Global ETD Search

21	Electrostatic properties at the interface of p53 Transactivation domain binding Corrigan, Alexsandra Nikol 25 May 2021 (has links) Intrinsically disordered proteins (IDPs) are an abundant class of proteins and protein regions which rapidly change between multiple structures without an equilibrium position. IDPs exist as a series of conformational ensembles of semi-stable conformations that can be adopted based on a hilly landscape of shallow free energy minima. Disordered sequences share characteristic features differentiating them from globular proteins, including low sequence complexity, low occurrence of hydrophobic residues, high polar and charged residue content, and high flexibility. IDPs are commonly involved in regulation in the cell, and frequently function as, or interact with, hub proteins in protein-protein interaction networks, making them an important class of macromolecules for understanding regulatory and other processes. Given their functional importance, these proteins are widely studied. Many analytical techniques are used, though rapid conformational sampling by IDPs makes it difficult to detect many states with NMR or other techniques. Computational approaches such as molecular dynamics are increasingly used to probe the binding and conformational sampling of these proteins, allowing for observation of factors that cannot be observed with traditional analytical methods such as NMR, such as differing conformational ensembles and the dipoles of individual residues. Here, we studied the role of electrostatic interactions in IDP protein-protein interaction using molecular dynamics simulations performed with the Drude-2019 force field (FF), a polarizable model that allows for more accurate representation of electrostatics, an important factor for highly charged systems like IDPs. For this project, a prototypical protein with disordered regions, p53, was simulated with two protein partners, the nuclear coactivator domain of the CREB binding protein (CBP), and the E3 ubiquitin-protein ligase mouse double minute 2 (MDM2). p53 is widely studied, and the p53 transactivation domain (TAD) is disordered and binds to many structurally diverse partners, making this protein domain a useful model for probing the role of electrostatic interactions formed by IDPs at protein-protein binding interfaces. We found that the Drude-2019 FF allows for simulation of the p53 TAD with Cα chemical shifts comparable to those observed with NMR, supporting that the Drude-2019 FF performs well in simulating IDPs. We observed large relative change in sidechain dipole moments when comparing the p53 TAD alone and when bound to either CBP or MDM2. We observed that aliphatic and aromatic amino acids experienced the largest relative change in sidechain dipole moments, and that there is sensitivity to binding shown in this dipole response. The largest percent changes in sidechain dipole moment were found to localize at and around the binding interface. Understanding the binding interactions of IDPs at a fundamental level, including the role of electrostatic interactions, may help with targeting IDPs or their partners for drug design. / Master of Science in Life Sciences / Many proteins adopt one main structure, and these proteins are called ordered proteins. Intrinsically disordered proteins (IDPs) are an abundant category of proteins which adopt multiple structures, and transition between these different structures is based on factors such as the environment around them, modifications, or interactions with other macromolecules. The flexible structures of IDPs allow them to bind to multiple different partners and to regulate processes in the cell. Since IDPs often regulate processes important to cell function, when these proteins are mutated, misfolded, or otherwise mis-regulated the resulting issues are associated with disease states. IDPs are widely studied with analytical techniques, but because IDPs frequently change shape it can be difficult to observe certain behaviors or certain factors with these techniques. Computational approaches, such as molecular dynamics (MD). MD is the study of molecular motion and interaction, and can allow observation of factors that would be difficult or impossible to observe otherwise, such as the varying structures of IDPs or the dipole moments of specific amino acids within the proteins. For this project we wanted to probe the role of dipole moments, which are charge-based interactions, in the binding of IDPs to protein partners, to better understand how IDPs bind to different partners. We used the p53 protein as an example of IDP binding and simulated it alone and bound to two other proteins, the CREB binding protein (CBP), and the E3 ubiquitin-protein ligase mouse double minute 2 (MDM2). We observed that our simulations were comparable to experiments done with nuclear magnetic resonance spectroscopy, which served to validate that our simulations were realistic. We observed that the dipole moments of the proteins change when simulating the proteins alone and in complex, and that the largest relative changes in dipole are observed for regions of the proteins involved in binding. Probing the role of charge-based interactions in protein-protein binding interactions for IDPs can help us to greater understand these interactions at a more fundamental level and could help with targeting IDPs or their partners for drug design or other problems. Intrinsically disordered proteins p53 transactivation domain molecular dynamics Drude-2019 force field electrostatic interactions MDM2 CBP
