Global ETD Search

11	Changes in proteoglycans in endothelial cells under hyperglycemic conditions Han, Juying 02 December 2009 (has links) Heparan sulfate proteoglycan (HSPG) or heparan sulfate (HS) degradation may contribute to endothelial cell (EC) dysfunction in diabetes. HSPGs, syndecan and perlecan, contain a protein core with mainly HS glycosaminoglycans (GAGs) attached. HSPGs modulate growth factors and function in membrane filtering. Heparanase induction is likely responsible for diabetic HS degradation. Heparin protects endothelium and insulin regulates glucose metabolism. Our objectives were to observe HSPG changes by studying EC GAG content and gene expression of syndecan, perlecan and heparanase under hyperglycemic conditions with insulin and/or heparin treatment.<p> GAGs, including HS, were determined by the carbazole assay and visualized by agarose gel electrophoresis in porcine aortic EC cultures treated with high glucose (30 mM) and/or insulin (0.01 U/ml) for 24, 48 and 72 hours and/or heparin (0.5 µg/ml) for 72 hours. High glucose decreased cell GAGs and increased medium GAGs. GAGs increased with time in control cultures and in high glucose plus insulin treated medium. GAGs were decreased with insulin but increased with insulin or heparin plus high glucose.<p> Confluent cultured human aortic ECs were incubated with control medium, high glucose and/or insulin and/or heparin for 24 hours. Real time PCR determination showed that: high glucose increased heparanase, decreased syndecan and had no effect on perlecan mRNA; insulin or heparin with/without high glucose decreased and insulin and heparin with high glucose increased heparanase mRNA; heparin and insulin with high glucose increased but insulin decreased syndecan mRNA. Actinomycin D (10 µg/ml) inhibited heparanase and syndecan mRNA with high glucose plus insulin plus heparin and inhibited heparanase mRNA with high glucose compared to time 0 but not â-actin after addition for 0, 2, 4, 8 and 24 hours. Bioinformatic studies revealed that transcription factor Sp1 activates heparanase promoter by high glucose and may play a role in regulation of perlecan and syndecan promoters.<p> Insulin or heparin inhibited the reduction in EC GAGs and syndecan mRNA and induction in heparanase by high glucose, indicating their protective effect. Decreased GAGs by insulin may relate to the pathology of hyperinsulinemia. Transcriptional regulation by heparin and/or insulin may cause variation in gene expression of heparanase, syndecan and perlecan. HPLC HS disaccharides gene expression perlecan diabetic cardiovascular complications heparanase syndecan real time PCR mRNA
12	Adhesion Dependent Signals : Cell Survival, Receptor Crosstalk and Mechanostimulation Riaz, Anjum January 2013 (has links) The integrin family of cell surface receptors is evolutionary conserved and found in all multicellular animals. In humans 8-alpha and 18-beta integrins are non-covalently associated into 24 dimers. Integrins mediate cell-extracellular matrix and cell-cell interactions and participate in cell signalling. This ideally places integrins to regulate vital processes such as cell adhesion, migration, differentiation and cytoskeleton dynamics. Integrins also play a fundamental role in regulating cell survival and anoikis. In this thesis molecular mechanisms employed by integrins to induce signal transduction, independently or through crosstalk with other receptors, were characterised. Rictor-mTOR (mTORC2) was required for Akt Ser473 phosphorylation in response to β1 integrin-mediated adhesion as well as EGF-, PDGF- or LPA-stimulation of MCF7 cells. ILK and PAK were dispensable for Akt Ser473 phosphorylation upon β1 integrin-engagement or EGF-stimulation. PAK was needed when this phosphorylation was induced by PDGF or LPA. β1 integrin-promoted cell survival during serum starvation conditions was mTORC2 dependent, indicating the importance of Akt Ser473 phosphorylation. mTORC2 was also required for Akt Ser473 phosphorylation induced upon heparanase treatment of cells. Heparanase preferred PI3K catalytic subunit p110α for the upstream lipid phosphorylation