Global ETD Search

1	Interaction du domaine nucleocapside de la polyprotéine Gag du VIH-1 avec la protéine cellulaire Unr : implication sur la traduction IRES-dépendante du virus / Interaction of the nucleocapsid domain of the Human lmmunodeficiency Virus type-1 with the cellular protein Unr : implication in viral IRES dependent translation Taha, Nedal 03 July 2015 (has links) La protéine de nucléocapside (NC) du virus de l’immunodéficience humaine (VIH-1) joue de nombreux rôles dans les phases précoce et tardive de l’infection. La NC est une protéine à deux doigts de zinc, chaperonne des acides nucléiques. Nous avons cherché de nouveaux partenaires cellulaires de la NCp7 et identifié une protéine de liaison aux ARNs, Upstream of N-ras (Unr), dont l’interaction avec Gag et NCp7 a été confirmée. L’interaction entre Gag et Unr est dépendante de l’ARN et médiée par le domaine NC. Unr est une ITAF (IRES transacting factor) régulant la traduction médiée par plusieurs IRESs cellulaires et viraux. L’ARN génomique du VIH-1 possède deux IRESs dont un localisé dans la région non traduite en 5’ qui permet aux ARNm viraux de conserver un fort niveau de traduction lorsque la traduction coiffe-dépendante de la cellule est affaiblie par l’arrêt du cycle viral induit par l’infection. En utilisant un système de dual luciférase, nous avons montré qu’Unr est une ITAF dont la surexpression stimule l’IRES VIH-1. Des mutations ponctuelles de cet IRES, dans un motif consensus de liaison à Unr, altèrent à la fois l’activité de l’IRES et sa réponse à Unr suggérant que l’activité IRES dépend fortement de Unr. L’effet d’Unr sur l’IRES est inhibé par la surexpression de NCp7 mais pas par celle de Gag dont l’effet stimulateur sur l’IRES est additif de celui d’Unr suggérant un rôle d’Unr différent dans les phases précoce et tardive de l’infection. Pour finir, le knockdown de l’expression d’Unr entraîne une diminution significative de l’infection par un pseudovirus non réplicatif soulignant l’implication fonctionnelle d’Unr dans la phase précoce. / The Human Immunodeficiency Virus-1 (HIV-1) nucleocapsid protein (NC), as a mature protein (NCp7) or as a domain of the polyprotein Gag, plays several important roles in both the early and late phase of the infection. NC is a nucleic acid chaperone protein with two zinc fingers. We searched for new cellular protein partners of NCp7 and identified the RNA binding protein Unr, Upstream of N-ras, whose interaction with both Gag and NCp7 was confirmed. Unr interaction with Gag is RNA dependent and mediated by its NC domain. Unr is an ITAF (IRES trans-acting factor) regulating the translation driven by several IRESs. The HIV-1 genomic mRNA harbors two IRESs elements: one of them found within the HIV-1 5’-Untranslated region drives HIV-1 mRNA translation when the cap-dependent translation is diminished due to the infection-induced cell cycle arrest. Using a dual luciferase assay, Unr was shown to act as an ITAF, increasing the HIV-1 IRES dependent translation. Point mutations of the HIV-1 IRES in a consensus Unr binding motif were found to alter both the IRES activity and its activation by Unr suggesting a strong dependency of the IRES on Unr. Unr stimulation effect is furthermore counteracted by NCp7, but not by Gag overexpression, which increases the IRES activity in an additive manner to Unr suggesting a differential Unr effect on the early and late phases of the infection. Finally, knockdown of Unr in HeLa cells leads to a decline in infection by a non-replicative lentivector proving its functional implication in the early phase. VIH Nucléocapside NCp7 Unr Gag IRES HIV Nucleocapsid NCp7 Unr Gag IRES 579.2 572.6
2	Mise en évidence et caractérisation de l'interaction de la protéine de la nucléocapside (NCp7) du VIH-1 avec des membranes lipidiques / Biophysical characterization of the interaction of the nucleocapsid protein (NCp7) of the HIV-1 and lipid membranes Kempf, Noémie 26 June 2014 (has links) La protéine NCp7 du VIH-1 est une cible thérapeutique de choix car, en plus d’être conservée, elle intervient lors de nombreuses étapes du cycle rétroviral. A ce jour, peu de données existent concernant l’interaction possible de NCp7 avec les membranes lipidiques. Or il a récemment été montré que, lors de l’assemblage des virions, le précurseur Gag adopte une conformation repliée qui permettrait à son domaine NC d’interagir avec la membrane plasmique. Dans le but de tester cette hypothèse nous avons utilisé NCp7 sous sa forme mature. Nos résultats indiquent que NCp7, libre ou liée à des acides nucléiques, se lie aux membranes lipidiques chargées négativement, possède la capacité de recruter les lipides chargés négativement de manière à optimiser sa liaison sur la membrane et peut également déstabiliser ces membranes. Finalement, en utilisant un système modèle, nous avons mis au point les conditions de travail pour la poursuite de cette étude à l’aide de la microscopie super-résolutive. / The NCp7 protein is an interesting