Global ETD Search

1	Dynamic Delta‐like1 expression in presomitic mesoderm cells during somite segmentation / 体節形成における未分節中胚葉細胞のDelta-like 1の発現動態 Takagi, Akari 23 March 2020 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22350号 / 医博第4591号 / 新制\|\|医\|\|1042(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授斎藤通紀, 教授浅野雅秀, 教授安達泰治 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM Delta-like 1 Hes7 Presomitic mesoderm Segmentation Somite Oscillation 490
2	Role of delta-like 4 in solid tumours and response to radiation therapy Bham, Saif Ahmed Shahab January 2013 (has links) Delta-like ligand 4 (DLL4) is a ligand for the Notch family of receptors. DLL4 is an important regulator of angiogenesis and DLL4 blockade promotes non-productive angiogenesis and delays tumour growth. The aim of this thesis was to investigate the effects of anti-DLL4 therapy in solid tumours in combination with a clinically relevant dose of ionising radiation (5 Gy; IR) and to analyse alterations in the Notch pathway induced by the treatments. Combining both treatments resulted in a greater than additive tumour growth delay in LS174T tumours, compared to either treatment alone. DLL4 blockade dysregulated vasculature and increased necrosis in LS174T and HCT-15 (DLL4-expressing and negative cell lines respectively) tumours within 3 days after treatment, but no changes were observed with IR alone. Additionally, combined IR and anti-DLL4 treatment of FaDu tumours (another DLL4-negative cell line) by our colleagues, also resulted in a supra-additive growth delay. These results show that combining IR with DLL4 blockade is an effective strategy for prolonging tumour growth delay and suggest that the stroma/vasculature provide the main therapeutic target for the anti-DLL4 therapy. Analysis of Notch pathway shows that IR upregulated Jag1 in tumour cells, and may inhibit Notch and downregulate DLL4 in the stroma. These changes may potentially affect tumour vessels and response to anti-DLL4 therapy. In vitro, anti-DLL4 therapy induced proliferation in quiescent contact-inhibited endothelial cells and also appeared to abrogate IR-induced inhibition of migration. These results suggest that DLL4 may be important in maintaining vessel quiescence and that IR may in part decrease migration through Notch signalling. Combining IR and DLL4 blockade to target tumour growth is an effective and well tolerated strategy and warrants further validation and refinement to be translated into clinical practice. 616.99
3	Exploring the sequence-fitness relationship of different protein systems using protein engineering approaches Jain, Charu January 2022 (has links) No description available. Chemistry
4	<b>A Cell Autonomous Function of Delta-Like 1 </b><b>Intracellular Domain In Skeletal Muscle</b> Sara Brooke Scinto (19199458) 25 July 2024 (has links) <p dir="ltr">Delta-like 1 (DLL1) is a protein on the surface of the cell that serves as a ligand for NOTCH receptors. Like NOTCH receptors, NOTCH ligands span the membrane of the cell and contain extracellular, transmembrane, and intracellular domains. NOTCH activation occurs through contact-dependent interactions between the NOTCH receptor on one cell and ligand on an adjacent cell. Previous studies have demonstrated that DLL1 predominantly functions cell non-autonomously to trigger NOTCH signaling in a neighbor cell but a cell-autonomous function of DLL1 has also been proposed in recent years. However, there is no direct evidence to support a cell-autonomous function of DLL1 in vivo. The overall goal of this thesis was to elucidate the cell-autonomous function of DLL1 by testing the hypothesis that the intracellular domain of DLL1 (DLL1ICD) can be cleaved and function in the DLL1-expressing cell in addition to triggering NOTCH signaling in a neighbor cell. The research strategy to test the hypothesis is by overexpression of full-length (FL) and cleaved Dll1 (Dll1ICD) in the murine myoblast cell line (C2C12). These plasmids utilize a tet-on system for inducible overexpression. Transfected myoblasts were used to analyze how overexpression of Dll1-FL and Dll1ICD affects proliferation, differentiation, fusion, and gene expression. The results show that Dll1-FL can be cleaved to generate an ICD. DLL1ICD overexpression promotes fusion without affecting proliferation. Further investigation reveals that overexpression of Dll1ICD affects the expression of NOTCH and myogenic-specific genes during differentiation, confirming the cell-autonomous role of DLL1ICD in myoblasts. These results together show that DLL1 can function cell autonomously through its intracellular domain to regulate myogenesis.</p> Animal cell and molecular biology Skeletal Muscle, Notch Signaling Delta-Like 1
