Global ETD Search

1	The generation of the amyloid precursor protein intracellular domain Duggan, Claire January 2005 (has links) Alzheimer's disease (AD) is the most common cause of a progressive decline of cognitive function in aged humans. It is thought to be a result of the formation of amyloid plaques in the brain that are largely composed of β-amyloid (Aβ), which is one of the cleavage products of the amyloid precursor protein (APP). The amyloidogenic processing of APP to produce the Aβ peptides requires sequential proteolytic cleavages by the β- and γ-secretases. APP is first cleaved by the β-secretase to produce APP-C99, and this product is a substrate for further processing by the γ-secretase that cleaves within its transmembrane domain to produce N-terminal Aβ peptides and the C-terminal APP intracellular domain (AICD). On the basis of similarities to the Notch processing pathway, it has been postulated that the AICD may play a role in gene regulation following its release in response to some form of extracellular signal. In order to better understand the production and fate of the AICD, I have investigated the potential for exploiting a cell-free system to study its generation and properties. Having generated a number of model APP-derived fragments and shown them to be efficiently membrane integrated in vitro, I went on to study AICD production. I discovered that AICD-like fragments are extremely labile when synthesised in a rabbit reticulocyte lysate system and are rapidly degraded via a metalloproteinase, most likely the insulin degrading enzyme (IDE). The in vitro stability of these model AICD-like fragments was dependent upon the precise chain length of the polypeptide and N-terminal processing may preface the activity of IDE in vitro. The rapid degradation of the AICD in vitro is in close agreement with previous in vivo studies, and taken together such data are consistent with a role for the AICD in a signalling pathway of some form. A variety of approaches were also taken to try to generate the AICD by the γ-secretase mediated cleavage of the APP-C99 fragment, a biologically relevant substrate. In no case was any evidence of such cleavage observed in vitro and hence I conclude that the endoplasmic reticulum does not possess an active form of the γ-secretase. Preliminary in vivo-based studies did provide evidence for the γ-secretase cleavage of APP-C99 fragments, consistent with current models implying that such processing takes place at the cell surface and/or in endosomes and not at the endoplasmic reticulum. 616.8
2	Regulation and proteolytic activity of ADAM12 metalloprotease Solomon, Emilia A. January 1900 (has links) Doctor of Philosophy / Department of Biochemistry / Anna Zolkiewska / ADAMs (a disintegrin and metalloprotease) can influence multiple cellular processes involved in normal development and pathogenesis. ADAM12 expression levels are elevated in many pathological conditions including cancer, cardiovascular disease, and muscle regeneration. Recently, ADAM12 has emerged as a candidate cancer gene in a comprehensive genetic analysis of human breast cancers. The regulation of ADAM12 expression is poorly understood. Identification of new substrates for ADAM12 metalloprotease can expand our knowledge of processes in which ADAM12 is involved. Here, we show that ADAM12 expression is upregulated by transforming growth factor beta (TGF-beta), an essential signaling pathway for many cellular processes. This upregulation requires proteosomal degradation of a transcriptional repressor SnoN. Furthermore, breast cancer cell lines expressing high levels of SnoN have significantly impaired induction of ADAM12 by TGF-beta, suggesting an inverse correlation between SnoN and the extent of regulation of ADAM12 by TGF-beta. Additionally, we demonstrate that ADAM12 is one of the metalloproteases involved in shedding a Notch ligand, Delta like 1 (Dll1). The Notch signaling pathway plays a crucial role in cell fate decision during development and in adults. Cleavage of Dll1 by ADAMs occurs in cis and results in activation of Notch signaling in a cell-autonomous