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Dermaseptine B2 : un peptide antimicrobien issue des sécrétions de peau de Phyllomedusa bicolore avec des activités antitumorales et angiostatiques / Dermaseptine B2 : an antimicrobial peptide from skin secretions of phyllomedusa bicolor with antitumor and angiostatic activitiesVan Zoggel, Johanna 09 December 2010 (has links)
Les secrétions de peau des grenouilles néo tropicales et sud américaines contiennent un large éventail de molécules biologiquement actives et notamment les peptides ayant des propriétés antimicrobiennes. Disposant de sécrétions de peau de la grenouille sud américaine du genre Phyllomedusa bicolor, nous avons recherché la présence molécules ayant des activités antitumoraleet angiostatique. Deux peptides cationiques antimicrobiens membres de la famille des dermaseptine (Drs) ont été identifies comme possédant ces activités: les dermaseptines B2 et B3 (Drs B2 et Drs B3). Ces deux peptides sont ainsi capables d’inhiber la prolifération et la formation de colonies de différentes lignées de cellules tumorales, la prolifération des cellules endothéliales ainsi que la formation de pseudo-capillaires in vitro. D’autre part, la Drs B2 est également capable d’inhiber la croissance des cellules tumorales dans un modèle in vivo dexénogreffe. L’exploration du mécanisme d’action de la Drs B2 sur les cellules tumorales PC3 nous a permis de mettre en évidence un rapide re-largage de la LDH cytosolique, une absence d’activation des caspases-3, -9 et -8 ainsi que l’absence de modification du potentiel de membrane mitochondriale. L’ensemble de ces données semble indiquer que la Drs B2 n’induit pas la mort de cellules tumorales par un mécanisme d’apoptose mais plus probablement par une fixation à la surface de cellules entraînant une lyse rapide de la membrane plasmique des cellules conduisant à une mort par nécrose. En conclusion, la Drs B2 est une molécule qui cible préférentiellement les cellules tumorales pour des concentrations efficaces de l’ordre du micro molaire, ce qui en fait un outil pharmacologique potentiellement intéressant pour le traitement du cancer. / The skin secretions of neotropical and South American frogs contains large amounts of a widerange of biological active molecules. Commonly studied are peptides with antimicrobialactivities. In this study we have postulated that the skin secretions from the South Americanfrog Phyllomedusa bicolor contain molecules with antitumor and angiostatic activities. Twowell known cationic alpha helical antimicrobial peptides of the dermaseptin (Drs) family wereidentified to have these activities: Drs B2 and Drs B3. Both peptides inhibited proliferationand colony formation of various tumor cell lines, and the proliferation and capillary formationof endothelial cell in vitro. Furthermore, Drs B2 inhibited tumor growth in a PC3 xenograftmodel in vivo.Research on the mechanism of action of Drs B2 on tumor cells PC3 demonstrated a rapidincreasing amount of cytosolic LDH, no activation of caspase-3, -9 or -8, and no changes inmitochondrial membrane potential. These data together indicate that Drs B2 does not act byapoptosis but possibly could fix to the tumor cell surface, disrupt the cellular plasmamembrane leading to its death by necrosis.In conclusion, Drs B2 could be an new interesting and promising pharmacological leadermolecule for the treatment of cancer. Its antitumor and angiostatic activities, especially itsselective targeting of tumoral cells with micro molar concentrations propose Drs B2 as anpotential candidate for the development of a new efficient targeting therapy against cancer.
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Saccharomyces cerevisiae: A Platform for Structure-activity Relationship Analysis and High-throughput Candidate PrioritizationSong, Kyung Tae Kevin 17 July 2013 (has links)
The budding yeast Saccharomyces cerevisiae has been an invaluable model organism in contributing to the current understanding of cellular biology, owing mainly to its highly tractable genetic system and the completion of its genome sequencing in 1996. Indeed, these bolstered the development of novel methods that have provided great insights into genetic and protein networks in human cells. With the large collection of datasets, S. cerevisiae also became an ideal platform for investigating the mechanism of action of novel compounds. The first part of my thesis uses a validated chemogenomic assay to investigate the mechanism of action of structurally related novel DNA-damaging agents, delineating valuable structure-activity relationship in the process. The second part describes the development of a method that uses drug-induced wild-type growth dynamic to characterize novel compounds, which, in combination with the chemogenomic assay, may complement existing high throughput screening experiments to improve the current drug development process.
