Global ETD Search

21	Avaliação de riscos para LER/DORT em empresa metalúrgica : uma experiência de utilização do índice TOR-TOM e protocolo Rodgers de avaliação de posturas Souza Filho, Geraldo de Azevedo e January 2006 (has links) O presente estudo buscou identificar fatores de risco para LER/DORT em uma linha de montagem de uma empresa metalúrgica. Foram utilizados o Índice TOR-TOM – indicador ergonômico da eficácia de pausas e outros mecanismos de regulação (COUTO, 2006) e um protocolo de avaliação postural (RODGERS, 1992). Os resultados apontam a necessidade de intervenção imediata para a proteção da saúde dos trabalhadores. O Índice TOR-TOM foi elevado para os dois operadores de solda-ponto e para os dois operadores de prensas, todos com queixas de dor/desconforto/fadiga, o que foi compatível com as queixas relatadas pelos trabalhadores. O protocolo de Rodgers foi mais sensível para identificar a necessidade de adequação de postura para um dos trabalhadores afastado do trabalho por apresentar LER/DORT. A utilização concomitante das duas ferramentas se mostrou mais efetiva para identificar os fatores de risco do que qualquer uma delas isoladamente. / The study analyses the risk factors for CTD/WRMSD in an assembly line, in a metallurgic company, using the TOR-TOM index – an ergonomic indicator of the effectiveness of pauses and other mechanisms of regulation had been used (COUTO, 2006) and a protocol of postural evaluation (RODGERS, 1992). The results showed that an intervention is necessary to protect the worker’s health. The TOR-TOM index was high for two spot welders and for two press operators. All workers presented pain/discomfort/fatigue. The protocol of Rodgers was more sensible to identify the necessity of adequacy of position for one of the workers moved away from the work for presenting LER/DORT. The concomitant use of the two tools if showed more effective to identify the risk factors than any one of them separately. Ergonomia Saúde do trabalhador Lesões por esforços repetitivos CTD/WRMSD Protocols TOR-TOM Ergonomics
22	Investigations into the regulation of histone H2B monoubiquitination / Investigations into the regulation of histone H2B monoubiquitination Shchebet, Andrei 18 April 2011 (has links) No description available. 000 Allgemeines, Wissenschaft Biology (incl. Psychology) Epigenetik chromatin Histon H2B Mono-Ubiquitinierung H2BK120ub1 CDK9 RNAPII CTD-Phosphorylierung UBE2A Epigenetics chromatin histone H2B monoubiquitination H2BK120ub1 CDK9 RNAPII CTD phosphorylation UBE2A 42.13 molecular biology W
23	Functional Characterization of the Cellular Protein p32 : A Protein Regulating Adenovirus Transcription and Splicing Through Targeting of Phosphorylation Öhrmalm, Christina January 2006 (has links) <p>Cellular processes involved in the conversion of the genetic information from DNA into a protein are often regulated by reversible phosphorylation reactions. By modulating the phosphorylated status of key proteins their activity can either be enhanced or repressed. In this thesis I have studied the significance of phosphorylation in the regulation of transcription and splicing using human adenovirus as a model system.</p><p>The results show that the activity of the cellular SR family of splicing enhancer or repressor proteins are reduced in adenovirus infected nuclear extracts by a virus-induced hypophosphorylation. The viral E4-ORF4 was shown to induce SR protein dephosphorylation by recruiting the cellular protein phosphatase PP2A. The E4-ORF4/PP2A complex was shown to relieve the SR protein-mediated repression of late virus-specific splicing and further activate alternative splicing in transiently transfected cells. Collectively, these results showed that alternative splicing, like many other biological processes, is regulated by reversible protein phosphorylation.</p><p>Similarly, the cellular p32 protein was shown to cause hypophosphorylation of the SR protein ASF/SF2 resulting in a reduced RNA binding capacity of ASF/SF2. This change in ASF/SF2 RNA binding also had a drastic effect on the function of ASF/SF2 as a regulatory protein affecting splice site choice. The cellular p32 protein and the viral E4-ORF4 protein both target the same cellular splicing factor, ASF/SF2. However, they regulate splicing by different mechanisms. E4-ORF4 recruits a phosphatase to dephosphorylate ASF/SF2, while p32 sequester ASF/SF2 in an inactive complex.