manner. Furthermore, the intracellular domain of Dll1 created after cleavage further enhances TGF-beta signaling in response to TGF-beta. Our analysis of breast cancer-associated mutations in the ADAM12 gene showed a lack of proper proteolytic processing of the ADAM12 protein and its mislocalization to the endoplasmic reticulum. Additionally, ADAM12 mutants show a dominant-negative effect on the processing of the wild-type ADAM12 and result in loss of the functional ADAM12 at the cell surface. Collectively, our results indicate a new mechanism of regulation of ADAM12 expression, expand the role of ADAM12 in the regulation of Notch signaling, and characterize cancer-associated mutations in the ADAM12 gene. ADAM12 TGF-beta Notch proteolytic processing Biology, Cell (0379) Biology, Molecular (0307)
3	Characterization of the Novel Cysteine-rich Extracellular Calmodulin-binding Protein cyrA from Dictyostelium discoideum Suarez, Andres 15 February 2010 (has links) A novel calmodulin (CaM)-binding cysteine-rich protein from Dictyostelium, cyrA, with epidermal growth factor-like (EGFL) repeats was discovered and characterized. Calcium-dependent and –independent CaM-binding was verified. Western blots show that full length cyrA is detected constitutively throughout development. Analyses of the extracellular medium reveal that cyrA is cleaved and that the fragments containing the N-terminus are secreted early in development, while those containing the C-terminus are secreted later. In support of this, GFP and immunohistochemistry studies reveal that cyrA localizes to the endoplasmic reticulum and secretory vesicles of vegetative cells, and to the extracellular matrix (slime sheath) of migrating slugs. The addition of EGFL1 peptides enhanced cell motility and cAMP-mediated chemotaxis. Finally, cyrA cleavage is regulated by extracellular Dictyostelium CaM and by the extracellular EGFL repeats. In total the data suggest that cyrA is a true matricellular protein that mediates cell motility during multicellular development. calmodulin-binding protein Dictyostelium extracellular matricellular epidermal growth factor-like cysteine rich proteolytic processing secreted calmodulin cyrA 0379
4	Characterization of the Novel Cysteine-rich Extracellular Calmodulin-binding Protein cyrA from Dictyostelium discoideum Suarez, Andres 15 February 2010 (has links) A novel calmodulin (CaM)-binding cysteine-rich protein from Dictyostelium, cyrA, with epidermal growth factor-like (EGFL) repeats was discovered and characterized. Calcium-dependent and –independent CaM-binding was verified. Western blots show that full length cyrA is detected constitutively throughout development. Analyses of the extracellular medium reveal that cyrA is cleaved and that the fragments containing the N-terminus are secreted early in development, while those containing the C-terminus are secreted later. In support of this, GFP and immunohistochemistry studies reveal that cyrA localizes to the endoplasmic reticulum and secretory vesicles of vegetative cells, and to the extracellular matrix (slime sheath) of migrating slugs. The addition of EGFL1 peptides enhanced cell motility and cAMP-mediated chemotaxis. Finally, cyrA cleavage is regulated by extracellular Dictyostelium CaM and by the extracellular EGFL repeats. In total the data suggest that cyrA is a true matricellular protein that mediates cell motility during multicellular development. calmodulin-binding protein Dictyostelium extracellular matricellular epidermal growth factor-like cysteine rich proteolytic processing secreted calmodulin cyrA 0379
