Cell biological studies of the transcription elongation factor TFIIS

Smith, Abigail J.

January 2001

No description available.

571

Cajal bodies

Transport U2 snRNA do Cajalových tělísek / U2 snRNA targeting to Cajal bodies

Roithová, Adriana

January 2014

In the cell we can find a lot of small noncoding RNAs, which are important for many processes. Among those RNAs are small nuclear RNA uridin rich, which with proteins create U snRNP.These particles play important role in pre-mRNA splicing. In this process are noncoding sequences (introns) removed and coding sequences (exons) are joined. It is catalyzed by spliceosome. The core of this spliceosome is created by U1, U2, U4, U5 and U6 snRNP. They are essential for this process. Some steps of U snRNP biogenesis proceed in nuclear structures called Cajal bodies (CB). In my thesis I focused on factors, which are important for targeting U snRNA into CB. I used U2 snRNA like a model. With the aid of microinjection of fluorescently labeled U2 snRNA mutants I found, that the Sm binding site on U2 snRNA is essential for targeting to CB. Knock down of Sm B/B'showed us, that Sm proteins are necessary for transport U2 snRNA to CB. Sm proteins are formed on U2 snRNA by SMN complex. Deletion of SMN binding site on U2 snRNA had the same inhibition effect. From these results we can see, that Sm proteins and SMN complex are important for U2 snRNA biogenesis espacially for targeting into CB. Key words: U snRNP, Cajal body, U snRNA, cell nucleus

Etude du rôle des protéines SMN et ICln dans la maturation et la production des snRNPs du Splicéosome / Functional analysis of the role of the SMN and ICln proteins in the maturation and production of the spliceosomal snRNPs

Barbarossa, Adrien

19 December 2012

Les petites particules ribonucléoprotéiques nucléaires (snRNPs) sont les composants majeurs du splicéosome, la machinerie responsable de l'épissage des pré-messagers. La biogenèse des snRNPs est un processus complexe qui fait intervenir de nombreux facteurs comme les protéines SMN et ICln. Au cours de ma thèse, je me suis intéressé à l'étude du rôle de ces deux protéines dans la maturation et la production des snRNPs du splicéosome.Dans la première partie de mon travail, les modifications internes des snRNAs ont été caractérisées dans des cellules dont les corpuscules de Cajal sont dispersés à cause d'une déficience de la protéine SMN. En effet, en plus de son rôle dans les étapes précoces de formation des snRNPs, la protéine SMN est également requise pour la formation des corpuscules de Cajal, structures nucléaires qui concentrent les scaRNAs impliqués dans le processus de modification post-transcriptionnelle des ARNs. Nous avons pu ainsi montrer que la protéine SMN et les corps de Cajal ne sont pas essentiels à la production des résidus 2'-O-methyl et pseudouridine dans les snRNAs majeurs et mineurs.La deuxième partie de mon travail a porté sur l'étude des relations fonctionnelles entre les protéines ICln et SMN in vivo en utilisant l'organisme modèle S. pombe. Après avoir caractérisé un homologue de la protéine humaine dans la levure fissipare, nous avons montré que la protéine ICln n'est pas essentielle mais est importante pour une croissance optimale des cellules de levure. Notre étude montre aussi que la modulation de l'activité de la protéine ICln ne permet pas de compenser les défauts dans la production de snRNPs observés dans les cellules portant un allèle muté de SMN. Finalement, l'utilisation d'une approche génomique montre que la délétion du gène ICln entraine des défauts différentiels d'épissage, indiquant que le choix des sites et la cinétique d'épissage sont fortement dépendants de la concentration des composants de base du splicéosome. / Small nuclear ribonucleoproteins (snRNPs) are the major components of the spliceosome, the machinery responsible for the splicing of pre-messenger RNAs. The biogenesis of snRNPs is a complex process that involves many factors such as the SMN and ICln proteins. During my thesis, I studied the role of these two proteins in the maturation and the production of the spliceosome snRNPs.The goal of the first part of my work was to characterize the internal modifications of snRNAs in SMN-deficient cells carrying disrupted Cajal bodies. Indeed, in addition to its role in the early stages of snRNPs assembly, the SMN protein is also required for the formation of Cajal bodies which are nuclear structures carrying the scaRNAs involved in the post-transcriptional modification process of RNAs. We could show that the SMN protein and Cajal bodies are not essential for the formation of 2'-O-methyl and pseudouridine residues in the major and minor snRNAs.In the second part of my work, the functional relationships between the ICln and SMN proteins were examined in vivo using the S. pombe model organism. We first identified a fission yeast homologue of the human ICln protein and found that the ICln protein is not essential but important for optimal growth of yeast cells. Our study also showed that the modulation of the activity of the ICln protein does not compensate for defects in the production of snRNPs observed in yeast cells carrying a SMN mutated allele. Finally, the use of a genome-wide approach allowed us to show that deletion of the ICln gene resulted in differential splicing defects, indicating that the choice of splice sites and the kinetics of splicing are strongly dependent on the concentration of the basic components of the spliceosome.