22	Interaction Between Antimicrobial Peptides and Phospholipid Membranes : Effects of Peptide Length and Composition Ringstad, Lovisa January 2009 (has links) Due to increasing problems with bacterial resistance development, there is a growing need for identifying new types of antibiotics. Antimicrobial peptides constitute an interesting group of substances for this purpose, since they are believed to act mainly by disrupting the bacterial membrane, which is a fast and non-specific mechanism. In order to understand the details on this action simplified phospholipid model membranes based on liposomes, monolayers and bilayers, were employed in this thesis. By in situ ellipsometry studies on supported lipid bilayers in combination with leakage from liposomes it was found that peptide-induced membrane rupture to a great extent is related to peptide adsorption. The peptide activity and mechanism of action is highly dependent on peptide properties such as length, topology, charge, and hydrophobicity. Electrostatic interactions are crucial for peptide adsorption, whereas α-helix formation is of less importance, demonstrated by the dominating peptide conformation being random coil both in absence and presence of membranes, as investigated by circular dichroism. Comparable effects were observed in both mono- and bilayer systems, showing that formation of transmembrane structures is no prerequisite for membrane rupture by complement-derived peptides. Electrochemical studies on these peptides further demonstrated that hydrophobic interactions facilitate peptide penetration into the membrane, causing defects in close proximity to the peptides, while strong electrostatic interactions arrest the peptide in the headgroup region. Increasing the peptide hydrophobicity, by e.g., tryptophan end-tagging, also increases salt resistance. Good correlations were found between model membrane investigations and antibacterial activity towards both Gram-negative and Gram-positive bacteria, showing that membrane rupture is a key mechanism of action for the peptides investigated. In addition, for all peptides investigated cell toxicity is low. Adsorption antibacterial antimicrobial peptide bilayer ellipsometry electrochemistry electrostatic interactions hydrophobicity liposome membrane monolayer phospholipid secondary structure supported bilayer. PHARMACY FARMACI
23	Surfactants in nonpolar oils: agents of electric charging and nanogel templates Guo, Qiong 27 March 2012 (has links) This thesis studies the formation of mobile and surface-bound electric charges in nonpolar liquids. Unlike aqueous media with their natural abundance of charged species, liquids of low dielectric constant do not readily accommodate charges, but can do so in the presence of certain surfactant additives. Surfactant-mediated charging in nonpolar oils has long been exploited industrially, but the underlying charging mechanisms are far from understood. The present work seeks clarification by comparing the effect of ionic and nonionic surfactants on the conductivity of nonpolar solutions and the electrophoretically observable surface charge of suspended polymer particles. Both types of surfactant are found to generate mobile ions in solution as well as particle charge; and in the more surprising case of nonionic surfactants, the occurrence of particle charge and screening ions is confirmed independently by measurements of the electrostatic particle interaction energy. A systematic variation of the particle material and functionalization, the residual water content, and the surfactant concentration above and below the critical micelle concentration provides insights about the possible charging pathways. Reverse surfactant micelles are explored not only as charging agents, but also as reactors and templates for the synthesis of novel nanogels with promise for drug delivery. Synthesis via copper-free Click chemistry is shown to allow for better control of the particle size than a more conventional polymerization scheme, while avoiding metal catalysts and free radicals that are considered hazardous for most biomedical applications. Colloidal particles stability Electrostatic interactions Electrophoretic mobility Conductivity in nonpolar media Charge fluctuation Nanogels Nanostructured materials Electrostatics