required for Akt activation. Interaction between this subunit and Ras was needed for optimal Akt phosphorylation upon heparanase exposure. Cell adhesion strongly promoted heparanase signalling, which was more efficient in β1 integrin-expressing fibroblasts compared to cells lacking this subunit. The cooperative signalling between integrins and heparanase involved FAK and PYK2 since simultaneous silencing of these kinases suppressed heparanase-triggered Akt activation. Furthermore, the resistance of cells to apoptosis induced by H2O2 or serum starvation was promoted by heparanase. Integrin stimulation by adhesion or cyclic stretching showed divergent downstream signalling responses. Cell attachment on integrin-specific ligands lead to robust phosphorylation of several intracellular integrin-effectors, e.g. p130CAS, FAK, Akt and ERK 1/2. However, mechanical cell stretching only triggered prominent phosphorylation of ERK 1/2. Signalling induced at early stages of integrin-mediated cell adhesion occurred independently of intracellular contraction. Reactive oxygen species (ROS) generated during adhesion and cell stretching influenced integrin signalling. Inhibition of mitochondrial ROS production blocked adhesion-induced Akt phosphorylation. In contrast, stretch-induced ERK 1/2 phosphorylation was elevated when extracellular ROS was scavenged. These results indicate that the two types of integrin stimuli generate signals by different mechanisms. Integrins Signal transduction Protein kinase B Akt PI3K Heparanase ROS Mechanosignalling
13	The generation of monoclonal antibodies to investigate perlecan turnover in cells and tissues Ma, Jin, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW January 2008 (has links) Perlecan is an important basement membrane heparan sulfate (HS) proteoglycan that is essential for various cell signaling events involved in tissue development. Heparanase is a lysosomal enzyme involved in the turnover of HS. This project aimed to assist in researching the structure of HS on perlecan and how this structure changes with tissue development. This will be achieved by generating monoclonal antibodies that have an altered affinity for perlecan after heparanase treatment. Recombinant perlecan domain I was characterized by ELISA and western blotting and used as the antigen for two fusions. The first fusion was focused on the production of IgM the common subtype of anti-glycosaminoglycans antibodies. However, no clones were produced, which may have been due to the lack of feeder layers. In order to address this problem, the fibroblast cell line MRC-5 was used as a feeder layer in the second fusion. From this fusion, we obtained 216 positive cultures, which were screened against full length perlecan from endothelial cells. Of these, 26 cultures were tested against heparanase treated perlecan, and then 2 cultures were chosen for subcloning based on the different immunoreactivity between enzyme treated and nontreated perlecan. From the 2 chosen cultures, 13 sub clones were derived and 10 of them were adapted into a serum free culture environment. The 10 monoclonal antibodies displayed strong immunoreactivity with full length perlecan in ELISA and Western Blotting. When they were used as primary antibodies in Immunocytochemistry, they were able to recognize the native perlecan deposited by human chondrocytes. When the cells were incubated with heparanase, antibody 5D7-2E4 and 13E9-3G5 showed an increase in immunoreactivity while antibody 13E9-3B3 gave a decrease. These three antibodies will be the potential tools used in the future to study perlecan turnover in different cells and tissue. The remaining seven antibodies will also be very useful in the research of perlecan as they have been shown to bind to the protein core. In the future, it will be worth subcloning some of the frozen stored stocks of uncloned hybridomas, where there are potential opportunities to select antibodies, which will react with the carbohydrate chains on perlecan. Heparanase. Perlecan. Heparan sulfate proteoglycan Monoclonal antibody. Basement membrane. Monoclonal antibodies. Hybridomas. Cells. Tissues.