antiviral target since it is conserved and plays a numerous key roles in the HIV-1 replication cycle. Interestingly, while only few data are currently available on the possible interaction of NCp7 with lipid membranes, it has been recently shown that during assembly, the Gag precursor can adopt a bent conformation where the NC domain may interact with the plasma membrane. In order to check this hypothesis we used the mature NCp7. Our data indicated that the NCp7 protein, free or bound with nucleic acids, binds to negatively charged lipid membrane with high affinity, can recruit negatively charged lipids to optimize its binding to lipid membranes and has the ability of to destabilize negatively charged lipid membranes at high concentrations. Finally, by using a receptor/ligand model system we established the working conditions to investigate Gag/membrane interactions by high resolution microscopy. HIV-1 NCp7 Nucléocapside Liaison AFM Microscopie Fluorescence Lipides HIV-1 NCp7 Nucleocapsid Binding AFM Microscopy Fluorescence Lipids 571.4 579.2
3	Distribution cellulaire de la protéine de la nucléocapside NCp7 du VIH-1 et caractérisation de son interaction avec la protéine nucléolaire hNoL12 / Cellular distribution of the nucleocapsid protein of HIV-1 NCp7 and characterization of its interaction with the nucleolar protein hNoL 12 Zgheib, Sarwat 08 December 2015 (has links) La protéine de nucléocapside (NC) du virus de l’immunodéficience humaine (VIH-1) joue un rôle majeur dans les différentes étapes du cycle viral du VIH-1 : soit comme domaine fonctionnel de la polyprotéine Gag (NC-Gag) dans les phases tardives du cycle viral, soit sous sa forme mature NCp7 dans les phases précoces. Afin de mieux comprendre le rôle de la forme mature dans le cycle viral, nous avons cherché de nouveaux partenaires cellulaires spécifiques de la NCp7 et identifié la protéine nucléolaire, hNoL12, impliquée dans la maturation des ARNs ribosomaux. L’interaction NCp7/hNoL12 a été confirmée par co-IP, FRET-FLIM et double hybride chez la levure et le domaine d’interaction a été localisé entre les a.a. 22 et 61 correspondant au domaine 5’-3’-exonucléase de hNoL12. Nous avons développé un test pour caractériser cette activité et montré qu’elle est spécifique des ARN simples brins. Enfin, l’extinction de l’expression de hNoL12 entraine une diminution significative de l’infection par un lentivecteur modèle des phases précoces de l’infection soulignant l’implication fonctionnelle de hNoL12 dans cette phase de l’infection. Dans un second projet, nous nous sommes intéressés au devenir de la NCp7 dans les cellules infectées, suite à la transcription inverse. Nous avons généré des vecteurs lentiviraux composés de protéines NCp7 fusionnées à une étiquette tétracysteine permettant son marquage spécifique avec le dérivé de la fluorescéine (FlAsH). Nous avons alors étudié, par microscopie confocale, la distribution intracellulaire de la NCp7 dans des conditions proches de l’infection. Nos résultats indiquent qu’une grande partie de la NCp7 se dissocie du PIC durant son transport dans le cytoplasme. Toutefois, la perte de la NCp7 est une étape tardive qui se déroule proche du noyau confirmant ainsi que la décapsidation a lieu à la membrane nucleaire juste avant l’entrée du complexe de préintegration dans le noyau. Le troisième projet a porté sur le développement d’antiviraux ciblant la NCp7. Nous avons travaillé sur la vectorisation et la caractérisation des propriétés antivirales en milieu cellulaire, d’un peptide sélectionné in vitro pour sa capacité à inhiber l’action chaperonne de la NCp7. L’activité antivirale du peptide vectorisé vis-à-vis d’une infection par un vecteur lentiviral basé sur le VIH-1 s’est révélée décevante. / The Human Immunodeficiency Virus-1 (HIV-1) nucleocapsid protein (NC) plays a major role in the different steps of theviral lifecycle under its two forms; either as a domain of the polyprotein Gag (NC-Gag) in the late phase or as a matureNCp7 protein in the early phase. In order to better understand the role of the mature form in the viral cycle, we searchedfor new NCp7 specific cellular partners and identified the nucleolar protein hNoL12 which is known to be involved inthe maturation of ribosomal RNAs. The NCp7/hNoL12 interaction was confirmed by co- IP, FRET-FLIM, and yeast twohybrid. The interaction domain was localized between a.a. 22 and 61 on hNoL12; which corresponds to its putative 5’-3’-exonuclease domain. We developed an assay to monitor this activity and found it to be specific of single strand RNA.Finally, the cellular knockdown of hNoL12 resulted in a significant decrease in the infection by a pseudovirus mimickingthe early phase of the infection, emphasizing the functional involvement of hNoL12 in this phase. In a second project, wewere interested in the fate of the viral incoming NCp7 in the infected cells, after reverse transcription. We thus generatedlentiviral vectors composed of NCp7 fused to a tetracysteine tag