24	Σχεδιασμός και εφαρμογή αλγορίθμων υπολογισμού ηλεκτροστατικών δυνάμεων σε μοριακά συστήματα Θεοδωράτου, Αντιγόνη 08 July 2011 (has links) Στην παρούσα εργασία σχεδιάστηκε και εφαρμόστηκε ένας νέος αλγόριθμος χειρισμού των ηλεκτροστατικών αλληλεπιδράσεων. Οι αλληλεπιδράσεις ηλεκτροστατικής φύσεως αποτελούν αντικείμενο εκτενούς μελέτης στον ερευνητικό κλάδο των μοριακών προσομοιώσεων. Ιδιαίτερα σε βιολογικά μοριακά συστήματα, τα οποία αποτελούνται από υδατικά διαλύματα πολυηλεκτρολυτών, οι ηλεκτροστατικές αλληλεπιδράσεις κυριαρχούν. Η ευρέως διαδεδομένη μέθοδος άθροισης κατά Ewald η οποία χαρακτηρίζεται για την ακρίβεια της, είναι ιδιαίτερα απαιτητική σε υπολογιστικό χρόνο δεδομένου ότι κλιμακώνεται ως Ν2, όπου Ν ο συνολικός αριθμός φορτίων του συστήματος. Στην παρούσα εργασία περιγράφεται η προσεγγιστική μέθοδος σφαιρικής αποκοπής για την περίπτωση πολυηλεκτρολυτών. Έως σήμερα, η μέθοδος της σφαιρικής αποκοπής έχει εφαρμοστεί σε μοριακά συστήματα ιοντικών κρυστάλλων. Σύμφωνα με τη μέθοδο αυτή, εισάγοντας μια σφαιρική αποκοπή στον υπολογισμό του ηλεκτροστατικού δυναμικού και παράλληλα επιτυγχάνοντας ηλεκτροουδετερότητα του υπό εξέταση σφαιρικού συστήματος, πραγματοποιείται μείωση του υπολογιστικού χρόνου σε δίχως σημαντικές απώλειες σε ακρίβεια. Στην παρούσα εργασία σχεδιάστηκε ο αλγόριθμος της σφαιρικής αποκοπής για δύο κατηγορίες μορίων: τους πολυηλεκτρολύτες χωρίς ενδομοριακές αλληλεπιδράσεις όπως είναι το μόριο του νερού και τους πολυηλεκτρολύτες με ενδομοριακές αλληλεπιδράσεις όπως είναι τα μόρια CiEj των αλκυλικών αιθέρων πολυ-(οξυ-αιθυλενίου). Επιπρόσθετα, επεκτείναμε τη μέθοδο άθροισης κατά Ewald για την εφαρμογή της σε πολυηλεκτρολύτες, χωρίς και με ενδομοριακές αλληλεπιδράσεις προκειμένου να προχωρήσουμε σε σύγκριση της ακριβής μεθόδου Ewald με τα αποτελέσματα του νέου αλγορίθμου της σφαιρικής αποκοπής. Συγκρίνοντας τα αριθμητικά αποτελέσματα των δύο μεθόδων για τα δύο διαφορετικά είδη πολυηλεκτρολυτών ( H2Ο και CiEj ) από ατομιστικές προσομοιώσεις μοριακής δυναμικής οδηγηθήκαμε σε πλήρη συμφωνία των δύο μεθόδων γεγονός που επιβεβαιώνει την εγκυρότητας της νέας μεθόδου. Επίσης, μέσω των αποτελεσμάτων των προσομοιώσεων μοριακής δυναμικής μελετήθηκαν οι θερμοδυναμικές, δομικές και δυναμικές ιδιότητες των δύο συστημάτων. Η παρούσα εργασία είναι δομημένη ως εξής: Στο πρώτο κεφάλαιο γίνεται μια εισαγωγή στο θεωρητικό υπόβαθρο προσομοιώσεων μοριακής δυναμικής. Στο δεύτερο κεφάλαιο περιγράφονται οι μέθοδοι χειρισμού των ηλεκτροστατικών αλληλεπιδράσεων που συναντούμε έως σήμερα στη βιβλιογραφία. Στη συνέχεια, στο κεφάλαιο 3 περιγράφεται ο αλγόριθμος της σφαιρικής αποκοπής. Στο τέταρτο κεφάλαιο παρουσιάζονται τα αποτελέσματα από τις προσομοιώσεις μοριακής δυναμικής με τις μεθόδους σφαιρικής αποκοπής και άθροισης κατά Ewald. / - Μοριακή δυναμική Άθροιση κατά Ewald 541.394 Molecular dynamics Electrostatic interactions Ewald sum Spherical truncation
25	Electrostatic Networks and Mechanisms of ΔpH-Dependent Gating in the Human Voltage-Gated Proton Channel Hv1 Bennett, Ashley L 01 January 2019 (has links) The structure of the voltage-gated proton (H+) channel Hv1 is homologous to the voltage sensor domain (VSD) of tetrameric voltage-gated Na+, K+ and Ca2+ channels (VGCs), but lacks a pore domain and instead forms a homodimer. Similar to other VSD proteins, Hv1 is gated by changes in membrane potential (V), but unlike VGCs, voltage-dependent gating in Hv1 is modulated by changes in the transmembrane pH gradient (DpH = pHo - pHi). In Hv1, pHo or pHi changes shift the open probability (POPEN)-V relation by ~40 mV per pH unit. To better understand the structural basis of pHo-dependent gating in Hv1, we constructed new resting- and activated-state Hv1 VSD homology models using physical constraints determined from experimental data measured under voltage clamp and conducted all-atom molecular dynamics (MD) simulations. Analyses of salt bridges and calculated pKas at conserved side chains suggests the existence of intracellular and extracellular electrostatic networks (ICEN and ECEN, respectively) that stabilize resting- or activated-state conformations of the Hv1 VSD. Structural analyses led to a novel hypothesis: two ECEN residues (E119 and D185) with coupled pKas coordinately interact with two S4 ‘gating charge’ Arg residues to modulate activated-state pHo sensitivity. Experimental data confirm that pH-dependent gating is compromised at acidic pHo in Hv1 E119A-D185A mutants, indicating that specific ECEN residue interactions are critical components of the ∆pH-dependent gating mechanism. E119 and D185 are known to participate in extracellular Zn2+ coordination, suggesting that H+ and Zn2+ utilize similar mechanisms to allosterically modulate the activated/resting state equilibrium in Hv1. Hv1 voltage sensor domain pH-dependent gating pKa salt bridge electrostatic interactions Biochemistry Biophysics Cellular and Molecular Physiology Structural Biology
