Global ETD Search

11	Molecular functions of the ubiquitin domain protein Herp in Synoviolin mediated endoplasmic reticulum associated protein degradation (ERAD) Kny, Melanie 10 September 2010 (has links) Die Akkumulation fehlerhafter Proteine im Endoplasmatischen Retikulum (ER) induziert den „unfolded protein response“ (UPR) - Signalweg zur Überwindung dieser zellulären Stress-Situation. Ein in Säugern stark UPR-induziertes Gen kodiert für das Ubiquitin-Domäne-Protein Herp. Herp interagiert mit der E3-Ligase Synoviolin, einer zentralen Komponente von Multiproteinkomplexen, welche die ER assoziierte Protein-Degradation (ERAD) vermitteln. Abhängig von seiner Ubiquitin-ähnlichen (‘UBL’) Domäne wird Herp für den effizienten Abbau von Synoviolin-Substraten benötigt. Der zugrundeliegende molekulare Mechanismus dieser Funktion von Herp ist kaum bekannt. In der vorliegenden Studie wurde gezeigt, dass Herp kontinuierlich an Synoviolin-basierten Komplexen umgesetzt wird, aber kein Substrat ist. Da sowohl Depletion als auch Stabilisierung von Herp zum verminderten Abbau von Synoviolin-Substraten führt, lässt sich schlussfolgern, dass der kontinuierliche Umsatz von Herp entscheidend ist für ERAD. Weiterhin regulierte Herp die Zusammensetzung Synoviolin-basierter Komplexe. Das deubiquitinierende Enzym Usp7 ist über seine Bindung an Herp mit Synoviolin assoziiert. Usp7 beeinflusste aber nicht die Stabilität von Herp oder ERAD-Substraten. Zusätzlich verstärkte Herp die Interaktion zwischen dem CUE-Domäne-Protein AUP1 und Synoviolin. In Abhängigkeit von der CUE-Domäne steigerte AUP1 den ERAD-Prozess. Auch das Herp-Homolog Herp2 war mit Synoviolin-basierten Komplexen assoziiert. Im Gegensatz zu Herp wurde Herp2 nicht durch den UPR-Signalweg induziert, war stabil und interagierte nicht Usp7. Diese Daten unterstreichen die einzigartige Funktion von Herp im ERAD-Prozess. Schlussfolgernd ist Herp eine dynamische ERAD-Komponente, welche die Rekrutierung akzessorischer Proteine an Synoviolin vermittelt und damit die Ubiquitinierung von Synoviolin-Substraten ermöglicht. Diese Daten zeigen die kritische Rolle von Herp für die Beseitigung fehlerhafter Proteine und das Überleben der Zelle. / The accumulation of aberrant proteins in the endoplasmic reticulum (ER) induces the unfolded protein response (UPR) pathway for surmounting this cellular stress situation. One of the strongly UPR-induced genes in mammalia encodes the ubiquitin domain protein Herp. Herp interacts with the E3 ligase Synoviolin, a central component of ER associated protein degradation (ERAD) mediating multiprotein complexes. Dependent on its ubiquitin-like (UBL) domain, Herp is required for the efficient degradation of Synoviolin substrates. The molecular mechanism underlying this function of Herp is poorly understood. In the present study, it was shown that Herp is continuously exchanged at Synoviolin based complexes. However, Herp did not serve as a Synoviolin substrate. Since both stabilisation and depletion of Herp resulted in the impaired degradation of Synoviolin substrates, the continuous turnover of Herp seems to be decisive for ERAD. Herp was also shown to regulate the composition of Synoviolin based complexes. The deubiquitinating enzyme Usp7 was linked to Synoviolin via its interaction with Herp. However, Usp7 did not influence the stability of Herp or ERAD substrates. In addition, Herp improved the association of the CUE domain protein AUP1 with Synoviolin. AUP1 triggered the ERAD process in a CUE domain dependent manner. Also Herp2, a homologue of Herp, was found to associate with Synoviolin based complexes. However, in contrast to Herp, Herp2 was not induced by the UPR, was stable, and did not bind Usp7 supporting the idea of Herp having a unique function in ERAD. In conclusion, Herp is a dynamic ERAD component recruiting accessory proteins to Synoviolin thus enabling Synoviolin dependent ubiquitination of substrates. These findings point out the crucial role of Herp for the elimination of misfolded proteins, which is important for cell survival. UPR ERAD Herp Synoviolin Usp7 AUP1 Herp2 UPR ERAD Herp Synoviolin Usp7 AUP1 Herp2 570 Biowissenschaften, Biologie 32 Biologie WE 3150 ddc:570