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Saccharomyces cerevisiae: A Platform for Structure-activity Relationship Analysis and High-throughput Candidate PrioritizationSong, Kyung Tae Kevin 17 July 2013 (has links)
The budding yeast Saccharomyces cerevisiae has been an invaluable model organism in contributing to the current understanding of cellular biology, owing mainly to its highly tractable genetic system and the completion of its genome sequencing in 1996. Indeed, these bolstered the development of novel methods that have provided great insights into genetic and protein networks in human cells. With the large collection of datasets, S. cerevisiae also became an ideal platform for investigating the mechanism of action of novel compounds. The first part of my thesis uses a validated chemogenomic assay to investigate the mechanism of action of structurally related novel DNA-damaging agents, delineating valuable structure-activity relationship in the process. The second part describes the development of a method that uses drug-induced wild-type growth dynamic to characterize novel compounds, which, in combination with the chemogenomic assay, may complement existing high throughput screening experiments to improve the current drug development process.
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Évaluation du potentiel et de voies innovantes de mise en oeuvre de composés phénoliques antimicrobiens d’origine végétale pour la conservation des aliments / Assessment of potential and innovative ways to implement plant-derived antimicrobial phenolic compounds for food preservationBouarab, Lynda 28 May 2018 (has links)
Le règne végétal est une ressource renouvelable d'une large gamme de métabolites secondaires biologiquement actifs. Ces travaux de thèse proposent une stratégie multidisciplinaire d'évaluation du potentiel de composés phénoliques antimicrobiens d'origine végétale pour la conservation des aliments. Un criblage de l'activité antimicrobienne in vitro vis-à-vis de 8 souches de la flore pathogène et d'altération des aliments d'une centaine de molécules pures et une soixantaine d'extraits végétaux a d'abord permis de sélectionner les plus actifs. Différents mécanismes d'action vis-à-vis de S. aureus ont pu être mis en évidence par cytométrie de flux couplée à l'utilisation de marqueurs de l'état physiologique des bactéries pour quelques uns des composés actifs sélectionnés. En vue d'une application à de la viande bovine, l'activité antibactérienne des composés phénoliques ou extraits végétaux les plus actifs a été réévaluée dans des milieux de culture plus complexes mimant leur teneur en protéines et en matières grasses. Les résultats de ce criblage et un suivi microbiologique de viande hachée de bœuf avec 1% (m/m) d'extrait ajouté ont permis d'observer que les pertes d'activité antibactérienne observées étaient notamment corrélées aux interactions des composés phénoliques avec les protéines ou les matières grasses. L'incorporation des composés phénoliques ou extraits végétaux dans des matériaux d'emballage en contact alimentaire a constitué la seconde voie de mise en œuvre envisagée. Des films plastiques conservant une activité antibactérienne ont ainsi pu être élaborés par voie fondue / The plant kingdom is a renewable resource of a wide range of biologically active secondary metabolites. This thesis proposes a multidisciplinary strategy for evaluating the potential of plant-derived antimicrobial phenolic compounds for food preservation. A screening of the antimicrobial activity in vitro against 8 strains of foodborne pathogenic and spoilage microorganisms of a hundred pure molecules and about sixty plant extracts allowed to select the most active. Different mechanisms of action with respect to S. aureus could be demonstrated by flow cytometry coupled with the use of probes of the physiological state of the bacteria for some of the selected active compounds. For application to beef, the antibacterial activity of the most active phenolic compounds or plant extracts has been re-evaluated in more complex culture media mimicking their protein and fat content. The results of this screening and a microbiological monitoring of minced beef with 1% (m / m) of added extract made it possible to observe that the observed losses of antibacterial activity were in particular correlated with the interactions of the phenolic compounds with the proteins or fat. Incorporation of phenolic compounds or plant extracts into packaging materials in contact with food constituted was the second proposed route of implementation. Plastic films that retain antibacterial activity have thus been able to be prepared by melting
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New insights into the persistence phenomenonGoormaghtigh, Frederic 23 September 2016 (has links)
