Regulace buněčné odpovědi na poškozenou DNA pomocí skládání komplexu MRN šaperonovým komplexem R2TP a pomocí kontroly buněčné lokalizace proteinu 53BP1. / Regulation of the DNA damage response by R2TP mediated MRN complex assembly and control of 53BP1 localisation.

Von Morgen, Patrick

January 2017

DNA double strand breaks are the most dangerous type of DNA damage. The MRN complex and 53BP1 have essential functions in the repair of DNA double strand breaks and are therefore important for maintaining genomic stability and preventing cancer. DNA double strand breaks are repaired by two main mechanisms - homologous recombination and non- homologous end joining. The MRN complex senses DNA double strand breaks and activates a cascade of posttranslational modifications that activates and recruits other effector proteins. In addition MRN mediated resection is important for removing adducts in non-homologous end joining and creating single stranded DNA required for homologous recombination. 53BP1 is recruited to DNA double strand breaks by site specific ubiquitinations and inhibits DNA resection, thereby promoting non-homologous end joining at the expense of homologous recombination. In this thesis we show that MRE11 binds to the R2TP chaperone complex through a CK2 mediated phosphorylation. Knockdown of R2TP or mutating the MRE11 binding site leads to decreased MRE11 levels and impaired DNA repair. Similar phenotype has been observed in cells from patients with ataxia-telangiectasia-like disorder (ATLD), containing MRE11 deletion mutation which is missing the R2TP complex binding site. Based on R2TP...

Delivery Performance Prediction Tool for Complex Assembly Systems

Beladi, Faried D

01 January 2014

Complex assembly systems are made up of hundreds, and in some cases, thousands of parts, that all need to be managed in a proper manner so part arrivals will coincide to meet a build plan, and ensure production requirements are satisfied. A major challenge faced by manufacturers for these complex systems is that many parts have long and complex supply chains, which result in long and highly variable supply lead times. The high cost and low volume makes holding large stocks of these components unviable. Thus, the need arises for the development of a simulation tool that can predict the time all of the required parts are ready for assembly, and allow for comparison of various ordering and inventory strategies. Two strategies were tested, the current practice of ordering to an agreed upon quoted lead time, and a strategy which accounts for lead time variability through advanced ordering. The results of these two strategies displayed the benefits of synchronizing the system through advance ordering, as a potential 60% reduction in inventory was observed. Future development in the tool would incorporate more granular steps of the build sequence, as well as the inclusion of quality non-conformance (QN) issues.

Discrete event simulation

complex assembly systems

delivery delay

simulation tool

Industrial Engineering

Operational Research

Biophysikalische und thermodynamische Charakterisierung der neuronalen SNARE-Komplexbildung / Biophysical and Thermodynamical Characterization of the Neuronal SNARE Complex Formation

Wiederhold, Katrin

30 April 2008

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Membranfusion

SNARE-Proteine

Komplexbildung

membrane fusion

SNARE proteins

complex assembly

35.73 Biochemische Reaktionen

The role of a trimeric coiled coil protein in WASH complex assembly / Rôle d’une protéine trimérique à superhélice dans l’assemblage du complexe WASH