</p><p>Further, we demonstrated that overexpression of p32 during a lytic infection suppressed transcription from the adenovirus major late transcription unit. p32 induced a selective repression of CAAT-box containing promoters indicating the involvement of the transcription factor CBF/NF-Y in this regulation. A further analysis showed that p32 caused a hyperphosphorylation of the CTD of RNA Pol II, which resulted in a significant reduction in the processivity of Pol II during the elongation phase of transcription.</p><p>In summary, we have shown that E4-ORF4 regulates the activity of splicing regulatory SR proteins, and that p32 regulates the activity of the SR protein ASF/SF2 in splicing and Pol II processivity during transcription elongation. Mechanistically, both E4-ORF4 and p32 appears to function by regulating the phosphorylated status of key cellular proteins involved in these processes.</p> Cell and molecular biology Adenovirus p32 ASF/SF2 E4-ORF4 Splicing Transcription CTD RNA Pol II Cell- och molekylärbiologi
24	Functional Characterization of the Cellular Protein p32 : A Protein Regulating Adenovirus Transcription and Splicing Through Targeting of Phosphorylation Öhrmalm, Christina January 2006 (has links) Cellular processes involved in the conversion of the genetic information from DNA into a protein are often regulated by reversible phosphorylation reactions. By modulating the phosphorylated status of key proteins their activity can either be enhanced or repressed. In this thesis I have studied the significance of phosphorylation in the regulation of transcription and splicing using human adenovirus as a model system. The results show that the activity of the cellular SR family of splicing enhancer or repressor proteins are reduced in adenovirus infected nuclear extracts by a virus-induced hypophosphorylation. The viral E4-ORF4 was shown to induce SR protein dephosphorylation by recruiting the cellular protein phosphatase PP2A. The E4-ORF4/PP2A complex was shown to relieve the SR protein-mediated repression of late virus-specific splicing and further activate alternative splicing in transiently transfected cells. Collectively, these results showed that alternative splicing, like many other biological processes, is regulated by reversible protein phosphorylation. Similarly, the cellular p32 protein was shown to cause hypophosphorylation of the SR protein ASF/SF2 resulting in a reduced RNA binding capacity of ASF/SF2. This change in ASF/SF2 RNA binding also had a drastic effect on the function of ASF/SF2 as a regulatory protein affecting splice site choice. The cellular p32 protein and the viral E4-ORF4 protein both target the same cellular splicing factor, ASF/SF2. However, they regulate splicing by different mechanisms. E4-ORF4 recruits a phosphatase to dephosphorylate ASF/SF2, while p32 sequester ASF/SF2 in an inactive complex. Further, we demonstrated that overexpression of p32 during a lytic infection suppressed transcription from the adenovirus major late transcription unit. p32 induced a selective repression of CAAT-box containing promoters indicating the involvement of the transcription factor CBF/NF-Y in this regulation. A further analysis showed that p32 caused a hyperphosphorylation of the CTD of RNA Pol II, which resulted in a significant reduction in the processivity of Pol II during the elongation phase of transcription. In summary, we have shown that E4-ORF4 regulates the activity of splicing regulatory SR proteins, and that p32 regulates the activity of the SR protein ASF/SF2 in splicing and Pol II processivity during transcription elongation. Mechanistically, both E4-ORF4 and p32 appears to function by regulating the phosphorylated status of key cellular proteins involved in these processes. Cell and molecular biology Adenovirus p32 ASF/SF2 E4-ORF4 Splicing Transcription CTD RNA Pol II Cell- och molekylärbiologi
