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Divalent cation-induced conformational changes and oligomerization of KChIP1Chen, Chia-Yi 19 June 2003 (has links)
Abstract
KChIPs are Kv channel-interacting proteins that bind to the cytoplasmic N-terminus of Kv4
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Identification of Structural Changes Associated with Regulation of Tyrosine HydroxylaseWang, Shanzhi 2010 August 1900 (has links)
Tyrosine hydroxylase (TyrH) is the first and rate-limiting enzyme of
catecholamine synthetic pathway, and its regulation is critical for controlling
catecholamine synthesis. The well recognized regulatory mechanisms are inhibition by
catecholamine binding and re-activation upon Ser40 phosphorylation. Catecholamines
bind to TyrH tightly, while phosphorylation of TyrH at Ser40 decreases the binding
affinity by several hundred-fold. Regulation of TyrH is accompanied by conformational
changes of the protein. This study focuses on the identification of the conformational
changes of TyrH upon dopamine binding and Ser40 phosphorylation, using hydrogen
deuterium exchange mass spectrometry (HDMS) and fluorescence spectroscopy.
HDMS identifies three peptides undergoing conformational changes upon
dopamine binding, peptide 35-41, 42-71 and 295-299. Peptides 35-41 and 42-71 are on
the regulatory domain, while peptide 295-299 is at the active site entrance. Upon
dopamine binding, all three peptides are protected from exchange; phosphorylation of
TyrH at Ser40 has opposite effects on the exchange kinetics of peptide 295-299, but
peptides 35-41 and 42-71 could not be detected by MS after phosphorylation. This suggests that the structural effects of dopamine binding and Ser40 phosphorylation are
opposite.
The fluorescence spectroscopy of mutant enzymes containing a single tryptophan
at position 14, 34 or 74 was performed before and after phosphorylation. F34W/F3W
TyrH has a significant decrease in steady-state fluorescence anisotropy, an increase in
the bimolecular quenching rate constant kq and dynamic anisotropy upon
phosphorylation at Ser40, while F14W/F3W TyrH and F74W/F3W TyrH exhibit much
smaller differences. This suggests that phosphorylation of TyrH at Ser40 increases the
flexibility of the regulatory domain.
The results are consistent with TyrH existing in two conformations, a closed
conformation stabilized by dopamine in which the N-terminal regulator domain of TyrH
covers the active site entrance and an open conformation stabilized by phosphorylation
in which the regulatory domain has moved away from the active site entrance.
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Probabilistic models for protein conformational changesNguyen, Chuong Thach 22 May 2020 (has links)
No description available.
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Asymmetric Crystal Growth of Resorcinol from the Vapor Phase: Surface reconstruction and conformational change are the Culprits.Anwar, Jamshed, Chatchawalsaisin, Jittima, Kendrick, John 2009 July 1928 (has links)
No / The growth of crystals of a-resorcinol from the vapor phase is asymmetric along the polar axis. By means of molecular-dynamics simulations, the slower growth at the (011) polar surface is traced back to conformational change of the molecule and to surface reconstruction, which may be a general phenomenon in polar crystals.
