28S rRNA genes to determine fungal community composition. Next, we used the soils from the permafrost plateau and the thermokarst bog as soil inoculum in a greenhouse experiment to measure whether shifts in fungal community and soil water level regulate plant productivity and composition.Overall, we found that fungal community composition differed significantly between the thawed and intact permafrost sites, but soil nutrient content did not. Relative abundance of mycorrhizal fungal taxa decreased while relative abundance of putative fungal pathogens increased with permafrost thaw. In the greenhouse, we found that ecto‐ and arbuscular‐associated host plants had higher productivity in permafrost‐intact soils relative to thawed soils. However, productivity of non‐mycorrhizal tussock grass was more affected by soil water levels than soil communities.Synthesis. Our results suggest that fungal communities are crucial in mediating plant community response to permafrost thaws inducing hydrology changes. [ABSTRACT FROM AUTHOR]

Published

2019

18. Warming Effects of Spring Rainfall Increase Methane Emissions From Thawing Permafrost.

Author

Neumann, Rebecca B., Moorberg, Colby J., Lundquist, Jessica D., Turner, Jesse C., Waldrop, Mark P., McFarland, Jack W., Euskirchen, Eugenie S., Edgar, Colin W., and Turetsky, Merritt R.

Subjects

*PERMAFROST, *CLIMATE change, *GROUND ice, *FROZEN ground, *GREENHOUSE gases

Abstract

Methane emissions regulate the near‐term global warming potential of permafrost thaw, particularly where loss of ice‐rich permafrost converts forest and tundra into wetlands. Northern latitudes are expected to get warmer and wetter, and while there is consensus that warming will increase thaw and methane emissions, effects of increased precipitation are uncertain. At a thawing wetland complex in Interior Alaska, we found that interactions between rain and deep soil temperatures controlled methane emissions. In rainy years, recharge from the watershed rapidly altered wetland soil temperatures, warming the top ~80 cm of soil in spring and summer and cooling it in autumn. When soils were warmed by spring rainfall, methane emissions increased by ~30%. The warm, deep soils early in the growing season likely supported both microbial and plant processes that enhanced emissions. Our study identifies an important and unconsidered role of rain in governing the radiative forcing of thawing permafrost landscapes. Plain Language Summary: Because the world is getting warmer, permanently frozen ground around the arctic, known as permafrost, is thawing. When permafrost thaws, the ground collapses and sinks. Often a wetland forms within the collapsed area. Conversion of permanently frozen landscapes to wetlands changes the exchange of greenhouse gases between the land and atmosphere, which impacts global temperatures. Wetlands release methane into the atmosphere. Methane is a potent greenhouse gas. The ability of methane to warm the Earth is 32 times stronger than that of carbon dioxide over a period of 100 years. In our study, we found that methane release from a thaw wetland in Interior Alaska was greater in rainy years when rain fell in spring. When spring rainwater entered the wetland, it rapidly warmed wetland soils. Rain has roughly the same temperature as the air, and during springtime in northern regions, the air is warmer than the ground. The microbial and plant processes that generate methane increase with temperature. Therefore, wetland soils, warmed by spring rainfall, supported more methane production and release. Northern regions are expected to receive more rainfall in the future. By warming soils and increasing methane release, this rainfall could increase near‐term global warming associated with permafrost thaw. Key Points: In rainy years, recharge from the watershed rapidly altered wetland soil temperatures, affecting sedge abundance and methane emissionsWhen wetland soils were warmed by spring rainfall, growing‐season methane emissions increased by ~30%By advecting thermal energy into soil, precipitation regulates the near‐term global warming potential of thawing permafrost landscapes [ABSTRACT FROM AUTHOR]

Published

2019

19. Soil microbial community composition is correlated to soil carbon processing along a boreal wetland formation gradient.

Author

Chapman, Eric J., Cadillo-Quiroz, Hinsby, Childers, Daniel L., Turetsky, Merritt R., and Waldrop, Mark P.