5	Molekulare Charakterisierung des Amyloidvorläuferproteins des Meerschweinchens Beck, Mike 28 November 2004 (has links) (PDF) Die Bildung von Amyloidablagerungen ist ein Kennzeichen der Alzheimerschen Erkrankung. Hauptbestandteil dieser senilen Plaques sind sogenannte A beta Peptide, die durch proteolytische Prozessierung aus einem Vorläufermolekül (APP) gebildet werden. Die vorliegende Arbeit beschreibt die Klonierung des Meerschweinchen - APP. Diese cDNA-Sequenz zeigt auf DNA-Ebene eine Homologie zum Human-APP von ca. 90%, auf Proteinebene beträgt die Identität ca. 97 %. Damit wird ein weiterer experimenteller Beweis für die evolutionäre Konservierung des Amyloidvorläuferproteins in Säugetieren erbracht. APP mRNA wird in Meerschweinchen-Geweben ubiquitär exprimiert. Durch alternatives Spleißen wird ein zum Human-APP im wesentlichen ähnliches Isoformenmuster gebildet: Isoformen, welche eine Proteaseinhibitordomäne enthalten, werden dominierend in peripheren Organen exprimiert, dagegen ist im Zentralnervensystem das APP 695 mit über 60 % der Gesamttranskripte die bevorzugt exprimierte Isoform. Die klonierte cDNA des Meerschweinchen-APP wurde in prokaryontischen wie auch eukaryontischen Zellsystemen exprimiert. Dabei wurde die Eignung einer Anzahl von gegen Human-APP gewonnenen Antikörpern zur Detektion des Meerschweinchen-APP und seiner Prozessierungsprodukte gezeigt. Die Expression der neuronal dominierend exprimierten Isoform APP 695 des Meerschweinchen-APP in humanen Neuroblastom-Zellen zeigte keine Unterschiede hinsichtlich der APP-Prozessierung und A beta-Bildung im direkten Vergleich zu Human-APP 695. Die proteolytische Prozessierung des Proteins wurde durch Detektion der typischen Spaltprodukte in vivo (im Liquor) als auch in einem neu etablierten in vitro-Modell primär kultivierter neuronaler Zellen untersucht. Diese Zellkulturen wurden zunächst immunhistochemisch und biochemisch charakterisiert und als "mixed brain"-Typ mit einem hohen neuronalen Anteil beschrieben. Die Prozessierung des endogenen Meerschweinchen-APP in kultivierten Zellen führt dabei zur Bildung und Akkumulation aggregationsfähiger A beta - Peptide. Zur Detektion dieser Peptide wurde ein sensitiver Nachweis durch Western-Blot etabliert. Es wird damit ein Modellsystem für in vitro-Untersuchungen vorgeschlagen, welches ein Studium der Expression und Prozessierung des Amyloidvorläuferproteins unter angenähert physiologischen Bedingungen ermöglicht. / A beta peptides, the major component of neuritic plaques found in the brains of patients with Alzheimers disease, are derived by proteolytic processing from a larger precursor molecule (amyloid precursor protein - APP). A combination of PCR methods was used to clone and sequence APP cDNA from guinea pig (Cavia porcellus). Guinea pig APP exhibits extensive similarities to human APP in terms of primary structure, mRNA expression of differentially spliced isoforms as shown by Northern blot and RT-PCR analysis as well as proteolytic processing to amyloidogenic A beta peptides. In contrast to rat and mouse APP, guinea pig APP - recombinantly expressed in human neuroblastoma-cells - was processed indistinguishable from human APP thus excluding intrinsic sequence-specific factors influencing processing. Further studies were performed using newly established primary cell cultures of guinea pig neurons. Refined methods have been used to detect and characterize major proteolytic processing products of APP in vitro and in vivo. In conclusion, guinea pigs provide a model to study expression and processing of APP that closely resembles the physiological situation in humans and should, therefore, be important in elucidating potential strategies to prevent amyloid formation in Alzheimers Disease. Biologie amyloid precursor protein APP cDNA-Sequenz sequence analysis Zellkultur proteolytic processing ddc:610
6	Translocation des colicines de type ribonuclease à travers la membrane interne bacterienne / Translocation of nuclease colicins D and E3 through the inner membrane of E. coli Chauleau, Mathieu 23 September 2011 (has links) Les colicines sont des toxines antibactériennes d’Escherichia coli qui sont relâchées par les cellules productrices (colicinogènes) dans le milieu extracellulaire en réponse à des conditions de stress environnementaux. Les colicines D et E3 sont des RNases qui clivent respectivement les tRNAArg et le 16S RNA ribosomique. Les deux colicines parvenues au cytoplasme de la cellule cible provoquent ainsi la mort par inactivation de la machinerie de biosynthèse des protéines. L’import de ces deux colicines nécessite d’abord le détournement de deux systèmes cellulaires différents (FepA/TonB ou BtuB/Tol) de leur fonction physiologique, permettant leur translocation à travers la membrane externe. L’idée que par la suite la translocation à travers la membrane interne nécessite au préalable une étape de processing des colicines nucléases est ancienne, mais elle n’a jamais été démontrée formellement. Nos travaux ont permis de montrer qu’une coupure endoprotéolytique des deux colicines constitue une étape de « processing » essentielle de leur action toxique. Nous avons détecté la présence du domaine C-terminal catalytique des deux colicines dans le cytoplasme des cellules cibles préalablement exposées à la toxine. Les mêmes fragments processés (PF) ont été identifiés dans les cellules sensibles et dans les cellules immunes contre ces colicines, qui sont protégées par une protéine d’immunité spécifique, formant un complexe neutre avec le domaine catalytique. Nous avons démontré que la protéase essentielle de la membrane interne, FtsH, est nécessaire au processing des deux colicines pendant leur import. Nous avons montré aussi que la signal-peptidase LepB, une autre enzyme essentielle de la membrane interne, interagit directement avec le domaine central de la colicine D in vitro et ainsi elle est un facteur protéique spécifiquement nécessaire au processing de la colicine D. Cependant ce n’est pas l’activité catalytique de LepB qui est impliquée dans la toxicité de la colicine D, mais elle jouerait un rôle structural. LepB ainsi faciliterait probablement l’association de la colicine D avec la membrane interne en vue de la reconnaissance de la toxine par FtsH. Nous avons aussi montré que la protéase OmpT de la membrane externe est responsable d’une coupure endoprotéolytique alternative, qui refléte probablement son rôle bien connu dans le système de défense des bactéries contre les peptides anti-microbiens. Même si cette coupure in vitro permet de libérer le domaine catalytique des colicines D et E3, il est établit maintenant que la protéase OmpT n’est pas impliquée dans le processing des colicines durant leur import dans le cytoplasme. / Colicins are antibacterial toxins of Escherichia coli that are released into the extracellular medium in response to environmental stress conditions. Colicin D is an RNase that cleaves the anticodon loop of all four isoaccepting tRNAArg. Colicin E3 cleaves 16 S ribosomal RNA. Both colicins provoke cell death by inactivating the protein biosynthetic machinery. Colicin producer cells are protected against both endogenous and exogenous toxin molecules by the constitutive expression of a cognate immunity protein, which forms a tight heterodimer complex with the nuclease domain of the colicin. The import of both colicins first requires the “hijack” of some distinct functions of the target cell (namely the BtuB/Tol and FepA/TonB systems, respectively), this allowing their translocation across the outer membrane. It has long been suggested that the import of nuclease colicins requires protein processing during the translocation across the inner membrane; however it had never been formally demonstrated. Our work shows that the two different RNase colicins E3 and D undergo a processing step inside the cell that is essential to their killing action. We have detected the presence of the C-terminal catalytic domains of these colicins in the cytoplasm of target bacteria. The same processed forms (PF) were identified in both colicin-sensitive cells and in cells immune to colicins, because of the expression of the cognate immunity protein. We demonstrate that the inner membrane protease FtsH is necessary for the processing of colicins D and E3 during their import. We also show that the signal peptidase LepB interacts directly with the central domain of colicin D in vitro and that it is a specific but not a catalytic requirement for in vivo processing of colicin D. The interaction of colicin D with LepB may ensure a stable association with the inner membrane that in turn allows the colicin recognition by FtsH. We have also shown that the outer membrane protease OmpT is responsible for alternative and distinct endoproteolytic cleavages of