Estudo de interações proteicas da Tiorredoxina Peroxidase Nuclear (nTPx) de Sacharomyces cerevisiae nos eventos de crescimento celular e silenciamento telomérico

Breyer, Carlos Alexandre

26 August 2011

Made available in DSpace on 2016-08-17T18:39:45Z (GMT). No. of bitstreams: 1 4644.pdf: 10384990 bytes, checksum: c8ab8c109d1671b477c700f556bd68bc (MD5) Previous issue date: 2011-08-26 / Universidade Federal de Minas Gerais / The thioredoxin peroxidase (Tpx) is a group of antioxidant proteins that has been widely studied due to its role in the decomposition of different peroxides such as H2O2, peroxynitrite and organic peroxides. The ability of peroxide decomposition by Tpx is related to the presence of a conserved cysteine called peroxidatic cysteine (CysP). Most Tpx has a second cysteine (resolving cysteine - CysR) which forms a disulfide with CysP after peroxide decomposition. In addition to the peroxidase activity, some Tpx have molecular chaperone activity and are also involved in signaling of cell growth induced by hydroperoxides. It has been demonstrated that the Tpx cytosolic isoform of Schizosaccharomyces pombe is able to interact directly with MAPK (Sty1) via mixed disulfide, which is stabilized when the CysR is replaced by a serine residue. Saccharomyces cerevisiae have a nuclear isoform of Tpx (nTPx) and review of the literature shows the importance of this protein in maintaining the telomere silencing and decomposition of organic peroxides in the nucleus. Scale proteomic studies using mass spectrometry and two-hybrid indicate the nTPx association with MAP kinases. However, despite its location and participation in biological processes of relevance, works related to nTPx are scarce. Scale proteomics studies reported the physical interaction between nTPx and Mec3, Gts1, Pc1 and Dog2. These proteins are related to cell signaling or maintenance of telomeric silencing. However, no specific studies were performed to confirm these interactions and if they are established by mixed disulfides. This study aimed to evaluate the interactions previously described in the literature between nTPx and Mec3, Pcl1, Dog2 and Gts1 through the expression and purification of these proteins and in vitro evaluation of interactions as well as in vivo tests using two-hybrid. Several efforts were made with different approaches, nevertheless it was impossible overexpression of Mec3, Pcl1, Dog2, indicating a toxic effect of these proteins on the strains used. Furthermore, we found great success in overexpression of nTPx and nTpxC112S (8 mg and 10 mg per liter of cell culture) in Eschericchia coli strain BL21 (DE3) C43. This is the first time that these proteins were expressed in native form. It was also possible to overexpress the Gts1 protein in the same strain. These results could lead for new approaches in future studies in order to determine these threedimensional structures, by methods such as X-ray crystallography or nuclear magnetic resonance (NMR). Finally, the results obtainedusing the technique of two-hybrid yeast confirmed the interaction in vivo among nTPx and Mec3, Gts1, Dog2. However, opposing the results described in the literature, no interaction was detected between nTPx and PCL1, emphasizing the necessity of specific experiments in addition to the large-scale ones. / As tiorredoxinas peroxidases (TPx), constituem um grupo de proteínas antioxidantes que vêm sendo bastante estudadas pela sua atuação na decomposição de diversos tipos peróxidos, como o H2O2, peroxinitritos e peróxidos orgânicos. A capacidade de decomposição de peróxidos pelas TPx está relacionada a presença de uma cisteína conservada denominada de cisteína peroxidásica (CysP). A maioria das TPx possuem uma segunda cisteína (cisteína de resolução - CysR) a qual forma um dissulfeto com CysP após a decomposição de um peróxido. Adicionalmente, à atividade peroxidásica, algumas TPx possuem atividade de chaperona molecular e também estão envolvidas em processos de sinalização de crescimento celular induzidos por hidroperóxidos. Já foi demonstrado que a isoforma citosólica de TPx de Schizosaccharomyces pombe é capaz de interagir diretamente com uma MAPK (Sty1) através da formação de um dissulfeto misto entre as proteínas, que é estabilizado quando a CysR é substituída por um resíduo de serina. Entretanto, nenhuma interação deste tipo foi descrita para outros organismos. Em Saccharomyces cerevisiae ocorre uma isoforma de TPx no núcleo (nTPx) e a revisão da literatura demonstra a relevância desta proteína na manutenção do silenciamento dos telômeros e decomposição de peróxidos orgânicos no núcleo. Estudos em escala proteômica utilizando espectrometria de massa e duplo híbrido indicam a associação de nTPx com MAP quinases, entretanto, apesar de sua localização e participação em processos biológicos de relevância, trabalhos relacionados com nTPx são escassos. Estudos em escala proteômica relataram a interação física entre nTPx e as proteínas Mec3, Gts1, Pcl1 e Dog2 relacionadas a sinalização celular ou manutenção do silenciamento telomérico. No entanto, não foram efetuados estudos pontuais visando confirmar estas interações como também averiguar a possibilidade das interações entre nTPx e as proteínas supracitadas serem estabelecidas através de dissulfetos mistos. Este trabalho teve por objetivo a avaliação de interações previamente descritas na literatura entre nTPx e Mec3, Pcl1 e Dog2 por meio da expressão e purificação destas proteínas e avaliação in vitro de interações como também in vivo através de ensaios de duplo híbrido. Diversos esforços com diferentes abordagens foram efetuados, entretanto não foi possível a superexpressão de Mec3, Pcl1, Dog2, indicando um efeito tóxico destas proteínas sobre as linhagens utilizadas. Por outro lado, obtivemos grande sucesso na superexpressão de nTPx e nTpxC112S (8 mg e 10 mg por litro de cultura de células) em linhagens de Eschericchia coli BL21 (DE3) C43, o que representa a primeira vez que estas proteínas foram expressas sem trucamentos. Também foi possível expressar na mesma linhagem a proteína Gts1. Estes resultados abrem a possibilidade de estudos posteriores visando a determinação de suas estruturas tridimensionais, por metodologias como cristalografia de raios-X ou ressonância magnética nuclear (RMN). Por fim, os resultados de interação in vivo utilizando a técnica de duplo híbrido em levedura, confirmaram a interação entre nTPx e Mec3, Gts1 e Dog2. Entretanto ao contrario dos resultados descritos na literatura, não foi detectada interação entre nTPx e Pcl1, reforçando que experimentos pontuais são necessários em adição aos experimentos de larga escala.