enabling its specific labeling with the fluoresceinderivative FlAsH. We then studied by confocal microscopy, the intracellular distribution of NCp7 containing viralparticles in conditions close to the infection. Our results showed that an important proportion of the NCp7 moleculesdissociates from the PIC during its transport in the cytoplasm. However, the loss of NCp7 is a late step of this processand seems to take place close to the nucleus suggesting that the dissociation of the capsid occurs at the nuclear membranejust before the nuclear entry of the PIC. The third project concerns the development of antiviral inhibitors targetingNCp7. We worked on the vectorization and the characterization of the antiviral properties of a peptide selected in vitrofor its ability to inhibit the NCp7 chaperone activity. The inhibitory activity of the vectorized peptide on infection ofHeLa cells by a HIV-1 based lentiviral vector was found deceiving. VIH Nucléocapside NCp7 HNoL12 Exonucléase Lentivecteur FlAsH HIV Nucleocapsid NCp7 HNoL12 Exonuclease Lentivector FlAsH 579.2 616.97 571.96
4	Interactions acides nucléiques/protéines non spécifiques : le nucléosome et les complexes de la NCp7 / Non-specific nucleic acids/protein interactions : nucleosome and NCp7 complexes Retureau, Romain 24 October 2019 (has links) Les protéines régulent et exécutent l'ensemble des fonctions vitales des organismes en interagissant notamment avec les acides nucléiques (AN), dont l’ADN, support de l’information génétique. Appréhender la nature de ces types d’interactions est central en biologie. Le nucléosome, qui est l’unité élémentaire de la compaction de l’ADN chez les cellules eucaryotes, est formé d’un d’ADN enroulé autour d’un cœur protéique d’histone ; il contrôle l’accessibilité de l’ADN en se formant et en se dissociant le long des génomes. Ici, le nucléosome a été modélisé par dynamique moléculaire en solution. L’ analyse de l’interface ADN-histone par une méthode géométrique innovante a permis de comprendre comment la forte cohésion de ce complexe était assurée. La description de l’interface a aussi servi à interpréter des expériences d’assemblage et de désassemblage du nucléosome qui ont par ailleurs démontré l’effet de la séquence d’ADN sur ces processus. Enfin, j’ai comparé les dynamiques de l’ADN nucléosomal et de l’ADN nu, et montré quelles propriétés structurales étaient conservées au sein du nucléosome et comment elles sont utilisées pour moduler l’efficacité de l’association ADN-histones. Une stratégie semblable a été appliquée à des structures expérimentales de complexes entre ADN ou ARN et NCp7, une protéine du VIH-1 chaperon des AN. Cette dernière étude propose un mécanisme d’association entre les partenaires sur des bases rationnelles. Dans ces deux études, je mets en évidence des mécanismes de formation des complexes en plusieurs étapes et j’illustre les préférences de structure et de séquence des AN chez des protéines dites non-spécifiques. / Proteins regulate and perform the vital functions of organisms, in particular by interacting with nucleic acids (NA), including DNA which carries the genetic information. Understanding the nature of these interactions is central in biology. The nucleosome is the basic unit of DNA compaction in eukaryotes. Composed of a DNA wrapped around a histone core, this complex regulates the DNA accessibility by assembling and disassembling along the genome. Here, we carried out molecular dynamic simulations of the nucleosome in solution. The analysis of the DNA-histone interface with an innovative geometrical method highlighted the strong cohesion of the complex. Such an in-depth description of the interface was also used to interpret nucleosome assembly and disassembly experiments. Those experiments emphasized in particular the DNA sequence effect in both assembly and disassembly processes. Finally, the comparison between nucleosomal and free DNA dynamics showed which structural properties were conserved in the complex and how they contributed to the DNA-histone assembly efficiency. A similar strategy was used on experimental structures of NCp7, a HIV-1 NA chaperone protein, complexed with either DNA or RNA. The latter analysis suggested a rational basis to describe the mechanism of partner assembly. In both studies, I evidenced stepwise mechanisms of complex assemblies and I illustrated NA structure and sequence preferences of some so-called non-specific proteins. Nucléosome NCp7 Dynamique moléculaire Nucleosome NCp7 Molecular dynamics
