Your search keyword '"Alyson E. Santoro"' showing total 95 results

1. Exaggerated trans-membrane charge of ammonium transporters in nutrient-poor marine environments

Author

Matthew Kellom, Stefano Pagliara, Thomas A. Richards, and Alyson E. Santoro

Subjects

competition, SAR11, SAR86, Thermoproteota, Thaumarchaea, membrane transport, Biology (General), QH301-705.5

Abstract

Transporter proteins are a vital interface between cells and their environment. In nutrient-limited environments, microbes with transporters that are effective at bringing substrates into their cells will gain a competitive advantage over variants with reduced transport function. Microbial ammonium transporters (Amt) bring ammonium into the cytoplasm from the surrounding periplasm space, but diagnosing Amt adaptations to low nutrient environments solely from sequence data has been elusive. Here, we report altered Amt sequence amino acid distribution from deep marine samples compared to variants sampled from shallow water in two important microbial lineages of the marine water column community—Marine Group I Archaea (Thermoproteota) and the uncultivated gammaproteobacterial lineage SAR86. This pattern indicates an evolutionary pressure towards an increasing dipole in Amt for these clades in deep ocean environments and is predicted to generate stronger electric fields facilitating ammonium acquisition. This pattern of increasing dipole charge with depth was not observed in lineages capable of accessing alternative nitrogen sources, including the abundant alphaproteobacterial clade SAR11. We speculate that competition for ammonium in the deep ocean drives transporter sequence evolution. The low concentration of ammonium in the deep ocean is therefore likely due to rapid uptake by Amts concurrent with decreasing nutrient flux.

Published

2022

2. Heterotrophic Thaumarchaea with Small Genomes Are Widespread in the Dark Ocean

Author

Frank O. Aylward and Alyson E. Santoro

Subjects

Thaumarchaeota, marine archaea, TACK, PQQ-dehydrogenase, RuBisCO, Microbiology, QR1-502

Abstract

ABSTRACT The Thaumarchaeota is a diverse archaeal phylum comprising numerous lineages that play key roles in global biogeochemical cycling, particularly in the ocean. To date, all genomically characterized marine thaumarchaea are reported to be chemolithoautotrophic ammonia oxidizers. In this study, we report a group of putatively heterotrophic marine thaumarchaea (HMT) with small genome sizes that is globally abundant in the mesopelagic, apparently lacking the ability to oxidize ammonia. We assembled five HMT genomes from metagenomic data and show that they form a deeply branching sister lineage to the ammonia-oxidizing archaea (AOA). We identify this group in metagenomes from mesopelagic waters in all major ocean basins, with abundances reaching up to 6% of that of AOA. Surprisingly, we predict the HMT have small genomes of ∼1 Mbp, and our ancestral state reconstruction indicates this lineage has undergone substantial genome reduction compared to other related archaea. The genomic repertoire of HMT indicates a versatile metabolism for aerobic chemoorganoheterotrophy that includes a divergent form III-a RuBisCO, a 2M respiratory complex I that has been hypothesized to increase energetic efficiency, and a three-subunit heme-copper oxidase complex IV that is absent from AOA. We also identify 21 pyrroloquinoline quinone (PQQ)-dependent dehydrogenases that are predicted to supply reducing equivalents to the electron transport chain and are among the most highly expressed HMT genes, suggesting these enzymes play an important role in the physiology of this group. Our results suggest that heterotrophic members of the Thaumarchaeota are widespread in the ocean and potentially play key roles in global chemical transformations. IMPORTANCE It has been known for many years that marine Thaumarchaeota are abundant constituents of dark ocean microbial communities, where their ability to couple ammonia oxidation and carbon fixation plays a critical role in nutrient dynamics. In this study, we describe an abundant group of putatively heterotrophic marine Thaumarchaeota (HMT) in the ocean with physiology distinct from those of their ammonia-oxidizing relatives. HMT lack the ability to oxidize ammonia and fix carbon via the 3-hydroxypropionate/4-hydroxybutyrate pathway but instead encode a form III-a RuBisCO and diverse PQQ-dependent dehydrogenases that are likely used to conserve energy in the dark ocean. Our work expands the scope of known diversity of Thaumarchaeota in the ocean and provides important insight into a widespread marine lineage.

Published

2020

3. Distinguishing between Microbial Habitats Unravels Ecological Complexity in Coral Microbiomes

Author

Amy Apprill, Laura G. Weber, and Alyson E. Santoro

Subjects

Caribbean, SSU rRNA gene, coral, microbiome, Microbiology, QR1-502

Abstract

ABSTRACT The diverse prokaryotic communities associated with reef-building corals may provide important ecological advantages to their threatened hosts. The consistency of relationships between corals and specific prokaryotes, however, is debated, and the locations where microbially mediated processes occur in the host are not resolved. Here, we examined how the prokaryotic associates of five common Caribbean corals with different evolutionary and ecological traits differ across mucus and tissue habitats. We used physical and chemical separation of coral mucus and tissue and sequencing of partial small-subunit rRNA genes of bacteria and archaea from these samples to demonstrate that coral tissue and mucus harbor unique reservoirs of prokaryotes, with 23 to 49% and 31 to 56% of sequences exclusive to the tissue and mucus habitats, respectively. Across all coral species, we found that 46 tissue- and 22 mucus-specific microbial members consistently associated with the different habitats. Sequences classifying as “Candidatus Amoebophilus,” Bacteroidetes-affiliated intracellular symbionts of amoebae, emerged as previously unrecognized tissue associates of three coral species. This study demonstrates how coral habitat differentiation enables highly resolved examination of ecological interactions between corals and their associated microorganisms and identifies previously unrecognized tissue and mucus associates of Caribbean corals for future targeted study. IMPORTANCE This study demonstrates that coral tissue or mucus habitats structure the microbiome of corals and that separation of these habitats facilitates identification of consistent microbial associates. Using this approach, we demonstrated that sequences related to “Candidatus Amoebophilus,” recognized intracellular symbionts of amoebae, were highly associated with the tissues of Caribbean corals and possibly endosymbionts of a protistan host within corals, adding a further degree of intricacy to coral holobiont symbioses. Examining specific habitats within complex hosts such as corals is useful for targeting important microbial associations that may otherwise be masked by the sheer microbial diversity associated with all host habitats.

Published

2016

4. Synechococcus nitrogen gene loss in iron-limited ocean regions

Author

Garrett Sharpe, Liang Zhao, Meredith G Meyer, Weida Gong, Shannon M Burns, Allesandro Tagliabue, Kristen N Buck, Alyson E Santoro, Jason R Graff, Adrian Marchetti, and Scott Gifford

Published

2023

5. Constraining the composition and quantity of organic matter used by abundant marine Thaumarchaeota

Author

Alma E. Parada, Xavier Mayali, Peter K. Weber, Jessica Wollard, Alyson E. Santoro, Jed A. Fuhrman, Jennifer Pett‐Ridge, and Anne E. Dekas

Subjects

Microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

Marine Group I (MGI) Thaumarchaeota were originally described as chemoautotrophic nitrifiers, but molecular and isotopic evidence suggests heterotrophic and/or mixotrophic capabilities. Here, we investigated the quantity and composition of organic matter assimilated by individual, uncultured MGI cells from the Pacific Ocean to constrain their potential for mixotrophy and heterotrophy. We observed that most MGI cells did not assimilate carbon from any organic substrate provided (glucose, pyruvate, oxaloacetate, protein, urea, and amino acids). The minority of MGI cells that did assimilate it did so exclusively from nitrogenous substrates (urea, 15% of MGI and amino acids, 36% of MGI), and only as an auxiliary carbon source (20% of that subset's total cellular carbon was derived from those substrates). At the population level, MGI assimilation of organic carbon comprised just 0.5%-11% of total biomass carbon. We observed extensive assimilation of inorganic carbon and urea- and amino acid-derived nitrogen (equal to that from ammonium), consistent with metagenomic and metatranscriptomic analyses performed here and previously showing a widespread potential for MGI to perform autotrophy and transport and degrade organic nitrogen. Our results constrain the quantity and composition of organic matter used by MGI and suggest they use it primarily to meet nitrogen demands for anabolism and nitrification.

Published

2022

6. Database of nitrification and nitrifiers in the global ocean

Author

Weiyi Tang, Bess B. Ward, Michael Beman, Laura Bristow, Darren Clark, Sarah Fawcett, Claudia Frey, Francois Fripiat, Gerhard J. Herndl, Mhlangabezi Mdutyana, Fabien Paulot, Xuefeng Peng, Alyson E. Santoro, Takuhei Shiozaki, Eva Sintes, Charles Stock, Xin Sun, Xianhui S. Wan, Min N. Xu, and Yao Zhang

Abstract

As a key biogeochemical pathway in the marine nitrogen cycle, nitrification (ammonia oxidation and nitrite oxidation) converts the most reduced form of nitrogen – ammonium/ammonia (NH4+/ NH3) into the oxidized species nitrite (NO2−) and nitrate (NO3−). In the ocean, these processes are mainly performed by ammonia-oxidizing archaea (AOA) and bacteria (AOB), and nitrite-oxidizing bacteria (NOB). By transforming nitrogen speciation and providing substrates for nitrogen removal, nitrification affects microbial community structure, marine productivity (including chemoautotrophic carbon fixation) and the production of a powerful greenhouse gas, nitrous oxide (N2O). Nitrification is hypothesized to be regulated by temperature, oxygen, light, substrate concentration, substrate flux, pH, and other environmental factors. Although the number of field observations from various oceanic regions has increased considerably over the last few decades, a global synthesis is lacking, and understanding how environmental factors control nitrification remains elusive. Therefore, we have compiled a database of nitrification rates and nitrifier abundance in the global ocean from published literature and unpublished datasets. This database includes 2393 and 1006 measurements of ammonia oxidation and nitrite oxidation rates, and 2187 and 631 quantifications of ammonia oxidizers and nitrite oxidizers, respectively. This community effort confirms and enhances our understanding of the spatial distribution of nitrification and nitrifiers, and their corresponding drivers such as the important role of substrate concentration in controlling nitrification rates and nitrifier abundance. Some conundrums are also revealed including the inconsistent observations of light limitation and high rates of nitrite oxidation reported from anoxic waters. This database can be used to constrain the distribution of marine nitrification, to evaluate and improve biogeochemical models of nitrification, and to quantify the impact of nitrification on ecosystem functions like marine productivity and N2O production. This database additionally sets a baseline for comparison with future observations and guides future exploration (e.g., measurements in the poorly sampled regions such as the Indian Ocean; method comparison/standardization). The database is publicly available at Zenodo repository: https://doi.org/10.5281/zenodo.7942922 (Tang et al., 2023).