25	Étude de la variante d’histone H2A.Z et du cycle de phosphorylation de l’ARN polymérase II chez Saccharomyces cerevisiae Bataille, Alain R. 02 1900 (has links) La chromatine est plus qu’un système d’empaquetage de l’ADN ; elle est le support de toutes les réactions liées à l’ADN dans le noyau des cellules eucaryotes et participe au contrôle de l’accès de l’ARN polymérase II (ARNPolII) à l’ADN. Responsable de la transcription de tous les ARNm des cellules eucaryotes, l’ARNPolII doit, suivant son recrutement aux promoteurs des gènes, transcrire l’ADN en traversant la matrice chromatinienne. Grâce au domaine C-terminal (CTD) de sa sous-unité Rpb1, elle coordonne la maturation de l’ARNm en cours de synthèse ainsi que les modifications de la chromatine, concomitantes à la transcription. Cette thèse s’intéresse à deux aspects de la transcription : la matrice, avec la localisation de la variante d’histone H2A.Z, et la machinerie de transcription avec le cycle de phosphorylation du CTD de l’ARNPolII. Suivant l’introduction, le chapitre 2 de cette thèse constitue un protocole détaillé et annoté de la technique de ChIP-chip, chez la levure Saccharomyces cerevisiae. Cette technique phare dans l’étude in vivo des phénomènes liés à l’ADN a grandement facilité l’étude du rôle de la chromatine dans les phénomènes nucléaires, en permettant de localiser sur le génome les marques et les variantes d’histones. Ce chapitre souligne l’importance de contrôles adéquats, spécifiques à l’étude de la chromatine. Au chapitre 3, grâce à la méthode de ChIP-chip, la variante d’histone H2A.Z est cartographiée au génome de la levure Saccharomyces cerevisiae avec une résolution d’environ 300 paires de bases. Nos résultats montrent que H2A.Z orne un à deux nucléosomes au promoteur de la majorité des gènes. L’enrichissement de H2A.Z est anticorrélé à la transcription et nos résultats suggèrent qu’elle prépare la chromatine pour l’activation des gènes. De plus H2A.Z semble réguler la localisation des nucléosomes. Le chapitre suivant s’intéresse à la transcription sous l’angle de la machinerie de transcription en se focalisant sur le cycle de phosphorylation de l’ARN polymérase II. Le domaine C-terminal de sa plus large sous-unité est formé de répétitions d’un heptapeptide YSPTSPS dont les résidus peuvent être modifiés au cours de la transcription. Cette étude localise les marques de phosphorylation des trois résidus sérine de manière systématique dans des souches mutantes des kinases et phosphatases. Nos travaux confirment le profil universel des marques de phosphorylations aux gènes transcrits. Appuyés par des essais in vitro, ils révèlent l’interaction complexe des enzymes impliqués dans la phosphorylation, et identifient Ssu72 comme la phosphatase de la sérine 7. Cet article appuie également la notion de « variantes » des marques de phosphorylation bien que leur étude spécifique s’avère encore difficile. La discussion fait le point sur les travaux qui ont suivi ces articles, et sur les expériences excitantes en cours dans notre laboratoire. / Chromatin is more than just the eucaryotic DNA packaging system; it is the substrate of all reactions involving DNA in eukaryotic cells and actively regulates RNA Polymerase II (RNAPolII) access to DNA. Responsible for all mRNA transcription in eucaryotes, the RNAPolII must, following its recruitment to the pre-initiation complex, overcome the chromatin barrier in order to transcribe genes. The RNAPolII CTD allows for the co-transcriptional coordination of mRNA maturation and chromatin modifications. The work covered in this thesis addresses two aspects of transcription: the chromatin substrate, with the localization of H2A variant, H2A.Z, and the transcription complex with the phosphorylation cycle of the RNAPolII CTD. Following the introduction, chapter 2 constitutes a detailed and annotated Saccharomyces cerevisiae ChIP-chip protocol, from the culture to the hybridization of the array, with an emphasis on the proper controls required for chromatin study. This technique, extremely powerful for the in vivo study of all DNA transactions, leads to a better understanding of chromatin function in nuclear phenomena, thanks to the localization of histone variants and modifications. The third chapter maps the H2A.Z variant across the yeast genome at ~300 base pairs resolution using ChIP-chip. Our data shows that H2A.Z is incorporated into one or two promoter-bound nucleosomes at the majority of genes. H2A.Z enrichment is anticorrelated with transcription, and the results suggest that it configures chromatin structure to poise genes for transcriptional activation. Furthermore, we have shown that H2A.Z can regulate nucleosome positioning. The next chapter focuses on the transcription machinery and, more precisely, on the phosphorylation cycle of RNAPolII. The CTD contains repetitions of a heptapeptide (YSPTSPS) on which all serines are differentially