Cartographie du réseau d'interactions protéiques de la machinerie de transcription dans les cellules humaines

Rusu, Natalia

12 1900

Les protéines sont les macromolécules les plus polyvalentes de la cellule. Elles jouent un rôle fondamental dans la majorité des processus biologiques à travers la formation de complexes multi-protéiques. Durant la transcription, une multitude de facteurs sont impliquées dans le contrôle de l’activité des complexes ARN polymérases. Notre laboratoire s’est intéressé au réseau d’interaction de la machinerie de transcription des ARN polymérases nucléaires, dans le but de mieux comprendre leurs mécanismes de régulation. Pour ce faire, une procédure protéomique comprenant la purification de complexes protéiques par affinité couplée à la spectrométrie de masse et à l’analyse bioinformatique a été développée. La méthode de purification TAP (Tandem Affinity Purification) a été adaptée pour permettre la purification de complexes protéiques solubles assemblés in vivo à partir de cellules humaines. L’objectif de mon projet de maîtrise était de purifier le complexe de l’ARN Pol I ainsi que de poursuivre l’expansion du réseau d’interactions protéine-protéine de la machinerie de transcription de l’ARN Pol II humaine. À l’aide des protéines POLR1E, TWISTNB, POLR2E, PFDN4, MBD2, XPA, CAND1 et PDCD5 étiquetées (TAP-tag) exprimées dans des lignées cellulaires ECR-293, plusieurs complexes protéiques solubles ont été purifiés et analysés par spectrométrie de masse. Les interactions protéiques ont été triées et validées bioinformatiquement pour donner en final une liste d’interactions ayant un haut degré de confiance à partir de laquelle des réseaux d’interactions protéine-protéine ont été créés. Le réseau créé au cours de ce projet connecte plusieurs composantes de la machinerie transcriptionnelle tels que les ARN Pol I, II et III, les complexes RPAP3/R2TP/prefoldin-like, TRiC/CCT, Mi-2/NuRD et des facteurs de transcription et de réparation de l’ADN. Ce type d’analyse nous a permis d’identifier et de caractériser de nouveaux régulateurs de la machinerie de transcription de l’ARN Pol I et II et de mieux comprendre son fonctionnement. / Proteins are the most versatile macromolecules of the cell. They play a fundamental role in the majority of biological processes through the formation of multiprotein complexes. During transcription, a multitude of factors are involved in the control of activity of RNA polymerases. Our laboratory was interested in defining the nuclear RNA polymerases transcription machinery interaction network to better understand their regulatory mechanisms. To do so, a proteomic procedure that allows affinity purification of protein complexes coupled to mass spectrometry and computational data analysis was developed. The tandem affinity purification procedure has been adapted for the purification of soluble protein complexes as they likely exist in live mammalian cells. The aim of my master project was to purify the RNA Pol I complex as well as to further pursue the expansion of the protein-protein interaction network of the human RNA Pol II transcription machinery. By using POLR1E, TWISTNB, POLR2E, PFDN4, MBD2, XPA, CAND1 and PDCD5 TAP – tagged proteins expressed in EcR-293 cell lines, multiple soluble protein complexes were purified and analyzed by mass spectrometry. Protein interactions have been sorted and validated computationally. High-confidence dataset of interactions were used to build the protein-protein interaction networks. The network created for this project connects several components of the transcriptional machinery such as RNA Pol I, II and III, RPAP3/R2TP/prefoldin-like, TRiC/CTC, Mi-2/NuRD complexes and DNA repair and transcription factors. This type of analysis allowed us to identify and characterize new regulators of RNA Pol I and II transcription machinery and to better understand its functioning.

