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STRUCTURAL AND FUNCTIONAL STUDIES OF F-BOX-ONLY PROTEIN FBXO7 AND ITS INTERACTIONS WITH PROTEASOME INHIBITOR PI31Shang, Jinsai 01 August 2015 (has links)
F-box only protein 7 (Fbxo7), a member of the F-box-only subfamily of FBPs, is a biologically and pathophysiologically important human protein that assumes many critical functions. The different functions of Fbxo7 depend on the formation of various multi-protein complexes. Possible interplay between different Fbxo7 functions further complicate the protein-protein interaction networks involved in Fbxo7 biology. Although significant progresses have been made to understand the functions, regulation, specificity, and protein interaction network of Fbxo7, a myriad of questions remain to be answered. The objectives of the work presented in this dissertation are to elucidate the molecular structures underlying the functions of Fbxo7 and the interaction with its protein partners, such as proteasome inhibitor PI31. The best known biological function of Fbxo7 is its role as the substrate-recognition subunit of the SCFFbxo7 (Skp1-Cul1-F-box protein) E3 ubiquitin ligase that catalyzes the ubiquitination of hepatoma up-regulated protein (HURP) and inhibitor of apoptosis protein (IAP). Fbxo7 also assumes various SCF-independent functions through interact with its protein partners that are not the substrates of the ubiquitin proteasome system, such as PI31, Cdk6, p27, PINK1 (PTEN-induced kinase 1), and Parkin. PI31 is a known proteasome regulator which was initially characterized as a proteasome inhibitor in vitro. The binding affinity between Fbxo7 and PI31 is very strong, and The Fbxo7-PI31 interaction is mediated by heterodimerization of the FP domains of the two proteins. This work is focus on study the protein structure of the two FP domains in Fbxo7 and PI3. Chapter 1 reviewed the F-box-only protein Fbxo7 biology including the function of Fbxo7 protein in ubiquitination proteasome pathway and some SCF-independent functions which are relate to human disease. Chapter 2 discussed the function of proteasome inhibitor PI31. With the many important biological functions, Fbxo7 is clearly an extraordinary important protein, but the lack of structural knowledge has hampered efforts to achieve a better understanding of Fbxo7 biology. In this work, we have determined the crystal structure of Fbxo7 FP domain (residues 181-335) and the crystal structure of the PI31 FP domain (residues 1-161) using a longer protein construct both at 2.0Å resolution. The Fbxo7 FP domain adopts an α/β-fold similar to that of the PI31 FP domain and the secondary structure elements of the two FP domains are comparable including the C-terminal helix, indicating that the two FP domains share the same overall global fold. However, an α helix and three β strands in the Fbxo7 are longer than their counterparts in the PI31 FP domain. The two FP domains also differ substantially in the length and conformation of the longest connecting loop. More importantly, structural differences between the two FP domains lead to drastically different modes of inter-domain protein–protein interaction: the PI31 FP domain utilizes either an α interface or β interface for homodimeric interaction, whereas the Fbxo7 FP domain utilizes an αβ interface. We have note that the inter-domain interaction of the Fbxo7 FP domain is much more extensive, featuring a larger contact surface area, better shape complementarity and more hydrophobic and hydrogen-bonding interactions. The results of this structural study provide critical insights into how Fbxo7 may dimerize (or multimerize) and interact with PI31 via the FP domain. Chapter 4 and Chapter 5 discussed the structure determinations, structure features and detail of protein-protein interactions of Fbxo7 and PI31 FP domains. Chapter 2 reviewed the corresponding fundamental biochemical techniques that been used in this study. Chapter 3 discussed protein structure determination by X-ray crystallography in structural biology studies. It was believed that the FP domains of Fbxo7 and PI31 mediate homodimerization and heterodimerization of the proteins and the FP domain is not present in other human proteins. In order to study the Fbxo7-PI31 heterodimerization protein-protein interactions, we performed modeling studies. Chapter 6 discussed the model building and binding studies. Based on the result of model building studies, we propose that an interaction between the two FP domains of Fbxo7 and PI31 should be mediated by a αβ interface using the α-helical surface of the Fbxo7 FP domain and the β-sheet surface of the PI31 FP domain. According to the result of pull down assay, the PI31 FP domain may complete with Skp1 for the binding with Fbxo7. It is possible that the formation of heterodimer between the Fbxo7 and PI31 mediate by FP domains may lead to the Fbxo7 dissociation from SCFFbxo7 complex which might reveal a new regulation mechanism.
