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Showing 41 to 50 of 51 (0.047 seconds)Spelling suggestions: "subject:"cryoelectron microscopy"" "subject:"exoelectron microscopy""
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Contribution à l'estimation de la similarité dans un ensemble de projections tomographiques non-orientées / Contribution in estimation of similarity from a set of tomographic projections taken at unknown directionsPhan, Minh-Son 07 October 2016 (has links)
La cryo-microscopie électronique est une technique tomographique permettant de reconstituer la structure 3D d’un objet complexe en biologie à partir d’un jeu d’acquisitions. Ces images de l’objet complexe sont appelées les projections et sont acquises sous orientations inconnues. Un des avantages de la cryo-microscopie électronique est l’obtention d’un modèle 3D de très haute résolution de l’objet dans un état naturel. La procédure de reconstruction comporte plusieurs étapes telles que l’alignement, la classification des projections, l’estimation de leurs orientations et le raffinement des projections. Lors de ces étapes, la distance entre deux projections est fréquemment mesurée. Le travail réalisé au cours de cette thèse s’organise autour de la recherche théorique d’une distance entre des projections non-orientées avec comme objectif l’amélioration de la procédure de reconstruction tomographique en cryo-microscopie électronique. La contribution de ce travail de thèse est une méthode permettant d’estimer la différence angulaire entre deux projections dans les cas 2D et 3D. Notre méthode est basée sur la construction d’un graphe de voisinage dont les sommets sont les projections, dont les arêtes relient des projections voisines et sont pondérées par une approximation locale de la différence angulaire. Le calcul de ces poids repose sur les propriétés des moments de projection. Notre méthode est testée sur des images simulées de différentes résolutions et de différents niveaux du bruit. La comparaison avec des autres méthodes d’estimation de la différence angulaire est aussi réalisée. / Cryo-electron microscopy is a tomographic technique allowing to reconstruct a 3D model of complex structure in biology from a set of acquired images. These images are known as the tomographic projections and are taken at unknown directions. The advantage of the cryo-electron microscopy is the 3D reconstruction at very high resolution. The reconstruction procedure consists of many steps such as projection alignment, projection classification, orientation estimation and projection refinement. During these steps, the distance between two projections is frequently measured. The work in this thesis aims at studying the distances mesured between two unknown-direction projections with the objective of improving the reconstruction result in the cryo-electron microscopy. The contribution of this thesis is the developement of a method for estimating the angular difference between two projections in 2D and 3D. Our method is based on the construction of a neighborhood graph whose vertices are the projections, whose edges link the projection neighbors and are weighted by a local approximation of the angular difference. The calculation of the weights relies on the projection moment properties. The proposed method has been tested on simulated images with different resolutions and at different noise levels. The comparison with others estimation methods of angular difference has been realised.
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Structural and Mechanistic Features of Protein Assemblies with Special Reference to SpliceosomeRakesh, Ramachandran January 2016 (has links) (PDF)
Macromolecular assemblies such as the ribosome, spliceosome, polymerases are imperative for cellular functions. The current understanding of these important machineries and many other assemblies at the molecular level is poor. The lack of structural data for many macromolecular assemblies further causes a bottleneck in understanding the cellular processes and the various disease manifestations. Hence, it is essential to characterize the structures and molecular architectures of these macromolecular assemblies.
Though the number of 3-D structures for individual proteins structures or domains in the Protein Data Bank (PDB) is growing, the number of structures deposited for macromolecular assemblies is relatively poor. Hence, apart from the use of experimental techniques for characterizing macromolecular assembly structures, the use of computational techniques would help in supplementing the growth of macromolecular assembly structures. This thesis deals with the use of integrative approaches where computational methods are combined with experimental data to model and understand the mechanistic features of macromolecular assemblies with a special focus on a sub-complex of the spliceosome machinery.
Chapter 1 of this thesis provides an introduction to protein-protein interactions and macromolecular assemblies. Further, the modelling of macromolecular assemblies using integrative methods are discussed, with a subsequent introduction to the spliceosome machinery.
