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An investigation into the effects of L-Arabinofuranose O-glycosylation of hydroxyprolineMantha, Venkata 07 July 2014 (has links)
The amino acid (2S, 4R)-4-hydroxyproline (Hyp) plays a critical role in animal kingdom as structural protein collagen. It is ubiquitous in plant cell walls performing various functions such as structural assembly, plant hormones, plant growth, defense against pathogens, etc. Glycosylation of Hyp is often seen in plant cell walls with L-Arabinofuranose and D-Galactopyranose and not in animal kingdom. Glycosylation is a post-translational modification, which affects characteristics of proteins and peptides.
The main objective of this thesis is to synthesize various L-arabinofuranosylated hydroxyproline model amides and investigate their thermodynamic and kinetic properties of cis/trans amide isomerization. These results are compared with the previous research of D-galactopyranosylated hydroxyproline model amides, which may provide an insight to structural implications for their stability and conformations of peptides and specificity in plants.
Both - and -L-arabinosylation of Hyp resulted in the stabilization of trans rotameric state at room temperature while the α-anomer leads to cis rotamer stabilization at higher temperature. Similarly, both unnatural 4S-hydroxyproline (hyp) building blocks resulted in stabilization of trans rotamer but α-anomer shows exo configuration instead of endo. This result shows a reverse trend when compared to galactosylated hydroxyproline building blocks as previous research results in our group. Our results may provide further insight to the role of glycosylation on protein structure and stability in plants.
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Using Molecular Dynamics to Elucidate the Mechanism of CyclophilinMcGowan, Lauren 09 May 2014 (has links)
Cyclophilins are ubiquitous enzymes that are involved in protein folding, signal transduction, viral proliferation, oncogenesis, and regulation of the immune system. Cyclophilin A is the prototype of the cyclophilin family. We use molecular dynamics to describe the catalytic mechanism of cyclophilin A in full atomistic detail by sampling critical points along the reaction coordinate, and use accelerated molecular dynamics to sample cis-trans interconversions. At these critical points, we analyze the conformational space sampled by the active site, flexibility of the enzyme backbone, and modulation of binding interactions.We use Kramer’s rate theory to determine how diffusion and free energy contribute to lowering the activation energy of prolyl isomerization. We also find preferential binding modes of several cyclophiln A inhibitors, and compare the conformational space sampled by inhibited cyclophilin A to the conformational space sampled during wild-type interactions. We also analyze the mechanism of the next family member cyclophilin B in order to probe differences in enzyme dynamics and intermolecular interactions that could possibly be exploited in isoform-specific drug design. Our results indicate that cyclophilin proceeds by a conformational selection binding mechanism that manipulates substrate sterics, electrostatic interactions, and multiple reaction timescales in order to speed up reaction rate. Conformational space sampled by cyclophilin when inhibited and when undergoing wild-type interactions share significant similarity. Cyclophilins A and B do have notable differences in enzyme dynamics, due to variation in intramolecular interactions that arise from variation in primary structures. This work demonstrates how computational methods can be used to clarify catalytic mechanisms.
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Folding mechanism of Glutaredoxin 2Gildenhuys, Samantha 19 May 2008 (has links)
ABSTRACT
Equilibrium unfolding, single- and double-jump kinetic studies were conducted to
determine the unfolding and refolding pathway of glutaredoxin 2. Structural
changes for wild-type glutaredoxin 2 were monitored by far-ultraviolet circular
dichroism and intrinsic tryptophan fluorescence for equilibrium unfolding and
intrinsic tryptophan fluorescence for single- and double-jump kinetics studies.
