Your search keyword '"Nathan D. Price"' showing total 5 results

1. Baseline Gut Metagenomic Functional Gene Signature Associated with Variable Weight Loss Responses following a Healthy Lifestyle Intervention in Humans

Author

Christian Diener, Shizhen Qin, Yong Zhou, Sushmita Patwardhan, Li Tang, Jennifer C. Lovejoy, Andrew T. Magis, Nathan D. Price, Leroy Hood, and Sean M. Gibbons

Subjects

Microbiology, QR1-502

Abstract

Recent human feeding studies have shown how the baseline taxonomic composition of the gut microbiome can determine responses to dietary interventions, but the exact functional determinants underlying this phenomenon remain unclear. In this study, we set out to better understand interactions between baseline BMI, metabolic health, diet, gut microbiome functional profiles, and subsequent weight changes in a human cohort that underwent a healthy lifestyle intervention.

Published

2021

2. Exploring Hydrogenotrophic Methanogenesis: a Genome Scale Metabolic Reconstruction of Methanococcus maripaludis

Author

Nathan D. Price, Juan Zhang, Thomas J. Lie, Matthew A. Richards, John A. Leigh, and Stephen W. Ragsdale

Subjects

0301 basic medicine, Methanococcus, Chemoautotrophic Growth, Methanogenesis, Archaeal Proteins, 030106 microbiology, Genome scale, Metabolic network, Computational biology, Microbiology, Metabolic engineering, 03 medical and health sciences, Genome, Archaeal, Molecular Biology, biology, Ecology, Methanococcus maripaludis, Articles, biology.organism_classification, Methanogen, 030104 developmental biology, Methane, Metabolic Networks and Pathways, Hydrogen

Abstract

Hydrogenotrophic methanogenesis occurs in multiple environments, ranging from the intestinal tracts of animals to anaerobic sediments and hot springs. Energy conservation in hydrogenotrophic methanogens was long a mystery; only within the last decade was it reported that net energy conservation for growth depends on electron bifurcation. In this work, we focus on Methanococcus maripaludis , a well-studied hydrogenotrophic marine methanogen. To better understand hydrogenotrophic methanogenesis and compare it with methylotrophic methanogenesis that utilizes oxidative phosphorylation rather than electron bifurcation, we have built iMR539, a genome scale metabolic reconstruction that accounts for 539 of the 1,722 protein-coding genes of M. maripaludis strain S2. Our reconstructed metabolic network uses recent literature to not only represent the central electron bifurcation reaction but also incorporate vital biosynthesis and assimilation pathways, including unique cofactor and coenzyme syntheses. We show that our model accurately predicts experimental growth and gene knockout data, with 93% accuracy and a Matthews correlation coefficient of 0.78. Furthermore, we use our metabolic network reconstruction to probe the implications of electron bifurcation by showing its essentiality, as well as investigating the infeasibility of aceticlastic methanogenesis in the network. Additionally, we demonstrate a method of applying thermodynamic constraints to a metabolic model to quickly estimate overall free-energy changes between what comes in and out of the cell. Finally, we describe a novel reconstruction-specific computational toolbox we created to improve usability. Together, our results provide a computational network for exploring hydrogenotrophic methanogenesis and confirm the importance of electron bifurcation in this process. IMPORTANCE Understanding and applying hydrogenotrophic methanogenesis is a promising avenue for developing new bioenergy technologies around methane gas. Although a significant portion of biological methane is generated through this environmentally ubiquitous pathway, existing methanogen models portray the more traditional energy conservation mechanisms that are found in other methanogens. We have constructed a genome scale metabolic network of Methanococcus maripaludis that explicitly accounts for all major reactions involved in hydrogenotrophic methanogenesis. Our reconstruction demonstrates the importance of electron bifurcation in central metabolism, providing both a window into hydrogenotrophic methanogenesis and a hypothesis-generating platform to fuel metabolic engineering efforts.

Published

2016

3. Genome-Scale Metabolic Reconstruction and Hypothesis Testing in the Methanogenic Archaeon Methanosarcina acetivorans C2A

Author

William W. Metcalf, Nathan D. Price, Matthew C. Gonnerman, and Matthew N. Benedict

Subjects

Formates, Computational biology, Biology, Models, Biological, Microbiology, Genome, Gene Knockout Techniques, Genome, Archaeal, Methanosarcina acetivorans, Molecular Biology, Gene, Organism, Carbon Monoxide, Articles, biology.organism_classification, Methanogen, Phenotype, Flux balance analysis, Biochemistry, Methanosarcina, Thermodynamics, Oxidoreductases, Methane, Metabolic Networks and Pathways