In chapter 2, modelling studies were performed on the proteins involved in the general amino acid control mechanism, which is triggered in yeast under amino acid starvation conditions. The proteins involved in the study were Gcn1, a ribosome binding protein and the RWD-domain containing proteins Gcn2, Yih1, Gir2 and Mtc5. From laboratory experiments it is known that in order for Gcn2 activation, an eIF2α kinase, its RWD-domain has to bind to Gcn1 and the residue Arg-2259 is important for this interaction. As the 3-D structure for the Gcn1 region containing Arg-2259 is not currently available, its 3-D structure was inferred using fold recognition and comparative modelling techniques. Further, in order to understand the Gcn2 RWD domain-Gcn1 molecular interaction, a complex structure was inferred by using a restrained protein-protein docking procedure. As the proteins, Yih1 and Gir2 are known to bind to Gcn1 using their RWD-domains, first the structures of the RWD-domain containing proteins including Mtc5 were inferred using a Gcn2 RWD domain NMR structure. Additionally, the Gcn1-Gcn2 complex was used to build a set of complexes to explain the binding of other RWD domain containing proteins Yih1, Gir2 and Mtc5. The important molecular interactions were obtained on analysing the interacting residues in these complexes. Thus, the Gcn1-Gcn2 interaction at the molecular level has been proposed for the first time. Future experiments guided by the protein-protein complex models and the proposed set of mutations should provide an understanding about the critical molecular interactions involved in the general amino acid control mechanism.
Chapter 3 describes an integrative approach that was used to decipher a pseudo-atomic model of the closed form of human SF3b complex. SF3b is a multi-protein complex containing seven components – p14, SF3b49, SF3b155, SF3b145, SF3b130, SF3b14b and SF3b10. It recognizes the branch point adenosine in the pre-mRNA as part of U2 snRNP or U11/U12 di-snRNP in the spliceosome. Although, the cryo-EM map for human SF3b complex has been available for more than a decade, the structure and relative spatial arrangement of all components in the complex are not yet known. The integrative modelling approach used here involved utilizing structural data in the form of available X-ray and NMR structures, fold recognition and comparative modelling as well as currently available experimental datasets, along with the available cryo-EM density map to provide a model with high structural coverage. Hence, the molecular architecture of closed form human SF3b complex was derived that can now provide insights into the functioning of SF3b in splicing. This might also help the future high resolution structure determination efforts of the entire human spliceosome machinery
In chapter 4, the molecular architecture of the closed form of SF3b complex obtained from the use of integrative modelling approach (Chapter 3) is extensively discussed. The structure-function relationships for some of the SF3b components based on the pseudo-atomic model has also been provided. In addition, the extreme flexibility associated with some of the SF3b components based on dynamics analysis has also been examined. Further, using an existing U11/U12 di-snRNP cryo-EM map and the closed form SF3b complex pseudo-atomic model, an open form of the SF3b complex was modelled and the component structures were fit into it. Hence, it was found that the transition between closed and open forms is primarily caused by a flap containing the HEAT repeat protein, SF3b155. This Protein is also known to harbour cancer causing mutations and has the potential to affect the Closed to open transition as well as SF3b complex structure and stability. Thus, this provides a framework for the future understanding of the closed to open transition in SF3b functioning within the spliceosome.
Chapter 5 builds upon the integrative modelling approach (Chapter 3) that proposed the molecular architecture of the closed form of human SF3b complex and an open form of SF3b that was derived due to a flap opening of the closed form and which might help in accommodating RNA and other trans-acting factors within the U11/U12 di-snRNP (Chapter 4). In the current chapter, the SF3b open form and its interaction with the RNA elements is studied. The 5' end of U12 snRNA and its interaction with pre-mRNA in branch point duplex was modelled guided by the open form of SF3b that provided the necessary structural constraints and the RNA model is topologically consistent with the existing biochemical data. Further, utilizing the SF3b opens form-RNA model and the existing experimental knowledge, an extensive discussion has been provided on how the architecture of SF3b acts as a scaffold for U12 snRNA: pre-mRNA branch point duplex formation as well as its potential implications for branch point adenosine recognition fidelity. Moreover, the reasons for SF3b to be defined as a “fuzzy” complex - a complex with highly flexible folded regions along with intrinsically disordered regions is also discussed. Hence, the current work adds to the excellent developments made previously and deepens the understanding of the structure-function relationship of the human SF3b complex in the context of the spliceosome machinery.
