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Rediscovering Arsenoacetic AcidWilson, Peter Stanley January 2009 (has links)
Arsonoacetic acid, H₂O₃As¹CH₂COOH, and arsenoacetic acid, punitively [AsVCH₂COOH]₂ have been synthesised according to historical literature methods, and have been characterised using modern techniques. Arsonoacetic acid was shown by an X-ray crystal structure analysis to be a molecular species with an extensive hydrogen bonding network in the crystal. Arsenoacetic acid proved to be more enigmatic. Electrospray mass spectra suggested it consisted of a mixtures of rings (RAs)n, n = 3-11, with n = 6 dominating. This was partly confirmed by a crystal structure of (AsCH₂COOH)₆ (as the pyridine solvate). On the other hand, ¹H and ¹³C NMR gave spectra that indicated only a single component for arsenoacetic acid. The formation of crystals of the high temperature phase of elemental sulfur, β-S8, at ambient temperature is also discussed.
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Structural Studies of O-antigen polysaccharides, Synthesis of 13C-labelled Oligosaccharides and Conformational Analysis thereof, using NMR SpectroscopyOlsson, Ulrika January 2008 (has links)
<p>In order to understand biological processes, to treat and diagnose diseases, find appropriate vaccines and to prevent the outbreak of epidemics, it is essential to obtain more knowledge about carbohydrate structures. This thesis deals with structure and conformation of carbohydrates, analysed by NMR spectroscopy and MD simulations.In the first two papers, the structures of O-antigen polysaccharides (PS) from two different <i>E. coli</i> bacteria were determined using NMR spectroscopy. The O-antigenic PS from <i>E. coli</i> O152 (paper I) consists of branched pentasaccharide repeating units, built up of three different carbohydrate residues and a phosphodiester, whilst the repeating unit of the O-antigen from <i>E. coli</i> O176 (paper II) is built up of a linear tetrasaccharide consisting of two different monosaccharides.</p><p>In papers III and IV, the conformational analysis of different disaccharides is described. Conformational analysis was performed using NMR spectroscopy and MD simulations (paper IV). In paper III four different glucobiosides were studied using coupling constants and Karplus-type relationships. By use of specific <sup>13</sup>C isotopically labelled derivatives, additional coupling constants were obtained and the number of possible torsion angles was reduced by half. In paper IV, we examine the conformations of two disaccharides that are part of an epitope of malignant cells. From NOE and T-ROE experiments, short proton-proton distances around the glycosidic linkage were estimated. Furthermore, interpretation of the extracted coupling constants using Kaplus relationships gave the values of the torsion angles. As in paper III, isotopically labelled compounds were synthesised in order to enhance the sensitivity of the analysis. Finally, MD simulations were performed and the results were compared with results from NMR data.</p>
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OmniMerge: A Systematic Approach to Constrained Conformational SearchTucker-Kellogg, Lisa, Lozano-Pérez, Tomás 01 1900 (has links)
OmniMerge performs a systematic search to enumerate all conformations of a molecule (at a given level of torsion-angle resolution) that satisfy a set of local geometric constraints. Constraints would typically come from NMR experiments, but applications such as docking or homology modeling could also give rise to similar constraints. The molecule to be searched is partitioned into small subchains so that the set of possible conformations for the whole molecule may be constructed by merging the feasible conformations for the subchain parts. However, instead of using a binary tree for straightforward divide-and-conquer, OmniMerge defines a sub-problem for every possible subchain of the molecule. Searching every subchain provides a counter-intuitive advantage: with every possible subdivision available for merging, one may choose the most favorable merge for each subchain, particularly for the bottleneck chain(s). Improving the bottleneck step may therefore cause the whole search to be completed more quickly. Finally, to discard infeasible conformations more rapidly, OmniMerge filters the solution set of each subchain based on compatibility with the solutions sets of all overlapping subchains. These two innovations—choosing the most favorable merges and enforcing consistency between overlapping subchains—yield significant improvements in run time. By determining the extent of structural variability permitted by a set of constraints, OmniMerge offers the potential to aid error analysis and improve confidence for NMR results on peptides and moderate-sized molecules. / Singapore-MIT Alliance (SMA)