14	Caractérisation des glycosaminoglycannes au cours de la croissance tumorale. Développement d’un nouvel outil pour leur étude : l’impression moléculaire / Recognition of oligosaccharides specific heparan sulphate implicated in tumor development. Application of molecular imprinting technology Mothere, Mouna 10 January 2013 (has links) Les GAGs, en particulier les HS et les CS, sont des polysaccharides linéaires sulfatés situés à la surface des cellules et la matrice extracellulaire où ils influencent les fonctions des cellules. Les GAGs sont connus pour se lier et réguler l'activité d'un certain nombre de protéines différentes appelées «protéines de liaison héparine», y compris les chimiokines, facteurs de croissance, des enzymes et des molécules d'adhésion. Dans le cas du développement de la tumeur, la surexpression de l'héparanase a été observée. En conséquence, une variété d'oligosaccharides de HS et de CS est libérée. Néanmoins, leurs structures et leurs effets biologiques sont inconnus.De nombreux outils existent pour la caractérisation des GAG cependant, le développement de nouvelles technologies pour isoler des fragments du HS endogènes est nécessaire. Dans ce contexte, nous proposons d'utiliser la technologie d'empreinte moléculaire, ce qui permettrait d'obtenir des polymères avec des cavités capables de reconnaître certains types d'oligosaccharides mimétiques de HS, et par la suite d'étudier les HS endogènes.Les GAGs extraits de tumeurs xénogreffes et du sang, de 3 à 8 semaines au cours de la croissance tumorale, ont été quantifiés par dosage colorimétrique. Nous avons observé une diminution de la quantité des GAG tumoraux et une augmentation des GAG sanguin, au cours de la croissance de la tumeur. En outre, les GAGs tumoraux montrent une affinité croissante pour le FGF-2 au cours de la croissance tumorale.Nous avons étudié l'applicabilité de la «technique d'empreinte moléculaire» pour la production d'hydrogels imprimés capables de reconnaître spécifiquement le fondaparinux, un oligosaccharide analogue de l'héparine. Nous avons préparé une bibliothèque d'hydrogels imprimés afin d'optimiser leur synthèse et obtenir des matériaux qui reconnaissent spécifique et sélectivement cette molécule cible. Nos résultats montrent que, par un contrôle minutieux de la stœchiométrie et de la proportion de l'agent de réticulation utilisé lors de leur synthèse ainsi que la détermination des conditions de reconnaissance, les hydrogels imprimés reconnaissent spécifiquement les oligosaccharides mimétiques de HS.Ces travaux ouvrent des intéressantes perspectives d'application de la technologie d'impression moléculaire à l'analyse des séquences de GAGs extraits d'un milieu biologique. / GAGs, and particularly heparan sulfate (HS) and chondoitin sulfate (CS), are linear and sulfated polysaccharides located at the cell surface and extracellular matrix from where they influence the functions of cells. GAGs are known to bind and regulate the activity of a number of distinct proteins known as ‘heparin binding proteins' including chemokines, growth factors, enzymes and adhesion molecules. In the case of tumor development, heparanase over-expression has been observed. As a consequence, a variety of HS and CS oligosaccharides are released which structures and biological effects are unknown.Many tools exist for GAG characterization and a need to develop a new technology to isolate fragments of endogenous HS is required. In this context, we propose to use molecular imprinting technology that could allow to obtain polymers owing cavities able to recognize specific types of HS mimetic oligosaccharides and therefore the endogenous HS.GAGs extracted from xenografted tumors and blood, at 3 to 8 weeks during tumor growth, were quantified by a colorimetric assay. We observed a decrease in the amount of GAGs tumors and an increase of GAGs blood, during the tumor growth. Moreover, tumor GAGs were tested by competition toward growth factor with enzyme immunoassay showing increasing affinity for FGF-2 during tumor growth.We investigated the applicability of ‘Molecular Imprinting Technology' to the generation of imprinted hydrogels able of specifically recognize fondaparinux, an oligosaccharide analogue of heparin. We have prepared a library of imprinted hydrogels in order to optimize their synthesis and obtain materials that specifically and selectively recognize that oligosaccharide. Our results show that, by a careful control of the stoichiometry and crossliking choice for their synthesis and by adapting rebinding conditions, namely the temperature, imprinted hydrogels can readily be prepared to specifically recognize the HS mimetic used as model.This work opens an interesting outlook to analyze GAGs extracted from a biological medium by molecular imprinting technology Héparane sulfate Tumeur Impression moléculaire Héparanase Heparan sulfate Tumor Molecular printing Heparanase 616.99
