Molecular Insights into the A. thaliana CDC48-NPL4-UFD1 Complex

Zahodnik-Huntington, Brandon D.

07 1900

The maintenance of protein homeostasis as a response to changing external conditions is crucial for cellular survival and proper function. Since plants cannot adapt by changing location, their need for a rapid intracellular response is accentuated. The AAA ATPase CDC48 maintains protein homeostasis in conjunction with NPL4 and UFD1 by coupling ATP hydrolysis with mechanical force to extract and unfold ubiquitylated proteins from organelle membranes, chromatin, or protein complexes. Our bioinformatic analysis revealed considerable domain and binding motif differences in A. thaliana NPL4 compared to its orthologs in animals and fungi. Using ITC, MST, and SEC-MALS, we found that NPL4 and UFD1 did not heterodimerize, NPL4 bound to CDC48A in the absence of UFD1, and the complex was not stable in vitro. Additionally, we provided the first medium-high-resolution reconstructions of CDC48A in both an AMP-PNP bound and apo state, using cryo-EM. AMP-PNP bound CDC48A was reconstructed in both a tense (3.3 Å) and relaxed (3.5 Å) conformation with the N domain was positioned above or coplanar with the D1 ring, respectively. Our heterogeneity analysis using CryoDRGN revealed continuous flexibility of the N domains between the two conformations. The apo state was reconstructed as a single conformation at 4.4 Å resolution. A cryo-EM reconstruction of the complex was also obtained at a resolution of ~6 Å, which showed expected cofactor stoichiometry and binding positions. Through our efforts, we have observed differences in the interaction between A. thaliana CDC48A and its cofactors UFD1 and NPL4 that may correspond to functional differences between kingdoms.

CDC48

Cofactors

cryo-EM

Protein homeostasis

UFDI

NPL4

Investigating the Functional Role of Drp1 in Mitochondrial Fission

Francy, Christopher Alfred

08 February 2017

No description available.

Biochemistry

Pharmacology

mitochondria

Drp1

dynamin

structural biology

cryo-EM

GTPase

Revealing Molecular Adversaries of Human Health Using Advanced Imaging Technology

Varano, Ann Cameron

07 December 2018

Single particle electron microscopy (EM) allows us to examine the molecular world and gain insights into protein structures implicated in human disease. Visualizing the 3D architecture of the macromolecules can inform drug design and preventative care. While X-ray crystallography and NMR are able to resolve atomic structures, the methodology is better suited for smaller structures with limited flexibility. Single particle EM allows us analyze larger structures that have inherent flexibility. Protein structures can broadly be categorized as symmetry or asymmetric. There are computational advantages when analyzing symmetrical structures. Specifically, structural information can be extrapolated from fewer vantage points. Thus, symmetrical macromolecules are an advantageous for pioneering new methodologies in single particle EM. Rotavirus double layered particles (DLPs) are large macromolecular complexes that display icosahedral symmetry. Previous studies have led to a high resolution structure of transcriptionally inactive rotavirus frozen in time. However, to more fully understand rotavirus we need to examine the structure under transcriptionally active conditions. To expand our understanding, we first evaluated these viral assemblies using cryo-EM under active and inactive conditions. We found both internal and external structural differences. Based on these findings we sought to further our understanding of these nano-machines by developing a liquid cell environment to evaluate their dynamics over time. Our research not only developed a new methodology to evaluate active particles over time, we also found that the mobility of the DLPs were directly correlated to the level of transcriptional activity. When analyzing asymmetrical and flexible protein complexes previous studies have utilized methodologies to limit the proteins' conformational variability. While this does allow for a higher resolution structure, it limits our understanding to a specific orientation and compromises the biological insights. BRCA1 is an asymmetric protein containing a large flexible region and is important in the prevention of breast cancer. We utilize silicon nitride microchips with integrated wells and decorated with a lipid monolayer to capture and image BRCA1 complexes. This imaging platform minimizes heterogeneity and ensures the sample quality while not biasing confirmation. Thus, allowing for high resolution cryo-EM imaging of flexible native proteins. We were able to examine BRCA1 complexes from cells at both the primary and metastatic sites. Our ability to visualize these proteins in their native form provide insights into the variability of BRCA1 in disease progression. We found that BRCA1 complexes isolated from metastatic cells have additional density in the C-terminal domain. Our data suggests this density it due an interaction with p53. Overall, our methodologies highlight the power of single particle EM for studying protein complexes. Furthermore, our findings emphasize the importance of examining protein complexes in their native state. / PHD / Single particle electron microscopy (EM) allows us to examine the molecular world and gain insights into protein structures implicated in human disease. Visualizing the 3D architecture of macromolecules can inform drug design and preventative care. While X-ray crystallography and NMR are able to resolve atomic structures, the methodology is better suited for smaller structures with limited flexibility. Single particle EM allow us analyze larger structures that have inherent flexibility. Protein structures can broadly be categorized as symmetry or asymmetric. There are computational advantages when analyzing symmetrical structures. Specifically, structural information can be extrapolated from fewer vantage points. Thus, symmetrical macromolecules are an advantageous for pioneering new methodologies in single particle EM. Rotavirus double layered particles (DLPs) are large, highly symmetrical macromolecular complexes that represent an ideal model system for developing technology. Previous studies have led to a high resolution structure of inactive rotavirus DLP frozen in time. However, to more fully understand rotavirus we need to examine the structure under active conditions. To expand our understanding, we first evaluated these viral assemblies using cryo-EM under active and inactive conditions. We found structural differences. Based on these findings we sought to further our understanding of these nano-machines by developing a liquid cell environment to evaluate their dynamics over time. Our new methodology revealed new insights into the mobility of the DLPs. When analyzing asymmetrical and flexible protein complexes previous studies have utilized methodologies to limit the proteins’ movement. While this does allow for a higher resolution structure, it limits our understanding to a specific orientation and compromises the biological insights. BRCA1 is a highly flexible asymmetric protein implicated in the development of breast cancer. We utilize specialized microchips to capture and image BRCA1 complexes. This imaging platform ensures sample quality and allows for high resolution cryoEM imaging of flexible native proteins. We were able to examine BRCA1 complexes from cells at both the primary and metastatic sites. Our ability to visualize these proteins in their native form provide insights into the variability of BRCA1 in disease progression. Our data found that BRCA1 complexes isolated from metastatic cells are structurally different than those at the primary site. Overall, our methodologies highlight the power of single particle EM for studying protein complexes. Furthermore, our findings emphasize the importance of examining protein complexes in their native state.