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A Regio- and Stereodivergent Route to All Isomers of vic-Amino AlcoholsOlofsson, Berit January 2002 (has links)
The first part of this thesis describes a synthetic strategythat provides all eight possible isomers of a given vic-aminoalcohol starting from vinylepoxides. The value of a generalroute is evident, as several isomers are needed ininvestigations of structure-activity relationships forpharmacologically active derivatives, and for optimizing theperformance of chiral ligands containing the amino alcoholmoiety. Vinylepoxides, obtained in high enantiomeric excess, werering-opened both with inversion and retention ofstereochemistry, delivering two diastereomeric amino alcoholswith high regio- and stereoselectivity. Via ring-closure toaziridines and subsequent regioselective ring-opening withsuitable oxygen nucleophiles, the two remaining amino alcoholswere selectively achieved. Within this study, two efficient protocols for theregioselective and stereospecific aminolysis of vinylepoxideshave been presented. Comparedto previous methods, theseprocedures use milder reaction conditions, shorter reactiontimes, generally give higher yields and are applicable to alarger set of substrates. Furthermore, the ring-closure ofvic-amino alcohols to the corresponding N-H vinylaziridines hasbeen investigated. Three routes have been found useful, whichone is preferred depends on substrate and scale. In the second part of the thesis, the synthetic strategy isapplied on the synthesis of Sphingosine and its regio- andstereoisomers. Moreover, a rapid way of determining relativeconfiguration of vic-amino alcohols is described, which shouldbe of substantial use when amino alcohols are formed bydiastereoselective reactions. amino alcohols, vinylepoxides, vinylaziridines, oxazolines,oxazolidinones, ring-opening, regioselective,diastereoselective, sphingosine, configuration, NMRspectroscopy.
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Structural Studies of O-antigen polysaccharides, Synthesis of 13C-labelled Oligosaccharides and Conformational Analysis thereof, using NMR SpectroscopyOlsson, Ulrika January 2008 (has links)
In order to understand biological processes, to treat and diagnose diseases, find appropriate vaccines and to prevent the outbreak of epidemics, it is essential to obtain more knowledge about carbohydrate structures. This thesis deals with structure and conformation of carbohydrates, analysed by NMR spectroscopy and MD simulations.In the first two papers, the structures of O-antigen polysaccharides (PS) from two different E. coli bacteria were determined using NMR spectroscopy. The O-antigenic PS from E. coli O152 (paper I) consists of branched pentasaccharide repeating units, built up of three different carbohydrate residues and a phosphodiester, whilst the repeating unit of the O-antigen from E. coli O176 (paper II) is built up of a linear tetrasaccharide consisting of two different monosaccharides. In papers III and IV, the conformational analysis of different disaccharides is described. Conformational analysis was performed using NMR spectroscopy and MD simulations (paper IV). In paper III four different glucobiosides were studied using coupling constants and Karplus-type relationships. By use of specific 13C isotopically labelled derivatives, additional coupling constants were obtained and the number of possible torsion angles was reduced by half. In paper IV, we examine the conformations of two disaccharides that are part of an epitope of malignant cells. From NOE and T-ROE experiments, short proton-proton distances around the glycosidic linkage were estimated. Furthermore, interpretation of the extracted coupling constants using Kaplus relationships gave the values of the torsion angles. As in paper III, isotopically labelled compounds were synthesised in order to enhance the sensitivity of the analysis. Finally, MD simulations were performed and the results were compared with results from NMR data.
