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221	CRYSTAL STRUCTURE DETERMINATION OF METALLOPROTEINS:PEPTIDE DEFORMYLASE, FIXL HEME DOMAIN, MONOMETHYLAMINE METHYLTRANSFERASE, AND CARBON MONOXIDE DEHYDROGENASE Hao, Bing 20 December 2002 (has links) No description available. Biophysics, General Crystal structure Metalloproteins Peptide deformylase BjFixLH Monomethylamine methyltransferase Carbon monoxide dehydrogenase
222	Precipitate Phases in Several High Temperature Shape Memory Alloys Yang, Fan 19 December 2012 (has links) No description available. Materials Science shape memory alloys precipitation crystal structure high angle annular dark field
223	Toward the Crystal Structure of a Type III Antifreeze Protein From Ocean Pout, Macrozoarces Americanus Bubanko, Steven A. 08 1900 (has links) <p> Four stucturally distinct types of macromolecular antifreezes have been previously isolated from the sera of polar marine fish. When the water temperature surrounding these organisms drops below -0.7°C, the freezing point of their bodily fluids, any contact with surrounding ice will nucleate internal ice crystal growth. The antifreeze proteins (AFPs) and antifreeze glycoproteins (AFGPs) synthesized by the fish act to inhibit the growth of existing ice crystals in their sera through direct adsorption to the ice lattice. The α-helical structure of type I AFP from winter flounder has been solved to atomic resolution and its mechanism of ice binding has been proposed. The NMR solution structure of a type III AFP from ocean pout has identified proteins in this class to exist in a β-sandwich conformation, however their mechanism of action remains uncertain.</p> <p> To facilitate the pursuit of an x-ray crystal structure solution, we subcloned the gene for a type III AFP (HPLC6) into pET15b and expressed recombinant His-rHPLC6 AFP in E. coli. Purified rmHPLC6 product has been successfully crystallized, and heavy atom soaks were performed in order to attempt a structure solution by multiple isomorphous replacement. The lone tyrosine in this recombinant AFP has been successfully derivatized in solution with iodine, and the modified protein was crystallized. In order to optimize the measurement of anomalous scattering information, modifications to our data collection system were required. Cryocrystallography techniques were employed to improve the quality of collected data.</p> <p> The expression, purification, crystallization and optimized data collection on an iodine-derivatized type III AFP from ocean pout will be presented here. This work has been instrumental in providing the high quality x-ray data required to solve the crystal structure to atomic resolution. Future examination of the solved structure will promote an increased understanding of the ice-binding mechanism exhibited by this class of proteins.</p> / Thesis / Master of Science (MSc)
224	Atomic Force Microscopy Study of Clay Mineral Dissolution Bickmore, Barry Robert 03 February 2000 (has links) An integrated program has been developed to explore the reactivity of 2:1 phyllosilicates (biotite and the clays montmorillonite, hectorite, and nontronite) with respect to acid dissolution using in situ atomic force microscopy (AFM). Three techniques are described which make it possible to fix these minerals and other small particles to a suitable substrate for examination in the fluid cell of the atomic force microscope. A suite of macros has also been developed for the Image SXM image analysis environment which make possible the accurate and consistent measurement of the dimensions of clay particles in a series of AFM images, so that dissolution rates can be measured during a fluid cell experiment. Particles of biotite and montmorillonite were dissolved, and their dissolution rates normalized to their reactive surface area, which corresponds to the area of their edge surfaces (A<sub>e</sub>). The A<sub>e</sub>-normalized rates for these minerals between pH 1-2 are all ~10E<sup>-8</sup> mol/m<sup>2</sup>*s, and compare very well to other A<sub>e</sub>-normalized dissolution rates in the literature. Differences between the A<sub>e</sub>-normalized rates for biotite and the BET-normalized rates (derived from solution chemical studies) found in the literature can be easily explained in terms of the proportion of edge surface area and the formation of leached layers. However, the differences between the A<sub>e</sub>-normalized montmorillonite rates and the literature values cannot be explained the same way. Rather, it is demonstrated that rates derived from solution studies of montmorillonite dissolution have been affected by the colloidal behavior of the mineral particles. Finally, the dissolution behavior of hectorite (a trioctahedral smectite) and nontronite ( a dioctahedral smectite) were compared. Based on the differential reactivity of their crystal faces, a model of their surface atomic structures is formulated using Hartman-Perdock crystal growth theory, which explains the observed data if it is assumed that the rate-determining step of the dissolution mechanism is the breaking of connecting bonds between the octahedral and tetrahedral sheets of the mineral structure. / Ph. D. HCl vermiculite kaolinite sapphire AFM polyethyleneimine crystal structure periodic bond chain phlogopite SFM biotite montmorillonite Tempfix
