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Molecular and genetic analysis of the vha16 gene in Drosophila melanogasterGraham, Shirley January 2000 (has links)
No description available.
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Role of ATP Hydrolysis and Mechanism of Substrate Reduction in NitrogenaseShaw, Sudipta 01 May 2017 (has links)
Nitrogenase consists of two metalloproteins, the MoFe protein and the Fe protein. The MoFe protein is an α2β2 heterotetramer and the Fe protein is an α2 homodimer. The catalytic cycle of nitrogenase involves binding of the Fe protein to each αβ catalytic half of the MoFe protein, electron transfer followed by ATP hydrolysis, Pi release and eventually dissociation of the two proteins. This cycle has to be repeated eight consecutive times to reduce one molecule of N2.
The two catalytic halves of the MoFe protein had been considered to be independent of each other. The research presented here showed that there is negative cooperativity associated between the two catalytic halves of the MoFe protein. The results suggested that only one half of the MoFe protein is operative during the first turnover of the enzyme.
In order to understand the substrate reduction mechanism of nitrogenase, the study focused on two important enzymes of the biogeochemical nitrogen cycle: nitrite (NO2 -) and nitrate (NO3 -). Two intermediates of NO2 - reduction were trapped by a remodeled nitrogenase (α-70Ala/α-195Gln MoFe protein) and characterized by advanced spectroscopic studies. These intermediates were found to be identical to the intermediates trapped during reduction of diazene (N2H2) and hydrazine (N2H4). The pathway for reduction NO2 - to ammonia (NH3) was also proposed.
NO3 - was established as a new substrate of nitrogenase. The advanced spectroscopic studies confirmed that the same two intermediates were trapped by the remodeled nitrogenase. Kinetic studies showed that two competing pathways lead to NO3 - reduction by nitrogenase, a primary 2 e- reduction pathway to form nitrite and a secondary 8 e- reduction pathway to form NH3. The pathways for reduction of NO3 - to NO2 - and NH3 were proposed.
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ATP Utilization by the DEAD-Box Protein DED1PLiu, Fei January 2010 (has links)
No description available.
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Investigation of the Effect of Changes in Lipid Bilayer Properties on the Activity of the Bacterial Cell Division Regulator Protein MinDAyed, Saud 13 September 2012 (has links)
Bacterial cell division requires formation of the cytokinetic cell division septum at the mid-cell position, a process that is determined by three Min proteins; MinC, MinD and MinE. Regulation of cell division by Min proteins occurs via a multi-step process involving interactions between various Min proteins, as well as the membrane. In this cycle, ATP-bound MinD binds to the membrane surface where it can recruit MinC to inhibit formation of the cell division septum. MinE binding to this complex displaces MinC and stimulates ATP hydrolysis, leading to the dissociation of MinD from the membrane. These interactions give rise to a dynamic pattern of Min protein localization that appears to involve a polymeric state that is designed to create a zone that is permissive to cell division at the mid-point of the cell. The interaction between MinD and the membrane is a critical aspect of this cycle, yet the role of the lipid bilayer in MinD activation, localization and polymerization is not well understood. To probe the role of membrane charge and fluidity on MinD activation and polymerization, we developed a kinetic assay of MinE-stimulated MinD ATPase activity. We found that membrane charge is essential for MinD activation and that differences in membrane fluidity give rise to changes in its activity. Moreover, a burst phase was also observed during the first few minutes of reaction, but only on the most fluid anionic lipid tested. To help determine if the observed membrane-dependent changes in MinD activity are linked to any changes in MinD polymer structure, we have begun to develop a method to identify surface exposed regions of MinD through a combination of covalent labeling and mass spectrometry. Optimization of various steps for the assay has been done, and the assay can be applied to the future characterization of MinD polymer structure. Results from this assay, in combination with those from the kinetic measurements described here, will help to improve understanding about how membrane properties modulate MinD ATPase activity, and how this can influence the Min protein oscillation that is required to ensure normal bacterial cell division.
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Conformational Studies of Myosin and Actin with Calibrated Resonance Energy TransferXu, Jin 05 1900 (has links)
Resonance energy transfer was employed to study the conformational changes of actomyosin during ATP hydrolysis. To calibrate the technique, the parameters for resonance energy transfer were defined. With conformational searching algorithms to predict probe orientation, the distances measured by resonance energy transfer are highly consistent with the atomic models, which verified the accuracy and feasibility of resonance energy transfer for structural studies of proteins and oligonucleotides.