12	Regulation des Ubiquitin-Proteasom-Systems in Säugetierzellen durch den Transkriptionsfaktor TCF11 Steffen, Janos 09 September 2010 (has links) Das Ubiquitin-Proteasom-System (UPS) ist das wichtigste System für den Abbau von nicht mehr benötigten oder beschädigten Proteinen innerhalb der eukaryotischen Zelle und ist somit an der Aufrechterhaltung der zellulären Homöostase beteiligt. Ein Abfall der proteasomalen Aktivität führt zu intrazellulärem Stress. Die Zelle wirkt diesem Abfall entgegen, indem sie die proteasomalen Gene verstärkt exprimiert und dadurch die Neubildung von 26S Proteasomen bewirkt. Während in der Bäckerhefe Saccharomyces cerevisiae mit Rpn4 der Transkriptionsfaktor für die verstärkte Expression identifiziert wurde, war dieser in Säugetieren noch nicht bekannt. In der vorliegenden Arbeit konnte TCF11 (transcription factor 11) als der verantwortliche Transkriptionsfaktor identifiziert werden, der in der humanen Endothelzelllinie Ea.hy926 die Transkription der proteasomalen Gene nach Proteasominhibition induziert. Unter physiologischen Bedingungen ist TCF11 ein N-glykosyliertes ER-ständiges Membranprotein, welches durch die ER-assoziierte Protein Degradation, unter der Mitwirkung des E3-Enzyms HRD1 und der AAA-ATPase p97, schnell abgebaut wird. Nach der Proteasominhibition kommt es zur Akkumulation von oxidierten Proteinen, und TCF11 wird aktiviert und in den Zellkern transportiert. Im Zellkern bindet TCF11 an AREs (antioxidant response element) in den proteasomalen Promotoren und aktiviert dadurch die Transkription der proteasomalen Gene. Darüber hinaus reguliert TCF11 auch die Expression von zahlreichen Enzymen, die die Ubiquitinierung von Proteinen katalysieren. Dadurch wird die zelluläre Homöostase wiederhergestellt und TCF11 sehr wahrscheinlich durch die neu gebildeten Proteasomen abgebaut. Die Ergebnisse der vorliegenden Arbeit zeigen auf, dass die Integrität des UPS nach Proteasominhibition in der humanen Endolthelzelllinie Ea.hy926 über einen TCF11 abhängigen Rückkopplungsmechanismus aufrechterhalten wird. / The ubiquitin-proteasome-system (UPS) is the most important system for regulated protein degradation in eukaryotes. Therefore it is involved in the regulation of cellular homeostasis. Reduced proteasome activity results in proteotoxic stress. To counteract for reduced proteasome activity, eukaryotic cells enhance proteasome gene expression, which results in formation of new 26S proteasomes and recovery of physiological conditions. While in bakers yeast Saccharomyces cerevisiae the transcription factor Rpn4 is responsible for enhanced proteasome gene expression in response to proteasome inhibition, in mammals the responsible transcription factor was unknown. In this thesis, transcription factor TCF11 (transcription factor 11) was identified as a key regulator for 26S-proteasome formation in the human cell line Ea.hy926 to compensate for reduced proteolytic activity. Under non-inducing conditions N-glycosylated TCF11 resides in the endoplasmic reticulum (ER) membrane, where TCF11 is targeted to ER-associated protein degradation system requiring the E3-ubiquitin ligase HRD1 and the AAA-ATPase p97. Proteasome inhibitors trigger the accumulation of oxidant-damaged proteins, and promote the nuclear translocation of TCF11 from the ER, permitting activation of proteasome gene expression by binding of TCF11 to antioxidant response elements (ARE) in their promoter regions. Furthermore TCF11 controlls the expression of additional UPS-related genes. Thus the transcriptional feedback loop regulating human proteasome dependent protein degradation to counteract proteotoxic stress caused by proteasome inhibition was uncovered. Genexpression ERAD Ubiquitin-Proteasom-System Proteasominhibition TCF11 ERAD ubiquitin-proteasome-system proteasome inhibition TCF11 genexpression 570 Biowissenschaften, Biologie 32 Biologie YC 7500 WD 5100 ddc:570