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Exploring the structure of oligo- and polysaccharides : Synthesis and NMR spectroscopy studiesJonsson, Hanna January 2010 (has links)
A deeper understanding of the diversity of carbohydrates and the many applications of oligo- and polysaccharides found in nature are of high interest. Many of the processes involving carbohydrates affect our everyday life. This thesis is based on six papers all contributing to an extended perspective of carbohydrate property and functionality. An introduction to carbohydrate chemistry together with a presentation of selected carbohydrate synthesis and analysis methods introduces the reader to the research field. The first paper is an NMR spectroscopy reinvestigation of the structures of the O-antigens from the lipopolysaccharides (LPS) of Shigella dysenteriae type 3 and Escherichia coli O124. The repeating units were concluded to be built of identical branched pentasaccharides now with the correct anomeric configurations. Paper II is a structural investigation of the O-antigen from the LPS of E. coli O74 which is built of branched tetrasaccharide repeating units including the uncommon monosaccharide d-Fuc3NAc. Paper III is a conformational study of a rhamnose derivative, using NMR spectroscopy and X-ray crystallography. The benzoyl ester group positioned at C4 prefers an “eclipsed” conformation in the crystal as well as in solution. The use of site-specifically 13C-labeled compounds in conformational studies is discussed in Papers IV and V. The disaccharide α-L-Rhap-(1→2)-α-L-Rhap-OMe was synthesized together with two 13C-isotopologues and studied with NMR spectroscopy to give seven J-couplings related to torsion angles φ and ψ. The trisaccharide α-L-Rhap-(1→2)[α-L-Rhap-(1→3)]-α-L-Rhap-OMe was synthesized with 13C-labeling at two positions which presented a solution to a problem of overlapping signals in the 1H NMR spectrum. The site-specific labeling also facilitated the measurement of two 3JCC and two 2JCH coupling constants. Finally, chapter 6 gives a short introduction to glycosynthase chemistry and discusses the synthesis of α-glycosyl fluorides. A novel cyclic heptasaccharide was synthesized from α-laminariheptaosyl fluoride using a mutant of the enzyme laminarase 16A and subsequently analyzed by NMR spectroscopy. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 4: Manuscript. Paper 5: Manuscript.
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On the mechanism of Urea-induced protein denaturationLindgren, Matteus January 2010 (has links)
It is well known that folded proteins in water are destabilized by the addition of urea. When a protein loses its ability to perform its biological activity due to a change in its structure, it is said to denaturate. The mechanism by which urea denatures proteins has been thoroughly studied in the past but no proposed mechanism has yet been widely accepted. The topic of this thesis is the study of the mechanism of urea-induced protein denaturation, by means of Molecular Dynamics (MD) computer simulations and Nuclear Magnetic Resonance (NMR) spectroscopy. Paper I takes a thermodynamic approach to the analysis of protein – urea solution MD simulations. It is shown that the protein – solvent interaction energies decrease significantly upon the addition of urea. This is the result of a decrease in the Lennard-Jones energies, which is the MD simulation equivalent to van der Waals interactions. This effect will favor the unfolded protein state due to its higher number of protein - solvent contacts. In Paper II, we show that a combination of NMR spin relaxation experiments and MD simulations can successfully be used to study urea in the protein solvation shell. The urea molecule was found to be dynamic, which indicates that no specific binding sites exist. In contrast to the thermodynamic approach in Paper I, in Paper III we utilize MD simulations to analyze the affect of urea on the kinetics of local processes in proteins. Urea is found to passively unfold proteins by decreasing the refolding rate of local parts of the protein that have unfolded by thermal fluctuations. Based upon the results of Paper I – III and previous studies in the field, I propose a mechanism in which urea denatures proteins mainly by an enthalpic driving force due to attractive van der Waals interactions. Urea interacts favorably with all the different parts of the protein. The greater solvent accessibility of the unfolded protein is ultimately the factor that causes unfolded protein structures to be favored in concentrated urea solutions.
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Conformational Bias in 2'-Selenium-Modified Nucleosides and the Effect on Helical Structure and Extracellular Recombinant Protein Production: Current Systems and ApplicationsThompson, Richard A 27 April 2011 (has links)
Part One. X-ray crystallography has benefited from the synthetic introduction of selenium to different positions within nucleic acids by easing the solving of the phase problem. Interestingly, its addition to the 2' position of the ribose ring also significantly enhances crystal formation. This phenomenon was investigated to describe the effect of selenium-based and other 2' modifications to the ribose ring of nucleosides in solution, as well as the incorporation of the selenium-modified nucleotides into a helical structure. This work correlates the difference in conformation propensity between the selenium containing nucleosides and oligomers towards a rationale behind the enhanced crystal forming behavior. Part Two. Recombinant protein production is a critical tool in laboratories and industries, and inducing extracellular transport of these products to the culture medium shows potential for improving cases where the yields are not sufficient in quality or quantity. This review incorporates current practices and systems with future perspectives.