Machinerie de transcription

Transcription machinery

ARN polymérase

RNA polymerase

Purification TAP

TAP purification

Partenaires d'interactions

Interaction partners

Réseau d’interactions

Interaction networks

Cartographie du réseau d'interactions protéiques de la machinerie de transcription dans les cellules humaines

Rusu, Natalia

12 1900

Les protéines sont les macromolécules les plus polyvalentes de la cellule. Elles jouent un rôle fondamental dans la majorité des processus biologiques à travers la formation de complexes multi-protéiques. Durant la transcription, une multitude de facteurs sont impliquées dans le contrôle de l’activité des complexes ARN polymérases. Notre laboratoire s’est intéressé au réseau d’interaction de la machinerie de transcription des ARN polymérases nucléaires, dans le but de mieux comprendre leurs mécanismes de régulation. Pour ce faire, une procédure protéomique comprenant la purification de complexes protéiques par affinité couplée à la spectrométrie de masse et à l’analyse bioinformatique a été développée. La méthode de purification TAP (Tandem Affinity Purification) a été adaptée pour permettre la purification de complexes protéiques solubles assemblés in vivo à partir de cellules humaines. L’objectif de mon projet de maîtrise était de purifier le complexe de l’ARN Pol I ainsi que de poursuivre l’expansion du réseau d’interactions protéine-protéine de la machinerie de transcription de l’ARN Pol II humaine. À l’aide des protéines POLR1E, TWISTNB, POLR2E, PFDN4, MBD2, XPA, CAND1 et PDCD5 étiquetées (TAP-tag) exprimées dans des lignées cellulaires ECR-293, plusieurs complexes protéiques solubles ont été purifiés et analysés par spectrométrie de masse. Les interactions protéiques ont été triées et validées bioinformatiquement pour donner en final une liste d’interactions ayant un haut degré de confiance à partir de laquelle des réseaux d’interactions protéine-protéine ont été créés. Le réseau créé au cours de ce projet connecte plusieurs composantes de la machinerie transcriptionnelle tels que les ARN Pol I, II et III, les complexes RPAP3/R2TP/prefoldin-like, TRiC/CCT, Mi-2/NuRD et des facteurs de transcription et de réparation de l’ADN. Ce type d’analyse nous a permis d’identifier et de caractériser de nouveaux régulateurs de la machinerie de transcription de l’ARN Pol I et II et de mieux comprendre son fonctionnement. / Proteins are the most versatile macromolecules of the cell. They play a fundamental role in the majority of biological processes through the formation of multiprotein complexes. During transcription, a multitude of factors are involved in the control of activity of RNA polymerases. Our laboratory was interested in defining the nuclear RNA polymerases transcription machinery interaction network to better understand their regulatory mechanisms. To do so, a proteomic procedure that allows affinity purification of protein complexes coupled to mass spectrometry and computational data analysis was developed. The tandem affinity purification procedure has been adapted for the purification of soluble protein complexes as they likely exist in live mammalian cells. The aim of my master project was to purify the RNA Pol I complex as well as to further pursue the expansion of the protein-protein interaction network of the human RNA Pol II transcription machinery. By using POLR1E, TWISTNB, POLR2E, PFDN4, MBD2, XPA, CAND1 and PDCD5 TAP – tagged proteins expressed in EcR-293 cell lines, multiple soluble protein complexes were purified and analyzed by mass spectrometry. Protein interactions have been sorted and validated computationally. High-confidence dataset of interactions were used to build the protein-protein interaction networks. The network created for this project connects several components of the transcriptional machinery such as RNA Pol I, II and III, RPAP3/R2TP/prefoldin-like, TRiC/CTC, Mi-2/NuRD complexes and DNA repair and transcription factors. This type of analysis allowed us to identify and characterize new regulators of RNA Pol I and II transcription machinery and to better understand its functioning.

