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The interaction of sequence-specific ligands with the nucleosomeLeslie, Kristofer David January 2001 (has links)
No description available.
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The Role of the Lipid Bilayer in P-glycoprotein Drug Binding, Transport and Catalytic FunctionsClay, Adam Thomas 16 December 2011 (has links)
The ABC protein P-glycoprotein (Pgp, ABCB1) transports many structurally diverse substrates from the lipid bilayer. Previous studies demonstrated the importance of the membrane environment, but few have quantified these effects. In the present work, purified Pgp reconstituted into defined lipid systems was employed. Drug binding affinities were determined using Trp quenching, and drug-lipid partitioning by equilibrium dialysis. Pgp bound substrates from the bilayer with affinities in the millimolar range; both drug-Pgp and drug-lipid interactions were important. The kinetics of Pgp-mediated drug transport were sensitive to drug structure and lipid environment. The rate of transport is proposed to depend on the affinity of Pgp for substrate and conformational changes. The lipid bilayer affected the stability of Pgp catalytic activity which provided evidence for distinct basal and drug-stimulated ATPase cycles. Overall, the lipid environment had pronounced effects on Pgp-mediated drug binding, transport and catalytic functions. / Canadian Cancer Society
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Characterisation of cytochrome P450 azole drug-resistant sterol demethylase CYP51B1 and expression of CYP123 and CYP136 from Mycobacterium tuberculosisFernandez, Christine Cheryl January 2011 (has links)
Tuberculosis (TB) affects nearly a third of the world’s population and has been termed a ‘Global Emergency’ by the WHO. The emergence of multi/extensively drug resistant (M/XDR) strains of Mycobacterium tuberculosis (Mtb), the causative agent of TB, and the increasing incidences of azole drug resistant sterol demethylases (CYP51) from pathogenic fungi has propelled studies to understand mechanisms of azole drug resistance on the drug target CYP51. Since Mtb is devoid of a sterol biosynthetic pathway, the presence and study of CYP51B1 and 19 other Cytochrome P450s in its genome is important to clarify host-pathogen mechanism of infection and the potential of using azole drugs to treat TB. In this study, CYP51B1 from Mtb was used as the model enzyme to study CYP51 mutants from Candida albicans fluconazole-resistant clinical strains. By protein engineering methods, F89H, L100F, S348F, G388S and R391K CYP51B1 mutants were made and azole drug binding properties were investigated using stopped-flow kinetics and static equilibrium methods. Dissociation constant (Kd) values were derived for a range of commercially available azole drugs by fitting the equilibrium binding data to a hyperbolic equation. Kd values for stopped-flow kinetics were derived by plotting observed binding rates (kobs) across different azole drug concentrations against time, followed by fitting multiple kobs data to a linear equation to derive azole drug de-binding (koff) and binding (kon) rate constants – the Kd was obtained by koff/kon. Extinction coefficient for heme b content in mutants and Wild Type (WT) CYP51B1 were an average of ɛ419 = 96.1 mM-1 cm-1. Biochemical characterisation of the mutants were carried out using established experiments on CYP51 – reduction of Fe(III)-heme to Fe(II)-heme, NO binding to Fe(III)-heme, rates of CO-Fe(II) adduct formation and rates of collapse of the P450 to P420 species in the presence of CO and estriol with redox partners from Mtb. In order to elucidate the effects of the above mutations on the iron-heme catalytic region, electron paramagnetic resonance (EPR) experiments were carried out with and without azole drugs. Circular dichroism (CD), differential scanning calorimetry (DSC) and multi-angled laser light scattering (MALLS) analysis confirmed that F89H, R391K and L100F mutants were stable and homogeneous. Crystallogenesis was successful for the above mentioned mutants and atomic structures were obtained for all mutants and WT CYP51B1 (in ligand-bound and substrate-free forms), except for S348F and G388S mutants which were expressed as inclusion bodies and 60% holoenzyme, respectively. Reconstituted catalytic assays to determine the sterol demethylating propensity of the mutants were carried out using redox partners from Mtb or E. coli, and with lanosterol and dihydrolanosterol as the surrogate substrates. Redox potentiometry showed similar potentials to WT for all mutants except for the G388S mutant which was relatively positive (–102 mV). Redox cycling experiments followed by EPR analysis for mutants and WT resulted in a novel P450 high-spin species at g value 5.84 (80 %) which gradually collapsed to the initial low spin state over 48 h. Expression trials were concurrently carried out on two other Mtb P450 genes – CYP123 (Rv0744c) and CYP136 (Rv3059) products of which may have similar functions to CYP51B1 or may share similar redox partners. CYP123 is located on the same operon as CYP51B1 while CYP136 has a 29% sequence identity to another CYP51 from a marine slime bacterium. Although further work is necessary, in this study CYP123 was expressed totally as inclusion bodies while CYP136 was expressed as soluble apoprotein fused with trigger factor chaperone.