phosphorylated along genes in a prescribed pattern during the transcription cycle. Here, we systematically profiled the location of the RNAPII phospho-isoforms in wild-type cells and mutants for most CTD modifying enzymes. The results provide evidence for a uniform CTD cycle across genes. Together with results from in vitro assays, these data reveal a complex interplay between the modifying enzymes, identify Ssu72 as the Ser7 phosphatase and show that proline isomerization is a key regulator of CTD dephosphorylation at the end of genes. Moreover, it reinforces the notion of variants of the phosphorylation marks, even though the exact nature of the variant is still difficult to identify. The discussion introduces the studies that followed this work, including new projects conceived in our lab. Immunoprécipitation de la chromatine Chromatine H2A.Z Transcription ARN polymérase II Chromatin Immunoprecipitation Chromatin RNA polymérase II CTD Kin28 Bur1 Ssu72 Fcp1
26	Caractérisation du domaine C-terminal de l'ARN polymérase II et de la phosphatase Glc7 dans la terminaison transcriptionnelle chez Saccharomyces cerevisiae Collin, Pierre 12 1900 (has links) No description available. Terminaison transcriptionnelle ARN polymérase II CTD Tyrosine 1 pause Nrd1 Sen1 Glc7 Pcf11 Rtt103 Transcription termination RNA polymerase II pausing
27	Atlantic-Caribbean Exchange through Windward Passage Smith, Ryan Hunter 01 January 2010 (has links) Windward Passage, which separates the islands of Cuba and Hispaniola, has been recognized as an important inflow channel to the Caribbean Sea for nearly a century. Despite this fact, few direct measurements of the volume transport through the passage exist. In an effort to gain a more comprehensive understanding of the variability, structure, and mean transport associated with flow through Windward Passage, the University of Miami?s Rosenstiel School of Marine and Atmospheric Science (RSMAS) and the National Oceanic and Atmospheric Administration (NOAA)?s Atlantic Oceanographic and Meteorological Laboratory (AOML) conducted a targeted research study of the passage and surrounding region from October 2003 through February 2005. The project deployed a moored current meter array across the passage and conducted four regional hydrographic surveys. Velocity sections collected across Windward Passage during the four cruises from lowered and hull-mounted acoustic Doppler current profilers show a highly variable field dominated by small-scale eddy features and other areas of locally-intensified flow. However, when integrated horizontally across the passage, the resulting transport-per-unit-depth profiles reveal a remarkably robust vertical shear structure. A net inflow of surface and thermocline waters was observed over the four cruises. Beneath these layers, a persistent outflow of intermediate water was found, intensified along the east side of the passage. Deep inflow, just above the sill depth maximum (1680 m), was observed on cruise #1 and, based on data from the moored current meter record, was determined to be a regular flow feature. Together, project velocity sections and water mass analyses of Windward and surrounding passages suggest that Surface Water (SFC), Subtropical Underwater (SUW), and Central Water (CW) primarily arrive at Windward Passage from the east via the Hispaniola Basin. A majority of SFC and SUW enters the Cayman Basin through Windward Passage, while the arriving CW bifurcates, with slightly more than half bypassing the passage and continuing westward north of Cuba. An intermediate water outflow pathway from the Cayman to the Hispaniola Basin via Windward Passage was also observed. Much of this outflow possessed a salinity signature characteristic of upstream inflow regions immediately to the east and south of the Lesser Antilles. Total Windward Passage transport, calculated from the four ship surveys, was found to be an inflow of 3.0 ±2.8 Sverdrups (1 Sv ≡ 10^6 m^3 s^-1). Data from the 16-month moored current meter array yielded a larger mean inflow of 5.0 ±1.6 Sv. These numbers are lower than previous estimates based on regional passage transport differences, and suggest that more transport may be entering the Florida Current system through passages in the Bahamas (the Northwest Providence and Old Bahama Channels) than previously thought, with proportionately less flow entering the system through the Caribbean Sea.