15	Extracellular remodeling enzyme processed heparan sulfate oligosaccharides: method development and characterization using liquid chromatography mass spectrometry Huang, Yu 22 January 2016 (has links) Glycans and glycoconjugates exert myriad important biological functions, extending and diversifying the functionality of protein molecules. Extensive studies have focused on the protein and gene realms; however, due to the lack of means for external amplification and the inherent heterogeneity of glycans and glycoconjugates, their researches have not adequately informed the understanding of critical biological and pathological processes. Researchers in glycoscience have strived to bridge this gap and redefine our understanding of carbohydrate functions. Glycosaminoglycans (GAGs) represent the most highly charged and poly-disperse animal glycans. GAGs exist on the surfaces of most mammalian cells and in the extracellular matrices. They play critical roles in anticoagulation, angiogenesis, inflammation, metastasis, cell proliferation and differentiation. Heparin and heparan sulfate (HS) are the most highly sulfated and structurally diverse GAGs, regulating a variety of cell functions by interacting directly with many growth factors and their receptors. Examples include fibroblast growth factor, bone morphogenetic protein and Wnt. These interactions rely on the unique structural properties of HS/heparin molecules. Extracellular enzymes (Sulfs and heparanase) also alter the fine structure of HS molecules. In order to investigate to the correlation between structure and function for mature HS/heparin chains, we employed mass spectrometry (MS) coupled with liquid chromatography (LC) as a sensitive and robust platform for composition profiling and detailed structural characterization. We developed a novel HPLC-chip based LC-MS platform to enable HS oligosaccharide profiling. In this thesis work, the chip LC-MS platform was improved for effective and informative tandem MS for HS oligosaccharides. We also advanced electron-based ion dissociation methods for more detailed and reliable sequence determination of HS oligosaccharides. These newly developed methods enable the investigation of the HS/heparin structural changes induced by HS extracellular remodeling enzymes, human Sulfs and heparanase. Application of the methods revealed the recognition preferences of these remodeling enzymes at the oligosaccharide level and led to the discovery of a novel peeling reaction induced by the 3-O-sulfation at the reducing end of HS saccharides. Biochemistry 3-O-sulfation Sulf Heparanase Heparan sulfate oligosaccharides Liquid chromatography Mass spectrometry
16	Implications of Heparan Sulfate and Heparanase in Inflammatory Diseases Digre, Andreas January 2017 (has links) Heparan sulfate (HS), an unbranched sulfated carbohydrate chain, and the HS-degrading enzyme heparanase play important roles in physiological and pathological processes during all stages of life, from early embryogenesis to ageing. Accumulated information shows that HS and heparanase are involved in inflammatory processes and associated diseases, e.g. rheumatoid arthritis (RA) and Alzheimer’s disease. In this thesis I have investigated the role of HS and heparanase (Hpa) in inflammatory-related pathologies. In the first project, Hpa overexpressing mice (Hpa-tg) were induced with a murine model of RA. We found a pro-inflammatory role of Hpa through enhancing the activity of T-cells and innate immune cells, which contributed to an augmented severity of clinical symptoms in the Hpa-tg mice. In my second project, we revealed co-current interaction of heparin with both ApoA1 and SAA of HDL isolated from plasma of inflamed mouse. Mass spectrometry analysis indicated close proximity of ApoA1 and SAA on the HDL surface, providing a molecular and structural mechanism for the simultaneous binding of