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Role of a highly conserved region of the NF-kappaB essential modulator in its scaffolding functionShaffer, Robert 05 February 2019 (has links)
Scaffold proteins facilitate many aspects of intracellular signaling. These proteins can regulate two or more proteins in the same pathway, or coordinate signaling from multiple pathways. Scaffold proteins are therefore key control points for the flux of signaling and play essential roles in biological systems. There are four possible mechanisms by which scaffold proteins achieve activation and propagate signaling: 1) rigid protein binding between two or more proteins to co-localize binding partners, 2) ligand-induced activation such as may result from a conformational change, 3) disorder-to-order transition where the scaffold protein folds as a result of a protein-protein interaction, and 4) dynamic processes such as phosphorylation. The scaffold protein NF-κB essential modulator (NEMO) functions via ligand-induced activation and serves as the key control point for canonical NF-κB signaling. The work described in this thesis investigates the role of a previously uncharacterized domain within NEMO that is required for function, which we term the Intervening Domain (IVD). Bioinformatic analysis reveals a high level of sequence conservation across species within this domain. Conformational changes following ligand binding are observed for NEMO and these changes require conserved sequences in the IVD. Additionally, a functional IVD is shown to increase the binding affinity of NEMO for IKKβ, enhance the thermal stability of NEMO, and is required to propagate NF-κB signaling in cells. A fluorescence-based assay is also developed to characterize the formation of a complex composed of NEMO, a zinc ion, and IκBα. A separate fluorescence-based assay is developed to measure IKK activity and is used to determine that NEMO alone or in the presence of linear tetraubiquitin does not enhance the rate of IKKβ phosphorylation of an IκBα-derived peptide. Furthermore, a number of organic small molecules and macrocycles are screened against the NEMO-IKKβ interaction. One small molecule was validated as an inhibitor and its biophysical properties and inhibition kinetics are described in this thesis. These analyses represent the first characterization of a highly conserved domain required for the function of the key control point in NF-κB signaling. The IVD domain of NEMO could be targeted for development of an allosteric effector for therapeutic discovery.
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Regulated release of P-Tefb from the 7sk SnrnpKrueger, Brian 01 December 2009 (has links)
Regulation of transcription elongation by P-TEFb is critical for proper gene expression and cell survival. The cell possesses large quantities of P-TEFb, but the vast majority of it is locked away and inactive in the 7SK snRNP. Since the discovery of the 7SK snRNP, research has been conducted to determine how P-TEFb is released from this complex. The goal of the research presented in this thesis is to better understand how the 7SK snRNP regulates P-TEFb and ultimately, gene expression.
This work documents the discovery and characterization of the 7SK stability protein LARP7. LARP7 is is associated with 7SK regardless of the presence of P-TEFb and HEXIM1. Stabilization of 7SK is essential for maintenance of the RNP because loss of LARP7 results in an increase in free P-TEFb and a significant reduction in the amount of 7SK. These results indicate that stabilization of the 7SK snRNP by LARP7 is important for regulating P-TEFb homeostasis.
Although P-TEFb was first characterized from Drosophila lysates, the conservation of the 7SK snRNP and the mechanisms regulating P-TEFb inhibition have not been described. Here, the Drosophila melanogaster homologues of LARP7 and 7SK are characterized. These studies show that the system of P-TEFb regulation is similar in flies and this makes Drosophila an attractive model system for studying P-TEFb regulation through embryonic and larval development.
Finally, factors and modifications involved in releasing P-TEFb directly are explored. An assay was developed for discovering proteins that can bind to and release P-TEFb from the 7SK snRNP. Use of this assay showed that post-translational modification of the components of the 7SK snRNP do not cause P-TEFb release directly. However, HIV Tat and the C-terminal P-TEFb binding region of the bromodomain containing protein, Brd4, are capable of extracting P-TEFb directly. Most importantly, the release of P-TEFb is followed by a conformational change in 7SK RNA that prevents the continued binding of HEXIM1 to the complex. P-TEFb release from the 7SK snRNP is the result of direct extraction of P-TEFb by viral or cellular proteins, and not post-translational modifications or a competition between HEXIM1 and hnRNP proteins for 7SK binding.
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Mechanistic Studies of Two Selected Flavin-Dependent Enzymes: Choline Oxidase and D-Arginine DehydrogenaseYuan, Hongling 11 August 2011 (has links)
Choline oxidase catalyzes the flavin-dependent, two-step oxidation of choline to glycine betaine via the formation of an aldehyde intermediate. The oxidation of choline includes two reductive half-reactions followed by oxidative half-reactions. In the first oxidation reaction, the alcohol substrate is activated to its alkoxide via proton abstraction and oxidized via transfer of a hydride from the alkoxide α-carbon to the N(5) atom of the enzyme-bound flavin. In the wild-type enzyme, proton and hydride transfers are mechanistically and kinetically uncoupled.