Subjects

*SOIL microbiology, *MICROBIAL communities, *SOIL composition, *CLIMATE change, *CARBON

Abstract

Climate change is modifying global biogeochemical cycles. Microbial communities play an integral role in soil biogeochemical cycles; knowledge about microbial composition helps provide a mechanistic understanding of these ecosystem-level phenomena. Next generation sequencing approaches were used to investigate changes in microbial functional groups during ecosystem development, in response to climate change, in northern boreal wetlands. A gradient of wetlands that developed following permafrost degradation was used to characterize changes in the soil microbial communities that mediate C cycling: a bog representing an “undisturbed” system with intact permafrost, and a younger bog and an older bog that formed following the disturbance of permafrost thaw. Reference 16S rRNA databases and several diversity indices were used to assess structural differences among these communities, to assess relationships between soil microbial community composition and various environmental variables including redox potential and pH. Rates of potential CO 2 and CH 4 gas production were quantified to correlate sequence data with gas flux. The abundance of organic C degraders was highest in the youngest bog, suggesting higher rates of microbial processes, including potential CH 4 production. In addition, alpha diversity was also highest in the youngest bog, which seemed to be related to a more neutral pH and a lower redox potential. These results could potentially be driven by increased niche differentiation in anaerobic soils. These results suggest that ecosystem structure, which was largely driven by changes in edaphic and plant community characteristics between the “undisturbed” permafrost bog and the two bogs formed following permafrost thaw, strongly influenced microbial function. [ABSTRACT FROM AUTHOR]

Published

2017

20. A decade of boreal rich fen greenhouse gas fluxes in response to natural and experimental water table variability.

Author

Olefeldt, David, Euskirchen, Eugénie S., Harden, Jennifer, Kane, Evan, McGuire, A. David, Waldrop, Mark P., and Turetsky, Merritt R.

Subjects

*TAIGA ecology, *FEN ecology, *METHANE & the environment, *DROUGHTS, *PEATLAND ecology

Abstract

Rich fens are common boreal ecosystems with distinct hydrology, biogeochemistry and ecology that influence their carbon (C) balance. We present growing season soil chamber methane emission ( FCH4), ecosystem respiration ( ER), net ecosystem exchange ( NEE) and gross primary production ( GPP) fluxes from a 9-years water table manipulation experiment in an Alaskan rich fen. The study included major flood and drought years, where wetting and drying treatments further modified the severity of droughts. Results support previous findings from peatlands that drought causes reduced magnitude of growing season FCH4, GPP and NEE, thus reducing or reversing their C sink function. Experimentally exacerbated droughts further reduced the capacity for the fen to act as a C sink by causing shifts in vegetation and thus reducing magnitude of maximum growing season GPP in subsequent flood years by ~15% compared to control plots. Conversely, water table position had only a weak influence on ER, but dominant contribution to ER switched from autotrophic respiration in wet years to heterotrophic in dry years. Droughts did not cause inter-annual lag effects on ER in this rich fen, as has been observed in several nutrient-poor peatlands. While ER was dependent on soil temperatures at 2 cm depth, FCH4 was linked to soil temperatures at 25 cm. Inter-annual variability of deep soil temperatures was in turn dependent on wetness rather than air temperature, and higher FCH4 in flooded years was thus equally due to increased methane production at depth and decreased methane oxidation near the surface. Short-term fluctuations in wetness caused significant lag effects on FCH4, but droughts caused no inter-annual lag effects on FCH4. Our results show that frequency and severity of droughts and floods can have characteristic effects on the exchange of greenhouse gases, and emphasize the need to project future hydrological regimes in rich fens. [ABSTRACT FROM AUTHOR]

Published

2017

21. Seasonal Electrical Resistivity Surveys of a Coastal Bluff, Barter Island, North Slope Alaska.

Author

Swarzenski, Peter W., Johnson, Cordell D., Lorenson, Tom D., Conaway, Christopher H., Gibbs, Ann E., Erikson, Li H., Richmond, Bruce M., and Waldrop, Mark P.