225	Building up co-crystals: structural motif consistencies across families of co-crystals Seaton, Colin C. 01 May 2022 (has links) Yes / The creation of co-crystals as a route to creating new pharmaceutical phases with modified or defined physicochemical properties is an area of intense research. Much of the current research has focused on creating new phases for numerous active pharmaceutical ingredients (APIs) to alter physical properties such as low solubilities, enhancing processability or stability. Such studies have identified suitable co-formers and common bonding motifs to aid with the design of new co-crystals but understanding how the changes in the molecular structure of the components are reflected in the packing and resulting properties is still lacking. This lack of insight means that the design and growth of new co-crystals is still a largely empirical process with co-formers selected and then attempts to grow the different materials undertaken to evaluate the resulting properties. This work will report on the results of a combination of crystal structure database analysis with computational chemistry studies to identify what structural features are retained across a selection of families of co-crystals with common components. The competition between different potential hydrogen bonding motifs was evaluated using ab initio quantum mechanical calculations and this was related to the commonality in the packing motifs when observed. It is found while the stronger local bonding motifs are often retained within systems, the balance of weaker long-range packing forces gives rise to many subtle shifts in packing leading to greater challenges in the prediction of final crystal structures. Co-crystals Crystal engineering Crystal structure prediction Hydrogen bonding Intermolecular interactions
226	Mechanistic Studies of the Roles of the Transcriptional Activator ExsA and Anti-activator Protein ExsD in the Regulation of the Type Three Secretion System in Pseudomonas aeruginosa Shrestha, Manisha 19 June 2018 (has links) Pseudomonas aeruginosa is a ubiquitous opportunistic pathogen that is a substantial threat, particularly in hospital settings, causing severe infections in immunocompromised patients that may lead to death. Pseudomonas aeruginosa harbors a multitude of virulence factors that enable this pathogen to establish both acute and chronic infections in humans. A key determinant of acute infections is a hollow molecular needle structure used for injecting toxins into a host cell, called the type three secretion system (T3SS). The secretion machinery itself is highly complex and, together with the specific secreted factors, requires expression of more than 30 genes. Due to the high energy cost of its synthesis to the organism this system is highly regulated to finely time gene expression to coincide with host contact. ExsA, a member of the AraC-type transcription factor family, is the main transcriptional activator of all the genes necessary for expression of the T3SS. Members of the AraC family are characterized by the presence of two helix-turn-helix (HTH) motifs, which bind to the promoter DNA and activate transcription. ExsA uses its HTH containing C-terminal domain (CTD) to regulate gene expression from 10 different promoters. The N-terminal domain (NTD) of ExsA mediates dimerization and regulation of ExsA-activity. While most AraC-type activators are regulated by a small molecule ligands, ExsA is regulated by another protein, ExsD. As part of a four-protein signaling cascade, ExsD interacts directly with ExsA to prevent transcription of T3SS-associated genes under non-inducing conditions prior to host cell contact. The entire regulatory cascade includes of two additional proteins, ExsC and ExsE. ExsA, ExsC, ExsD, and ExsE follow a partner-switching mechanism to link expression of the secretion system with host cell contact. Our laboratory is working to understand this unique signaling mechanism by determining the molecular basis for the regulation of this important virulence factor. Previous studies in the laboratory have solved the structures of ExsE, ExsC and ExsD, and shed light on how these proteins interact and compete for overlapping binding sites. However, it is still unclear as to how the ExsA and ExsD interact and thus how regulation is mediated at the molecular level. In the presented study, we sought to map the molecular interface between ExsA and ExsD. First, the crystal structure of ExsA-NTD is presented wherein the dimerization interface of the protein was identified. Two of the well-studied AraC-type proteins, AraC