The role of Ser101 was investigated in this dissertation. Replacement of Ser101 with threonine, alanine, cysteine, or valine demonstrated the importance of the hydroxyl group of Ser101 in proton abstraction and in hydride transfer. Moreover, the kinetic studies on the Ser101Ala variant have revealed the importance of a specific residue for the optimization of the overall turnover of choline oxidase. The UV-visbible absorbance of Ser101Cys suggests Cys101 can form an adduct with the C4a atom of the flavin. The mechanism of formation of the C4a-cysteinyl adduct has been elucidated.
D-arginine dehydrogenase (DADH) catalyzes the oxidation of D-amino acids to the corresponding imino acids, which are non-enzymatically hydrolyzed to α-keto acids and ammonia. The enzyme is strick dehrogenase and deoesnot react with molecular oxygen. Steady state kinetic studies wirh D-arginine and D-histidine as a substrate and PMS as the electron acceptor has been investigated. The enzyme has broad substrate specificity for D-amino acids except aspartate, glutamate and glycine, with preference for arginine and lysine. Leucine is the slowest substrate in which steady state kinetic parameters can be obtained. The chemical mechanism of leucine dehydrogenation catalyzed by DADH was explored with a combination of pH, substrate and solvent kinetic isotope effects (KIE) and proton inventories by using rapid kinetics in a stopped-flow spectrophotometer. The data are discussed in the context of the crystallographic structures at high resolutions (<1.3 Å) of the enzyme in complex with iminoarginine or iminohistidine.
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Structure Based Study of CA SPASE-3 and D-Arginine DehydrogenaseFu, Guoxing 07 December 2012 (has links)
Caspases are important players in programmed cell death. Normal activities of caspases are critical for the cell life cycle and dysfunction of caspases may lead to the development of cancer and neurodegenerative diseases. They have become a popular target for drug design against abnormal cell death. In this study, the recognition of P5 position in substrates by caspase-3, -6 and -7 has been investigated by kinetics, modeling and crystallography. Crystal structures of caspase-3 and -7 in complexes with substrate analog inhibitor Ac-LDESD-CHO have been determined at resolutions of 1.61 and 2.45 Å, respectively, while a model of caspase-6/LDESD is constructed. Enzymatic study and structural analysis have revealed that Caspase-3 and -6 recognize P5 in pentapeptides, while caspase-7 lacks P5-binding residues.
D-arginine dehydrogenase catalyzes the flavin-dependent oxidative deamination of D-amino acids to the corresponding imino acids and ammonia. The X-ray crystal structures of DADH and its complexes with several imino acids were determined at 1.03-1.30 Å resolution. The DADH crystal structure comprises a product-free conformation and a product-bound conformation. A flexible loop near the active site forms an “active site lid” and may play an essential role in substrate recognition. The DADH Glu87 forms an ionic interaction with the side chain of iminoarginine, suggesting its importance for DADH preference of positively charged D-amino acids. Comparison of the kinetic data of DADH activity on different D-amino acids and the crystal structures demonstrated that this enzyme is characterized by relatively broad substrate specificity, being able to oxidize positively charged and large hydrophobic D-amino acids bound within a flask-like cavity.
Understanding biology at the system level has gained much more attention recently due to the rapid development in genome sequencing and high-throughput measurements. Current simulation methods include deterministic method and stochastic method. Both have their own advantages and disadvantages. Our group has developed a deterministic-stochastic crossover algorithm for simulating biochemical networks. Simulation studies have been performed on biological systems like auto-regulatory gene network and glycolysis system. The new system retains the high efficiency of deterministic method while still reflects the random fluctuations at lower concentration.
