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160 results on '"Youngblut, Nicholas D."'

1. Tracing Carbon Metabolism with Stable Isotope Metabolomics Reveals the Legacy of Diverse Carbon Sources in Soil

Author

Wilhelm, Roland C, Barnett, Samuel E, Swenson, Tami L, Youngblut, Nicholas D, Koechli, Chantal N, Bowen, Benjamin P, Northen, Trent R, and Buckley, Daniel H

Subjects
Medical Biochemistry and Metabolomics, Biomedical and Clinical Sciences, Carbon, Soil, Soil Microbiology, Isotopes, Amino Acids, metabolomics, stable isotope probing, soil carbon cycle, community metabolism, Microbiology, Medical microbiology
Abstract

Tracking the metabolic activity of whole soil communities can improve our understanding of the transformation and fate of carbon in soils. We used stable isotope metabolomics to trace 13C from nine labeled carbon sources into the water-soluble metabolite pool of an agricultural soil over time. Soil was amended with a mixture of all nine sources, with one source isotopically labeled in each treatment. We compared changes in the 13C enrichment of metabolites with respect to carbon source and time over a 48-day incubation and contrasted differences between soluble sources (glucose, xylose, amino acids, etc.) and insoluble sources (cellulose and palmitic acid). Whole soil metabolite profiles varied singularly by time, while the composition of 13C-labeled metabolites differed primarily by carbon source (R2 = 0.68) rather than time (R2 = 0.07), with source-specific differences persisting throughout incubations. The 13C labeling of metabolites from insoluble carbon sources occurred slower than that from soluble sources but yielded a higher average atom percent (atom%) 13C in metabolite markers of biomass (amino acids and nucleic acids). The 13C enrichment of metabolite markers of biomass stabilized between 5 and 15 atom% 13C by the end of incubations. Temporal patterns in the 13C enrichment of tricarboxylic acid cycle intermediates, nucleobases (uracil and thymine), and by-products of DNA salvage (allantoin) closely tracked microbial activity. Our results demonstrate that metabolite production in soils is driven by the carbon source supplied to the community and that the fate of carbon in metabolites do not generally converge over time as a result of ongoing microbial processing and recycling. IMPORTANCE Carbon metabolism in soil remains poorly described due to the inherent difficulty of obtaining information on the microbial metabolites produced by complex soil communities. Our study demonstrates the use of stable isotope probing (SIP) to study carbon metabolism in soil by tracking 13C from supplied carbon sources into metabolite pools and biomass. We show that differences in the metabolism of sources influence the fate of carbon in soils. Heterogeneity in 13C-labeled metabolite profiles corresponded with compositional differences in the metabolically active populations, providing a basis for how microbial community composition correlates with the quality of soil carbon. Our study demonstrates the application of SIP-metabolomics in studying soils and identifies several metabolite markers of growth, activity, and other aspects of microbial function.

Published
2022

5. Lake microbial communities are resilient after a whole-ecosystem disturbance

Author

Shade, Ashley, Read, Jordan S, Youngblut, Nicholas D, Fierer, Noah, Knight, Rob, Kratz, Timothy K, Lottig, Noah R, Roden, Eric E, Stanley, Emily H, Stombaugh, Jesse, Whitaker, Rachel J, Wu, Chin H, and McMahon, Katherine D

Subjects
Microbiology, Biological Sciences, Ecology, Human Genome, Genetics, Bacteria, Biota, Ecosystem, Lakes, Models, Statistical, Oxygen, Phylogeny, RNA, Ribosomal, 16S, Seasons, Sequence Analysis, DNA, Temperature, Water, Water Microbiology, beta diversity, pyrosequencing, ARISA, time series, resistance, robustness, Environmental Sciences, Technology, Biological sciences, Environmental sciences
Abstract

Disturbances act as powerful structuring forces on ecosystems. To ask whether environmental microbial communities have capacity to recover after a large disturbance event, we conducted a whole-ecosystem manipulation, during which we imposed an intense disturbance on freshwater microbial communities by artificially mixing a temperate lake during peak summer thermal stratification. We employed environmental sensors and water chemistry analyses to evaluate the physical and chemical responses of the lake, and bar-coded 16S ribosomal RNA gene pyrosequencing and automated ribosomal intergenic spacer analysis (ARISA) to assess the bacterial community responses. The artificial mixing increased mean lake temperature from 14 to 20 °C for seven weeks after mixing ended, and exposed the microorganisms to very different environmental conditions, including increased hypolimnion oxygen and increased epilimnion carbon dioxide concentrations. Though overall ecosystem conditions remained altered (with hypolimnion temperatures elevated from 6 to 20 °C), bacterial communities returned to their pre-manipulation state as some environmental conditions, such as oxygen concentration, recovered. Recovery to pre-disturbance community composition and diversity was observed within 7 (epilimnion) and 11 (hypolimnion) days after mixing. Our results suggest that some microbial communities have capacity to recover after a major disturbance.

