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Modelling the Effect of Catalysis on Membrane Contactor Mass Transfer Coefficients for Carbon Dioxide Absorption SystemsMiller, Jacob 05 October 2021 (has links)
No description available.
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Study of enzyme reactions in the ordered assembly states / 空間的に規制された配置にある酵素の反応解析DINH, THI THU HUYEN 24 September 2019 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第22087号 / エネ博第395号 / 新制||エネ||76(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 森井 孝, 教授 木下 正弘, 教授 片平 正人 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM
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Karboranové strukturní bloky v medicinální chemii / Carborane structural blocks in medicinal chemistryNekvinda, Jan January 2018 (has links)
This work deals with carborane and metallacarborane clusters, in terms of their fundamental chemistry and complexation with cyclodextrins, and in the context of emerging pharmacophores applicable in medicinal chemistry. Arguably, the most important part of this work is the preparation of cobalt bis(dicarbollide) sulfamide derivatives. The sulfamido group is attached to the metallacarborane carbon vertex by an alkyl chain that may be modified in its length. This was accomplished by, firstly, the abstraction of the acidic hydrogen, located on the {CH}-vertex from the metallacarborane, by reaction with lithium base, followed by, secondly, reaction with electrophilic agents (PFA, oxirane and oxetane), which leads to a cascade of reactions to give the desired sulfamide derivatives. These compounds were then tested by collaborators in other institutes for in vitro and in vivo activity towards Carbonic Anhydrase IX (CA IX), which is an enzyme associated with tumour growth. In vivo tests on mice have shown that these types of substances are able to effectively reduce tumour size by 30%. The synthetic research continued with the preparation of sulfonamide compounds of the isomers of the carborane series. The reactions began exclusively with propylhydroxy carborane starting materials, which provide optimum...
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Karboranové strukturní bloky v medicinální chemii / Carborane structural blocks in medicinal chemistryNekvinda, Jan January 2018 (has links)
This work deals with carborane and metallacarborane clusters, in terms of their fundamental chemistry and complexation with cyclodextrins, and in the context of emerging pharmacophores applicable in medicinal chemistry. Arguably, the most important part of this work is the preparation of cobalt bis(dicarbollide) sulfamide derivatives. The sulfamido group is attached to the metallacarborane carbon vertex by an alkyl chain that may be modified in its length. This was accomplished by, firstly, the abstraction of the acidic hydrogen, located on the {CH}-vertex from the metallacarborane, by reaction with lithium base, followed by, secondly, reaction with electrophilic agents (PFA, oxirane and oxetane), which leads to a cascade of reactions to give the desired sulfamide derivatives. These compounds were then tested by collaborators in other institutes for in vitro and in vivo activity towards Carbonic Anhydrase IX (CA IX), which is an enzyme associated with tumour growth. In vivo tests on mice have shown that these types of substances are able to effectively reduce tumour size by 30%. The synthetic research continued with the preparation of sulfonamide compounds of the isomers of the carborane series. The reactions began exclusively with propylhydroxy carborane starting materials, which provide optimum...
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Cloning of Carbonic Anhydrase from Cotton (Gossypium hirsutum L.)Local, Andrea 12 1900 (has links)
Carbonic anhydrase is a ubiquitous zinc-metalloenzyme that catalyzes the interconversion of carbon dioxide and carbonate and has been found to play a wide range of roles in animals, plants and bacteria. Cotton genomic and cDNA libraries were screened for the plastidial isoform of carbonic anhydrase. The nucleotide sequences of two 1.2 Kb partial cDNA clones were determined. These clones exhibit high homology to carbonic anhydrases from other dicot plants and possess all the expected peptide motifs. For example, serine and threonine rich chloroplastic targeting peptide and conserved zinc binding residues are both present. These clones were utilized to isolate two carbonic anhydrase genes that were shown to encode different isoforms by PCR and RFLP analysis.