Biotecnologia

Saccharomyces cerevisiae

Células - crescimento

Silenciamento telomérico

Tiorredoxinas peroxidases

Thioredoxin Peroxidase

Cell Growth

Telomeric silencing

Mass spectrometry as a tool to dissect the role of chromatin assembly factors in regulating nucleosome assembly

Gharib, Marlène

12 1900

L'assemblage des nucléosomes est étroitement couplée à la synthèse des histones ainsi qu’à la réplication et la réparation de l’ADN durant la phase S. Ce processus implique un mécanisme de contrôle qui contribue soigneusement et de manière régulée à l’assemblage de l’ADN en chromatine. L'assemblage des nucléosomes durant la synthèse de l’ADN est crucial et contribue ainsi au maintien de la stabilité génomique. Cette thèse décrit la caractérisation par spectrométrie de masse(SM) des protéines jouant un rôle critique dans l’assemblage et le maintien de la structure chromatinienne. Plus précisément, la phosphorylation de deux facteurs d’assemblage des nucléosome, le facteur CAF-1, une chaperone d’histone qui participe à l'assemblage de la chromatine spécifiquement couplée à la réplication de l'ADN, ainsi que le complexe protéique Hir, jouant de plus un rôle important dans la régulation transcriptionelle des gènes d’histones lors de la progression normale du cycle cellulaire et en réponse aux dommages de l'ADN, a été examiné. La caractérisation des sites de phosphorylation par SM nécéssite la séparation des protéines par éléctrophorèse suivi d’une coloration a l’argent. Dans le chapitre 2, nous demontrons que la coloration à l’argent induit un artéfact de sulfatation. Plus précisément, cet artéfact est causé par un réactif spécifiquement utilisé lors de la coloration. La sulfatation présente de fortes similitudes avec la phosphorylation. Ainsi, l’incrément de masse observé sur les peptides sulfatés et phosphorylés (+80 Da) nécéssite des instruments offrant une haute résolution et haute précision de masse pour différencier ces deux modifications. Dans les chapitres 3 et 4, nous avons d’abord démontré par SM que Cac1, la plus grande sous-unité du facteur CAF-1, est cible de plusieurs sites de phosphorylation. Fait intéréssant, certains de ces sites contiennent des séquences consensus pour les kinases Cdc7-Dbf4 et CDKs. Ainsi, ces résultats fournissent les premières évidences que CAF-1 est potentiellement régulé par ces deux kinases in vivo. La fonction de tous les sites de phosphorylation identifiés a ensuite été évaluée. Nous avons démontré que la phosphorylation de la Ser-503, un site consensus de la DDK, est essentielle à la répréssion transcriptionelle des gènes au niveau des télomères. Cependant, cette phosphorylation ne semble pas être nécéssaire pour d’autres fonctions connues de CAF-1, indiquant que le blocage de la phsophorylation de Cac1 Ser-503 affecte spécifiquement la fonction de CAF-1 aux structures hétérochromatiques des télomères. Ensuite, nous avons identifiés une intéraction physique entre CAF-1 et Cdc7-Dbf4. Des études in vitro ont également demontré que cette kinase phosphoryle spécifiquement Cac1 Ser-503, suggérant un rôle potential pour la kinase Cdc7-Dbf4 dans l’assemblage et la stabilité de la structure hétérochromatique aux télomères. Finalement, les analyses par SM nous ont également permi de montrer que la sous-unité Hpc2 du complexe Hir est phosphorylée sur plusieurs sites consensus des CDKs et de Cdc7-Dbf4. De plus, la quantification par SM d’un site spécifique de phosphorylation de Hpc2, la Ser-330, s’est révélée être fortement induite suite à l’activation du point de contrôle de réplication (le “checkpoint”) suite au dommage a l’ADN. Nous montrons que la Ser-330 de Hpc2 est phopshorylée par les kinases de point de contrôle de manière Mec1/Tel1- et Rad53-dépendante. Nos données préliminaires suggèrent ainsi que la capacité du complex Hir de réguler la répréssion transcriptionelle des gènes d'histones lors de la progression du cycle cellulaire normal et en réponse au dommage de l'ADN est médiée par la phosphorylation de Hpc2 par ces deux kinases. Enfin, ces deux études mettent en évidence l'importance de la spectrométrie de masse