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Structural features and functional residues important for the activity of an unusual membrane bound O-acyltransferaseTran, Tam Nguyen Thu January 1900 (has links)
Doctor of Philosophy / Biochemistry and Molecular Biophysics / Timothy P. Durrett / The membrane bound O-acyltransferase (MBOAT) family contains multi-pass membrane proteins that add fatty acids to different compounds. Despite their importance in economic activity and human health, little is known about the localization of the active site and regions important for determining substrate specificity of MBOATs. Euonymus alatus diacylglycerol acetyltransferase (EaDAcT) is the only known MBOAT enzyme that exhibits a high preference for acetyl-CoA, the shortest possible acyl-CoA. EaDAcT catalyzes the transfer of the acetate group from acetyl-CoA to the sn-3 position of diacylglycerol to form 3-acetyl-1,2-diacyl-sn-glycerol. Our goal was to investigate the structural features and the amino acid residues that define substrate specificity of EaDAcT to provide insights into the mechanism by which MBOAT family controls substrate selection. By mapping the membrane topology of EaDAcT we obtained the first experimentally determined topology model for a plant MBOAT. The EaDAcT model contains four transmembrane domains with both the N- and C- termini oriented toward the endoplasmic reticulum lumen. The MBOAT signature region including the putative active site His-257 of the protein is embedded in the third transmembrane domain close to the interface between the membrane and the cytoplasm. In order to identify amino acid residues important for acetyltransferase activity, we isolated and characterized orthologs of EaDAcT from other acetyl-TAG producing plants. Among them, the acetyltransferase from Euonymus fortunei possessed the highest activity in vivo and in vitro. Mutagenesis of conserved residues of DAcTs revealed that Ser-253, His-257 and Asp-258 are essential for enzyme activity of EaDAcT, suggesting their involvement in the enzyme catalysis. Alteration of residues unique to acetyltransferases did not alter the acyl donor specificity of EaDAcT, implying that multiple amino acids are important for substrate recognition. Together, this work identifies the structural features of EaDAcT and offers an initial view of the amino acids important for activity of the enzyme.
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Topology and Dynamics of Macromolecular Aggregates Studied by Pressure NMRAl-Abdul-Wahid, Mohamed Sameer 06 December 2012 (has links)
The topology and dynamics of biomolecules are intricately linked with their biological function. The focus of this thesis is the NMR-based measurement of topology and dynamics in biomolecular systems, and methods of measuring immersion depth and orientation of membrane-associated molecules.
In detergent micelles and lipid bilayers, the local concentrations of hydrophobic and hydrophilic molecules are a function of their bilayer immersion depth. For paramagnetic molecular oxygen or metal cations, the magnitudes of the associated paramagnetic isotropic contact shifts and relaxation rate enhancements (PREs) are therefore depth-dependent. NMR measurements of these effects reveal the immersion depth of bilayer- or detergent-associated molecules.
This work first explores transbilayer oxygen solubility and thermodynamics, as measured from contact shifts and PREs of the constituent lipid molecules in the presence of 30 bar oxygen. Contact shifts revealed the transmembrane O2 solubility profile spans a factor of seven across the bilayer, while PREs indicated that oxygen partitioning into bilayers and dodecylphosphocholine (DPC) micelles is entropically driven.
Next, this work describes how paramagnetic effects from molecular oxygen and Ni(II) cations may be employed to study the immersion depth and topology of drug and protein molecules in DPC micelles. In one study, the positioning of the amphipathic drug imipramine in micelles was determined from O2- and Ni(II)-induced contact shifts. A second study, relying solely on O2-induced PREs, determined the tilt angles and micelle immersion depths of the two alpha helices in a monomeric mutant of the membrane protein phospholamban. A third study utilized 19F NMR to explore the importance of juxtamembraneous tryptophans on the topology of the membrane protein synaptobrevin, via O2-induced contact shifts and solvent-induced isotope shifts of a juxtamembraneous 19F-phenylalanine. Comparison of synaptobrevin constructs with zero, one, and two juxtamembraneous tryptophans revealed that while one tryptophan is sufficient to ‘anchor’ the protein in micelle, the addition of a second tryptophan dampens local dynamics.
These solution state NMR studies demonstrate how paramagnetic effects from dissolved oxygen, complemented with measurements of local water exposure, provide detailed, accurate descriptions of membrane immersion depth and topology. These techniques are readily extended to the study of a wide range of biomolecules.
