On the properties of plasma crystals

Steel, William H.

January 1999

No description available.

530.44

The study of structure and dynamics in organometallic compounds

Stevenson, Maya

January 1998

No description available.

530.41

Redetermination of metarossite, CaV25+O6 center dot 2H(2)O

Downs, Robert T., Domanik, Kenneth J., Kobsch, Anais

09 1900

The crystal structure of metarossite, ideally CaV2O6 center dot 2H(2)O [chemical name: calcium divanadium(V) hexaoxide dihydrate], was first determined using precession photographs, with fixed isotropic displacement parameters and without locating the positions of the H atoms, leading to a reliability factor R = 0.11 [Kelsey & Barnes (1960). Can. Mineral. 6, 448- 466]. This communication reports a structure redetermination of this mineral on the basis of single- crystal X- ray diffraction data of a natural sample from the Blue Cap mine, San Juan County, Utah, USA (R1 = 0.036). Our study not only confirms the structural topology reported in the previous study, but also makes possible the refinement of all non- H atoms with anisotropic displacement parameters and all H atoms located. The metarossite structure is characterized by chains of edge- sharing [CaO8] polyhedra parallel to [100] that are themselves connected by chains of alternating [VO5] trigonal bipyramids parallel to [010]. The two H2O molecules are bonded to Ca. Analysis of the displacement parameters show that the [VO5] chains librate around [010]. In addition, we measured the Raman spectrum of metarossite and compared it with IR and Raman data previously reported. Moreover, heating of metarossite led to a loss of water, which results in a transformation to the brannerite- type structure, CaV2O6, implying a possible dehydration pathway for the compounds M2+V2O6 center dot xH(2)O, with M = Cu, Cd, Mg or Mn, and x = 2 or 4.

crystal structure

redetermination

metarossite

hydrogen bonds

phase transformation

brannerite

The KsgA methyltransferase: Characterization of a universally conserved protein involved in robosome biogenesis

O'Farrell, Heather Colleen

01 January 2007

The KsgA enzymes comprise an ancient family of methyltransferases that are intimately involved in ribosome biogenesis. Ribosome biogenesis is a complicated process, involving numerous cleavage, base modification and assembly steps. All ribosomes share the same general architecture, with small and large subunits made up of roughly similar rRNA species and a variety of ribosomal proteins. However, the fundamental assembly process differs significantly between eukaryotes and eubacteria, not only in distribution and mechanism of modifications but also in organization of assembly steps. Despite these differences, members of the KsgA/Dim1 methyltransferase family and their resultant modification of small-subunit rRNA are found throughout evolution, and therefore were present in the last common ancestor. The first member of the family to be described, KsgA from Escherichia coli, was initially shown to be the determining factor for resistance/sensitivity to the antibiotic kasugamycin and was subsequently found to dimethylate two adenosines in 16S rRNA during maturation of the 30S subunit. Since then, numerous other members of the family have been characterized in eubacteria, eukaryotes, archaea and in eukaryotic organelles. The eukaryotic ortholog, Dim1, is essential for proper processing of the pre-rRNA, in addition to and separate from its methyltransferase function. The KsgA/Dim1 family bears sequence and structural similarity to a larger group of S-adenosyl-L-methionine dependent methyltransferases, which includes both DNA and RNA methyltransferases. In this document we report that KsgA orthologs from archaea and eukaryotes are able to complement for KsgA function in bacteria, both in vivo and in vitro. This indicates that all of these enzymes can recognize a common ribosomal substrate, and that the recognition elements must be largely unchanged since the evolutionary split between the three domains of life. We have characterized KsgA structurally, and discuss aspects of KsgA's activity in light of the structural data. We also propose a model for KsgA binding to the 30S subunit, based on solution probing data. This model sheds light on KsgA's unusual regulation and on the dual function of the Dim1 enzymes.