Visweshwaran, Sai Prasanna

22 September 2017

Le complexe Arp2/3 génère des réseaux d’actine branchés, qui produisent une forcée de poussée permettant à la cellule de remodeler ses membranes. Le complexe WASH active le complexe Arp2/3 à la surface des endosomes et facilite ainsi la scission membranaire des intermédiaires de transports contenants des récepteurs internalisés tels que les intégrines α5β1. De ce fait, le complexe WASH en favorisant le recyclage des intégrines, joue un rôle crucial dans l’invasion des cellules tumorales durant la progression tumorale. Cependant, le mécanisme d’assemblage du complexe WASH est inconnu. Dans cette étude, nous rapportons l’identification du premier facteur d’assemblage du complexe WASH. Nous avons identifié la protéine HSBP1 grâce à un crible des protéines qui se lient aux formes précurseurs des sous-unités mais plus au complexe une fois assemblé. La reconstitution biochimique et la modélisation moléculaire nous a permis de montrer que HSBP1 est associé avec le précurseur trimérique CCDC53, le dissocie et forme un hétérotrimère qui va éventuellement libérer une forme monomérique de CCDC53 pour l’assemblage du complexe WASH. Le rôle de HSBP1 dans l’assemblage du complexe WASH est conservé. En effet, WASH est déstabilisé dans des cellules mammaires par le knock-down de HSBP1 et dans l’amibe Dictyostelium par le knock-out de HSBP1. La déstabilisation du complexe WASH par le knock-out de HSBP1 phénocopie la déplétion de WASH dans l’amibe Dictyostelium. Dans des cellules humaines de carcinomes mammaires l’inhibition de l’expression de HSBP1 altère le recyclage des intégrines à la membrane plasmidique. Il en résulte des adhésions focales défectueuses et des capacités invasives réduites. De plus, HSBP1 est localisé aux centrosomes et est requis pour la polarité des cellules lors de la migration. Enfin, nous avons trouvé que la surexpression de HSBP1 dans des tumeurs mammaires est associée à une augmentation des niveaux du complexe WASH et à un mauvais pronostic pour les patientes atteintes de cancer du sein. En conclusion, HSBP1 est un facteur d’assemblage conservé qui contrôle les niveaux du complexe WASH. / The Arp2/3 complex generates branched actin networks, which produces a pushing force that helps the cell to remodel its membranes. The WASH complex activates the Arp2/3 complex at the surface of endosomes and thereby, facilitates the membrane scission of the transport intermediates containing internalized receptors such as α5β1 integrins. Hence, by promoting integrin recycling, the WASH complex plays a crucial role in tumor cell invasion during cancer progression. However, how cells assemble the WASH complex at first is unknown. Here we report the identification of the first assembly factor of the WASH complex. We identified HSBP1 in a proteomics screen for proteins binding to precursor forms of subunits, but not to the fully assembled WASH complex. Through biochemical reconstitution and molecular modeling, we found that HSBP1 associates with the precursor CCDC53 trimer, dissociates it and forms a heterotrimer that will eventually contribute a single CCDC53 molecule to the assembling WASH complex. The role of HSBP1 in WASH complex assembly is well conserved since WASH is similarly destabilized upon HSBP1 knock-down in mammalian cells or upon HSBP1 knock-out in Dictyostelium amoeba. In line with the defective assembly of the WASH complex, the HSBP1 knock-out closely phenocopies WASH knock-out in amoeba. In human mammary carcinoma cells, HSBP1 depletion results in impaired integrin recycling to the plasma membrane leading to the defective development of focal adhesions and reduced invasion abilities. Moreover, HSBP1 was found to localize at the centrosome and was required for the polarization associated with the migration. On the other end, in mammary breast tumors, we found that HSBP1 was often overexpressed and that its overexpression was associated with increased levels of the WASH complex and with poor prognosis for breast cancer patients. Hence, HSBP1 is a conserved assembly factor that controls the levels of the WASH complex.