In chapter 6, a methodology has been proposed for the use of evolutionary conservation of protein-protein interfacial residues in multiple protein cryo-EM density based fitting of the protein components in the low-resolution density maps of multi-protein assemblies. First, the methodology was tested on a dataset of simulated density maps generated at four different resolutions -10, 15, 20 and 25 Å. On utilizing the evolutionary conservation scores obtained from multiple sequence alignments to score the fitted complexes, it was found that there was a decrease in the conservation scores when compared to that of the crystal structures, which were used to generate the simulated density maps. Further, the assessment of the multiple protein density fitting technique to align the actual protein-protein interface residues correctly using a performance metric called F-measure showed there was a decrease in performance as the resolutions became poorer. Hence, based on evolutionary conservations scores as well as F-measure the decrease in conservation scores or performance was found to be mainly due to the errors associated with the fitting process.
Subsequently, a refinement methodology was designed involving the use of conservation scores, which improved the accuracy of the fitted models and the same, was observed in an experimental cryo-EM density test case of RyR1-FKBP12 complex. Hence, the conservation information acts as an effective filter to distinguish the incorrectly fitted structures and improves the accuracy of the fitting of the protein structures in the density maps. Thus, one can incorporate the conserved surface residues information in the current density fitting tools to reduce ambiguity and improve the accuracy of the macromolecular assembly structures determined using cryo-EM.
In the concluding chapter 7, the learnings on the structural and mechanistic features of protein assemblies obtained from the use of computational techniques and integration of experimental datasets is discussed. In chapter 2, the modelling of a binary macromolecular complex such as the Gcn1-Gcn2 complex was performed using computational structure prediction strategies to understand the molecular basis of its interaction. Due to the potential inaccuracies which can exist in computational modelling, the chapters 3 to 5 dealt with the use of integrative approaches, primarily guided by the cryo-EM map, in order to decipher the molecular architecture of the human SF3b complex in the closed and open forms as well as its contribution for branch point adenosine recognition. Based on the extensive experience gained in modelling of assemblies using cryo-EM data in the previous chapters, a new method has been proposed on the use of evolutionary conservation information to improve the accuracy of cryo-EM density based fitting. Hence, these studies have provided strategies for modelling macromolecular assemblies as well as a deeper understanding of its mechanistic features.
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Structural And Functional Studies Of Neisserial Lactoferrin Binding ProteinsRavi Yadav (11850101) 17 December 2021 (has links)
<p>Two species of <i>Neisseria</i>, <i>N. meningitidis</i> and <i>N.
gonorrhoeae</i>, are obligate human pathogens that cause meningitis and
gonorrhea, respectively. Although generally asymptomatic, <i>N. meningitidis</i>
can cause invasive meningococcal disease with high mortality rate. Due to
emerging antibiotic resistance strains of <i>N. gonorrhoeae</i>, the Centers
for Disease Control and Prevention (CDC) have designated it as an urgent threat
to public health. Therefore, immediate interventions are required for fight
against these Neisserial pathogens. Iron is an essential nutrient for all
bacteria, including <i>Neisseria</i>. However, free iron is scarce in human,
therefore, <i>Neisseria</i> have evolved to acquire iron from host proteins.
These iron acquisition systems are immunogenic and important for infection and
are promising therapeutic targets.</p>
<p> In the
host, lactoferrin sequesters free iron and limits iron availability to
pathogens. However, <i>Neisseria</i> have evolved machinery to hijack iron directly
from lactoferrin itself. Lactoferrin
binding proteins, LbpA and LbpB, are outer membrane proteins that together
orchestrate the acquisition of iron from lactoferrin. Additionally, LbpB serves
an additional role in providing protection against host cationic antimicrobial
peptides and innate immune response. Despite studies aimed at deciphering the
roles of LbpA and LbpB, the molecular mechanisms underpinning iron acquisition
and immune protection remain unknown. Here, we investigated the role of the lactoferrin
binding proteins in iron acquisition and protection against cationic
antimicrobial peptides. We obtained three-dimensional structures of <i>Neisseria</i>
LbpA and LbpB in complex with lactoferrin using cryo-electron microscopy and
X-ray crystallography. These structures show that both LbpA and LbpB bind to
C-lobe of lactoferrin, albeit at distinct sites. Structural analyses show that
while lactoferrin maintains its iron-bound closed conformation in the
LbpB-lactoferrin complex, it undergoes a large conformational change from an
iron-bound closed to an iron-free open conformation upon binding to LbpA. This
observation suggest that LbpA alone can trigger the extraction of iron from
lactoferrin. Our studies also provide an explanation for LbpB’s preference
towards holo-lactoferrin over apo-lactoferrin and LbpA’s inability to
distinguish between holo- and apo-lactoferrin. Furthermore, using mutagenesis
and binding studies, we show that anionic loops in the C-lobe of LbpB
contribute to binding the cationic antimicrobial peptide lactoferricin.