13	Functional organisation of the Hrd1 ubiquitin ligase complex and its role in ERAD Schulz, Jasmin January 2013 (has links) Endoplasmic reticulum (ER)-associated degradation (ERAD) of misfolded proteins of the secretory pathway is crucial for ER homeostasis and the physiological importance of this mechanism is reflected by more than 60 diseases that have been linked to ERAD to date. The best characterised mammalian ERAD complex is centred on the ubiquitin ligase Hrd1, and for a complete understanding of the dynamics of the ERAD network it is important to thoroughly characterise the interactions within the Hrd1 complex and to decipher the functions of the individual accessory factors. SEL1L is a well characterised interaction partner of Hrd1 and here we identify a highly hydrophobic region in the lumenal part of SEL1L as necessary, but not sufficient, to interact with Hrd1; as a consequence, the topology of SEL1L may need to be re-evaluated. Furthermore, we investigate the roles of the novel Hrd1 interaction partners AUP1 and FAM8A1 in ERAD. We establish here that AUP1 adds to the complexity of the ERAD network by making the cognate E2 of gp78, Ube2g2, accessible to Hrd1 and by regulating the access of polyubiquitinated proteins to the Hrd1 complex. Moreover, we demonstrate that Hrd1 is the regulator of FAM8A1 half-life and that the interaction between these two proteins is necessary for degradation of the lumenal ERAD model substrate TTR<sub>D18G</sub>. 571.6
14	Caractérisation du domaine cytoplasmique du récepteur du facteur autocrine de motilité et formation du complexe AMFR/p97/ubiquitine Dang, Thao January 2006 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. AMFR Enzyme ligase (E3) p97 Ubiquitination Motif RING Domaine CUE ERAD
15	Examining the Role of Herp in the ER Stress Response of Pancreatic Beta Cells Siva, Madura 11 January 2011 (has links) The unfolded protein response, which is activated during ER stress, counteracts stress conditions by increasing folding capacity and by increasing the degradation of misfolded ER proteins by the ER-Associated Degradation (ERAD) system. Studies using an engineered insulinoma cell line with inducible expression of the Akita folding-deficient insulin have shown a large induction of Herp, a protein that has been implicated in the ERAD pathway. We hypothesized that Herp is an essential protein that regulates the degradation of misfolded insulin during the ER stress response. Indeed, we found that the degradation of mutant insulin is Herp-dependent and that maintaining Herp expression is vital for maintaining cell survival. We have also observed that the expression of Herp mRNA and protein is induced in various cell culture and animal models of diabetes. These results suggest that Herp is an important ER stress response protein that is induced under diabetic conditions in pancreatic β-cells. Herp ER stress beta cell ERAD Type 2 Diabetes 0719 0379 0487
16	Examining the Role of Herp in the ER Stress Response of Pancreatic Beta Cells Siva, Madura 11 January 2011 (has links) The unfolded protein response, which is activated during ER stress, counteracts stress conditions by increasing folding capacity and by increasing the degradation of misfolded ER proteins by the ER-Associated Degradation (ERAD) system. Studies using an engineered insulinoma cell line with inducible expression of the Akita folding-deficient insulin have shown a large induction of Herp, a protein that has been implicated in the ERAD pathway. We hypothesized that Herp is an essential protein that regulates the degradation of misfolded insulin during the ER stress response. Indeed, we found that the degradation of mutant insulin is Herp-dependent and that maintaining Herp expression is vital for maintaining cell survival. We have also observed that the expression of Herp mRNA and protein is induced in various cell culture and animal models of diabetes. These results suggest that Herp is an important ER stress response protein that is induced under diabetic conditions in pancreatic β-cells. Herp ER stress beta cell ERAD Type 2 Diabetes 0719 0379 0487
