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1	SAXS and X-ray Crystallography Studies of the Cellulosome from Clostridium thermocellum Currie, Mark 14 September 2010 (has links) Cellulosomes are the most efficient plant cell wall degradation machines discovered to date. All cellulosomal components contain protein modules connected by linkers of varying lengths, which are predicted to be flexible. Consequently, structural studies of the cellulosome have employed a “dissect and build” strategy, whereby individual modules are studied in isolation with the hope to later model the intact complex. However, representative individual structures are now available for all of the cellulosome modules and many questions still remain. The studies described in this thesis depart from the ‘dissection’ stage and enter the ‘build’ stage of cellulosome structural studies of the cellulosome from Clostridium thermocellum. We first describe the crystal structure of a heterodimeric complex comprising the type-II cohesin (CohII) from cell surface anchoring protein SdbA and a trimodular C-terminal truncation of the CipA scaffoldin protein containing the ninth type-I cohesin module (CohI9), a linker, the X-module (X), and the type-II dockerin module (DocII). This structure revealed novel intertwining of scaffoldin molecules and extensive reciprocal contacts between the CohI9 and the X-module of another scaffoldin molecule. Sedimentation velocity experiments indicate dimerization also occurs in solution. We have carried out the crystallization and structural analysis of a heterotrimeric complex containing the CohI9—X-DocII:CohII complex bound to the type-I dockerin module (DocI) from the Cel9D enzyme, which represents the largest cellulosome fragment ever determined. Identical inter-scaffoldin interactions were observed in the heterotrimeric complex structure as were seen in the heterodimeric complex. However, small angle X-ray scattering (SAXS) studies indicate that this dimerization does not occur in solution. The crystal structures and additional SAXS studies reveal flexibility in the CohI9—X linker that is surprisingly restricted to two dimensions. In addition, this structure provides the first evidence of an orientation bias in DocI binding. Finally, SAXS was used to investigate modular orientations and linker flexibility in several cellulosome fragments. These studies indicate that cellulosomal linkers exhibit restricted and in some cases highly restrained flexibility. Specifically, scaffoldin linkers display two dimensional motions, enzymes maintain close contact with their cognate DocI modules, and enzyme positions rotate about 90° relative to neighbouring enzymes on the scaffoldin. / Thesis (Ph.D, Biochemistry) -- Queen's University, 2010-09-02 02:50:11.12 Cellulosome X-ray crystallography SAXS
2	Rôle des glycosides hydrolases de famille 9 dans la dégradation de la cellulose et exploration du catabolisme de xyloglucane chez Ruminiclostridium cellulolyticum / Role of family-9 Glycoside Hydrolases in cellulose degradation and exploration of xyloglucan catabolism in Ruminiclostriidium cellulolyticum Ravachol, Julie 15 October 2015 (has links) R. cellulolyticum est une bactérie mésophile, anaérobie stricte et cellulolytique, qui sécrète des macro-complexes multienzymatiques (cellulosomes) très performants dans la dégradation des polysaccharides de la paroi végétale. Les Glycoside Hydrolases de famille 9 (GH9) sont toujours surreprésentées chez les bactéries à cellulosomes. Le génome de R. cellulolyticum code 13 GH9 dont 12 participent aux cellulosomes. Mon travail de thèse a consisté à étudier l’ensemble des GH9 de R. cellulolyticum, en déterminant leurs activités à l’état libre et en complexes, afin d’élucider leurs rôles dans la dégradation de la cellulose. Les GH9 ont chacune des activités et des spécificités de substrats différentes. Deux GH9 présentent des activités atypiques, puisque l’une d’elles est inactive et l’autre est une xyloglucanase. Les caractérisations en complexes ont souligné l’importance de la diversité des GH9 et ont montré qu’elles agissent en synergie dans la dégradation de la cellulose. De plus, l’élargissement du panel des GH9 de R. cellulolyticum par l’introduction d’une cellulase exogène de Lachnoclostridium phytofermentans a permis d’améliorer les capacités cellulolytiques de la clostridie. L’activité xyloglucanase d’une des GH9 m’a poussé à étudier le catabolisme du xyloglucane chez R. cellulolyticum. Ce travail a mis en exergue la présence d’un équipement spécialisé dans l’utilisation de ce sucre. Ainsi, après une dégradation du xyloglucane