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Topology and Dynamics of Macromolecular Aggregates Studied by Pressure NMRAl-Abdul-Wahid, Mohamed Sameer 06 December 2012 (has links)
The topology and dynamics of biomolecules are intricately linked with their biological function. The focus of this thesis is the NMR-based measurement of topology and dynamics in biomolecular systems, and methods of measuring immersion depth and orientation of membrane-associated molecules.
In detergent micelles and lipid bilayers, the local concentrations of hydrophobic and hydrophilic molecules are a function of their bilayer immersion depth. For paramagnetic molecular oxygen or metal cations, the magnitudes of the associated paramagnetic isotropic contact shifts and relaxation rate enhancements (PREs) are therefore depth-dependent. NMR measurements of these effects reveal the immersion depth of bilayer- or detergent-associated molecules.
This work first explores transbilayer oxygen solubility and thermodynamics, as measured from contact shifts and PREs of the constituent lipid molecules in the presence of 30 bar oxygen. Contact shifts revealed the transmembrane O2 solubility profile spans a factor of seven across the bilayer, while PREs indicated that oxygen partitioning into bilayers and dodecylphosphocholine (DPC) micelles is entropically driven.
Next, this work describes how paramagnetic effects from molecular oxygen and Ni(II) cations may be employed to study the immersion depth and topology of drug and protein molecules in DPC micelles. In one study, the positioning of the amphipathic drug imipramine in micelles was determined from O2- and Ni(II)-induced contact shifts. A second study, relying solely on O2-induced PREs, determined the tilt angles and micelle immersion depths of the two alpha helices in a monomeric mutant of the membrane protein phospholamban. A third study utilized 19F NMR to explore the importance of juxtamembraneous tryptophans on the topology of the membrane protein synaptobrevin, via O2-induced contact shifts and solvent-induced isotope shifts of a juxtamembraneous 19F-phenylalanine. Comparison of synaptobrevin constructs with zero, one, and two juxtamembraneous tryptophans revealed that while one tryptophan is sufficient to ‘anchor’ the protein in micelle, the addition of a second tryptophan dampens local dynamics.
These solution state NMR studies demonstrate how paramagnetic effects from dissolved oxygen, complemented with measurements of local water exposure, provide detailed, accurate descriptions of membrane immersion depth and topology. These techniques are readily extended to the study of a wide range of biomolecules.
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Membrane Domain of Plant 3-Hydroxy-3-Methylglutaryl Coenzyme A Reductase: Targeting, Topology, and FunctionDenbow, Cynthia J. 06 May 1997 (has links)
The rate limiting step in isoprenoid biosynthesis is catalyzed by 3-hydroxy-3-methylglutaryl CoA reductase (HMGR, EC 1.1.1.34). In plants, HMGR is encoded by small gene families whose members are differentially expressed. In tomato, hmg2 was previously isolated and sequenced. We report the isolation and sequence analysis of a clone (pCD4) encompassing exon I of tomato hmg1 which encodes the putative membrane domain. Sequence comparisons of plant HMGR proteins reveal two hydrophobic stretches within the amino terminus which are highly conserved among species. Using in vitro transcription and translation systems, the membrane domain structure of two tomato HMGR isoforms, HMG1 and HMG2, were analyzed. Results from these experiments reveal that tomato HMGRs are targeted to microsomal membranes in a cotranslational fashion that does not involve cleavage of an N-terminal targeting peptide. Membrane topography of HMGR was revealed by protease protection studies, indicating that both tomato HMGRs span the membrane two times such that both the C- and N-termini are located within the cytosol. HMG2 but not HMG1 was glycosylated in the in vitro system. Deletion of the hmg1 5' untranslated regions and sequences encoding the first six highly charged amino acids resulted in inefficient translation in vitro. However, targeting to microsomes was unchanged. HMG1 membrane domain was tagged with a FLAG epitope to facilitate in vivo studies. Agrobacterium-mediated transformation was used to introduce the tagged hmg1 gene into two Nicotiana tabacum cell lines, BY-2 and KY-14. The slow growth kinetics of KY-14 prevented effective recovery of transformed lines, however, Northern analyses of BY-2 showed that the hmg1 transgene was expressed. Comparisons of BY-2 and KY-14 revealed differences in defense responses to elicitor treatment. BY-2 cells showed minimal defense capabilities, whereas KY-14 cells were rapidly induced as indicated by increased HMGR enzyme activity and browning of the cells. HMGR enzyme activity was decreased in both KY-14 and BY-2 cells following sterol treatment, but the reduction was more pronounced in KY-14 cells. Thus transgenic BY-2 cells may be useful in future in vivo immunolocalization studies, but analyses of HMGR transcriptional regulation and regulated degradation will require use of the more responsive KY-14 cells.. / Ph. D.
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