Caracterização funcional da proteína Nop8p de Saccharomyces cerevisiae / Functional characterization of the Saccharomyces cerevisiae nucleolar protein Nop8p

Santos, Márcia Cristina Teixeira dos

21 October 2011

A proteína nucleolar Nop8p de levedura foi identificada inicialmente através de sua interação com Nip7p e está envolvida na formação da subunidade ribossomal 60S. A depleção de Nop8p em células de levedura leva à degradação prematura dos rRNAs, porém o mecanismo bioquímico responsável por este fenótipo ainda não é conhecido. Neste trabalho, mostramos que a interação de Nop8p com o rRNA 5.8S se dá através de sua região amino-terminal, enquanto que a porção carboxi-terminal é responsável pela interação com Nip7p e complementa parcialmente o defeito no crescimento observado na cepa mutante condicional Δnop8/GAL::NOP8. Além disso, Nop8p media a associação de Nip7p com as partículas pré-ribossomais. Nop8p também interage com a subunidade Rrp6p do exossomo e inibe a atividade do complexo in vitro, sugerindo que a diminuição dos níveis da subunidade ribosomal 60S detectada após a depleção de Nop8p pode ser resultado da degradação dos pré-rRNAs pelo exossomo. Estes resultados indicam que Nop8p pode regular a atividade do exossomo durante o processamento do pré-rRNA. / The yeast nucleolar protein Nop8p has previously been shown to interact with Nip7p and to be required for 60S ribosomal subunit formation. Although depletion of Nop8p in yeast cells leads to premature degradation of rRNAs, the biochemical mechanism responsible for this phenotype is still not known. In this work, we show that the Nop8p amino-terminal region mediates interaction with the 5.8S rRNA, while its carboxylterminal portion interacts with Nip7p and can partially complement the growth defect of the conditional mutant strain Δnop8/GAL::NOP8. Interestingly, Nop8p mediates the association of Nip7p to pre-ribosomal particles. Nop8p also interacts with the exosome subunit Rrp6p and inhibits the complex activity in vitro, suggesting that the decrease in 60S ribosomal subunit levels detected upon depletion of Nop8p may result from degradation of pre-rRNAs by the exosome. These results strongly indicate that Nop8p may control exosome function during pre-rRNA processing.

Complexo TRAMP

Controle de qualidade de RNA

Exosome

Exossomo

Nip7p

Nip7p

Nop8p

Nop8p

Processamento de rRNA

RNA

RNA

RNA-surveillance

rRNA processing

TRAMPcomplex.

Caracterização da função molecular de Nop53 e de seu papel no controle do exossomo em Saccharomyces cerevisiae / Characterization of the role of Nop53 in the control of the Saccharomyces cerevisiae exosome

