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Analysis of the Arabidopsis Polyadenylation Factors PAP1, CstF64 and CstF77 and their characteristic inter-relationshipBandyopadhyay, Amrita 01 January 2009 (has links)
3’-end modification by polyadenylation is a ubiquitous feature of almost all eukaryotic mRNA species and is catalyzed by a consortium of enzymes, the polyadenylation factors. Poly(A) polymerase (PAP), the enzyme catalyzing the addition of adenosine residues during the polyadenylation stage, exists in four isoforms within Arabidopsis. In silico and yeast two-hybrid studies showed that PAP1 has unique expression and interaction pattern in Arabidopsis, suggesting non-canonical functions of PAP1. Its exclusive interaction with PAP4 has not been reported in other living systems until now and hints at a difference in polyadenylation in plants with respect to mammals and yeast. Cleavage Stimulation Factor (CstF), a heterotrimeric complex of the polyadenylation factors CstF50, CstF64 and CstF77, plays a role largely in cleavage of pre-mRNA. This study highlights some aspects of the Arabidopsis homologs of CstF64 and CstF77, central to various cellular processes other than nuclear polyadenylation. In silico studies showed an elevated expression of CstF64 in the pollen while that of CstF77 remained fairly low. Yeast two-hybrid assays indicated a novel kind of interaction of CstF64 with Fip1(V). It is also speculated from sub-cellular localization techniques by agroinfiltration in tobacco leaves that CstF64 localizes in the cytoplasm and CstF77 in the nucleus, as found for the orthologs of CstF77 in other systems.
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Partenaires et rôle dans le cycle viral des différentes formes de la protéine RT du Cucurbit aphid-borne yellows virus / Partners and role in viral cycle of the different forms of Cucurbit aphid-borne yellows virus RT proteinBoissinot, Sylvaine 15 February 2013 (has links)
Les polérovirus infectent de nombreuses plantes d’intérêt économique telles que la pomme de terre, la betterave à sucre et les cucurbitacées. Ces virus icosaédriques renferment un ARN simple brin et leur capside est constituée d’une protéine majeure (CP) et d’un composant mineur (RT*) localisé à la surface des virions. Ces virus sont restreints aux cellules du phloème dans lesquelles ils se multiplient et se déplacent. Les protéines CP et RT sont essentielles à la dissémination du virus par le puceron vecteur et à son mouvement dans la plante. L’objectif de cette étude a consisté à identifier dans les cellules du phloème, les protéines associées aux virions susceptibles d’intervenir dans le cycle viral en criblant une banque d’ADNc de cellules compagnes (CC) d’A. thaliana avec les protéines de structure ou des domaines protéiques du CABYV. Quatre gènes codant pour une protéine Heat Shock (HSP), la profiline 3 (PRF3) une glysosyl hydrolase ; et la protéine « Response to low sulfur 3 » ont été identifiés. Tous ces gènes candidats interagissent avec le domaine RTC-ter du CABYV et avec la protéine RT* pour la protéine HSP. En plus de ces gènes candidats, je me suis intéressée à la protéine ALY, identifiée au laboratoire, au cours du criblage d’une banque d’ADNc de puceron entier avec les deux protéines de structure du Turnip yellows virus (un autre polérovirus). Cette protéine possède quatre orthologues chez Arabidopsis susceptibles d’être impliquées dans le mécanisme de gene silencing mis en place contre le Tomato Bushy Stunt Virus. Les protéines ALY sont donc des candidats intéressants et j’ai montré une interaction entre les protéines de structure du CABYV et du TuYV et les quatre orthologues d’Arabidopsis. L’implication de ces gènes candidats n’a pas pu être confirmée à ce jour dans des mutants knock-out d’arabidopsis. Les résultats complexes obtenus pour le candidat PRF3 au cours des analyses de validation fonctionnelle, m’a conduit à étudier l’interaction entre ce candidat et le domaine RTC-ter du CABYV in planta par FLIM mais aucune interaction n’a pu être confirmée à ce jour. Tous les candidats isolés lors du criblage de la banque d’ADNc de CC interagissant avec le domaine RTC-ter du CABYV, ce travail m’a conduit à analyser le rôle dans