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Biophysical Interactions of the OHC Motor Protein Prestin: A Study at the Single Molecule LevelJanuary 2011 (has links)
The exquisite frequency selectivity and amplification characteristics of mammalian hearing intimately depend on the fast electromechanical motion of the outer hair cells in the cochlea. This membrane based process, termed electromotility, is driven by the protein prestin which is uniquely present in the OHC lateral wall. Voltage dependent motility, in OHCs and mammalian cells expressing prestin, is accompanied by intramembranous charge movement which is widely considered a signature of electromotility and prestin function. How prestin converts changes in membrane potential into axial length changes of OHCs is currently not understood at the molecular level. Many electromotility models predict that prestin conformational changes are the underlying mechanism connecting charge movement and motility. Currently, however, only indirect evidence for a prestin conformational change is available. Various experiments have indicated that the oligomeric states of prestin may be an important determinant of function. Numerous reports have provided varying estimates of prestin oligomeric state. However, estimates have been based on measurements performed outside the membrane making, firm biophysical conclusions difficult. Biophysical studies of prestin function have demonstrated its dependence on membrane properties. Alterations of membrane cholesterol affect voltage dependence of charge movement and motility. In addition cholesterol manipulations cause spatial redistribution of prestin and possibly change prestin oligomeric state. However, the underlying cause for prestin sensitivity to cholesterol and its relation to membrane distribution is unknown. We have applied single molecule fluorescence (SMF) imaging, single particle tracking (SPT), and Förster resonance energy transfer (FRET) to investigate prestin interactions at the molecular level. The results of our SMF experiments have suggested that prestin forms mainly tetramers and dimers in the cell membrane. Using SPT to map the trajectories of prestin in the membrane, we have found that prestin undergoes diffusion in and hops between membrane confinements of varying size. In addition, we have found that cholesterol affects the size and confinement strength of the compartments but does not affect the diffusivity within the compartments. Finally, using a combination of electrophysiology and FRET we have demonstrated that prestin undergoes voltage dependent structural changes. In total, our results refine our molecular understanding of prestin function.
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The regulation of conformation and binding kinetics of integrin alphaLbeta2Zhang, Fang 09 July 2007 (has links)
The interaction mediated by integrin alphaLbeta2 and its ligand plays major role in many immune responses by regulating leukocyte adhesion. This study investigated the conformational regulation of alphaLbeta2 and the effects of conformational change on the ligand binding of alphaLbeta2. Micropipette adhesion frequency assay was used to measure the two-dimensional binding affinity and kinetics of alphaLbeta2 on K562 cells and neutrophils. The conformations of alphaLbeta2 were regulated by mutations, antibodies, small molecule antagonists, as well as divalent cations. Our results indicated that the change in binding affinity and off-rate was mostly due to the alphaL I domain conformational change. Without affecting the I domain conformation, the extension of alphaLbeta2 only increases the on-rate for several fold by providing a better orientation and accessibility of the molecule on cell surface. The binding characteristics of divalent cations to I domain MIDAS and other metal ion binding sites in alphaLbeta2 are determined by the nature of divalent cations, Mn2+ has higher binding affinity to the metal ion binding sites than Mg2+. The conformation of I domain also affected the binding of divalent cations. Open and intermediate I domains have higher binding affinity for Mn2+ and Mg2+ than WT and closed I domains. Divalent cations dissociate from I domain MIDAS very slowly but from those metal ion binding sites that important for conformational change of alphaLbeta2 rapidly. One of the most important biological processes mediated by alphaLbeta2 and other beta2 integrins is the recruitment and migration of neutrophils during inflammation. The activation of beta2 integrins by E-selectin binding to neutrophils in this process was also investigated. The binding of E-selectin, but not P- or L-selectin, activates beta2 integrins in a timescale of ~ 5 seconds and the activation may require the crosslink of E-selectin ligands. These results provide insights into the relationship between the conformational change and the function of alphaLbeta2 and most importantly would contribute to the understanding of integrin regulation mechanisms.
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