Cepeda, Leidy Paola Paez

21 August 2017

Nop53 e uma protena nucleolar, conservada evolutivamente e essencial na levedura Saccharomyces cerevisiae para a biogênese da subunidade maior do ribossomo, 60S. O principal fenotipo causado pela repressão da expressão de Nop53 e o acumulo do intermedi ario de processamento de pre-Rrna, 7S, que tambem e substrato do complexo exossomo na formação do rRNA maduro 5:8S. Nop53 interage diretamente com a subunidade do exossomo Rrp6 e com a subunidade Mtr4 do co-ativador do exossomo TRAMP. O objetivo principal deste trabalho foi o de analisar como a interação entre Nop53 e o exossomo pode modular a atividade deste ultimo. Para isso, foram utilizados metodos bioqumicos, geneticos e de biologia molecular. Os resultados mostrados aqui demonstram que a depleção de Nop53 faz com que mais protenas ribossomais, principalmente da subunidade maior, sejam co-imunoprecipitadas com o core do exossomo, sugerindo que Nop53 possa ter um papel na liberação do exossomo da subunidade pre-60S depois da formação do rRNA maduro 5:8S. Esta hipotese foi conrmada atraves da separação de complexos por centrifugação em gradiente de glicerol, que mostrou a presenca de subunidades do exossomo em complexos maiores na ausência de Nop53, provavelmente correspondendo a partculas pre-ribossomais. Co-imunoprecipitação de RNA com o exossomo na ausência de Nop53 tambem conrmou uma maior associação deste complexo com o pre-rRNA 7S. Como tambem mostrado aqui, alem de interagir com Rrp6, Nop53 interage com subunidades do core do exossomo e a superexpressão de uma destas subunidades, Rrp43, complementa parcialmente a ausência de Nop53 na celula. Estes resultados levaram a conclusão de que Nop53 pode recrutar o exossomo para a partcula ribossomal pre-60S para a maturação do pre-rRNA 7S a 5:8S, e atue tambem na liberação do exossomo, possivelmente atraves de sua interação com a helicase Mtr4. / Abstract Nop53 is a nucleolar, conserved and essential protein in the yeast Saccharomyces cerevisiae, involved in the biogenesis of the large ribosomal subunit 60S. The main phenotype of the depletion of Nop53 in yeast cells is the accumulation of the prerRNA processing intermediate 7S, which is also the substrate of the exosome complex for the formation of the mature rRNA 5:8S. Nop53 directly interacts with the exosome subunit Rrp6, and with the subunit Mtr4 of the TRAMP complex, an exosome co-activator. The main objective of this work was the analysis of the interaction between Nop53 and the exosome and the identication of the mechanism through which Nop53 regulates the exosome activity. The results shown here demonstrate that the depletion of Nop53 leads to a more stable association of the exosome with the pre-60S ribosome particle, as determined by co-immunoprecipitation of proteins with one of the exosome core subunits, and by fractionation of complexes through glycerol gradients. These results suggested that Nop53 could play a role in the release of the exosome after the formation of the mature rRNA 5:8S. This hypothesis was conrmed through the co-immunoprecipitation of pre-rRNA 7S with the exosome in the absence of Nop53. In addition to the interaction with the exosome subunit Rrp6, as shown here, Nop53 also interacts with core subunits of the complex. Interestingly, overexpression of one of these subunits, Rrp43, partially complements the depletion of Nop53. These results led to the conclusion that Nop53 may recruit the exosome to the pre-60S particle for the maturation of the pre-rRNA 7S to the mature 5:8S, but Nop53 may also be involved in the release of the exosome, possibly through its interaction with the helicase Mtr4.

Exosome

Exossomo

Nop53

Nop53

pre-60S ribosome particle

processamento de RNA

rRNA processing

Saccharomyces cerevisiae

Saccharomyces cerevisiae

Subunidade pre-60S

Caracterização funcional da proteína Nop8p de Saccharomyces cerevisiae / Functional characterization of the Saccharomyces cerevisiae nucleolar protein Nop8p

Márcia Cristina Teixeira dos Santos

21 October 2011

A proteína nucleolar Nop8p de levedura foi identificada inicialmente através de sua interação com Nip7p e está envolvida na formação da subunidade ribossomal 60S. A depleção de Nop8p em células de levedura leva à degradação prematura dos rRNAs, porém o mecanismo bioquímico responsável por este fenótipo ainda não é conhecido. Neste trabalho, mostramos que a interação de Nop8p com o rRNA 5.8S se dá através de sua região amino-terminal, enquanto que a porção carboxi-terminal é responsável pela interação com Nip7p e complementa parcialmente o defeito no crescimento observado na cepa mutante condicional Δnop8/GAL::NOP8. Além disso, Nop8p media a associação de Nip7p com as partículas pré-ribossomais. Nop8p também interage com a subunidade Rrp6p do exossomo e inibe a atividade do complexo in vitro, sugerindo que a diminuição dos níveis da subunidade ribosomal 60S detectada após a depleção de Nop8p pode ser resultado da degradação dos pré-rRNAs pelo exossomo. Estes resultados indicam que Nop8p pode regular a atividade do exossomo durante o processamento do pré-rRNA. / The yeast nucleolar protein Nop8p has previously been shown to interact with Nip7p and to be required for 60S ribosomal subunit formation. Although depletion of Nop8p in yeast cells leads to premature degradation of rRNAs, the biochemical mechanism responsible for this phenotype is still not known. In this work, we show that the Nop8p amino-terminal region mediates interaction with the 5.8S rRNA, while its carboxylterminal portion interacts with Nip7p and can partially complement the growth defect of the conditional mutant strain Δnop8/GAL::NOP8. Interestingly, Nop8p mediates the association of Nip7p to pre-ribosomal particles. Nop8p also interacts with the exosome subunit Rrp6p and inhibits the complex activity in vitro, suggesting that the decrease in 60S ribosomal subunit levels detected upon depletion of Nop8p may result from degradation of pre-rRNAs by the exosome. These results strongly indicate that Nop8p may control exosome function during pre-rRNA processing.