17	Function and trafficking of the MMTV-encoded Rem gene product Byun, Hyewon 02 July 2013 (has links) Mouse mammary tumor virus (MMTV), a member of the betaretrovirus family, primarily induces mammary carcinomas in mice. Like human immunodeficiency virus (HIV), MMTV is a complex retrovirus that encodes a viral regulatory protein, Rem. Rem is a 33 kDa glycosylated protein containing an unusually long ER signal peptide (SP). MMTV SP contains all of the functional motifs for the nuclear export of MMTV unspliced/genomic RNA. SP activity requires binding to MMTV RNA. To characterize the minimal Rem-responsive element (RmRE) that overlaps the 3’ LTR, several deletion mutations were introduced in the MMTV-based reporter plasmid, pHMRluc. Results from these mutants in transient transfections revealed a 476-nt RmRE at the junction of the envelope gene and the 3’ LTR. RmRE function was not cell-type specific. The RmRE is predicted to have a complex secondary structure, similar to the Rev-responsive element (RRE) of HIV. Unlike the HIV RRE, the 3’ LTR RmRE occurs in all MMTV mRNAs, and Rem does not increase the export of unspliced RNA of the pHMRluc reporter vector. These results suggest that another RmRE near the 5’-end participates in export of MMTV genomic RNA, whereas the RmRE overlapping the 3’ LTR supports different Rem functions, such as translational regulation. Recent research has shown that SP directs Rem translation to the ER where Rem is cleaved and released into the cytoplasm. Rem mutants with ER signal peptidase cleavage site mutations completely lost function, and mutant proteins were highly unstable and mislocalized. Dominant-negative AAA ATPase p97 and Derlin-1 proteins, which are involved in the ER-associated degradation (ERAD) pathway, inhibited Rem function. Therefore, Rem is a precursor protein that is processed by ER signal peptidases. Rem then manipulates the ERAD system to retrotranslocate SP to the cytoplasm prior to nuclear entry and MMTV RNA binding. Unexpectedly, a commercial control shRNA expression vector, LK0.1, induced additional Rem, HIV-1 Rev and human T-cell leukemia virus type 1 Rex activity (called super-induction). Also, the LK0.1 vector increased protein expression levels of co-transfected genes, and the target of the shRNA was not critical. When the hairpin segment was deleted from LK0.1, the super-induction of Rem activity was greatly reduced. Deletion of cis-acting lentiviral segments also decreased protein expression levels. Although LK0.1 did not affect the levels of interferon-induced genes or eIF-2α phosphorylation, LK0.1 reduced the number of stress granules significantly. Therefore, LK0.1 may induce several cellular signaling pathways, leading to Rem super-induction. This study characterizes the minimal RmRE overlapping the 3’ MMTV LTR and reveals the unique processing of Rem and SP trafficking prior to nucleolar localization. Additional functions of MMTV Rem and other retroviruses may be discovered using studies of cellular events induced by LK0.1. / text MMTV Rem Rem response element Signal peptide (SP) ERAD Retrotranslocation LK0.1
18	The quality control of transmembrane domains along the secretory pathway Briant, Kit January 2015 (has links) Protein quality control is crucial to maintaining cellular function. A failure to clear misfolded, aggregation prone proteins can lead to the accumulation of toxic protein aggregates that interfere with cellular pathways and lead to cell death. In addition, the degradation of partially functional proteins can lead to loss of function diseases. Understanding proteins quality control mechanisms is therefore of fundamental importance to understanding these disease pathways. Systems that operate to monitor the structure of soluble protein domains are now relatively well understood. However, in addition to soluble domains, membrane proteins contain regions that span lipid bilayers, and a key question that remains is where and how these transmembrane domains (TMDs) that fail to assemble correctly or are otherwise aberrant are recognised within subcellular compartments. As such, in this study model chimeric proteins containing the luminal and cytoplasmic domain of the single-spanning membrane protein CD8 and exogenous TMDs derived from polytopic membrane proteins were used to investigate the handling of non-native TMDs in the secretory pathway. CD8 chimeras containing non-native TMDs were found to be recognised by endoplasmic reticulum (ER) quality control pathways. Importantly, ER-associated degradation of CD8 chimeras containing exogenous TMDs was reliant upon ubiquitination of cytoplasmic lysine residues prior to retrotranslocation