5	Protein and mRNA Studies of Rat FA1/Pref-1/dlk Persdotter Hedlund, Gabriella January 2007 (has links) <p>The timing of cell differentiation is important for development and renewal of well functioning organs and tissues. One protein involved in this process is Preadipocyte factor 1 (Pref-1). Most likely, the role of this protein is to maintain cells in an undifferentiated state. </p><p>The work presented in this thesis, has employed the rat as an animal model for the studies of Pref-1. Rat models of obesity (Zucker, ZO) and type II diabetes (Goto-Kakizaki, GK) were used to determine metabolic influence on Pref-1 and adipokine mRNA expression in adipose tissues.</p><p>The Pref-1 cleavage product was purified from rat amniotic fluid and physicochemically characterised. Concentration of Pref-1 in serum, amniotic fluid and urine was determined by ELISA. Soluble Pref-1 and the compartmentalisation of the protein were highly similar to what had previously been demonstrated in mice and humans.</p><p>Immunohistochemistry studies displayed similar staining patterns of Pref-1 in adrenal glands, ovaries and pituitary glands of non-pregnant and pregnant rats. This suggests that pregnancy do not influence the protein expression of Pref-1 in these organs.</p><p>In the GK rats, Pref-1 mRNA was altered and a decrease in the visceral compared to subcutaneous adipose depots was demonstrated, in contrast to the ZO rats. Additionally, adiponectin, leptin, IL-6 and TNF-α mRNA levels were altered in the diabetic strain, indicating that this animal model expresses many of the typical features of type II diabetes.</p><p>In conclusion, the rat is an appropriate model for studies of FA1/Pref-1/dlk. Pref-1 is highly elevated in fetal and maternal serum during pregnancy. However, the expression of Pref-1 in some endocrine tissues did not alter due to pregnancy. The mRNA expression of Pref-1 was altered between adipose depots and demonstrated to be affected by metabolic disturbances in the animals.</p> Laboratory animals Preadipocyte factor 1 delta like protein Fetal antigen 1 Goto-Kakizaki Zucker adipokines adipose tissue diabetes obesity Försöksdjursvetenskap
6	An Investigation of Vascular Strategies to Augment Radiation Therapy / An Investigation of Vascular Strategies to Augment Radiation Therapy El Kaffas, Ahmed 18 July 2014 (has links) Radiation therapy is administered to more than 50% of patients diagnosed with cancer. Mechanisms of interaction between radiation and tumour cells are relatively well understood on a molecular level, but much remains uncertain regarding how radiation interacts with the tumour as a whole. Recent studies have suggested that tumour response to radiation may in fact be regulated by endothelial cell response, consequently stressing the role of tumour blood vessels in radiation treatment response. As a result, various treatment regimens have been proposed to strategically combine radiation with vascular targeting agents. A great deal of effort has been aimed towards developing efficient vascular targeting agents. Nonetheless, no optimal method has yet been devised to strategically deliver such agents. Recent evidence suggesting that these drugs may “normalize” tumour blood vessels and enhance radiosensitivity, is supporting experiments where anti-angiogenic drugs are combined with cytotoxic therapies such as radiotherapy. In contrast, ultrasound-stimulated microbubbles have recently been demonstrated to enhance radiation therapy by biophysically interacting with endothelial cells. When combined with single radiation doses, these microbubbles are believed to cause localized vascular destruction followed by tumour cell death. Finally, a new form of ‘pro-angiogenics’ has also been demonstrated to induce a therapeutic tumour response. The overall aim of this thesis is to study the role of tumour blood vessels in treatment responses to single-dose radiation therapy and to investigate radiation-based vascular targeting strategies. Using pharmacological and biophysical agents, blood vessels were altered to determine how they influence tumour cell death, clonogenicity, and tumour growth, and to study how these may be optimally combined with radiation. Three-dimensional high-frequency power Doppler ultrasound was used throughout these studies to investigate vascular response to therapy. Tumour Vasculature Radiation Therapy Ultrasound Doppler Anti-Vascular Microbubbles Delta Like Ligand 4 0786 0760 0992 0756 0541