Subjects

*ELECTRICAL resistivity, *SHORELINES, *SUMMER, *THAWING

Abstract

Select coastal regions of the North Slope of Alaska are experiencing high erosion rates that can be attributed in part to recent warming trends and associated increased storm intensity and frequency. The upper sediment column of the coastal North Slope of Alaska can be described as continuous permafrost underlying a thin (typically less than 1-2 m) active layer that responds variably to seasonal thaw cycles. Assessing the temporal and spatial variability of the active layer and underlying permafrost is essential to better constrain how heightened erosion may impact material fluxes to the atmosphere and the coastal ocean, and how enhanced thaw cycles may impact the stability of the coastal bluffs. In this study, multi-channel electrical resistivity tomography (ERT) was used to image shallow subsurface features of a coastal bluff west of Kaktovik, on Barter Island, northeast Alaska. A comparison of a suite of paired resistivity surveys conducted in early and late summer 2014 provided detailed information on how the active layer and permafrost are impacted during the short Arctic summer. Such results are useful in the development of coastal resilience models that tie together fluvial, terrestrial, climatic, geologic, and oceanographic forcings on shoreline stability. [ABSTRACT FROM AUTHOR]

Published

2016

22. Linking microbial community structure and microbial processes: an empirical and conceptual overview.

Author

Bier, Raven L., Bernhardt, Emily S., Boot, Claudia M., Graham, Emily B., Hall, Edward K., Lennon, Jay T., Nemergut, Diana R., Osborne, Brooke B., González, Clara Ruiz, Schimel, Joshua P., Waldrop, Mark P., and Wallenstein, Matthew D.

Subjects

*MICROBIAL ecology, *RANK correlation (Statistics), *MICROORGANISMS, *STATISTICAL correlation, *MICROBIOLOGY

Abstract

A major goal of microbial ecology is to identify links between microbial community structure and microbial processes. Although this objective seems straightforward, there are conceptual and methodological challenges to designing studies that explicitly evaluate this link. Here, we analyzed literature documenting structure and process responses to manipulations to determine the frequency of structure-process links and whether experimental approaches and techniques influence link detection. We examined nine journals (published 2009-13) and retained 148 experimental studies measuring microbial community structure and processes. Many qualifying papers (112 of 148) documented structure and process responses, but few (38 of 112 papers) reported statistically testing for a link. Of these tested links, 75% were significant and typically used Spearman or Pearson's correlation analysis (68%). No particular approach for characterizing structure or processes was more likely to produce significant links. Process responses were detected earlier on average than responses in structure or both structure and process. Together, our findings suggest that few publications report statistically testing structure-process links. However, when links are tested for they often occur but share few commonalities in the processes or structures that were linked and the techniques used for measuring them. [ABSTRACT FROM AUTHOR]

Published

2015

23. Relationships between protein-encoding gene abundance and corresponding process are commonly assumed yet rarely observed.

Author

Rocca, Jennifer D, Hall, Edward K, Lennon, Jay T, Evans, Sarah E, Waldrop, Mark P, Cotner, James B, Nemergut, Diana R, Graham, Emily B, and Wallenstein, Matthew D

Subjects

*ECOLOGICAL genetics, *GENETIC code, *META-analysis, *GENETIC translation, *OPEN reading frames (Genetics), *GENETIC transcription

Abstract

For any enzyme-catalyzed reaction to occur, the corresponding protein-encoding genes and transcripts are necessary prerequisites. Thus, a positive relationship between the abundance of gene or transcripts and corresponding process rates is often assumed. To test this assumption, we conducted a meta-analysis of the relationships between gene and/or transcript abundances and corresponding process rates. We identified 415 studies that quantified the abundance of genes or transcripts for enzymes involved in carbon or nitrogen cycling. However, in only 59 of these manuscripts did the authors report both gene or transcript abundance and rates of the appropriate process. We found that within studies there was a significant but weak positive relationship between gene abundance and the corresponding process. Correlations were not strengthened by accounting for habitat type, differences among genes or reaction products versus reactants, suggesting that other ecological and methodological factors may affect the strength of this relationship. Our findings highlight the need for fundamental research on the factors that control transcription, translation and enzyme function in natural systems to better link genomic and transcriptomic data to ecosystem processes. [ABSTRACT FROM AUTHOR]

Published

2015

24. Mechanisms for retention of low molecular weight organic carbon varies with soil depth at a coastal prairie ecosystem.