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Characterizing drug interactions in the substrate binding pocket of the P-glycoprotein multidrug efflux pumpWard, David 02 February 2012 (has links)
P-glycoprotein (Pgp, ABCB1) is a polyspecific efflux transporter implicated in multidrug resistance in human cancers. In this study, tetramethylrhodamine-5-carbonyl azide (AzTMR) was covalently crosslinked to the Pgp drug binding pocket with a stoichiometry of 1. The Pgp-AzTMR adduct was functionally equivalent to unlabelled Pgp and retained its ability to transport Hoechst 33342. The binding site of AzTMR in Pgp was nonpolar, with a similar environment to that of propanol. Pgp-AzTMR could bind a second drug molecule, with a higher affinity for H-site drugs and lower affinity for other R-site drugs. Unlabelled Pgp interacted with dimeric versions of known Pgp modulators, binding them with higher affinity than the monomer. These compounds were also found to either stimulate or inhibit Pgp ATPase activity depending on the concentration. Pgp-AzTMR was able to bind dimeric drugs, indicating that 3 substrate moieties can fit into the binding pocket. / The Canadian Cancer Society
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Mathematical and computational models of drug transport in tumoursGroh, C.M., Hubbard, M.E., Jones, P.F., Loadman, Paul, Periasamy, Nagarajan, Sleeman, B.D., Smye, S.W., Twelves, Christopher J., Phillips, Roger M. 12 March 2014 (has links)
No / The ability to predict how far a drug will penetrate into the tumour microenvironment
within its pharmacokinetic (PK) lifespan would provide
valuable information about therapeutic response. As the PK profile is directly
related to the route and schedule of drug administration, an in silico tool
that can predict the drug administration schedule that results in optimal
drug delivery to tumours would streamline clinical trial design. This paper
investigates the application of mathematical and computational modelling
techniques to help improve our understanding of the fundamental mechanisms
underlying drug delivery, and compares the performance of a simple
model with more complex approaches. Three models of drug transport are
developed, all based on the same drug binding model and parametrized by
bespoke in vitro experiments. Their predictions, compared for a ‘tumour
cord’ geometry, are qualitatively and quantitatively similar. We assess the
effect of varying the PK profile of the supplied drug, and the binding affinity
of the drug to tumour cells, on the concentration of drug reaching cells and the
accumulated exposure of cells to drug at arbitrary distances from a supplying
blood vessel. This is a contribution towards developing a useful drug transport
modelling tool for informing strategies for the treatment of tumour
cells which are ‘pharmacokinetically resistant’ to chemotherapeutic strategies.
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Multi-cavity molecular descriptor interconnections: Enhanced protocol for prediction of serum albumin drug bindingAkawa, O.B., Okunlola, F.O., Alahmdi, M.I., Abo-Dya, N.E., Sidhom, P.A., Ibrahim, M.A.A., Shibl, M.F., Khan, Shahzeb, Soliman, M.E.S. 03 November 2023 (has links)
Yes / The role of human serum albumin (HSA) in the transport of molecules predicates its involvement in the determination of drug distribution and metabolism. Optimization of ADME properties are analogous to HSA binding thus this is imperative to the drug discovery process. Currently, various in silico predictive tools exist to complement the drug discovery process, however, the prediction of possible ligand-binding sites on HSA has posed several challenges. Herein, we present a strong and deeper-than-surface case for the prediction of HSA-ligand binding sites using multi-cavity molecular descriptors by exploiting all experimentally available and crystallized HSA-bound drugs. Unlike previously proposed models found in literature, we established an in-depth correlation between the physicochemical properties of available crystallized HSA-bound drugs and different HSA binding site characteristics to precisely predict the binding sites of investigational molecules. Molecular descriptors such as the number of hydrogen bond donors (nHD), number of heteroatoms (nHet), topological polar surface area (TPSA), molecular weight (MW), and distribution coefficient (LogD) were correlated against HSA binding site characteristics, including hydrophobicity, hydrophilicity, enclosure, exposure, contact, site volume, and donor/acceptor ratio. Molecular descriptors nHD, TPSA, LogD, nHet, and MW were found to possess the most inherent capacities providing baseline information for the prediction of serum albumin binding site. We believe that these associations may form the bedrock for establishing a solid correlation between the physicochemical properties and Albumin binding site architecture. Information presented in this report would serve as critical in provisions of rational drug designing as well as drug delivery, bioavailability, and pharmacokinetics.
