Theses and Dissertations at Montana State University (MSU)
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Item Metabolic interactions and activity partitioning in a methanogenic, interdomain biofilm(Montana State University - Bozeman, College of Letters & Science, 2019) Camilleri, Laura Beth; Chairperson, Graduate Committee: Matthew Fields; Kristopher A. Hunt, Aurelien Mazurie, Jennifer Kuehl, Alex Michaud, James Connolly, Egan Lohman, Zack Miller, Adam M. Deutschbauer and Matthew W. Fields were co-authors of the article, 'Differential gene expression of a bacterial-archaeal interdomain biofilm producing methane' submitted to the journal 'Biofilms' which is contained within this dissertation.; B.P. Bowen, C.J. Petzold, T.R. Northen and M.W. Fields were co-authors of the article, 'Activity partitioning in an archaeal-bacterial biofilm' submitted to the journal 'Letters in applied microbiology' which is contained within this dissertation.; Matthew W. Fields was a co-author of the article, 'Methanococcus maripaludis factor causes slowed growth in Desulfovibrio vulgaris Hildenborough' submitted to the journal 'Letters in applied microbiology' which is contained within this dissertation.; Matthew W. Fields was a co-author of the article, 'Growth effects of sulfopyruvate and sulfoacetate on the sulfate-reducing bacterium, Desulfovibrio vulgaris Hildenborough, and the methanogenic archaeon Methanococcus maripaludis S2' submitted to the journal 'Scientific reports' which is contained within this dissertation.; Matthew W. Fields was a co-author of the article, 'Methane production in Pelosinus fermentans JBW45' submitted to the journal 'Letters in applied microbiology' which is contained within this dissertation.Biofilms are an ancient survival strategy in which communities of organisms can grow as a cohesive unit, generally attached to a surface and/or at interfaces. Despite the paradigm that 99% of microorganisms grow as a biofilm in the environment, current research methods are largely limited to monoculture planktonic studies. Although more investigations are trying to improve culture complexity by evaluating interactions between two or more populations, experiments are still more readily performed with microorganisms in the planktonic growth mode. The research presented here aims to elucidate the complexity of interactions between two microorganisms from different domains of life that results in enhanced metabolism due to localization of cells in close proximity within an anaerobic biofilm. Desulfovibrio vulgaris Hildenborough (DvH) and Methanococcus maripaludis S2 (Mmp) form a syntrophic mutualism when grown in sulfate-limited media that requires electron flux from DvH to Mmp through what is commonly assumed to be interspecies hydrogen transfer, thereby establishing cross-feeding. The biofilm has been shown to promote a stable and more even carrying capacity for both populations that is likely linked to improved hydrogen transfer (and/or other potential carbon and electron co-metabolites) as compared to planktonic populations. Transcriptomic and proteomic analyses, utilizing RNA-seq and deuterated water respectively, were used to elucidate genes and proteins that contribute to the biofilm growth mode that results in a more efficient metabolism for the syntrophic co-culture (defined by biomass per substrate flux). The results demonstrate the expression of many genes with unknown functions, and others that contribute to cell-cell interactions as well as active proteins in electron processing (e.g., lactate oxidation) in DvH and CO2 reduction (e.g., methanogenesis) in Mmp. A metabolic model of the coculture provided reinforcement for transcriptomic assumptions and aided in the identification of a sulfonate and other amino acids as important syntrophic metabolites. Assessment of biofilm co-culture activity utilizing a new method, Biorthogonal Noncanonical Amino Acid Tagging (BONCAT), showed Mmp was less active in the uptake of a methionine analog as compared to DvH. Alternate assessments confirmed that Mmp was in fact active (based upon methane generation) although translational activity was below the detection limit. Further investigation of the system under sulfate stress showed that the metabolic pairing is more stable than previously thought and could indicate survival strategies that drive the seemingly 'mutualistic' relationship as a forced cooperation. The sulfate stress response coincided with observed lags in DvH growth when grown in Mmp spent medium that was associated with a decoupling of lactate-oxidation and sulfate-reduction. Together the results demonstrate metabolic interactions and activity partitioning within a methanogenic archaeal-bacterial biofilm. The dogma of mutualism being synonymous with equal reciprocity is challenged as it pertains to this model biofilm system. Moreover, this