cryo-EM

cryo chip

BRCA1

rotavirus

fibrocystin polyductin complex

Studies on the structure and function of Na?-pumping NADH-quinone oxidoreductase from Vibrio cholerae / コレラ菌Na?輸送性NADH-キノン酸化還元酵素の構造および機能に関する研究

Fukuda(Ishikawa), Moe

25 March 2024

京都大学 / 新制・課程博士 / 博士(農学) / 甲第25335号 / 農博第2601号 / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 三芳 秀人, 教授 白井 理, 教授 森 直樹 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Na+-NQR

inhibitor

cryo-EM

ubiquinone

bioenergetics

610

Insights into the structure of Lloviu cuevavirus nucleoprotein-RNA complex through cryo-EM / クライオ電子顕微鏡によるリョビュウイルスの核タンパク質-RNA複合体の構造観察

Hu, Shangfan

25 March 2024

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第25450号 / 生博第521号 / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 野田 岳志, 教授 朝長 啓造, 教授 鈴木 淳 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Filovirus

Lloviu virus

nucleocapsid

cryo-EM,

single-particle analysis

460

Regulation of transcription : structural studies of an RNA polymerase elongation complex bound to transcription factor NusA / Régulation de la transcription : études structurales du complexe d’élongation de l'ARN polymérase lié au facteur de transcription NusA

Guo, Xieyang

04 September 2018

La pause transcriptionnelle marquée par les ARN polymérases (RNAP) est un mécanisme clé pour réguler l'expression des gènes dans tous les règnes de la vie et est une condition préalable à la terminaison de la transcription. Le facteur de transcription bactérien essentiel NusA stimule à la fois la pause et la terminaison de la transcription, jouant ainsi un rôle central. Ici, je présente des reconstructions par cryo-microscopie électronique (cryo-EM) à une seule particule de NusA lié à des complexes d'élongation en présence et en absence d’ARN en épingle à cheveux dans le canal de sortie de l'ARN. Les structures révèlent quatre interactions entre NusA et RNAP qui suggèrent comment NusA stimule le repliement de l’ARN, la pause et la terminaison de la transcription. Un intermédiaire de translocation asymétrique de l'ARN et de l'ADN convertit le site actif de l'enzyme en un état inactif, fournissant une explication structurelle pour l'inhibition de la catalyse. La comparaison de RNAP à différentes étapes de la mise en pause donne un aperçu de la nature dynamique du processus et du rôle de NusA en tant que facteur de régulation. / Transcriptional pausing by RNA polymerases (RNAPs) is a key mechanism to regulate gene expression in all kingdoms of life and is a prerequisite for transcription termination. The essential bacterial transcription factor NusA stimulates both pausing and termination of transcription, thus playing a central role. Here, I present single-particle electron cryo-microscopy (cryo-EM) reconstructions of NusA bound to paused elongation complexes with and without a pause-enhancing hairpin in the RNA exit channel. The structures reveal four interactions between NusA and RNAP that suggest how NusA stimulates RNA folding, pausing, and termination. An asymmetric translocation intermediate of RNA and DNA converts the active site of the enzyme into an inactive state, providing a structural explanation for the inhibition of catalysis. Comparing RNAP at different stages of pausing provides insights on the dynamic nature of the process and the role of NusA as a regulatory factor.