7	Protein and mRNA Studies of Rat FA1/Pref-1/dlk Persdotter Hedlund, Gabriella January 2007 (has links) The timing of cell differentiation is important for development and renewal of well functioning organs and tissues. One protein involved in this process is Preadipocyte factor 1 (Pref-1). Most likely, the role of this protein is to maintain cells in an undifferentiated state. The work presented in this thesis, has employed the rat as an animal model for the studies of Pref-1. Rat models of obesity (Zucker, ZO) and type II diabetes (Goto-Kakizaki, GK) were used to determine metabolic influence on Pref-1 and adipokine mRNA expression in adipose tissues. The Pref-1 cleavage product was purified from rat amniotic fluid and physicochemically characterised. Concentration of Pref-1 in serum, amniotic fluid and urine was determined by ELISA. Soluble Pref-1 and the compartmentalisation of the protein were highly similar to what had previously been demonstrated in mice and humans. Immunohistochemistry studies displayed similar staining patterns of Pref-1 in adrenal glands, ovaries and pituitary glands of non-pregnant and pregnant rats. This suggests that pregnancy do not influence the protein expression of Pref-1 in these organs. In the GK rats, Pref-1 mRNA was altered and a decrease in the visceral compared to subcutaneous adipose depots was demonstrated, in contrast to the ZO rats. Additionally, adiponectin, leptin, IL-6 and TNF-α mRNA levels were altered in the diabetic strain, indicating that this animal model expresses many of the typical features of type II diabetes. In conclusion, the rat is an appropriate model for studies of FA1/Pref-1/dlk. Pref-1 is highly elevated in fetal and maternal serum during pregnancy. However, the expression of Pref-1 in some endocrine tissues did not alter due to pregnancy. The mRNA expression of Pref-1 was altered between adipose depots and demonstrated to be affected by metabolic disturbances in the animals. Laboratory animals Preadipocyte factor 1 delta like protein Fetal antigen 1 Goto-Kakizaki Zucker adipokines adipose tissue diabetes obesity Försöksdjursvetenskap
8	Étude de la régulation de l'activité du ligand Delta dans le cadre de la signalisation Notch Assaker, Gloria 05 1900 (has links) La voie de signalisation Notch est conservée au cours de l'évolution. Elle joue un rôle clé dans le développement, et elle est impliquée dans de nombreuses décisions de destin cellulaire, dans le maintien des cellules souches, et dans le contrôle de la prolifération et de la différenciation cellulaires. Une dérégulation de la signalisation Notch est impliquée dans diverses maladies et cancers, y compris les tumeurs solides, comme les cancers du sein et du col de l'utérus, et les leucémies, comme la Leucémie Aiguë Lymphoblastique des cellules T (LAL-T). Notch est un récepteur transmembranaire activé par des ligands transmembranaires de la famille DSL (Delta/Serrate/Lag-2). Bien que plusieurs mutations oncogéniques ont été identifiées au niveau du récepteur Notch, de nombreux cancers modulés par Notch demeurent ligand-dépendants. Étonnamment, les mécanismes moléculaires régulant l'activation du ligand sont encore relativement peu caractérisés par rapport à ceux qui régissent le récepteur Notch lui-même. Utilisant un essai de co-culture avec un rapporteur luciférase de Notch, nous avons effectué le premier crible d'ARNi pan-génomique visant spécifiquement à identifier des régulateurs des ligands de Notch dans la cellule émettrice du signal. Nous avons ainsi pu découvrir de nouvelles classes de régulateurs communs pour les ligands Delta-like1 et 4. Ces régulateurs comprennent des inhibiteurs de protéases, des facteurs de transcription, et