Global ETD Search

11	Identification et caractérisation d'un domaine de transactivation dans l’hélicase E1 des papillomavirus humains Morin, Geneviève 04 1900 (has links) Les papillomavirus sont des virus à ADN qui infectent la peau et les muqueuses. Ils causent des verrues et peuvent aussi mener au développement de cancers, dont le cancer du col de l’utérus. La réplication de leur génome nécessite deux protéines virales : l’hélicase E1 et le facteur de transcription E2, qui recrute E1 à l’origine de réplication virale. Pour faciliter l’étude de la réplication du génome viral, un essai quantitatif et à haut débit basé sur l’expression de la luciférase a été développé. Parallèlement, un domaine de transactivation a été identifié dans la région régulatrice N-terminale de la protéine E1. La caractérisation de ce domaine a montré que son intégrité est importante pour la réplication de l’ADN. Cette étude suggère que le domaine de transactivation de E1 est une région protéique intrinsèquement désordonnée qui permet la régulation de la réplication du génome viral par son interaction avec diverses protéines. / Papillomaviruses are small DNA viruses that infect skin and mucosa. They cause warts and can also lead to the development of cancers, including cervical cancer. Replication of their genome requires two viral proteins: the E1 helicase and the E2 transcription factor, which recruits E1 to the viral origin of replication. To facilitate the study of viral genome replication, a quantitative and high-throughput assay based on luciferase expression has been developed. In parallel, a transactivation domain has been identified in the N-terminal regulatory region of the E1 protein. Characterization of this domain showed that its integrity is important for DNA replication. This study suggests that the E1 transactivation domain is an intrinsically unstructured protein region that allows regulation of viral genome replication by its interaction with diverse proteins. Papillomavirus Hélicase E1 Réplication de l'ADN Luciférase SV40 Transactivation Désordre protéique Papillomavirus Helicase E1 DNA replication Luciferase SV40 Transactivation Protein disorder
12	Identification et caractérisation d'un domaine de transactivation dans l’hélicase E1 des papillomavirus humains Morin, Geneviève 04 1900 (has links) Les papillomavirus sont des virus à ADN qui infectent la peau et les muqueuses. Ils causent des verrues et peuvent aussi mener au développement de cancers, dont le cancer du col de l’utérus. La réplication de leur génome nécessite deux protéines virales : l’hélicase E1 et le facteur de transcription E2, qui recrute E1 à l’origine de réplication virale. Pour faciliter l’étude de la réplication du génome viral, un essai quantitatif et à haut débit basé sur l’expression de la luciférase a été développé. Parallèlement, un domaine de transactivation a été identifié dans la région régulatrice N-terminale de la protéine E1. La caractérisation de ce domaine a montré que son intégrité est importante pour la réplication de l’ADN. Cette étude suggère que le domaine de transactivation de E1 est une région protéique intrinsèquement désordonnée qui permet la régulation de la réplication du génome viral par son interaction avec diverses protéines. / Papillomaviruses are small DNA viruses that infect skin and mucosa. They cause warts and can also lead to the development of cancers, including cervical cancer. Replication of their genome requires two viral proteins: the E1 helicase and the E2 transcription factor, which recruits E1 to the viral origin of replication. To facilitate the study of viral genome replication, a quantitative and high-throughput assay based on luciferase expression has been developed. In parallel, a transactivation domain has been identified in the N-terminal regulatory region of the E1 protein. Characterization of this domain showed that its integrity is important for DNA replication. This study suggests that the E1 transactivation domain is an intrinsically unstructured protein region that allows regulation of viral genome replication by its interaction with diverse proteins. Papillomavirus Hélicase E1 Réplication de l'ADN Luciférase SV40 Transactivation Désordre protéique Papillomavirus Helicase E1 DNA replication Luciferase SV40 Transactivation Protein disorder
13	Étude moléculaire des événements associés à la transformation par l'antigène grand T du virus de polyome (PyLT-Ag) = An analysis of molecular events associated with transformation by polyomavirus large T antigen (PyLT-Ag) Rodier, Francis January 2004 (has links) Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal. Carcinogénèse Étapes multiples Immortalisation Transformation Polyome murin SV40 Antigène grand-T
14	Interactions of CPI drugs with the SV40 DNA replication origin and characterization of the porphyrin-quadruplex complexes / Han, Xiaoguang, January 1998 (has links) Thesis (Ph. D.)--University of Texas at Austin, 1998. / Vita. Includes bibliographical references (leaves 203-212). Available also in a digital version from Dissertation Abstracts.
15	Microphysiometry Studies of Rapid Binding of Insulin-Like Growth Factor I by Parental and Transfected Mammary Epithelial Cell Lines Robinson, Rose Marie 13 November 1998 (has links) Breast cancer is a leading cause of cancer death of women in the U.S. today. Members of the family of insulin-like growth factors (IGFs) are proposed to play a major role in the development and subsequent uncontrolled proliferation of breast cancer cells. Insulin-like growth factor-I (IGF-I) is known to be a potent mitogen for mammary epithelial cells. IGF-I acts by binding to cell surface receptors, thereby stimulating a cascade of events leading to cell division. In the interest of interrupting the effect of IGF-I on cancerous mammary epithelial cells, an understanding of how IGF-I behaves in the presence of other extracellular components is needed. This study examines the IGF-I response of SV40-IGF-I, an immortalized bovine mammary epithelial cell line which secretes IGF-I constitutively. The microphysiometer allows real-time sampling of cellular activity by measuring the excretion of protons from a sample of cells stimulated by IGF-I binding. The contributions of other factors in enhancing or suppressing stimulation can be compared by examining the pH response of cells exposed to IGF-I in the presence of these factors. We present data showing the stimulatory effect of IGF-I in a dose dependent manner on the SV40-IGF-I cell line. In addition, we compare IGF-I stimulation with stimulation by long R3IGF-I, a substituted analogue of IGF-I having a reduced binding affinity for the IGF binding proteins. We examine the effect of insulin-like binding protein-3 (IGFBP-3) both in the presence and absence of IGF-I, finding no IGF-I independent effect in the rapid binding experiment and no effect on stimulation of IGFBP-3 pre-incubated cells by subsequent IGF-I challenge. This is of particular interest due to recent work demonstrating an IGF-independent IGFBP-3 response in a number of cell lines. Binding studies to correlate with the rapid binding stimulation show binding of the IGFBP-3 molecule with high affinity to a small number of surface receptors on the SV40-IGF-I cell. Analysis of the extracellular environment and the components contributing to the binding of IGF-I to the cell membrane receptor will provide information for the development of interventions to slow or interrupt the process of IGF-I binding and therefore cancer growth. Optimization of the Cytosensor(r) Microphysiometer System for the (transfected) SV40-IGF-I and the (parental) MAC-T cell lines was achieved to continue comparison studies of autocrine and paracrine stimulation of bovine mammary epithelial cells by IGF-I. This work was supported by the Whitaker Foundation Biomedical Engineering Grant. / Master of Science Insulin-Like Growth Factor II (IGF-II) Insulin-Like Growth Factor I (IGF-I) SV40-IGF-I MAC-T

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