Complexo TRAMP

Controle de qualidade de RNA

Exossomo

Nip7p

Nop8p

Processamento de rRNA

RNA

Exosome

Nip7p

Nop8p

RNA

RNA-surveillance

rRNA processing

TRAMPcomplex.

Estudo de interações entre subunidades do exossomo e com outras proteínas celulares em Saccharomyces cerevisiae / Study of interactions between exosome subunits and other cellular proteins in Saccharomyces cerevisae

Fernando Alexis Gonzales Zubiate

31 August 2001

Em Saccharomyces cerevisiae, Rrp43p é uma proteína que faz parte do exossomo, um complexo multiproteíco que atua no processamento de snoRNAs, snRNAs e rRNAs e na degradação de mRNA. O exossomo está envolvido nesses processos através de uma ação 3\'→5\' exonucleolítica. Este complexo é composto por onze subunidades em S. cerevisiae e cada uma dessas subunidades tem uma ação predominante nos diferentes processos em que o complexo participa. Por estar envolvido diretamente na maturação dos rRNAs e alguns snoRNAs e snRNAs, assim como na degradação de mRNAs, o exossomo tem um papel importante no controle de expressão gênica. Com o objetivo de entender melhor a função da subunidade do exossomo Rrp43p, e conseqüentemente do complexo, nas modificações do RNA, realizamos estudos de interação entre proteínas através do método de \"two hybrid\", que permite analisar interações in vivo entre duas proteínas, convertendo-se assim, em uma ferramenta importante nestes estudos. Utilizando Rrp43p como \" isca\" estudamos interações com outras proteínas expressas em Saccharomyces cerevisiae, na procura de proteínas envolvidas em alguns eventos de processamento de RNA, que pudessem ajudar a esclarecer em maior detalhe o papel do exossomo na célula. Também examinamos interações da Rrp43p com os demais componentes do exossomo para determinar a possível estrutura deste complexo. Os resultados obtidos demonstram que Rrp43p interage com somente uma outra subunidade do exossomo, Rrp46p. A força desta interação, quando quantificada através do nível de expressão de um gene repórter, é compatível com o fato dessas proteínas formarem parte de um complexo. Estes dados constituem resultados inéditos a respeito da interação entre subunidades do exossomo. Os resultados evidenciam também a interação entre Rrp43p e uma proteína com função ainda não caracterizada em levedura (aqui denominada 137p). Esta interação foi detectada através do sistema do duplo híbrido, e depois confirmada por co-imunoprecipitação. A determinação da função desta nova proteína poderá ampliar as ferramentas de estudo da função e controle de atividade de Rrp43p e do exossomo. / In the yeast Saccharomyces cerevisiae, Rrp43p is one of the eleven subunits of the exosome, a complex involved in the processing of snoRNAs, snRNAs and rRNAs, and in mRNA degradation. The exosome participates in these processes through a 3\'-to-5\' exonucleolytic activity. Each of the eleven subunits is predominately active in one or few of the processes in which the complex takes part. Since the exosome is involved directly in rRNAs, and in some snRNAs and snoRNAs maturation, as well as in mRNA degradation, it plays an important role on the control of gene expression. Aiming to a better understanding of the Rrp43p subunit function on RNA processing, we started a screening for Rrp43p-interacting proteins through the yeast two hybrid system. In this study we expected to find proteins interacting with Rrp43p, which were involved in some aspects of RNA processing, and would improve the current knowledge on the exosome function. In order to obtain more information about the complex structure, we have also studied the interactions between Rrp43p and the other exosome subunits. The results shown here demonstrate that Rrp43p interacts with only one other exosome subunit, Rrp46p. These results can help elucidate the final exosome structure. We also found the interaction of Rrp43p with a protein of yet uncharacterized function (here named 137p). This interaction, identified in the two hybrid system, was also confirmed through co-immunoprecipitation analysis, and the study of 137p function might bring new insights on Rrp43p function and control.