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Intracellular unbound drug concentrations : Methodology and application for understanding cellular drug exposureMateus, André January 2016 (has links)
Most known drug targets and metabolizing enzymes are located inside cells. Interactions with these proteins are determined by intracellular unbound drug concentrations. Assessing intracellular drug exposure is technically challenging, but essential for predicting pharmacokinetic, pharmacological, and toxicological profiles of new drugs. This thesis aims at establishing and applying a straightforward methodology to measure intracellular unbound drug concentrations. This was achieved by separately measuring cellular drug binding (fu,cell), and total intracellular drug accumulation (Kp). This allowed the calculation of intracellular drug bioavailability (Fic), which represents the fraction of the concentration added to the cells that is unbound in the cell interior. The methodology was initially developed in HEK293 cells, where the Fic of 189 drug-like compounds was measured. Binding to HEK293 cells was governed by compound lipophilicity and was correlated with binding to more complex systems, such as hepatocytes and brain. Due to negligible expression of drug transporters, Fic in this cell line was consistent with pH-dependent subcellular sequestration of lipophilic cations in low pH compartments. The methodology was then applied to study the effects of drug transporters on Fic. The uptake transporter OATP1B1 increased the Fic of its substrates in a concentration-dependent manner. In contrast, the Fic of P-gp substrates was decreased when P-gp was present. In human hepatocytes, the methodology allowed the determination of Fic without prior knowledge of transporter mechanisms or metabolic activity. Finally, the methodology was applied to measure the impact of Fic on target binding and cellular drug response. Intracellular concentrations of active metabolites of pro-drugs targeting the intracellular target thymidylate synthase were in agreement with the level of binding to this target. Further, high Fic was generally required for kinase and protease inhibitors to be active in cellular assays. In conclusion, the methodology can be used to predict if new drug candidates reach their intracellular targets in sufficient amounts. Furthermore, the methodology can improve in vitro predictions of drug clearance and drug-drug interactions, by measuring the drug available for intracellular enzymes. Finally, this work can be expanded to other xenobiotics, e.g., to predict their intracellular toxicity.
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Targeting the mevalonate pathway for pharmacological interventionTsoumpra, Maria January 2011 (has links)
Farnesyl pyrophosphate synthase (FPPS) is a key branch point enzyme in the mevalonate pathway and the main molecular target of nitrogen-containing bisphosphonates (N-BPs), potent inhibitors of osteoclastic activity and the leading drug of choice for conditions characterized by excessive bone resorption. The main aim of this thesis is to investigate the interaction of N-BPs with FPPS in order to gain further insights into the mechanism of drug inhibition. Kinetic and crystallographic studies following site-directed mutagenesis of FPPS reveal key residues involved in stabilization of carbocation intermediate, substrate binding and formation of a tight enzyme-inhibitor complex. The aromatic ring of Tyr204 is involved in N-BP binding but not in the catalytic mechanism, where the hydroxyl moiety plays an important role. Lys200 is implicated in regulation of substrate binding, product specificity and enzyme isomerization which leads to a tight binding inhibition. Phe239 is considered important for the FPPS C-terminal switch which stabilizes substrate binding and promotes the inhibitor induced isomerized state. The highly conserved Arg112, Asp103 and Asp107 are pivotal for catalysis. Successful purification of the full length of Rab geranylgeranyl transferase (RGGT) complex downstream of the FPPS in the mevalonate pathway was achieved and may lead to co-crystallization with BP analogues and identification of the putative site of drug binding. Investigation of the in vitro effect of N-BPs on osteoclastogenesis suggest a correlation with FPPS inhibition kinetics for the most potent N-BPs but indicate an alternative mechanism of the disruption of bone resorption by alendronate. Together these results highlight the importance of the multiple interactions of N-BPs with side-chain residues of FPPS which dictate their strength of binding and advance the understanding of their pharmacophore effect.