Published
2012

6. Millimeter-scale patterns of phylogenetic and trait diversity in a salt marsh microbial mat

Author

Armitage, David W., Gallagher, Kimberley L., Youngblut, Nicholas D., Buckley, Daniel H., and Zinder, Stephen H.

Subjects
BRII recipient: Armitage
Abstract

Intertidal microbial mats are comprised of distinctly colored millimeter-thick layers whose communities organize in response to environmental gradients such as light availability, oxygen/sulfur concentrations, and redox potential. Here, slight changes in depth correspond to sharp niche boundaries. We explore the patterns of biodiversity along this depth gradient as it relates to functional groups of bacteria, as well as trait-encoding genes. We used molecular techniques to determine how the mat’s layers differed from one another with respect to taxonomic, phylogenetic, and trait diversity, and used these metrics to assess potential drivers of community assembly. We used a range of null models to compute the degree of phylogenetic and functional dispersion for each layer. The SSU-rRNA reads were dominated by Cyanobacteria and Chromatiales, but contained a high taxonomic diversity. The composition of each mat core was significantly different for developmental stage, year, and layer. Phylogenetic richness and evenness positively covaried with depth, and trait richness tended to decrease with depth. We found evidence for significant phylogenetic clustering for all bacteria below the surface layer, supporting the role of habitat filtering in the assembly of mat layers. However, this signal disappeared when the phylogenetic dispersion of particular functional groups, such as oxygenic phototrophs, was measured. Overall, trait diversity measured by orthologous genes was also lower than would be expected by chance, except for genes related to photosynthesis in the topmost layer. Additionally, we show how the choice of taxa pools, null models, spatial scale, and phylogenies can impact our ability to test hypotheses pertaining to community assembly. Our results demonstrate that given the appropriate physiochemical conditions, strong phylogenetic, and trait variation, as well as habitat filtering, can occur at the millimeter-scale.

Published
2012

11. Silent recognition of flagellins from human gut commensal bacteria by Toll-like receptor 5

Author

Clasen, Sara J., primary, Bell, Michael E. W., additional, Borbón, Andrea, additional, Lee, Du-Hwa, additional, Henseler, Zachariah M., additional, de la Cuesta-Zuluaga, Jacobo, additional, Parys, Katarzyna, additional, Zou, Jun, additional, Wang, Yanling, additional, Altmannova, Veronika, additional, Youngblut, Nicholas D., additional, Weir, John R., additional, Gewirtz, Andrew T., additional, Belkhadir, Youssef, additional, and Ley, Ruth E., additional

Published
2023
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12. An integrated systems-biology platform for power-to-gas technology

Author

Casini, Isabella, primary, McCubbin, Tim, additional, Esquivel-Elizondo, Sofia, additional, Luque, Guillermo G., additional, Evseeva, Daria, additional, Fink, Christian, additional, Beblawy, Sebastian, additional, Youngblut, Nicholas D., additional, Aristilde, Ludmilla, additional, Huson, Daniel H., additional, Dräger, Andreas, additional, Ley, Ruth E., additional, Marcellin, Esteban, additional, Angenent, Largus T., additional, and Molitor, Bastian, additional

Published
2022
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14. Codiversification of gut microbiota with humans

Author

Suzuki, Taichi A., primary, Fitzstevens, J. Liam, additional, Schmidt, Victor T., additional, Enav, Hagay, additional, Huus, Kelsey E., additional, Mbong Ngwese, Mirabeau, additional, Grießhammer, Anne, additional, Pfleiderer, Anne, additional, Adegbite, Bayode R., additional, Zinsou, Jeannot F., additional, Esen, Meral, additional, Velavan, Thirumalaisamy P., additional, Adegnika, Ayola A., additional, Song, Le Huu, additional, Spector, Timothy D., additional, Muehlbauer, Amanda L., additional, Marchi, Nina, additional, Kang, Hyena, additional, Maier, Lisa, additional, Blekhman, Ran, additional, Ségurel, Laure, additional, Ko, GwangPyo, additional, Youngblut, Nicholas D., additional, Kremsner, Peter, additional, and Ley, Ruth E., additional

Published
2022
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15. ResMiCo: increasing the quality of metagenome-assembled genomes with deep learning

Author

Mineeva, Olga, Danciu, Daniel, Schölkopf, Bernhard, Ley, Ruth E., Rätsch, Gunnar, and Youngblut, Nicholas D.