heparin to apoA1 and SAA. In my third project, we investigated the role of Hpa in AA amyloid formation and resolution in mice in a model of AA-amyloidosis. We found a similar degree of amyloid formation in Hpa-KO mice compared to the wildtype control mice, but the resolution process was faster in Hpa-KO mice. The rapid clearance of deposited SAA in Hpa-KO mice was associated with upregulated expression of matrix metalloproteases. The results suggest an associated function of ECM proteases with heparanase in the process of AA amyloid resolution. In my fourth project, we found that overexpression of heparanase impaired inflammation associated beta amyloid (Aβ) clearance in the brain of an Alzheimer’s disease mouse model. Examination of the cytokine profile of brain lysates revealed an overall lower inflammatory reaction in the double transgenic (tgHpa*Swe) mice compared to single APP-tg (tg-Swe) mice in response to LPS-induced inflammation. Heparanase Heparan sulfate Inflammation Inflammatory diseases Autoimmune diseases Amyloidosis Reumathoid arthritis SAA APP A beta Neuroinflammation Basic Medicine Medicinska grundvetenskaper
17	Urofacial syndrome : a genetic model to understand human urinary tract abnormalities Stuart, Helen January 2015 (has links) Urofacial syndrome (UFS; MIM# 236730) is a rare autosomal recessive condition characterised by urinary bladder and bowel voiding dysfunction with a pathognomonic abnormality of facial movement with expression. UFS can be caused by biallelic putative loss-of-function mutations in HPSE2, which encodes heparanase 2. Failure to discover HPSE2 mutations in all cases of UFS suggests genetic heterogeneity. The urinary tract features of UFS overlap those seen in the spectrum of non-syndromic non-neurogenic voiding dysfunction and vesicoureteric reflux (VUR). This overlap suggests there may be some aspects of pathogenesis in common. The project aimed to define the genotypic and phenotypic spectrum associated with mutations in HPSE2 by Sanger sequencing and multiplex ligation-dependent probe amplification (MPLA) in newly referred cases of UFS and making comparison to a review of mutations and phenotypes seen in the literature. This work discovered five further families with HPSE2 associated UFS increasing known mutations whilst, reinforced that this is an under-recognised condition and emphasised the previously under-reported feature of facial weakness. The failure to discover HPSE2 mutations in all cases referred provided further evidence of genetic heterogeneity. The project also aimed to discover further genes associated with UFS. Autozygosity mapping and whole exome sequencing was carried out in cases of UFS without mutations in HPSE2. This led to the recognition that UFS is also caused by biallelic putative loss-of-function mutations in LRIG2 encoding the leucine-rich repeats and immunoglobulin-like domains 2 (LRIG2) protein in three families. Failure to identify LRIG2 mutations in all HPSE2 negative families suggests further genetic heterogeneity. To address the question of whether the pathogenesis of UFS overlaps more common conditions with a similar spectrum of urinary tract abnormalities I aimed to examine whether pathogenic variants in HPSE2 and LRIG2 were seen in these phenotypes. Unexpectedly this led to the discovering of further families affected by UFS but failed to show an association of variants in UFS genes with non-syndromic urinary tract abnormalities. However, variants of potential interest were discovered. As part of work toward understanding the pathogenesis of UFS and designing a model to test the pathogenesis of sequence variants expression studies in a Xenopus tropicalis hpse2 knock-down model of UFS were carried out. The knock-down model provided valuable insight in to the likely pathogenesis of UFS with evidence pointing towards a congenital peripheral neuropathy with failure of correct nerve path finding. Understanding the pathogenesis of UFS has the potential to direct further research in to therapeutic intervention. 616.6