Biologia molecular

Exossomo

Interação

Proteína

Proteínas da membrana (Estudo)

RNA

Saccharomyces

Exosome

Interaction

Membrane proteins (Study)

Molecular biology

Protein

RNA

Saccharomyces

Tumour-stroma Signalling in Cancer Cell Motility and Metastasis

Luga, Valbona

10 January 2014

The tumour-associated stroma, consisting of fibroblasts, inflammatory cells, vasculature and extracellular matrix proteins, plays a critical role in tumour growth, but how it regulates cancer cell migration and metastasis is poorly understood. The Wnt-planar cell polarity (PCP) pathway regulates convergent extension movements in vertebrate development. However, it is unclear whether this pathway also functions in cancer cell migration. In addition, the factors that mobilize long-range signalling of Wnt morphogens, which are tightly associated with the plasma membrane, have yet to be completely characterized. Here, I show that fibroblasts secrete membrane microvesicles of endocytic origin, termed exosomes, which promote tumour cell protrusive activity, motility and metastasis via the exosome component Cd81. In addition, I demonstrate that fibroblast exosomes activate autocrine Wnt-PCP signalling in breast cancer cells as detected by the association of Wnt with Fzd receptors and the asymmetric distribution of Fzd-Dvl and Vangl-Pk complexes in exosome-stimulated cancer cell protrusive structures. Moreover, I show that Pk expression in breast cancer cells is essential for fibroblast-stimulated cancer cell metastasis. Lastly, I reveal that trafficking in cancer cells promotes tethering of autocrine Wnt11 to fibroblast exosomes. These studies further our understanding of the role of the tumour-associated stroma in cancer metastasis and bring us closer to a more targeted approach for the treatment of cancer spread.

exosome

microvesicle

breast cancer

cell motility

PCP signalling

cancer-associated fibroblast

Wnt signalling

tumour microenvironment

0307

0379

Tumour-stroma Signalling in Cancer Cell Motility and Metastasis

Luga, Valbona

10 January 2014

The tumour-associated stroma, consisting of fibroblasts, inflammatory cells, vasculature and extracellular matrix proteins, plays a critical role in tumour growth, but how it regulates cancer cell migration and metastasis is poorly understood. The Wnt-planar cell polarity (PCP) pathway regulates convergent extension movements in vertebrate development. However, it is unclear whether this pathway also functions in cancer cell migration. In addition, the factors that mobilize long-range signalling of Wnt morphogens, which are tightly associated with the plasma membrane, have yet to be completely characterized. Here, I show that fibroblasts secrete membrane microvesicles of endocytic origin, termed exosomes, which promote tumour cell protrusive activity, motility and metastasis via the exosome component Cd81. In addition, I demonstrate that fibroblast exosomes activate autocrine Wnt-PCP signalling in breast cancer cells as detected by the association of Wnt with Fzd receptors and the asymmetric distribution of Fzd-Dvl and Vangl-Pk complexes in exosome-stimulated cancer cell protrusive structures. Moreover, I show that Pk expression in breast cancer cells is essential for fibroblast-stimulated cancer cell metastasis. Lastly, I reveal that trafficking in cancer cells promotes tethering of autocrine Wnt11 to fibroblast exosomes. These studies further our understanding of the role of the tumour-associated stroma in cancer metastasis and bring us closer to a more targeted approach for the treatment of cancer spread.

exosome

microvesicle

breast cancer

cell motility

PCP signalling

cancer-associated fibroblast

Wnt signalling

tumour microenvironment

0307

0379

Can exosomes be used as drug delivery vesicles?