5	Etude de complexes d'inhibiteurs à visée thérapeutique : applications à des métalloprotéines impliquées dans des pathologies / Study of inhibitors complexes with therapeutic properties : applications to metalloproteins involved in pathologies El Khoury, Léa 16 February 2017 (has links) Les fonctions catalytiques de l'intégrase (IN) du Virus de l'Immunodéficience humaine (VIH-1) sont strictement nécessaires pour l'intégration du génome viral dans les cellules hôtes. Aujourd'hui, trois inhibiteurs anti-IN appartenant à la famille des dikétoacides sont utilisés en thérapie : le raltegravir, l'elvitegravir et le dolutegravir. Cependant, les patients traités par ces médicaments développent des mutations de résistance. Dans ce travail, nous cherchons à mieux comprendre le mécanisme d'interaction de ces drogues avec l'ADN viral. Ce travail a également contribué à la conception de molécules qui devraient être dotées d'une affinité augmentée pour l'ADN, permettant de surmonter le problème de la résistance virale. La compréhension du mécanisme d'inhibition de IN s'est poursuivie par l'étude de deux anticorps monoclonaux anti-K159 (peptide 147-175 du coeur catalytique de IN), 4C6 et 4F4. Les résultats montrent que les anticorps reconnaissent leurs épitopes dans l'IN. D'autre part, du fait de son implication dans de nombreuses étapes du cycle du VIH-1, nous ciblons la protéine 7 de la nucléocapside (NCp7). Pour ce faire, nous avons étudié la structure de nos systèmes (NCp7 et NCp7-ADN) et nous avons pu déterminer les interactions clés responsables de la structuration, ainsi que des fonctions, de ces systèmes. Dans un second temps, nous avons évalué les interactions de NCp7 avec un inhibiteur éjecteur de zinc (C247) de la famille des thioesters. Enfin, sur le plan méthodologique, nous avons raffiné dans le potentiel SIBFA (Sum of Interaction Between Fragments Ab initio computed) la représentation des doublets libres de type sp et sp2 dans les molécules conjuguées. / The catalytic functions of integrase (IN) of Human Immunodeficiency Virus (HIV-1) are strictly necessary for the integration of the viral genome into the host cells. To this day, three anti-IN inhibitors belonging to the diketoacids are used in therapy: raltegravir, elvitegravir and dolutegravir. However, under treatments with these drugs, patients develop resistance mutations. In this work, we seek to better understand the interaction of the three drugs with viral DNA. This work also contributed to the design of novel molecules. These should be endowed with increased DNA binding affinities as a step towards overcoming viral resistance. The understanding of the inhibition mechanism of IN was pursued by the study of two monoclonal antibodies, 4F4 and 4C6, which are directed against sequence 147-175 of the catalytic core of HIV-1 IN, a peptide denoted K159. The results show that the antibodies recognize their epitopes in IN. We also aim to target an HIV-1 nucleocaspid protein NCp7 involved in many stages of the viral cycle. We have thus studied the structure of NCp7 and its viral DNA complex. We were able to determine the interactions responsible for the structuring and thus the functions of these complexes. Then, we evaluated the interactions of NCp7 with an inhibitor of the thioester family, C247, which acts as a zinc ejector. Finally, from the methodological standpoint, we have refined in SIBFA (Sum of Interaction Between Fragments Ab initio computed) the representation of the sp2 and sp lone pairs in conjugated molecules. Intégrase du VIH-1 ADN viral Anticorps monoclonaux NCp7 du VIH-1 Thioesters Paires-Libres étalées HIV-1 integrase HIV-1 NCp7 Monoclonal antibodies 547.1
6	The Study of Au(III) Compounds and their Interaction with Zinc Finger Proteins Spell, Sarah 01 January 2014 (has links) Gold compounds have been used in medicine dating back as early as 2500 BC. Over the years gold(I) and gold(III) compounds have been used and designed to target rheumatoid arthritis, cancer, and viral diseases. New drug targets have been found for gold compounds that give insight into their mechanisms of action. Here we focus on the synthesis of Au(III) compounds designed to selectively target zinc finger (ZF) proteins. ZF proteins exhibit a variety of functions, including transcription, DNA repair, and apoptosis. Displacement of the central zinc ion, along with mutation of coordinated amino acids can result in a loss of biological function. Synthesis of complexes that selectively target zinc finger proteins, in turn inhibiting DNA/ZF interactions and therefore resulting in loss of protein function, is of great interest. Of particular interest here is the Cys3His (Cys = cysteine, His = histidine) HIV nucleocapsid zinc finger protein, NCp7. NCp7 is involved in multiple steps of the HIV life cycle, thus making it a desirable drug target. Previous studies from our group show platinated nucleobases such as [Pt(dien)(9-EtG)]2+ (dien = diethylenetriamine; 9-EtG = 9-ethylguanine) to stack effectively in a non-covalent manner with tryptophan of the C-terminal finger of HIV Nucleocapsid, NCp7(F2), a key residue involved in nucleic acid recognition. Due to the isoelectronic and isostructural relationship of Au(III) to Pt(II), we have expanded this system to Au(III)-(nucleobase/N-heterocycle) compounds. Novel Au(III)(dien)(N-heterocycle) compounds, including the first Au(III)N3(N-purine) examples, were synthesized. As previously reported for [AuCl(dien)]Cl2, these