le cycle viral de ce domaine et de la protéine RT (sous sa forme complète ou dépourvue du domaine RTC-ter), en étudiant l’accumulation de ces mutants dans les plantes et le clivage de la protéine RT. Tout d’abord, afin de localiser précisément le site de clivage de la protéine RT, des mutants ponctuels dans la zone de clivage ont été réalisés ce qui a permis de montrer que la structure secondaire de la protéine est importante pour son clivage. Puis, afin d’analyser le rôle du domaine RTC-ter dans le cycle viral, j’ai obtenu par délétion, un mutant n’exprimant plus ce domaine. Ce mutant synthétise uniquement la protéine RT tronquée, forme des particules virales semblables au virus sauvage et est transmissible par puceron. Par contre, de façon surprenante, ce mutant est incapable d’envahir les feuilles non-inoculées d’une plante. Ce résultat suggère que les deux formes de la protéine RT (complète et tronquée) sont indispensables au mouvement à longue distance du virus et nous proposons un modèle dans lequel le domaine C-terminal de la protéine RT agit en trans sur la particule virale pour promouvoir le mouvement du CABYV à longue distance. / Poleroviruses infect a wide range of cultivated plants such as potatoes, sugar beet and plants of Cucurbitaceae family. These viruses are restricted to phloem tissue where they replicate in nucleated cells and translocate over long distances through sieve elements. Polerovirus capsid is composed of the major coat protein (CP) and of a minor component referred to as the readthrough (RT*) protein and exposed at the outside of the particles. CP and RT proteins are essential for virus movement and transmission by aphids. The aim of this study is to identify phloem proteins interacting with viral proteins and potentially involved in viral cycle, by screening an A. thaliana companion cell (CC) cDNA library with structural proteins or protein domains of CABYV. Four genes encoding for a heat shock protein (HSP), a profilin (PRF3), a glycosyl hydrolase and the protein ”Response to low sulfur ” (LSU3) were identified and interact with the C-terminal part of the RT protein (RTC‑ter) and with the RT* protein for the HSP. An additional gene encoding for the protein ALY, identified in the laboratory, by screening an aphid cDNA library with structural proteins of the Turnip yellows virus (another polerovirus) was studied. This protein has four orthologues in Arabidopsis, involved in the gene silencing mechanism against Tomato Bushy Stunt Virus. Here we show that CABYV and TuYV structural proteins interact with the four orthologues of Arabidopsis. Involvement of these candidate genes was not confirmed in Arabidopsis knock-out mutants. In functional experiments, ambiguous results were obtained with PRF3 arabidopsis mutants, and this lead me to study the interaction between PRF3 protein CABYV RT c-ter domain by FLIM, but no interaction was found so far. As all candidat interact with the RTC-ter domain, we studied more precisely the role of this domain in the viral cycle and the role of the complete RT protein. We studied the in vivo RT protein processing and its consequences on systemic movement of CABYV mutants. Using a collection of point mutations introduced in the central domain of the CABYV RT protein, we approached the site of the RT processing and proposed that this process is affected by the secondary structure around the cleavage site. We also reported for the first time the generation of a polerovirus mutant able to synthesize only the RT* protein and to incorporate it into the particle. This mutant was unable to move systemically. Conversely another mutant producing a full-length RT protein impaired in correct processing and incorporating a shorter version of the RT* protein showed very weak systemic infection. These data are strongly in favor of a role of both RT proteins in efficient CABYV movement. An inefficient virus transport was still maintained in the absence of RT proteins suggesting an RT-independent movement pathway. Based on these results, we propose a model for CABYV long-distance transport in which the complete RT protein, or its C-terminal part, acts in trans on wild-type virions to promote their efficient long-distance transport.