Published

2023

7. Quantitative analysis of food web dynamics in a low export ecosystem

Author

Heather M. McNair, Meredith G. Meyer, Sarah J. Lerch, Amy E. Maas, Brandon M. Stephens, James Fox, Kristen N. Buck, Shannon M. Burns, Ivona Cetinić, Melanie Cohn, Colleen Durkin, Scott Gifford, Weida Gong, Jason R. Graff, Bethany Jenkins, Erin L. Jones, Alyson E. Santoro, Connor H. Shea, Karen Stamieszkin, Deborah K. Steinberg, Adrian Marchetti, Craig A. Carlson, Susanne Menden-Deuer, Mark A. Brzezinski, David A. Siegel, and Tatiana A. Rynearson

Abstract

Food webs trace the flow of organic matter and energy among producers and consumers; for pelagic marine food webs, network complexity directly influences the amount and form of carbon exported to the deep ocean via the biological pump. Here we present a synoptic view of mixed layer food web dynamics observed during the late summer 2018 EXport Processes in the Ocean from Remote Sensing (EXPORTS) field campaign in the subarctic Northeast Pacific at the long-running time-series site, Ocean Station Papa. Carbon biomass reservoirs of phytoplankton, microzooplankton, and bacterioplankton, were approximately equal while mesozooplankton biomass was 70% lower. Live organisms composed ∼40% of the total particulate organic carbon within the mixed layer: the remainder was attributed to detritus. Rates of carbon transfer among reservoirs indicated production and assimilation rates were well balanced by losses, leaving little organic carbon available for export. The slight positive net community production rate generated organic carbon that was exported from the system in the form of food web byproducts, such as large fecal pellets generated by mesozooplankton. This characteristically regenerative food web had relatively slow turnover times with small-magnitude transfers of carbon relative to standing stocks that occurred amidst a high background concentration of detrital particles and dissolved organic matter. The concurrent estimation of food web components and rates revealed that separated processes dominated the transfer of carbon within the food web compared to those that contributed to export.Plain Language SummaryThe biological carbon pump drives a downward flux of organic matter from the sunlit surface ocean to the vast ocean interior. Ecological interactions in the surface ocean directly affect the amount and type of carbon that is exported to the deep ocean. In this study, we present a synthesis of the late summer mixed layer food web in the Northeast Pacific that was extensively characterized during the 2018 EXport Processes in the Ocean from Remote Sensing (EXPORTS) field campaign. We found the majority of carbon was recycled within the mixed layer by microbes through multiple transfers between producers and consumers. Larger organisms, mesozooplankton and salps, only consumed a small amount of carbon but through the formation of sinking fecal pellets were the main mechanism of transporting carbon out of the system. The study highlights the need to concurrently study microbial and large organism dynamics to develop a predictive understanding of the fate of organic carbon in the oceans.Key PointsThe microbial loop dominated carbon flow in the late summer mixed layer food web of the North Pacific, most net production was respired leaving little carbon available for export.Active production and consumption of organic carbon occurred amid a high background of detrital particulate organic carbon (58% of total) with slow turnover time, 66 d.Mesozooplankton which had relatively minor carbon consumption rates created the majority of export production due to efficient repackaging of consumed material.

Published

2023

8. Shifts in the Isotopic Composition of Nitrous Oxide between El Niño and La Niña in the Eastern Tropical South Pacific

Author

Noah Gluschankoff, Alyson E Santoro, Carolyn Buchwald, and Karen L Casciotti

Abstract

The El Niño-Southern Oscillation (ENSO) is a natural climate phenomenon that alters the biogeochemical and physical dynamics of the Eastern Tropical Pacific Ocean. Its two phases, El Niño and La Niña, are characterized by decreased and increased coastal upwelling, respectively, which have cascading effects on primary productivity, organic matter supply, and ocean-atmosphere interactions. The Eastern Tropical South Pacific (ETSP) oxygen minimum zone (OMZ) is a source of nitrous oxide (N2O), a potent greenhouse gas, to the atmosphere. While nitrogen cycling in the ETSP OMZ has been shown to be sensitive to ENSO, we present the first study to directly compare N2O distributions during both ENSO phases using N2O isotopocule analyses. Our data show that during La Niña, N2O accumulation increased six-fold in the upper 100 m of the water column, and N2O fluxes to the atmosphere increased up to 100-fold. N2O isotopocule data demonstrated substantial increases in δ18O up to 60.5‰ and decreases in δ15Nβ down to -10.3‰, signaling a shift in N2O cycling during La Niña in the oxycline compared to El Niño. N2O production via the hybrid pathway and incomplete denitrification with overprinting of N2O consumption are likely co-occurring to maintain the high site preference (SP) values (17‰ – 26.7‰), corroborating previous hypotheses. Ultimately, our results illustrate a strong connection between upwelling intensity, biogeochemistry, and N2O flux to the atmosphere, and highlight the importance of repeat measurements in the same region to constrain N2O interannual variability and cycling dynamics under different climate scenarios.

Published

2023

9. US National BioGeoSCAPES Workshop Report

Author

Benjamin S. Twining, Mak A. Saito, Alyson E. Santoro, Adrian Marchetti, and Naomi M. Levine

Abstract

BioGeoSCAPES (BGS) is an international program being developed to understand controls on ocean productivity and metabolism by integrating systems biology (‘omics) and biogeochemistry (Figure 1). To ensure global input into the design of the BGS Program, countries interested in participating were tasked with holding an organizing meeting to discuss the country-specific research priorities. A United States BGS planning meeting, sponsored by the Ocean Carbon & Biogeochemistry (OCB) Project Office, was convened virtually November 10-12, 2021. The objectives of the meeting were to communicate the planning underway by international partners, engage the US community to explore possible national contributions to such a program, and build understanding, support, and momentum for US efforts towards BGS. The meeting was well-attended, with 154 participants and many fruitful discussions that are summarized in this document. Key outcomes from the meeting were the identification of additional programs and partners for BGS, a prioritization of measurements requiring intercalibration, and the development of a consensus around key considerations to be addressed in a science plan. Looking forward, the hope is that this workshop will serve as the foundation for future US and international discussions and planning for a BGS program, enabled by NSF funding for an AccelNet project (AccelNet - Implementation: Development of an International Network for the Study of Ocean Metabolism and Nutrient Cycles on a Changing Planet (BioGeoSCAPES)), beginning in 2022.

Published

2023

10. Microbial siderophore production is tightly coupled to iron in hydrothermal plumes

Author

Colleen L. Hoffman, Patrick J. Monreal, Justine B. Albers, Alastair J.M. Lough, Alyson E. Santoro, Travis Mellett, Kristen N. Buck, Alessandro Tagliabue, Maeve C. Lohan, Joseph A. Resing, and Randelle M. Bundy

Abstract

Specialized molecules, such as siderophores, are used to access and retain iron in soluble forms by marine microorganisms. These siderophores form part of the ocean dissolved iron-binding ligand pool and are hypothesized to exert a key control on the persistence of iron in hydrothermal environments. To explore this hypothesis, we measured iron, iron-binding ligands, and siderophores from 11 geochemically distinct sites along a 1,700 km section of the Mid-Atlantic Ridge. We found siderophores at all sites and proximity to the vent played an important role in dictating siderophore types and diversity. The notable presence of amphiphilic siderophores may enable microbes to access particulate iron in hydrothermal plumes. The tight coupling between strong ligands and dissolved iron across six distinct hydrothermal environments, combined with the local presence of siderophore producing microbial genera suggests that biological production of siderophores exerts a key control on hydrothermal dissolved iron concentrations.

Published

2023

11. Microbial functional diversity across biogeochemical provinces in the central Pacific Ocean

Author

Jaclyn K. Saunders, Matthew R. McIlvin, Chris L. Dupont, Drishti Kaul, Dawn M. Moran, Tristan Horner, Sarah M. Laperriere, Eric A. Webb, Tanja Bosak, Alyson E. Santoro, and Mak A. Saito

Subjects

Proteomics, Nitrite Reductases, Pacific Ocean, Multidisciplinary, Bacteria, Bacterial Proteins, Archaeal Proteins, Microbiota, Seawater, Biodiversity, Archaea, Nitrification

Abstract

Enzymes catalyze key reactions within Earth’s life-sustaining biogeochemical cycles. Here, we use metaproteomics to examine the enzymatic capabilities of the microbial community (0.2 to 3 µm) along a 5,000-km-long, 1-km-deep transect in the central Pacific Ocean. Eighty-five percent of total protein abundance was of bacterial origin, with Archaea contributing 1.6%. Over 2,000 functional KEGG Ontology (KO) groups were identified, yet only 25 KO groups contributed over half of the protein abundance, simultaneously indicating abundant key functions and a long tail of diverse functions. Vertical attenuation of individual proteins displayed stratification of nutrient transport, carbon utilization, and environmental stress. The microbial community also varied along horizontal scales, shaped by environmental features specific to the oligotrophic North Pacific Subtropical Gyre, the oxygen-depleted Eastern Tropical North Pacific, and nutrient-rich equatorial upwelling. Some of the most abundant proteins were associated with nitrification and C1 metabolisms, with observed interactions between these pathways. The oxidoreductases nitrite oxidoreductase (NxrAB), nitrite reductase (NirK), ammonia monooxygenase (AmoABC), manganese oxidase (MnxG), formate dehydrogenase (FdoGH and FDH), and carbon monoxide dehydrogenase (CoxLM) displayed distributions indicative of biogeochemical status such as oxidative or nutritional stress, with the potential to be more sensitive than chemical sensors. Enzymes that mediate transformations of atmospheric gases like CO, CO 2 , NO, methanethiol, and methylamines were most abundant in the upwelling region. We identified hot spots of biochemical transformation in the central Pacific Ocean, highlighted previously understudied metabolic pathways in the environment, and provided rich empirical data for biogeochemical models critical for forecasting ecosystem response to climate change.

Published

2022

12. Candidatus Nitrosopelagicus

Author

Alyson E. Santoro, Barbara Bayer, Felix J. Elling, and Ann Pearson

Published

2021

13. The microbiome of a bacterivorous marine choanoflagellate contains a resource-demanding obligate bacterial associate

Author

David M. Needham, Camille Poirier, Charles Bachy, Emma E. George, Susanne Wilken, Charmaine C. M. Yung, Alexander J. Limardo, Michael Morando, Lisa Sudek, Rex R. Malmstrom, Patrick J. Keeling, Alyson E. Santoro, and Alexandra Z. Worden

Subjects

Microbiology (medical), Pacific Ocean, Bacteria, Microbiota, Prevention, Immunology, Cell Biology, Applied Microbiology and Biotechnology, Microbiology, Type IV Secretion Systems, Medical Microbiology, Genetics, Animals, Humans, Infection, Life Below Water, Choanoflagellata

Abstract

Microbial predators such as choanoflagellates are key players in ocean food webs. Choanoflagellates, which are the closest unicellular relatives of animals, consume bacteria and also exhibit marked biological transitions triggered by bacterial compounds, yet their native microbiomes remain uncharacterized. Here we report the discovery of a ubiquitous, uncultured bacterial lineage we name Candidatus Comchoanobacterales ord. nov., related to the human pathogen Coxiella and physically associated with the uncultured marine choanoflagellate Bicosta minor. We analyse complete ‘Comchoano’ genomes acquired after sorting single Bicosta cells, finding signatures of obligate host-dependence, including reduction of pathways encoding glycolysis, membrane components, amino acids and B-vitamins. Comchoano encode the necessary apparatus to import energy and other compounds from the host, proteins for host-cell associations and a type IV secretion system closest to Coxiella’s that is expressed in Pacific Ocean metatranscriptomes. Interactions between choanoflagellates and their microbiota could reshape the direction of energy and resource flow attributed to microbial predators, adding complexity and nuance to marine food webs.

Published

2022

14. Controls on the relative abundances and rates of nitrifying microorganisms in the ocean

Author

Emily J. Zakem, Barbara Bayer, Wei Qin, Alyson E. Santoro, Yao Zhang, and Naomi M. Levine

Subjects

Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes

Abstract

Nitrification controls the oxidation state of bioavailable nitrogen. Distinct clades of chemoautotrophic microorganisms – predominantly ammonia-oxidizing archaea (AOA) and nitrite-oxidizing bacteria (NOB) – regulate the two steps of nitrification in the ocean, but explanations for their observed relative abundances and nitrification rates remain incomplete and their contributions to the global marine carbon cycle via carbon fixation remain unresolved. Using a mechanistic microbial ecosystem model with nitrifying functional types, we derive simple expressions for the controls on AOA and NOB in the deep, oxygenated open ocean. The relative biomass yields, loss rates, and cell quotas of AOA and NOB control their relative abundances, though we do not need to invoke a difference in loss rates to explain the observed relative abundances. The supply of ammonium, not the traits of AOA or NOB, controls the relatively equal ammonia and nitrite oxidation rates at steady state. The relative yields of AOA and NOB alone set their relative bulk carbon fixation rates in the water column. The quantitative relationships are consistent with multiple in situ datasets. In a complex global ecosystem model, nitrification emerges dynamically across diverse ocean environments, and ammonia and nitrite oxidation and their associated carbon fixation rates are decoupled due to physical transport and complex ecological interactions in some environments. Nevertheless, the simple expressions capture global patterns to first order. The model provides a mechanistic upper estimate on global chemoautotrophic carbon fixation of 0.2–0.5 Pg C yr−1, which is on the low end of the wide range of previous estimates. Modeled carbon fixation by AOA (0.2–0.3 Pg C yr−1) exceeds that of NOB (about 0.1 Pg C yr−1) because of the higher biomass yield of AOA. The simple expressions derived here can be used to quantify the biogeochemical impacts of additional metabolic pathways (i.e., mixotrophy) of nitrifying clades and to identify alternative metabolisms fueling carbon fixation in the deep ocean.