Epissage

SnRNPs

Smn

ICln

Corps de Cajal

S.pombe

Splicing

SnRNPs

Smn

ICln

Cajal Bodies

S.pombe

Funkční analýza mutací hPrp8 spojených s onemocněním retinitis pigmentosa. / Functional analysis of hPrp8 mutations linked to retinitis pigmentosa.

Matějů, Daniel

January 2013

hPrp8 is an essential pre-mRNA splicing factor. This highly conserved protein is a component of the U5 small ribonucleoprotein particle (U5 snRNP), which constitutes one of the building blocks of the spliceosome. hPrp8 acts as a key regulator of spliceosome activation and interacts directly with U5 snRNA and with the regions of pre-mRNA that are involved in the transesterification reactions during splicing. Mutations in hPrp8 have been shown to cause an autosomal dominant form of retinitis pigmentosa (RP), an inherited disease leading to progressive degeneration of retina. In this study, we analyzed the effects of the RP-associated mutations on the function of hPrp8. Using BAC recombineering, we created mutant variants of hPrp8-GFP construct and we generated stable cell lines expressing the recombinant proteins. The mutant proteins were expressed and localized to the nucleus. However, one of the missense mutations affected the localization and stability of hPrp8. Further experiments suggested that RP-associated mutations affect the ability of hPrp8 to interact with other components of the U5 snRNP and with pre-mRNA. We further studied the biogenesis of U5 snRNP. We depleted hPrp8 by siRNA to interfere with U5 snRNP assembly and we observed that the incompletely assembled U5 snRNPs accumulate in...

Kontrola kvality v průběhu biogeneze snRNP částic / Quality control in snRNP biogenesis

Roithová, Adriana

January 2018

(English) snRNPs are key components of the spliceosome. During their life, they are found in the cytoplasm and also in the nucleus, where carry out their function. There are five major snRNPs named according to RNA they contain U1, U2, U4, U5 and U6. Each snRNP consists from RNA, ring of seven Sm or LSm proteins and additional proteins specific for each snRNP. Their biogenesis starts in the nucleus, where they are transcribed. Then they are transported into the cytoplasm. During their cytoplasmic phase, the SMN complex forms the Sm ring around the specific sequence on snRNA and cap is trimethylated. These two modifications are the signals for reimport of snRNA into the nucleus, where they accumulate in the nuclear structures called Cajal bodies (CBs), where the final maturation steps occur. There are several quality control points during snRNP biogenesis that ensure that only fully assembled particles reach the spliceosome. The first checkpoint is in the nucleus immediately after the transcription, when the export complex is formed. The second checkpoint is in the cytoplasm and proofreads Sm ring assembly. If the Sm ring formation fails, the defective snRNPs are degraded in the cytoplasm by Xrn1 exonuclease. However, it is still unclear, how the cell distinguishes between normal and defective...

Studium organizace a dynamiky bezmembránových buněčných kompartmentů / Study of the organization and dynamics of the membraneless cell compartments

Blažíková, Michaela

January 2014

of Doctoral Thesis Title: Study of the organization and dynamics of the membraneless cell compartments Author: Michaela Blažíková Institute: Charles University in Prague, Faculty of Mathematics and Physics, Institute of Physics of Charles University Supervisor: Doc. RNDr. Petr Heřman, CSc., Charles University in Prague, Faculty of Mathematics and Physics, Institute of Physics of Charles University Abstract Eukaryotic cells contain many organelles and specific bodies. Beside the membrane delimited organelles such as nucleus, mitochondria or Golgi apparatus there are other structurally and functionally distinct membraneless structures in the cells. In this work we studied the self-organization processes, i.e. the processes that do not require specific interactions, of membraneless structures in nuclei, cytoplasm and plasma membrane of mammalian cells and yeast. The research was focused on the formation of nucleoli and Cajal bodies in mammalian cell nulei and processing bodies (P- bodies) in the cytoplasm of mammalian cells. The organization of MCC domains in the yeast plasma membrane (Membrane compartment of Can1) was studied as well. It was shown that nonspecific interactions as the result of macromolecular crowding could be one of the main driving forces in formation and stabilization of these...

Kontrola kvality v průběhu biogeneze snRNP částic / Quality control in snRNP biogenesis

Roithová, Adriana

January 2018

(English) snRNPs are key components of the spliceosome. During their life, they are found in the cytoplasm and also in the nucleus, where carry out their function. There are five major snRNPs named according to RNA they contain U1, U2, U4, U5 and U6. Each snRNP consists from RNA, ring of seven Sm or LSm proteins and additional proteins specific for each snRNP. Their biogenesis starts in the nucleus, where they are transcribed. Then they are transported into the cytoplasm. During their cytoplasmic phase, the SMN complex forms the Sm ring around the specific sequence on snRNA and cap is trimethylated. These two modifications are the signals for reimport of snRNA into the nucleus, where they accumulate in the nuclear structures called Cajal bodies (CBs), where the final maturation steps occur. There are several quality control points during snRNP biogenesis that ensure that only fully assembled particles reach the spliceosome. The first checkpoint is in the nucleus immediately after the transcription, when the export complex is formed. The second checkpoint is in the cytoplasm and proofreads Sm ring assembly. If the Sm ring formation fails, the defective snRNPs are degraded in the cytoplasm by Xrn1 exonuclease. However, it is still unclear, how the cell distinguishes between normal and defective...