Transcription

Structure de l'ARN polymérase

Pause transcriptionnelle

NusA

Cryo-EM

Transcription

RNA Polymerase structure

Transcriptional pausing

NusA

Cryo-EM

572.8

Etude structurale du complexe de remodelage de la chromatine NuRD et sa sous-unité MBD3 liée à l'ADN / Structural study of the chromatin remodeling complex NuRD and its DNA-binding subunit MBD3

Tabaroni, Rachel

12 December 2018

La régulation de la transcription est un processus dynamique faisant intervenir le recrutement de complexes protéiques impliqués dans le remodelage de la chromatine. Parmi eux, mon travail s’est focalisé sur le complexe NuRD (Nucleosome Remodeling and histone Deacetylation) et sa sous-unité de liaison à l’ADN CpG MBD3. Pour cela une approche de biologie structurale intégrative combinant la préparation biochimique, la caractérisation biophysique et l’étude structurale par cryo-EM et cristallographie aux rayons-X a été mise en place. Les caractérisations biophysiques de MBD3 ont permis de mettre en évidence son interaction avec un ADN non-modifié CpG et des cristaux diffractant jusqu’à 3.9 Å ont été obtenu. De plus la région désordonnée en aval du domaine de liaison a été identifiée et son impact dans la formation de complexe caractérisé. Des cristaux pour les différentes constructions en complexe avec l’ADN ont été obtenus et sont actuellement optimisés. Enfin l’optimisation de la purification et la préparation du complexe, ont permis la visualisation du complexe NuRD et mettent en avant pour la première fois une organisation en domaines du complexe. / Transcription regulation of chromatin is a very dynamic process regulated through the recruitment of chromatin-remodeling complexes. My work focuses on NuRD for Nucleosome remodeling and histones deacetylation complex a 1 MDa multi-subunit protein complex and its subunit MBD3 a CpG-binding protein and more precisely on an integrated biology approach of this molecular assembly and its interaction with DNA. It combines biochemical preparation, biophysical characterization, single particle cryo-eletron microscopy and x-ray crystallography. Biophysical analysis show that MBD domain of MBD3 interacts with unmodified CpG DNA, a crystal diffracting up to 3.9 Å were obtained. Moreover a C-terminal intrinsically disordered region of MBD3 were identified and despite is inherent disorder seems to increase the binding affinity of MBD3 for DNA. Crystals were obtained for both constructs in complex with DNA and are currently optimized.Cryo-EM study of NuRD complex allows us to develop and optimized purification and grids preparation for the visualization of the complex. The present results reveal a domain organization of the complex never identify before.

NuRD

MBD3

Cristallographie aux rayons-X

Cryo-EM

NuRD

MBD3

X-ray crystallography

Cryo-EM

Remodelling

572.8

571.4

Etude structure-fonction du complexe de remodelage de la chromatine NuRD / Structure-Function study of the chromatin remodelling complex NuRD

Torchy, Morgan

16 December 2014

Une approche de biologie structurale intégrative a été mise à profit pour l'étude de l’organisation structurale du complexe NuRD. Mon travail s'est focalisé essentiellement sur trois sous-unités du complexe: MBD3, RbAp46 et RbAp48. J'ai mis en place les protocoles de production et de purification de ces différentes sous-unités, et les ai caractérisé biophysiquement par diverses méthodes. Nous avons ensuite entrepris des études de liaisons sur des nucléosomes reconstitués au laboratoire. Pour MBD3, l'optimisation du complexe nous a permis d'obtenir des cristaux diffractant jusqu'à 7 A de résolution. Parallèlement, une reconstruction 3D préliminaire à partir de données de cryo-microscopie électronique a pu être obtenue à 25A de résolution. Pour RbAp46/48, nous avons pu montrer que ces protéines formaient un complexe stable avec le nucléosome, pavant la voie pour leur future étude structurale par cryo-microscopie électronique ou cristallographie aux rayons-X. / An integrative structural biology approach has been used to study the structural organization of the NuRD complex.My work focused especially on three subunits of this complex: MBD3, RbAp46 and RbAp48. I set up the preparation of the individual subunits and characterized them by various biophysical methods. We next carried out binding assays with homemade human nucleosomes. For MBD3, optimization of the complex led to crystals diffracting up to 7 Å. In parallel, a preliminary 3-D reconstruction at 25 Å resolution has been solved in cryo-EM. For RbAp46/48, crystal we were able to show that these proteins form stable complexes with the nucleosome, paving the way for future structural analysis by cryo-EM or X-ray crystallography.