Solution scattering studies of the LbpB-lactoferricin complex showed that LbpB
undergoes a small conformational change upon peptide binding.</p>
Together,
our studies provide structural insights into the role of the lactoferrin
binding proteins in iron acquisition and evasion of the host immune defenses.
Moreover, this work lays the foundation for structure-based design of
therapeutics against <i>Neisseria</i> targeting the lactoferrin binding
proteins.
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Segmentace biologických vzorků v obrazech z kryo-elektronového mikroskopu s využitím metod strojového učení / Segmentation of biological samples in cryo-electron microscopy images using machine learning methodsSokol, Norbert January 2021 (has links)
Zobrazovanie pomocou kryo-elektrónovej mikroskopie má svoje nezastúpiteľné miesto v analýze viacerých biologických štruktúr. Lokalizácia buniek kultivovaných na mriežke a ich segmentácia voči pozadiu alebo kontaminácii je základom. Spolu s vývojom viacerých metód hlbokého učenia sa podstatne zvýšila úspešnosť úloh sémantickej segmentácie. V tejto práci vyvinieme hlbokú konvolučnú neurónovú sieť pre úlohu sémantickej segmentácie buniek kultivovaných na mriežke. Dátový súbor pre túto prácu bol vytvorený pomocou dual-beam kryo-elektónového mikroskopu vyvinutého spoločnosťou Thermo Fisher Scientific Brno.
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Structural basis of modulation by pH and calcium in a ligand-gated ion channelAndén, Olivia January 2021 (has links)
Pentameriska ligandstyrda jonkanaler (pLGICs) är avgörande för omvandlingen av kemisk till elektrisk signalöverföring i djurs nervsystem. Dysfunktion i dessa kanaler har visat sig vara kopplad till flera sjukdomar inklusive epilepsi, schizofreni, Alzheimers och autism, vilket gör dem till en måltavla för en mängd olika läkemedel. Att studera eukaryota kanaler är dock mycket utmanande, så upptäckten av prokaryota homologer, som är mycket lättare att studera, har därmed bidragit mycket till förståelsen för struktur och funktion hos proteiner i denna familj. I detta projekt producerades och renades en prokaryotisk pLGIC kallad DeCLIC från Escherichia coli. Strukturell bestämning av kanalen genomfördes med användning av kryo-elektronmikroskopi vid lågt pH och i närvaro av kalcium. En elektrontäthet med 3.4 Å upplösning uppnåddes och jämfördes med tidigare bestämda strukturer vid olika förhållanden i ett försök att bestämma hur proteinets struktur moduleras av kalcium och pH. Resultaten visar flera skillnader i kanalens konformation i närvaro och frånvaro av kalcium såväl som vid olika pH-värden. Dessutom antyder analys av den bestämda elektrontätheten ett möjligt intermediärt tillstånd vid lågt pH i närvaro av kalcium. / Pentameric ligand-gated ion channels (pLGICs) are crucial for the conversion of chemical to electrical signaling in the nervous system of mammals. Dysfunction in these channels has been found to be connected to several diseases including epilepsy, schizophrenia, Alzheimer’s, and autism, making them the target of a wide variety of therapeutic agents. However, studying eukaryotic channels is challenging so the discovery of prokaryotic homologs that are much easier to study has thus greatly helped in the understanding of the structure and function in this family of proteins. In this project, a prokaryotic pLGIC called DeCLIC was produced and purified from Escherichia coli. Structural determination of the channel was pursued using cryo-electron microscopy at a low pH and in the presence of calcium. An electron density at 3.4 Å resolution was achieved and compared to previously determined structures at different conditions in an attempt to determine the structural modulation of calcium and pH. Results show multiple differences in channel conformation in the presence and absence of calcium as well as in different pH conditions. Furthermore, analysis of the determined electron density suggests a possible intermediate state at low pH in the presence of calcium.