26	Ion Channel (mimetic) Sensors : Mechanism of Charge Propagation through Thiol-, Protein- and Dendrimer-Modified Electrodes Degefa, Tesfaye Hailu 22 December 2005 (has links) The mechanism of ion channel (mimetic) sensors (ICSs) consisting of (poly)electrolyte type alkane thiol, protein or dendrimer self assembled monolayers (SAMs) at gold electrodes as a sensing layer and highly charged redox-active marker ions in solution was investigated by cyclic voltammetry (CV), differential pulse voltammetry (DPV) and rotating disk voltammetry (RDV) in the presence of a series of analytes, i.e, suppressor and enhancer ions, leading to the following general statements: (i) electrostatic binding of marker ions to the sensing layer is a prerequisite for an electrochemical current and (ii) charge propagation through the layer consists of electron hopping between surface-confined marker ions and solution born marker ions. It is further shown that there exists (iii) competition between equally charged ions for coordination sites at the oppositely charged sensing layer. An apparent charge inversion (iv) by surface confinement of multiple charged counter ions occurs. Thereby an existing electron transfer (ET) path can be cut or a new one can be induced. Build up of a second layer of multiple charged electroactive ions (v) can take place on top of the charge inverted layer. Competing ET (vi) through the inner and outer redox layer can take place. In addition to fundamental insight into the mechanism of charge propagation, valuable information for the design, optimization, and tailoring of new biosensors based on the ICS concept, the possibilities of exploiting layer-by-layer electrostatic SAMs and dendrimer-DNA interaction for bioanalytical applications are demonstrated by the current findings. Self assembled monolayer Marker ions Electrostatic interactions Electron transfer catalysis Ion channel (mimetic) sensors 30.14 30 - Chemie ddc:670
27	Investigation of Halogen Bonding Interactions Through Solid-State Nuclear Magnetic Resonance and Nuclear Quadrupole Resonance Morin, Vincent 26 April 2021 (has links) Electrostatic interactions such as halogen bonding and pnictogen bonding interactions have gained a lot of interest in the field of crystal engineering and pharmaceutical science. In the first part of this thesis, we expand our knowledge on anion coordinated halogen bonded cocrystals by looking at a series of cocrystals made from 3-iodoethynyl pyridine and 3-iodoethynylbenzoic acid. We utilize the power of mechanochemistry to create the new cocrystals made with phosphonium salts and use multinuclear solid-state nuclear magnetic resonance spectroscopy and X-ray diffraction and characterize them. We found that mechanochemistry is a fast and powerful tool to explore and synthesize new halogen bonded cocrystals and ³¹P solid-state NMR is a rapid way to identify the formation of a cocrystal. In the second part, we look at the versatility of the pnictogen atom, specifically antimony, as a pnictogen bond donor and a halogen bond acceptor. We evaluate these electrostatic interactions with nuclear quadrupolar resonance and found that nuclear quadrupole resonance is a strong spectroscopy tool to probe these types of electrostatic interactions. Solid-state nuclear magnetic resonance Nuclear quadrupole resonance Electrostatic interactions Pnictogen bonding Halogen bonding X-ray diffraction
28	The birth and growth of the protein folding nucleus : Studies of protein folding focused on critical contacts, topology and ionic interactions Hedberg, Linda January 2008 (has links) <p>Proteins are among the most complex molecules in the cell and they play a major role in life itself. The complexity is not restricted to just structure and function, but also embraces the protein folding reaction. Within the field of protein folding, the focus of this thesis is on the features of the folding transition state in terms of growing contacts, common nucleation motifs and the contribution of charged residues to stability and folding kinetics. </p><p>During the resent decade, the importance of a certain residue in structure formation has been deduced from Φ-value analysis. As a complement to Φ-value analysis, I present how scatter in a Hammond plot is related to site-specific information of contact formation, Φ´(β<sup>TS</sup>), and this new formalism was experimentally tested on the protein L23. The results show that the contacts with highest Φ growth at the barrier top were distributed like a second layer outside the folding nucleus. This contact layer is the critical interactions needed to be formed to overcome the entropic barrier. </p><p>Furthermore, the nature of the folding nucleus has been shown to be very similar among proteins with homologous structures and, in the split β-α-β family the proteins favour a two-strand-helix