Chromatine

NuRD

Nucléosome

Remodelage

Biochimie

Cristallographie

Cryo-EM

Chromatin

NuRD

Nucleosome

Remodelling

Biochemistry

Crystallography

Cryo-EM

572.4

572.8

Peptídeos bioativos do plasma de Acanthoscurria rondoniae. / Bioactives Peptides from Plasma of Acanthoscurria rondoniae.

Riciluca, Katie Cristina Takeuti

08 June 2016

Peptídeos antimicrobianos (AMP) são importantes componentes do sistema imune de todos os organismos vivos. No plasma de Acanthoscurria rondoniae isolamos 15 AMP com similaridade com a hemocianina. As sete subunidades da hemocianina foram sequenciadas e sua estrutura tridimensional determinada. A rondonina, processada a partir de uma enzima do plasma em condições ácidas apresentou melhor atividade em pH ácido, sinergismo com gomesina, não citotóxico, não interagiu com membranas artificiais lipídicas, protegeu as células da infecção por vírus humanos de RNA e seu mecanismo de ação em leveduras está associado com material genético. Nossos resultados nos ajudam a entender porque aracnídeos sobreviveram por um longo tempo na escala evolutiva. E como as doenças infecciosas estão entre as principais causas de morte da população humana torna-se vital investir na busca de substâncias naturais ou sintéticas que exibam atividades antimicrobianas específicas e, acima de tudo, que as exerçam através de mecanismos de ação alternativos daqueles dos antibióticos disponíveis. / Antimicrobial peptides (AMP) are important components of the immune system of all living organisms. In the plasma of Acanthoscurria rondoniae we isolated 15 AMP with similarity to hemocyanin. The seven subunits hemocyanin were sequenced and determined its three-dimensional structure. The rondonin, processed from a plasma enzyme under acidic conditions showed best activity at acid pH, synergism with gomesin, non-cytotoxic, does not interacted with lipid artificial membrane, protected the cells from infection by human virus RNA and its mechanism of action in yeast is associated with genetic material. Our results help us understand why arachnids have survived for a long time on the evolutionary scale. And how infectious diseases are among the leading causes of death in human population becomes vital to invest in the search for natural or synthetic substances that exhibit specific antimicrobial activities and, above all, that engage through alternative mechanisms of action of these antibiotics available.

Antiviral activity

Atividade antiviral

cryo-EM

cryo-EM

DNA-binding

Fragmentos de hemocianina

Hemocyanins fragments

Ligação com DNA

Rondonin

Rondonina

Transcriptoma

Transcriptome

Peptídeos bioativos do plasma de Acanthoscurria rondoniae. / Bioactives Peptides from Plasma of Acanthoscurria rondoniae.

Katie Cristina Takeuti Riciluca

08 June 2016

Peptídeos antimicrobianos (AMP) são importantes componentes do sistema imune de todos os organismos vivos. No plasma de Acanthoscurria rondoniae isolamos 15 AMP com similaridade com a hemocianina. As sete subunidades da hemocianina foram sequenciadas e sua estrutura tridimensional determinada. A rondonina, processada a partir de uma enzima do plasma em condições ácidas apresentou melhor atividade em pH ácido, sinergismo com gomesina, não citotóxico, não interagiu com membranas artificiais lipídicas, protegeu as células da infecção por vírus humanos de RNA e seu mecanismo de ação em leveduras está associado com material genético. Nossos resultados nos ajudam a entender porque aracnídeos sobreviveram por um longo tempo na escala evolutiva. E como as doenças infecciosas estão entre as principais causas de morte da população humana torna-se vital investir na busca de substâncias naturais ou sintéticas que exibam atividades antimicrobianas específicas e, acima de tudo, que as exerçam através de mecanismos de ação alternativos daqueles dos antibióticos disponíveis. / Antimicrobial peptides (AMP) are important components of the immune system of all living organisms. In the plasma of Acanthoscurria rondoniae we isolated 15 AMP with similarity to hemocyanin. The seven subunits hemocyanin were sequenced and determined its three-dimensional structure. The rondonin, processed from a plasma enzyme under acidic conditions showed best activity at acid pH, synergism with gomesin, non-cytotoxic, does not interacted with lipid artificial membrane, protected the cells from infection by human virus RNA and its mechanism of action in yeast is associated with genetic material. Our results help us understand why arachnids have survived for a long time on the evolutionary scale. And how infectious diseases are among the leading causes of death in human population becomes vital to invest in the search for natural or synthetic substances that exhibit specific antimicrobial activities and, above all, that engage through alternative mechanisms of action of these antibiotics available.

Atividade antiviral

cryo-EM

Fragmentos de hemocianina

Ligação com DNA

Rondonina

Transcriptoma

Antiviral activity

cryo-EM

DNA-binding

Hemocyanins fragments

Rondonin

Transcriptome