Published

2022

15. Microbial ecology of coral-dominated reefs in the Federated States of Micronesia

Author

Sean McNally, Alyson E. Santoro, Angela Richards Donà, Konrad A Hughen, Amy Apprill, Henry C. Holm, Laura Weber, Cynthia Becker, Thierry M. Work, Greta S. Aeby, and Matthew J. Neave

Subjects

0106 biological sciences, 0301 basic medicine, geography, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Coral, Coral reef, Aquatic Science, Biology, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Microbial ecology, Reef, Ecology, Evolution, Behavior and Systematics, Ssu rrna gene

Abstract

Microorganisms are central to the functioning of coral reef ecosystems, but their dynamics are unstudied on most reefs. We examined the microbial ecology of shallow reefs within the Federated States of Micronesia. We surveyed 20 reefs surrounding 7 islands and atolls (Yap, Woleai, Olimarao, Kosrae, Kapingamarangi, Nukuoro, and Pohnpei), spanning 875053 km2. On the reefs, we found consistently higher coral coverage (mean ± SD = 36.9 ± 22.2%; max 77%) compared to macroalgae coverage (15.2 ± 15.5%; max 58%), and low abundances of fish. Reef waters had low inorganic nutrient concentrations and were dominated by Synechococcus, Prochlorococcus, and SAR11 bacteria. The richness of bacterial and archaeal communities was significantly related to interactions between island/atoll and depth. High coral coverage on reefs was linked to higher relative abundances of Flavobacteriaceae, Leisingera, Owenweeksia, Vibrio, and the OM27 clade, as well as other heterotrophic bacterial groups, consistent with communities residing in waters near corals and within coral mucus. Microbial community structure at reef depth was significantly correlated with geographic distance, suggesting that island biogeography influences reef microbial communities. Reefs at Kosrae Island, which hosted the highest coral abundance and diversity, were unique compared to other locations; seawater from Kosrae reefs had the lowest organic carbon (59.8-67.9 µM), highest organic nitrogen (4.5-5.3 µM), and harbored consistent microbial communities (>85% similar), which were dominated by heterotrophic cells. This study suggests that the reef-water microbial ecology on Micronesian reefs is influenced by the density and diversity of corals as well as other biogeographical features.

Published

2021

16. Systematic comparison of unilamellar vesicles reveals that archaeal core lipid membranes are more permeable than bacterial membranes

Author

Urszula Łapińska, Georgina Glover, Zehra Kahveci, Nicholas A. T. Irwin, David S. Milner, Maxime Tourte, Sonja-Verena Albers, Alyson E. Santoro, Thomas A. Richards, and Stefano Pagliara

Subjects

General Immunology and Microbiology, General Neuroscience, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology

Abstract

One of the deepest branches in the tree of life separates the Archaea from the Bacteria. These prokaryotic groups have distinct cellular systems including fundamentally different phospholipid membrane bilayers. This dichotomy has been termed the lipid divide and possibly bestows different biophysical and biochemical characteristics on each cell type. Classic experiments suggest that bacterial membranes (formed from lipids extracted from Escherichia coli, for example) show permeability to key metabolites comparable to archaeal membranes (formed from lipids extracted from Halobacterium salinarum), yet systematic analyses based on direct measurements of membrane permeability are absent. Here, we develop a new approach for assessing the membrane permeability of approximately 10 μm unilamellar vesicles, consisting of an aqueous medium enclosed by a single lipid bilayer. Comparing the permeability of 18 metabolites demonstrates that diether glycerol-1-phosphate lipids with methyl branches, often the most abundant membrane lipids of sampled archaea, are permeable to a wide range of compounds useful for core metabolic networks, including amino acids, sugars, and nucleobases. Permeability is significantly lower in diester glycerol-3-phosphate lipids without methyl branches, the common building block of bacterial membranes. To identify the membrane characteristics that determine permeability, we use this experimental platform to test a variety of lipid forms bearing a diversity of intermediate characteristics. We found that increased membrane permeability is dependent on both the methyl branches on the lipid tails and the ether bond between the tails and the head group, both of which are present on the archaeal phospholipids. These permeability differences must have had profound effects on the cell physiology and proteome evolution of early prokaryotic forms. To explore this further, we compare the abundance and distribution of transmembrane transporter-encoding protein families present on genomes sampled from across the prokaryotic tree of life. These data demonstrate that archaea tend to have a reduced repertoire of transporter gene families, consistent with increased membrane permeation. These results demonstrate that the lipid divide demarcates a clear difference in permeability function with implications for understanding some of the earliest transitions in cell origins and evolution.

Published

2023

17. Nitrification and nitrous oxide dynamics in the Southern California Bight

Author

Jason M. Smith, Troy Gunderson, Douglas G. Capone, Michael Morando, Alyson E. Santoro, and Sarah M. Laperriere

Subjects

chemistry.chemical_compound, chemistry, Environmental chemistry, Environmental science, Nitrification, Nitrous oxide, Aquatic Science, Oceanography

Published

2020

18. Synechococcusnitrogen gene loss in iron-limited ocean regions

Author

Garrett Sharpe, Liang Zhao, Meredith G. Meyer, Weida Gong, Shannon M. Burns, Allesandro Tagliabue, Kristen N. Buck, Alyson E. Santoro, Jason R. Graff, Adrian Marchetti, and Scott Gifford

Abstract

Synechococcusare the most abundant cyanobacteria in high latitude regions and are responsible for an estimated 17% of annual marine primary productivity. Despite their biogeochemical importance,Synechococcuspopulations have been unevenly sampled across the ocean, with most studies focused on low-latitude strains. In particular, the near absence ofSynechococcusgenomes from high-latitude, High Nutrient Low Chlorophyll (HNLC) regions leaves a gap in our knowledge of picocyanobacterial adaptation to iron limitation and their influence on carbon, nitrogen, and iron cycles. We examinedSynechococcuspopulations from the subarctic North Pacific, a well-characterized HNLC region, with quantitative metagenomics. Assembly with short and long reads produced two near completeSynechococcusmetagenome-assembled genomes (MAGs). Quantitative metagenome-derived abundances of these populations matched well with flow cytometry counts, and theSynechococcusMAGs were estimated to comprise >99% of theSynechococcusat Station P. Whereas the Station PSynechococcusMAGs contained multiple genes for adaptation to iron limitation, both genomes lacked genes for uptake and assimilation of nitrate and nitrite, suggesting a dependence on ammonium, urea, and other forms of recycled nitrogen leading to reduced iron requirements. A global analysis ofSynechococcusnitrate reductase abundance in the TARA Oceans dataset found nitrate assimilation genes are also lower in other HNLC regions. We propose nitrate and nitrite assimilation gene loss inSynechococcusrepresents an adaptation to severe iron limitation in high-latitude regions where ammonium availability is higher. Our findings have implications for models that quantify the contribution of cyanobacteria to primary production and subsequent carbon export.SignificanceThe cyanobacteriumSynechococcusis a major contributor to ocean primary production and biogeochemistry. Here, we used quantitative metagenomics to assemble and enumerate twoSynechococcusgenomes from an iron-limited, High Nutrient Low Chlorophyll region. We show these genomes represent the majority ofSynechococcuscells at the site and are the first knownSynechococcusunable to assimilate either nitrate or nitrite. This gene loss is likely due to the high iron quota of these proteins and predominant availability of recycled forms of nitrogen.Synechococcus’loss of nitrate assimilation affects their role in elemental cycles (e.g., carbon, nitrogen, and iron), limits their potential for carbon export, and enhances our understanding ofSynechococcusevolution in response to nutrient limitation and competition.

Published

2022

19. Complete Genome Sequences of Two Phylogenetically Distinct Nitrospina Strains Isolated from the Atlantic and Pacific Oceans

Author

Barbara Bayer, Matthew Kellom, Frederica Valois, John B. Waterbury, Alyson E. Santoro, and Stewart, Frank J

Subjects

Immunology and Microbiology (miscellaneous), Human Genome, Genetics, Molecular Biology

Abstract

The complete genome sequences of two chemoautotrophic nitrite-oxidizing bacteria of the genus Nitrospina are reported. Nitrospina gracilis strain Nb-211 was isolated from the Atlantic Ocean, and Nitrospina sp. strain Nb-3 was isolated from the Pacific Ocean. We report two highly similar ~3.07-Mbp genome sequences that differ by the presence of ferric iron chelator (siderophore) biosynthesis genes.

Published

2022

20. Roadmap Towards Communitywide Intercalibration and Standardization of Ocean Nucleic Acids ‘Omics Measurements

Author

Paul M. Berube, Scott M. Gifford, Bonnie Hurwitz, Bethany Jenkins, Adrian Marchetti, and Alyson E. Santoro

Abstract

In January 2020, the US Ocean Carbon & Biogeochemistry (OCB) Project Office funded the Ocean Nucleic Acids 'omics Intercalibration and Standardization workshop held at the University of North Carolina in Chapel Hill. Thirty-two participants from across the US, along with guests from Canada and France, met to develop a framework for standardization and intercalibration (S&I) of ocean nucleic acid ‘omics (na’omics) approaches (i.e., amplicon sequencing, metagenomics and metatranscriptomics). During the three-day workshop, participants discussed numerous topics, including: a) sample biomass collection and nucleic acid preservation for downstream analysis, b) extraction protocols for nucleic acids, c) addition of standard reference material to nucleic acid isolation protocols, d) isolation methods unique to RNA, e) sequence library construction, and f ) integration of bioinformatic considerations. This report provides a summary of these and other topics covered during the workshop and a series of recommendations for future S&I activities for na’omics approaches.

Published

2022

21. Single-Cell Transcriptomics of Abedinium Reveals a New Early-Branching Dinoflagellate Lineage

Author

Elizabeth C. Cooney, Anna Cho, Alyson E. Santoro, Patrick J. Keeling, Thomas A. Richards, Noriko Okamoto, Alexandra Z. Worden, Brian S. Leander, and Elisabeth Hehenberger

Subjects

0303 health sciences, Mitochondrial DNA, biology, Lineage (evolution), Genome, Plastid, Dinoflagellate, Ribosomal RNA, biology.organism_classification, Transcriptome, 03 medical and health sciences, 0302 clinical medicine, Noctilucales, RNA editing, Evolutionary biology, Dinoflagellida, Genetics, Single-Cell Analysis, Plastid, Phylogeny, 030217 neurology & neurosurgery, Ecology, Evolution, Behavior and Systematics, Research Article, 030304 developmental biology

Abstract

Dinoflagellates possess many cellular characteristics with unresolved evolutionary histories. These include nuclei with greatly expanded genomes and chromatin packaged using histone-like proteins and dinoflagellate-viral nucleoproteins instead of histones, highly reduced mitochondrial genomes with extensive RNA editing, a mix of photosynthetic and cryptic secondary plastids, and tertiary plastids. Resolving the evolutionary origin of these traits requires understanding their ancestral states and early intermediates. Several early-branching dinoflagellate lineages are good candidates for such reconstruction, however these cells tend to be delicate and environmentally sparse, complicating such analyses. Here, we employ transcriptome sequencing from manually isolated and microscopically documented cells to resolve the placement of two cells of one such genus, Abedinium, collected by remotely operated vehicle in deep waters off the coast of Monterey Bay, CA. One cell corresponds to the only described species, Abedinium dasypus, whereas the second cell is distinct and formally described as Abedinium folium, sp. nov. Abedinium has classically been assigned to the early-branching dinoflagellate subgroup Noctilucales, which is weakly supported by phylogenetic analyses of small subunit ribosomal RNA, the single characterized gene from any member of the order. However, an analysis based on 221 proteins from the transcriptome places Abedinium as a distinct lineage, separate from and basal to Noctilucales and the rest of the core dinoflagellates. The transcriptome also contains evidence of a cryptic plastid functioning in the biosynthesis of isoprenoids, iron–sulfur clusters, and heme, a mitochondrial genome with all three expected protein-coding genes (cob, cox1, and cox3), and the presence of some but not all dinoflagellate-specific chromatin packaging proteins.