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Analises estruturais e estudos das interações das proteinas INT6 e NY-REN-21 / Structural analysis and interaction studies of the INT6 and NY-REN-sa proteinsCarneiro, Flavia Raquel Gonçalves 30 May 2006 (has links)
Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-06T21:20:48Z (GMT). No. of bitstreams: 1
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Previous issue date: 2006 / Resumo: O gene que codifica a proteína INT6 corresponde a um dos sítios de inserção do vírus de tumor de glândula mamária em camundongo (MMTV). Esta inserção pode levar à formação de proteínas truncadas sem a porção C-terminal e sem o domínio PCI, descrito como domínio de interação entre proteínas. Neste trabalho, realizamos 3 triagens para a identificação dos ligantes protéicos da proteína humana INT6 (hINT6) pelo método do duplo-híbrido de levedura. Embora interações específicas tenham sido identificadas, não foi possível a confirmação in vitro das novas interações isoladas. Para análises estruturais, usamos a proteína INT6 de Arabidopsis thaliana (AtINT6), visto que a proteína humana expressou em níveis muito baixos na fração solúvel do extrato de Escherichia coli. Análises de dicroísmo circular revelaram que a proteína AtINT6 é rica em estrutura do tipo a-hélice. A região que compreende os aminoácidos 172 a 415, incluindo o domínio PCI, foi identificada por proteólise parcial e espectrometria de massas como um domínio estrutural que após sua clonagem apresentou alto nível de expressão, solubilidade e estabilidade. Este trabalho envolveu também a caracterização da NY-REN-21, que foi isolada pelo duplo-híbrido para a identificação dos ligantes protéicos da proteína hINT6 e representa uma possível ortóloga para o fator de transcrição ZFP38 de camundongo. Ambas as proteínas apresentam um domínio de dimerização (SCAN), 7 domínios dedos de zinco tipo C2H2 na porção C-terminal e uma região central predita como desestruturada. A proteína NY-REN-21 se mostrou parcialmente desenovelada e sua estrutura secundária é afetada pela incubação com EDTA. Ensaios de proteólise limitada, dicroísmo circular e fluorescência confirmaram que sua região central é intrinsicamente desordenada, além de apresentar mobilidade anômala em gel de SDS-PAGE e representa uma fração flexível da proteína. Não foi possível a caracterização da região dos dedos de zinco, pois esta região se mostrou altamente instável. O domínio SCAN da NY-REN-21 é capaz de formar homodímeros e heterodímeros com a proteína SCAND1. Esta interação pode representar uma forma de regulação da atividade da proteína NY-REN-21 / Abstract: The INT6 gene was reported as a frequent genome integration site of Mouse Mammary Tumor Virus (MMTV). This integration may result in truncated forms of INT6 protein lacking its C-terminal region and the PCI domain. It has been reported that this domain is involved in protein-protein interaction. We performed 3 yeast two-hybrid screens in order to identify the human INT6 (hINT6) interaction partners. Although two previously described specific interactions were identified in these screens, it was not possible to confirm the new interactions by in vitro binding assays. The Arabidopis thalina INT6 ortholog (AtINT6) was used for structural analyses, since the hINT6 was insoluble following expression in Escherichia coli. AtINT6 showed CD spectra with high helical content. The region comprising amino acids 172 to 415 forms a compact protease resistant domain as determined by limited proteolysis and mass spectrometry analyses. This domain, comprising the PCI domain sequence, was cloned and expressed in E. coli and showed high solubility and stability. This recombinant protein has the potential to serve as a model protein for three-dimensional structure determination of the PCI domain. We also studied the NY-REN-21 protein, which was isolated as a potential hINT6 interaction partner and represents a putative ortholog of the mouse ZFP38 transcriptional factor. Both proteins are C2H2 type multifinger proteins, containing a conserved oligomerization domain (SCAN) in the N-terminal region and a predicted disordered central region. Our analyses showed that full-length NY-REN-21 is partially unfolded and its secondary structure content is affected by incubation with EDTA. The central region of NY-REN-21 shows an aberrant mobility on SDS-PAGE and is intrinsically unstructured as reveled by circular dichroism, fluorescence and limited proteolysis. The zinc finger region was not characterized because of its unstable nature. The recombinant SCAN domain of NY-REN-21 can form homodimers and heterodimers with the SCAND1 protein. This interaction may represent a novel regulatory mechanism of NY-REN-21 activity / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular
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Analise funcional da proteina humana codificada pelol novo gene de resposta a interferon ISG95 / Functional analysis of the human protein encoded by the new interferon stimulated gene ISG95Vaz, Thais Haline 14 August 2008 (has links)
Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-11T17:37:36Z (GMT). No. of bitstreams: 1
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Previous issue date: 2008 / Resumo: A resposta individual das células está na base da resistência do organismo à infecção viral. O principal mecanismo de resistência envolve a participação de inúmeros genes da via de sinalização dos interferons. Vários estudos vêm sendo conduzidos em larga escala para identificar genes que respondem aos mais variados tratamentos, assim como clusters gênicos relacionados a determinadas enfermidades, como a leucemia. A função do produto de muitos destes genes ainda não foi caracterizada. Numa ampla revisão destes artigos identificamos a proteína KIAA0082/ISG95 respondendo a interferon, à infecção pelo vírus da hepatite C (HCV), ao tratamento celular com oligodeoxinucleotídeos CpG, fazendo parte de um cluster de genes relacionados à leucemia e sendo super-expressa em linfócitos T ativados. Embora não possua função conhecida, esta proteína apresenta quatro domínios que indicam uma possível atividade relacionada ao metabolismo de RNA. Neste trabalho demonstramos que o promotor do gene ISG95 responde à estimulação por interferon num sistema repórter em células Vero. As atividades bioquímicas de ISG95 foram determinadas usando a proteína recombinante expressa em células de inseto Sf9. ISG95 interage com RNA e com S-adenosilmetionina, possuindo também atividade de metiltransferase in vitro. Ensaios de localização sub-celular demonstraram sua distribuição nuclear. Além disso, através do método duplo-híbrido de levedura e de ensaio de co-imunoprecipitação, foi possível identificar sua interação com o domínio C-terminal (CTD) da RNA polimerase II, o que é consistente com sua localização nuclear e com a função predita para o domínio WW localizado na extremidade C-terminal de ISG95. Os resultados indicam que ISG95 é parte da via de resposta a interferon e tem função associada possivelmente a eventos de processamento de prémRNA mediados pelo domínio CTD da RNA polimerase II / Abstract: A major mechanism of cellular resistance to viral invasion involves genes from the interferon signaling pathway, called ISGs (interferon stimulated genes). Global transcriptional profiling studies have linked increased expression of ISG95 (KIAA0082) to response to interferon treatment and to viral infection, suggesting that it may be part of the cellular defense against viral replication. In this work, we shown that the ISG95 promoter can drive interferoninduced transcription of a reporter gene in Vero cell cultures. The biochemical functions of ISG95 were assessed using recombinant protein. ISG95 shows RNA- and S-adenosyl-methionine binding and protein methyltransferase activity in vitro. ISG95 interacts with the C-terminal domain of RNA polymerase II, which is consistent with its nuclear localization and with the predicted function of the WW domain found in the C-terminal region of ISG95. The results presented in this work indicate that ISG95 is part of the interferon response pathway and functions in the pre-mRNA processing events mediated by the C-terminal domain of the RNA polymerase II / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular
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Estudos das interações da septina 4 humana / Study of Human Septin 4 interactionsNayara Cavalcante Silva 09 September 2009 (has links)
Septinas são proteínas ligantes a GTP encontradas desde fungos até metazoários. A primeira função identificada para septinas foi o seu papel central na organização e dinâmica do septo de divisão de leveduras. Uma das características marcantes é que septinas se organizam em heterofilamentos de 7 a 9 nm de espessura que foram purificados de diversos organismos tais como Saccharomyces cerevisiae, Drosophila e cérebro de camundongos. Hoje se sabe que septinas não estão envolvidas apenas nos processos de divisão celular, mas em uma variedade de processos como tráfico de vesículas, exocitose, interação com proteínas do citoesqueleto e com a membrana plasmática, o que resulta em alterações da morfologia celular. Neste trabalho foram desenvolvidos estudos da septina 