Together with the current antibiotic resistance crisis, bacterial persistence appears to play an increasingly important role in the frequent failure of antibiotic treatments. Persister cells are rare bacteria that transiently become drug tolerant, allowing them to survive lethal concentrations of bactericidal antibiotics. Upon antibiotic removal, persister cells are able to resume growth and give rise to a new bacterial population as sensitive to the antibiotic as the original population. Interest in persister cells seriously increased in the past few years as these phenotypic variants were shown to be involved in the recalcitrance of chronic infections, such as tuberculosis and pneumonia and in the well-known biofilm tolerance to antibiotics. Persistence has therefore been extensively studied throughout the last decade, which led to the discovery of large variety of different molecular mechanisms involved in persisters formation. However, the specific physiology of bacterial persisters remains elusive up to now, mainly because of the transient nature and the low frequencies of persister cells in growing bacterial cultures. This work aims to gain a better understanding of the physiology of Escherichia coli persisters by combining population analyses with single-cell observations.In the first part of this thesis, we developed an experimental method allowing for measuring persistence with increased reproducibility. The method was further refined, which allowed us to observe four distinct phases in the ofloxacin time-kill curve, suggesting the existence of a tolerance continuum at the population level at treatment time. Characterization of these four phases notably revealed that the growth rate and the intrinsic antibiotic susceptibility of the strain define the number of surviving cells at the onset of the persistence phase, while persister cells survival mainly relies on active stress responses (SOS and stringent responses in particular).We next investigated the molecular mechanisms underlying the well-known correlation between persistence and the growth rate. Interestingly, we showed that the growth rate determines the number of survival cells at the onset of the persistent phase, whereas it does not affect the death rate of persister cells during antibiotic treatment. Furthermore, slow growth was shown to influence survival to ofloxacin independently of the replication rate, thereby suggesting that target inactivation solely cannot explain this correlation. However, our preliminary data indicate that ppGpp induction upon ofloxacin exposure substantially increases in slow growing bacterial populations, supporting a model in which slow growth would allow bacteria to respond faster to the antibiotic treatment, thereby generating more persisters than fast growing bacterial populations.Finally, both population and single-cell analyses were performed to assess the influence of the SOS response on persistence to ofloxacin. Firstly, population analyses revealed that the SOS response is required for survival of both sensitive and persister cells, but only during recovery, after ofloxacin removal, presumably allowing cells to induce SOS-dependent DNA repair pathways, required to deal with the accumulated ofloxacin-induced DNA lesions. The SOS response therefore appears as a good target for anti-persisters strategies, as shown by the 100-fold decrease in persistence upon co-treatment of a bacterial population with an SOS-inhibitor and ofloxacin. Secondly, single-cell analyses revealed that persister cells sustain similar DNA damages than sensitive cells upon ofloxacin treatment and induce SulA- and SOS-independent filamentation upon antibiotic removal, probably reflecting the presence of remaining cleaved complexes, formed during ofloxacin exposure. Importantly, we showed filamentation to occur in persister cells upon ampicillin treatment as well, thereby suggesting these filaments to be part of a more general survival pathway, which molecular basis remains unknown. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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INHIBITION OF ERYTHROCYTE BAND 3 TYROSINE PHOSPHORYLATION: CHARACTERIZATION OF A NOVEL THERAPY FOR SICKLE CELL DISEASE AND MALARIAPanae Noomuna (10716546) 29 April 2021 (has links)
While the molecular
defect that cause sickle cell disease has well been established, the cause of
vaso-occlusive crisis remains elusive and largely debated upon. Majority of
studies have linked the painful episodes to polymerization of sickle hemoglobin
following its deoxygenation. The variability of the disease symptoms among
patients, compounds efforts for a holistic therapy. Hydroxyurea, a stimulator
of Hb F induction and a widely used treatment, has ameliorated the complication
of SCD but it is only effective in 50% of the patients. Expression of Hb F
lowers the content of Hb S in blood and hence reduces oxidative stress caused
by Hb S denaturation. Sickle cell disease severity depends on several factors.