To study intramyosin distances, resonance energy transfer probes were attached to skeletal myosin's nucleotide site, subfragment-2, and regulatory light chain to examine nucleotide analog-induced structural transitions. The distances between the three positions were measured in the presence of different nucleotide analogs. No distance change was considered to be statistically significant. The measured distance between the regulatory light chain and nucleotide site was consistent with either the atomic model of skeletal myosin subfragment-1 or an average of the three models claimed for different ATP hydrolysis states, which suggested that the neck region was flexible in solution. To examine the participation of actin in the powerstroke process, resonance energy transfer between different sites on actin and myosin was measured in the presence of nucleotide analogs. The efficiencies of energy transfer between myosin catalytic domain and actin were consistent with the actoS1 docking model. However, the neck region was much closer to the actin filament than predicted by static atomic models. The efficiency of energy transfer between Cys 374 and the regulatory light chain was much greater in the presence of ADP-AlF4, ADP-BeFx, and ADP-vanadate than in the presence of ADP or no nucleotide. These data detect profound differences in the conformations of the weakly and strongly attached crossbridges which appear to result from a conformational selection that occurs during the weak binding of the myosin head to actin.
The resonance energy transfer data exclude a number of versions of the swinging lever arm model, and indicate that actin participation is indispensable for conformational changes leading to force generation. The conformational selection during weak binding at the actomyosin interface may precock the myosin head for the ensuing powerstroke.
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Investigation of the Effect of Changes in Lipid Bilayer Properties on the Activity of the Bacterial Cell Division Regulator Protein MinDAyed, Saud 13 September 2012 (has links)
Bacterial cell division requires formation of the cytokinetic cell division septum at the mid-cell position, a process that is determined by three Min proteins; MinC, MinD and MinE. Regulation of cell division by Min proteins occurs via a multi-step process involving interactions between various Min proteins, as well as the membrane. In this cycle, ATP-bound MinD binds to the membrane surface where it can recruit MinC to inhibit formation of the cell division septum. MinE binding to this complex displaces MinC and stimulates ATP hydrolysis, leading to the dissociation of MinD from the membrane. These interactions give rise to a dynamic pattern of Min protein localization that appears to involve a polymeric state that is designed to create a zone that is permissive to cell division at the mid-point of the cell. The interaction between MinD and the membrane is a critical aspect of this cycle, yet the role of the lipid bilayer in MinD activation, localization and polymerization is not well understood. To probe the role of membrane charge and fluidity on MinD activation and polymerization, we developed a kinetic assay of MinE-stimulated MinD ATPase activity. We found that membrane charge is essential for MinD activation and that differences in membrane fluidity give rise to changes in its activity. Moreover, a burst phase was also observed during the first few minutes of reaction, but only on the most fluid anionic lipid tested. To help determine if the observed membrane-dependent changes in MinD activity are linked to any changes in MinD polymer structure, we have begun to develop a method to identify surface exposed regions of MinD through a combination of covalent labeling and mass spectrometry. Optimization of various steps for the assay has been done, and the assay can be applied to the future characterization of MinD polymer structure. Results from this assay, in combination with those from the kinetic measurements described here, will help to improve understanding about how membrane properties modulate MinD ATPase activity, and how this can influence the Min protein oscillation that is required to ensure normal bacterial cell division.
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Role of the V-ATPase a3 Subunit in Osteoclast Maturation and FunctionOchotny, Noelle Marie 14 January 2014 (has links)
Bone resorption involves osteoclast-mediated acidification via a vacuolar type H+-ATPase (V-ATPase) found in lysosomes and at the ruffled border membrane. V-ATPases are proton pumps that include the a3 subunit, one of four isoforms (a1-a4) in mammals. The a3 isoform is enriched in osteoclasts where it is essential for bone resorption. Over 50% of humans with osteopetrosis have mutations in the a3 subunit and a3 mutations in mouse also result in osteopetrosis. A mouse founder with an osteopetrotic phenotype was identified in an N-ethyl-N-nitrosourea (ENU) mutagenesis screen. This mouse bears a dominant missense mutation in the Tcirg1 gene that encodes the a3 subunit resulting in the replacement of a highly conserved amino acid, arginine 740, with serine (R740S). The heterozygous mice (+/R740S) exhibit high bone density but otherwise have a normal appearance, size and weight. Osteoblast parameters are unaffected whereas osteoclast number and marker expression are increased along with a decreased number of apoptotic osteoclasts. V-ATPases from +/R740S osteoclast membranes have severely reduced proton transport along with wild type levels of ATP hydrolysis, indicating that the R740S mutation uncouples ATP hydrolysis from proton transport. The mutation however has no effect on ruffled border formation or polarization of +/R740S osteoclasts. Mice homozygous for R740S (R740S/R740S) have more severe osteopetrosis than +/R740S mice and die by postnatal day 14. Similarly to the mouse models that lack the a3 subunit (oc/oc and Tcirg1-/-) R740S/R740S osteoclasts do not polarize and lack ruffled border membranes. However R740S/R740S osteoclasts exhibit unique phenotypic traits, including increased apoptosis and defective early stage autophagy. Intracellular and extracellular acidification is absent in R740S/R740S osteoclasts, providing evidence for a requirement for lysosomal acidification for cytoplasmic distribution of key osteoclast enzymes such as TRAP and other important osteoclast phenotypic traits. This work provides evidence that the a3 subunit of V-ATPases and the proton pumping function of a3-containing V-ATPases play a major role in osteoclast survival, maturation and function.