4 humana (SEPT4) nos quais foi realizado a expressão e purificação da SEPT4 pelo uso do sistema de expressão heteróloga em E. coli e em células de insetos (Sf-9) via baculovírus. A tentativa de expressão usando o vetor pETTEV em E.coli não obteve sucesso, pois a proteína não foi expressa na forma solúvel. A construção do baculovírus recombinante AcSept4 e expressão da SEPT4 nas células de insetos foi realizada com êxito, mas o processo de purificação não foi satisfatório. Com o intuito de obter informações sobre possíveis proteínas que interagem com a SEPT4 e conseqüentemente sobre as funções desempenhadas por ela na célula, a SEPT4 foi utilizada como isca para ensaios de interação proteína-proteína pela técnica de duplo híbrido. Para isso, o gene da SEPT4 foi clonado fusionado ao domínio de ligação ao DNA Lex-A. A realização do ensaio de duplo híbrido com a proteína completa não foi possível, pois a mesma provocou a auto ativação do sistema, por isso uma nova construção foi realizada com a região GTPase e C-terminal SEPT4GC (124-478) como isca. Dentre as interações identificadas, foram encontradas apenas septinas do grupo II (SEPT6, SEPT8, SEPT10 e SEPT11) e quatro novas interações, que ainda precisam ser confirmadas. Por outro lado, uma interação já descrita na literatura envolve a proteína α-sinucleína, que é uma proteína abundantemente expressa no cérebro e associada à doença de Parkinson. O foco do estudo dessa interação foi realizar ensaios com os diferentes domínios da SEPT4 para comprovar uma interação direta e com isso tentar mapear o sítio de interação com a α-sinucleína. Os resultados obtidos pela ressonância plasmônica de superfície (SPR) indicam que o domínio C-terminal participa da interação com baixa afinidade (K,D=390 µM) e sugerem que o domínio GTPase também pode estar envolvido. Já os dados obtidos com os experimentos de RMN e anisotropia de fluorescência mostram indícios que a interação é dependente da conformação da α-sinucleína por que a interação aconteceria com maior afinidade quando a α-sinucleína está na presença de SDS. / Septins are a family of GTP binding proteins found in a great diversity of organisms. These proteins have been identified as having a central role in septum organization during yeast division. Septins are organized into heterofilaments which are 7 to 9 nm wide and these have been purified from yeast, Drosophila and mice brain. Septins are not only required for cell division, but seem to play a role also in vesicle trafficking and in the formation of diffusion barriers within cells, since they interact with cytoskeleton proteins and the plasma membrane causing changes in cell morphology. In the present work, the aim was investigate human Septin 4 (SEPT4), a septin highly expressed in the brain. One objective of this work was to find a suitable expression system and purification method for SEPT4. The protein was expressed in both E.coli and insect cells (Sf-9). Expression in E. coli with the vector pETTEV was unsuccessful because the protein was insoluble. Expression in insect cells using the recombinant baculovirus AcSept4, was obtained successfully, but the purification was difficult. Important information concerning SEPT4 function might be acquired, if interactions partners involved in cellular process were identified. With this goal in mind, a yeast two hybrid assays were performed. The sept4 gene was fused to the Lex-A DNA binding domain and used as bait in the yeast two hybrid essays. However, full length SEPT4 showed autonomous activation of reporter genes. A second construct was prepared including only GTPase domain and the carboxy terminus domain, (residues 124 to 478) and the screen of interactions were carried out only with SEPT4GC. All of the group II septins (SEPT6, SEPT8, SEPT10 and SEPT11) were identified together with four new interactions. The latter still need be confirmed. In addition, another interaction already described in the literature is between SEPT4 and α-synuclein, which is a protein highly expressed in brain and related to Parkinson\'s disease. Different spectroscopic methods and SPR were used to identify which domain of SEPT4 interacts directly with α-synuclein and in which region. The surface plasmon resonance (SPR) results indicate that the carboxy terminus participates in the interaction with low affinity (KD = 390 µM) and suggests that the GTPase domain may also be involved. The results obtained by fluorescence anisotropy and NMR studies provide evidence that the interaction is dependent on the α-synuclein conformation, because the affinity of SEPT4 and α-synuclein seemed to be higher in the presence of SDS.