Machinerie de transcription

Transcription machinery

ARN polymérase

RNA polymerase

Purification TAP

TAP purification

Partenaires d'interactions

Interaction partners

Réseau d’interactions

Interaction networks

Structural Feature of Prokaryotic Promoters and their Role in Gene Expression

Aditya Kumar, *

January 2015

Transcription initiation is an important step in the process of gene regulation in prokaryotes. Promoters are stretches of DNA sequence that are present in the upstream region of transcription start sites (TSSs), where RNA polymerase and other transcription factors bind to initiate transcription. Recent advancement in sequencing technologies has resulted in huge amount of raw data in the form of whole genome sequences. This sequence data has to be annotated, in order to identify coding, non-coding and regulatory regions. Computational tools are useful for a quick and fairly reliable annotation of many genome sequences. Promoter prediction is an important step in genome annotation process which is needed, not only for the validation of predicted genes, but also for the identification of novel genes, especially those coding for non-coding RNA, which are missed by gene prediction programs. DNA sequence dependent structural properties such as DNA duplex stability, bendability and intrinsic curvature have been found to be associated with promoter regions in all domains of life. The work presented in this thesis focuses on the analysis of these structural features in the promoter regions of published prokaryotic transcriptome data. Furthermore, promoters were predicted using these structural features and their role in gene expression were studied. The organization of thesis is as follows. An overview of transcription machinery of prokaryotes, promoter architecture, available promoter prediction programs and sequence dependent structural features is presented in chapter 1. Chapter 2 describes the datasets and methods used in entire study. Structural features of promoters associated with primary and operon TSSs of H.pylori26695 genes and their orthologs (chapter 3) Promoter regions in genomic sequences from all domains of life show similar trends in their structural properties such as stability, bendability, curvature. This chapter dis-cuss the DNA duplex stability and bendability of various classes of promoter regions (based on the identification of different classes of transcription start sites, viz. primary, secondary, internal, operon TSSs etc, in transcriptome study) of Helicobacter pylori 26695 strain. It is found that the primary TSS and operon associated TSS promoters show significantly strong structural features in their promoter regions. DNA free energy based promoter prediction tool PromPredict has been used to annotate promoters of different classes and very high recall values (80%) are obtained for primary TSS. Orthologous genes from 10 different strains of H. pylori show conservation of structural properties in promoter regions as well as coding regions. PromPredict annotates promoters of orthologous genes with very high recall and precision values. DNA duplex stability of promoter region is conserved in the orthologous genes in 10 different strains of Helicobacter pylori genome. Sequence dependent structural features of promoters in prokaryotic transcriptome (chapter 4) Next-generation sequencing studies have revealed that a wide range of transcripts such as primary, internal, antisense and non-coding RNA, are present in the prokaryotic transcriptome and a large fraction of them are functionally involved in various regulatory activities. Identification of promoters associated with different transcripts is important for characterization of transcriptome. The current chapter discusses DNA sequence dependent structural properties like stability, bendability and curvature in the promoter region of six different prokaryotic transcriptomes (Helicobacter pylori, Anabaena, Synechocystis, Escherichia coli, Salmonella and Klebsiella). Using these structural features, promoters associated with different category of transcripts were predicted, which constitute an integral part of the transcriptome. Promoter annotation using structural features is fairly accurate and reliable as compared to motif-based approach since different category of transcripts show poor sequence conservation in the promoter region. Most importantly, it is universal in nature unlike sequence-based approach that is generally organism specific. Role of sequence dependent structural properties in gene expression in prokaryotes (chapter 5) DNA duplex stability, bendability and intrinsic curvature play crucial roles in the process of transcription initiation. Hence, in order to understand the relationship be-tween these structural features and gene expression, the relative differences in stability, bendability and curvature in the promoter regions of high and low expressed genes were studied. It is found that these features are relatively accentuated in the promoter regions associated with high gene expression as compared to low gene expression. Promoter regions associated with high gene expression are annotated more reliably using DNA structural features, compared to those for low gene expression. Sequence dependent structural properties in the promoter region of essential and non-essential genes of the prokaryotes (chapter 6) Essential genes are the minimal possible set of genes required for the survival of organism. These sets of genes can be identified by experiments such as single gene deletion and transposon mediated inactivation. Here, the analysis of DNA duplex stability and bendability in the promoter regions of essential and nonessential genes of prokaryotes is reported. It is found that the average free energy and bendability pro-files are distinct in the promoters regions of essential and nonessential genes. Whole genome promoter predictions using in-house program, PromPredict, for essential and nonessential genes has also been carried out. Chapter 7 present the summary and conclusion of the entire thesis work followed by future perspectives in the field. Optimization of PromPredict algorithm and updating PromBase with newly sequenced genomes (Appendix A) PromPredict is an in-house program, which is based on the relative stability of the DNA in flanking regions. It was found to perform well in predicting promoters across all organisms. In previous studies, it was observed that for organisms having low genomic GC content (<35%), promoter prediction resulted in low precision values, which indicates higher false positive rate. Threshold values of PromPredict algorithm were re-vised in order to optimize the algorithm with low false positive rate. PromBase is a comparative genomics database of microbial genomes. It stores different genomic and structural properties of the microbial genomes. It also displays the predictions obtained from PromPredict in a graphical as well as tabular format. Newly sequenced genomes were downloaded from NCBI and processed using in-house programs and added to the mysql database (back end of the PromBase). Stability profiles for predictions were also added for the RNA coding genes, earlier only profiles for protein coding genes were displayed. Comparative genomics of asymmetric gene orientation in prokaryotes (Appendix B) Transcription proceeds in 5’ to 3’ direction on the template strand, hence it provides directionality. Prokaryotic genomes show asymmetry in gene orientation on leading and lagging strands. The different phyla of prokaryotes were analyzed in terms of asymmetry in gene orientation. It is found that organisms belonging to a particular phyla known as “Firmicutes”, show high asymmetry in gene orientation, which are known to have different DNA polymerase systems for replication.

