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dc.contributor.advisorChairperson, Graduate Committee: Matthew Fieldsen
dc.contributor.authorCamilleri, Laura Bethen
dc.contributor.otherKristopher 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.en
dc.contributor.otherB.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.en
dc.contributor.otherMatthew 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.en
dc.contributor.otherMatthew 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.en
dc.contributor.otherMatthew 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.en
dc.date.accessioned2021-07-13T19:48:04Z
dc.date.available2021-07-13T19:48:04Z
dc.date.issued2019en
dc.identifier.urihttps://scholarworks.montana.edu/xmlui/handle/1/16364en
dc.description.abstractBiofilms 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.en
dc.language.isoenen
dc.publisherMontana State University - Bozeman, College of Letters & Scienceen
dc.subject.lcshBiofilmsen
dc.subject.lcshMethaneen
dc.subject.lcshMetabolismen
dc.subject.lcshSulfate-reducing bacteriaen
dc.subject.lcshRNAen
dc.subject.lcshProteomicsen
dc.titleMetabolic interactions and activity partitioning in a methanogenic, interdomain biofilmen
dc.typeDissertationen
dc.rights.holderCopyright 2019 by Laura Beth Camillerien
thesis.degree.committeemembersMembers, Graduate Committee: Christine Foreman; Michael Franklin; Robin Gerlachen
thesis.degree.departmentMicrobiology & Immunology.en
thesis.degree.genreDissertationen
thesis.degree.namePhDen
thesis.format.extentfirstpage1en
thesis.format.extentlastpage400en
mus.data.thumbpage59en


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