Most importantly, the ability of red cell to sickle dominates all other
determinants. While deoxygenation of sickle hemoglobin may be inevitable, the
duration with which the red cell remains in the deoxygenated state can be
manipulated. Deoxygenation is a transient process that when compared to the
time taken to develop the long filaments of deoxyhemoglobin to causes severe
sickling, the red cell would have been cycled back to the lungs and
re-oxygenated to restore the healthy conditions of the cell. In fact, if sickle
cells would flow as fast as healthy erythrocytes, the detrimental impacts of
sickling such as vaso-occlusive crisis, would not be a concern for this
disease. Unfortunately, the unstable sickle hemoglobin undergoes denaturation
through auto-oxidation, which imposes oxidative stress to the cells. The
oxidative stress inhibits erythrocytes tyrosine phosphatases, a course which
subsequently impair their constitutive action against the tyrosine kinases. In
the end, a net tyrosine phosphorylation state in the red cell membrane
proteins, most notably the transmembrane protein band 3, succeeds. Band 3
tyrosine phosphorylation abrogates the protein’s interaction with ankyrin and
spectrin-actin cytoskeleton, hence the cytoskeleton loses its major anchorage
to the membrane thus engendering membrane destabilization. A destabilized
erythrocyte sheds membrane fragments in form of microvesicles/microparticles
and discharges free hemoglobin into the extra cellular matrix. In consequence,
the microparticles power initiation of coagulation cascade through activation of
thrombin, while free Hb inflicts inflammation, scavenges nitric oxide which is
necessary for vasodilation and induces further oxidative stress within the
microvasculature, and activates expression of adhesion receptors on the
endothelium. Taken together, these events culminate in entrapment of red cells
(not naming leucocytes and platelets) in the microvasculature, blockade of
blood vessels and further damage of erythrocytes through prolonged deoxygenated
state thus terminating in tissue injury, strokes, and organ damage, amid
vaso-occlusive episodes which always require hospitalization and extensive
medical care for survival. Band 3 tyrosine phosphorylation and membrane
weakening is not unique just to SCD, but also a druggable target for malaria.
Malaria, a disease that is touted as the evolutionary cause of sickle cell
disease, surprisingly thrives through the same mechanism. Briefly, malaria
parasite consumes hemoglobin for its DNA synthesis, and in the process generate
reactive oxygen species from denatured hemoglobin that feeds into the oxidative
stress which triggers band 3 tyrosine phosphorylation. In this case however, a
destabilized membrane offers perfect conditions for merozoites’ (malaria
daughter parasites) egress/exit out of the cell to begin infecting other red
cells. Ultimately, the ensuing anemia and organ dysfunction leads to patient’s
death. Treatment of diseased cells with imatinib and other Syk inhibitors
effectively reversed membrane weakening. A stabilized membrane not only
survives longer in circulation to alleviate SCD symptoms but also traps and
starves malaria parasite leading to termination of the parasitic infection.
With band 3 tyrosine phosphorylation at center stage, this dissertation
explores the above events in an effort to unveil a novel therapy for sickle
cell and malaria diseases. First, the therapeutic strategy regarding SCD is
discussed in detail beginning with non-transfused patients and ending in
additional mechanistic study on inactivation of the principal erythrocyte’s protein
tyrosine phosphatase 1 B, PTP1B. The dissertation then provides an initial
proof of concept on efficacy of imatinib in treatment of malaria as a
monotherapy and its efficacy when used in a triple combination therapy with the
standard of care treatment. Finally, I outline an alternative possible
mechanism of action of quinine against malaria.