Author

McFarland, Jack W., Lawrence, Corey R., Creamer, Courtney, Schulz, Marjorie S., Conaway, Christopher H., Peek, Sara, Waldrop, Mark P., Sevilgen, Sabrina, and Haw, Monica

Subjects

*MOLECULAR weights, *SOIL depth, *CARBON in soils, *OXALIC acid, *CARBON compounds, *PRAIRIES

Abstract

Though primary sources of carbon (C) to soil are plant inputs (e.g., rhizodeposits), the role of microorganisms as mediators of soil organic carbon (SOC) retention is increasingly recognized. Yet, insufficient knowledge of sub-soil processes complicates attempts to describe microbial-driven C cycling at depth as most studies of microbial-mineral-C interactions focus on surface horizons. We leveraged a well-studied paleo-marine terrace (90 ka) located near Santa Cruz, CA, to characterize the short-term (days to weeks) and intermediate-term (months to years) fate of two low molecular weight organic carbon. compounds at three depths in the soil profile (∼25 cm, A horizon; ∼75 cm A/B transition; and ∼125 cm, B horizon). We employed isotopically-labeled glucose (GLU) and oxalic acid (OXA) to represent two common classes of rhizodeposits: carbohydrates and organic acids. Using a combination of laboratory (9 d) and field (490 d) incubations, we traced the fate of GLU-C and OXA-C through dissolved-, metal-associated-, and microbially-respired CO 2 and bulk SOC pools. Our results suggest new SOC retention (i.e., defined as 13C label identified in solid or aqueous fractions) over intermediate time frames (490 d) is correlated with patterns in short-term (9 d) cycling dynamics, which in turn is related to the theoretical efficiency by which microorganisms process each substrate. For all horizons (A, A/B, and B) GLU-C was converted to CO 2 more quickly than OXA-C with modeled decomposition rates ∼2–4 times faster for GLU depending on microbial density (higher in A than B horizon). The faster decomposition rates of GLU-C increased fractional recovery (0.399 ± 0.026 to 0.504 ± 0.030 for GLU-C) compared to OXA-C (0.035 ± 0.003 to 0.127 ± 0.010) among all horizons in our field experiment (490 d). Though the overall proportion of GLU-C recovered in solid fractions did not vary significantly with horizon, based on 13C recovered in aqueous fractions the apparent mechanism for retention did. After the 9-d laboratory incubation, fractional recovery for GLU-C among C pools associated with microbial biomass was almost 20× higher than OXA-C (0.192 versus 0.010, respectively across all horizons). More than a year later, 43–46% of GLU-C retained in the field incubation was extractable with a neutral salt (representing a pool of soil C residing within or available to microbial biomass) among A and A/B horizons, while only 6% of retained GLU-C was similarly extractable in the B horizon. Thus, it appears among depths with higher microbial density (A, A/B horizons), anabolic recycling is the most likely process contributing to the persistence of glucose C, whereas abiotic sinks contributed more to intermediate-term stability for GLU-C in the B horizon. By contrast, most OXA-C was lost, presumably as CO 2 , over the short-term from the A and A/B horizons (fractional recovery: 0.136 ± 0.011 and 0.091 ± 0.002, respectively). However, though substantially lower than GLU-C recovered at the conclusion of our field experiment, the fraction of oxalic acid C retained in the B horizon over both short- (0.72 ± 0.037) and intermediate-time (0.127 ± 0.010) frames was several-fold higher than for overlying horizons. The specific process(es) (e.g., more efficient microbial utilization, metal-organic complexation, direct adsorption to the mineral matrix, etc.) contributing to higher retention for OXA-C at depth are discussed but remain unresolved. We examined the cycling of two different isotopically labeled low molecular weight organic carbon (LMWOC) compounds, glucose (red) and oxalic acid (blue), using a combination of field and laboratory incubations. Our results suggest that in surface soils, glucose was retained to a greater extent, likely through microbial reassimilation of necromass, compared to oxalic acid, which was largely lost through mineralization to CO 2. In the subsurface soils, mechanisms including organo-metal complexation (hexagons) and other unidentified mineral organic associations allowed for greater abiotic retention of both carbon compounds. Though, there was still evidence of greater glucose recycling and oxalic acid mineralization at depth. [Display omitted] • Glucose and oxalic acid C traced over 9 and 490 d through A, A/B, B soil horizons. • After 490 d in situ approximately half of glucose C was retained among all horizons. • Anabolism appears to contribute to persistence of glucose C at all depths. • Oxalic acid C poorly retained among A, A/B soil horizons; more persistent at depth. • Importance of organo-metal complexation appears to increase with depth for newer OC. [ABSTRACT FROM AUTHOR]