Published

2020

22. Diversity, ecology and evolution of Archaea

Author

Valerie De Anda, Kiley W. Seitz, Alyson E. Santoro, Karen G. Lloyd, Nina Dombrowski, and Brett J. Baker

Subjects

Microbiology (medical), 0303 health sciences, biology, 030306 microbiology, Phylum, Ecology (disciplines), Tree of life (biology), Immunology, Cell Biology, biology.organism_classification, Applied Microbiology and Biotechnology, Microbiology, Genome, 03 medical and health sciences, Microbial ecology, Phylogenetics, Evolutionary biology, Genetics, Evolutionary ecology, 030304 developmental biology, Archaea

Abstract

Compared to bacteria, our knowledge of archaeal biology is limited. Historically, microbiologists have mostly relied on culturing and single-gene diversity surveys to understand Archaea in nature. However, only six of the 27 currently proposed archaeal phyla have cultured representatives. Advances in genomic sequencing and computational approaches are revolutionizing our understanding of Archaea. The recovery of genomes belonging to uncultured groups from the environment has resulted in the description of several new phyla, many of which are globally distributed and are among the predominant organisms on the planet. In this Review, we discuss how these genomes, together with long-term enrichment studies and elegant in situ measurements, are providing insights into the metabolic capabilities of the Archaea. We also debate how such studies reveal how important Archaea are in mediating an array of ecological processes, including global carbon and nutrient cycles, and how this increase in archaeal diversity has expanded our view of the tree of life and early archaeal evolution, and has provided new insights into the origin of eukaryotes.

Published

2020

23. Abundant nitrite-oxidizing metalloenzymes in the mesopelagic zone of the tropical Pacific Ocean

Author

Alyson E. Santoro, Mak A. Saito, Frederica W. Valois, Dawn M. Moran, Christopher L. Dupont, Marian Westley, Jaclyn K. Saunders, Patrick A. Rafter, Matthew R. McIlvin, Carl H. Lamborg, Drishti Kaul, and John B. Waterbury

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, Biogeochemical cycle, chemistry, Nitrite oxidoreductase, Abundance (ecology), Mesopelagic zone, Environmental chemistry, General Earth and Planetary Sciences, Organic matter, Pelagic zone, Nitrite, Oxygen minimum zone

Abstract

Numerous biogeochemical reactions occur within the oceans’ major oxygen minimum zones, but less attention has been paid to the open ocean extremities of these zones. Here we report measurements on oxygen minimum zone waters from the Eastern to the Central Tropical North Pacific, which we analysed using metaproteomic techniques to discern the microbial functions present and their influence on biogeochemical cycling. We found nitrite oxidoreductase—an iron-rich enzyme from Nitrospina bacteria—to be one of the most abundant microbial proteins present in the mesopelagic zone, with over 60 billion molecules per litre. Estimated reaction rates imply that this enzyme is undersaturated and that its high abundance provides a latent mesopelagic catalytic capacity to rapidly oxidize nitrite derived from episodic fluxes of degrading sinking organic matter. In addition, given the enzyme’s intensive iron demand, its high abundance represents a previously unrecognized microbial reservoir within suboxic mesopelagic zones. Nitrite oxidoreductase may also contribute to other reactions involving nitrogen and redox-sensitive metals. We suggest that the abundance and extent of nitrite oxidoreductase may increase with continued deoxygenation in the oceans, and result in increased mesopelagic demand for iron and other potential changes to marine biogeochemical cycles. Continued deoxygenation of the oceans will probably lead to enhanced demand for iron, as implied by the abundance of an iron-rich enzyme in the mesopelagic waters of the Pacific.

Published

2020

24. Controlled sampling of ribosomally active protistan diversity in sediment-surface layers identifies putative players in the marine carbon sink

Author

Raquel Rodríguez-Martínez, Frédéric Mahé, Karen Moore, Guy Leonard, Sebastian Sudek, Mike Conway, David S. Milner, Theresa Hudson, Patrick J. Keeling, Thomas A. Richards, Alyson E. Santoro, and Alexandra Z. Worden

Subjects

Water microbiology, Geologic Sediments, sédiment, Analyse qualitative, Biodiversity, Microbial ecology, Phylogeny, Bacillariophyceae, 0303 health sciences, biology, Population composite, Ecology, Microbiota, Community structure, Labyrinthulomycetes, Biodiversité, Stramenopiles, Carbon Sequestration, Microbiology, Article, Carbon cycle, Caractéristique du peuplement, 03 medical and health sciences, Algae, Arn ribosomal, Seawater, 14. Life underwater, Ciliophora, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Écologie marine, 030306 microbiology, fungi, Sediment, 15. Life on land, Ribosomal RNA, biology.organism_classification, Diatom, M40 - Écologie aquatique, Écologie microbienne

Abstract

Marine sediments are one of the largest carbon reservoir on Earth, yet the microbial communities, especially the eukaryotes, that drive these ecosystems are poorly characterised. Here, we report implementation of a sampling system that enables injection of reagents into sediments at depth, allowing for preservation of RNA in situ. Using the RNA templates recovered, we investigate the ‘ribosomally active’ eukaryotic diversity present in sediments close to the water/sediment interface. We demonstrate that in situ preservation leads to recovery of a significantly altered community profile. Using SSU rRNA amplicon sequencing, we investigated the community structure in these environments, demonstrating a wide diversity and high relative abundance of stramenopiles and alveolates, specifically: Bacillariophyta (diatoms), labyrinthulomycetes and ciliates. The identification of abundant diatom rRNA molecules is consistent with microscopy-based studies, but demonstrates that these algae can also be exported to the sediment as active cells as opposed to dead forms. We also observe many groups that include, or branch close to, osmotrophic–saprotrophic protists (e.g. labyrinthulomycetes and Pseudofungi), microbes likely to be important for detrital decomposition. The sequence data also included a diversity of abundant amplicon-types that branch close to the Fonticula slime moulds. Taken together, our data identifies additional roles for eukaryotic microbes in the marine carbon cycle; where putative osmotrophic–saprotrophic protists represent a significant active microbial-constituent of the upper sediment layer.

Published

2020

25. Carbon content, carbon fixation yield and dissolved organic carbon release from diverse marine nitrifiers

Author

Barbara Bayer, Kelsey McBeain, Craig A. Carlson, and Alyson E. Santoro

Subjects

Aquatic Science, Oceanography

Abstract

Nitrifying microorganisms, including ammonia-oxidizing archaea, ammonia-oxidizing bacteria and nitrite-oxidizing bacteria, are the most abundant chemoautotrophs in the ocean and play an important role in the global carbon cycle by fixing dissolved inorganic carbon (DIC) into biomass. The release of organic compounds by these microbes is less well known but may represent an as-yet unaccounted source of dissolved organic carbon (DOC) available to heterotrophic marine food webs. Here, we provide measurements of cellular carbon and nitrogen quotas, DIC fixation yields and DOC release of ten phylogenetically diverse marine nitrifiers grown in multiple culture conditions. All investigated strains released DOC during growth, making up on average 5-15% of the fixed DIC. Neither substrate concentration nor temperature affected the proportion of fixed DIC released as DOC, but release rates varied between closely related species. Our results also indicate previous studies may have underestimated DIC fixation yields of marine nitrite oxidizers due to partial decoupling of nitrite oxidation from CO2 fixation, and due to lower observed yields in artificial compared to natural seawater medium. The results of this study provide values for biogeochemical models of the global carbon cycle, and help to further constrain the implications of nitrification-fueled chemoautotrophy for marine food-web functioning and the biological sequestration of carbon in the ocean.

Published

2022

26. Phytoplankton size-class contributions to new and regenerated production during the EXPORTS Northeast Pacific Ocean field deployment

Author

Meredith G. Meyer, Weida Gong, Sile M. Kafrissen, Olivia Torano, Diana E. Varela, Alyson E. Santoro, Nicolas Cassar, Scott Gifford, Alexandria K. Niebergall, Garrett Sharpe, and Adrian Marchetti

Subjects

Atmospheric Science, Environmental Engineering, Ecology, Geology, Geotechnical Engineering and Engineering Geology, Oceanography

Abstract

The NASA EXport Processes in the Ocean from RemoTe Sensing (EXPORTS) program was established to better quantify the pathways of the biological carbon pump in order to gain a more comprehensive understanding of global carbon export efficiency. The summer 2018 field campaign in the vicinity of Ocean Station Papa (Station P; 50°N, 145°W) in the Northeast Pacific Ocean yielded evidence of low phytoplankton biomass and primary productivity dominated by small cells (

Published

2022

27. Microbial signatures of protected and impacted Northern Caribbean reefs: changes from Cuba to the Florida Keys

Author

Fernando Bretos, Amy Apprill, Víctor M. Ferrer, Laura Weber, Erich Bartels, Alyson E. Santoro, Maickel Armenteros, and Patricia González-Díaz

Subjects

Context (language use), Microbiology, 03 medical and health sciences, Microbial ecology, Animals, Humans, Seawater, 14. Life underwater, Reef, Research Articles, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, geography, geography.geographical_feature_category, Bacteria, biology, Coral Reefs, 030306 microbiology, Ecology, Microbiota, fungi, technology, industry, and agriculture, Cuba, Biogeochemistry, Coral reef, biochemical phenomena, metabolism, and nutrition, 15. Life on land, Anthozoa, biology.organism_classification, Archaea, Caribbean Region, Microbial population biology, 13. Climate action, Florida, population characteristics, Prochlorococcus, geographic locations, Research Article

Abstract

Summary There are a few baseline reef‐systems available for understanding the microbiology of healthy coral reefs and their surrounding seawater. Here, we examined the seawater microbial ecology of 25 Northern Caribbean reefs varying in human impact and protection in Cuba and the Florida Keys, USA, by measuring nutrient concentrations, microbial abundances, and respiration rates as well as sequencing bacterial and archaeal amplicons and community functional genes. Overall, seawater microbial composition and biogeochemistry were influenced by reef location and hydrogeography. Seawater from the highly protected ‘crown jewel’ offshore reefs in Jardines de la Reina, Cuba had low concentrations of nutrients and organic carbon, abundant Prochlorococcus, and high microbial community alpha diversity. Seawater from the less protected system of Los Canarreos, Cuba had elevated microbial community beta‐diversity whereas waters from the most impacted nearshore reefs in the Florida Keys contained high organic carbon and nitrogen concentrations and potential microbial functions characteristic of microbialized reefs. Each reef system had distinct microbial signatures and within this context, we propose that the protection and offshore nature of Jardines de la Reina may preserve the oligotrophic paradigm and the metabolic dependence of the community on primary production by picocyanobacteria.

Published

2019

28. Membrane permeability differentiation at the lipid divide

Author

Urszula Łapińska, Georgina Glover, Zehra Kahveci, Nicholas A. T. Irwin, David S. Milner, Maxime Tourte, Sonja-Verena Albers, Alyson E. Santoro, Thomas A. Richards, and Stefano Pagliara

Subjects

Protocell, chemistry.chemical_compound, Membrane, Membrane permeability, biology, Chemistry, Permeability (electromagnetism), Vesicle, Biophysics, Phospholipid, Lipid bilayer, biology.organism_classification, Archaea

Abstract

One of the deepest branches in the tree of life separates the Archaea from the Bacteria. These prokaryotic groups have distinct cellular systems including fundamentally different phospholipid membrane bilayers. This dichotomy has been termed the lipid divide and possibly bestows different biophysical and biochemical characteristics on each cell type. Classic experiments suggest that bacterial membranes (formed from lipids extracted fromEscherichia colifor example) show permeability to key metabolites comparable to archaeal membranes (formed from lipids extracted fromHalobacterium salinarum), yet systematic analyses based on direct measurements of membrane permeability are absent. Here we develop a new approach for assessing the membrane permeability of ~10 μm unilamellar vesicles, consisting of an aqueous medium enclosed by a single lipid bilayer. Comparing the permeability of eighteen metabolites demonstrates that diether glycerol-1-phosphate lipids with methyl branches, often the most abundant membrane lipids of known archaea, are permeable to a wide range of compounds useful for core metabolic networks, including amino acids, sugars, and nucleobases. Permeability is significantly lower in diester glycerol-3-phosphate lipids without methyl branches, the common building block of bacterial membranes. To identify the membrane characteristics that determine permeability we use this experimental platform to test a variety of lipid forms bearing a diversity of intermediate characteristics. We found that increased membrane permeability is dependent on both the methyl branches present on the archaeal phospholipid tails and the ether bond between the tails and the head group. These permeability differences must have had profound effects on the cell physiology and proteome evolution of early prokaryotic forms. To explore this further, we compare the abundance and distribution of transmembrane transporter-encoding protein families present on genomes sampled from across the prokaryotic tree of life. Archaea have a reduced repertoire of transporter gene families, consistent with increased membrane permeation. These results demonstrate that the lipid divide demarcates a clear difference in permeability function with implications for understanding some of the earliest transitions in cell evolution.