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Computational Method for Drug Target Search and Application in Drug DiscoveryChen, Yuzong, Li, Zerong, Ung, C.Y. 01 1900 (has links)
Ligand-protein inverse docking has recently been introduced as a computer method for identification of potential protein targets of a drug. A protein structure database is searched to find proteins to which a drug can bind or weakly bind. Examples of potential applications of this method in facilitating drug discovery include: (1) identification of unknown and secondary therapeutic targets of a drug, (2) prediction of potential toxicity and side effect of an investigative drug, and (3) probing molecular mechanism of bioactive herbal compounds such as those extracted from plants used in traditional medicines. This method and recent results on its applications in solving various drug discovery problems are reviewed. / Singapore-MIT Alliance (SMA)
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Identifications des interactions des inhibiteurs connus des canaux HCNs.Tanguay, Jeremie 08 1900 (has links)
Les canaux activés par l’hyperpolarisation et sensibles aux nucléotides cycliques (hy- perpolarization cyclic nucleotide-gated channel; HCN) ont un rôle dans la régulation du rythme cardiaque ainsi que dans la transmission des influx nerveux. De nombreuses pathologies sont causées par un disfonctionnement de ces canaux. A ce jour, Ivabradine représente la seule molécule utilisée comme médicament, mais malgré sa spécificité en- vers les canaux HCNs, elle n’est pas sélective entre les isoformes de la famille HCN. Dans le but d’identifier une molécule plus adéquate pour le traitement qu’Ivabradine, nous avons analysé l’interaction entre les canaux HCNs et 9 bloqueurs connus garce à l’arrimage moléculaire. Cette analyse nous a permis d’identifier les résidus nécessaires pour la liaison des ligands. On observe aussi qu’Ivabradine ne forme aucune liaison so- lide avec les canaux HCNs mais ne fait que bloquer le passage par sa présence tout comme ses dérivées Zatebradine et Cilobradine. Les ligands de plus petites tailles quant à eux, se logent dans une cavité hydrophobe et forme des liaisons stable avec les pro- téines. Nos résultats semblent suggérer que le blocage par Ivabradine est plus efficace, mais que les liaisons stables des petits ligands possèdent un potentiel plus grand vers une meilleure affinité. Par contre, les interactions observées suggèrent que la spécificité envers les isoformes proviendrait des cinétiques des canaux et des dépendances d’états des ligands plutôt que des interactions identifiées. Pour finir, l’arrimage des ligands sur la conformation fermé du canal HCN1 suggère qu’il existerait une conformation fermée- liée non connue puisqu’aucun ligand n’a pu accéder au pore. / HCN channels have a role in regulating heart rate as well as in the transmission of nerve impulses. Many pathologies are caused by a malfunction of these channels. To date, Ivabradine is the only molecule used as a drug, but despite its specificity for HCN chan- nels, it is not selective between the isoforms of the HCN family. In order to identify a molecule more suitable for the treatment than ivabradine, we analyzed the interaction between HCN family and 9 known blockers using docking. This analysis allowed us to identify the necessary residuals for ligand binding. It is also observed that ivabradine forms no solid bond with the HCN channels but only blocks the passage by its pres- ence, the same was observed for its derivatives Zatebradine and Cilobradine. Ligands of smaller size, for their part, are lodged in a hydrophobic cavity and form stable bonds with the proteins. Our results seem to suggest that blocking with Ivabradine is more effi- cient but that the stable bonds of small ligands have a greater potential for better affinity. However, the observed interactions suggest that the specificity towards isoforms would come from the kinetics of the channels and state dependencies of ligands rather than identified interactions. Finally, the binding of the ligands to the closed conformation of the HCN1 channel suggests that there would be a closed-bound conformation that is not known since no ligand has been able to access the pore.
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