A Functional Analysis of the Small Nuclear RNP Import Adaptor, Snurportin1

Ospina, Jason Kerr

01 August 2005

No description available.

Biology, Genetics

Snurportin

snRNP biogenesis

Nuclear import

Survival of Motor Neurons

Spinal Muscular Atrophy

Cajal Bodies

Estudos da dinâmica do núcleo da célula hospedeira durante a infecção por Trypanosoma cruzi / Studies of the dynamics of host cell nucleus during infection with Trypanosoma cruzi

Castro, Camila Gachet de

03 May 2016

Trypanosoma cruzi é o agente causador da Doença de Chagas, que segundo a OMS, atinge oito milhões de pessoas principalmente na América Latina, causando danos à saúde pública, juntamente com um impacto econômico negativo. Durante o processo de infecção, uma variedade de eventos celulares ocorre apenas pelo simples contato do parasito com a célula hospedeira, levando a modificações no metabolismo celular e alterações morfológicas. O parasita é capaz de modular respostas celulares e imunológicas da célula hospedeira para sua própria sobrevivência. Além do que, pode alterar compartimentos celulares como o número e tamanho de nucléolos, sugerindo que a presença do parasita poderia estar interferindo na maquinaria nuclear. Porém, pouco se conhece sobre a organização nuclear da célula hospedeira quando infectada por Trypanosoma cruzi. O objetivo deste estudo foi de investigar pela primeira vez os compartimentos nucleares das células hospedeiras durante o curso da infecção por T. cruzi. Células LLC-MK2 foram infectadas com T. cruzi e reações de imunofluorescência indireta foram realizadas utilizando anticorpos e marcadores específicos para proteínas nucleares. As análises das imagens de microscopia confocal e quantificação das fluorescências pelo ImageJ mostraram padrões distintos nos compartimentos nucleares quando comparadas com células não infectadas. Corpos de Cajal e Speckles sofrem alterações quando a célula está infectada e isso depende do ciclo celular do parasita. Neste trabalho também foi investigado através de quantificação de imagem e immunoblotting o comportamento das Ribonucleoproteínas A1 e A2B1 durante a parasitemia. Estas análises demonstram que o T. cruzi pode modular a célula hospedeira quando infectada a favor de sua sobrevivência, promovendo alterações na dinâmica dos compartimentos nucleares durante o seu ciclo celular. Esse estudo inédito poderá auxiliar a compreender a biologia do parasita e sua interação com a célula hospedeira e desta maneira contribuir na busca de possíveis alvos terapêuticos / Trypanosoma cruzi is the causal agente of Chagas disease, that affects about eight million people mostly in Latin America according to the WHO, causing damage to public health and a negative economic impact. During infection, a variety of signaling processes occur after contact of the parasite to the host cell, what can lead to metabolic modifications as well morphological alterations in both cells. The parasite can modulate host cell cellular and immunological responses for its own survival. In addiction, the presence of T. cruzi can modify the nuclear compartments such as nucleoli, suggesting that the presence of the parasite could be interfering with the nuclear machinery. However, little is know about the nuclear organization when the host cell is infected with Trypanosoma cruzi. This study aimed to investigate for the first time the nuclear compartment of host cells infected by T. cruzi using specific antibodies and fluorescent markers for nuclear compartments, in order to investigate the morphological and functional changes in the nucleus of the host cell. Using LLC-MK2 cells infected with T. cruzi, we performed indirect immunofluorescence using distinct nuclear antibodies. Confocal microscopy analysis of infected cells showed pattern variations in the nuclear compartments when compared to uninfected cells. Cajal bodies and Speckles suffer alterations when the cell is infected and it is related to the parasite life cycle. In this work we also investigated by image quantification and immunoblotting the behavior of Ribonucleoproteins A1 and A2B1 during infection. These evidences support the idea that T. cruzi can modulate host cell response to ensure its own survival during the infection, promoting changes in the dynamics of the nuclear compartments. This unpublished data may help to understand the biology of the parasite and its interaction with the host cell and thus contributing to seek for potential therapeutic targets

Cajal bodies

Compartimentos nucleares

Corpos de Cajal

hnRNP A1 and hnRNP A2B1

hnRNP A1 e hnRNP A2B1

Magazines nuclear

RNA polimerase II

RNA polymerase II

speckles

Speckles

Trypanosoma cruzi

Trypanosoma cruzi

Biochemische und zellbiologische Untersuchungen zur Rolle der Cajal Bodies bei der Zusammenlagerung spleißosomaler UsnRNP Partikel / Biochemical and cellbiological characterization of the role of Cajal Bodies in spliceosomal UsnRNP assembly

Schaffert, Nina

26 April 2005

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

WF und WH