Cooke, Fiona Ghina Mary

January 2018

The inflammatory arthritis Ankylosing Spondylitis (AS) is linked to the human leucocyte antigen HLA-B27. HLA-B27 is thought to drive AS because it misfolds during assembly in the endoplasmic reticulum (ER), inducing ER cell stress. Modulating HLA-B27 folding in the ER is therefore a therapeutic target pathway. The recent discovery of polymorphisms in the ER-resident peptidase ERAP1 that can impact on HLA-B27 and AS, makes ERAP1 one such target. Exosomes are small, typically 50-200 nm sized particles, formed in the endosomal recycling pathway, which can be released into the extracellular environment. Exosomes have a wide range of biological activities depending on the cell type of origin, and on the delivered cargo, which can include bio-active proteins, lipids, mRNA and miRNA. There is interest in the use of exosomes as drug delivery agents. Here, exosomes were studied as a delivery agent to modulate ERAP1, as a potential therapeutic tool for the treatment of AS. Exosomes, isolated from cell lines including CEM and Jurkat (T cell lineage), Jesthom (B cell lineage), U937 (monocyte lineage) and the epithelial HeLa cell line, were characterized by nanoparticle tracking analysis, flow cytometry and immunoblotting using markers including CD9, CD63, CD81 and TSG101. Differential expression of these markers in the immune cell lines indicated the complexity of defining exosomes. EVs were then tested using cell penetrating peptides, electroporation, lipid transfection and sonication for their ability to load FITC-siRNA or FITC-antibody as cargo. Significantly, post-loading RNase A or trypsin incubation demonstrated that many techniques do not lead to efficient cargo loading of exosomes. Sonication proved the most effective technique, with up to 30% efficiency. Loading of exosomes with ERAP1-targetted siRNA did not however lead to notable ERAP1 inhibition. The data indicates that external loading of exosomes with cargo remains a significant challenge in developing exosomes as therapeutic tools.

Caracterização da função molecular de Nop53 e de seu papel no controle do exossomo em Saccharomyces cerevisiae / Characterization of the role of Nop53 in the control of the Saccharomyces cerevisiae exosome

Leidy Paola Paez Cepeda

21 August 2017

Nop53 e uma protena nucleolar, conservada evolutivamente e essencial na levedura Saccharomyces cerevisiae para a biogênese da subunidade maior do ribossomo, 60S. O principal fenotipo causado pela repressão da expressão de Nop53 e o acumulo do intermedi ario de processamento de pre-Rrna, 7S, que tambem e substrato do complexo exossomo na formação do rRNA maduro 5:8S. Nop53 interage diretamente com a subunidade do exossomo Rrp6 e com a subunidade Mtr4 do co-ativador do exossomo TRAMP. O objetivo principal deste trabalho foi o de analisar como a interação entre Nop53 e o exossomo pode modular a atividade deste ultimo. Para isso, foram utilizados metodos bioqumicos, geneticos e de biologia molecular. Os resultados mostrados aqui demonstram que a depleção de Nop53 faz com que mais protenas ribossomais, principalmente da subunidade maior, sejam co-imunoprecipitadas com o core do exossomo, sugerindo que Nop53 possa ter um papel na liberação do exossomo da subunidade pre-60S depois da formação do rRNA maduro 5:8S. Esta hipotese foi conrmada atraves da separação de complexos por centrifugação em gradiente de glicerol, que mostrou a presenca de subunidades do exossomo em complexos maiores na ausência de Nop53, provavelmente correspondendo a partculas pre-ribossomais. Co-imunoprecipitação de RNA com o exossomo na ausência de Nop53 tambem conrmou uma maior associação deste complexo com o pre-rRNA 7S. Como tambem mostrado aqui, alem de interagir com Rrp6, Nop53 interage com subunidades do core do exossomo e a superexpressão de uma destas subunidades, Rrp43, complementa parcialmente a ausência de Nop53 na celula. Estes resultados levaram a conclusão de que Nop53 pode recrutar o exossomo para a partcula ribossomal pre-60S para a maturação do pre-rRNA 7S a 5:8S, e atue tambem na liberação do exossomo, possivelmente atraves de sua interação com a helicase Mtr4. / Abstract Nop53 is a nucleolar, conserved and essential protein in the yeast Saccharomyces cerevisiae, involved in the biogenesis of the large ribosomal subunit 60S. The main phenotype of the depletion of Nop53 in yeast cells is the accumulation of the prerRNA processing intermediate 7S, which is also the substrate of the exosome complex for the formation of the mature rRNA 5:8S. Nop53 directly interacts with the exosome subunit Rrp6, and with the subunit Mtr4 of the TRAMP complex, an exosome co-activator. The main objective of this work was the analysis of the interaction between Nop53 and the exosome and the identication of the mechanism through which Nop53 regulates the exosome activity. The results shown here demonstrate that the depletion of Nop53 leads to a more stable association of the exosome with the pre-60S ribosome particle, as determined by co-immunoprecipitation of proteins with one of the exosome core subunits, and by fractionation of complexes through glycerol gradients. These results suggested that Nop53 could play a role in the release of the exosome after the formation of the mature rRNA 5:8S. This hypothesis was conrmed through the co-immunoprecipitation of pre-rRNA 7S with the exosome in the absence of Nop53. In addition to the interaction with the exosome subunit Rrp6, as shown here, Nop53 also interacts with core subunits of the complex. Interestingly, overexpression of one of these subunits, Rrp43, partially complements the depletion of Nop53. These results led to the conclusion that Nop53 may recruit the exosome to the pre-60S particle for the maturation of the pre-rRNA 7S to the mature 5:8S, but Nop53 may also be involved in the release of the exosome, possibly through its interaction with the helicase Mtr4.