Published

2021

29. The microbiome of a bacterivorous marine choanoflagellate contains a resource-demanding obligate bacterial associate

Author

David M, Needham, Camille, Poirier, Charles, Bachy, Emma E, George, Susanne, Wilken, Charmaine C M, Yung, Alexander J, Limardo, Michael, Morando, Lisa, Sudek, Rex R, Malmstrom, Patrick J, Keeling, Alyson E, Santoro, and Alexandra Z, Worden

Subjects

Type IV Secretion Systems, Pacific Ocean, Bacteria, Microbiota, Animals, Humans, Choanoflagellata

Abstract

Microbial predators such as choanoflagellates are key players in ocean food webs. Choanoflagellates, which are the closest unicellular relatives of animals, consume bacteria and also exhibit marked biological transitions triggered by bacterial compounds, yet their native microbiomes remain uncharacterized. Here we report the discovery of a ubiquitous, uncultured bacterial lineage we name Candidatus Comchoanobacterales ord. nov., related to the human pathogen Coxiella and physically associated with the uncultured marine choanoflagellate Bicosta minor. We analyse complete 'Comchoano' genomes acquired after sorting single Bicosta cells, finding signatures of obligate host-dependence, including reduction of pathways encoding glycolysis, membrane components, amino acids and B-vitamins. Comchoano encode the necessary apparatus to import energy and other compounds from the host, proteins for host-cell associations and a type IV secretion system closest to Coxiella's that is expressed in Pacific Ocean metatranscriptomes. Interactions between choanoflagellates and their microbiota could reshape the direction of energy and resource flow attributed to microbial predators, adding complexity and nuance to marine food webs.

Published

2021

30. An operational overview of the EXport Processes in the Ocean from RemoTe Sensing (EXPORTS) Northeast Pacific field deployment

Author

Yannick Huot, Bethany D. Jenkins, Tatiana A. Rynearson, Andrea J. Fassbender, Colleen A. Durkin, Jason R. Graff, Jong-Mi Lee, Brandon M. Stephens, Deborah K. Steinberg, Phoebe J. Lam, Salvatore Caprara, Ken O. Buesseler, Zachary K. Erickson, Heather McNair, Deric Gray, Inia Soto Ramos, Roberta C. Hamme, Adrian B. Burd, Marie Robert, David A. Siegel, Weida Gong, Kanesa Duncan Seraphin, Kristen N. Buck, Uta Passow, Montserrat Roca-Martí, Melissa M. Omand, Susanne Menden-Deuer, Dennis A. Hansell, Andrew M. P. McDonnell, Xiaodong Zhang, Philip W. Boyd, Lee Karp-Boss, Scott M. Gifford, Adrian Marchetti, Hilary G. Close, Michael J. Behrenfeld, Craig A. Carlson, Margaret L. Estapa, Kelsey Bisson, Yuanheng Xiong, Eric A. D'Asaro, Kim Halsey, Mark A. Brzezinski, Norman B. Nelson, David P. Nicholson, Heidi M. Sosik, Shawnee Traylor, Ivona Cetinić, Alyson E. Santoro, Olivier Marchal, Sasha J. Kramer, Erik Fields, Nicolas Cassar, James Fox, Laure Resplandy, Claudia R. Benitez-Nelson, Vinicius Amaral, Weiyi Tang, Alexandria K. Niebergall, Françoise Morison, Scott A. Freeman, Geneviève Potvin, Shannon Burns, Benjamin A. S. Van Mooy, Karen Stamieszkin, Craig M. Lee, Andrew F. Thompson, Brian N. Popp, Mary Jane Perry, Nils Haëntjens, Amy E. Maas, Lionel Guidi, Emmanuel Boss, Collin S. Roesler, Oregon State University, Corvallis, USA, Laboratoire d'océanographie de Villefranche (LOV), Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de la Mer de Villefranche (IMEV), and Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0106 biological sciences, Atmospheric Science, Environmental Engineering, 010504 meteorology & atmospheric sciences, Field (physics), Biological pump, NPP fates, Oceanography, 01 natural sciences, Carbon cycle, 14. Life underwater, Export pathways, 0105 earth and related environmental sciences, Remote sensing, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Ecology, 010604 marine biology & hydrobiology, Geology, Geotechnical Engineering and Engineering Geology, 13. Climate action, Software deployment, Remote sensing (archaeology), Organic carbon export, Environmental science, NASA field campaign

Abstract

International audience; The goal of the EXport Processes in the Ocean from RemoTe Sensing (EXPORTS) field campaign is to develop a predictive understanding of the export, fate, and carbon cycle impacts of global ocean net primary production. To accomplish this goal, observations of export flux pathways, plankton community composition, food web processes, and optical, physical, and biogeochemical (BGC) properties are needed over a range of ecosystem states. Here we introduce the first EXPORTS field deployment to Ocean Station Papa in the Northeast Pacific Ocean during summer of 2018, providing context for other papers in this special collection. The experiment was conducted with two ships: a Process Ship, focused on ecological rates, BGC fluxes, temporal changes in food web, and BGC and optical properties, that followed an instrumented Lagrangian float; and a Survey Ship that sampled BGC and optical properties in spatial patterns around the Process Ship. An array of autonomous underwater assets provided measurements over a range of spatial and temporal scales, and partnering programs and remote sensing observations provided additional observational context. The oceanographic setting was typical of late-summer conditions at Ocean Station Papa: a shallow mixed layer, strong vertical and weak horizontal gradients in hydrographic properties, sluggish sub-inertial currents, elevated macronutrient concentrations and low phytoplankton abundances. Although nutrient concentrations were consistent with previous observations, mixed layer chlorophyll was lower than typically observed, resulting in a deeper euphotic zone. Analyses of surface layer temperature and salinity found three distinct surface water types, allowing for diagnosis of whether observed changes were spatial or temporal. The 2018 EXPORTS field deployment is among the most comprehensive biological pump studies ever conducted. A second deployment to the North Atlantic Ocean occurred in spring 2021, which will be followed by focused work on data synthesis and modeling using the entire EXPORTS data set.

Published

2021

31. Unexpected mitochondrial genome diversity revealed by targeted single-cell genomics of heterotrophic flagellated protists

Author

Raquel Rodríguez-Martínez, Patrick J. Keeling, Finlay Maguire, Karen Moore, Nicholas A.T. Irwin, Camille Poirier, Jeremy G. Wideman, Alyson E. Santoro, Alexandra Z. Worden, David S. Milner, Guy Leonard, Emily Cook, Adam Monier, and Thomas A. Richards

Subjects

Microbiology (medical), Mitochondrial DNA, Nuclear gene, Immunology, Genomics, Biology, DNA, Mitochondrial, Applied Microbiology and Biotechnology, Microbiology, Genome, Evolution, Molecular, 03 medical and health sciences, Genetics, 14. Life underwater, Flagellate, Gene, Phylogeny, 030304 developmental biology, 0303 health sciences, Pacific Ocean, Phylogenetic tree, 030306 microbiology, Intron, Eukaryota, Genetic Variation, Heterotrophic Processes, Cell Biology, biology.organism_classification, Introns, Genes, Mitochondrial, Flagella, Evolutionary biology, Genome, Mitochondrial, Single-Cell Analysis, Stramenopiles

Abstract

Most eukaryotic microbial diversity is uncultivated, under-studied and lacks nuclear genome data. Mitochondrial genome sampling is more comprehensive, but many phylogenetically important groups remain unsampled. Here, using a single-cell sorting approach combining tubulin-specific labelling with photopigment exclusion, we sorted flagellated heterotrophic unicellular eukaryotes from Pacific Ocean samples. We recovered 206 single amplified genomes, predominantly from underrepresented branches on the tree of life. Seventy single amplified genomes contained unique mitochondrial contigs, including 21 complete or near-complete mitochondrial genomes from formerly under-sampled phylogenetic branches, including telonemids, katablepharids, cercozoans and marine stramenopiles, effectively doubling the number of available samples of heterotrophic flagellate mitochondrial genomes. Collectively, these data identify a dynamic history of mitochondrial genome evolution including intron gain and loss, extensive patterns of genetic code variation and complex patterns of gene loss. Surprisingly, we found that stramenopile mitochondrial content is highly plastic, resembling patterns of variation previously observed only in plants. Single-cell sequencing of flagellated heterotrophic unicellular eukaryotes provides insights into the dynamics of mitochondrial genome evolution.

Published

2019

32. A distinct lineage of giant viruses brings a rhodopsin photosystem to unicellular marine predators

Author

Chang Jae Choi, Keiichi Kojima, Nicholas A.T. Irwin, Alexandra Z. Worden, Edward F. DeLong, Sebastian Sudek, Patrick J. Keeling, Yuki Sudo, Elisabeth Hehenberger, Guy Leonard, Mikako Shirouzu, Charles Bachy, Susanne Wilken, Susumu Yoshizawa, Toshiaki Hosaka, Tomomi Kimura-Someya, Wataru Iwasaki, David M. Needham, Daniel K. Olson, Rex R. Malmstrom, Cheuk Man Yung, Daniel R. Mende, Yu Nakajima, Thomas A. Richards, Alyson E. Santoro, Rika Kurihara, Camille Poirier, and Freshwater and Marine Ecology (IBED, FNWI)

Subjects

Rhodopsin, marine carbon cycle, Oceans and Seas, Genome, Viral, Genome, Viral Proteins, viral evolution, 03 medical and health sciences, MD Multidisciplinary, Genetics, Phycodnaviridae, Seawater, Giant Virus, Mimiviridae, Viral, 14. Life underwater, Life Below Water, Gene, Ecosystem, Phylogeny, host-virus interactions, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, single-cell genomics, 030306 microbiology, Neurosciences, Eukaryota, Biological Sciences, biology.organism_classification, Biological Evolution, host–virus interactions, Infectious Diseases, PNAS Plus, Evolutionary biology, Metagenomics, Giant Viruses, Viral evolution, biology.protein, Protons, Infection, Environmental Sciences, Bacteria

Abstract

Significance Although viruses are well-characterized regulators of eukaryotic algae, little is known about those infecting unicellular predators in oceans. We report the largest marine virus genome yet discovered, found in a wild predatory choanoflagellate sorted away from other Pacific microbes and pursued using integration of cultivation-independent and laboratory methods. The giant virus encodes nearly 900 proteins, many unlike known proteins, others related to cellular metabolism and organic matter degradation, and 3 type-1 rhodopsins. The viral rhodopsin that is most abundant in ocean metagenomes, and also present in an algal virus, pumps protons when illuminated, akin to cellular rhodopsins that generate a proton-motive force. Giant viruses likely provision multiple host species with photoheterotrophic capacities, including predatory unicellular relatives of animals., Giant viruses are remarkable for their large genomes, often rivaling those of small bacteria, and for having genes thought exclusive to cellular life. Most isolated to date infect nonmarine protists, leaving their strategies and prevalence in marine environments largely unknown. Using eukaryotic single-cell metagenomics in the Pacific, we discovered a Mimiviridae lineage of giant viruses, which infects choanoflagellates, widespread protistan predators related to metazoans. The ChoanoVirus genomes are the largest yet from pelagic ecosystems, with 442 of 862 predicted proteins lacking known homologs. They are enriched in enzymes for modifying organic compounds, including degradation of chitin, an abundant polysaccharide in oceans, and they encode 3 divergent type-1 rhodopsins (VirR) with distinct evolutionary histories from those that capture sunlight in cellular organisms. One (VirRDTS) is similar to the only other putative rhodopsin from a virus (PgV) with a known host (a marine alga). Unlike the algal virus, ChoanoViruses encode the entire pigment biosynthesis pathway and cleavage enzyme for producing the required chromophore, retinal. We demonstrate that the rhodopsin shared by ChoanoViruses and PgV binds retinal and pumps protons. Moreover, our 1.65-Å resolved VirRDTS crystal structure and mutational analyses exposed differences from previously characterized type-1 rhodopsins, all of which come from cellular organisms. Multiple VirR types are present in metagenomes from across surface oceans, where they are correlated with and nearly as abundant as a canonical marker gene from Mimiviridae. Our findings indicate that light-dependent energy transfer systems are likely common components of giant viruses of photosynthetic and phagotrophic unicellular marine eukaryotes.