and dislocation from the ER membrane. In contrast, CD8 containing the endogenous TMD but a misfolded luminal domain could be efficiently degraded when cytoplasmic lysines were removed, suggesting that the retrotranslocation mechanisms for these proteins are distinct and defined by the domain which is misfolded. A proportion of the CD8 chimeras containing non-native TMDs were able to exit the ER, and were retrieved to the ER from the Golgi. Golgi-to-ER retrieval was found to be at least partially mediated by Rer1. CD8 chimeras that escaped ER retrieval could also be retained in the Golgi and subsequently degraded in lysosomes, indicating the presence of an as yet undefined TMD-based Golgi quality control checkpoint in mammalian cells. Furthermore, in contrast to WT CD8 which was stable at the plasma membrane, CD8 chimeras containing non-native TMDs that trafficked to the cell surface were rapidly internalised and sorted to lysosomes. This process was largely independent of the cytoplasmic domain of CD8, suggesting signals within the TMD induced internalisation of these CD8 chimeras. The proportion of the CD8 chimeras that trafficked to the plasma membrane, and the stability of the protein at the cell surface, was dependent upon the presence of polar residues within the TMDs, indicating that exposed polar residues in non-native TMDs may alter the handling of proteins at the Golgi and cell surface. Together, these results further our understanding of the mechanisms by which proteins containing aberrant transmembrane domains are handled at multiple subcellular compartments. 572
19	Experiments on fatty acids chain elongation and glycan flipping in the ER membrane Pujol, F. (François) 17 March 2009 (has links) Abstract Very long chain fatty acids (VLCFA) are essential molecules that take part in many different cellular processes such as membrane pore stabilization, membrane trafficking and signaling pathways. The fatty acid elongation pathway in yeast has been studied for about a decade. As part of our work on cellular VLCFA elongation, we identified and characterized the condensing enzyme as well as ketoacyl reductases of the elongation pathway in cotton. In order to identify the yeast 3-hydroxyacyl-CoA dehydratase, we introduced a redundancy in this function by engineering a chimera consisting of the two first predicted transmembrane domains of Elo3p and the hydratase2 domain of Candida tropicalis Mfe2p. Yeast harboring the chimeric construct were subjected to random mutagenesis, and screened for mutants whose survival was dependent on the chimera. The mutants isolated contained RFT1 mutations and exhibited a defect in protein glycosylation, but no VLCFA deficiencies. The N-linked glycosylation pathway is well conserved in eukaryotes. Glycan synthesis occurs on the ER membrane; first on the cytoplasmic side up to Dol-PP-GlcNAc2Man5, which is then translocated to the ER luminal side in an Rft1p-dependent flipping process. The core glycan is further extended to Dol-PP-GlcNAc2Glc3Man9, and then transferred to an asparagine side chain of the nascent polypeptide to be glycosylated. It was found that the Elo3'-hydratase2 chimera acts as a multicopy suppressor of the Rft1p deficiency. The subsequent studies elucidated new aspects of Rft1p function, as well as a hitherto under-appreciated role of the ER associated protein degradation process in the maintenance of ER integral membrane complexes and the physical integrity of the membrane. The functionality of the human Rft1p homologue was demonstrated using a yeast complementation assay. A mutant variant from a patient was analyzed, aiding in the identification and characterization of the first reported case of a glycosylation deficiency in humans caused by a defective RFT1 allele. ER ERAD N-linked glycosylation RFT1 Very long chain fatty acid condensation flipping
20	Reconstitution of retrotranslocation by the Hrd1 ubiquitin ligase with purified components Vasic, Vedran 27 June 2019 (has links) No description available. 572 Protein quality control Endoplasmic reticulum Ubiquitination Protein translocation ERAD Membrane proteins Protein folding Biologie (PPN619462639)

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