DNA Structural Biology

Prokaryotic Promoters

Prokaryotes Gene Expression

Computational Biology

Prokaryotic Transcription Machinery

Prokaryotic Trascritptome

Operon TSS

Helicobacter pylori

Prokaryotic Promoter

Prokaryotes - Gene Expression

Molecular Biophysics

Systematic analysis of protein complexes involved in the human RNA polymerase II machinery

Al-Khoury, Racha

02 1900

La transcription, la maturation d’ARN, et le remodelage de la chromatine sont tous des processus centraux dans l'interprétation de l'information contenue dans l’ADN. Bien que beaucoup de complexes de protéines formant la machinerie cellulaire de transcription aient été étudiés, plusieurs restent encore à identifier et caractériser. En utilisant une approche protéomique, notre laboratoire a purifié plusieurs composantes de la machinerie de transcription de l’ARNPII humaine par double chromatographie d’affinité "TAP". Cette procédure permet l'isolement de complexes protéiques comme ils existent vraisemblablement in vivo dans les cellules mammifères, et l'identification de partenaires d'interactions par spectrométrie de masse. Les interactions protéiques qui sont validées bioinformatiquement, sont choisies et utilisées pour cartographier un réseau connectant plusieurs composantes de la machinerie transcriptionnelle. En appliquant cette procédure, notre laboratoire a identifié, pour la première fois, un groupe de protéines, qui interagit physiquement et fonctionnellement avec l’ARNPII humaine. Les propriétés de ces protéines suggèrent un rôle dans l'assemblage de complexes à plusieurs sous-unités, comme les protéines d'échafaudage et chaperonnes. L'objectif de mon projet était de continuer la caractérisation du réseau de complexes protéiques impliquant les facteurs de transcription. Huit nouveaux partenaires de l’ARNPII (PIH1D1, GPN3, WDR92, PFDN2, KIAA0406, PDRG1, CCT4 et CCT5) ont été purifiés par la méthode TAP, et la spectrométrie de masse a permis d’identifier de nouvelles interactions. Au cours des années, l’analyse par notre laboratoire des mécanismes de la transcription a contribué à apporter de nouvelles connaissances et à mieux comprendre son fonctionnement. Cette connaissance est essentielle au développement de médicaments qui cibleront les mécanismes de la transcription. / Genomes encode most of the functions necessary for cell growth and differentiation. Gene transcription, RNA processing, and chromatin remodeling are central processes in the interpretation of the information contained in genomic DNA. Although many protein complexes forming the cellular machinery that interprets mammalian genomes have been studied, a number of additional complexes remain to be identified and characterized. Using proteomic approaches, Dr. Benoit Coulombe’s laboratory purified many components of the RNAPII transcription machinery using tandem affinity purification (TAP), a procedure that allows the isolation of protein complexes as they likely exist in live mammalian cells, and the identification of interaction partners using mass spectrometry. High confidence interactions were selected computationally and used to draw the map of a network connecting many components of the mRNA transcriptional machinery. By applying this procedure, our lab has identified, for the first time, a group of proteins, that interacts both physically and functionally with human RNAPII, and whose properties suggest a role in the assembly of multi-subunit complexes, acting as RNAPII-specific scaffolding proteins and chaperones. The aim of my project was to continue the characterization of the network of protein complexes involving transcription factors, and thus, further pursuing our survey of protein complexes in whole cell extracts. Eight novel RNAPII interaction partners (PIH1D1, GPN3, WDR92, PFDN2, KIAA0406, PDRG1, CCT4 and CCT5) were purified using the tandem affinity purification (TAP) method, and their interaction partners were identified by mass spectrometry. Over the years, our lab’s analysis of transcriptional regulation and mechanisms has contributed novel and important knowledge that provided better understanding of mRNA synthesis. This knowledge is paramount to the development of therapeutics that will target transcriptional mechanisms.