Abstract

The number of published metagenome assemblies is rapidly growing due to advances in sequencing technologies. However, sequencing errors, variable coverage, repetitive genomic regions, and other factors can produce misassemblies, which are challenging to detect for taxonomically novel genomic data. Assembly errors can affect all downstream analyses of the assemblies. Accuracy for the state of the art in reference-free misassembly prediction does not exceed an AUPRC of 0.57, and it is not clear how well these models generalize to real-world data. Here, we present the Residual neural network for Misassembled Contig identification (ResMiCo), a deep learning approach for reference-free identification of misassembled contigs. To develop ResMiCo, we first generated a training dataset of unprecedented size and complexity that can be used for further benchmarking and developments in the field. Through rigorous validation, we show that ResMiCo is substantially more accurate than the state of the art, and the model is robust to novel taxonomic diversity and varying assembly methods. ResMiCo estimated 4.7% misassembled contigs per metagenome across multiple real-world datasets. We demonstrate how ResMiCo can be used to optimize metagenome assembly hyperparameters to improve accuracy, instead of optimizing solely for contiguity. The accuracy, robustness, and ease-of-use of ResMiCo make the tool suitable for general quality control of metagenome assemblies and assembly methodology optimization.Author summary Metagenome assembly quality is fundamental to all downstream analyses of such data. The number of metagenome assemblies, especially metagenome-assembled genomes (MAGs), is rapidly increasing, but tools to assess the quality of these assemblies lack the accuracy needed for robust quality control. Moreover, existing models have been trained on datasets lacking complexity and realism, which may limit their generalization to novel data. Due to the limitations of existing models, most studies forgo such approaches and instead rely on CheckM to assess assembly quality, an approach that only utilizes a small portion of all genomic information and does not identify specific misassemblies. We harnessed existing large genomic datasets and high-performance computing to produce a training dataset of unprecedented size and complexity and thereby trained a deep learning model for predicting misassemblies that can robustly generalize to novel taxonomy and varying assembly methodologies.Competing Interest StatementThe authors have declared no competing interest., bioRxiv

Published
2022

18. Interpreting tree ensemble machine learning models with endoR

Author

Ruaud, Albane, Pfister, Niklas, Ley, Ruth E., Youngblut, Nicholas D., Ruaud, Albane, Pfister, Niklas, Ley, Ruth E., and Youngblut, Nicholas D.

Abstract

Tree ensemble machine learning models are increasingly used in microbiome science as they are compatible with the compositional, high-dimensional, and sparse structure of sequence-based microbiome data. While such models are often good at predicting phenotypes based on microbiome data, they only yield limited insights into how microbial taxa may be associated. We developed endoR, a method to interpret tree ensemble models. First, endoR simplifies the fitted model into a decision ensemble. Then, it extracts information on the importance of individual features and their pairwise interactions, displaying them as an interpretable network. Both the endoR network and importance scores provide insights into how features, and interactions between them, contribute to the predictive performance of the fitted model. Adjustable regularization and bootstrapping help reduce the complexity and ensure that only essential parts of the model are retained. We assessed endoR on both simulated and real metagenomic data. We found endoR to have comparable accuracy to other common approaches while easing and enhancing model interpretation. Using endoR, we also confirmed published results on gut microbiome differences between cirrhotic and healthy individuals. Finally, we utilized endoR to explore associations between human gut methanogens and microbiome components. Indeed, these hydrogen consumers are expected to interact with fermenting bacteria in a complex syntrophic network. Specifically, we analyzed a global metagenome dataset of 2203 individuals and confirmed the previously reported association between Methanobacteriaceae and Christensenellales. Additionally, we observed that Methanobacteriaceae are associated with a network of hydrogen-producing bacteria. Our method accurately captures how tree ensembles use features and interactions between them to predict a response. As demonstrated by our applications, the resultant visualizations and summary outputs facilitate model interpret

Published
2022

19. Silent recognition of flagellins from human gut commensal bacteria by Toll-like receptor 5

Author

Clasen, Sara J., primary, Bell, Michael E. W., additional, Lee, Du-Hwa, additional, Henseler, Zachariah M., additional, Borbón, Andrea, additional, de la Cuesta-Zuluaga, Jacobo, additional, Parys, Katarzyna, additional, Zou, Jun, additional, Youngblut, Nicholas D., additional, Gewirtz, Andrew T., additional, Belkhadir, Youssef, additional, and Ley, Ruth E., additional