colicins D and E3 in vitro, presumably reflecting its known role in the bacterial defense against antimicrobial peptides. Even though the OmpT-catalyzed in vitro cleavage also liberates the catalytic domain from colicins D and E3, it is not involved in the processing of nuclease colicins during their import into the cytoplasm Toxines bactériennes Nucléases anti-microbiennes Import de colicines Translocation membranaire Processing protéolytique Signal-peptidase LepB Membrane protéase FtsH RNase colicine Bacterial toxines Antibacterial nucleases Colicin import Membrane translocation Proteolytic processing Signal-peptidase LepB Membrane-protease FtsH RNase colicin
7	Structural rearrangements of the HIV-1 genomic RNA during maturation of the viral particle / Etude des remaniements structuraux de l'ARN génomique du VIH-1 lors de la maturation des particules virales Mailler, Élodie 22 September 2017 (has links) Le VIH-1 bourgeonne sous forme immature et doit subir l’étape de maturation afin d’acquérir son caractère infectieux. La maturation protéolytique du précurseur Pr55Gag induit le réarrangement morphologique de la particule alors que le dimère d’ARNg acquiert une compaction optimale. Ces réarrangements conformationnels restent encore inconnus et sont facilités par l’activité chaperonne de la protéine NCp7. Notre but a été de déterminer les différentes étapes menant à l’obtention d’un dimère d’ARNg mature. Nous avons donc étudié la structure des 550 premiers nucléotides du génome par cartographie chimique, à la fois 1. in vitro en présence des protéines Pr55Gag, GagΔp6, intermédiaires contenant le domaine NC et NCp7 et 2. in viro par l’approche hSHAPE-Seq que nous avons développé. Les particules matures et bloquées aux différentes étapes de maturation de Pr55Gag ont été analysées ainsi que des particules matures et totalement immatures traitées avec l’éjecteur de zinc AT-2. Ce traitement permet d’identifier les sites de protection de Pr55Gag et NCp7 ainsi que leur activité déstabilisatrice. / The HIV-1 particle buds from the infected cell as an immature particle and has to undergo a maturation process to become infectious. Proteolytic processing of Pr55Gag triggers morphological rearrangements of the particle whereas the gRNA dimer becomes more stable. Genomic rearrangements remain poorly understood and are facilitated by the RNA chaperone activity of the NCp7 protein. Our goal was to determining the different steps leading to the formation of the mature dimeric gRNA. To this end, the structure of the first 550 nucleotides of the HIV-1 genome was assessed by chemical probing 1. in vitro with Pr55Gag, GagΔp6, NC-containing intermediates and NCp7 proteins and 2. in viro with the hSHAPE-Seq approach we developed. Wild type and mutant viruses mimicking the sequential processing of Pr55Gag were analysed, as well as immature PR- and mature particles treated with the AT-2 zinc ejector, in order to identify the Pr55Gag and NCp7 binding sites and their gRNA destabilising activity. VIH-1 Maturation protéique Maturation génomique Cartographie chimique de l’ARN Séquençage à haut débit Structure secondaire de l’ARN Activité chaperonne de l’ARN HIV-1 Proteolytic processing Genomic maturation RNA chemical probing High-throughput sequencing RNA secondary structure RNA chaperone activity 572.8 616.97
8	Angiopoietin 1 and 2-regulated Tie2 receptor translocation in endothelial cells and investigation of Angiopoietin-2 splice variant 443 Pietilä, R. (Riikka) 19 May 2015 (has links) Abstract Angiopoietins 1 and 2 (Ang1 and Ang2) are the ligands of the Angiopoietin/Tie signalling system, which is a binary pathway offering mechanisms for healthy vessels to reach and maintain their quiescence but also to rapidly respond to activating stimuli leading to a remodelling of endothelium. The latter is linked to disease settings such as inflammation and cancer where endothelial cell (EC) integrity is compromised and is often related to an increase in Ang2 expression. This study focused on the mechanisms enabling Ang1 to mediate both EC stability and migration and molecular and cellular determinants for