dans la caractérisation des sites de phosphorylation des protéines, nous permettant ainsi de comprendre plus précisement les mécanismes de régulation de l'assemblage de la chromatine et de la synthèse des histones. / Nucleosome assembly entails a controlled mechanism that is tightly coupled to DNA and histone synthesis during DNA replication and repair in S-phase. Importantly, this contributes to the prompt and carefully orchestrated assembly of newly replicated DNA into chromatin, which is essential for the maintenance of genomic integrity. This thesis describes the mass spectrometric characterization of proteins critical in the regulation of nucleosome assembly behind the replication fork and chromatin structure. More specifically, the phosphorylation of Chromatin Assembly Factor 1 (CAF-1), a nucleosome assembly factor that uniquely functions during replication-coupled de novo nucleosome assembly in S-phase and the Hir protein complex, a second nucleosome assembly factor that also contributes to the transcriptional regulation of histone genes during normal cell cycle progression and in response to DNA damage, was examined. We first demonstrated that characterization of protein phosphorylation by mass spectrometry (MS), which often relies on the separation of proteins by gel electrophoresis followed by silver staining for visualization, should be given careful considerations. In chapter 2, we report a potential pitfall in the interpretation of phosphorylation modifications due to the artifactual sulfation of serine, threonine and tyrosine residues caused by a specific reagent used during silver staining. Sulfation and phosphorylation both impart an 80 Da addition of these residues making them distinguishable only with MS systems offering high resolution and high mass accuracy capabilities. Chapter 3 and 4 present the MS characterization of in vivo phosphorylation occurring on CAF-1 and Hir proteins, respectively. We first demonstrated that Cac1, the largest subunit of CAF-1, is phosphorylated on several novel residues containing the consensus sequences recognized by either Cdc7-Dbf4 (DDK) or cyclin-dependent kinases(CDKs). These results have provided the first evidence that CAF-1 is regulated by these two kinases in vivo. The function of all identified Cac1 phosphorylation sites was then assessed. In vivo phenotypic studies showed that the specific phosphorylation of Ser-503, a Cac1 DDK-like site identified in our study, is essential for heterochromatin-mediated telomeric silencing. Cac1-Ser-503 did not appear to be required for other known functions of CAF-1, including DNA damage resistance and mitotic chromosom segregation, indicating that blocking Cac1 phosphorylation on Ser-503 sepcifically cripples CAF-1 function at telomeres. Next, biochemical purifications identified a physical interaction between CAF-1 and Cdc7-Dbf4. Consistent with this physical interaction data, in vitro kinase assay studies showed that Cdc7-Dbf4 specifically phosphorylates Cac1 Ser-503 thereby uncovering a novel role for Cdc7-Dbf4 in heterochromatin assembly and/or stability that is potentially mediated through CAF-1. Finally, MS analysis also showed that the Hpc2 subunit of the Hir protein complex is phosphorylated on several CDK- and DDK-like consensus sites. Furthermore, MS quantification of a specific phosphorylation site,Hpc2 Ser-330, was shown to be highly induced following the activation of the DNA damage checkpoint in response to DNA damage. We show that Hpc2 Ser-330 is phopshorylated by checkpoint kinases in a Mec1/Tel1- and Rad53-dependent manner. Our preliminary data suggest that the ability of the Hir protein complex to regulate the transcriptional repression of histone genes during normal cell cycle progression and in response to DNA damage is mediated through the regulated phosphorylation of Hpc2 by these kinases. Finally, these two studies highlight the importance of mass spectrometry in characterizing protein phosphorylation events, which has yielded novel insights into the regulation of chromatin assembly by CAF-1 and histone synthesis mediated by Hir proteins.