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Charakterisierung von humanem PI31 und neuen alternativen Spleißvarianten des PI31 Gens PSMF1Schwarz, Tobias 01 April 2009 (has links)
Das Ubiquitin-Proteasom-System eukaryotischer Zellen spielt eine zentrale Rolle beim Abbau von fehlgefalteten und nicht mehr benötigten Proteinen. Damit erfüllt es regulatorische Funktionen bei zellulären Prozessen wie z.B. dem Zellzyklus und der Transkription. Das Protein Proteasominhibitor 31 (PI31) wurde als Inhibitor des Proteasoms in vitro charakterisiert. Des weiteren wurde gezeigt, daß überexprimiertes PI31 im murinen System ein Modulator der Assemblierung des Immunoproteasoms (i20S) ist. Über die Funktion und Regulation von PI31 im humanen System war bisher nichts bekannt und wurde deshalb in dieser Arbeit untersucht. Es konnte gezeigt werden, daß neben dem PI31-Transkript mindestens neun weitere alternative Spleißvarianten des humanen PI31 Gens PSMF1 existieren. Die PI31-Isoformen V2 bis V10 unterscheiden sich von PI31 (V1) teils durch eine fehlende N-terminale Domäne oder einen veränderten C-Terminus. Die Isoform V5 wird als einzige gewebespezifisch in Testikeln exprimiert und ist im Zellkern lokalisiert. Ausschließlich die Überexpression der Isoform V3 führt zur Inhibition der proteasomalen Aktivität in vivo. Ein modulatorischer Einfluß von PI31 oder einer der Isoformen auf die Assemblierung des humanen i20S bestätigte sich dagegen nicht. Die Überexpression von PI31 und V3 in humanen Zellen führte indes zu einer Akkumulation und verzögerten Degradation von proteasomalen Substraten. Es wurde außerdem gezeigt, daß die Expression von humanem PI31 durch virusassoziierte Stimuli wie dsRNA und Typ I-Interferone induziert werden kann. Für die 3kb lange 3’UTR der PI31-mRNA konnte zusätzlich nachgewiesen werden, daß sie inhibitorisch auf die Expression wirkt und somit eine regulatorische Funktion besitzt. In Zusammenhang mit der von Kirk et al. (2008) gezeigten Heterodimerisierung von PI31 mit dem F-Box Protein Fbxo7, weisen die hier vorgestellten Ergebnisse auf eine Funktion von PI31 und dessen Isoformen bei der Ubiquitinierung von proteasomalen Substraten hin. / The ubiquitin–proteasome pathway is the major intracellular system for protein degradation. It plays an important role in the regulation of cellular processes like cell cycle control, signal transduction and gene transcription. The protein proteasome inhibitor 31 (PI31) was initially characterized as a potent inhibitor of proteasomal activity in vitro. Furthermore it was shown that PI31 modulates the assembly of the murine immunoproteasome (i20S). The function and regulation of PI31 in the human system is so far unexplored and therefore the topic of this study. It was shown that at least nine alternatively spliced variants of the PI31 gene PSMF1 exist additionally to the PI31 transcript. The PI31 isoforms V2 to V10 differ from PI31 (V1) in parts of the N-terminus and in a modified C-terminus. Only the isoform V5 is tissue specific expressed in testis and localized in the nucleus. After overexpression only the isoform V3 has the ability to inhibit the proteasomal activity in vivo. In contrast to the murine system neither PI31 nor the isoforms showed a modulatory effect on the assembly of the i20S. The overexpression of PI31 and V3 in human cells results instead in the accumulation and delayed degradation of proteasomal substrates. Furthermore the expression of human PI31 can be induced by virus associated stimuli like dsRNA and type I interferones. In addition, for the 3kb long 3’UTR of the PI31-mRNA an inhibitory effect on the expression and therefore a regulatory role was shown. Together with data from Kirk et al. (2008), who show the heterodimerization of PI31 with the F-box protein Fbxo7, the presented results suggest a function of PI31 and its isoforms in the process of ubiquitination of proteasomal substrates.
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