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FRAGMENT BASED DRUG DEVELOPMENT BASED ON 6,7 DIMETHOXYQUINAZOLINE AS A CORE SCAFFOLDOrahoske, Cody M. 11 July 2023 (has links)
No description available.
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Improved in silico methods for target deconvolution in phenotypic screensMervin, Lewis January 2018 (has links)
Target-based screening projects for bioactive (orphan) compounds have been shown in many cases to be insufficiently predictive for in vivo efficacy, leading to attrition in clinical trials. Phenotypic screening has hence undergone a renaissance in both academia and in the pharmaceutical industry, partly due to this reason. One key shortcoming of this paradigm shift is that the protein targets modulated need to be elucidated subsequently, which is often a costly and time-consuming procedure. In this work, we have explored both improved methods and real-world case studies of how computational methods can help in target elucidation of phenotypic screens. One limitation of previous methods has been the ability to assess the applicability domain of the models, that is, when the assumptions made by a model are fulfilled and which input chemicals are reliably appropriate for the models. Hence, a major focus of this work was to explore methods for calibration of machine learning algorithms using Platt Scaling, Isotonic Regression Scaling and Venn-Abers Predictors, since the probabilities from well calibrated classifiers can be interpreted at a confidence level and predictions specified at an acceptable error rate. Additionally, many current protocols only offer probabilities for affinity, thus another key area for development was to expand the target prediction models with functional prediction (activation or inhibition). This extra level of annotation is important since the activation or inhibition of a target may positively or negatively impact the phenotypic response in a biological system. Furthermore, many existing methods do not utilize the wealth of bioactivity information held for orthologue species. We therefore also focused on an in-depth analysis of orthologue bioactivity data and its relevance and applicability towards expanding compound and target bioactivity space for predictive studies. The realized protocol was trained with 13,918,879 compound-target pairs and comprises 1,651 targets, which has been made available for public use at GitHub. Consequently, the methodology was applied to aid with the target deconvolution of AstraZeneca phenotypic readouts, in particular for the rationalization of cytotoxicity and cytostaticity in the High-Throughput Screening (HTS) collection. Results from this work highlighted which targets are frequently linked to the cytotoxicity and cytostaticity of chemical structures, and provided insight into which compounds to select or remove from the collection for future screening projects. Overall, this project has furthered the field of in silico target deconvolution, by improving the performance and applicability of current protocols and by rationalizing cytotoxicity, which has been shown to influence attrition in clinical trials.
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Interactions peptides antibactériens - surfaces bactériennes : Etude de la carnobactériocine Cbn BM1, une bactériocine de classe IIa / Antimicrobial peptide - bacterial surfaces interactions : Study of the class IIa bacteriocin Cbn BM1Jacquet, Thibaut 23 November 2011 (has links)
Les bactériocines de classe IIa présentent une activité antimicrobienne résultant d'un mécanisme d'action ciblant les membranes des bactéries à Gram positif. Cette activité est modulée par différentes caractéristiques des surfaces bactériennes. Les propriétés physico-chimiques de surface de dix-huit souches bactériennes ont été déterminées afin d'étudier le lien entre ces propriétés et les phénotypes de résistance/sensibilité à Cbn BM1. Les résultats obtenus indiquent une grande diversité des propriétés physico-chimiques des surfaces analysées, sans cependant permettre d’établir un lien entre celles-ci et le phénotype de sensibilité/résistance à CbnBM1. Les mécanismes d'action de Cbn BM1 ont ensuite été étudiés sur Carnobacterium maltaromaticum DSM20730 et Listeria monocytogenes EGDe. L'atteinte de l'intégrité physique des membranes plasmiques par l'action de Cbn BM1 montre une hétérogénéité de réponse des populations bactériennes. Ce résultat a été confirmé par microscopie de force atomique in vivo à haute résolution. L'interaction de Cbn BM1 avec les membranes a été mise en évidence par mesure de l'anisotropie de