unique bacterial-archaeal biofilm represents interdomain interactions that could represent systems that contributed shared metabolic processes that lead to the development of eukaryotic life.Item Evolution and function of flavin-based electron bifurcation(Montana State University - Bozeman, College of Letters & Science, 2018) Poudel, Saroj; Chairperson, Graduate Committee: Eric Boyd; John W. Peters (co-chair); Eric C. Dunham, Melody R. Lindsay, Maximiliano J. Amenabar, Elizabeth M. Fones, Daniel R. Colman and Eric S. Boyd were co-authors of the article, 'Origin and evolution of flavin-based electron bifurcating enzymes' in the journal 'Frontiers in microbiology' which is contained within this thesis.; Amaya M. Garcia Costas was an author and Anne-Frances Miller, Gerrit J. Schut, Rhesa N. Ledbetter, Kathryn R. Fixen, Lance C. Seefeldt, Michael W. W. Adams, Caroline S. Harwood, Eric S. Boyd and John W. Peters were co-authors of the article, 'Defining electron bifurcation in the electron transferring flavoprotein family' in the journal 'Journal of bacteriology' which is contained within this thesis.; Daniel R. Colman was an author and Kathryn R. Fixen, Rhesa N. Ledbetter, Yanning Zheng, Natasha Pence, Lance C. Seefeldt, John W. Peters, Caroline S. Harwood and Eric S. Boyd, were co-authors of the article, 'Electron transfer to nitrogenase in different genomic and metabolic backgrouns' in the journal 'Journal of bacteriology' which is contained within this thesis.Anaerobic microorganisms live in energy limited environments with low nutrient fluxes. Thus, selection has likely acted on these cells to innovate mechanisms that improve the efficiency of anaerobic energy metabolism. In 2008, the process of flavin-based electron bifurcation (FBEB) was discovered and has since been shown to be a critical process that allows anaerobic cells to overcome thermodynamic barriers and to improve metabolic efficiency. FBEB enzymes catalyze the coupling of exergonic and endergonic oxidation--reduction reactions with the same electron donor to circumvent thermodynamic barriers and minimize free energy loss. To date, a total of 12 FBEB enzymes have been discovered that share common features that include the presence of protein-bound flavin, the proposed site of bifurcation, and the electron carrier ferredoxin. Due to its recent discovery, a comprehensive description of the natural history of bifurcating enzymes is lacking. In this thesis, we report the taxonomic and ecological distribution, functional diversity, and evolutionary history of bifurcating enzyme homologs in available complete genomes and environmental metagenomes. Moreover, we investigated the functional and ecological constraints that led to the emergence of FBEB enzymes. Bioinformatics analyses revealed that FBEB enzyme homologs were primarily detected in the genomes of anaerobes, including those of sulfate-reducers, acetogens, fermenters, and methanogens. Phylogenetic analyses of these enzyme homologs suggest that they were not a property of the Last Universal Common Ancestor of Archaea and Bacteria indicating that they are a more recent evolutionary innovation. Consistent with the role of these enzymes in the energy metabolism of anaerobes, FBEB homologs were enriched in metagenomes from subsurface environments relative to those from surface environments. In fact, the earliest evolving homologs of most bifurcating enzymes were detected in subsurface environments, including fluids from subsurface rock fractures and hydrothermal systems. Together, these data highlight the central role that FBEB played and continued to play in the energy metabolism of anaerobic microbial cells inhabiting subsurface environments.Item Microbial interactions and the role of environmental stress in natural and synthetic consortia(Montana State University - Bozeman, College of Letters & Science, 2018) Beck, Ashley Esther; Chairperson, Graduate Committee: Ross Carlson; Kristopher A. Hunt, Hans C. Bernstein and Ross P. Carlson were co-authors of the chapter, 'Interpreting and designing microbial communities for bioprocess applications, from components to interactions to emergent poperties' in the book 'Biotechnology for biofuel production and optimization' which is contained within this thesis.; Kristopher A. Hunt and Ross P. Carlson were co-authors of the article, 'Measuring cellular biomass composition for computational biology applications' submitted to the journal 'Processes, methods in computational biology special issue' which is contained within this thesis.; Hans C. Bernstein, and Ross P. Carlson were co-authors of the article, 'Stoichiometric network analysis of cyanobacterial acclimation to photosynthesis-associated stresses identifies heterotrophic niches' in the journal 'Processes, microbial community modeling: prediction of microbial interactions and community