Published

2022

25. A pan-Arctic synthesis of CH4 and CO2 production from anoxic soil incubations.

Author

Treat, Claire C., Natali, Susan M., Ernakovich, Jessica, Iversen, Colleen M., Lupascu, Massimo, McGuire, Anthony David, Norby, Richard J., Roy Chowdhury, Taniya, Richter, Andreas, Šantrůčková, Hana, Schädel, Christina, Schuur, Edward A. G., Sloan, Victoria L., Turetsky, Merritt R., and Waldrop, Mark P.

Subjects

*CARBON dioxide, *SOIL composition, *METAL content of soils, *SOIL moisture, *SOIL ecology, *PLANT-soil relationships

Abstract

Permafrost thaw can alter the soil environment through changes in soil moisture, frequently resulting in soil saturation, a shift to anaerobic decomposition, and changes in the plant community. These changes, along with thawing of previously frozen organic material, can alter the form and magnitude of greenhouse gas production from permafrost ecosystems. We synthesized existing methane (CH4) and carbon dioxide (CO2) production measurements from anaerobic incubations of boreal and tundra soils from the geographic permafrost region to evaluate large-scale controls of anaerobic CO2 and CH4 production and compare the relative importance of landscape-level factors (e.g., vegetation type and landscape position), soil properties (e.g., pH, depth, and soil type), and soil environmental conditions (e.g., temperature and relative water table position). We found fivefold higher maximum CH4 production per gram soil carbon from organic soils than mineral soils. Maximum CH4 production from soils in the active layer (ground that thaws and refreezes annually) was nearly four times that of permafrost per gram soil carbon, and CH4 production per gram soil carbon was two times greater from sites without permafrost than sites with permafrost. Maximum CH4 and median anaerobic CO2 production decreased with depth, while CO2:CH4 production increased with depth. Maximum CH4 production was highest in soils with herbaceous vegetation and soils that were either consistently or periodically inundated. This synthesis identifies the need to consider biome, landscape position, and vascular/moss vegetation types when modeling CH4 production in permafrost ecosystems and suggests the need for longer-term anaerobic incubations to fully capture CH4 dynamics. Our results demonstrate that as climate warms in arctic and boreal regions, rates of anaerobic CO2 and CH4 production will increase, not only as a result of increased temperature, but also from shifts in vegetation and increased ground saturation that will accompany permafrost thaw. [ABSTRACT FROM AUTHOR]

Published

2015

26. Spatially explicit estimation of aboveground boreal forest biomass in the Yukon River Basin, Alaska.

Author

Ji, Lei, Wylie, Bruce K., Brown, Dana R. N., Peterson, Birgit, Alexander, Heather D., Mack, Michelle C., Rover, Jennifer, Waldrop, Mark P., McFarland, Jack W., Chen, Xuexia, and Pastick, Neal J.