Published
2022
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22. Codiversification of gut microbiota with humans

Author

Suzuki, Taichi A., primary, Fitzstevens, Liam, additional, Schmidt, Victor T., additional, Enav, Hagay, additional, Huus, Kelsey, additional, Mbong, Mirabeau, additional, Adegbite, Bayode R., additional, Zinsou, Jeannot F., additional, Esen, Meral, additional, Velavan, Thirumalaisamy P., additional, Adegnika, Ayola A., additional, Song, Le Huu, additional, Spector, Timothy D., additional, Muehlbauer, Amanda L., additional, Marchi, Nina, additional, Blekhman, Ran, additional, Ségurel, Laure, additional, Youngblut, Nicholas D., additional, Kremsner, Peter, additional, and Ley, Ruth E., additional

Published
2021
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26. Free-living, psychrotrophic bacteria of the Genus Psychrobacter are descendants of pathobionts

Author

Welter, Daphne K., Ruaud, Albane, Henseler, Zachariah M., De Jong, Hannah N., Van Coeverden de Groot, Peter, Michaux, Johan, Gormezano, Linda, Waters, Jillian L., Youngblut, Nicholas D., Ley, Ruth E., Welter, Daphne K., Ruaud, Albane, Henseler, Zachariah M., De Jong, Hannah N., Van Coeverden de Groot, Peter, Michaux, Johan, Gormezano, Linda, Waters, Jillian L., Youngblut, Nicholas D., and Ley, Ruth E.

Abstract

Host-adapted microorganisms are generally assumed to have evolved from free-living, environmental microorganisms, as examples of the reverse process are rare. In the phylum Gammaproteobacteria, family Moraxellaceae, the genus Psychrobacter includes strains from a broad ecological distribution including animal bodies as well as sea ice and other nonhost environments. To elucidate the relationship between these ecological niches and Psychrobacter's evolutionary history, we performed tandem genomic analyses with phenotyping of 85 Psychrobacter accessions. Phylogenomic analysis of the family Moraxellaceae reveals that basal members of the Psychrobacter clade are Moraxella spp., a group of often-pathogenic organisms. Psychrobacter exhibited two broad growth patterns in our phenotypic screen: one group that we called the “flexible ecotype” (FE) had the ability to grow between 4 and 37°C, and the other, which we called the “restricted ecotype” (RE), could grow between 4 and 25°C. The FE group includes phylogenetically basal strains, and FE strains exhibit increased transposon copy numbers, smaller genomes, and a higher likelihood to be bile salt resistant. The RE group contains only phylogenetically derived strains and has increased proportions of lipid metabolism and biofilm formation genes, functions that are adaptive to cold stress. In a 16S rRNA gene survey of polar bear fecal samples, we detect both FE and RE strains, but in in vivo colonizations of gnotobiotic mice, only FE strains persist. Our results indicate the ability to grow at 37°C, seemingly necessary for mammalian gut colonization, is an ancestral trait for Psychrobacter, which likely evolved from a pathobiont. IMPORTANCE Host-associated microbes are generally assumed to have evolved from free-living ones. The evolutionary transition of microbes in the opposite direction, from host associated toward free living, has been predicted based on phylogenetic data but not studied in depth. Here, we provide evidence

Published
2021

46. Human Salivary Amylase Gene Copy Number Impacts Oral and Gut Microbiomes

Author

Poole, Angela C., primary, Goodrich, Julia K., additional, Youngblut, Nicholas D., additional, Luque, Guillermo G., additional, Ruaud, Albane, additional, Sutter, Jessica L., additional, Waters, Jillian L., additional, Shi, Qiaojuan, additional, El-Hadidi, Mohamed, additional, Johnson, Lynn M., additional, Bar, Haim Y., additional, Huson, Daniel H., additional, Booth, James G., additional, and Ley, Ruth E., additional

Published
2019
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49. Human salivary amylase gene copy number impacts oral and gut microbiomes

Author

Poole, Angela C., primary, Goodrich, Julia K., additional, Youngblut, Nicholas D., additional, Luque, Guillermo G., additional, Ruaud, Albane, additional, Sutter, Jessica L., additional, Waters, Jillian L., additional, Shi, Qiaojuan, additional, El-Hadidi, Mohamed, additional, Johnson, Lynn M., additional, Bar, Haim Y., additional, Huson, Daniel H., additional, Booth, James G., additional, and Ley, Ruth E., additional

Published
2018
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