Published

2019

33. Metabolic versatility of the nitrite-oxidizing bacterium Nitrospira marina and its proteomic response to oxygen-limited conditions

Author

Dawn M. Moran, Christopher L. Dupont, Alyson E. Santoro, Sebastian Lücker, Matthew R. McIlvin, Mak A. Saito, Thomas S. Lankiewicz, and Barbara Bayer

Subjects

Proteomics, Technology, Hydrogenase, Oxidative phosphorylation, Formate dehydrogenase, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Autotroph, Nitrite, Ecology, Evolution, Behavior and Systematics, Ferredoxin, Nitrites, Ecosystem, 030304 developmental biology, 0303 health sciences, biology, Bacteria, 030306 microbiology, Chemistry, Biological Sciences, biology.organism_classification, Oxygen, Biochemistry, Ecological Microbiology, Proteome, Nitrospira, Oxidation-Reduction, Environmental Sciences

Abstract

The genus Nitrospira is the most widespread group of nitrite-oxidizing bacteria and thrives in diverse natural and engineered ecosystems. Nitrospira marina Nb-295T was isolated from the ocean over 30 years ago; however, its genome has not yet been analyzed. Here, we investigated the metabolic potential of N. marina based on its complete genome sequence and performed physiological experiments to test genome-derived hypotheses. Our data confirm that N. marina benefits from additions of undefined organic carbon substrates, has adaptations to resist oxidative, osmotic, and UV light-induced stress and low dissolved pCO2, and requires exogenous vitamin B12. In addition, N. marina is able to grow chemoorganotrophically on formate, and is thus not an obligate chemolithoautotroph. We further investigated the proteomic response of N. marina to low (∼5.6 µM) O2 concentrations. The abundance of a potentially more efficient CO2-fixing pyruvate:ferredoxin oxidoreductase (POR) complex and a high-affinity cbb3-type terminal oxidase increased under O2 limitation, suggesting a role in sustaining nitrite oxidation-driven autotrophy. This putatively more O2-sensitive POR complex might be protected from oxidative damage by Cu/Zn-binding superoxide dismutase, which also increased in abundance under low O2 conditions. Furthermore, the upregulation of proteins involved in alternative energy metabolisms, including Group 3b [NiFe] hydrogenase and formate dehydrogenase, indicate a high metabolic versatility to survive conditions unfavorable for aerobic nitrite oxidation. In summary, the genome and proteome of the first marine Nitrospira isolate identifies adaptations to life in the oxic ocean and provides insights into the metabolic diversity and niche differentiation of NOB in marine environments.

Published

2021

34. Marine and Terrestrial Nitrifying Bacteria are Sources of Diverse Bacteriohopanepolyols

Author

Jenan J. Kharbush, Roger E. Summons, Eva Spieck, Alyson E. Santoro, Felix J Elling, B. Bayer, Jordon D. Hemingway, V. Nathan, Thomas W. Evans, and Ann Pearson

Subjects

Biogeochemical cycle, biology, Nitrifying bacteria, Carbon fixation, Botany, Bacterioplankton, Geologic record, biology.organism_classification, Genome, Hopanoids, Bacteria

Abstract

Summary Hopanoid lipids and their derivatives, bacteriohopanepolyols, are membrane components of some bacteria that are commonly used as biomarkers for specific bacterial groups or biogeochemical processes in the geologic record ( Newman et al., 2016 ). However, the sources of hopanoids to marine and freshwater environments remain largely unconstrained. Recent marker gene studies suggest widespread capacity for hopanoid biosynthesis in marine bacterioplankton, including nitrifying (i.e., nitrite- or ammonia-oxidizing) bacteria ( Kharbush et al., 2018 ). To explore their hopanoid biosynthetic capacities, we studied the distribution of hopanoid biosynthetic genes in the genomes of cultivated and uncultivated ammonia-oxidizing (AOB) nitrite-oxidizing (NOB) bacteria. We found that hopanoid biosynthesis is common among seven of the nine presently cultivated clades of AOB and NOB. Hopanoid biosynthesis pathways are also conserved among the diverse lineages of AOB and NOB detected in environmental metagenomes. Distinct carbon isotopic signatures of biomass, hopanoids, and fatty acids suggest operation of distinct carbon fixation pathways among nitrifying bacteria. Accordingly, nitrifying bacterial contributions to the geologic record of hopanoids could be estimated by their carbon isotopic compositions. The ubiquity of nitrifying bacteria in the ocean today and the antiquity of this metabolic process suggest the potential for significant contributions to the geologic record of hopanoids.

Published

2021

35. Metabolic versatility of the nitrite-oxidizing bacterium Nitrospira marina and its proteomic response to oxygen-limited conditions

Author

Barbara, Bayer, Mak A, Saito, Matthew R, McIlvin, Sebastian, Lücker, Dawn M, Moran, Thomas S, Lankiewicz, Christopher L, Dupont, and Alyson E, Santoro

Subjects

Oxygen, Proteomics, Bacteria, Oxidation-Reduction, Ecosystem, Nitrites

Abstract

The genus Nitrospira is the most widespread group of nitrite-oxidizing bacteria and thrives in diverse natural and engineered ecosystems. Nitrospira marina Nb-295

Published

2020

36. mSystems

Author

Frank O. Aylward, Alyson E. Santoro, Biological Sciences, and Bouskill, Nick

Subjects

ALCOHOL-DEHYDROGENASE, Thaumarchaeota, Physiology, lcsh:QR1-502, DIVERSITY, Biochemistry, Genome, lcsh:Microbiology, CRYSTAL-STRUCTURE, TREE, 0303 health sciences, biology, Carbon fixation, QUINOPROTEIN GLUCOSE-DEHYDROGENASE, QR1-502, Computer Science Applications, INSIGHTS, ESCHERICHIA-COLI, Modeling and Simulation, rubisco, Life Sciences & Biomedicine, Research Article, DATABASE, Ecological and Evolutionary Science, Microbiology, 03 medical and health sciences, tack, Genetics, ARCHAEA, Molecular Biology, Quinoprotein glucose dehydrogenase, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, thaumarchaeota, 030306 microbiology, Phylum, fungi, Human Genome, RuBisCO, TACK, biology.organism_classification, EVOLUTION, pqq-dehydrogenase, Evolutionary biology, Metagenomics, biology.protein, marine archaea, PQQ-dehydrogenase, Archaea

Abstract

It has been known for many years that marine Thaumarchaeota are abundant constituents of dark ocean microbial communities, where their ability to couple ammonia oxidation and carbon fixation plays a critical role in nutrient dynamics. In this study, we describe an abundant group of putatively heterotrophic marine Thaumarchaeota (HMT) in the ocean with physiology distinct from those of their ammonia-oxidizing relatives. HMT lack the ability to oxidize ammonia and fix carbon via the 3-hydroxypropionate/4-hydroxybutyrate pathway but instead encode a form III-a RuBisCO and diverse PQQ-dependent dehydrogenases that are likely used to conserve energy in the dark ocean. Our work expands the scope of known diversity of Thaumarchaeota in the ocean and provides important insight into a widespread marine lineage., The Thaumarchaeota is a diverse archaeal phylum comprising numerous lineages that play key roles in global biogeochemical cycling, particularly in the ocean. To date, all genomically characterized marine thaumarchaea are reported to be chemolithoautotrophic ammonia oxidizers. In this study, we report a group of putatively heterotrophic marine thaumarchaea (HMT) with small genome sizes that is globally abundant in the mesopelagic, apparently lacking the ability to oxidize ammonia. We assembled five HMT genomes from metagenomic data and show that they form a deeply branching sister lineage to the ammonia-oxidizing archaea (AOA). We identify this group in metagenomes from mesopelagic waters in all major ocean basins, with abundances reaching up to 6% of that of AOA. Surprisingly, we predict the HMT have small genomes of ∼1 Mbp, and our ancestral state reconstruction indicates this lineage has undergone substantial genome reduction compared to other related archaea. The genomic repertoire of HMT indicates a versatile metabolism for aerobic chemoorganoheterotrophy that includes a divergent form III-a RuBisCO, a 2M respiratory complex I that has been hypothesized to increase energetic efficiency, and a three-subunit heme-copper oxidase complex IV that is absent from AOA. We also identify 21 pyrroloquinoline quinone (PQQ)-dependent dehydrogenases that are predicted to supply reducing equivalents to the electron transport chain and are among the most highly expressed HMT genes, suggesting these enzymes play an important role in the physiology of this group. Our results suggest that heterotrophic members of the Thaumarchaeota are widespread in the ocean and potentially play key roles in global chemical transformations. IMPORTANCE It has been known for many years that marine Thaumarchaeota are abundant constituents of dark ocean microbial communities, where their ability to couple ammonia oxidation and carbon fixation plays a critical role in nutrient dynamics. In this study, we describe an abundant group of putatively heterotrophic marine Thaumarchaeota (HMT) in the ocean with physiology distinct from those of their ammonia-oxidizing relatives. HMT lack the ability to oxidize ammonia and fix carbon via the 3-hydroxypropionate/4-hydroxybutyrate pathway but instead encode a form III-a RuBisCO and diverse PQQ-dependent dehydrogenases that are likely used to conserve energy in the dark ocean. Our work expands the scope of known diversity of Thaumarchaeota in the ocean and provides important insight into a widespread marine lineage.

Published

2020

37. Nitrification and nitrous oxide production in the offshore waters of the Eastern Tropical South Pacific

Author

Alyson E. Santoro, Karen L. Casciotti, Carolyn Buchwald, William M. Berelson, Douglas G. Capone, and Angela N. Knapp

Subjects

0106 biological sciences, Atmospheric Science, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Oxygen deficient, 010604 marine biology & hydrobiology, Biogeochemistry, Nitrous oxide, 01 natural sciences, chemistry.chemical_compound, Ammonia, chemistry, Nitrate, Nitrite oxidation, Environmental chemistry, Environmental Chemistry, Nitrification, Nitrogen cycle, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Marine oxygen deficient zones (ODZs) are dynamic areas of microbial nitrogen cycling. Nitrification, the microbial oxidation of ammonia to nitrate, plays multiple roles in the biogeochemistry of th...