18	Conception de polysaccharides sulfatés inhibiteurs de l’héparanase pour le traitement de l’angiogénèse tumorale / Design of sulfated polysaccharide-based heparanase inhibitors for the treatment of tumor angiogenesis Poupard, Nicolas 30 June 2017 (has links) L’angiogénèse tumorale correspond à la formation de nouveaux vaisseaux sanguins afin d’alimenter la tumeur et d’amplifier son développement. Cette étape constitue un facteur pronostique défavorable pour les patients et son inhibition représente un fort intérêt thérapeutique. Parmi les acteurs participant à l’angiogénèse tumorale, on retrouve l’enzyme de dégradation héparanase au sein du microenvironnement tumoral de nombreux cancers. Ces travaux de thèse ont pour objectif de développer des inhibiteurs spécifiques de l’héparanase à partir de polysaccharides sulfatés pour le traitement de l’angiogénèse tumorale. La première partie de ces travaux a été consacrée à l’élaboration de polysaccharides sulfatés de bas poids moléculaires issus de sources animales (Héparine, Chrondroïtine sulfate), algales (Fucoïdanes, Carraghénane-λ-ι-κ) ou bactérienne (Dextran sulfate). Nous avons utilisé pour cela un procédé de dépolymérisation radicalaire assisté par ultrasons, développé en 2013 au laboratoire, que nous avons associé à un procédé de modification chimique appelé glycol-split. Les composés produits ont été évalués pour leurs activités d’inhibition de l’héparanase et de la coagulation sanguine. Ce criblage a notamment permis l’identification d’un dérivé de bas poids moléculaire issu de Carraghénane-λ possédant une forte inhibition de l’héparanase pour une faible inhibition de la coagulation. La deuxième partie de ces travaux s’est ensuite concentrée sur l’évaluation du potentiel anti-angiogénique des inhibiteurs de l’héparanase. Dans ce but, nous avons dans un premier temps évalué le rôle de l’hypoxie et/ou le manque de nutriments sur la production d’héparanase par des cellules de cancers mammaires. Dans ces conditions de stress, nous avons observé que la lignée MCF-7 excrétait une forte quantité d’héparanase. L’analyse en Matrigel 3D du réseau angiogénique formé par des cellules microvasculaires HskMEC, en présence du surnageant de MCF-7 riche en héparanase, a montré une forte stimulation de l’angiogénèse. Les mêmes tests réalisés en présence des inhibiteurs de l’héparanase ont montré une inhibition de l’angiogénèse qui semblait corrélée avec l’inhibition de l’héparanase. / Tumor angiogenesis is defined by the spouting of new blood vessels from preexisting ones in order to sustain and amplify the tumor development. This crucial step is associated with poor prognosis for patients and it’s inhibition is therefore considered as a primising way to treat cancer. Among several actors participating in the angiogenesis process, the degradative enzyme heparanase is active in the tumor microenvironment of many cancers. The work presented in this thesis aim to develop specific heparanase inhibitors using sulfated polysaccharides for the treatment of tumor angiogenesis. The first part of this work is dedicated to the conception of low molecular weights sulfated polysaccharides obtainable from animal source (Héparine, Chondroïtine sulfate), algal source (Fucoidan, Carrageenan-λ-ι-κ) and bacterial source (dextran sulfate). To do so, we used a depolymeriation process based on free radicals associated to ultrasonic waves developed in 2013 in the laboratory. This depolymerization method was then coupled with a chemical process called glycol-split. The produced compounds were evaluated for their capacity to inhibit heparanase and blood coagulation. This screening phase lead to the identification of a low molecular weight compound produced from λ-carrageenan endowed with a strong heparanase inhibition power and a low impact on the blood coagulation. The second part of this work was then focused on the evaluation of the anti-angiogenic properties of our best heparanase inhibitors. To do so, we first evaluated the role of hypoxia and lack of nutrients on the heparanase production from breast cancer cell lines. In these higly stressful conditions, we observed that the MCF-7 cell line secreted a huge amount of heparanase. 3D Matrigel angiogenesis network formation using Hsk-MEC microvascular cells in the presence of MCF-7 heparanase rich supernatant showed a strong angiogenesis stimulation. Same tests realized in the presence of heparanase inhibitors showed an angiogenesis inhibition power that seemed correlated with heparanase inhibition. Angiogénèse Héparanase Coagulation sanguine Microenvironnement tumoral Polysaccharides sulfatés Glycol-split Hypoxie Ciblage thérapeutique Angiogenesis Heparanase Blood coagulation Tumor microenvironment Sulfated polysaccharides Glycol-split Hypoxia Therapeutic targeting