and ToxT crystal structures have been solved by others in the presence of their respective ligands. Residues that were involved in ligand binding in AraC and ToxT were aligned with the residues in ExsA and analyzed for interaction with ExsD. However, this canonical binding pocket appeared to be not involved in the interaction between ExsA and ExsD. Structure directed site-specific mutagenesis was carried out to construct many different variants of ExsD and ExsA. Thus constructed variants were purified and analyzed in a functional assay. Using this approach, we were able to identify regions on ExsD and ExsA that are crucial for the interaction and for the regulation of ExsA-dependent transcription. It turns out that backbone interactions between the amino-terminal residues of ExsD and the beta-barrel region of the ExsA-NTD are pivotal. This result explains how ExsA and ExsC compete for ExsD binding, since both target the same regions on ExsD. / PHD / Pseudomonas aeruginosa is an opportunistic pathogen that is notorious for causing severe infections in immunocompromised individuals. Acute Pseudomonas aeruginosa infections are characterized by immediate adverse effects. An initial acute infection may become chronic, leading to long-term morbidity and mortality in affected individuals. During the initial stages of infection P. aeruginosa uses the type three secretion system, a syringe-like structure, to puncture the host cell and inject potent toxins. The activation of the genes required for forming this structure is tightly controlled by an activator protein, ExsA. When P.aeruginosa is not invading a host, ExsA is inhibited by another protein called ExsD, to prevent the needless production of the secretion apparatus. The presented work explores the mechanism of how ExsD achieves this inhibition of ExsA. This information is of potential biomedical interest because a clear understanding of the molecular basis for the interaction could inform the development of a small-molecule mimic of ExsD to be used in therapy. In Chapter 2 we report the structure of the domain of ExsA that is known to bind ExsD. Also, in this chapter and more so in Chapter 3, we performed a detailed analysis of potential interacting regions and ultimately succeeded in identifying key interacting regions in both ExsA and ExsD. transcription activator type three secretion system pseudomonas aeruginosa Crystal structure site-directed mutagenesis
227	Rationalization of Racemate Resolution: Predicting Spontaneous Resolution through Crystal Structure Prediction. Kendrick, John, Gourlay, Matthew D., Leusen, Frank J.J. 2009 July 1914 (has links) No / Crystal structure prediction simulations are reported on 5-hydroxymethyl-2-oxazolidinone and 4-hydroxymethyl-2-oxazolidinone to establish the feasibility of predicting the spontaneous resolution of racemates of small organic molecules. It is assumed that spontaneous resolution occurs when the enantiomorph is more stable than the racemic solid. The starting point is a gas phase conformational search to locate all low-energy conformations. These conformations are used to predict the possible crystal structures of 5- and 4-hydroxymethyl-2-oxazolidinone. In both cases, the racemic crystal structure is predicted to have the lowest energy. The energy differences between the lowest-energy racemic solids and the lowest-energy enantiomorphs are 0.2 kcal mol-1 for 5-hydroxymethyl-2-oxazolidinone and 0.9 kcal mol-1 for 4-hydroxymethyl-2-oxazolidinone. In the case of 4-hydroxymethyl-2-oxazolidinone, where the racemic crystal is known to be more stable and the experimental crystal structures of both the racemate and the enantiomorph are available, the simulation results match the observed data. For 5-hydroxymethyl-2-oxazolidinone, where only enantiopure crystals are observed experimentally, the known experimental structure is found 1.6 kcal mol-1 above the lowest-energy predicted structure. This work shows that it is possible to predict whether the racemate of a small chiral molecule can be resolved spontaneously, although further advances in the accuracy of lattice energy calculations are required. Lattice energy Conformation Gas phase Organic molecule Digital simulation Crystal structure Structure resolution Racemates