des gènes divers à fonction inconnue, tels que Tmem128 « Transmembrane protein 128 », ou à fonction préalablement caractérisée tels que la co-chaperonne moléculaire Cdc37 « Cell division cycle 37 homolog ». Par la suite, nous avons développé des cribles secondaires fonctionnels où nous avons démontré l'importance de ces régulateurs pour des événements Notch-dépendants, comme la différenciation des cellules T normales, et la survie des cellules souches pré-leucémiques isolées à partir d'un modèle murin de LAL-T. En outre, nous avons prouvé que les régulateurs les plus forts du crible de survie sont également nécessaires pour l'activité d'auto-renouvellement des cellules souches pré-leucémiques. Finalement, nous avons entamé une caractérisation moléculaire préliminaire de deux régulateurs nouvellement identifiés; Tmem128 et Cdc37 afin d'étudier leur mécanisme d'action sur les ligands. En conclusion, cette étude nous a permis d'identifier de nouveaux régulateurs de la voie Notch qui pourraient servir de cibles thérapeutiques potentielles dans les cancers; tel qu'illustré par le modèle LAL-T. La compréhension des détails moléculaires sous-jacents aux fonctions de ces régulateurs sera essentielle afin de développer des inhibiteurs pharmacologiques pour bloquer leur action et entraver la signalisation Notch dans le cancer. / The Notch signalling pathway is evolutionarily conserved. It plays a key role in development and it is involved in multiple cell fate decisions, in the maintenance of stem cells, and in the regulation of cell proliferation and differentiation. Misregulation of Notch signalling is implicated in various diseases and cancers including solid tumours, such as breast and cervical cancers, and leukemias, such as T-cell Acute Lymphoblastic Leukemia (T-ALL). Notch is a transmembrane receptor activated by transmembrane ligands of the DSL family (Delta/Serrate/Lag-2). Whereas oncogenic mutations have been identified in the Notch receptor, many Notch-mediated cancers remain ligand-dependent. Strikingly, the molecular mechanisms that regulate ligand activation are still poorly characterized as compared to those regulating the Notch receptor itself. Using a co-culture assay with a luciferase Notch reporter, we performed the first genome-wide RNAi screen aiming specifically at identifying regulators of Notch ligands in the signal-sending cell. We thereby unraveled new classes of common regulators for both Delta-like1 and 4 ligands. These regulators include protease inhibitors, transcription factors and various genes of unknown function such as Tmem128 (Transmembrane protein 128), or of previously characterized function such as the molecular co-chaperone Cdc37 (Cell division cycle 37 homolog). We next developed functional secondary screens where we demonstrated that our hits are important for Notch-mediated events, such as normal T-cell differentiation, and survival of pre-leukemic stem cells (pre-LSCs) isolated from a mouse model of T-ALL. Moreover, we showed that top hits from the pre-LSC survival screen are also required for the self-renewal activity of pre-LSCs. Finally, we performed a preliminary molecular characterization of two newly identified regulators; Tmem128 and Cdc37 in order to investigate their mechanism of action on Delta-like ligands. Altogether, this study led to the identification of novel Notch pathway regulators that could serve as potential therapeutic targets in Notch cancers, as exemplified by the T-ALL model. Elucidating the finer details that underlie the molecular functions of these regulators will be critical to develop pharmacological inhibitors to counteract their action and impede Notch signalling in cancer. Notch Delta-like Crible Screen Inhibiteurs de protéases Protease inhibitors Tmem128 Cdc37 Différenciation des cellules T T-cell differentiation LAL-T T-ALL
9	The Role of Chicken Delta-Like Protein 1 Expression in Skeletal Muscle Development and Regeneration Shin, Jonghyun 01 October 2009 (has links) No description available. Biology Chicken Delta-Like Protein 1 (gDLK1) Myogenic Regulatory Factors (MRFs) Muscle hypertrophy Development Regeneration Cell Differentiation Myofibers Broilers Leghorn Layers Low Score Normal (LSN) Muscular Dystrophy (MD)

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