compounds exhibit pH dependency of the 1H NMR chemical shifts of the dien ligand. The acidity of the dien ligand is affected by the nature of the fourth ligand as a leaving group. The presence of an inert nitrogen donor, compared to that of the more labile Cl-, as the leaving group stabilizes the Au(III) metal center towards reduction, resulting in significant enhancement of π−π stacking interactions with tryptophan relative to platinum(II) and palladium(II) compounds. The presence of a more inert N-donor as the leaving group slows down the reaction with the sulfur-containing amino acid N-Acetylmethionine (N-AcMet); essentially no reaction was observed for the Au(III)-N-heterocycle compounds. All compounds react readily with N-Acetylcysteine (N-AcCys), however lack of N-heterocycle ligand dissociation indicates, to our knowledge, the first long-lived N-heterocycle-Au-S species in solution. Electrospray ionization mass spectrometry (ESI-MS) studies with NCp7(F2) indicate [Au(dien)(DMAP)]3+ (DMAP = 4-dimethylaminopyridine) to be the least reactive of the Au(III) compounds studied, showing the presence of intact NCp7(F2) zinc finger at initial reaction times. Reactivity of the Au-compounds was compared with that of Sp1(F3), a Cys2His2 ZF; in contrast, no intact ZF was observed for any of the compounds studied, suggesting the mode of action of these compounds is dependent on the nature of the zinc binding core. ESI-MS studies were expanded to that of the full HIV NCp7 zinc finger. [Au(dien)(9-EtG)]3+ reacts quickly with NCp7, resulting in immediate zinc ejection and replacement with up to three gold ions. Unlike with [Au(dien)(DMAP)]3+, no intact NCp7 was observed. Addition of [Au(dien)(9-EtG)]3+ to preformed NC-SL2 complex results in release of free RNA; based on EMSA (electrophoretic mobility shift assay) studies, [Au(dien)(9-EtG)]3+ disrupts the NCp7-RNA complex with an IC50 of ~450 µM. It is possible that this HIV nucleocapsid-nucleic acid antagonism may result in a loss of viral activity. Gold(III) Zinc Fingers HIV NCp7 Nucleocapsid Protein N-heterocycles Purines Chemistry Physical Sciences and Mathematics
7	Platinum Complexes and Zinc Finger Proteins: From Target Recognition to Fixation Tsotsoros, Samantha 01 January 2014 (has links) Bioinorganic chemistry strives to understand the roles of metals in biological systems, whether in the form of naturally occurring or addition of non-essential metals to natural systems. Metal ions play vital roles in many cellular functions such as gene expression/regulation and DNA transcription and repair. The study of metal-protein-DNA/RNA interactions has been relatively unexplored. It is important to understand the role of metalloprotein interactions with DNA/RNA as this enhanced knowledge may lead to better understanding of diseases and therefore more effective treatments. A major milestone in the development of this field was the discovery of the cytotoxic properties of cisplatin in 1965 and its FDA approval in 1978. Since then, two other chemotherapeutic drugs containing platinum, carboplatin and oxaliplatin, have been used in the clinic. These three compounds are all bifunctional with the ligands surrounding platinum In the cis conformation and rearrangement of the ligands to the trans orientation results in a loss of cytotoxic properties due to rapid deactivation through binding to S-containing proteins. This enhanced reactivity yields new opportunities to study the reactions between proteins and DNA. One of the first crosslinking experiments used transplatin to crosslink NCp7 to viral RNA in order to understand how/where the protein bound to RNA. We have studied the interaction between cis and trans dinuclear platinum complexes and the C-terminal zinc finger (ZF). The trans complex reacts at a faster rate than the cis isomer and causes N- terminal specific cleavage of the ZF. The dinuclear structure plays a critical role in the peptide cleavage as studies with transplatin (the mononuclear derivative) does not result in cleavage. Monofunctional trans platinum-nucleobase complexes (MPNs) serve as a model for the binding of transplatin to DNA. This provides an interesting opportunity to study their reactions with S-containing proteins, such as HIV1 NCp7. MPNs have been shown to bind to the C-terminal ZF of HIV1 NCp7, resulting in zinc ejection. This occurs through a two-step process where the nucleobase π-stacks with Trp37 on the ZF, followed by covalent binding at the labile Cl site to Cys. MPNs have also shown antiviral activity in vitro. The labile Cl on MPNs reduces specificity of these compounds, as it leaves an available coordination site on the platinum center for binding to other S-proteins or DNA. Therefore, we have moved to an inert PtN4 coordination sphere, [Pt(dien)L]2+ (dien= diethylenetri- amine). Due to the strong bond between platinum and nitrogen, covalent reactions are highly unlikely to occur at rapid rates. The strength of the pi-stacking interaction between