Glutaredoxin 2 possesses two tryptophan residues in domain 2. In order to
monitor changes in domain 1, cysteine 9 at the active site cysteines, situated in
domain 1, was labelled with an extrinsic fluorophore, AEDANS, and a mutant
was created (Y58W glutaredoxin 2). The AEDANS labelled protein displayed
decreased alpha-helical secondary structure and conformational stability. A high
degree of cooperativity and similar conformational stability was observed during
the two-state transition of the urea-induced equilibrium unfolding of both the
wild-type and Y58W glutaredoxin 2 proteins therefore Y58W glutaredoxin 2
could be used to assess structural changes in the local environment of domain 1
during unfolding and refolding. Two phases of unfolding, the fast and slow phase,
occurred for both the wild-type and Y58W proteins. The slow phase involves
structural rearrangements that expose small amounts of surface area while the fast
phase represents gross structural unfolding exposing large amounts of surface
area. The isomerization of the Val48-Pro49 peptide bond to the trans
conformation occurs during the slow phase and this isomerization is coupled to
conformational unfolding of the protein. The structural separation of these phases
could be represented by two structural units (unit x and unit y), these units do not
represent domain 1 and 2. The units could also result in parallel refolding
pathways with the folding of the x unit involving the fast and slow refolding
phases and the folding of the y unit of structure is represented by the medium
phase of refolding. The fast and slow phases are further separated as the fast
phase represents the gross structural folding of glutaredoxin 2 for species with the
Val48-Pro49 peptide bond in the native cis conformation. The development of the
slow phase after extended unfolding delay periods during double-jump refolding
studies, as well as the acceleration of the rate of the phase by the peptidyl prolyl
isomerase hFKBP-12 proved that the phase involves a proline peptide bond
iv
isomerization. This phase represents a slow isomerization coupled with
conformational folding similar to the slow unfolding phase. Complex unfolding
and refolding kinetics indicated the involvement of kinetic intermediates during
(un)folding.
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Computational Perspective on Intricacies of Interactions, Enzyme Dynamics and Solvent Effects in the Catalytic Action of Cyclophilin ATork Ladani, Safieh 11 May 2015 (has links)
Cyclophilin A (CypA) is the well-studied member of a group of ubiquitous and evolutionarily conserved families of enzymes called peptidyl–prolyl isomerases (PPIases). These enzymes catalyze the cis-trans isomerization of peptidyl-prolyl bond in many proteins. The distinctive functional path triggered by each isomeric state of peptidyl-prolyl bond renders PPIase-catalyzed isomerization a molecular switching mechanism to be used on physiological demand. PPIase activity has been implicated in protein folding, signal transduction, and ion channel gating as well as pathological condition such as cancer, Alzheimer’s, and microbial infections.
The more than five order of magnitude speed-up in the rate of peptidyl–prolyl cis–trans isomerization by CypA has been the target of intense research. Normal and accelerated molecular dynamic simulations were carried out to understand the catalytic mechanism of CypA in atomistic details. The results reaffirm transition state stabilization as the main factor in the astonishing enhancement in isomerization rate by enzyme. The ensuing intramolecular polarization, as a result of the loss of pseudo double bond character of the peptide bond at the transition state, was shown to contribute only about −1.0 kcal/mol to stabilizing the transition state. This relatively small contribution demonstrates that routinely used fixed charge classical force fields can reasonably describe these types of biological systems. The computational studies also revealed that the undemanding exchange of the free substrate between β- and α-helical regions is lost in the active site of the enzyme, where it is mainly in the β-region. The resultant relative change in conformational entropy favorably contributes to the free energy of stabilizing the transition state by CypA. The isomerization kinetics is strongly coupled to the enzyme motions while the chemical step and enzyme–substrate dynamics are in turn buckled to solvent fluctuations. The chemical step in the active site of the enzyme is therefore not separated from the fluctuations in the solvent. Of special interest is the nature of catalysis in a more realistic crowded environment, for example, the cell. Enzyme motions in such complicated medium are subjected to different viscosities and hydrodynamic properties, which could have implications for allosteric regulation and function.
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Understanding Hydrogen Bonding in PhotoenolizationScott, Tianeka S. 18 October 2013 (has links)
No description available.
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A Numerical Model for Nonadiabatic Transitions in MoleculesAgrawal, Devanshu 01 May 2014 (has links)
In molecules, electronic state transitions can occur via quantum coupling of the states. If the coupling is due to the kinetic energy of the molecular nuclei, then electronic transitions are best represented in the adiabatic frame. If the coupling is instead facilitated through the potential energy of the nuclei, then electronic transitions are better represented in the diabatic frame. In our study, we modeled these latter transitions, called ``nonadiabatic transitions.'' For one nuclear degree of freedom, we modeled the de-excitation of a diatomic molecule. For two nuclear degrees of freedom, we modeled the de-excitation of an ethane-like molecule undergoing cis-trans isomerization. For both cases, we studied the dependence of the de-excitation on the nuclear configuration and potential energy of the molecule.