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The Role of Base Modifications on Tyrosyl-tRNA Structure, Stability, and Function in Bacillus subtilis and Bacillus anthracisDenmon, Andria 16 September 2013 (has links)
tRNA molecules contain more than 80 chemically unique nucleotide base modifications that contribute to the chemical and physical diversity of RNAs as well as add to the overall fitness of the cell. For instance, base modifications have been shown to play a critical role in tRNA molecules by improving the fidelity and efficiency of translation. Most of this work has been carried out extensively in Gram-negative bacteria, however, the role of modified bases in tRNAs as they relate to thermostability, structure, and transcriptional regulation in Gram-positive bacteria, such as Bacillus subtilis and Bacillus anthracis, are not well characterized. Infections by Gram-positive bacteria that have become more resistant to established drug regiments are on the rise, making Gram-positive bacteria a serious threat to public safety.
My thesis work examined what role partial base modification of the tyrosyl-anticodon stem-loops (ASLTyr ) of B. subtilis and B. anthracis have on thermostability, structure, and transcriptional regulation. The ASLTyr molecules have three modified residues which include Queuine (Q34), 2-thiomethyl-N6-dimethylallyl (ms2i6A37), and pseudouridine (Y39). Differential Scanning Calorimetry (DSC) and UV melting were employed to examine the thermodynamic effects of partial modification on ASLTyr stability. The DSC and UV data indicated that the Y39 and i6A37 modifications improved the molecular stability of the ASL.
To examine the effects of partial base modification on ASLTyr structure, NMR spectroscopy was employed. The NMR data indicated that the unmodified and [Y39]-ASLTyr form a protonated C-A+ Watson-Crick-like base pair instead of the canonical bifurcated C-A+ interaction. Additionally, the loop regions of the unmodified and [Y39]-ASLTyr molecules were well ordered. Interestingly, the [i6A37]- and [i6A37; Y39]- ASLTyr molecules did not form a protonated C-A+ base pair and the bases of the loop region were not well ordered. The NMR data also suggested that the unmodified and partially modified molecules do not adopt the canonical U-turn structure. The structures of the unmodified, [Y39]-, and [i6A37;Y39]-ASLTyr molecules did not depend on the presence of Mg2+, but the structure of the [i6A37]-ASLTyr molecule did depend on the presence of multivalent cations.
Finally, to determine the repercussions that partial modification has on physiology and tRNA mediated transcriptional regulation in B. anthracis, antibiotic sensitivity tests, growth curves, and quantitative real-time polymerase chain reaction (qRT-PCR) were employed. Strains deficient in ms2 showed comparable growth to the parent strain when cultured in defined media, but Q deficient strains did not. The loss of ms2i6A37 conferred resistance to spectinomycin and ciprofloxacin, whereas the loss of Q34 resulted in sensitivity to erythromycin. Changes in the ratio full-length to truncated transcripts of the tyrS1 and tyrS2 genes were used to monitor tRNA mediated transcriptional regulation. The qRT-PCR data suggested that tyrS1 and tyrS2 are T-box regulated and that the loss of ms2i6A37 and Q34 might affect the interaction of the tRNATyr molecule with the specifier sequence, which is located in the 5’-untranscribed region (UTR) of the messenger RNA (mRNA).
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NMR Structure Improvement: A Structural Bioinformatics & Visualization ApproachBlock, Jeremy January 2010 (has links)
<p>The overall goal of this project is to enhance the physical accuracy of individual models in macromolecular NMR (Nuclear Magnetic Resonance) structures and the realism of variation within NMR ensembles of models, while improving agreement with the experimental data. A secondary overall goal is to combine synergistically the best aspects of NMR and crystallographic methodologies to better illuminate the underlying joint molecular reality. This is accomplished by using the powerful method of all-atom contact analysis (describing detailed sterics between atoms, including hydrogens); new graphical representations and interactive tools in 3D and virtual reality; and structural bioinformatics approaches to the expanded and enhanced data now available.</p>
<p> The resulting better descriptions of macromolecular structure and its dynamic variation enhances the effectiveness of the many biomedical applications that depend on detailed molecular structure, such as mutational analysis, homology modeling, molecular simulations, protein design, and drug design.</p> / Dissertation
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