Complexe WASH

Cytosquelette d'actine

Assemblage des complexes

Migration des cellules

Invasion des cellules

Centrosome

Complexe Arp2/3

WASH complex

Actin cytoskeleton

Multiprotein complex assembly

Cell migration

Cell invasion

Centrosome

Arp2/3 complex

Global quantification of cellular protein degradation kinetics

McShane, Erik

31 March 2017

Es wird allgemein angenommen, dass Proteine exponentiell degradiert werden. Das bedeutet, dass neu synthetisierte als auch alte Proteine mit gleicher Wahrscheinlichkeit degradiert werden. Es tauchen jedoch immer mehr Hinweise dafür auf, dass das nicht immer der Fall sein muss. Um diese Fragestellung systematisch anzugehen, haben wir eine Methode zur metabolischen Pulsmarkierung mit der nichtkanonischen Aminosäure Azidohomoalanine (AHA) entwickelt. AHA ermöglicht die Anreicherung von neu synthetisierten Proteinen direkt nach einem Puls oder nach einer „chase“ (Nachverfolgung) Periode in AHA freiem Medium. Wir kombinierten diese Methode mit SILAC und Shotgun Proteomik um zu quantifizieren wieviel Protein nach verschiedenen chase-Perioden übrig bleibt. Damit konnten wir Degradationsprofile für tausende von Proteinen erstellen. Unsere Daten zeigen, dass mehr als 10 % der Proteine nicht exponentiell degradiert werden (NED). Diese Proteine werden mit fortschreitendem Alter ausschließlich stabiler. Proteasomale Degradation von überschüssigen Proteinkomplexuntereinheiten scheint einen Großteil der NEDs zu erklären. Beim Vergleich zwischen murinen und humanen Zellen stellte sich heraus, dass NED teilweise konserviert ist. Das liegt scheinbar daran, dass diese Zellen trotz unterschiedlichem Ursprungs einheitlich bestimmte Untereinheiten überproduzieren. Da überschüssige NED Proteine bereits unter Standardbedingungen degradiert werden, nahmen wir an, dass die zusätzliche Überproduktion eines NED Proteins seine Level im stationären Zustand nicht verändern sollte. Um dies zu zeigen, quantifizierten wir Degradationskinetiken von Proteinen einer aneuploidenZelllinie. Wir fanden, dass NED Proteine, die auf trisomischen Chromosomen codiert sind, nicht in gleichem Maße ihr stationäres Level steigerten wie exponentiell degradierte Proteine. In Übereinstimmung mit unserer Hypothese verzeichneten wir stattdessen eine Zunahme der anfänglichen Degradationsraten dieser NED Proteine. / Proteins are thought to be degraded exponentially. That means that newly synthesized proteins have the same probability to be degraded as old proteins. However, evidence has accumulated showing that this is not true in all cases. To analyze this more systematically, we developed a method employing metabolic pulse-labeling by the non-canonical amino acid azidohomoalanine (AHA). AHA enables enrichment of newly synthesized proteins directly after pulse or after chase in AHA-free medium. We used SILAC and shotgun proteomics to quantify how much protein remains after different lengths of chase to create degradation profiles for thousands of proteins. Importantly, these degradation profiles allowed us to detect changes in degradation kinetics as the proteins age. We found that more than 10 % of proteins are non-exponentially degraded (NED). These protein are exclusively stabilized by age. Proteasomal degradation of excess protein complex subunits seems to explain a large fraction of NED. Comparing NED in mouse and human cells, we found that NED is at least partially conserved, seemingly due to cells consistently making too much of certain subunits. These overproduced subunits are on average shorter and more structured than the exponentially degraded proteins within the same complex. Finally, since excess NED proteins are degraded during baseline conditions, we hypothesized that making more of a NED protein would not increase its steady state levels. We employed an aneuploidy cell model and found that indeed NED proteins encoded on trisomic chromosomes did not increase in steady state levels to the same extent as exponentially degraded proteins. Instead, we recorded an increase in initial degradation of these proteins. In summary, we present a method for global pule-chase experiments allowing the detection of age-dependent protein degradation with possible implications for the understanding of aneuploidy and cancer.

SILAC

Azidohomoalanine

pulse-chase

Nicht Exponentiell Degradationskinetik

Proteine Degradierung

Proteinekomplex

Shotgun Proteomik

Massenspectrometrie

Aneuploidie

protein degradation

mass spectrometry

SILAC

shotgun proteomics

Azidohomoalanine

pulse-chase experiments

non-exponential kinetics

protein complex assembly

Aneuploidy

570 Biowissenschaften, Biologie

32 Biologie

WD 5100

WD 2200

ddc:570