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Fonction des protéines de l'enveloppe et de la périphérie nucléaire sur l'organisation du noyau chez Arabidopsis thaliana / Function of envelope and nuclear periphery proteins on the organization of Arabidopsis thaliana nucleiVoisin, Maxime 07 December 2017 (has links)
Le noyau est une innovation évolutive majeure caractéristique des organismes eucaryotes. Ces dernières années de nombreux travaux se sont intéressés à l’organisation de la chromatine dans l’espace nucléaire lors de l’interphase. Les protéines associées à la périphérie nucléaire ou ancrées dans la membrane nucléaire interne ont suscité un intérêt majeur due à leur contribution dans l’organisation spatiale de la chromatine. Chez les animaux, les lamines qui forment des filaments à la périphérie nucléaire et le complexe LINC, un complexe protéique reliant la membrane externe et interne du noyau sont connues pour interagir avec la chromatine, influencer l’organisation de cette dernière et moduler la régulation transcriptionnelle. Chez la plante modèle Arabidopsis thaliana utilisée dans ce travail, le complexe LINC est conservé, par contre les lamines ne le sont pas et seraient remplacées par d’autres acteurs spécifiques du règne végétal. Le travail détaillé dans ce manuscrit porte sur la mise en évidence d’un nouveau réseau d’interaction protéique localisé à la périphérie nucléaire et sur l’impact de ces protéines dans la morphologie du noyau et l’organisation de la chromatine. Mes travaux se sont concentrés sur les protéines à domaine SUN, l’une des composantes du complexe LINC et sur les protéines CRWN et KAKU4 présentes à la périphérie du noyau. Des cribles double hybride chez la levure m’ont permis d’identifier 24 partenaires protéiques potentiels dont plus d’un tiers sont des facteurs de transcription L’étude plus précise du facteur de transcription MaMYB pour lequel nous avons créé un allèle nul par la méthode CRISPR montre qu’il joue un rôle plus spécifique dans la formation des racines. L’étude de mutants combinatoires pour les gènes SUN, CRWN et KAKU4 montre des anomalies développementales notamment des tissus reproductifs. Enfin, une étude plus détaillée de la protéine KAKU4 suggère sa participation au maintien de la morphologie du noyau et au rapprochement de l’hétérochromatine vers la périphérie nucléaire. En résumé, mes travaux ont mis en évidence l’existence d’un réseau de facteurs de transcription recrutés à la périphérie nucléaire par les protéines SUN, CRWN et KAKU4. Ce réseau d’interaction protéine-protéine participerait à un mécanisme de séquestration de certains facteurs de transcription et/ou d'un rapprochement à la périphérie nucléaire de certains domaines de chromatine afin d’activer ou de réprimer leur transcription. / The nucleus is a major evolutionary innovation characteristic of eukaryotic organisms. In recent years, numerous studies have focused on the organization of chromatin in nuclear space during interphase. Proteins associated with the nuclear periphery or anchored in the inner nuclear membrane have been particularly studied for their contribution to the spatial organization of chromatin. In animals, the lamina that forms filaments at the nuclear periphery and the LINC complex, a protein complex linking the outer and inner membrane of the nucleus, are known to interact with chromatin, to influence its organization and to modulate transcriptional regulation. In the model plant Arabidopsis thaliana used in this work, the LINC complex is conserved, but not the lamina constituents, which are replaced by other specific actors of the plant kingdom. The work detailed in this manuscript identified a new protein interaction network located on the nuclear periphery and studied the impact of these proteins on nuclear morphology and chromatin organization. My work focused on SUN-domain proteins, one of the components of the LINC complex, and on the CRWN and KAKU4 proteins at the periphery of the nucleus. Double hybrid screens in yeast allowed me to identify 24 potential protein partners, more than a third of which are transcription factors. The more precise study of the transcription factor MaMYB for which we created a null allele using the CRISPR method, shows that it plays a more specific role in root formation. The study of mutant combinations for SUN, CRWN and KAKU4 genes reveals developmental abnormalities, particularly in reproductive tissue. Finally, a more detailed study of the role of the KAKU4 protein suggests that it contributes to the morphology of the nucleus in maintaining heterochromatin at the nuclear periphery. In summary, we propose the existence of a transcription factor network recruited to the nuclear periphery by SUN, CRWN and KAKU4 proteins. This protein-protein interaction network would participate in the sequestration of certain transcription factors and/or the localization of certain chromatin domains to the nuclear periphery in order to activate or suppress their transcription.