Published

2020

38. The Fire and Tree Mortality Database, for empirical modeling of individual tree mortality after fire

Author

James B. Cronan, Tara L. Keyser, Jens T. Stevens, Joseph C. Restaino, Barbara J. Bentz, Sharon M. Hood, Crystal A. Kolden, Virginia L. McDaniel, John Paul Roccaforte, Kevin C. Ryan, Joseph J. O'Brien, Jonathan D. Bakker, Douglas J. Westlind, Karen E. Kopper, Robert A. Andrus, Carolyn Hull Sieg, María J. Lombardero, Peter Z. Fulé, Charles W. McHugh, Jim L. Hanula, Micah Charles Wright, Jason Kreitler, Michael T. Stoddard, Ryan S. Davis, R. Gregory Corace, Douglas S. Cram, Sheri L. Smith, Nicole M. Vaillant, Nathan L. Stephenson, Joel D. McMillin, Rebecca J. Smith, Tom W. Coleman, Adrian J. Das, Andrew M. Latimer, Thomas Kolb, Mary Stuever, J. Kevin Hiers, Lisa M. Ganio, Shelby A. Weiss, W. Wallace Covington, Carolyn R. Breece, Jason J. Moghaddas, Travis Woolley, Brendan M. Rogers, David W. Peterson, Charles B. Halpern, Darci M. Dickinson, Kenneth F. Raffa, Daniel R. Cluck, Elizabeth D. Reinhardt, Hugh D. Safford, J. Morgan Varner, Brian J. Harvey, Joseph E. Crouse, Susan J. Prichard, Mary Beth Keifer, Matthew P. Ayres, Alyson E. Santoro, Phillip J. van Mantgem, Daniel D. B. Perrakis, Lindsay M. Grayson, Timothy M. Shearman, Bruce D. Ayres, Michael Battaglia, Andrew P. Lerch, Michelle C. Agne, David W. Huffman, Jesse K. Kreye, Robert A. Progar, James K. Brown, Stephen Arthur Fitzgerald, Alice M. Shumate, C. Alina Cansler, Leda N. Kobziar, and Walter G. Thies

Subjects

0106 biological sciences, Statistics and Probability, Data Descriptor, 010504 meteorology & atmospheric sciences, Range (biology), Woodland, Forests, Library and Information Sciences, computer.software_genre, 010603 evolutionary biology, 01 natural sciences, Fires, Trees, Education, lcsh:Science, Ecological modelling, 0105 earth and related environmental sciences, Database, Fire ecology, Forestry, United States, Computer Science Applications, Tree (data structure), Good Health and Well Being, Geography, Databases as Topic, lcsh:Q, Statistics, Probability and Uncertainty, computer, Information Systems

Abstract

Wildland fires have a multitude of ecological effects in forests, woodlands, and savannas across the globe. A major focus of past research has been on tree mortality from fire, as trees provide a vast range of biological services. We assembled a database of individual-tree records from prescribed fires and wildfires in the United States. The Fire and Tree Mortality (FTM) database includes records from 164,293 individual trees with records of fire injury (crown scorch, bole char, etc.), tree diameter, and either mortality or top-kill up to ten years post-fire. Data span 142 species and 62 genera, from 409 fires occurring from 1981-2016. Additional variables such as insect attack are included when available. The FTM database can be used to evaluate individual fire-caused mortality models for pre-fire planning and post-fire decision support, to develop improved models, and to explore general patterns of individual fire-induced tree death. The database can also be used to identify knowledge gaps that could be addressed in future research., Measurement(s)plant morphology trait • tree mortality • fire • tree fire injury • wildfireTechnology Type(s)digital curationFactor Type(s)year of data collection • geographic location of fire • tree fire injurySample Characteristic - OrganismtreesSample Characteristic - Environmentforest ecosystemSample Characteristic - LocationCascades Region • Blue Mountains • Far Northern Rockies • Sierra Nevada • Piedmont Province • Region of Piedmont • Atlantic and Gulf Coastal Plain Floristic Province • Northern Rocky Mountains Provincial Park Machine-accessible metadata file describing the reported data: 10.6084/m9.figshare.12369293

Published

2020

39. Global reconstruction reduces the uncertainty of oceanic nitrous oxide emissions and reveals a vigorous seasonal cycle

Author

Samuel T. Wilson, Daniele Bianchi, Thomas Weber, Rolf E. Sonnerup, John L. Bullister, Mark J. Warner, Bonnie X. Chang, Alyson E. Santoro, Annette Kock, Simon Yang, and Annie Bourbonnais

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, Flux, Stratification (water), Climate change, Seasonality, 010502 geochemistry & geophysics, Spatial distribution, Atmospheric sciences, medicine.disease, 01 natural sciences, Atmosphere, 13. Climate action, Greenhouse gas, Physical Sciences, medicine, Environmental science, Upwelling, 14. Life underwater, 0105 earth and related environmental sciences

Abstract

Assessment of the global budget of the greenhouse gas nitrous oxide ( N 2 O) is limited by poor knowledge of the oceanic N 2 O flux to the atmosphere, of which the magnitude, spatial distribution, and temporal variability remain highly uncertain. Here, we reconstruct climatological N 2 O emissions from the ocean by training a supervised learning algorithm with over 158,000 N 2 O measurements from the surface ocean—the largest synthesis to date. The reconstruction captures observed latitudinal gradients and coastal hot spots of N 2 O flux and reveals a vigorous global seasonal cycle. We estimate an annual mean N 2 O flux of 4.2 ± 1.0 Tg N ⋅ y − 1 , 64% of which occurs in the tropics, and 20% in coastal upwelling systems that occupy less than 3% of the ocean area. This N 2 O flux ranges from a low of 3.3 ± 1.3 Tg N ⋅ y − 1 in the boreal spring to a high of 5.5 ± 2.0 Tg N ⋅ y − 1 in the boreal summer. Much of the seasonal variations in global N 2 O emissions can be traced to seasonal upwelling in the tropical ocean and winter mixing in the Southern Ocean. The dominant contribution to seasonality by productive, low-oxygen tropical upwelling systems (>75%) suggests a sensitivity of the global N 2 O flux to El Niño–Southern Oscillation and anthropogenic stratification of the low latitude ocean. This ocean flux estimate is consistent with the range adopted by the Intergovernmental Panel on Climate Change, but reduces its uncertainty by more than fivefold, enabling more precise determination of other terms in the atmospheric N 2 O budget.

Published

2020

40. Heterotrophic Thaumarchaeota with ultrasmall genomes are widespread in the ocean

Author

Frank O. Aylward and Alyson E. Santoro

Subjects

0303 health sciences, Thaumarchaeota, biology, 030306 microbiology, Phylum, Lineage (evolution), biology.organism_classification, Deep sea, Genome, 03 medical and health sciences, 13. Climate action, Evolutionary biology, Metagenomics, 14. Life underwater, Genome size, 030304 developmental biology, Archaea

Abstract

The Thaumarchaeota comprise a diverse archaeal phylum including numerous lineages that play key roles in global biogeochemical cycling, particularly in the ocean. To date, all genomically-characterized marine Thaumarchaeota are reported to be chemolithoautotrophic ammonia-oxidizers. In this study, we report a group of heterotrophic marine Thaumarchaeota (HMT) with ultrasmall genome sizes that is globally abundant in deep ocean waters, apparently lacking the ability to oxidize ammonia. We assemble five HMT genomes from metagenomic data derived from both the Atlantic and Pacific Oceans, including two that are >95% complete, and show that they form a deeply-branching lineage sister to the ammonia-oxidizing archaea (AOA). Metagenomic read mapping demonstrates the presence of this group in mesopelagic samples from all major ocean basins, with abundances reaching up to 6% that of AOA. Surprisingly, the predicted sizes of complete HMT genomes are only 837-908 Kbp, and our ancestral state reconstruction indicates this lineage has undergone substantial genome reduction compared to other related archaea. The genomic repertoire of HMT indicates a highly reduced metabolism for aerobic heterotrophy that, although lacking the carbon fixation pathway typical of AOA, includes a divergent form III-a RuBisCO that potentially functions in a nucleotide scavenging pathway. Despite the small genome size of this group, we identify 13 encoded pyrroloquinoline quinone (PQQ)-dependent dehydrogenases that are predicted to shuttle reducing equivalents to the electron transport chain, suggesting these enzymes play an important role in the physiology of this group. Our results suggest that heterotrophic Thaumarchaeota are widespread in the ocean and potentially play key roles in global chemical transformations.ImportanceIt has been known for many years that marine Thaumarchaeota are abundant constituents of dark ocean microbial communities, where their ability to couple ammonia oxidation and carbon fixation plays a critical role in nutrient dynamics. In this study we describe an abundant group of heterotrophic marine Thaumarchaeota (HMT) in the ocean with physiology distinct from their ammonia-oxidizing relatives. HMT lack the ability to oxidize ammonia and fix carbon via the 3-hydroxypropionate/4-hydroxybutyrate pathway, but instead encode a form III-a RuBisCO and diverse PQQ-dependent dehydrogenases that are likely used to generate energy in the dark ocean. Our work expands the scope of known diversity of Thaumarchaeota in the ocean and provides important insight into a widespread marine lineage.

Published

2020

41. Microbial metabolites in the marine carbon cycle

Author

Mary Ann Moran, Elizabeth B. Kujawinski, William F. Schroer, Shady A. Amin, Nicholas R. Bates, Erin M. Bertrand, Rogier Braakman, C. Titus Brown, Markus W. Covert, Scott C. Doney, Sonya T. Dyhrman, Arthur S. Edison, A. Murat Eren, Naomi M. Levine, Liang Li, Avena C. Ross, Mak A. Saito, Alyson E. Santoro, Daniel Segrè, Ashley Shade, Matthew B. Sullivan, and Assaf Vardi

Subjects

Microbiology (medical), Bacteria, Immunology, Phytoplankton, Genetics, Seawater, Cell Biology, Applied Microbiology and Biotechnology, Microbiology, Carbon, Carbon Cycle

Abstract

One-quarter of photosynthesis-derived carbon on Earth rapidly cycles through a set of short-lived seawater metabolites that are generated from the activities of marine phytoplankton, bacteria, grazers and viruses. Here we discuss the sources of microbial metabolites in the surface ocean, their roles in ecology and biogeochemistry, and approaches that can be used to analyse them from chemistry, biology, modelling and data science. Although microbial-derived metabolites account for only a minor fraction of the total reservoir of marine dissolved organic carbon, their flux and fate underpins the central role of the ocean in sustaining life on Earth.

Published

2019

42. Observations of Variable Ammonia Oxidation and Nitrous Oxide Flux in a Eutrophic Estuary

Author

Alexander W. Fisher, Rebecca J. Fox, Alyson E. Santoro, Nicholas J. Nidzieko, and Sarah M. Laperriere

Subjects

0106 biological sciences, Pycnocline, geography, Denitrification, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Stable isotope ratio, 010604 marine biology & hydrobiology, Estuary, Nitrous oxide, Aquatic Science, Atmospheric sciences, 01 natural sciences, chemistry.chemical_compound, Flux (metallurgy), chemistry, Environmental science, Eutrophication, Surface water, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Accurate global forecasting of marine nitrous oxide (N2O) emissions requires a better understanding of atmospheric N2O fluxes from coastal systems, particularly the mechanisms controlling the net balance between N2O production and consumption. The objective of this study was to examine how physical and biological processes in the eutrophic Chesapeake Bay estuary influence the temporal and spatial variability of N2O using a combination of gas measurements (N2O and N2/Ar) and stable isotope tracer incubations. Observed concentrations of N2O varied considerably in both space and time with the highest concentrations (up to 20.9 nM) across the pycnocline. Ammonia oxidation rates ranged from 14.3 to 108.9 nM h−1 and were highest following wind events that mixed oxygenated surface water below the pycnocline into ammonium-rich bottom waters, resulting in nitrite (NO2−) accumulations of up to 13 μM. During periods of weak vertical mixing, both N2O concentrations and ammonia oxidation rates were lower, while lower O2 concentrations also allowed N2O consumption by denitrification. A three-layer box model provided estimates of N2O production at the surface and across the pycnocline of 4 μmol m−2 day−1 and 21 μmol m−2 day−1, respectively, and an estimate of N2O consumption below the pycnocline of approximately −3 μmol m−2 day−1. Our results demonstrate that physical processes affect the net balance between N2O production and consumption, making Chesapeake Bay a variable source and sink for N2O.