dynamics special issue' which is contained within this thesis.; Kathryn Pintar, Diana Schepens, Ashley Schrammeck, Tim Johnson, Alissa Bleem, Hans C. Bernstein, Tomas Gedeon, Jeffrey J. Heys and Ross P. Carlson were co-authors of the article, 'Escherichia coli co-metabolizes glucose and lactate for enhanced growth' submitted to the journal 'Applied and Environmental Microbiology' which is contained within this thesis.; Ross P. Carlson was a co-author of the article, 'Synthetic consortia engineered for push and pull dynamics show conditional optimality over metabolic generalist' which is contained within this thesis.Microbial communities are critical underpinnings of most natural processes, e.g. biogeochemical cycling, and can also be harnessed and engineered for a variety of industrial applications. Despite the abundance of detailed physiological characterization of many individual microorganisms, as well as large data sets describing microbial community composition, the area of interspecies interactions requires further research to truly appreciate and harness the potential of microbial capabilities. Using a combination of in silico metabolic modeling and in vitro laboratory approaches linked to guiding ecological theories, this dissertation investigates metabolite exchange as a mechanism of interspecies interactions and focuses on the role of environmental stress in mediating interactions. A stoichiometric metabolic network model was constructed for the thermophilic cyanobacterium Thermosynechococcus elongatus BP-1 and was analyzed with elementary flux mode analysis to predict metabolic acclimations to light and oxygen, two common environmental stressors in photoautotrophic habitats. High stress levels were predicted to activate organic byproduct secretion pathways, which opens a niche to support growth of heterotrophic partners. To further investigate metabolite exchange in the laboratory, synthetic consortia were designed through genetic engineering and pairing of Escherichia coli strains to form metabolically partitioned organic acid cross-feeding systems. These controlled systems were used to investigate the impact of division of labor as well as the effect of byproduct detoxification. Kinetic data from these systems were also applied to interpret ecological theories regarding microbial community structure. Altogether, these studies demonstrate an integrated approach to studying microbial community interactions by combining in silico metabolic modeling and in vitro laboratory experiments with ecological theory as a basis for interpretation. This dissertation provides insight into rationale for microbial community structure and highlights the role of environmental stress, particularly byproduct inhibition, in driving microbial consortia interactions.Item Nutrient limitation alters metabolism, CR(VI) response, and biofilm matrix composition in desulfovibrio vulgaris Hildenborough(Montana State University - Bozeman, College of Letters & Science, 2017) Franco, Lauren Christine; Chairperson, Graduate Committee: Matthew Fields; Grant Zane, Sadie Steinbeisser, Judy Wall and Matthew W. Fields were co-authors of the article, 'Cr(VI) reduction and physiological toxicity is impacted by resource ratio in Desulfovibrio vulgaris Hildenborough' submitted to the journal 'Applied microbiology and microbiology' which is contained within this thesis.; Julijana Ivanisevic, Gary Siuzdak and Matthew W. Fields were co-authors of the article, 'Nutrient limitation causes decline in metabolites important for cell cycle progression in bacterial biofilm' submitted to the journal 'Applied microbiology and microbiology' which is contained within this thesis.; Siva Wu, Michael Joo, Joel Mancuso, Jonathan Remis, Amita Gorur, Ambrose Leung, Danielle M. Jorgens, Joaquin Correa, Manfred Auer and Matthew W. Fields were co-authors of the article, 'Extracellular membrane structures in Desulfovibrio vulgaris Hildenborough biofilms' which is contained within this thesis.; Chris Petzold and Matthew W. Fields were co-authors of the article, 'Outer membrane vesicles and associated proteins produced by Desulfovibrio vulgaris Hildenborough biofilms' submitted to the journal 'Applied microbiology and microbiology' which is contained within this thesis.Sulfate-reducing bacteria (SRB) are a diverse group of anaerobic microorganisms that live in anoxic environments and play critical roles in biogechemical cycling, namely linkages between the carbon and sulfur cycles. Desulfovibrio vulgaris Hildenborough (DvH) is a model organism for SRB that has been studied for its ability to reduce toxic heavy metals to insoluble forms and its involvement in microbially induced corrosion in oil pipelines and other industrial settings. The described work investigated how the availability of electron donor/carbon sources and electron acceptors affected