par les enzymes cellulosomales en xyloglucane dextrines, ces dernières sont importées dans le cytoplasme par un transporteur ABC spécifique puis hydrolysées séquentiellement par les enzymes cytoplasmiques en mono et disaccharides assimilables. / Ruminiclostridium cellulolyticum is a mesophilic and strictly anaerobic bacterium. It produces multienzymatic complexes called cellulosomes which efficiently degrade the plant cell wall polysaccharides. Family-9 Glycoside Hydrolases (GH9) are plethoric in cellulosome-producing bacteria. The genome of R. cellulolyticum thus encodes for 13 GH9 enzymes, 12 of them participate to the cellulosomes.My Ph. D. aimed at characterizing all GH9 enzymes from R. cellulolyticum, by determining their activities in a free and complexed states, in order to elucidate their role in cellulose degradation. All GH9 enzymes exhibit various activities and substrate specificities. Two of them have atypical activities, since one is inactive and one is a xyloglucanase. Results obtained when all GH9 are in complex highlighted the importance of GH9 diversity and revealed they act synergistically in cellulose depolymerization. Moreover, expanding the panel of GH9 enzymes by introducing an exogenous cellulase from Lachnoclostridium phytofermentans improved the cellulolytic capacities of R. cellulolyticum. The xyloglucanase activity of one GH9 enzyme prompted me to investigate the xyloglucan catabolism in R. cellulolyticum. This work uncovered the presence of a specialized equipment for xyloglucan utilization. After extracellular digestion of xyloglucan by cellulosomal enzymes, xyloglucan dextrins are imported into the cytoplasm via a specific ABC-transporter and sequentially hydrolyzed by cytoplasmic enzymes into fermentable mono and disaccharides. Gh9 Cellulase Ruminiclostridium cellulolyticum Cellulolyse Cellulosome Xyloglucane Gh9 Cellulase Ruminiclostridium cellulolyticum Cellulolysis Cellulosome Xyloglucan 579
3	Cellulose hydrolysis and metabolism in the mesophilic, cellulolytic bacterium, Clostridium termitidis CT1112 Munir, Rifat January 2015 (has links) Consolidated bioprocessing (CBP) provides a cost effective cellulose processing strategy, in which enzyme production, substrate hydrolysis, and fermentation of sugars to ethanol are all carried out in a single step by microorganisms. For industrial-scale bioethanol production, CBP-enabling microbes must be able to both efficiently degrade lignocellulosic material to fermentable sugars and synthesize bioethanol with high yields. Microbes with these properties have so far not been identified. Developing naturally occurring cellulolytic isolates with CBP-relevant properties requires a comprehensive understanding of their lignocellulosic hydrolysis mechanism and metabolism. In my quest to find a suitable organism for potential use in CBP, I took to investigate the under-characterized anaerobic bacterium, Clostridium termitidis strain CT1112. C. termitidis produces fermentative hydrogen and ethanol from a variety of lignocellulose derived substrates. I sought to investigate the metabolism of C. termitidis on different substrates and the mechanisms of substrate hydrolysis using a combination of microscopy, comparative bioinformatics, and ‘Omic (transcriptomic and proteomic) analyses. Comparative bioinformatics analyses revealed higher numbers of genes encoding carbohydrate active enzymes (CAZymes) with the potential to hydrolyze a wide-range of carbohydrates, and ‘Omic analyses were used to quantify the levels of expression of CAZymes, including endoglucanases, exoglucanases, hemicellulases and cellulosomal components. While cellulases and cellulosome components were highly expressed on cellulose, xylanases and glucosidases were predominantly expressed on pentoses, and chitinases (as well as cellobiose phosphorylases) were significantly up-regulated on cellobiose. In addition to growth on xylan, the simultaneous consumption of two important lignocellulose constituents, cellobiose and xylose was also observed. The ability to metabolize both hexose and pentose sugars is a highly desirable feature of CBP-relevant organisms. Metabolic profiles in association with ‘Omics analyses showed that hexoses and pentoses are consumed via the Embden-Meyerhof-Parnas and Pentose-Phosphate pathways, respectively, and that the genome content and expression profiles dictate end-product synthesis patterns. Genes and gene-products of enzymes in central metabolism and end-product synthesis were detected in high abundance under all substrate conditions, regardless of the amounts of end-products synthesized. The capabilities described thus far, identifies C. termitidis as a strain of interest for CBP. Further studies are, however, required for its development in to an industry-ready strain for biofuel production. / February 2016 Clostridium termitidis Cellulosome forming Cellulolytic 'Omics technologies Consolidated bioprocessing Lignocellulosic biomass Metabolism CAZymes
