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Development of Synthetic Peptide Sequences for Mitochondrial Delivery and DisruptionHorton, Kristin 15 September 2011 (has links)
The mitochondrion is an important therapeutic target due to its roles in energy metabolism, reactive oxygen species production, and activation of cell death. The connection of these cellular processes with diabetes, obesity, neurodegenerative disorders, and cancer makes this organelle a potential control point for treatment of these diseases. The advancement of mitochondrial medicine will be accelerated by the development of organelle-specific cellular transporters as well as by strategies to enhance the activity of mitochondrially-active drugs. Here, the discovery and development of a new class of mitochondria-specific agents, mitochondria-penetrating peptides (MPPs), is described. These peptides, exemplified by the sequences (FXY)3 and (FXY)4 where FX=cyclohexylalanine and Y=basic arginine or lysine residues, display hydrophobic and cationic residues critical for access to this organelle, and appear to accumulate within cells and mitochondria through membrane potential-dependent mechanisms. Subcellular localization of the peptides was determined by the interplay of hydrophobicity and positive charge, and necessary lipophilicity “thresholds” for access to the mitochondrion. MPPs can be engineered to have minimal mitochondrial disruptive activity and cytotoxicity through minimization of hydrophobicity and length. Furthermore, MPPs appear to accumulate predominantly in the mitochondrial matrix, a feature which places them within an exclusive class of mitochondria-specific transporters and may enable delivery applications for a number of therapeutically-relevant cargoes. Information gained from MPP studies on the physiochemical parameters that drive mitochondrial localization were applied to improve the activity of the anticancer peptide d-(KLAKLAK)2, an agent that activates apoptosis through mitochondrial disruption. Residue substitutions that increased peptide hydrophobicity, regardless of changes to secondary structure, enhanced mitochondrial localization, activity, and cytotoxicity induced by the peptide. In conclusion, these studies provide important guidelines for how to drive the subcellular localization and activity of peptides, and expand the possibilities for mitochondrially-targeted therapeutics.
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Development of Synthetic Peptide Sequences for Mitochondrial Delivery and DisruptionHorton, Kristin 15 September 2011 (has links)
The mitochondrion is an important therapeutic target due to its roles in energy metabolism, reactive oxygen species production, and activation of cell death. The connection of these cellular processes with diabetes, obesity, neurodegenerative disorders, and cancer makes this organelle a potential control point for treatment of these diseases. The advancement of mitochondrial medicine will be accelerated by the development of organelle-specific cellular transporters as well as by strategies to enhance the activity of mitochondrially-active drugs. Here, the discovery and development of a new class of mitochondria-specific agents, mitochondria-penetrating peptides (MPPs), is described. These peptides, exemplified by the sequences (FXY)3 and (FXY)4 where FX=cyclohexylalanine and Y=basic arginine or lysine residues, display hydrophobic and cationic residues critical for access to this organelle, and appear to accumulate within cells and mitochondria through membrane potential-dependent mechanisms. Subcellular localization of the peptides was determined by the interplay of hydrophobicity and positive charge, and necessary lipophilicity “thresholds” for access to the mitochondrion. MPPs can be engineered to have minimal mitochondrial disruptive activity and cytotoxicity through minimization of hydrophobicity and length. Furthermore, MPPs appear to accumulate predominantly in the mitochondrial matrix, a feature which places them within an exclusive class of mitochondria-specific transporters and may enable delivery applications for a number of therapeutically-relevant cargoes. Information gained from MPP studies on the physiochemical parameters that drive mitochondrial localization were applied to improve the activity of the anticancer peptide d-(KLAKLAK)2, an agent that activates apoptosis through mitochondrial disruption. Residue substitutions that increased peptide hydrophobicity, regardless of changes to secondary structure, enhanced mitochondrial localization, activity, and cytotoxicity induced by the peptide. In conclusion, these studies provide important guidelines for how to drive the subcellular localization and activity of peptides, and expand the possibilities for mitochondrially-targeted therapeutics.
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Reduced numbers and proapoptotic features of mucosal-associated invariant T cells as a characteristic finding in IBD patients / 炎症性腸疾患患者ではMucosal-associated invariant T細胞が減少しており、アポトーシスを起こしやすいという特徴がある。Hiejima, Eitaro 25 January 2016 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第12978号 / 論医博第2104号 / 新制||医||1012(附属図書館) / 32448 / 京都大学大学院医学研究科医学専攻 / (主査)教授 三森 経世, 教授 椛島 健治, 教授 生田 宏一 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Etude des régions d'insertion membranaire des protéines de la famille Bcl-2 et conception de "poropetides" anticancéreux / Study of membrane-active regions of Bcl-2 family proteins and development of anticancer "poropeptides"Garcia Valero, Juan 18 February 2011 (has links)
Les protéines de la famille Bcl-2 sont des régulateurs-clés de l’apoptose (mort cellulaire), qui agissent en contrôlant la perméabilisation de la membrane mitochondriale externe par un processus encore mal connu. La dérégulation des membres de cette famille est souvent associée à la progression tumorale et à la résistance à la chimiothérapie. Notre projet a cherché à éclaircir le mode d’action de ces protéines en se focalisant sur les déterminants structuraux régissant leur interaction avec les membranes biologiques. Les connaissances glanées ont permis (i) de mieux comprendre les déterminants à l’origine de la divergence évolutive entre membres pro- et anti-apoptotiques de la famille Bcl-2 ; (ii) d’ouvrir la voie à la conception de ‘poropeptides’ conçus sur le modèle des hélices d’insertion membranaire des protéines Bcl-2, et qui pourraient être utilisés pour induire l’apoptose de cellules tumorales ou des cellules endothéliales entourant les tumeurs. / Bcl-2 family proteins, which include pro- and antiapoptotic members, positively or negatively regulate mitochondrial outer membrane permeabilization, i.e. a critical step in apoptosis. Over-expression of pro-survival members is associated with tumor progression and may be responsible for chemotherapy resistance. Detailed understanding of the precise mechanisms by which Bcl-2 family members control apoptosis is therefore of considerable therapeutic interest. The overall aim of our project was to delineate a structure-function relationship of Bcl-2 family proteins with emphasis on their membrane-active domains. This analysis has provided a basis (i) to elucidate the molecular mechanisms by which different Bcl-2 proteins evolved opposite functions ; (i) to develop a new generation of pore-forming peptides targeting the mitochondrial outer membrane that may be used to kill neoplastic or tumor endothelial cells.
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