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Advanced Bioinspired Approaches to Strengthen and Repair ConcreteRosewitz, Jessica A. 23 April 2020 (has links)
Concrete is the most widely used construction material in the world and is responsible for 7% of global carbon emissions. It is inherently brittle, and it requires frequent repair or replacement which is economically expensive and further generates large volumes of carbon dioxide. Current methods of repair by agents such as mortar, epoxies, and bacteria result in structures with reduced strength and resiliency. Recent advances in the design of structural composites often mimic natural microstructures. Specifically, the structure of abalone nacre with its high stiffness, tensile strength, and toughness is a source of inspiration from the process of evolution. The inspiration from nacre can lead to design of a new class of architected structural materials with superb mechanical properties. This body of work first presents a method to reinforce concrete with an architected polymer phase. Second is presented how a ubiquitous enzyme, Carbonic anhydrase (CA), can be used to repair and strengthen cracked concrete, and how it can be used as an additive in fresh concrete. The first study presents an experimental and computational study on a set of bioinspired architected composites created using a cement mortar cast with brick-and-mortar and auxetic polymer phases. The impact of this unit-cell architected polymer phase on the flexural and compressive strengths, resilience, and toughness is studied as a function of microstructural geometry. All mechanical properties of the architected composite samples are found to be greater than those of control samples due to prevention of localized deformation and failure, resulting in higher strength. The microstructurally designed composites showed more layer shear sliding during fracture, whereas the control samples showed more diagonal shear failure. After initial cracking, the microstructurally designed composites gradually deformed plastically due to interlocking elements and achieved high stresses and strains before failure. Results also show that microstructurally designed composites with the architected polymer phase outperform control samples with equal volume fraction of a randomly oriented polymer fiber phase. Computational studies of the proposed unit cells are also performed, and the results suggest that the orientation of cells during loading is critical to achieve maximum performance of a cementitious composite. The implications of these results are immense for future development of high performing construction materials. The second study outlines methods for repair of concrete and lays the groundwork to develop a self-healing concrete that uses trace amounts of the CA enzyme. The CA catalyzes the reaction between calcium ions and carbon dioxide to create calcium carbonate that naturally incorporates into concrete structures with similar thermomechanical properties as concrete. The reaction is safe, actively consumes carbon dioxide, generates low amounts of heat, and avoids using unhealthy reagents, resulting in a strong structure. This repair method results in concrete samples with similar strength and water permeability as the intact materials. These results offer an inexpensive, safe, and efficient method to create self-healing concrete structures. The science underlying the creation of self-healing concrete is described, producing a material intrinsically identical to the original using the CA enzyme. Using this strategy, a preliminary self-healing concrete mix is able to self-repair fractures via hydration. This body of work addresses a major issue: Is there an efficient and ecological repair for decaying concrete infrastructure? These methods propose alternative reinforcement, alleviates high monetary and energy costs associated with concrete replacement, and consume the greenhouse gas, carbon dioxide.
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Ionization in H2O -- bearing carbon dioxide determined by conductivity measurementsCapobianco, Ryan Michael 28 June 2013 (has links)
Recent studies report rapid corrosion of metals and carbonation of minerals in contact with H2O-saturated (or nearly saturated) CO2. One explanation for this behavior is that addition of small amounts of H2O to CO2 leads to significant ionization within the fluid (analogous to corrosion in aqueous fluids). The extent of ionization in the bulk CO2 fluid was determined using a flow-through conductivity cell capable of analyzing very dilute solutions. Experiments were conducted from 25 to 200"C and 25 to 200 bar with H2O concentrations up to ~1650 ppmw. In all experiments, conductivities <10 nS/cm were obtained, indicating that the solution is essentially ion-free. This observation suggests that mobile ions are not present in the bulk CO2--rich fluid, and that the observed corrosion and carbonation reactions are not the result of ionization in the bulk fluid. / Master of Science
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<em>Thiomicrospira crunogena</em>: A Chemoautotroph With a Carbon Concentrating MechanismDobrinski, Kimberly P 13 July 2009 (has links)
Gammaproteobacterium Thiomicrospira crunogena thrives at deep-sea vents despite extreme oscillations in the environmental supply of dissolved inorganic carbon (DIC; =CO2 + HCO3- + CO3-2). Survival in this habitat is likely aided by the presence of a carbon concentrating mechanism (CCM). Though CCMs are well-documented in cyanobacteria, based on this study T. crunogena is the first chemolithoautotroph to have a physiologically characterized CCM. T. crunogena is capable of rapid growth in the presence of 20 micrometers DIC, has the ability to use both extracellular HCO3- and CO2, and generates intracellular DIC concentrations 100-fold greater than extracellular, all of which are consistent with a CCM analogous to those present in cyanobacteria. Interestingly, however, the T.crunogena genome lacks apparent orthologs of many of the components of the cyanobacteria CCM (e.g., HCO3- transporters). However, despite this lack, several candidate genes were identified during genome annotation as likely to play a role in DIC uptake and fixation (three carbonic anhydrase genes: alpha-CA, beta-CA, and csoSCA, as well as genes encoding three RubisCO enzymes: cbbLS, CScbbLS, and cbbM, which encode a cytoplasmic form I RubisCO, a carboxysomal form I RubisCO, and a form II RubisCO, respectively).