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Role of the V-ATPase a3 Subunit in Osteoclast Maturation and FunctionOchotny, Noelle Marie 14 January 2014 (has links)
Bone resorption involves osteoclast-mediated acidification via a vacuolar type H+-ATPase (V-ATPase) found in lysosomes and at the ruffled border membrane. V-ATPases are proton pumps that include the a3 subunit, one of four isoforms (a1-a4) in mammals. The a3 isoform is enriched in osteoclasts where it is essential for bone resorption. Over 50% of humans with osteopetrosis have mutations in the a3 subunit and a3 mutations in mouse also result in osteopetrosis. A mouse founder with an osteopetrotic phenotype was identified in an N-ethyl-N-nitrosourea (ENU) mutagenesis screen. This mouse bears a dominant missense mutation in the Tcirg1 gene that encodes the a3 subunit resulting in the replacement of a highly conserved amino acid, arginine 740, with serine (R740S). The heterozygous mice (+/R740S) exhibit high bone density but otherwise have a normal appearance, size and weight. Osteoblast parameters are unaffected whereas osteoclast number and marker expression are increased along with a decreased number of apoptotic osteoclasts. V-ATPases from +/R740S osteoclast membranes have severely reduced proton transport along with wild type levels of ATP hydrolysis, indicating that the R740S mutation uncouples ATP hydrolysis from proton transport. The mutation however has no effect on ruffled border formation or polarization of +/R740S osteoclasts. Mice homozygous for R740S (R740S/R740S) have more severe osteopetrosis than +/R740S mice and die by postnatal day 14. Similarly to the mouse models that lack the a3 subunit (oc/oc and Tcirg1-/-) R740S/R740S osteoclasts do not polarize and lack ruffled border membranes. However R740S/R740S osteoclasts exhibit unique phenotypic traits, including increased apoptosis and defective early stage autophagy. Intracellular and extracellular acidification is absent in R740S/R740S osteoclasts, providing evidence for a requirement for lysosomal acidification for cytoplasmic distribution of key osteoclast enzymes such as TRAP and other important osteoclast phenotypic traits. This work provides evidence that the a3 subunit of V-ATPases and the proton pumping function of a3-containing V-ATPases play a major role in osteoclast survival, maturation and function.
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Investigation of the Effect of Changes in Lipid Bilayer Properties on the Activity of the Bacterial Cell Division Regulator Protein MinDAyed, Saud January 2012 (has links)
Bacterial cell division requires formation of the cytokinetic cell division septum at the mid-cell position, a process that is determined by three Min proteins; MinC, MinD and MinE. Regulation of cell division by Min proteins occurs via a multi-step process involving interactions between various Min proteins, as well as the membrane. In this cycle, ATP-bound MinD binds to the membrane surface where it can recruit MinC to inhibit formation of the cell division septum. MinE binding to this complex displaces MinC and stimulates ATP hydrolysis, leading to the dissociation of MinD from the membrane. These interactions give rise to a dynamic pattern of Min protein localization that appears to involve a polymeric state that is designed to create a zone that is permissive to cell division at the mid-point of the cell. The interaction between MinD and the membrane is a critical aspect of this cycle, yet the role of the lipid bilayer in MinD activation, localization and polymerization is not well understood. To probe the role of membrane charge and fluidity on MinD activation and polymerization, we developed a kinetic assay of MinE-stimulated MinD ATPase activity. We found that membrane charge is essential for MinD activation and that differences in membrane fluidity give rise to changes in its activity. Moreover, a burst phase was also observed during the first few minutes of reaction, but only on the most fluid anionic lipid tested. To help determine if the observed membrane-dependent changes in MinD activity are linked to any changes in MinD polymer structure, we have begun to develop a method to identify surface exposed regions of MinD through a combination of covalent labeling and mass spectrometry. Optimization of various steps for the assay has been done, and the assay can be applied to the future characterization of MinD polymer structure. Results from this assay, in combination with those from the kinetic measurements described here, will help to improve understanding about how membrane properties modulate MinD ATPase activity, and how this can influence the Min protein oscillation that is required to ensure normal bacterial cell division.
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Regulation of antiviral responses by RIG-I dissociation from dsRNA / dsRNAからのRIG-I解離による抗ウイルス反応の調節Im, Jung Hyun 24 November 2023 (has links)
京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24984号 / 生博第513号 / 新制||生||68(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 野田 岳志, 教授 朝長 啓造, 教授 今吉 格 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM
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