Published

2018

43. Identifying protist consumers of photosynthetic picoeukaryotes in the surface ocean using stable isotope probing

Author

William D. Orsi, Alyson E. Santoro, Javier del Campo, Thomas A. Richards, Patrick J. Keeling, Thierry J. Heger, Erick R. James, Susanne Wilken, and Alexandra Z. Worden

Subjects

0301 basic medicine, Picoeukaryote, biology, Ecology, Stable-isotope probing, Protist, biology.organism_classification, medicine.disease_cause, Microbiology, 18S ribosomal RNA, Telonema, 03 medical and health sciences, Food chain, 030104 developmental biology, Phytoplankton, medicine, Ecology, Evolution, Behavior and Systematics, Trophic level

Abstract

Photosynthetic picoeukaryotes contribute a significant fraction of primary production in the upper ocean. Micromonas pusilla is an ecologically relevant photosynthetic picoeukaryote, abundantly and widely distributed in marine waters. Grazing by protists may control the abundance of picoeukaryotes such as M. pusilla, but the diversity of the responsible grazers is poorly understood. To identify protists consuming photosynthetic picoeukaryotes in a productive North Pacific Ocean region, we amended seawater with living 15 N, 13 C-labelled M. pusilla cells in a 24-h replicated bottle experiment. DNA stable isotope probing, combined with high-throughput sequencing of V4 hypervariable regions from 18S rRNA gene amplicons (Tag-SIP), identified 19 operational taxonomic units (OTUs) of microbial eukaryotes that consumed M. pusilla. These OTUs were distantly related to cultured taxa within the dinoflagellates, ciliates, stramenopiles (MAST-1C and MAST-3 clades) and Telonema flagellates, thus, far known only from their environmental 18S rRNA gene sequences. Our discovery of eukaryotic prey consumption by MAST cells confirms that their trophic role in marine microbial food webs includes grazing upon picoeukaryotes. Our study provides new experimental evidence directly linking the genetic identity of diverse uncultivated microbial eukaryotes to the consumption of picoeukaryotic phytoplankton in the upper ocean.

Published

2018

44. Crystal ball: the microbial map of the ocean

Author

Alyson E. Santoro

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, 010504 meteorology & atmospheric sciences, Mineralogy, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Ecology, Evolution, Behavior and Systematics, Geology, Crystal Ball, 0105 earth and related environmental sciences

Published

2018

45. Environmental controls on estuarine nitrifying communities along a salinity gradient

Author

Maria Monteiro, Daniel F. R. Cleary, Catarina Magalhães, Luís Torgo, Newton C. M. Gomes, Alyson E. Santoro, and Joana Séneca

Subjects

0301 basic medicine, geography, geography.geographical_feature_category, biology, Ecology, 030106 microbiology, Sediment, Estuary, Aquatic Science, biology.organism_classification, Salinity, 03 medical and health sciences, 030104 developmental biology, Oceanography, Nitrifying bacteria, Environmental science, Nitrification, Ecology, Evolution, Behavior and Systematics

Published

2017

46. Thaumarchaeal ecotype distributions across the equatorial Pacific Ocean and their potential roles in nitrification and sinking flux attenuation

Author

Mak A. Saito, Alyson E. Santoro, Carl H. Lamborg, Tyler J. Goepfert, Giacomo R. DiTullio, and Christopher L. Dupont

Subjects

0301 basic medicine, Biogeochemical cycle, Ecotype, Mesopelagic zone, chemistry.chemical_element, Aquatic Science, Biology, Ammonia volatilization from urea, Ammonia monooxygenase, 16. Peace & justice, Oceanography, Nitrogen, 03 medical and health sciences, 030104 developmental biology, Water column, chemistry, 13. Climate action, Environmental chemistry, Nitrification, 14. Life underwater

Abstract

Thaumarchaea are among the most abundant microbial groups in the ocean, but controls on their abundance and the distribution and metabolic potential of different subpopulations are poorly constrained. Here, two ecotypes of ammonia-oxidizing thaumarchaea were quantified using ammonia monooxygenase (amoA) genes across the equatorial Pacific Ocean. The shallow, or water column “A” (WCA), ecotype was the most abundant ecotype at the depths of maximum nitrification rates, and its abundance correlated with other biogeochemical indicators of remineralization such as NO3 : Si and total Hg. Metagenomes contained thaumarchaeal genes encoding for the catalytic subunit of the urease enzyme (ureC) at all depths, suggesting that members of both WCA and the deep, water column “B” (WCB) ecotypes may contain ureC. Coupled urea hydrolysis-ammonia oxidation rates were similar to ammonia oxidation rates alone, suggesting that urea could be an important source of ammonia for mesopelagic ammonia oxidizers. Potential inducement of metal limitation of both ammonia oxidation and urea hydrolysis was demonstrated via additions of a strong metal chelator. The water column inventory of WCA was correlated with the depth-integrated abundance of WCB, with both likely controlled by the flux of sinking particulate organic matter, providing strong evidence of vertical connectivity between the ecotypes. Further, depth-integrated amoA gene abundance and nitrification rates were correlated with particulate organic nitrogen flux measured by contemporaneously deployed sediment traps. Together, the results refine our understanding of the controls on thaumarchaeal distributions in the ocean, and provide new insights on the relationship between material flux and microbial communities in the mesopelagic.

Published

2017

47. Contributions of single-cell genomics to our understanding of planktonic marine archaea

Author

Sarah M. Laperriere, Matthew Kellom, and Alyson E. Santoro

Subjects

Metabolic function, biology, Ecology (disciplines), Group ii, Genomics, Computational biology, Population biology, Articles, Plankton, biology.organism_classification, Genome, Archaea, General Biochemistry, Genetics and Molecular Biology, Genome, Archaeal, Single-Cell Analysis, General Agricultural and Biological Sciences

Abstract

Single-cell genomics has transformed many fields of biology, marine microbiology included. Here, we consider the impact of single-cell genomics on a specific group of marine microbes—the planktonic marine archaea. Despite single-cell enabled discoveries of novel metabolic function in the marine thaumarchaea, population-level investigations are hindered by an overall lower than expected recovery of thaumarchaea in single-cell studies. Metagenome-assembled genomes have so far been a more useful method for accessing genome-resolved insights into the Marine Group II euryarchaea. Future progress in the application of single-cell genomics to archaeal biology in the ocean would benefit from more targeted sorting approaches, and a more systematic investigation of potential biases against archaea in single-cell workflows including cell lysis, genome amplification and genome screening. This article is part of a discussion meeting issue ‘Single cell ecology’.

Published

2019

48. Targeted metagenomic recovery of four divergent viruses reveals shared and distinctive characteristics of giant viruses of marine eukaryotes

Author

David M, Needham, Camille, Poirier, Elisabeth, Hehenberger, Valeria, Jiménez, Jarred E, Swalwell, Alyson E, Santoro, and Alexandra Z, Worden

Subjects

Pacific Ocean, Eukaryota, virus–host mutualism, Genome, Viral, Articles, Giant Viruses, Metagenome, Metagenomics, Mimiviridae, uncultivated giant viruses, Phylogeny, Research Article

Abstract

Giant viruses have remarkable genomic repertoires—blurring the line with cellular life—and act as top–down controls of eukaryotic plankton. However, to date only six cultured giant virus genomes are available from the pelagic ocean. We used at-sea flow cytometry with staining and sorting designed to target wild predatory eukaryotes, followed by DNA sequencing and assembly, to recover novel giant viruses from the Pacific Ocean. We retrieved four ‘PacV’ partial genomes that range from 421 to 1605 Kb, with 13 contigs on average, including the largest marine viral genomic assembly reported to date. Phylogenetic analyses indicate that three of the new viruses span a clade with deep-branching members of giant Mimiviridae, incorporating the Cafeteria roenbergensis virus, the uncultivated terrestrial Faunusvirus, one PacV from a choanoflagellate and two PacV with unclear hosts. The fourth virus, oPacV-421, is phylogenetically related to viruses that infect haptophyte algae. About half the predicted proteins in each PacV have no matches in NCBI nr (e-value < 10−5), totalling 1735 previously unknown proteins; the closest affiliations of the other proteins were evenly distributed across eukaryotes, prokaryotes and viruses of eukaryotes. The PacVs encode many translational proteins and two encode eukaryotic-like proteins from the Rh family of the ammonium transporter superfamily, likely influencing the uptake of nitrogen during infection. cPacV-1605 encodes a microbial viral rhodopsin (VirR) and the biosynthesis pathway for the required chromophore, the second finding of a choanoflagellate-associated virus that encodes these genes. In co-collected metatranscriptomes, 85% of cPacV-1605 genes were expressed, with capsids, heat shock proteins and proteases among the most highly expressed. Based on orthologue presence–absence patterns across the PacVs and other eukaryotic viruses, we posit the observed viral groupings are connected to host lifestyles as heterotrophs or phototrophs. This article is part of a discussion meeting issue ‘Single cell ecology’.

Published

2019

49. Diversity, ecology and evolution of Archaea

Author

Brett J, Baker, Valerie, De Anda, Kiley W, Seitz, Nina, Dombrowski, Alyson E, Santoro, and Karen G, Lloyd

Subjects

Ecology, Genome, Archaeal, Environmental Microbiology, Genetic Variation, Biodiversity, Energy Metabolism, Archaea, Biological Evolution, Phylogeny

Abstract

Compared to bacteria, our knowledge of archaeal biology is limited. Historically, microbiologists have mostly relied on culturing and single-gene diversity surveys to understand Archaea in nature. However, only six of the 27 currently proposed archaeal phyla have cultured representatives. Advances in genomic sequencing and computational approaches are revolutionizing our understanding of Archaea. The recovery of genomes belonging to uncultured groups from the environment has resulted in the description of several new phyla, many of which are globally distributed and are among the predominant organisms on the planet. In this Review, we discuss how these genomes, together with long-term enrichment studies and elegant in situ measurements, are providing insights into the metabolic capabilities of the Archaea. We also debate how such studies reveal how important Archaea are in mediating an array of ecological processes, including global carbon and nutrient cycles, and how this increase in archaeal diversity has expanded our view of the tree of life and early archaeal evolution, and has provided new insights into the origin of eukaryotes.

Published

2019

50. Microbial communities can predict the ecological condition of headwater streams

Author

Jason Cessna, Regina Trott, Sarah M. Laperriere, Robert H. Hilderbrand, Alyson E. Santoro, and Stephen R. Keller

Subjects

0106 biological sciences, 0301 basic medicine, Geologic Sediments, Ecological Parameter Monitoring, Marine and Aquatic Sciences, Water Columns, Artificial Gene Amplification and Extension, Oceanography, 01 natural sciences, Polymerase Chain Reaction, Water column, RNA, Ribosomal, 16S, Data Management, Sedimentary Geology, Multidisciplinary, Ecology, Microbiota, Community structure, High-Throughput Nucleotide Sequencing, Eukaryota, Geology, Replicate, Spring, Freshwater Fish, Community Ecology, Benthic zone, Vertebrates, Medicine, Seasons, Environmental Monitoring, Research Article, Microbial Taxonomy, Computer and Information Sciences, Science, Research and Analysis Methods, Index of biological integrity, 03 medical and health sciences, Rivers, Animals, Ecosystem, Molecular Biology Techniques, Molecular Biology, Petrology, Taxonomy, Community, Bacteria, 010604 marine biology & hydrobiology, Ecology and Environmental Sciences, Organisms, Biology and Life Sciences, Archaea, 030104 developmental biology, Fish, Metagenomics, Earth Sciences, Environmental science, Sediment, Zoology

Abstract

Humanity's reliance on clean water and the ecosystem services provided makes identifying efficient and effective ways to assess the ecological condition of streams ever more important. We used high throughput sequencing of the 16S rRNA region to explore relationships between stream microbial communities, environmental attributes, and assessments of stream ecological condition. Bacteria and archaea in microbial community samples collected from the water column and from stream sediments during spring and summer were used to replicate standard assessments of ecological condition performed with benthic macroinvertebrate collections via the Benthic Index of Biotic Integrity (BIBI). Microbe-based condition assessments were generated at different levels of taxonomic resolution from phylum to OTU (Operational Taxonomic Units) in order to understand appropriate levels of taxonomic aggregation. Stream sediment microbial communities from both spring and summer were much better than the water column at replicating BIBI condition assessment results. Accuracies were as high as 100% on training data used to build the models and up to 80% on validation data used to assess predictions. Assessments using all OTUs usually had the highest accuracy on training data, but were lower on validation data due to overfitting. In contrast, assessments at the order-level had similar performance accuracy for validation data, and a reduced subset of orders also performed well, suggesting the method could be generalized to other watersheds. Subsets of the important orders responded similarly to environmental gradients compared to the entire community, where strong shifts in community structure occurred for known aquatic stressors such as pH, dissolved organic carbon, and nitrate nitrogen. The results suggest the stream microbes may be useful for assessing the ecological condition of streams and especially useful for stream restorations where many eukaryotic taxa have been eliminated due to prior degradation and are unable to recolonize.

Published

2019