In order to clarify their possible roles in DIC uptake and fixation, alpha-CA, beta-CA and csoSCA transcription by low-DIC and high-DIC T. crunogena were assayed by qRT PCR, heterologous expression in E. coli, and potentiometric assays of low-DIC and high-DIC T. crunogena. Transcription of alpha-CA and beta-CA were not sensitive to the DIC concentration available during growth. When overexpressed in E.coli, carbonic anhydrase activity was detectable, and it was possible to measure the effects of the classical carbonic anhydrase inhibitors ethoxyzolamide and acetazolamide, as well as dithiothreitol (DTT; recently determined to be a carboxysomal CA inhibitor). The alpha-CA was sensitive to both of the classical inhibitors, but not DTT. Beta-CA was insensitive to all inhibitors tested, and the carboxysomal carbonic anhydrase was sensitive to both ethoxyzolamide and DTT. The observation that the CA activity measureable potentiometrically with intact T. crunogena cells is sensitive to classical inhibitors, but not DTT, strongly suggests the alpha-CA is extracellular. The presence of carbonic anhydrase activity in crude extracts of high-DIC cells that was resistant to classical inhibitors suggests that beta-CA may be more active in high-DIC cells. Incubating cells with ethoxyzolamide (which permeates cells rapidly) resulted in inhibition of carbon fixation, but not DIC uptake, while incubation with acetazolamide (which does not permeate cells rapidly) had no apparent effect on either carbon fixation or DIC uptake. The observations that inhibition of alpha-CA has no effect on DIC uptake and fixation, and that the beta-CA is not transcribed more frequently under low-DIC conditions, make it unlikely that either play a role in DIC uptake and fixation in low-DIC cells. Further studies are underway to determine the roles of alpha-CA and beta-CA in T. crunogena.
To assay the entire genome for genes transcribed more frequently under low-DIC conditions, and therefore likely to play a role in the T. crunogena CCM, oligonucleotide arrays were fabricated using the T. crunogena genome sequence. RNA was isolated from cultures grown in the presence of both high (50 mM) and low (0.05 mM) concentrations of DIC, directly labeled with cy5 fluorophore, and hybridized to microarrays. Genes encoding the three RubisCO enzymes present in this organism demonstrated differential patterns of transcription consistent with what had been observed previously in Hydrogenovibrio marinus. Genes encoding two conserved hypothetical proteins were also found to be transcribed more frequently under low-DIC conditions, and this transcription pattern was verified by qRT-PCR. Knockout mutants are currently being generated to determine whether either gene is necessary for growth under low-DIC conditions. Identifying CCM genes and function in autotrophs beyond cyanobacteria will serve as a window into the physiology required to flourish in microbiallydominated ecosystems where noncyanobacterial primary producers dominate.
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APE1/REF-1 redox signaling regulates HIF1A-mediated CA9 expression in hypoxic pancreatic cancer cells : combination treatment in patient-derived pancreatic tumor modelLogsdon, Derek Paul 14 December 2017 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Pancreatic ductal adenocarcinoma (PDAC) is an extremely deadly disease
characterized by aggressive metastasis and therapeutic resistance. Reactive stroma in
pancreatic tumors contributes to tumor signaling, fibrosis, inflammation, and hypoxia.
Hypoxia signaling creates a more aggressive phenotype with increased potential for
metastasis and decreased therapeutic efficacy. Carbonic anhydrase IX (CA9) functions as
part of the cellular response to hypoxia by regulating intracellular pH to promote cell
survival. Apurinic/Apyrimidinic Endonuclease-1-Reduction/oxidation Effector Factor 1
(APE1/Ref-1) is a multi-functional protein with two major activities: endonuclease activity
in DNA base excision repair and a redox signaling activity that reduces oxidized
transcription factors, enabling them to bind target sequences in DNA. APE1/Ref-1 is a
central node in redox signaling, contributing to the activation of transcription factors
involved in tumor survival, growth, and hypoxia signaling. This work evaluates the
mechanisms underlying PDAC cell responses to hypoxia and APE1/Ref-1 redox signaling
control of hypoxia inducible factor 1 alpha (HIF1a), a critical factor in hypoxia-induced
CA9 transcription. We hypothesized that obstructing the HIF-CA9 axis at two points via APE1/Ref-1 inhibition and CA9 inhibition results in enhanced PDAC cell killing under
hypoxic conditions.
We found that HIF1a-mediated induction of CA9 is significantly attenuated
following APE1/Ref-1 knock-down or redox signaling inhibition in patient-derived PDAC
cells and pancreatic cancer-associated fibroblast cells. Additionally, dual-targeting of
APE1/Ref-1 redox signaling activity and CA9 activity results in enhanced acidification and
cytotoxicity of PDAC cells under hypoxic conditions as well as decreased tumor growth in
an ex-vivo 3-dimensional tumor co-culture model. Further experiments characterized
novel analogs of clinically relevant drugs targeting the key enzymes in this pathway,
resulting in improved potency. These results underscore the notion that combination
therapy is essential and demonstrate the potential clinical utility of blocking APE1/Ref-1
and CA9 function for novel PDAC therapeutic treatment.
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Hypoxia-inducible factor 1 promotes chemoresistance of lung cancer by inducing carbonic anhydrase IX expression / 低酸素誘導性因子は、炭酸脱水素酵素IXの誘導により、肺がんの抗がん剤耐性を惹起するSowa, Terumasa 24 July 2017 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20614号 / 医博第4263号 / 新制||医||1023(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 高田 穣, 教授 平井 豊博, 教授 岩井 一宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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