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Identification of the function of the carboxy terminus of AFAP-110 in regulating AFAP-110's self-association, cell localization and the integrity of actin filamentsQian, Yong. January 1999 (has links)
Thesis (Ph. D.)--West Virginia University, 1999. / Title from document title page. Document formatted into pages; contains vi, 163 p. : ill. (some col.) Vita. Includes abstract. Includes bibliographical references.
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Factor inhibiting ATF4-mediated transcription is a novel leucine zipper transcriptional repressor that regulates bone massYu, Vionnie Wing Chi. January 2007 (has links)
Skeletal development is a complex event that requires a delicate balance between bone formation and bone resorption. Multiple transcription factors expressed in the bone-forming cells, osteoblasts, play crucial roles during the process of bone formation. Among them, ATF4 (Activating Transcription Factor 4) is a basic domain-leucine zipper transcriptional activator that is responsible for osteoblast differentiation, osteoblast-specific genes expression, synthesis of type I collagen, and osteoclast differentiation. Mice deficient for ATF4 are runted and exhibit severe skeletal dysplasia. Our laboratory has discovered Factor Inhibiting ATF4-mediated Transcription (FIAT), whose name was coined for its interaction with ATF4 and subsequent repression of ATF4-mediated osteocalcin gene transcription. FIAT is a leucine zipper nuclear molecule lacking a basic domain for DNA binding. We hypothesize that FIAT suppresses the bone-forming activities of osteoblasts by interacting with ATF4 and thereby blocking ATF4 attachment to the DNA to mediate downstream signalling pathways. To prove this hypothesis, we monitored the expression profiles of FIAT in parallel with ATF4 during osteoblastogenesis. Mechanism of FIAT repression of ATF4 was investigated through structure-function and mutation analysis. The physiological significance of FIAT expression in osteoblasts was studied through silencing FIAT in osteoblasts by RNA interference, as well as through characterization of two genetic mouse models: FIAT transgenic mice which overexpress FIAT in osteoblasts, and osteoblast-specific FIAT knockout mice. These studies showed that FIAT and ATF4 are co-expressed in osteoblasts, and that FIAT inhibition of matrix mineralization requires dimerization with ATF4 through the second leucine zipper. Furthermore, transgenic mice overexpressing FIAT exhibited osteopenia whereas FIAT knockout mice showed enhanced bone formation. These results support our hypothesis and demonstrate that FIAT is a key transcriptional repressor that modulates osteoblast function.
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Factor inhibiting ATF4-mediated transcription is a novel leucine zipper transcriptional repressor that regulates bone massYu, Vionnie Wing Chi. January 2007 (has links)
No description available.
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Characterization of VP4, a minor core protein of African horse sickness virus with putative capping enzyme activityVan den Bout, Jan Iman 06 May 2005 (has links)
African horse sickness virus (AHSV) affects equine populations around the world. It is the cause of a high rate of morbidity and associated large economic losses in affected regions. The virus is a segmented double stranded RNA virus and a member of Orbivirus genus in the Reoviridae family. The prototype member of the orbiviruses is bluetongue virus (STY) and other members include Chuzan virus and St. Croix River virus. These viruses are all characterized by a genome of ten dsRNA segments that encode at least ten different proteins. Three of the minor core proteins are found within the core of BTV. These are all associated with the RNA transcription complex and the enzymatic activities with which they are associated include an RNA polymerase (VP1), an RNA capping enzyme (VP4) and an RNA helicase (VP6). Genes homologous to the BTV genes that encode these proteins are found in all members of the Orbivirus genus. The aim of this thesis is to characterize VP4 of AHSV, the capping enzyme candidate, and to compare it to other orbivirus capping enzymes. Possible functional motifs and regions of importance within the orbivirus capping enzymes will be identified. The gene will also be expressed and used to perform assays to characterize the different enzymatic activities of VP4. The VP4 cDNA of AHSV serotype 3 was cloned and sequenced. From the full-length verified nucleotide sequence an open reading frame was