nucleobases (free and platinated) and the aromatic amino acid, tryptophan (Trp), showed an enhanced binding constant for platinated nucleobases. This was confirmed by density functional theory (DFT) calculations as the difference in energy between the HOMO of Trp and the LUMO of the nucleobase was smaller for the platinum complex. The studies were extended to the Trp-containing C-terminal ZF of HIV1 NCp7 and an increase in association constant was seen compared to free Trp. Reaction of PtN4 nucleobases compounds with a short amino acid sequence con- taining either Ala (no pi-stacking capabilities) or Trp (pi-stacking interactions) revealed an enhanced rate of reactivity for the Trp-containing peptide. This result supports the theory of a two-step reaction mechanism where the platinum-nucleobase complex recognizes the pep- tide through a pi-stacking interaction with Trp followed by covalent binding to the platinum center. The [Pt(dien)L]2+ motif allows for systematic modification of the structural elements surrounding platinum in a search for the most effective compound. Methylation of the dien ligand should, in theory, increase lipophilicity of the compounds, however, due to 2+ charge of the compounds, this simple association does not hold true. Analysis of the cellular accumulation profiles showed little change in the uptake with the addition of methyl groups to the dien ligand, in agreement with the non-linear change in lipophilicity. Modification of L using different nucleobases allows for the tuning of the strength of the π-stacking interaction between Trp and the platinum complex. The addition of inosine (which lacks a H-bonding donor/acceptor at the C2 position) resulted in a lower association constant with both N-AcTrp and the C-terminal zinc finger of HIV1 NCp7. Interestingly, the addition of xanthosine resulted in an ehanced pi-stacking interaction with the C-terminal zinc finger of HIV1 NCp7; likely as a results of the addition of a H-bonding donor (double-bonded O) at the C2 position. The ability of PtN4 nucleobase complexes to inhibit formation of the NCp7 complexation with viral RNA was studied by mass spectrometry and gel electrophoresis. Dissociation of the NCp7-RNA complex was seen upon addition of PtN4 compounds. These compounds were also able to retard formation of the NCp7-RNA complex when pre-incubated with the protein. These results have important implications as inhibition of complex formation between NCp7 and viral RNA has negative implications for viral replication. Despite the success of platinum-nucleobase compounds, it is important to evaluate all potential pi-stacking ligands. A series of pyridine- and thiazole-based compounds were evaluated for the strength of the pi-stacking interaction with N-AcTrp and the C-terminal ZF of HIV1 NCp7. There was notable increase in association constant for the platinum- DMAP (4-dimethylaminopyridine) complex compared to other ligands studied. This result highlights the importance of exploring multiple avenues for the design of specifically targeted inhibitors and further confirms the viability of the medicinal chemistry dual approach of target recognition (non-covalent) followed by target fixation (covalent). HIV platinum NCp7 zinc finger purine N-heterocycle cisplatin transplatin pi-stacking Chemistry Physical Sciences and Mathematics
8	Flexibilités et hétérogéneités structurelles de biomolécules impliquées dans la transcription inverse du virus de l'immunodéficience humaine / Flexibility and structural heterogeneity of biomolecules involved in the reverse transcription of the human immunodeficiency virus Gelot, Thomas 22 October 2012 (has links) Le but de cette thèse est de sonder la flexibilité de NCp7 et de Δ(-)PBS, deux bio-molécules impliquées dans le second saut de brin de la transcription inverse du VIH. Deux stratégies expérimentales ont été mises en place. Un nouveau montage de spectroscopie ultra-rapide de fluorescence par down-conversion a été construit. Les dynamiques de quenching de la 2-aminopurine (2Ap), insérée en position 6, 8 et 10 de la boucle Δ(-)PBS ont pu être entièrement résolues à une résolution sub-ps. Pour chaque position, 4 temps de vie ont été révélés. Des mesures d'anisotropie confirment que les deux composantes < 5 ps sont liées à un empilement de la 2Ap avec les Guanines avoisinantes. Cet empilement est site-spécifique, prouvé par l'augmentation significative de leurs amplitudes lorsque la 2Ap est située près de la tige (position 10). La faible proportion de conformations reliées à un quenching collisionnel est significative de la faible exposition des 2Ap au solvant et de l'encombrement général de la boucle. La seconde approche avait pour but d'étudier l'effet du repliement du squelette protéique de [35-50] NCp7 autour de son atome de zinc par CID et par LID. Les spectres CID de la protéine nue sont expliqués par le modèle du proton mobile et une description détaillée d'un schéma de fragmentation spécifique autour du Tryptophane (Trp) a été soulignée, attribué une Lysine voisine. Un seul fragment issu de l'excitation à 266 nm a été identifié, son apparition entre en compétition avec les fragments CID du Trp. L'effet général du repliement autour du Zinc se traduit par une augmentation du taux de fragmentation autour du Trp et par une perte de spécificité pour le reste du spectre.Les flexibilités de Δ(-)PBS et NCp7 ont été respectivement évaluées par spectroscopie ultra-rapide de type down-conversion et par spectrométrie en phase gazeuse. La première méthode nécessite l'utilisation d'une sonde fluorescente non invasive, la 2-aminopurine (2Ap), placée en position 6, 8 et 10 de la boucle Δ(-)PBS. Notre résolution temporelle permet de résoudre entièrement les dynamiques locales de quenching et d'anisotropie de la 2Ap. Les composantes liées au quenching statique et quenching collisionnel ont été discriminées et révèlent les degrés d'empilement / encombrement locaux de la boucle. L'effet du repliement de [35-50] NCp7 autour de son atome de zinc a été étudié par CID et par LID à 266 nm. La protéine nue présente un interessant shéma de fragmentation autour du Tryptophane (Trp), exalté par la complexation avec le zinc, au prix une perte de spécificité pour le reste du spectre. Un seul fragment LID a été identifié, un mécanisme de sa formation est proposé. / This thesis aims to probe the flexibility of NCp7 and Δ(-)PBS, two biomolecules involved in the second strand transfer of the HIV's reverse transcription. We brought to the front two original experimental methods. A new ultrafast fluorescence down-conversion setup has been built, suitable for biological chromophore investigations. The quenching dynamics of 2-aminopurine (2Ap), site-mutated at the positions 6, 8 and 10 of Δ(-)PBS loop, were completely resolved under a ps scale. For each location, 4 decay times, were highlighted. Further anisotropy measurements confirmed that the two < 5 ps components correspond to stacking interactions of 2Ap with neighbouring Guanines. The site-specific aspect of the stacking were supported by a significant increase of their relative amplitudes when 2Ap were cloesly located to the stem (position 10). The minor portion of conformations involved with ps to ns collisional quenching suggests a low exposure of 2Ap towards the solvent as well as a general restriction of the loop. The second method planned to investigate the effet of the zinc-folding on [35-50] NCp7's peptidic backbone, thanks to CID and LID. The CID-generated spectra of the bare peptide were explained by the mobile proton model, and an exhaustive tryptophan (Trp) fragmentation pattern was described, mainly due to a neighbouring Lysin effects. Only one LID-fragment has been identified upon 266 nm excitation, probably created through a pathway competing with the generation of Trp fragments by CID. The main aspects related to zinc-folding are a general enhancement of the fragmentation ratios related to Trp and a loss of specificity for the remaining mass spectra parts.Δ(-)PBS et NCp7 has been respectively investigated by ultrafast down-conversion spectroscopy and gas-phase spectrometry. The first method implies the use of a non invasive fluorescent probe, named 2 aminopurine (2Ap), site mutated in position 6, 8 et 10 of the Δ(-)PBS loop. Our time resolution allows to fully depict the local quenching dynamics and anisotropy decays. The component related to static and collisional has been solved, thus describing different stacking degrees as well as local restrictions. The effect of [35-50] NCp7 folding around its zinc atom has been studied by CID and 266 nm LID. The bare protein displays an interesting fragmentation pathway around its Tryptophan (Trp), enhanced with zinc complexation, at the cost of a loss of specificity for the remaining mass spectra parts. Only one LID fragment has been identified, its occurence has been interpreted. NCp7 PBS 2-Aminopurine Quenching de fluorescence Dynamique structurelle Flexibilité LID CID Phase gazeuse Down-conversion NCp7 PBS 2-Aminopurine Fluorescence quenching Structural dynamic Flexibility LID CID Gas-phase Down-conversion 571.43 572.5
9	Zinc Environment in Proteins: The Flexible and Reactive Core of HIV-1 NCp7 and The Inhibitory Site of Caspase-3 Daniel, A. Gerard 02 December 2013 (has links) Zinc is an essential cofactor of several proteins. The roles of zinc in these proteins are classified as catalytic, structural or regulatory. Zinc present in structural sites is considered to be a chemically inert, static structural element. On the contrary, previous studies on a C2H2 type zinc finger model compound and the C3H type HIV-1 NCp7 C-terminal zinc knuckle have shown that zinc at these sites can undergo coordination sphere expansion under the influence of a Pt based electrophile. The pentacoordination observed around zinc in these experiments raises an important question: are the structural zinc motifs found in the proteins susceptible to coordination sphere expansion? Through