CAF-1

Proteines Hir

Spectrométrie de masse

Coloration à l'argent

Sulfatation

Phosphorylation

Assemblage de la chromatine

Réplication de l'ADN

Répréssion télomérique

Régulation des gènes d'histones

Dommage à l'ADN

CAF-1

Hir proteins

Mass spectrometry

Silver staining

Sulfation

Phosphorylation

Chromatin assembly

DNA replication

Telomeric silencing

Histone gene regulation

DNA damage

Mass spectrometry as a tool to dissect the role of chromatin assembly factors in regulating nucleosome assembly

Gharib, Marlène

12 1900

L'assemblage des nucléosomes est étroitement couplée à la synthèse des histones ainsi qu’à la réplication et la réparation de l’ADN durant la phase S. Ce processus implique un mécanisme de contrôle qui contribue soigneusement et de manière régulée à l’assemblage de l’ADN en chromatine. L'assemblage des nucléosomes durant la synthèse de l’ADN est crucial et contribue ainsi au maintien de la stabilité génomique. Cette thèse décrit la caractérisation par spectrométrie de masse(SM) des protéines jouant un rôle critique dans l’assemblage et le maintien de la structure chromatinienne. Plus précisément, la phosphorylation de deux facteurs d’assemblage des nucléosome, le facteur CAF-1, une chaperone d’histone qui participe à l'assemblage de la chromatine spécifiquement couplée à la réplication de l'ADN, ainsi que le complexe protéique Hir, jouant de plus un rôle important dans la régulation transcriptionelle des gènes d’histones lors de la progression normale du cycle cellulaire et en réponse aux dommages de l'ADN, a été examiné. La caractérisation des sites de phosphorylation par SM nécéssite la séparation des protéines par éléctrophorèse suivi d’une coloration a l’argent. Dans le chapitre 2, nous demontrons que la coloration à l’argent induit un artéfact de sulfatation. Plus précisément, cet artéfact est causé par un réactif spécifiquement utilisé lors de la coloration. La sulfatation présente de fortes similitudes avec la phosphorylation. Ainsi, l’incrément de masse observé sur les peptides sulfatés et phosphorylés (+80 Da) nécéssite des instruments offrant une haute résolution et haute précision de masse pour différencier ces deux modifications. Dans les chapitres 3 et 4, nous avons d’abord démontré par SM que Cac1, la plus grande sous-unité du facteur CAF-1, est cible de plusieurs sites de phosphorylation. Fait intéréssant, certains de ces sites contiennent des séquences consensus pour les kinases Cdc7-Dbf4 et CDKs. Ainsi, ces résultats fournissent les premières évidences que CAF-1 est potentiellement régulé par ces deux kinases in vivo. La fonction de tous les sites de phosphorylation identifiés a ensuite été évaluée. Nous avons démontré que la phosphorylation de la Ser-503, un site consensus de la DDK, est essentielle à la répréssion transcriptionelle des gènes au niveau des télomères. Cependant, cette phosphorylation ne semble pas être nécéssaire pour d’autres fonctions connues de CAF-1, indiquant que le blocage de la phsophorylation de Cac1 Ser-503 affecte spécifiquement la fonction de CAF-1 aux structures hétérochromatiques des télomères. Ensuite, nous avons identifiés une intéraction physique entre CAF-1 et Cdc7-Dbf4. Des études in vitro ont également demontré que cette kinase phosphoryle spécifiquement Cac1 Ser-503, suggérant un rôle potential pour la kinase Cdc7-Dbf4 dans l’assemblage et la stabilité de la structure hétérochromatique aux télomères. Finalement, les analyses par SM nous ont également permi de montrer que la sous-unité Hpc2 du complexe Hir est phosphorylée sur plusieurs sites consensus des CDKs et de Cdc7-Dbf4. De plus, la quantification par SM d’un site spécifique de phosphorylation de Hpc2, la Ser-330, s’est révélée être fortement induite suite à l’activation du point de contrôle de réplication (le “checkpoint”) suite au dommage a l’ADN. Nous montrons que la Ser-330 de Hpc2 est phopshorylée par les kinases de point de contrôle de manière Mec1/Tel1- et Rad53-dépendante. Nos données préliminaires suggèrent ainsi que la capacité du complex Hir de réguler la répréssion transcriptionelle des gènes d'histones lors de la progression du cycle cellulaire normal et en réponse au dommage de l'ADN est médiée par la phosphorylation de Hpc2 par ces deux kinases. Enfin, ces deux études mettent en évidence l'importance de la spectrométrie de masse dans la caractérisation des sites de phosphorylation des protéines, nous permettant