ligand-specific functions of Ang2 and its isoform Ang2443. The findings revealed that Ang1 induces differential signalling depending on whether it anchors and activates Tie2 in cell-cell junctions in quiescent ECs, or in cell-matrix contacts in mobile ECs, thus leading to cellular phenotypes characteristic of resting and mobile ECs, respectively. In the second part of the thesis Ang2-Tie2 specific cell-extracellular matrix (ECM) contact sites were studied. Formation of Ang2/Tie2 EC-ECM contact sites was dependent on the collagen I and IV matrices, low Ang2 oligomerization state, α2β1-integrins, and intact microtubules. In the third part of the thesis the comparison of Ang2 mRNA splice variant Ang2443 with full length Ang2 (Ang2FL) revealed both redundant and ligand form–specific effects, expression of Ang2443443 increased the amount of monomeric ligand forms due to proteolytic processing and promoted transendothelial migration of cancer cells in vitro. On the other hand, both Ang2443 and Ang2FL were stored in endothelial Weibel-Palade bodies (WPBs), similarly induced Ang2-specific Tie2 cellular redistribution, and were mostly comparable in developmental angio- and lymphangiogenesis. / Tiivistelmä Angiopoietiinit 1 ja 2 (Ang1 ja Ang2) ovat Ang/Tie signalointireitin kasvutekijöitä. Ang1 kasvutekijää tarvitaan sydämen ja verisuoniston sikiöaikaiseen kehittymiseen, se vähentää Tie2 reseptorin kautta verisuonten läpäisevyyttä, mutta edistää myös yksittäisten endoteelisolujen liikkumista. Saman Tie2 signalointireitin toisen kasvutekijän Ang2:n ilmeneminen johtaa verisuonten läpäisevyyden kasvuun tulehduksessa, uusien verisuonten muodostumiseen syöpäkasvaimissa ja syöpäsolujen leviämiseen elimistössä. Väitöskirjatutkimuksessa selvitettiin niitä solutason mekanismeja, joilla Ang1 kykenee välittämään sekä endoteelisolujen tiiviyttä että liikkumista. Lisäksi tutkittiin niitä molekyyli- ja solutason mekanismeja, joilla Ang2 ja sen isomuoto Ang2443 välittävät kasvutekijäspesifisiä vaikutuksiaan. Väitöskirjassa osoitettiin että Tie2 reseptori paikantuu verisuonten endoteelisoluissa Ang1 sitoutumisen seurauksena joko solu-soluliitoksiin, tai yksittäisissä endoteelisoluissa solu-soluväliaine rajapinnalle. Tie2:n siirtyminen solu-soluliitoksiin aktivoi soluissa signalointireittejä, jotka ovat tyypillisiä normaaleille tiiviille verisuonille ja solu-soluväliaineliitoksissa liikkuville endoteelisoluille tyypillisiä piirteitä. Väitöskirjatyön toisessa osassa tutkittiin Ang2:lle ominaisia vaikutuksia ja Ang2-Tie2 kompleksin paikantumista erityisiin solu-soluväliaineliitoksiin. Tämä oli riippuvaista Ang2:n oligomerisaatiosta, kollageenisoluväliaineesta, α2β1-integriinistä ja normaalista mikrotubulusverkostosta. Väitöskirjatyön kolmannessa osassa osoitettiin että Ang2443 isomuodolla on sekä yhteisiä että isomuotospesifisiä piirteitä verrattuna kokopitkään Ang2:een (Ang2FL). Liukoinen Ang2443, mutta ei Ang2FL, esiintyi yleisesti monomeerisenä ligandimuotona proteiinin multimerisaatio-osan pilkkomisen seurauksena. Ang2443 lisäsi myös syöpäsolujen liikkumista endoteelisolujen läpi. Toisaalta sekä Ang2443 että Ang2FL varastoitiin endoteelisoluissa Weibel-Palade varastokappaleisin, ne välittivät samanlaista Tie2 reseptorin paikantumista endoteelisoluissa ja toimivat pääsääntöisesti samanlaisina kasvutekijöinä veri- ja imusuonten kehityksen aikana hiiressä. Angiopoietin-1 Angiopoietin-2 Weibel-Palade body alternative mRNA splicing cell adhesion cell-cell junctions endothelial cell extracellular matrix proteolytic processing vasculature Angiopoietiini-1 Angiopoietiini-2 Weibel-Palade kappale endoteelisolu mRNA:n vaihtoehtoinen silmukointi proteolyyttinen muokkaus solu-soluliitokset soluväliaine verisuonisto Tie2