identified and used to predict the amino acid sequence. These were compared to other orbivirus species including STY, Chuzan virus and St. Croix River virus. These alignments identified a number of highly conserved regions, consisting of four or more amino acids conserved between all the sequences analyzed. A fibronectin type 3-like motif, containing 12 conserved amino acids, was identified which could be responsible for protein binding. This motif contains 12 conserved amino acids making it a good candidate for a functional motif. Conservation does not, however, always predict regions of importance. In BTV a lysine-containing motif was identified to be responsible for GMP binding. This region is not conserved between the different viruses. AHSV has a motif containing a lysine residue similar to the motif identified in rotavirus and reovirus. Two other motifs described in BTV were also not conserved in the other viruses. One of them, a leucine zipper, was shown to dimerize BTV VP4. Phylogenetically, AHSV and Chuzan virus are the most closely related while BTV is more distant and St. Croix River virus forms a distinct out-group when the different VP4 sequences are compared. AHSV-3 VP4 was expressed as a histidine-tagged protein in the baculovirus expression system. Not unexpectedly, the protein was found to be insoluble, similar to BTV VP4 produced by means of the same system. However, whereas BTV VP4 could be solubilized by the addition of salt the AHSV VP4 remained insoluble at high salt concentrations. Several adjustments were made. Cells were lysed in a high salt buffer, the pH of the buffers was adjusted and sucrose cushions were used but none of the methods was found to improve the yield of soluble VP4 significantly. However, the pellet containing VP4 was relatively empty of contaminating protein and, therefore, a number of enzymatic assays were performed with the pellet. Assays for inorganic phosphatase and nucleotide phosphatase were performed. Strikingly, both assays indicated the presence of active phosphatases in the WT and VP4 pellets. Also, an assay was performed for guanylyltransferase activity but no activity was observed for this assay. The sequence data therefore points to VP4 as the probable capping enzyme although it may have a different structural complex. The failure to produce a reliable source of soluble purified AHSV VP4 made it impossible to provide evidence to confirm the associated enzymatic activities. / Dissertation (MSc(Genetics))--University of Pretoria, 2005. / Genetics / unrestricted
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Expanding the Spiroligomers Toolbox as Protein-Protein Interaction InhibitorsAkula, Kavitha January 2017 (has links)
This work presents the application of spiroligomers as inhibitors of protein-protein interactions. After the discovery of an acyl-transfer coupling reaction by Dr. Zachary Brown, a previous graduate student of Schafmeister group, the synthesis of highly functionalized spiroligomers that mimic the helical domain of p53 was undertaken before each molecule was tested for binding to HDM2, a natural binding partner of p53. A library of molecules was synthesized on solid support that altered the stereochemistry along the spiroligomer as well as the presented functional groups. It was determined that spiroligomers enter human liver cancer cells through passive diffusion and induces a biological response in both a dose- and time-dependent manner. The synthesis of additional spiroligomer analogues achieved low micromolar to high nanomolar range activity during screening in direct and competitive binding assays. In parallel to the project above, a series of spiroligomers that mimic the side chains of the leucine zipper region of Max were synthesized in an effort to disrupt the interaction of the protein with c-Myc. The series of compounds contained various stereocenter combinations and different functional groups as before but were made in solution before testing for inhibition. Initial binding assays resulted in low micromolar activity, however, secondary assays (ELISA and cellular assays) did not confirm the inhibitory effect of spiroligomers on the c-Myc/Max heterodimer. In summary, this work illustrates that spiroligomers are capable mimics of helical peptides and can induce a biological response. / Chemistry
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Myc and Mad target genes /James, Leonard Philip, January 2000 (has links)
Thesis (Ph. D.)--University of Washington, 2000. / Vita. Includes bibliographical references (leaves 137-154).
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