RNA modification

crystal structure

Life Sciences

Nové materiály pro nelineární optiku - soli a kokrystaly heteroaromatických bází / Novel materials for nonlinear optics - salts and cocrystals of heteroaromatic bases

Kloda, Matouš

January 2014

The main issue of this master thesis is investigation of new compounds of aminopyrazine and 3-amino-1,2,4-triazine in consideration of their potential usage in the field of nonlinear optics. The focus of this thesis was finishing of characterisation of an adduct of aminopyrazine and boric acid prepared as a part of previous bachelor thesis, as well as preparation of salts and cocrystals combining 3-amino-1,2,4-triazine with selected acids. Prepared materials were characterised mainly by the means of vibrational spectroscopy and x-ray diffraction analysis. Prediction of nonlinear optical properties of selected molecules and interpretation of recorded vibrational spectra was based on quantum chemical calculations. Finally, measurements of second harmonic generation efficiency of selected powder samples were performed.

Deciphering the mechanism and function of stage-specific protein association with the membrane cytoskeleton of Toxoplasma gondii:

Dubey, Rashmi

January 2017

Thesis advisor: Marc-Jan Gubbels / Apicomplexan parasites like Toxoplasma gondii have a complex life cycle comprising of transitions between different hosts, different organ systems and between the extracellular and intracellular milieu. The parasite must thus adjust itself and its cellular processes in accordance with its environment. In this dissertation, I have focused on such stage specific behaviors of three distinct intermediate filament-like proteins as well as a glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase 1 (GAPDH1). These proteins relocate from the cytosol to the unique cortical membrane skeleton of non-dividing parasites. The intermediate filament-like proteins IMC7, 12 and 14, localize exclusively to the mature cytoskeleton. One model of function was that these proteins differentially stabilized mother and budding daughter cytoskeletons in the division process, but we ruled out this role for the individual proteins, as they are not essential for the lytic cycle of the parasite. However, we determined that IMC7 and IMC14 are contributing to the maintenance of rigidity of the cytoskeleton under osmotic stress conditions in extracellular parasites. In addition, IMC14 is critical in cell cycle progression as its depletion results in the formation of multiple daughters per division round. When the parasite egresses from the host cell, glycolytic enzyme GAPDH1 translocates to the cortex. The functional role of GAPDH1 in the parasite and the mechanism of its cortical translocation are deciphered based on the 2.25Å resolution crystal structure of the GAPDH1 holoenzyme in a quaternary complex. These studies identified that GAPDH1’s enzymatic function is essential for intracellular replication but we confirmed the previous reports that glycolysis is not strictly essential in presence of excess L-glutamine. We identify, for the first time, S-loop phosphorylation as a novel, critical regulator of enzymatic activity that is consistent with the notion that the S-loop is critical for cofactor binding, allosteric activation and oligomerization. We show that neither enzymatic activity nor phosphorylation state correlate with the ability to translocate to the cortex. However, we demonstrate that association of GAPDH1 with the cortex is mediated by Cysteine 3 in the N-terminus, likely by palmitoylation. Overall, glycolysis and cortical translocation are functionally decoupled by post-translational modifications. Collectively, the discoveries made in this dissertation reveal unprecedented detail in mechanism and function of cortical protein translocation and thereby identifying new drug targets. / Thesis (PhD) — Boston College, 2017. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