28	Microsystems Technology for Underwater Vehicle Applications Jonsson, Jonas January 2012 (has links) The aim of this thesis work has been to investigate how miniaturization, such as microsystems technology, can potentially increase the scientific throughput in exploration of hard-to-reach underwater environments, such as the subglacial lakes of Antarctica, or other challenging environments, including cave systems and wrecks. A number of instruments and subsystems applicable to miniature submersibles have been developed and studied, and their potential to provide a high functionality density for size-restricted exploration platforms has been assessed. To provide an onboard camera system with measurement capabilities, simulation and design tools for diffractive optics were developed, and microoptics realized to project reference patterns onto objects to reveal their topography. The influence of murky water on the measurement accuracy was also studied. For longer-range mapping of the surroundings, and under conditions with even less visibility, the performance of a very small, high-frequency side-scanning sonar was investigated using extensive modeling and physical testing. In particular, the interference on the acoustic beam from tight mounting in a hull was investigated. A range in excess of 30 m and centimeter resolution were obtained. Besides these systems, which can be used to navigate and map environments, a two-dimensional, thermal sensor for minute flows was developed. Measuring speed and direction of water flows, this sensor can aid in the general classification of the environment and also monitor the submersible’s movement. As the flow of waters in subglacial lakes is estimated to be minute, the detection limit and sensitivity were investigated. Measurements of water properties are facilitated by the chip-based conductivity, temperature, and depth sensor system developed. Macroscopically, this is an essential oceanographic instrument with which salinity is determined. Contrary to what was expected, MHz frequencies proved to be advantageous for conductivity measurements. Finally, sampling of water using an acoustically enriching microdevice, and even enabling return of pristine samples via the use of integrated latchable, high-pressure valves, was realized and evaluated. Particularly, investigations of the device’s ability to capture and hold on to microorganisms, were conducted. Further developed and studied, these devices – as subsystems to miniature submersibles, or as stand-alone instruments – should enable exploration of previously unreachable submerged environments. / Deeper Access, Deeper Understanding (DADU) Aquatic Submersible Underwater Micro Miniaturized Sonar Sidescan Topography Laser Diffractive Optics Sampler Particle Microorganism Acoustic Enriching Conductivity Temperature Depth CTD Flow
29	Étude de la variante d’histone H2A.Z et du cycle de phosphorylation de l’ARN polymérase II chez Saccharomyces cerevisiae Bataille, Alain R. 02 1900 (has links) La chromatine est plus qu’un système d’empaquetage de l’ADN ; elle est le support de toutes les réactions liées à l’ADN dans le noyau des cellules eucaryotes et participe au contrôle de l’accès de l’ARN polymérase II (ARNPolII) à l’ADN. Responsable de la transcription de tous les ARNm des cellules eucaryotes, l’ARNPolII doit, suivant son recrutement aux promoteurs des gènes, transcrire l’ADN en traversant la matrice chromatinienne. Grâce au domaine C-terminal (CTD) de sa sous-unité Rpb1, elle coordonne la maturation de l’ARNm en cours de synthèse ainsi que les modifications de la chromatine, concomitantes à la transcription. Cette thèse s’intéresse à deux aspects de la transcription : la matrice, avec la localisation de la variante d’histone H2A.Z, et la machinerie de transcription avec le cycle de phosphorylation du CTD de l’ARNPolII. Suivant l’introduction, le chapitre 2 de cette thèse constitue un protocole détaillé et annoté de la technique de ChIP-chip, chez la levure Saccharomyces cerevisiae. Cette technique phare dans l’étude in vivo des phénomènes liés à l’ADN a grandement facilité l’étude du rôle de la chromatine dans les phénomènes nucléaires, en permettant de localiser sur le génome les marques et les variantes d’histones. Ce chapitre souligne l’importance de contrôles adéquats, spécifiques à l’étude de la chromatine. Au chapitre 3, grâce à la méthode de ChIP-chip, la variante d’histone H2A.Z est cartographiée au génome de la levure Saccharomyces cerevisiae avec une résolution d’environ 300 paires de bases. Nos