Cr(VI) reduction, metabolism, and biofilm growth and composition in DvH. DvH was grown planktonically at 20°C and 30°C in batch mode or as a biofilm under continuous flow at 20°C. In the second chapter of this dissertation, it is established that electron acceptorlimitation (EAL) predisposes cells to Cr(VI) toxicity compared to a balanced electron donor to electron acceptor (BAL) condition and electron donor-limited (EDL) condition. The effect of nutrient limitation on DvH biofilms is investigated, and microscopy revealed unique extracellular membranous structures that have not previously been observed. The extracellular structures were heterogeneously distributed, connected to cells, co-localized with metal precipitates, and more prevalent under EAL compared to BAL condition. Differential staining indicated that the structures were composed of lipid, consistent with the observation that these structures are membrane derived. Metabolomic analysis revealed an up-regulation of fatty acids under the EAL condition, which was confirmed and quantified via GC-MS. Down-regulated metabolites for biofilm grown under the EAL condition included those involved in DNA turnover, N-cycling, and peptidoglycan turnover, indicating that EAL may induce a switch from growth to fatty acid production that may coordinate with alternative electron transfer mechanisms. Outer membrane vesicles (OMVs) were purified from DvH biofilm and proteins detected in OMVs included porins, lipoproteins, hydrogenases, and oxidative stress response proteins. The results presented here show that nutrient limitation and resource ratio affect DvH physiology in both biofilm and planktonic growth modes. The analysis of the DvH biofilm matrix highlights the importance of investigating extracellular capabilities that are unique to the biofilm growth mode and has implications for activities and physiological states in the environment.Item Nox protein expression, purification and structure analysis(Montana State University - Bozeman, College of Agriculture, 2004) Baniulis, Danas; Chairperson, Graduate Committee: Algirdas J. JesaitisFlavocytochrome b558 (Cytb) is a heterodimeric integral membrane protein that serves as the electron transferase of the NADPH oxidase. Six homologues of gp91-phox, the large subunit of Cytb, have been identified (Nox family). Understanding of the structure and function of the Nox proteins is limited. To distinguish solvent-accessible and membrane or conformation sequestered regions on native structure of gp91-phox, a number of proteolytic enzyme cleavage products on the lipid reconstituted protein were identified using mass spectrometry, in this study. Affinity-purified rabbit anti-peptide antibodies binding to intact neutrophils suggested extracellular localization of gp91-phox regions, however, results using control CGD-cells suggested that these antibodies may cross-react with an unusual non-gp91-phox species in the normal and CGD-derived plasma membranes. Further, a monoclonal antibody CL5 epitope was mapped to the region 135-DPYSVALSELGDR on the gp91-phox, the prototype for the Nox family proteins. Epitopes of previously described mAb 54.1 and CL5 in gp91-phox align with Nox family proteins with high degree of identity and the use of these two monoclonal antibodies as immunoprobes for Nox family proteins was evaluated. Ab 54.1 was found to be specifically reactive with homologous Nox protein fragments expressed in E. coli. Nox3 protein expressed in HEK293H cells was also detected by 54.1, but not by CL5. Nox1 expression in stably transfected NIH 3T3 was examined using the antibodies, but no detectable binding to Nox1 was observed in immunoblotting assays and by flow-cytometry analysis. The antibodies were also used to probe for presence of potential truncated forms of gp91-phox expressed in chronic granulomatous disease (CGD) affected neutrophils with premature termination of gp91-phox synthesis. Analysis did not detect any smaller size protein fragments by immunoblotting. In addition, two other proteins were found to be crossreactive with 54.1 and CL5, they were identified as GRP58 and gelsolin, respectively, two universally expressed cytosolic proteins with regulated association with the plasma membrane. Finally, to help in ongoing structural biology efforts, a recombinant human Cytb expressing PLB-985 cell line was used to develop process of large-scale production of the protein for application in structural biology experiments.Item Human neutrophil flavocytochrome b : structure and function(Montana State University - Bozeman, College of Agriculture, 2002) Foubert, Thomas RichardItem The fate of fermentation products and glycollate in hot spring microbial mats with emphasis on the role played by Chloroflexus aurantiacus(Montana State University - Bozeman, College of Agriculture, 1983) Tayne, Timothy Alden