crystal structure

Cytoskeleton

drug target

GAPDH

IMC

translocation

Functional studies on a novel cytochrome c from Rhodobacter sphaeroides

Li, Bor-Ran

January 2009

SHP (Sphaeroides Heme Protein) is a monoheme cytochrome c of unknown function. In general, ligands cannot bind to ferric SHP, but some diatomic molecules, such as O2 or NO, can bind to ferrous SHP. The gene encoding SHP and genes encoding a diheme cytochrome c (DHC) and a b-type cytochrome (Cyt-b) are found in the same chromosome region in different species. In the case of Shewanella oneidensis MR-1, mRNA levels for SHP, DHC, and Cyt-b are up-regulated by nearly 10-fold when grown under anaerobic conditions using nitrate as the electron acceptor. Thus it is possible that the physiological role of SHP may be in nitrate metabolism. However, nitrate is too big to be a candidate substrate for SHP, and some nitrification steps need more than one electron transfer (SHP is a monoheme cytochrome). Therefore, we will focus on the nitrite reductase, nitric oxide reductase and nitric oxide dioxygenase activities of SHP. In this thesis it is shown that SHP can catalyse the reaction between oxygen and nitric oxide to give a nitrate ion as the final product. Thus a possible aerobic function for SHP as a nitric oxide dioxygenase is proposed. Aerobically, SHP is proposed to be a nitric oxide dioxygenase which utilizes the same mechanism as other NO dioxygenases, flavohemoglobin (HMP) and neuroglobin (Ngb). This mechanism is proposed to proceed via an oxy-ferrous complex (SHP2+-O2) which reacts with nitric oxide. A mechanism for the catalytic reaction with ferrous-NO complex is described. SHP2+-NO can be quickly converted back to ferrous SHP by reacting with superoxide liberated by SHP2+-O2 or from another source. In addition it is also found that Shewanella MR-1 wild type reveals a higher NO tolerance than the SHP knockout strain in aerobic conditions. The catalytic mechanism of NO dioxygenase is oxygen-dependent, but the SHP mRNA up-regulation in Shewanella oneidensis MR-1 grown with nitrate under anaerobic conditions indicates that SHP may also perform some anaerobic function and may possibly be involved in nitrate metabolism. This work found that SHP reveals anaerobic nitrite reductase activity. However, the catalytic efficiency of SHP is considerably lower than other nitrite reductases. This infers that although SHP can reduce nitrite in vitro, it is unlikely to function as a nitrite reductase in vivo. Ferrous SHP binds NO with a Kd of less than 1 μM, and does not auto-oxidise. Therefore, under anaerobic conditions SHP2+-NO must be processed by some other mechanism. In addition, biochemical results reveal that the SHP/DHC complex has NO reductase activity under anaerobic conditions. Unfortunately, this function was not proved in vivo. SHP was initially isolated from Rhodobacter sphaeroides and its structure was reported in 2000. Based upon this structure, SHP is clearly a class I cytochrome c with one axial histidine ligand to the heme iron. Unusually, however, it has an asparagine residue as the other axial heme ligand, and as such is unique among cytochromes c. For this reason it may be assumed that the asparagine plays a special role. This study reveals several potential reasons why SHP utilises asparagine as a heme ligand. Firstly, in the ferric form, asparagine 88 binds to the heme iron to prevent small molecules binding. Secondly, in the ferrous form it moves to allow oxygen to bind and form the oxy-ferrous complex, using hydrogen bonding for stability. Thirdly, using asparagine as a heme ligand creates a suitable redox potential for reduction by DHC, thus allowing NO dioxygenation.

572.6

Crystal structure prediction at high pressures : stability, superconductivity and superionicity

Nelson, Joseph Richard

January 2017

The physical and chemical properties of materials are intimately related to their underlying crystal structure: the detailed arrangement of atoms and chemical bonds within. This thesis uses computational methods to predict crystal structure, with a particular focus on structures and stable phases that emerge at high pressure. We explore three distinct systems. We first apply the ab initio random structure searching (AIRSS) technique and density functional theory (DFT) calculations to investigate the high-pressure behaviour of beryllium, magnesium and calcium difluorides. We find that beryllium fluoride is extensively polymorphic at low pressures, and predict two new phases for this compound - the silica moganite and CaCl$_2$ structures - to be stable over the wide pressure range 12-57 GPa. For magnesium fluoride, our results show that the orthorhombic `O-I' TiO$_2$ structure ($Pbca$, $Z=8$) is stable for this compound between 40 and 44 GPa. Our searches find no new phases at the static-lattice level for calcium difluoride between 0 and 70 GPa; however, a phase with $P\overline{6}2m$ symmetry is energetically close to stability over this pressure range, and our calculations predict that this phase is stabilised at high temperature. The $P\overline{6}2m$ structure exhibits an unstable phonon mode at large volumes which may signal a transition to a superionic state at high temperatures. The Group-II difluorides are isoelectronic to a number of other AB$_2$-type compounds such as SiO$_2$ and TiO$_2$, and we discuss our results in light of these similarities. Compressed hydrogen sulfide (H$_2$S) has recently attracted experimental and theoretical interest due to the observation of high-temperature superconductivity in this compound ($T_c$ = 203 K) at high pressure (155 GPa). We use the AIRSS technique and DFT calculations to determine the stable phases and chemical stoichiometries formed in the hydrogen-sulfur system as a function of pressure. We find that this system supports numerous stable compounds: H$_3$S, H$_7$S$_3$, H$_2$S, H$_3$S$_2$, H$_4$S$_3$, H$_2$S$_3$ and HS$_2$, at various pressures. Working as part of a collaboration, our predicted H$_3$S and H$_4$S$_3$ structures are shown to be consistent with XRD data for this system, with H$_4$S$_3$ identified as a major decomposition product of H$_2$S in the lead-up to the superconducting state. Calcium and oxygen are two elements of generally high terrestrial and cosmic abundance, and we explore structures of calcium peroxide (CaO$_2$) in the pressure range 0-200 GPa. Stable structures for CaO$_2$ with $C2/c$, $I4/mcm$ and $P2_1/c$ symmetries emerge at pressures below 40 GPa, which we find are thermodynamically stable against decomposition into CaO and O$_2$. The stability of CaO$_2$ with respect to decomposition increases with pressure, with peak stability occurring at the CaO B1-B2 phase transition at 65 GPa. Phonon calculations using the quasiharmonic approximation show that CaO$_2$ is a stable oxide of calcium at mantle temperatures and pressures, highlighting a possible role for CaO$_2$ in planetary geochemistry, as a mineral redox buffer. We sketch the phase diagram for CaO$_2$, and find at least five new stable phases in the pressure/temperature ranges 0 $\leq P\leq$ 60 GPa, 0 $\leq T\leq$ 600 K, including two new candidates for the zero-pressure ground state structure.