Subjects

*TAIGAS, *FOREST biomass, *CARBON cycle, *LANDSAT satellites, *REMOTE-sensing images, *REGRESSION analysis

Abstract

Quantification of aboveground biomass (AGB) in Alaska’s boreal forest is essential to the accurate evaluation of terrestrial carbon stocks and dynamics in northern high-latitude ecosystems. Our goal was to map AGB at 30 m resolution for the boreal forest in the Yukon River Basin of Alaska using Landsat data and ground measurements. We acquired Landsat images to generate a 3-year (2008–2010) composite of top-of-atmosphere reflectance for six bands as well as the brightness temperature (BT). We constructed a multiple regression model using field-observed AGB and Landsat-derived reflectance, BT, and vegetation indices. A basin-wide boreal forest AGB map at 30 m resolution was generated by applying the regression model to the Landsat composite. The fivefold cross-validation with field measurements had a mean absolute error (MAE) of 25.7 Mg ha−1(relative MAE 47.5%) and a mean bias error (MBE) of 4.3 Mg ha−1(relative MBE 7.9%). The boreal forest AGB product was compared with lidar-based vegetation height data; the comparison indicated that there was a significant correlation between the two data sets. [ABSTRACT FROM AUTHOR]

Published

2015

27. Impact of fire on active layer and permafrost microbial communities and metagenomes in an upland Alaskan boreal forest.

Author

Taş, Neslihan, Prestat, Emmanuel, McFarland, Jack W, Wickland, Kimberley P, Knight, Rob, Berhe, Asmeret Asefaw, Jorgenson, Torre, Waldrop, Mark P, and Jansson, Janet K

Subjects

*PERMAFROST microbiology, *FOREST fires, *TAIGAS, *SOIL microbiology, *CLIMATE change, *GREENHOUSE gases & the environment, *FOREST reserves

Abstract

Permafrost soils are large reservoirs of potentially labile carbon (C). Understanding the dynamics of C release from these soils requires us to account for the impact of wildfires, which are increasing in frequency as the climate changes. Boreal wildfires contribute to global emission of greenhouse gases (GHG-CO2, CH4 and N2O) and indirectly result in the thawing of near-surface permafrost. In this study, we aimed to define the impact of fire on soil microbial communities and metabolic potential for GHG fluxes in samples collected up to 1 m depth from an upland black spruce forest near Nome Creek, Alaska. We measured geochemistry, GHG fluxes, potential soil enzyme activities and microbial community structure via 16SrRNA gene and metagenome sequencing. We found that soil moisture, C content and the potential for respiration were reduced by fire, as were microbial community diversity and metabolic potential. There were shifts in dominance of several microbial community members, including a higher abundance of candidate phylum AD3 after fire. The metagenome data showed that fire had a pervasive impact on genes involved in carbohydrate metabolism, methanogenesis and the nitrogen cycle. Although fire resulted in an immediate release of CO2 from surface soils, our results suggest that the potential for emission of GHG was ultimately reduced at all soil depths over the longer term. Because of the size of the permafrost C reservoir, these results are crucial for understanding whether fire produces a positive or negative feedback loop contributing to the global C cycle. [ABSTRACT FROM AUTHOR]

Published

2014

28. Estimating aboveground biomass in interior Alaska with Landsat data and field measurements

Author

Ji, Lei, Wylie, Bruce K., Nossov, Dana R., Peterson, Birgit, Waldrop, Mark P., McFarland, Jack W., Rover, Jennifer, and Hollingsworth, Teresa N.