Abstract

Methanosarcina acetivorans strain C2A is a marine methanogenic archaeon notable for its substrate utilization, genetic tractability, and novel energy conservation mechanisms. To help probe the phenotypic implications of this organism's unique metabolism, we have constructed and manually curated a genome-scale metabolic model of M. acetivorans , iMB745, which accounts for 745 of the 4,540 predicted protein-coding genes (16%) in the M. acetivorans genome. The reconstruction effort has identified key knowledge gaps and differences in peripheral and central metabolism between methanogenic species. Using flux balance analysis, the model quantitatively predicts wild-type phenotypes and is 96% accurate in knockout lethality predictions compared to currently available experimental data. The model was used to probe the mechanisms and energetics of by-product formation and growth on carbon monoxide, as well as the nature of the reaction catalyzed by the soluble heterodisulfide reductase HdrABC in M. acetivorans . The genome-scale model provides quantitative and qualitative hypotheses that can be used to help iteratively guide additional experiments to further the state of knowledge about methanogenesis.

Published

2012

4. Expanded Metabolic Reconstruction of Helicobacter pylori ( i IT341 GSM/GPR): an In Silico Genome-Scale Characterization of Single- and Double-Deletion Mutants

Author

Ines Thiele, Nathan D. Price, Thuy D. Vo, and Bernhard O. Palsson

Subjects

Genetics, Mutation, Helicobacter pylori, Models, Genetic, Genomics and Proteomics, In silico, Biotin, Reproducibility of Results, Mutagenesis (molecular biology technique), Genome project, Biology, medicine.disease_cause, Microbiology, Phenotype, Genome, Mutagenesis, medicine, Genes, Lethal, Energy Metabolism, Molecular Biology, Gene, Gene Deletion, Genome, Bacterial, Gene knockout

Abstract

Helicobacter pylori is a human gastric pathogen infecting almost half of the world population. Herein, we present an updated version of the metabolic reconstruction of H. pylori strain 26695 based on the revised genome annotation and new experimental data. This reconstruction, i IT341 GSM/GPR, represents a detailed review of the current literature about H. pylori as it integrates biochemical and genomic data in a comprehensive framework. In total, it accounts for 341 metabolic genes, 476 intracellular reactions, 78 exchange reactions, and 485 metabolites. Novel features of i IT341 GSM/GPR include (i) gene-protein-reaction associations, (ii) elementally and charge-balanced reactions, (iii) more accurate descriptions of isoprenoid and lipopolysaccharide metabolism, and (iv) quantitative assessments of the supporting data for each reaction. This metabolic reconstruction was used to carry out in silico deletion studies to identify essential and conditionally essential genes in H. pylori . A total of 128 essential and 75 conditionally essential metabolic genes were identified. Predicted growth phenotypes of single knockouts were validated using published experimental data. In addition, in silico double-deletion studies identified a total of 47 synthetic lethal mutants involving 67 different metabolic genes in rich medium.

Published

2005

5. Development of a Gene Knockout System Using Mobile Group II Introns (Targetron) and Genetic Disruption of Acid Production Pathways in Clostridium beijerinckii.

Author

Vi Wang, Xiangzhen Li, Milne, Caroline B., Janssen, Holger, Weiyin Lin, Phan, Gloria, Huiying Hu, Yong-Su Jin, Nathan D. Price, and Hans P. Blaschek

Subjects

*CLOSTRIDIUM beijerinckii, *BIOMASS energy, *INTRONS, *BUTYRATES, *GLUCOSE, *ANTIBIOTIC prophylaxis, *GENOTYPE-environment interaction

Abstract

Clostridium beijerinckii is a well-known solvent-producing microorganism with great potential for biofuel and biochemical production. To better understand and improve the biochemical pathway to solvents, the development of genetic tools for engineer-ing C. beijerinckii is highly desired. Based on mobile group II intron technology, a targetron gene knockout system was developed for C. beijerinckii in this study. This system was successfully employed to disrupt acid production pathways in C. beijerinckii, leading to pta (encoding phosphotransacetylase)- and buk (encoding butyrate kinase)-negative mutants. In addition to experimental characterization, the mutant phenotypes were analyzed in the context of our C. beijerinckii genome-scale model. Compared to those of the parental strain (C. beijerinckii 8052), acetate production in the pta mutant was substantially reduced and butyrate production was remarkably increased, while solvent production was dependent on the growth medium. Thepta mutant also produced much higher levels of lactate, suggesting that disruptingpta influenced the energy generation and electron flow pathways. In contrast, acetate and butyrate production in the buk mutant was generally similar to that of the wild type, but solvent production was consistently 20 to 30% higher and glucose consumption was more rapid and complete. Our results suggest that the acid and solvent production of C. beijerinckii can be effectively altered by disrupting the acid production pathways. As the gene disruption method developed in this study does not leave any antibiotic marker in a disrupted allele, multiple and high-throughput gene disruption is feasible for elucidating genotype and phenotype relationships in C. beijerinckii. [ABSTRACT FROM AUTHOR]

Published

2013