fluorescence. Cette approche a révélé que Cbn BM1 présente des degrés de pénétration différents dans la membrane de C. maltaromaticum DSM20730 par rapport à L. monocytogenes EGDe. L'action de Cbn BM1 conduit cependant, pour les deux souches, à la modification de la force protomotrice membranaire. Ces différentes approches retenues pour l'étude des mécanismes d'action ont révélé que C. maltaromaticum DSM20730 et L. monocytogenes EGDe présentent une sensibilité à Cbn BM1 uniquement lorsque les cellules sont en phase exponentielle de croissance. / The antimicrobial activity of class IIa bacteriocins toward Gram positive bacteria relies on their membrane targeting mechanisms of action. These mechanisms are modulated by the bacterial surface properties. The physico-chemical surface properties of eighteen bacterial strains were determined to link these properties to the resistance/sensitivity to Cbn BM1 of the bacterial strains. In this way, two approaches were undertaken : the microbial adhesion to solvents and electrophoretic mobility measurements. The results show a large diversity of the determined properties among the strains but without establishing a direct link between the surface properties and the resistance/sensitivity phenotypes. Mechanisms of action of the bacteriocin Cbn BM1 on Carnobacterium maltaromaticum DSM20730 and Listeria monocytogenes EGDe were determined. Syto9® and propidium iodide allowed to show the heterogeneity of the bacterial populations toward the alteration of the membrane integrity. The interaction of Cbn BM1 with the bacterial membrane was studied by monitoring the fluorescence anisotropy of DPH and TMA-DPH. The results highlight a difference between the mechanism of action of Cbn BM1 on C. maltaromaticum DSM20730 and on L. monocytogenes EGDe. However, a treatment by Cbn BM1 leads to a perturbation of the component of the proton-motive force of the membrane for both strains. These approaches revealed that these bacterial strains exhibit a sensitivity to Cbn BM1 only when treated in log growth phase. Modification of nano-mechanical properties of C. maltaromaticum DSM20730 after a treatment by Cbn BM1 were assessed by an atomic force microscopy approach.
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Mechanism of Transformation and Therapeutic Targets for Hematological Neoplasms Harboring Oncogenic KIT MutationMartin, Holly René January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Gain-of-function mutations in the KIT receptor tyrosine kinase have been associated with highly malignant human neoplasms. In particular, an acquired somatic mutation at codon 816 in the second catalytic domain of KIT involving an aspartic acid to valine substitution is found in patients with systemic mastocytosis (SM) and acute myeloid leukemia (AML). The presence of this mutation in SM and AML is associated with poor prognosis and overall survival. This mutation changes the conformation of the KIT receptor resulting in altered substrate recognition and constitutive tyrosine autophosphorylation leading to constitutive ligand independent growth. As there are currently no efficacious therapeutic agents against this mutation, this study sought to define novel therapeutic targets that contribute to aberrant signaling downstream from KITD816V that promote transformation of primary hematopoietic stem/progenitor cells in diseases such as AML and SM. This study shows that oncogenic KITD814V (murine homolog) induced myeloproliferative neoplasms (MPN) occurs in the absence of ligand stimulation, and that intracellular tyrosines are important for KITD814V-induced MPN. Among the seven intracellular tyrosines examined, tyrosine 719 alone has a unique role in regulating KITD814V-induced proliferation and survival. Residue tyrosine 719 is vital for activation of the regulatory subunit of phosphatidylinositol 3-kinase (PI3K), p85α, downstream from KITD814V. Downstream effectors of the PI3K signaling pathway, in of leukemic cells bearing KITD814V with an allosteric inhibitor of Pak or its genetic inactivation results in growth repression due to enhanced apoptosis. To assess the role of Rac GEFs in KITD814V induced transformation, EHop-016, an inhibitor of Rac, was used to specifically target Vav1, and found to be a potent inhibitor of human and murine leukemic cell growth. In vivo, the inhibition of Vav or Rac or Pak delayed the onset of MPN and rescued the associated pathology in mice. These studies provide insight on mechanisms and potential novel therapeutic targets for hematological malignancies harboring an oncogenic KIT mutation.
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