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Using the Yeast Two-Hybrid System to Determine the Function of Parkin E3 Ubiquitin LigaseNguyen, Vanessa 01 December 2014 (has links)
Parkin is a cytosolic E3 ubiquitin ligase that is recruited to the mitochondria during cellular stress and has been suggested to be involved in a variety of biological processes such as mitophagy. The recruitment of Parkin (PARK2) to the mitochondria is dependent upon the kinase activity and the accumulation of PINK1 on damaged mitochondria. Mutations in either PINK1 or Parkin genes disrupt this protective pathway and lead to the accumulation of damaged mitochondria. From a clinical standpoint, mutations in the PARK2 gene have been associated with the progression and onset of autosomal recessive juvenile parkinsonism. Without the presence of a quality control system such as that of the PINK1/Parkin pathway, the accumulation of damaged mitochondria could lead to increased levels of oxidative stress, a decrease in ATP, and the progression towards cellular death. However, many of the details regarding the mechanism of Parkin-mediated ubiquitination and its involvement in mitophagy are not fully established. The intent of this thesis is to further explore the function of Parkin by utilizing the yeast-two hybrid system to identify novel Parkin interactors/substrates. A HeLa (cervical cell carcinoma) cDNA library was screened using Parkin124-465 as the "bait" protein. From this screening, six positive Parkin interactors were isolated and characterized. Using this approach it is possible to gain a better understanding of the function of Parkin in regulating cellular processes such as mitophagy.
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Interactions Between the Organellar Pol1A, Pol1B, and Twinkle DNA Replication Proteins and Their Role in Plant Organelle DNA ReplicationMorley, Stewart Anthony 01 March 2019 (has links)
Plants maintain organelle genomes that are descended from ancient microbes. Ages ago, these ancient microbes were engulfed by larger cells, beginning a process of co-evolution we now call the endo-symbiotic theory. Over time, DNA from the engulfed microbe was transferred to the genome of the larger engulfing cell, eventually losing the ability to be free-living, and establishing a permanent residency in the larger cell. Similarly, the larger cell came to rely so much on the microbe it had engulfed, that it too lost its ability to survive without it. Thus, mitochondria and plastids were born. Nearly all multicellular eukaryotes possess mitochondria; however, different evolutionary pressures have created drastically different genomes in plants versus animals. For one, animals have very compact, efficient mitochondrial genomes, with about 97% of the DNA coding for genes. These genomes are very consistent in size across different animal species. Plants, on the other hand, have mitochondrial genomes 10 to more than 100 times as large as animal mitochondrial genomes. Plants also use a variety of mechanisms to replicate and maintain their DNA. Central to these mechanisms are nuclear-encoded, organelle targeted replication proteins. To date, there are two DNA polymerases that have been identified in plant mitochondria and chloroplasts, Pol1A and Pol1B. There is also a DNA helicase-primase that localizes to mitochondria and chloroplasts called Twinkle, which has similarities to the gp4 protein from T7 phage. In this dissertation, we discuss the roles of the polymerases and the effects of mutating the Pol1A and Pol1B genes respectively. We show that organelle genome copy number decreases slightly and over time but with little effect on plant development. We also detail the interactions between Twinkle and Pol1A or Pol1B. Plants possess the same organellar proteins found in animal mitochondria, which are homologs to T7 phage DNA replication proteins. We show that similar to animals and some phage, plants utilize the same proteins in similar interactions to form the basis of a DNA replisome. However, we also show that plants mutated for Twinkle protein show no discernable growth defects, suggesting there are alternative replication mechanisms available to plant mitochondria that are not accessible in animals.
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Cysteine residues of the mammalian GET receptor: Essential for tail-anchored protein insertion?Schaefer, Moritz 30 May 2017 (has links)
No description available.