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Ein 3D-Modell des Ribosomen-gebundenen OST-Sec61-TranslokonsFalke, Kristian 04 October 2012 (has links)
Gleich einem Etikett dient die N-Glykokosylierung vom Ribosom neu synthetisierter Proteine durch die Oligosaccharyltransferase (OST) bei der kotranslationalen Translokation in das Endoplasmatische Retikulum (ER) als Startpunkt vielschichtiger Prozessierungen. Bisher fehlte der strukturelle Nachweis, dass die OST als mit dem Ribosom assoziierten Membranprotein (RAMP) Bestandteil des auf dem proteinleitenden Kanal, dem Sec61-Komplex, basierenden Translokons ist. In dieser Arbeit berichten wir von der kryoelektronenmikroskopischen 3D-Struktur eines definierten OST-Sec61-Ribosom-Komplexes aus Saccharomyces cerevisiae bei 15,4 Å Auflösung. Dazu wurden die Komponenten (OST, Sec61 und Ribosomen mit naszierender Proteinkette) affinitätschromatographisch gereinigt und das Bindungsverhalten mit 80S-Ribosomen in vitro untersucht. Die OST band mit einer KD von 12,8 nM hochaffin und spezifisch an den bekannten Sec61-Ribosomen-Komplex. Dieser in vitro rekonstituierte trimere Komplex zeigte eine neuartige eng an das Ribosom anschließende Translokonstruktur mit zwei bisher unbekannten ribosomalen Verbindungen, einer einzigen dezentralen porenförmigen Vertiefung und zusätzlichen luminalen Bereichen. Durch das Docken eines Sec61-Homologs in einer alternativen Bindeposition sowie das Docken eines Stt3p-Homologs (der katalytischen Untereinheit der OST) und mit Hilfe der mittels (Kryo-)Negativkontrastierung gewonnenen 3D-Struktur der OST konnten Hybridmodelle erstellt werden. Daraus wurde unter Einbeziehung von bekannten molekularbiologisch gewonnenen Interaktionsdaten das 3D-Modell eines aktiven Ribosomen-gebundenen OST-Sec61-Translokons entwickelt. / Like a label, N-glycosylation by the oligosaccharyltransferase (OST) of newly synthesized proteins emerging from the ribosome while being cotranslationally translocated into the endoplasmic reticulum (ER) provides a starting point for a multitude of processes. Hitherto no structural proof has been presented, that the OST as a ribosome associated membrane protein (RAMP) is a constituent of the translocon, based at its core on the protein conducting channel (Sec61-complex). In this work we report on the 3D-structure of a defined OST-Sec61-ribosome complex from Saccharomyces cerevisiae by cryo-electron microscopy at 15.4 Å resolution. Thereto, the components (OST, Sec61, ribosome nascent chain complexes) have been purified by affinity chromatography and the binding of 80S-ribosomes has been checked in vitro. The OST bound with high affinity by a KD of 12.8 nM specifically to the established Sec61-ribosome complex. This trimeric complex reconstituted in vitro exhibits a new kind of tightly bound ribosomal translocon showing two hitherto unknown connections to the ribosome, a single off-center pore-like indentation and an additional luminal domain. By docking of a Sec61 homologue at an alternative binding position plus the docking of a Stt3p homologue (the catalytic subunit of the OST) and by means of the 3D-structure of the OST using the (cryo-)negative staining technique, hybrid models could be created. Consequently, integrating known interaction data from molecular biology experiments has been used to develop a 3D-model of an active ribosome-bound OST-Sec61-translocon.