Dinuclear Manganese Complexes for Artificial Photosynthesis : Synthesis and Properties

Anderlund, Magnus

January 2005

<p>This thesis deals with the synthesis and characterisation of a series of dinuclear manganese complexes. Their ability to donate electrons to photo-generated ruthenium(III) has been investigated in flash photolysis experiments followed by EPR-spectroscopy. These experiment shows several consecutive one-electron transfer steps from the manganese moiety to ruthenium(III), that mimics the electron transfer from the oxygen evolving centre in photosystem II.</p><p>The redox properties of these complexes have been investigated with electro chemical methods and the structure of the complexes has been investigated with different X-ray techniques. Structural aspects and the effect of water on the redox properties have been shown.</p><p>One of the manganese complexes has been covalently linked in a triad donor-photosensitizer-acceptor (D–P–A) system. The kinetics of this triad has been investigated in detail after photo excitation with both optical and EPR spectroscopy. The formed charge separated state (D^––P–A⁺) showed an unusual long lifetime for triad based on ruthenium photosensitizers.</p><p>The thesis also includes a study of manganese-salen epoxidation reactions that we believe can give an insight in the oxygen transfer mechanism in the water oxidising complex in photosystem II.</p>

Crystal Structure

Artificial photosynthesis

Manganese complex

Organic chemistry

Organisk kemi

Dinuclear Manganese Complexes for Artificial Photosynthesis : Synthesis and Properties

Anderlund, Magnus

January 2005

This thesis deals with the synthesis and characterisation of a series of dinuclear manganese complexes. Their ability to donate electrons to photo-generated ruthenium(III) has been investigated in flash photolysis experiments followed by EPR-spectroscopy. These experiment shows several consecutive one-electron transfer steps from the manganese moiety to ruthenium(III), that mimics the electron transfer from the oxygen evolving centre in photosystem II. The redox properties of these complexes have been investigated with electro chemical methods and the structure of the complexes has been investigated with different X-ray techniques. Structural aspects and the effect of water on the redox properties have been shown. One of the manganese complexes has been covalently linked in a triad donor-photosensitizer-acceptor (D–P–A) system. The kinetics of this triad has been investigated in detail after photo excitation with both optical and EPR spectroscopy. The formed charge separated state (D––P–A+) showed an unusual long lifetime for triad based on ruthenium photosensitizers. The thesis also includes a study of manganese-salen epoxidation reactions that we believe can give an insight in the oxygen transfer mechanism in the water oxidising complex in photosystem II.

Crystal Structure

Artificial photosynthesis

Manganese complex

Organic chemistry

Organisk kemi