4	QUARTZ CRYSTAL MICROBALANCE INVESTIGATION OF CELLULOSOME ACTIVITY FROM CLOSTRIDIUM THERMOCELLUM ON MODEL CELLULOSE FILMS Zhou, Shanshan 01 January 2014 (has links) The cost of deconstructing cellulose into soluble sugars is a key impediment to the commercial production of lignocellulosic biofuels. The use of the quartz crystal microbalance (QCM) to investigate reaction variables critical to enzymatic cellulose hydrolysis is investigated here, extending previous studies of fungal cellulase activity for the first time to whole cell cellulases. Specifically, the activity of the cellulases of Clostridium thermocellum, which are in the form of cellulosomes, was investigated. To clearly differentiate the activity of free cellulosome and cell-bound cellulosome, the distribution of free cellulosome and cell-bound cellulosome in crude cell broth at different growth stages of C. thermocellum (ATCC 27405) was quantified. Throughout growth, greater than 70% of the cellulosome in the crude cell broth was unattached to the cell. The frequency response of the QCM was shown to capture adsorption and hydrolysis of amorphous cellulose films by the whole-cell cellulases. Further, both crude cell broth and free cellulosomes were found to have similar inhibition pattern (within 0 - 10 g/L cellobiose). Thus, kinetic models developed for the cell-free cellulosomes, which allow for more accurate interfacial adsorption analysis by QCM than their cell-attached counterparts, may provide insight into hydrolysis events in both systems. C.thermocellum cellulosome QCM cellulose hydrolysis inhibition Biochemical and Biomolecular Engineering Catalysis and Reaction Engineering
5	Construction of an efficient degradation system for cellulosic biomass / セルロースバイオマスの高効率分解系の構築 Bae, Jungu 23 March 2015 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第19041号 / 農博第2119号 / 新制\|\|農\|\|1032(附属図書館) / 学位論文\|\|H27\|\|N4923(農学部図書室) / 31992 / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授植田充美, 教授渡邊隆司, 教授梅澤俊明 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Clostridium cellulovorans Exoproteome analysis Cellulosome Noncellulosomal enzymes Saccharomyces cerevisiae Cell surface engineering Proximity effect 610
6	Evaluation of Complex Biocatalysis in Aqueous Solution. Part I: Efforts Towards a Biophysical Perspective of the Cellulosome; Part II: Experimental Determination of Methonium Desolvation Thermodynamics King, Jason Ryan January 2014 (has links) <p>The intricate interplay of biomolecules acting together, rather than alone, provides insight into the most basic of cellular functions, such as cell signaling, metabolism, defense, and, ultimately, the creation of life. Inherent in each of these processes is an evolutionary tendency towards increased efficiency by means of biolgocial synergy-- the ability of individual elements of a system to produce a combined effect that is different and often greater than the sum of the effects of the parts. Modern biochemists are challenged to find model systems to characterize biological synergy.</p><p>We discuss the multicomponent, enzyme complex the cellulosome as a model system of biological synergy. Native cellulosomes comprise numerous carbohydrate-active binding proteins and enzymes designed for the efficient degradation of plant cell wall matrix polysaccharides, namely cellulose. Cellulosomes are modular enzyme complexes, comparable to enzyme "legos" that may be readily constructed into multiple geometries by synthetic design. Cellulosomal enzymes provide means to measure protein efficiency with altered complex geometry through assay of enzymatic activity as a function of geometry.</p><p>Cellulosomes are known to be highly efficient at cellulose depolymerization, and current debates on the molecular origins of this efficiency suggest two related effects provide this efficiency: i) substrate targeting, which argues that the localization of the enzyme complex at the interface of insoluble cell wall polysaccharides facilitates substrate depolymerization; and ii) proximity effects, which describe the implicit benefit for co-localizing multiple enzymes with divergent substrate preferences on the activity of the whole complex.