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Strukturen von eEF3 und Sec61 als aktive ribosomale LigandenBecker, Thomas 30 January 2007 (has links)
Zusammenfassung Thema dieser Arbeit sind zwei zentrale biochemische Aspekte der Proteinbiosynthese , wobei das Ribosom eine zentrale Komponente darstellt: erstens wird ein spezieller Faktor des Elongationszyklus in Pilzen, eEF3, und zweitens der proteinleitende Kanal bei der kotranslationalen Proteintranslokation durch die Membran des endoplasmatischen Retikulums (ER) betrachtet. Für die Elongation der Polypeptidkette benötigen alle Organismen zwei Elongationsfaktoren, die GTPasen eEF1A (EF-Tu in Prokaryoten) und eEF2 (EF-G in Prokaryoten). Bei Fungi wird noch ein dritter Elongationsfaktor, eEF3, benötigt. Dieser Faktor ist eine ATPase mit ABC-Kassetten-Domänen. Durch einen nicht bekannten Mechamismus stimuliert er in Gegenwart von ATP die eEF1A-abhängige Bindung von Aminoacyl-tRNA an die ribosomale A-Stelle. Es wurde vorgeschlagen, dass eEF3 die Freisetzung von deacylierter tRNA aus der ribosomalen E-Stelle ermöglicht, und dadurch über allosterische Kopplung die Affinität der A-Stelle für Aminoacyl-tRNA erhöht. In dieser Arbeit wird die Kryo-EM Struktur von ribosomengebundenem eEF3 bei 13,3 Å vorgestellt. Dabei zeigt sich eine vollig neue ribosomale Bindungsstelle für eEF3 von der aus tatsächlich die Affinität für tRNA in der ribosomalen E-Stelle moduliert werden kann. Mit Hilfe der Kristallstruktur von eEF3 wurde ein molekulares Modell für eEF3 in seiner funktionalen Konformation generiert, welches die strukturelle Basis für die Aktivität dieses ABC-Proteins im Kontext der Translation liefert. Bei der kotranslationalen Translokation stellt der heterotrimere Sec61-Komplex einen signalsequenzgesteuerten proteinleitenden Kanal (PCC) dar, der die Translokation eines sekretorischen Proteins durch, oder die Integration von Membranproteinen in die ER-Membran erlaubt. Es wird angenommen, dass der aktive proteinleitende Kanal im ribosomengebundenen Zustand aus einer oligomeren Struktur mit mehreren Kopien des Sec61-Heterotrimers besteht. Die Kristallstruktur eines inaktiven PCC zeigt jedoch nur ein einziges Heterotrimer (Monomer), das auch im aktiven Zustand funktional sein könnte. In dieser Arbeit wird eine Kryo-EM-Struktur des aktiven proteinleitenden Kanals im Komplex mit einem translatierenden Ribosom aus Hefe präsentiert, die die bislang detailierteste Elektronendichtekarte für den PCC zeigt. Als charakteristisches Merkmal kann eine trichterförmige Pore auf der zytosolischen Seite visualisiert werden. Es wurden verschiedene molekulare Modelle für den aktiven Zustand in die Elektronendichte gedockt. Obwohl eine genaue molekulare Interpretation durch die Auflösung (12,3 Å) nach wie vor limitiert ist, erscheint es sehr wahrscheinlich, dass nur ein einziges, geöffnetes Sec61-Heterotrimer im aktiven Kanal vorliegt. / This work presents cryo-EM structures of two active ribosomal ligands in yeast, namely eEF3 and Sec61. Protein synthesis requires two canonical elongation factors in all kingdoms. These are the GTPases eEF1A (EF-Tu in prokaryotes) and eEF2 (EF-G in prokayotes). In fungi, a third elongation factor eEF3 is required, which belongs to the ATP-binding cassette- (ABC-) protein family. This factor is essential for the binding of the aminoacyl-tRNA-eEF1A-GTP ternary complex to the A site of the ribosome and has been suggested to do so by facilitating the clearance of deacyl-tRNA from the ribosomal E-site. The cryo-EM structure of the ATP-bound form of eEF3 in complex with an 80S ribosome shows that eEF3 binds the ribosome in the post-translocational conformation using a novel binding site. From there the affinity for tRNA in the ribosomal E site could be easily modified. Using the crystal structure of eEF3, a molecular model for eEF3 was generated, which provides the structural basis for the activity of an ABC protein in the context of translation. In co-translational translocation the trimeric Sec61-complex serves as a signal sequence-gated protein-conducting channel (PCC) which allows the translocation of a secetory protein through and the integration of a membrane protein into the lipid bilayer of the ER. Bound to a ribosome, the active PCC seems to have an oligomeric structure consisting of several copies of Sec61-trimers. The crystal structure of an inactive PCC, however, shows only a single heterotrimer (monomer) which could also be functional in the active state. The cryo-EM structure of the active PCC in complex with a translating ribosome shows the hitherto most detailed electron density map for the PCC. The most characteristic feature is a funnel-shaped off-centered pore at the cytosolic side. Several models for the active state were docked into the EM-density. Although a precise molecular interpretation is limited by the resolution (12, 3 Å), a single copy of an opened Sec61-heterotrimer seems to be the most reasonable fit for the density.