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Analyse structurale et fonctionnelle de la sous-unité SKP1 du complexe SCF (Skp1-Cullin-Fbox) chez le riz (Oryza sativa) / Structural and functional analysis of the SKP1 subunit of SCF complex (Skp1-Cullin-Fboxes) in rice (Oryza sativa)Kahloul, Senda 18 December 2012 (has links)
Chez les eucaryotes, la voie de protéolyse Ub/ protéasome 26S est responsable de la dégradation sélective de la plupart des protéines intracellulaires. Cette dégradation par le protéasome 26S est initiée par une polyubiquitination de la protéine réalisée grâce à l’action d’une cascade enzymatique impliquant 3 types d'enzymes nommées « ubiquitin-activating enzyme » (E1), « ubiquitin-conjugating enzyme » (E2) et « ubiquitin-protein ligase » (E3). Il existe différentes classes d’ubiquitines ligases (E3), parmi lesquelles la plus connue est le complexe SCF (Skp1-Cullin-F-box). La protéine SKP1 fixe à la fois la Culline et la F-box qui va reconnaitre spécifiquement la protéine cible. Contrairement aux protistes, les champignons et certains vertébrés qui possèdent un unique gène SKP1 fonctionnel, de nombreux animaux et espèces de plantes présentent plusieurs SKP1 homologues. Vingt et un et trente deux gènes SKP1 ont été décrits respectivement chez Arabidopsis thaliana et Oryza sativa. En dépit de l’importance du complexe SCF, chez le riz, peu de travaux décrivent les interactions entre les dizaines de protéines « SKP1-like » et les centaines de protéines F-box. Dans un premier temps, nous avons collecté et analysé les séquences de 288 gènes « SKP1-like » appartenant à 17 espèces, dont la mousse Physcomitrella patens, cinq monocotylédones et 11 eudicotylédones. Les analyses structurales et phylogénétiques de ces gènes indiquent qu’ils peuvent être divisés en différentes sous-familles. Nos analyses ont montré qu’OSK1 et OSK20 chez le riz constituent une classe de gènes SKP1 à intron unique conservé. Dans un deuxième temps, nous avons étudié le profil d’expression des gènes « SKP1-like » chez le riz. Notre investigation sur le nombre d’EST a montré que les gènes OSK1 et OSK20 sont les plus largement représentés dans les bases de données EST publiques. La méta-analyse de l’expression des gènes « SKP1-like » chez le riz, indique que les gènes OSK présentent des profils d'expression hétérogènes selon les tissus et les conditions physiologiques. Les résultats des intearctions protéine-protéine en double hybride ont révélé que les protéines OSK présentent différentes capacités d’interactions avec les protéines F-box. Cependant, OSK1 et OSK20 semblent interagir avec la plupart des protéines F-box testées. Les études de localisation subcellulaire ont indiqué que OSK1 et OSK20 sont des protéines nucléaires et cytosoliques. En se basant sur les divers résultats obtenus dans ce travail, nous pouvons suggérer que chez le riz, les gènes OSK1 et OSK20 sont fonctionnellement équivalents aux gènes ASK1 et ASK2 chez Arabidopsis thaliana. Nous pouvons également proposer les équivalents de ces gènes chez les autres espèces végétales dont le génome a été séquencé. / In eukaryotes, the ubiquitin Ub/26S proteasome pathway is responsible for the selective degradation of most intracellular proteins. This cellular process is initiated by protein polyubiquitination mediated by a three-step cascade involving: an ubiquitin-activating enzyme (E1), an ubiquitin-conjugating enzyme (E2) and an ubiquitin-protein ligase (E3). The E3 ubiquitin ligases contain several classes, among which the best-known are Skp1-Cullin-F-box (SCF) complexes. The SKP1 protein binds both Cullin and F-box which recognizes specifically the target proteins. Whereas protists, fungi and some vertebrates have a single functional SKP1 gene, many animal and plant species possess multiple SKP1 homologues. Twenty one and thirty-two SKP1-related genes have been described respectively in the Arabidopsis and Oryza sativa genome. Despite the importance of the SCF complex, there have been a few reports of systematic surveys of interactions between the dozens of SKP1-like proteins and the hundreds of F-box proteins in rice. In a first step, we retrieved and analyzed 288 SKP1-like genes belonging to 17 species including the moss Physcomitrella patens, five monocots and 11 eudicots. Structural and phylogenetic analysis of rice OSK genes and other plant SKP1-like genes have indicated that the different members of the plant SKP1 can be split into different subfamily. Our analyses indicated that OSK1 and OSK20 belong to a class of SKP1 genes that contain one intron at a conserved position. In a second step, we studied expression profiles of the rice Skp1-like genes. Our EST survey indicated that OSK1 and OSK20 are the most widely represented genes in public EST databases. Meta-analysis of the expression of rice SKP1-like genes indicated that OSK genes exhibit an expression profile that was heterogeneous in terms of tissues, conditions and overall intensity. Yeast two-hybrid results revealed that OSK proteins display a differing ability to interact with F-box proteins. However, OSK1 and OSK20 seemed to interact with most F-box proteins tested. Subcellular localization studies indicated that OSK1 and OSK20 are nuclear and cytosolic proteins. Based on the results obtained in this study, we can suggest that rice OSK1 and OSK20 are likely to have similar functions as do the Arabidopsis ASK1 and ASK2 genes. Similarly, we suggest a list of functional equivalent in the other sequenced plant genomes.
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