Exossomo

Nop53

processamento de RNA

Saccharomyces cerevisiae

Subunidade pre-60S

Exosome

Nop53

pre-60S ribosome particle

rRNA processing

Saccharomyces cerevisiae

Changes In Threonyl-Trna Synthetase Expression And Secretion In Response To Endoplasmic Reticulum Stress By Monensin In Ovarian Cancer Cells

Hammer, Jared Louis

01 January 2017

Aminoacyl-tRNA synthetases (ARS) are a family of enzymes that catalyze the charging of amino acids to their cognate tRNA in an aminoacylation reaction. Many members of this family have been found to have secondary functions independent of their primary aminoacylation function. Threonyl-tRNA synthetase (TARS), the ARS responsible for charging tRNA with threonine, is secreted from endothelial cells in response to both vascular endothelial growth factor (VEGF) and tumor necrosis factor-α (TNF-α), and stimulates angiogenesis and cell migration. Here we show a novel experimental approach for studying TARS secretion, and for observing the role of intracellular TARS in the endoplasmic reticulum (ER) stress response and in angiogenesis. Using Western blotting, immunofluorescence microscopy and RT-qPCR we were able to investigate changes in TARS protein and transcript levels. We initially hypothesized that TARS was secreted by exosomal release, and so we treated a human ovarian cancer cell line (CaOV-3) with monensin, an ionophore that increases exosome production, and VEGF to observe changes in intracellular and extracellular TARS protein. Monensin treatment consistently increased extracellular and intracellular TARS protein, however CD63, an exosome marker protein, levels were unaffected by monensin treatment. VEGF had no effect on intracellular TARS. We therefore hypothesized that the TARS response was a result of ER stress. The unfolded protein response (UPR) is a series of signaling pathways that are activated upon ER stress. When CaOV-3 cells were treated with increasing concentrations of monensin, intracellular levels of TARS and p-eIF2α, a downstream UPR target, increased accordingly. Monensin increased intracellular TARS protein and transcript levels in CaOV-3 cells. Monensin also increased DNAJB9, an ER chaperone protein, transcript levels, further confirming ER stress. Interestingly, monensin increased VEGF transcript levels about 6-fold. Borrelidin, a natural TARS inhibitor, also increased VEGF transcript levels, and caused an increase in p-eIF2α protein. Although the mechanism of TARS secretion remains unresolved, these data indicate that intracellular TARS expression increases in response to ER stress by monensin. Given TARS and VEGF transcript expression increased accordingly, it is possible that intracellular TARS may have pro-angiogenic function. Future directions may include investigating TARS interactions with translational control machinery.