motif. Here I show that the two-strand-helix motif is also present in the ribosomal protein S6 from<i> A. aeolicus</i> even though the nucleation and core composition of this protein differ from other related structure-homologues. </p><p>In contrast to nucleation and contact growth, which are events driven by the hydrophobic effect, my most recent work is focused on electrostatic effects. By pH titration and protein engineering the charge content of S6 from <i>T. thermophilus</i> was altered and the results show that the charged groups at the protein surface might not be crucial for protein stability but, indeed, have impact on folding kinetics. Furthermore, by site-specific removal of all acidic groups the entire pH dependence of protein stability was depleted.</p> protein folding protein stability two-state folding chevron plot transition-state movements Hammond behaviour topology electrostatic interactions pH dependence mass-action protein engineering pKa Biochemistry Biokemi
29	The birth and growth of the protein folding nucleus : Studies of protein folding focused on critical contacts, topology and ionic interactions Hedberg, Linda January 2008 (has links) Proteins are among the most complex molecules in the cell and they play a major role in life itself. The complexity is not restricted to just structure and function, but also embraces the protein folding reaction. Within the field of protein folding, the focus of this thesis is on the features of the folding transition state in terms of growing contacts, common nucleation motifs and the contribution of charged residues to stability and folding kinetics. During the resent decade, the importance of a certain residue in structure formation has been deduced from Φ-value analysis. As a complement to Φ-value analysis, I present how scatter in a Hammond plot is related to site-specific information of contact formation, Φ´(βTS), and this new formalism was experimentally tested on the protein L23. The results show that the contacts with highest Φ growth at the barrier top were distributed like a second layer outside the folding nucleus. This contact layer is the critical interactions needed to be formed to overcome the entropic barrier. Furthermore, the nature of the folding nucleus has been shown to be very similar among proteins with homologous structures and, in the split β-α-β family the proteins favour a two-strand-helix motif. Here I show that the two-strand-helix motif is also present in the ribosomal protein S6 from A. aeolicus even though the nucleation and core composition of this protein differ from other related structure-homologues. In contrast to nucleation and contact growth, which are events driven by the hydrophobic effect, my most recent work is focused on electrostatic effects. By pH titration and protein engineering the charge content of S6 from T. thermophilus was altered and the results show that the charged groups at the protein surface might not be crucial for protein stability but, indeed, have impact on folding kinetics. Furthermore, by site-specific removal of all acidic groups the entire pH dependence of protein stability was depleted. protein folding protein stability two-state folding chevron plot transition-state movements Hammond behaviour topology electrostatic interactions pH dependence mass-action protein engineering pKa Biochemistry Biokemi
30	Thermodynamic and Spectroscopic Studies on the Molecular Interaction of Doxorubicin (DOX) with Negatively Charged Polymeric Nanoparticles Gaurav, Raval 26 November 2012 (has links) The aim of this study was to investigate the molecular interactions of the anti-cancer drug Doxorubicin (DOX) with poly(methacrylic acid) grafted starch nanoparticles (PMAA-g-St). In order to fully understand the DOX/PMAA-g-St system, we conducted in-depth studies on DOX dimer dissociation and DOX/PMAA-g-St binding interactions using various techniques such as isothermal titration calorimetry (ITC), dynamic light scattering (DLS), and fluorescence and absorption spectroscopy. Based on our experimental results, we developed a quantitative thermodynamic model with relevant parameters such as dissociation constant, Kd, as well as enthalpy of binding, ΔH, in order to explain DOX/PMAA-g-St interactions. In addition, we also studied the effect of environmental factors such as pH and NaCl on DOX self-association and DOX/PMAA-g-St complex formation. In conclusion, the combination of results obtained from various techniques as well as the multispecies equilibrium model, enables us to interpret quantitatively the data of drug loading onto and release from polymeric nanoparticles. Doxorubicin Isothermal Titration Calorimetry Dynamic Light Scattering Drug/Polymer Interactions Electrostatic Interactions Specific binding Mechanism of binding effect of sodium chloride effect of pH 0491 0494 0495 0572

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