DFT modeling, the existence and nature of the five coordinate zinc species was investigated. mPW1PW91 was chosen as the DFT method by benchmarking against the experimental parameters of a molecule that closely resembles those to be modeled. The results suggest that the observed coordination sphere expansion is due to the flexible nature of thiolate and chloride ligands that are part of the structure. However, if certain conditions are not met, the same flexibility can lead to the destabilization of these rather fragile structures. Unlike the stable three or four coordinate catalytic and structural zinc sites, at regulatory sites, zinc is typically bound to one or two protein ligands. Zinc inhibition of caspases which are central to the process of apoptosis is one such scenario. Several of the caspases are inhibited by zinc at low micromolar range. Regulation of caspases is a strategy for drug development toward apoptosis related diseases; thus it is important to know the molecular details of zinc inhibition of caspases. Currently, it is speculated that zinc binds to the active site His and Cys residues of caspases thus competing with the substrate. However our studies on caspase-3, using enzyme kinetics and biophysical methods, imply more than one zinc binding sites. Contrary to current beliefs, more than 50% of the inhibition is achieved by zinc without affecting substrate binding. Using DFT models, an alternative inhibitory zinc binding site, which better fits our experimental observations, is predicted. caspase DFT enzyme kinetics HIV-1 NCp7 caspase inhibition zinc finger platinum drug Chemistry Physical Sciences and Mathematics
10	Experimental study of the kinetics of two systems : DNA complexation by the NCp7 protein and probe dynamics in a glassy colloidal suspension / Etude expérimentale de cinétique de deux systèmes : complexation de l'ADN par la protéine NCp7 et dynamique d'une suspension colloïdale vitreuse Klajner, Piotr 11 May 2012 (has links) Dans la première partie de cette thèse, nous étudions la cinétique de la complexation d'un double brin d'ADN par la protéine NCp7. Pour ce faire, nous étudions l'évolution des propriétés mécaniques de l'ADN au fur et à mesure de sa complexation, en étirant la complexe ADN/NCp7 à l'aide d'un montage de piégeage optique. Nous avons observé que la longueur de persistance du complexe diminue au fur et à mesure de la complexation. En utilisant un modèle statistique décrivant l'évolution de la flexibilité de l'ADN complexé par NCp7. Notre principal résultat est que la fraction//phi de paires de bases ayant réagi n'est pas une fonction linéaire du temps aux faibles //phi. Nous interprétons nos résultats en supposant que l'adsorption de NCp7 sur l'ADN est fortement coopérative. Dans deuxième chapitre, nous décrivons la dynamique de particules sondes dans une suspension vitreuse colloïdale de Laponite. La Laponite est une particule colloïdale discoïdale de 25nm de diamètre et de 0.92 nm d'épaisseur. Nous utilisons une expérience de microscopie en onde évanescente, et suivons le mouvement de particules fluorescentes de latex. Nous imageons ensuite ces particules. Nous montrons que, pour un mouvement possédant une seule échelle de temps caractéristique, elle est simplement une fonction linéaire du temps. Nous obtenons que, quelle que soit leur taille, le mouvement des particules sondes peut être décrit par une succession de deux modes dynamiques, où le mode le plus rapide correspond à la diffusion des particules dans un fluide viscoélastique. / In the first part of this thesis, we study the kinetics of the complexation of a double-stranded DNA byNCp7 protein. To do this, we study the evolution of mechanical properties of DNA and its complexation by stretching the DNA/NCp7 complex with a optical trap. We observed that the persistence length of the complex decreases progressively during the complexation. Using astatistical model we describe the evolution of the flexibility of DNA complexed with NCp7. Our main result is that the fraction phi of base pairs that have reacted is not a linear function of time at low phi.We interpret our results assuming that the adsorption of NCp7 on DNA is highly cooperative. In the second chapter, we describe the dynamics of probe particles in a colloidal glassy suspension of Laponite. Laponite is a colloidal discoidal particle of 25 nm in diameter and 0.92 nm thick. We take advantage of evanescent wave microscopy, and follow the movement of fluorescent latex particles.Then we image these particles. We show that for a movement that has a single characteristic time scale, it is simply a linear function of time. We find that, what ever their size, the motion of probe particles can be described by a succession of two dynamic modes, where the fastest mode corresponds to the diffusion of particles in a viscoelastic fluid. NCp7 Laponite Single molecule Real time Optical tweezers Optical trap TIRFM 541.34

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