</p><p>Substrate targeting can be traced to the activity of a single protein, the cellulosomal scaffoldin cellulose binding module CBM3a that is thought to uniquely bind highly crystalline, insoluble cellulose. We introduce methods to develop a molecular understanding of the substrate preferences for CBM3a on soluble and insoluble cellulosic substrates. Using pivaloylysis of cellulose triacetate, we obtain multiple soluble cello-oligosaccharides with increasing degree of glucose polymerization (DP) from glucose (DP1) to cellodecaose (DP10) in high yield. Using calorimetry and centrifugal titrations, cello-oligosacharides were shown to not bind Clostridial cellulolyticum CMB3a. We developed AFM cantilever functionalization protocols to immobilize CBM3a and then probe the interfacial binding between CBM3a and a cellulose nanocrystal thin film using force spectroscopy. Specific binding at the interface was demonstrated in reference to a control protein that does not bind cellulose. The results indicate that i) CBM3a specifically binds nanocrystalline cellulose and ii) specific interfacial binding may be probed by force spectroscopy with the proper introduction of controls and blocking agents.</p><p>The question of enzyme proximity effects in the cellulosome must be answered by assaying the activity of cellulosomal cellulases in response to cellulosome geometry. The kinetic characterization of cellulases requires robust and reproducible assays to quantify functional cellulase content of from recombinant enzyme preparations. To facilitate the real-time routine assay of cellulase activity, we developed a custom synthesis of a fluorogenic cellulase substrate based on the cellohexaoside of Driguez and co-workers (vide infra). Two routes to synthesize a key thiophenyl glycoside building block were presented, with the more concise route providing the disaccharide in four steps from a commercial starting material. The disaccharide building blocks were coupled by chemical activation to yield the fully protected cellohexaoside over additional six steps. Future work will include the elaboration of this compound into an underivatized FRET-paired hexasaccharide and its subsequent use in cellulase activity assays.</p><p>This dissertation also covers an experimental system for the evaluation of methonium desolvation thermodynamics. Methonium (-N+Me3, Am) is an organic cation widely distributed in biological systems. The appearance of methonium in biological transmitters and receptors seems at odds with the large unfavorable desolvation free energy reported for tetramethylammonium (TMA+), a frequently utilized surrogate of methonium. We report an experimental system that facilitates incremental internalization of methonium within the molecular cavity of cucurbit[7]uril (CB[7]).</p><p>Using a combination of experimental and computational studies we show that the transfer of methonium from bulk water to the CB[7] cavity is accompanied by a remarkably small desolvation enthalpy of just 0.5±0.3 kcalmol-1, a value significantly less endothermic than those values suggested from gas-phase model studies (+49.3 kcalmol-1). More surprisingly, the incremental withdrawal of methonium surface from water produces a non- monotonic response in desolvation enthalpy. A partially desolvated state exists, in which a portion of the methonium group remains exposed to solvent. This structure incurs an increased enthalpic penalty of ~3 kcal*mol-1 compared to other solvation states. We attribute this observation to the pre- encapsulation de-wetting of the methonium surface. Together, our results offer a rationale for the wide biological distribution of methonium and suggest limitations to computational estimates of binding affinities based on simple parameterization of solvent-accessible surface area.</p> / Dissertation Chemistry Biochemistry Organic chemistry cellulosome force spectroscopy isothermal titration calorimetry ligand binding thermodynamics methonium desolvation oligosaccharide synthesis
7	Studies on molecular recognition and degradation mechanism of plant cell wall polysaccharides-assimilating Clostridium cellulovorans using proteome analysis / プロテオーム解析を用いたクロストリジウムセルロボランスの植物細胞壁多糖分解と分子認識機構の解析 Aburaya, Shunsuke 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第21808号 / 農博第2321号 / 新制\|\|農\|\|1066(附属図書館) / 学位論文\|\|H31\|\|N5180(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授植田充美, 教授渡邊隆司, 教授栗原達夫 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Clostridium cellulovorans Plant cell wall polysaccharides Quantitative proteome analysis Two-component regulatory system Design of Experiments Cellulosome 610

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