Machinerie transcriptionnelle

ARN polymérase II humaine

Purification TAP

Partenaires d'interactions

Réseau d’interactions

Transcription machinery

Human RNA polymerase II

TAP purification

Interaction partners

Interaction networks

Systematic analysis of protein complexes involved in the human RNA polymerase II machinery

Al-Khoury, Racha

02 1900

La transcription, la maturation d’ARN, et le remodelage de la chromatine sont tous des processus centraux dans l'interprétation de l'information contenue dans l’ADN. Bien que beaucoup de complexes de protéines formant la machinerie cellulaire de transcription aient été étudiés, plusieurs restent encore à identifier et caractériser. En utilisant une approche protéomique, notre laboratoire a purifié plusieurs composantes de la machinerie de transcription de l’ARNPII humaine par double chromatographie d’affinité "TAP". Cette procédure permet l'isolement de complexes protéiques comme ils existent vraisemblablement in vivo dans les cellules mammifères, et l'identification de partenaires d'interactions par spectrométrie de masse. Les interactions protéiques qui sont validées bioinformatiquement, sont choisies et utilisées pour cartographier un réseau connectant plusieurs composantes de la machinerie transcriptionnelle. En appliquant cette procédure, notre laboratoire a identifié, pour la première fois, un groupe de protéines, qui interagit physiquement et fonctionnellement avec l’ARNPII humaine. Les propriétés de ces protéines suggèrent un rôle dans l'assemblage de complexes à plusieurs sous-unités, comme les protéines d'échafaudage et chaperonnes. L'objectif de mon projet était de continuer la caractérisation du réseau de complexes protéiques impliquant les facteurs de transcription. Huit nouveaux partenaires de l’ARNPII (PIH1D1, GPN3, WDR92, PFDN2, KIAA0406, PDRG1, CCT4 et CCT5) ont été purifiés par la méthode TAP, et la spectrométrie de masse a permis d’identifier de nouvelles interactions. Au cours des années, l’analyse par notre laboratoire des mécanismes de la transcription a contribué à apporter de nouvelles connaissances et à mieux comprendre son fonctionnement. Cette connaissance est essentielle au développement de médicaments qui cibleront les mécanismes de la transcription. / Genomes encode most of the functions necessary for cell growth and differentiation. Gene transcription, RNA processing, and chromatin remodeling are central processes in the interpretation of the information contained in genomic DNA. Although many protein complexes forming the cellular machinery that interprets mammalian genomes have been studied, a number of additional complexes remain to be identified and characterized. Using proteomic approaches, Dr. Benoit Coulombe’s laboratory purified many components of the RNAPII transcription machinery using tandem affinity purification (TAP), a procedure that allows the isolation of protein complexes as they likely exist in live mammalian cells, and the identification of interaction partners using mass spectrometry. High confidence interactions were selected computationally and used to draw the map of a network connecting many components of the mRNA transcriptional machinery. By applying this procedure, our lab has identified, for the first time, a group of proteins, that interacts both physically and functionally with human RNAPII, and whose properties suggest a role in the assembly of multi-subunit complexes, acting as RNAPII-specific scaffolding proteins and chaperones. The aim of my project was to continue the characterization of the network of protein complexes involving transcription factors, and thus, further pursuing our survey of protein complexes in whole cell extracts. Eight novel RNAPII interaction partners (PIH1D1, GPN3, WDR92, PFDN2, KIAA0406, PDRG1, CCT4 and CCT5) were purified using the tandem affinity purification (TAP) method, and their interaction partners were identified by mass spectrometry. Over the years, our lab’s analysis of transcriptional regulation and mechanisms has contributed novel and important knowledge that provided better understanding of mRNA synthesis. This knowledge is paramount to the development of therapeutics that will target transcriptional mechanisms.

Machinerie transcriptionnelle

ARN polymérase II humaine

Purification TAP

Partenaires d'interactions

Réseau d’interactions

Transcription machinery

Human RNA polymerase II

TAP purification

Interaction partners

Interaction networks