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CEMOVIS, développements méthodologiques et étude ultrastructurale de la cellule HT29 : De la cellule aux nucléosomes / CEMOVIS methodological developments and structural study of HT 29 cell : from cell to nucleosomsLemercier, Nicolas 23 March 2012 (has links)
Nous avons utilisé la méthode de CEMOVIS (Cryo-Electron Microscopy Of Vitreous Sections) pour étudier l’ultrastructure des cellules HT29 (lignée cancéreuse colique humaine) et plus particulièrement l’organisation de la chromatine au sein du noyau. Pour améliorer la méthode, nous avons développé un micromanipulateur qui facilite la collecte des coupes et leur transfert sur la grille. Nous avons également cherché à préparer de nouveaux films métalliques (en remplacement du carbone) permettant une meilleure adhésion des coupes sur le support Au vu des premiers tests réalisés, les films de TiO2 que nous avons fabriqués au laboratoire et caractérisés par microscopie électronique (HR, spectroscopie et cartographie EELS) semblent offrir des perspectives intéressantes que nous attribuons à leur propriétés de conducteur électrique à basse température (ce qui reste à démontrer). Les organites cellulaires (noyaux, réseaux de filaments du cytosquelette, systèmes multilamellaires) ont été identifiés in situ. Les conditions d’imagerie choisies nous ont permis d’obtenir une résolution permettant d’identifier les deux feuillets des bicouches membranaires. Dans le noyau, nous avons observé des motifs striés, distants de 2.7 à 3.5 nm que nous attribuons à la molécule d’ADN enroulée autour du cœur d’histones. Comparées aux images de phases denses de nucléosomes, ces images suggèrent que les nucléosomes (jamais identifiés in situ jusqu’à présent) présentent un ordre très local au sein de la chromatine, que nous discutons à la lumières des modèles polymériques actuels. / The ultrastructure of HT29 cells (human epithelial adenocarcinoma cell line) was studied by CEMOVIS (Cryo-Electron Microscopy of Vitreous Sections) with a special emphasis on chromatin organization in the cell nucleus. We proposed methodological improvements for this technique:- We first developed a grid holding micromanipulator to facilitate both cryosections collect and deposition on carbon-coated TEM grids.- We also developed new metallic thin films (to replace carbon-base supports) to enhance the adhesion of cryosections on their support. The TiO2 thin films that we produced and analysed by electron microscopy (high resolution imaging, EELS and chemical mapping) seem to be an interesting alternative to carbon films for the deposition of cryosections. Their adhesive properties could be due to Titanium high electric conductance at low temperature (although this relation has not been clearly demonstrated yet).In HT 29 cells, we indentified cell organites (nucleus; cytoskeleton filament bundles, multilamellar bodies) in situ. Selected imaging conditions provide for a high enough resolution to visualise the two membrane leaflets. In the cell nucleus, we observed striated patterns separated from 2.7 to 3.5 nm that we assume to be DNA molecule turns wrapped around the histone protein core. Compared with the dense phases formed in vitro by nucleosome core particle in solution, our images suggest that nucleosomes are locally ordered in chromatin. This observation is discussed regarding the chromatin polymeric models.
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New Algorithms for Macromolecular Structure Determination / Neue Algorithmen zur Strukturbestimmung von MakromolekülenHeisen, Burkhard Clemens 08 September 2009 (has links)
No description available.
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The Development of Image Processing Algorithms in Cryo-EMRui Yan (6591728) 15 May 2019 (has links)
Cryo-electron microscopy (cryo-EM) has been established as the leading imaging technique for structural studies from small proteins to whole cells at a molecular level. The great advances in cryo-EM have led to the ability to provide unique insights into a wide variety of biological processes in a close to native, hydrated state at near-atomic resolutions. The developments of computational approaches have significantly contributed to the exciting achievements of cryo-EM. This dissertation emphasizes new approaches to address image processing problems in cryo-EM, including tilt series alignment evaluation, simultaneous determination of sample thickness, tilt, and electron mean free path based on Beer-Lambert law, Model-Based Iterative Reconstruction (MBIR) on tomographic data, minimization of objective lens astigmatism in instrument alignment and defocus and magnification dependent astigmatism of TEM images. The final goal of these methodological developments is to improve the 3D reconstruction of cryo-EM and visualize more detailed characterization.
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