19	Aide au ciblage du microenvironnement tumoral par le développement d’un nano-système de détection et de traitement des tumeurs avec inhibition ciblée de l’héparanase / Tumor microenvironment targeting by the development of a nano-system for the detection and treatment of tumors by targeted inhibition of heparanase Achour, Oussama 07 July 2014 (has links) Le microenvironnement des cellules tumorales présente plusieurs particularités comme l'hypoxie, l'acidification du milieu extracellulaire et l'hypersécrétion d'enzymes hydrolytiques. Ces hydrolases, comme la cathepsine D et l'héparanase, interviennent dans les étapes de la progression tumorale et notamment l'angiogenèse. Cette thèse s'intègre dans un projet dont la finalité est de concevoir un nano-objet moléculaire enzymo-sensible qui réagirait d'une manière spécifique aux enzymes hypersécrétées dans le microenvironnement tumoral pour assurer de façon simultanée, une fonction de détection et de ciblage des tumeurs. La première partie de nos travaux a été consacrée à la conception et à la validation d'un lien peptidique intégrable dans l'objet moléculaire, sensible aux formes de la cathepsine D actives du microenvironnement tumoral de cancers mammaires. Cet objectif a été réalisé suite à l'étude cinétique de l'hydrolyse de 5 peptides par la cathepsine D mature et la pro-cathepsine D dans les conditions de pH du microenvironnement tumoral. Nous avons également étudié l'effet de l'hypoxie et de l'acidification du milieu extracellulaire sur la sécrétion des formes actives de la cathepsine D par la lignée tumorale de cancer mammaire MCF-7. Dans une deuxième partie, nous avons travaillé sur l'élaboration d'héparines de bas poids moléculaire pouvant assurer la fonction thérapeutique de l'objet moléculaire grâce à leur activité anti-angiogénique. Nous avons mis au point une méthode innovante pour la dépolymérisation de l'héparine qui consiste en une hydrolyse radicalaire par le péroxyde d'hydrogène assistée par les ultrasons. Cette technique permet la production d'oligosaccharides d'héparines caractérisées par des poids moléculaires et des degrés de sulfatation contrôlés. En fonction des conditions de dépolymérisation par cette technique, les héparines de bas poids moléculaires produites peuvent être utilisées comme anticoagulant ou anti-angiogénique. / Tumor microenvironment is characterized by several particularities such as hypoxia, extracellular media acidification and the hyper-secretion of hydrolytic enzymes. These hydrolases, such as cathepsin D and heparanase, are involved in many steps of tumor progression like angiogenesis. This thesis is a part of a project that aims to develop a "smart" molecular nano-object that specifically reacts to hyper-secreted enzymes in the tumor microenvironment for the simultaneous detection and targeting of tumor. The first part of our work concerned the design and the validation of a peptide that is sensitive to active forms of cathepsin D which is a protease, unregulated in many tumors microenvironment such as breast cancers. This objective has been achieved following the kinetic study of the hydrolysis of 5 peptides by mature cathepsin D and procathepsin D in the pH conditions of the tumor microenvironment. On the other hand, we studied the effect of hypoxia and the acidification of the extracellular medium on the secretion of active forms of cathepsin D by the breast cancer cell line MCF-7. In a second part, we worked on the development of low molecular weight heparins that may provide therapeutic function of the molecular object through their anti-angiogenic activity. We have developed an innovative method for the depolymerization of heparin that consists on a radical hydrogen peroxide hydrolysis assisted by ultrasound. This technique allows the production of heparins oligosaccharides characterized by controlled molecular weight and degree of sulfatation. Depending on the depolymerization conditions by this technique, the produced low molecular weight heparins can be used as an anticoagulant or anti-angiogenic. Microenvironnement tumoral Héparanase Cathepsine D Ciblage thérapeutique Théranostique Imagerie moléculaire Héparine de bas poids moléculaire Tumor microenvironment Heparanase Cathepsin D Drug delivery Theranostic Molecular imaging Low molecular weight heparin

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