aminoacyl tRNA synthetase

angiogenesis

ER stress

exosome

ovarian cancer

threonyl tRNA synthetase (TARS)

Biochemistry

Cell Biology

Pharmacology

Estudo de interações entre subunidades do exossomo e com outras proteínas celulares em Saccharomyces cerevisiae / Study of interactions between exosome subunits and other cellular proteins in Saccharomyces cerevisae

Zubiate, Fernando Alexis Gonzales

31 August 2001

Em Saccharomyces cerevisiae, Rrp43p é uma proteína que faz parte do exossomo, um complexo multiproteíco que atua no processamento de snoRNAs, snRNAs e rRNAs e na degradação de mRNA. O exossomo está envolvido nesses processos através de uma ação 3\'→5\' exonucleolítica. Este complexo é composto por onze subunidades em S. cerevisiae e cada uma dessas subunidades tem uma ação predominante nos diferentes processos em que o complexo participa. Por estar envolvido diretamente na maturação dos rRNAs e alguns snoRNAs e snRNAs, assim como na degradação de mRNAs, o exossomo tem um papel importante no controle de expressão gênica. Com o objetivo de entender melhor a função da subunidade do exossomo Rrp43p, e conseqüentemente do complexo, nas modificações do RNA, realizamos estudos de interação entre proteínas através do método de \"two hybrid\", que permite analisar interações in vivo entre duas proteínas, convertendo-se assim, em uma ferramenta importante nestes estudos. Utilizando Rrp43p como \" isca\" estudamos interações com outras proteínas expressas em Saccharomyces cerevisiae, na procura de proteínas envolvidas em alguns eventos de processamento de RNA, que pudessem ajudar a esclarecer em maior detalhe o papel do exossomo na célula. Também examinamos interações da Rrp43p com os demais componentes do exossomo para determinar a possível estrutura deste complexo. Os resultados obtidos demonstram que Rrp43p interage com somente uma outra subunidade do exossomo, Rrp46p. A força desta interação, quando quantificada através do nível de expressão de um gene repórter, é compatível com o fato dessas proteínas formarem parte de um complexo. Estes dados constituem resultados inéditos a respeito da interação entre subunidades do exossomo. Os resultados evidenciam também a interação entre Rrp43p e uma proteína com função ainda não caracterizada em levedura (aqui denominada 137p). Esta interação foi detectada através do sistema do duplo híbrido, e depois confirmada por co-imunoprecipitação. A determinação da função desta nova proteína poderá ampliar as ferramentas de estudo da função e controle de atividade de Rrp43p e do exossomo. / In the yeast Saccharomyces cerevisiae, Rrp43p is one of the eleven subunits of the exosome, a complex involved in the processing of snoRNAs, snRNAs and rRNAs, and in mRNA degradation. The exosome participates in these processes through a 3\'-to-5\' exonucleolytic activity. Each of the eleven subunits is predominately active in one or few of the processes in which the complex takes part. Since the exosome is involved directly in rRNAs, and in some snRNAs and snoRNAs maturation, as well as in mRNA degradation, it plays an important role on the control of gene expression. Aiming to a better understanding of the Rrp43p subunit function on RNA processing, we started a screening for Rrp43p-interacting proteins through the yeast two hybrid system. In this study we expected to find proteins interacting with Rrp43p, which were involved in some aspects of RNA processing, and would improve the current knowledge on the exosome function. In order to obtain more information about the complex structure, we have also studied the interactions between Rrp43p and the other exosome subunits. The results shown here demonstrate that Rrp43p interacts with only one other exosome subunit, Rrp46p. These results can help elucidate the final exosome structure. We also found the interaction of Rrp43p with a protein of yet uncharacterized function (here named 137p). This interaction, identified in the two hybrid system, was also confirmed through co-immunoprecipitation analysis, and the study of 137p function might bring new insights on Rrp43p function and control.

Biologia molecular

Exosome

Exossomo

Interação

Interaction

Membrane proteins (Study)

Molecular biology

Protein

Proteína

Proteínas da membrana (Estudo)

RNA

RNA

Saccharomyces

Saccharomyces