Subjects

*ESTIMATION theory, *BIOMASS estimation, *LANDSAT satellites, *DATA analysis, *FIELD theory (Physics), *ECOLOGICAL systems theory

Abstract

Abstract: Terrestrial plant biomass is a key biophysical parameter required for understanding ecological systems in Alaska. An accurate estimation of biomass at a regional scale provides an important data input for ecological modeling in this region. In this study, we created an aboveground biomass (AGB) map at 30-m resolution for the Yukon Flats ecoregion of interior Alaska using Landsat data and field measurements. Tree, shrub, and herbaceous AGB data in both live and dead forms were collected in summers and autumns of 2009 and 2010. Using the Landsat-derived spectral variables and the field AGB data, we generated a regression model and applied this model to map AGB for the ecoregion. A 3-fold cross-validation indicated that the AGB estimates had a mean absolute error of 21.8Mg/ha and a mean bias error of 5.2Mg/ha. Additionally, we validated the mapping results using an airborne lidar dataset acquired for a portion of the ecoregion. We found a significant relationship between the lidar-derived canopy height and the Landsat-derived AGB (R 2 =0.40). The AGB map showed that 90% of the ecoregion had AGB values ranging from 10Mg/ha to 134Mg/ha. Vegetation types and fires were the primary factors controlling the spatial AGB patterns in this ecoregion. [Copyright &y& Elsevier]

Published

2012

29. Microbes in thawing permafrost: the unknown variable in the climate change equation.

Author

Graham, David E, Wallenstein, Matthew D, Vishnivetskaya, Tatiana A, Waldrop, Mark P, Phelps, Tommy J, Pfiffner, Susan M, Onstott, Tullis C, Whyte, Lyle G, Rivkina, Elizaveta M, Gilichinsky, David A, Elias, Dwayne A, Mackelprang, Rachel, VerBerkmoes, Nathan C, Hettich, Robert L, Wagner, Dirk, Wullschleger, Stan D, and Jansson, Janet K

Subjects

*PERMAFROST microbiology, *CLIMATE change, *METHANOBACTERIACEAE, *HUMUS, *MICROBIOLOGICAL synthesis, *THERMOKARST, *HYDROLOGY

Published

2012

30. Stoichiometry of soil enzyme activity at global scale.

Author

Sinsabaugh, Robert L., Lauber, Christian L., Weintraub, Michael N., Ahmed, Bony, Allison, Steven D., Crenshaw, Chelsea, Contosta, Alexandra R., Cusack, Daniela, Frey, Serita, Gallo, Marcy E., Gartner, Tracy B., Hobbie, Sarah E., Holland, Keri, Keeler, Bonnie L., Powers, Jennifer S., Stursova, Martina, Takacs-Vesbach, Cristina, Waldrop, Mark P., Wallenstein, Matthew D., and Zak, Donald R.

Subjects

*SOIL enzymology, *META-analysis, *BIOTIC communities, *EXTRACELLULAR enzymes, *STOICHIOMETRY, *ORGANIC compounds, *BIODEGRADATION

Abstract

Extracellular enzymes are the proximate agents of organic matter decomposition and measures of these activities can be used as indicators of microbial nutrient demand. We conducted a global-scale meta-analysis of the seven-most widely measured soil enzyme activities, using data from 40 ecosystems. The activities of β-1,4-glucosidase, cellobiohydrolase, β-1,4- N-acetylglucosaminidase and phosphatase g−1 soil increased with organic matter concentration; leucine aminopeptidase, phenol oxidase and peroxidase activities showed no relationship. All activities were significantly related to soil pH. Specific activities, i.e. activity g−1 soil organic matter, also varied in relation to soil pH for all enzymes. Relationships with mean annual temperature (MAT) and precipitation (MAP) were generally weak. For hydrolases, ratios of specific C, N and P acquisition activities converged on 1 : 1 : 1 but across ecosystems, the ratio of C : P acquisition was inversely related to MAP and MAT while the ratio of C : N acquisition increased with MAP. Oxidative activities were more variable than hydrolytic activities and increased with soil pH. Our analyses indicate that the enzymatic potential for hydrolyzing the labile components of soil organic matter is tied to substrate availability, soil pH and the stoichiometry of microbial nutrient demand. The enzymatic potential for oxidizing the recalcitrant fractions of soil organic material, which is a proximate control on soil organic matter accumulation, is most strongly related to soil pH. These trends provide insight into the biogeochemical processes that create global patterns in ecological stoichiometry and organic matter storage. [ABSTRACT FROM AUTHOR]

Published

2008

31. Extracellular Enzyme Activities and Soil Organic Matter Dynamics for Northern Hardwood Forests receiving Simulated Nitrogen Deposition.