228	Crystal Structure Prediction and Isostructurality of Three Small Molecule Asmadi, Aldi, Kendrick, John, Leusen, Frank J.J. January 2010 (has links) No / A crystal structure prediction (CSP) study of three small, rigid and structurally related organic compounds (differing only in the position and number of methyl groups) is presented. A tailor-made force field (TMFF; a non-transferable force field specific for each molecule) was constructed with the aid of a dispersion-corrected density functional theory method (the hybrid method). Parameters for all energy terms in each TMFF were fitted to reference data generated by the hybrid method. Each force field was then employed during structure generation. The experimentally observed crystal structures of two of the three molecules were found as the most stable crystal packings in the lists of their force-field-optimised structures. A number of the most stable crystal structures were re-optimised with the hybrid method. One experimental crystal structure was still calculated to be the most stable structure, whereas for another compound the experimental structure became the third most stable structure according to the hybrid method. For the third molecule, the experimentally observed polymorph, which was found to be the fourth most stable form using its TMFF, became the second most stable form. Good geometrical agreements were observed between the experimental structures and those calculated by both methods. The average structural deviation achieved by the TMFFs was almost twice that obtained with the hybrid method. The TMFF approach was extended by exploring the accuracy of a more general TMFF (GTMFF), which involved fitting the force-field parameters to the reference data for all three molecules simultaneously. This GTMFF was slightly less accurate than the individual TMFFs but still of sufficient accuracy to be used in CSP. A study of the isostructural relationships between these molecules and their crystal lattices revealed a potential polymorph of one of the compounds that has not been observed experimentally and that may be accessible in a thorough polymorph screen, through seeding, or through the use of a suitable tailor-made additive. Crystal Structure Prediction Molecular Mechanics Crystal Engineering Density Functional Calculations Lattice Energy Lanscapes Polymorphism
229	A major advance in crystal structure prediction. Neumann, M.A., Leusen, Frank J.J., Kendrick, John 20 February 2008 (has links) No / A crystal ball? A new method for crystal structure prediction combines a tailor-made force field with a density functional theory method incorporating a van der Waals correction for dispersive interactions. In a blind test, the method predicts the correct crystal structure for all four compounds, one of which is a cocrystal. The picture shows the predicted structure of one of the compounds in green and the experimental structure in blue. REF 2014 Crystal structure prediction Crystal engineering Density functional calculations Molecular mechanics Polymorphism
230	Development of selective DprE1 inhibitors: Design, synthesis, crystal structure and antitubercular activity of benzothiazolylpyrimidine-5-carboxamides Chikhale, R., Menghani, S., Babu, R., Bansode, Ratnadeep V., Bhargavi, G., Karodia, Nazira, Rajasekharan, M.V., Paradkar, Anant R, Khedekar, Pramod 26 May 2015 (has links) No / Decaprenylphosphoryl-b-d-ribose 20-epimerase (DprE1) is a potential drug target for development of antitubercular agents. Structure based drug discovery approach yielded twenty novel derivatives of benzothiazolylpyrimidine-5-carboxamides (7a–t) which were synthesised by three component one pot reaction involving benzothiazolyl oxobutanamide, thiourea and substituted aromatic benzaldehydes. These derivatives were evaluated for antitubercular activity to determine MIC and compound 7a, 7e, 7f and 7o were found to be potentially active against Mycobacterium tuberculosis (H37Rv). Log P of these compounds was found to be between 2.0 and 3.0 making them suitable for oral dosing. DprE1 selectivity and pharmacokinetic studies were carried out for these compounds of which 7a and 7o were found to be highly selective and bioavailability was found to be above 52% by oral dose. Crystal structure of 7a was studied and molecular packing was determined, it exhibited a triclinic crystal lattice arrangement having hydrogen bonded dimeric arrangement. Drug receptor interactions were studied which exhibited docking in the active site of receptor with hydrogen bonding, hydrophobic interactions, vdW interactions with amino acid residues such as Cys387, Asn385, Lys418, Tyr314, Gln334 and Lys367 respectively. 3D QSAR analysis was carried out by kNN-MFA method to determine and develop theoretical model, best suitable model was found to be based on Simulated Annealing k-Neariest Neighbour Molecular Field Analysis (SA kNN-MFA). The model provided with hydrophobic descriptors in positive side indicating the need of bulky groups, steric and electronegative descriptors in negative coordinates hints with contribution by the electronegative substitutions as favourable and desirable moieties for enhancing the activity. The q2, q2_se and Pred_r2se were found to be 0.5000, 0.6404 and 1.0094 respectively. A pharmacophore model was generated which suggested for necessity of aromatic, aliphatic carbon centre and hydrogen bond donor for development of newer DprE1 selective inhibitors. / Council of Scientific and Industrial Research DprE1 inhibitors Crystal structure Molecular docking 3D-QSAR Pharmacphore modelling Antitubercular activity Benzothiazole

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