9	Molekulare Charakterisierung des Amyloidvorläuferproteins des Meerschweinchens Beck, Mike 09 December 1998 (has links) Die Bildung von Amyloidablagerungen ist ein Kennzeichen der Alzheimerschen Erkrankung. Hauptbestandteil dieser senilen Plaques sind sogenannte A beta Peptide, die durch proteolytische Prozessierung aus einem Vorläufermolekül (APP) gebildet werden. Die vorliegende Arbeit beschreibt die Klonierung des Meerschweinchen - APP. Diese cDNA-Sequenz zeigt auf DNA-Ebene eine Homologie zum Human-APP von ca. 90%, auf Proteinebene beträgt die Identität ca. 97 %. Damit wird ein weiterer experimenteller Beweis für die evolutionäre Konservierung des Amyloidvorläuferproteins in Säugetieren erbracht. APP mRNA wird in Meerschweinchen-Geweben ubiquitär exprimiert. Durch alternatives Spleißen wird ein zum Human-APP im wesentlichen ähnliches Isoformenmuster gebildet: Isoformen, welche eine Proteaseinhibitordomäne enthalten, werden dominierend in peripheren Organen exprimiert, dagegen ist im Zentralnervensystem das APP 695 mit über 60 % der Gesamttranskripte die bevorzugt exprimierte Isoform. Die klonierte cDNA des Meerschweinchen-APP wurde in prokaryontischen wie auch eukaryontischen Zellsystemen exprimiert. Dabei wurde die Eignung einer Anzahl von gegen Human-APP gewonnenen Antikörpern zur Detektion des Meerschweinchen-APP und seiner Prozessierungsprodukte gezeigt. Die Expression der neuronal dominierend exprimierten Isoform APP 695 des Meerschweinchen-APP in humanen Neuroblastom-Zellen zeigte keine Unterschiede hinsichtlich der APP-Prozessierung und A beta-Bildung im direkten Vergleich zu Human-APP 695. Die proteolytische Prozessierung des Proteins wurde durch Detektion der typischen Spaltprodukte in vivo (im Liquor) als auch in einem neu etablierten in vitro-Modell primär kultivierter neuronaler Zellen untersucht. Diese Zellkulturen wurden zunächst immunhistochemisch und biochemisch charakterisiert und als "mixed brain"-Typ mit einem hohen neuronalen Anteil beschrieben. Die Prozessierung des endogenen Meerschweinchen-APP in kultivierten Zellen führt dabei zur Bildung und Akkumulation aggregationsfähiger A beta - Peptide. Zur Detektion dieser Peptide wurde ein sensitiver Nachweis durch Western-Blot etabliert. Es wird damit ein Modellsystem für in vitro-Untersuchungen vorgeschlagen, welches ein Studium der Expression und Prozessierung des Amyloidvorläuferproteins unter angenähert physiologischen Bedingungen ermöglicht. / A beta peptides, the major component of neuritic plaques found in the brains of patients with Alzheimers disease, are derived by proteolytic processing from a larger precursor molecule (amyloid precursor protein - APP). A combination of PCR methods was used to clone and sequence APP cDNA from guinea pig (Cavia porcellus). Guinea pig APP exhibits extensive similarities to human APP in terms of primary structure, mRNA expression of differentially spliced isoforms as shown by Northern blot and RT-PCR analysis as well as proteolytic processing to amyloidogenic A beta peptides. In contrast to rat and mouse APP, guinea pig APP - recombinantly expressed in human neuroblastoma-cells - was processed indistinguishable from human APP thus excluding intrinsic sequence-specific factors influencing processing. Further studies were performed using newly established primary cell cultures of guinea pig neurons. Refined methods have been used to detect and characterize major proteolytic processing products of APP in vitro and in vivo. In conclusion, guinea pigs provide a model to study expression and processing of APP that closely resembles the physiological situation in humans and should, therefore, be important in elucidating potential strategies to prevent amyloid formation in Alzheimers Disease. info:eu-repo/classification/ddc/610 ddc:610 Biologie
10	Regulation of BAP1 tumor suppressor complex by post-translational modifications Mashtalir, Nazar 04 1900 (has links) Le régulateur transcriptionnel BAP1 est une déubiquitinase nucléaire (DUB) dont le substrat est l’histone H2A modifiée par monoubiquitination au niveau des residus lysines 118 et 119 (K118/K119). Depuis les dernières années, BAP1 emerge comme un gene suppresseur de tumeur majeur. En effet, BAP1 est inactivé dans un plethore de maladies humaines héréditaires et sporadiques. Cependant, malgré l’accumulation significative des connaissances concernant l’occurrence, la pénétrance et l’impact des défauts de BAP1 sur le développement de cancers, ses mécanismes d’action et de régulation restent très peu compris. Cette