résultats montrent que H2A.Z orne un à deux nucléosomes au promoteur de la majorité des gènes. L’enrichissement de H2A.Z est anticorrélé à la transcription et nos résultats suggèrent qu’elle prépare la chromatine pour l’activation des gènes. De plus H2A.Z semble réguler la localisation des nucléosomes. Le chapitre suivant s’intéresse à la transcription sous l’angle de la machinerie de transcription en se focalisant sur le cycle de phosphorylation de l’ARN polymérase II. Le domaine C-terminal de sa plus large sous-unité est formé de répétitions d’un heptapeptide YSPTSPS dont les résidus peuvent être modifiés au cours de la transcription. Cette étude localise les marques de phosphorylation des trois résidus sérine de manière systématique dans des souches mutantes des kinases et phosphatases. Nos travaux confirment le profil universel des marques de phosphorylations aux gènes transcrits. Appuyés par des essais in vitro, ils révèlent l’interaction complexe des enzymes impliqués dans la phosphorylation, et identifient Ssu72 comme la phosphatase de la sérine 7. Cet article appuie également la notion de « variantes » des marques de phosphorylation bien que leur étude spécifique s’avère encore difficile. La discussion fait le point sur les travaux qui ont suivi ces articles, et sur les expériences excitantes en cours dans notre laboratoire. / Chromatin is more than just the eucaryotic DNA packaging system; it is the substrate of all reactions involving DNA in eukaryotic cells and actively regulates RNA Polymerase II (RNAPolII) access to DNA. Responsible for all mRNA transcription in eucaryotes, the RNAPolII must, following its recruitment to the pre-initiation complex, overcome the chromatin barrier in order to transcribe genes. The RNAPolII CTD allows for the co-transcriptional coordination of mRNA maturation and chromatin modifications. The work covered in this thesis addresses two aspects of transcription: the chromatin substrate, with the localization of H2A variant, H2A.Z, and the transcription complex with the phosphorylation cycle of the RNAPolII CTD. Following the introduction, chapter 2 constitutes a detailed and annotated Saccharomyces cerevisiae ChIP-chip protocol, from the culture to the hybridization of the array, with an emphasis on the proper controls required for chromatin study. This technique, extremely powerful for the in vivo study of all DNA transactions, leads to a better understanding of chromatin function in nuclear phenomena, thanks to the localization of histone variants and modifications. The third chapter maps the H2A.Z variant across the yeast genome at ~300 base pairs resolution using ChIP-chip. Our data shows that H2A.Z is incorporated into one or two promoter-bound nucleosomes at the majority of genes. H2A.Z enrichment is anticorrelated with transcription, and the results suggest that it configures chromatin structure to poise genes for transcriptional activation. Furthermore, we have shown that H2A.Z can regulate nucleosome positioning. The next chapter focuses on the transcription machinery and, more precisely, on the phosphorylation cycle of RNAPolII. The CTD contains repetitions of a heptapeptide (YSPTSPS) on which all serines are differentially phosphorylated along genes in a prescribed pattern during the transcription cycle. Here, we systematically profiled the location of the RNAPII phospho-isoforms in wild-type cells and mutants for most CTD modifying enzymes. The results provide evidence for a uniform CTD cycle across genes. Together with results from in vitro assays, these data reveal a complex interplay between the modifying enzymes, identify Ssu72 as the Ser7 phosphatase and show that proline isomerization is a key regulator of CTD dephosphorylation at the end of genes. Moreover, it reinforces the notion of variants of the phosphorylation marks, even though the exact nature of the variant is still difficult to identify. The discussion introduces the studies that followed this work, including new projects conceived in our lab. Immunoprécipitation de la chromatine Chromatine H2A.Z Transcription ARN polymérase II Chromatin Immunoprecipitation Chromatin RNA polymérase II CTD Kin28 Bur1 Ssu72 Fcp1