Author

Sinsabaugh, Robert L., Gallo, Marcy E., Lauber, Christian, Waldrop, Mark P., and Zak, Donald R.

Subjects

*ENZYMES, *HUMUS, *FORESTS & forestry, *NITROGEN, *SEDIMENTATION & deposition, *CARBON

Abstract

Anthropogenic nitrogen enrichment alters decomposition processes that control the flux of carbon (C) and nitrogen (N) from soil organic matter (SOM) pools. To link N-driven changes in SOM to microbial responses, we measured the potential activity of several extracellular enzymes involved in SOM degradation at nine experimental sites located in northern Michigan. Each site has three treatment plots (ambient, +30 and +80 kg N ha−1 y−1). Litter and soil samples were collected on five dates over the third growing season of N treatment. Phenol oxidase, peroxidase and cellobiohydrolase activities showed significant responses to N additions. In the Acer saccharum– Tilia americana ecosystem, oxidative activity was 38% higher in the litter horizon of high N treatment plots, relative to ambient plots, while oxidative activity in mineral soil showed little change. In the A. saccharum– Quercus rubra and Q. velutina– Q. alba ecosystems, oxidative activities declined in both litter (15 and 23%, respectively) and soil (29 and 38%, respectively) in response to high N treatment while cellobiohydrolase activity increased (6 and 39% for litter, 29 and 18% for soil, respectively). Over 3 years, SOM content in the high N plots has decreased in the Acer– Tilia ecosystem and increased in the two Quercus ecosystems, relative to ambient plots. For all three ecosystems, differences in SOM content in relation to N treatment were directly related ( r 2 = 0.92) to an enzyme activity factor that included both oxidative and hydrolytic enzyme responses. [ABSTRACT FROM AUTHOR]

Published

2005

32. Restoration and Canopy Type Influence Soil Microflora in a Ponderosa Pine Forest.

Author

Boyle, Sarah I., Hart, Stephen C., Kaye, Jason P., and Waldrop, Mark P.

Subjects

*CONSERVATION of natural resources, *PINE, *PINACEAE, *EVAPORATION (Meteorology), *ENZYMES, *BIOGEOCHEMICAL cycles

Abstract

In ponderosa pine (Pinus ponderosa Dougl. ex Laws.) forests of the western USA, fire exclusion by Euro-American settlers facilitated pine invasion of grass openings, increased forest floor detritus, and shifted the disturbance regime toward stand-replacing fires. We evaluated the impacts of two replicated ecological restoration treatments involving tree thinning alone (thinning restoration) and a combination of tree thinning, forest floor reduction, and prescribed burning (composite restoration) on soil microbial activity, biomass, and function approximately 8 yr after initial treatments. Microbial-N levels in the two restoration treatments were not significantly different from the control during either the dry or wet periods of the growing season. Soil respiration measured in situ was significantly higher in the restoration treatments than in the control only during the dry period, while soil enzyme activities were generally higher in the composite restoration treatment than in the thinning restoration or control treatments during the wet period. Community-level physiological profiles suggested differences in the physiological capacities of bacteria and fungi in the composite restoration treatment compared with the other treatments. We also compared microbial characteristics under different canopy types to evaluate the impacts of pine invasion and establishment in grass openings on soil microorganisms. Soil respiration rates (dry period only) and enzyme activities (wet period only) were higher in grass openings than under presettlement trees, with intermediate values found under postsettlement pines that have invaded grass areas. Taken together, our results suggest that restoration treatments have long-term impacts on the soil microflora in these forests. [ABSTRACT FROM AUTHOR]

Published

2005