étude est dédiée à la caractérisation moléculaire et fonctionnelle du complexe multi-protéique de BAP1 et se présente parmi les premiers travaux décrivant sa régulation par des modifications post-traductionnelles. D’abord, nous avons défini la composition du corps du complexe BAP1 ainsi que ses principaux partenaires d’interaction. Ensuite, nous nous sommes spécifiquement intéressés a investiguer d’avantage deux principaux aspects de la régulation de BAP1. Nous avons d’abord décrit l’inter-régulation entre deux composantes majeures du complexe BAP1, soit HCF-1 et OGT. D’une manière très intéressante, nous avons trouvé que le cofacteur HCF-1 est un important régulateur des niveaux protéiques d’OGT. En retour, OGT est requise pour la maturation protéolytique de HCF-1 en promouvant sa protéolyse par O-GlcNAcylation, un processus de régulation très important pour le bon fonctionnement de HCF-1. D’autre part, nous avons découvert un mécanisme unique de régulation de BAP1 médiée par l’ubiquitine ligase atypique UBE2O. en effet, UBE2O se caractérise par le fait qu’il s’agit aussi bien d’une ubiquitine conjuratrice et d’une ubiquitine ligase. UBE2O, multi-monoubiquitine BAP1 au niveau de son domaine NLS et promeut son exclusion du noyau, le séquestrant ainsi dans le cytoplasme. De façon importante, nos travaux ont permis de mettre de l’emphase sur le rôle de l’activité auto-catalytique de chacune de ces enzymes, soit l’activité d’auto-déubiquitination de BAP1 qui est requise pour la maintenance de sa localisation nucléaire ainsi que l’activité d’auto-ubiquitination d’UBE2O impliquée dans son transport nucléo-cytoplasmique. De manière significative, nous avons trouvé que des défauts au niveau de l’auto-déubiquitination de BAP1 due à des mutations associées à certains cancers indiquent l’importance d’une propre regulation de cette déubiquitinase pour les processus associés à la suppression de tumeurs. / BAP1 is a nuclear deubiquitinating enzyme (DUB) that acts as a transcription regulator and a DUB of nucleosomal histone H2AK119. In the recent years, it has become clear that BAP1 is a major tumor suppressor, inactivated in a plethora of hereditary and sporadic human malignancies. Although, we now accumulated a significant body of knowledge in respect to the occurrence, penetrance and impact of BAP1 disruption in cancer, its mechanism of action and regulation remained poorly defined. This work is dedicated to the biochemical and functional characterization of the BAP1 multiprotein complex and presents one of the first cases regarding its regulation by post-translational modifications. First, we defined the initial composition of the BAP1 complex and its main interacting components. Second, we specifically focused on two aspects of BAP1 regulation. We described the cross regulation between the two major components of the complex namely HCF-1 and OGT. We found that HCF-1 is important for the maintenance of the cellular levels of OGT. OGT, in turn, is required for the proper maturation of HCF-1 by promoting O-GlcNAcylation-mediated limited proteolysis of its precursor. Third, we discovered an intricate regulatory mechanism of BAP1 mediated by the atypical ubiquitin ligase UBE2O. UBE2O multi-monoubiquitinates BAP1 on its NLS and promotes its exclusion from the nucleus. Importantly, our work emphasises the role of the autocatalytic activity of both enzymes namely the auto-deubiquitination activity of BAP1, required for the maintenance of nuclear BAP1 and the auto-ubiquitination of UBE2O implicated in its nucleocytoplasmic transport. Significantly, we found that auto-deubiquitination of BAP1 is disrupted by cancer-associated mutations, indicating the involvement of this process in tumor suppression. Chromatine Marque épigénctique O-GlcNAcylation Régulation protéolytique Ubiquitination Déubiquitinase Ubiquitine ligase atypique Activité auto-catalytique Cancer Chromatin Epigenetic mark Proteolytic processing Ubiquitination Deubiquitinase Atypical ubiquitin ligase Autocatalytic activity Host cell factor 1 BRCA1-associated protein 1 UBE2O

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