30	Study Of Rpb4, A Component Of RNA Polymerase II As A Coordinator Of Transcription Initiation And Elongation In S. Cerevisiae Deshpande, Swati January 2013 (has links) (PDF) RNA polymerase II (Pol II) is the enzyme responsible for the synthesis of all mRNAs in eukaryotic cells. As the central component of the eukaryotic transcription machinery, Pol II is the final target of transcription regulatory pathways. While the role for different Pol II associated proteins, co-activators and general transcription factors (GTFs) in regulation of transcription in response to different stimuli is well studied, a similar role for some subunits of the core Pol II is only now being recognized. The studies reported in this thesis address the role of the fourth largest subunit of Pol II, Rpb4, in transcription and stress response using Saccharomyces cerevisiae as the model system. Rpb4 is closely associated with another smaller subunit, Rpb7 and forms a dissociable complex (Edwards et al. 1991). The rpb4 null mutant is viable but is unable to survive at extreme temperatures (>34ºC and <12ºC) (Woychik and Young, 1989). This mutant has also been shown to be defective in activated transcription and unable to respond adequately to several stress conditions (Pillai et al. 2001; Sampath and Sadhale, 2005). In spite of wealth of available information, the exact role of Rpb4 in transcription process remains poorly understood. In the present work, we have used genetic, molecular and biochemical approaches to understand the role of Rpb4 as described in three different parts below: I. Role of Rpb4 in various pathways related to Transcription Elongation The genome-wide recruitment study of RNA pol II in presence and absence of Rpb4 has indicated role of Rpb4 in transcription elongation (Verma-Gaur et al. 2008). However, a recent proteomics based report has argued against it (Mosley et al. 2013). To address this conflict and understand Rpb4 functions, we monitored recruitment of RNA pol II on a few individual long genes in wild type and rpb4∆ cells. It was observed that RNA pol II recruitment on genes with longer coding regions is not significantly affected in rpb4∆ as compared to wild type thus ruling out role of Rpb4 in transcription elongation of these genes. However, our genetic interaction studies have shown a strong interaction (synthetic lethality) between RPB4 and the PAF1 and SPT4 genes, the products of which code for well-known transcription elongation factors. The studies based on Rpb4 overexpression in mutants for elongation factors, 6-Azauracil sensitivity of cells, effect of Dst1 overexpression in rpb4∆ cells and mitotic recombination rate in rpb4∆ cells have indicated functional interactions of Rpb4 with many of the transcription elongation factors. II. Studies on Genetic and Functional Interactions of Rpb4 with SAGA Complex in Promoter- Specific Transcription Initiation To carry out transcription, RNA pol II depends on several general transcription factors, mediators, activators, co-activators and chromatin remodeling complexes. In the present study, we explored the genetic and functional relationships between Rpb4 and the SAGA complex of transcription machinery, to gain some insight on the role of Rpb4 during transcription. Our chromatin immunoprecipitation data suggest that RNA pol II does not associate with promoters of heat shock genes during transcription activation of these heat stress induced genes in absence of Rpb4. SAGA coactivator complex is required for RNA pol II recruitment and transcription activation of these genes (Zanton and Pugh, 2004). However, recruitment of the SAGA complex at promoters of these heat shock genes was not affected in rpb4∆ cells after heat stress. Our genetic interaction analysis between RPB4 and components of SAGA complex (spt20∆) showed synthetic lethality indicating that fully functional Rpb4 and SAGA complex are required for cellular functions in the absence of heat stress and the simultaneous deletion of factors in the two complexes leads to cell death. III. Role of Rpb4 in phosphorylation cycles of Rpb1-CTD The C-Terminal Domain (CTD) of Rpb1 protein of RNA pol II undergoes several rounds of phosphorylation cycles at Ser-2 and Ser-5 residues on its heptad repeats during transcription. These phosphorylation marks are to be erased before the start of next round of transcription. Using protein pull down assay, we observed that hyperphosphorylated form of Rpb1 is reduced in rpb4∆ as compared to that seen in wild type cells among the free RNA pol II molecules. The level of Rpb2 protein was unaffected in both wild type and rpb4∆. These preliminary data hints at role of Rpb4 in the regulation of Rpb1 phosphorylation. Yeast Genetics RNA Polymerase Saccharomyces cerevisiae RNA Transcription Rpb4 RNA Polymerase II Genetic Transcription Rpb1-CTD RNA Pol II Biochemical Genetics

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