ainsi de comprendre plus précisement les mécanismes de régulation de l'assemblage de la chromatine et de la synthèse des histones. / Nucleosome assembly entails a controlled mechanism that is tightly coupled to DNA and histone synthesis during DNA replication and repair in S-phase. Importantly, this contributes to the prompt and carefully orchestrated assembly of newly replicated DNA into chromatin, which is essential for the maintenance of genomic integrity. This thesis describes the mass spectrometric characterization of proteins critical in the regulation of nucleosome assembly behind the replication fork and chromatin structure. More specifically, the phosphorylation of Chromatin Assembly Factor 1 (CAF-1), a nucleosome assembly factor that uniquely functions during replication-coupled de novo nucleosome assembly in S-phase and the Hir protein complex, a second nucleosome assembly factor that also contributes to the transcriptional regulation of histone genes during normal cell cycle progression and in response to DNA damage, was examined. We first demonstrated that characterization of protein phosphorylation by mass spectrometry (MS), which often relies on the separation of proteins by gel electrophoresis followed by silver staining for visualization, should be given careful considerations. In chapter 2, we report a potential pitfall in the interpretation of phosphorylation modifications due to the artifactual sulfation of serine, threonine and tyrosine residues caused by a specific reagent used during silver staining. Sulfation and phosphorylation both impart an 80 Da addition of these residues making them distinguishable only with MS systems offering high resolution and high mass accuracy capabilities. Chapter 3 and 4 present the MS characterization of in vivo phosphorylation occurring on CAF-1 and Hir proteins, respectively. We first demonstrated that Cac1, the largest subunit of CAF-1, is phosphorylated on several novel residues containing the consensus sequences recognized by either Cdc7-Dbf4 (DDK) or cyclin-dependent kinases(CDKs). These results have provided the first evidence that CAF-1 is regulated by these two kinases in vivo. The function of all identified Cac1 phosphorylation sites was then assessed. In vivo phenotypic studies showed that the specific phosphorylation of Ser-503, a Cac1 DDK-like site identified in our study, is essential for heterochromatin-mediated telomeric silencing. Cac1-Ser-503 did not appear to be required for other known functions of CAF-1, including DNA damage resistance and mitotic chromosom segregation, indicating that blocking Cac1 phosphorylation on Ser-503 sepcifically cripples CAF-1 function at telomeres. Next, biochemical purifications identified a physical interaction between CAF-1 and Cdc7-Dbf4. Consistent with this physical interaction data, in vitro kinase assay studies showed that Cdc7-Dbf4 specifically phosphorylates Cac1 Ser-503 thereby uncovering a novel role for Cdc7-Dbf4 in heterochromatin assembly and/or stability that is potentially mediated through CAF-1. Finally, MS analysis also showed that the Hpc2 subunit of the Hir protein complex is phosphorylated on several CDK- and DDK-like consensus sites. Furthermore, MS quantification of a specific phosphorylation site,Hpc2 Ser-330, was shown to be highly induced following the activation of the DNA damage checkpoint in response to DNA damage. We show that Hpc2 Ser-330 is phopshorylated by checkpoint kinases in a Mec1/Tel1- and Rad53-dependent manner. Our preliminary data suggest that the ability of the Hir protein complex to regulate the transcriptional repression of histone genes during normal cell cycle progression and in response to DNA damage is mediated through the regulated phosphorylation of Hpc2 by these kinases. Finally, these two studies highlight the importance of mass spectrometry in characterizing protein phosphorylation events, which has yielded novel insights into the regulation of chromatin assembly by CAF-1 and histone synthesis mediated by Hir proteins.

CAF-1

Proteines Hir

Spectrométrie de masse

Coloration à l'argent

Sulfatation

Phosphorylation

Assemblage de la chromatine

Réplication de l'ADN

Répréssion télomérique

Régulation des gènes d'histones

Dommage à l'ADN

CAF-1

Hir proteins

Mass spectrometry

Silver staining

Sulfation

Phosphorylation

Chromatin assembly

DNA replication

Telomeric silencing

Histone gene regulation

DNA damage