We constructed a numerical model to solve the time-dependent Schr\"{o}dinger Equation for two coupled wave functions. Our algorithm takes full advantage of the sparseness of the numerical system, leading to a final set of equations that is solved recursively using nothing more than the Tridiagonal Algorithm.
We observed that the most effective de-excitation occurred when the molecule transitioned from a stable equilibrium configuration to an unstable equilibrium configuration. This same mechanism is known to drive fast electronic transitions in the adiabatic frame. We concluded that while the adiabatic and diabatic frames are strongly opposed physically, the mathematical mechanism driving electronic transitions in the two frames is in some sense the same.
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Molecular Dynamics Simulations Towards The Understanding of the Cis-Trans Isomerization of Proline As A Conformational Switch For The Regulation of Biological ProcessesVelazquez, Hector 10 May 2014 (has links)
Pin1 is an enzyme central to cell signaling pathways because it catalyzes the cis–trans isomerization of the peptide ω-bond in phosphorylated serine/threonine-proline motifs in many proteins. This regulatory function makes Pin1 a drug target in the treatment of various diseases. The effects of phosphorylation on Pin1 substrates and the basis for Pin1 recognition are not well understood. The conformational consequences of phosphorylation on Pin1 substrate analogues and the mechanism of recognition by the catalytic domain of Pin1 were determined using molecular dynamics simulations. Phosphorylation perturbs the backbone conformational space of Pin1 substrate analogues. It is also shown that Pin1 recognizes specific conformations of its substrate by conformational selection. Dynamical correlated motions in the free Pin1 enzyme are present in the enzyme of the enzyme–substrate complex when the substrate is in the transition state configuration. This suggests that these motions play a significant role during catalysis. These results provide a detailed mechanistic understanding of Pin1 substrate recognition that can be exploited for drug design purposes and further our understanding of the subtleties of post-translational phosphorylation and cis–trans isomerization.
Results from accelerated molecular dynamics simulations indicate that catalysis occurs along a restricted path of the backbone configuration of the substrate, selecting specific subpopulations of the conformational space of the substrate in the active site of Pin1. The simulations show that the enzyme–substrate interactions are coupled to the state of the prolyl peptide bond during catalysis. The transition-state configuration of the substrate binds better than the cis and trans states to the catalytic domain of Pin1. This suggests that Pin1 catalyzes its substrate by noncovalently stabilizing the transition state. These results suggest an atomistic detail understanding of the catalytic mechanism of Pin1 that is necessary for the design of novel inhibitors and the treatment of several diseases. Additionally, a set of constant force biased molecular dynamics simulations are presented to explore the kinetic properties of a Pin1 substrate and its unphosphorylated analogue. The simulations indicate that the phosphorylated Pin1 substrate isomerizes slower than the unphosphorylated analogue. This is due to the lower diffusion constant for the phosphorylated Pin1 substrate.
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Determination of Dynamical Conservation in Human Cyclophilin IsoformsVu, Phuoc Jake D. 08 August 2017 (has links)
Among the peptidyl prolyl isomerases, the Cyclophilin family of proteins has been linked to various cellular activities such as regulation of homeostasis, mitochondrial permeability, and cell death. Their functionality spans throughout the cell and throughout all cell types as different isoforms. Previous studies done on Cyclophilin A revealed an interesting contact ensemble when bound to a substrate. Because of the similarity of CypA to its homologues, it is believed that they too will exhibit the same contact dynamics. We have defined the dynamics of cyclophilin isoforms through Molecular Dynamics simulations and determined their contact dynamics, characterizing their contact ensembles, and their relative dynamical conservation to each other.
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Azobenzene Derivatives And Their Application In Designing Photoresponsive Dynamic Supramolecular AggregregatesBenson, Kome Olanrewaju 13 July 2022 (has links)
No description available.
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Modulating Photochromism of Acylated Anthocyanins by Ultraviolet-Visible Excitation and Acylation Patterns for the Expansion of Color DiversificationLa, Ellia Hyeseung January 2022 (has links)
No description available.
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