Global ETD Search

1	Transcriptional Regulatory Mechanisms of Ribosomal Protein Genes Uprety, Bhawana 01 August 2015 (has links) Ribosomal protein genes are crucial for ribosome biogenesis. The ribosome itself is responsible for protein synthesis and hence cellular growth and development. Intertwining network of proteins in conjugation with cellular environment such as nutrition and growth factors collectively regulate expression of the ribosomal protein genes. DNA microarray analysis has implicated the role of 26S proteasome in transcriptional regulation of the ribosomal protein genes tying protein degradation to protein synthesis pathway. To determine the mechanism as to how the 26S proteasome promotes transcription of the ribosomal protein genes a series of experiments were performed. The results reveal that the 19S subcomplex of the 26S proteasome is recruited to the promoters of the ribosomal protein genes in a TOR (Target of Rapamycin)-dependent manner. TOR signals environmental cues and controls the expression of the ribosomal protein genes. Thus recruited 19S proteasome subcomplex promotes transcriptional initiation via facilitation of the recruitment of co-activator NuA4 (Nucleasome acetyltransferase of histone H4) complex to activator Rap1. NuA4 enhances PIC (Pre-initiation complex) formation at the core promoter, but it is not clearly understood how does it do so. Researches have identified two different forms of TBP: TAF (TBP associated factor)-dependent form of TBP and TAF-independent form of TBP. This work shows that impaired association of NuA4 interferes with TFIID recruitment, but recruits TAF-independent form of TBP to the core promoter. This recruitment of TBP is dependent on SAGA (Spt-Ada-Gcn5-acetyltransferase). Like ribosomal protein genes, antisense transcription is also enhanced by TAFs. However, it remains unknown whether NuA4 also promotes TAF-regulated antisense transcription. The results illustrate that like ribosomal protein genes, transcription of GAL10 antisense is also promoted by NuA4 HAT (histone acetyl transferase). NuA4 HAT is recruited to the 3’-end of the GAL10 coding sequence, acetylates histone H4 and promotes GAL10 antisense transcription. This work also reveals the roles of other chromatin regulatory factors in controlling antisense transcription. Collectively, these results significantly advance our current understanding of the regulatory mechanisms of ribosomal protein genes’ expression and antisense transcription. The ribosome and antisense are involved in virtually all the biological processes. Aberrant expression of the ribosomal protein genes and antisense transcripts are associated with numerous human disorders including cancers and cardiovascular diseases. Therefore, analyses of their regulatory processes provide valuable information toward understanding the etiology of numerous human diseases with potential therapeutic interventions. Antisense NuA4 Proteasome Ribosomal protein genes TOR Transcription initiation
2	ISOLATION AND CHARACTERIZATION OF A SECOND PROTEIN L-ISOASPARTYL METHYLTRANSFERASE GENE IN ARABIDOPSIS THALIANA Xu, Qilong 01 January 2004 (has links) Conversion of aspartate and asparagine residues to isoaspartate is a prevalent covalent protein modification in cells. The accumulation of these altered residues can lead to the loss of protein function and the consequent loss of cellular function. The L-ISOASPARTATE METHYLTRANSFERASE (EC 2.1.1.77) (PIMT) iteratively methylates abnormal isoaspartyl residues leading to conversion to L-aspartate, thereby mitigating the injurious effects of aging. Arabidopsis thaliana is unique among eukaryotes studied to date in that it possesses two genes (At3g48330 (PIMT1) and At5g50240 (PIMT2)) encoding PIMT. The PIMT2 gene exhibits a complex transcriptional control involving different transcriptional initiation sites and 5'- and 3'- alternative splice site selection in the first intron. Varying the transcriptional initiation site results in alternative targeting of the PIMT2 proteins thus produced to: 1) the nucleus, or 2) the cytoplasm, while PIMT1 is cytosolic. Inclusion of a 51 nucleotide 5 alternatively spliced sequence with or without a nine nucleotide 3 alternatively spliced sequence dramatically alteres the subcellular protein localization from the cytoplasm and around the chloroplast to inside the chloroplast. All recombinant PIMT2 isoform tested exhibit PIMT activity, although solubility varied among them. Multiplex RT-PCR was used to establish PIMT1 and PIMT2 transcript presence and abundance, relative to -TUBULIN, in various tissues and under a variety of stresses imposed on seeds and seedlings. PIMT1 transcript is constitutively present but can increase, along with PIMT2, in developing seeds presumably in response to increasing endogenous ABA. Transcript from PIMT2 also increases in establishing seedlings due to exogenous ABA application or applied stress presumably through an ABA-dependent pathway. Furthermore, Cleaved Amplified Polymorphic Sequence analysis of the PIMT2 amplicons has shown that the ratio among the splicing variants alters upon ABA application, implicating a role for the spliceosome or differential RNA stability in orchestrating the plant's response to stress. T-DNA insertional mutants of both genes were isolated but no obvious phenotype has been identified. The double mutant has been generated and will be evaluated.
3	Transcriptional regulation of the human system a amino acid transporter, snat2 gene by amino acid availability Palii, Stela S., January 2004 (has links) Thesis (Ph.D.)--University of Florida, 2004. / Typescript. Title from title page of source document. Document formatted into pages; contains 210 pages. Includes Vita. Includes bibliographical references.
4	Structure of the Pol II initation complex with TFIIH and core Mediator and mechanistic implications for transcription Schilbach, Sandra 19 February 2018 (has links) No description available. 570 transcription initiation RNA polymerase II Mediator TFIIH macromolecular complex cryo-EM XL-MS Biologie (PPN619462639)
5	Genome-wide analysis of transcription initiation and promoter architecture in eukaryotes Raborn, R. Taylor 01 January 2012 (has links) The transcriptome represents the entirety of RNA molecules within a cell or tissue at a given time. Recent advances have facilitated the production of large-scale, global interrogations of transcriptomes, finding that genomes are extensively transcribed and contain diverse classes of RNAs (Dinger et al., 2009). Information generated by high-throughput analyses of mRNA transcription start sites (TSSs) such as CAGE (Cap Analysis of Gene Expression) indicate that eukaryotic genomes have complex landscapes of transcription initiation. The TSS is important for the annotation of cis-regulatory sequences, because it provides a link between the mRNA transcript and the promoter. The patterns of TSS distributions observed within mRNA 5' end profiling studies prevent straightforward annotation of putative promoters. To address this challenge, we developed a method to identify- on a genome-wide basis- the putative promoter, which we define by TSS distributions and designate the transcription start region (TSR). We applied a clustering method to identify and annotate TSRs within the budding yeast Saccharomyces cerevisiae using a full-length cDNA dataset (Miura et al., 2006). To validate these TSR annotations, we performed an integrative genomic analysis using multiple datasets. Our method identified TSRs at positions consistent with bona fide promoters in S. cerevisiae. In addition, using 5'RACE, we find overall agreement between computationally-defined TSRs and TSSs identified experimentally. From this analysis, we find that a significant proportion of genes exhibiting alternative promoter usage within sporulation are associated with respiration, suggesting that this is regulated on a condition-specific basis in budding yeast. We further developed our TSS clustering method into a bioinformatics tool called TSRchitect, which identifies and annotates TSRs from large-scale TSS profiling information. TSRchitect is capable of handling both tag and sequence-based TSS information and efficiently computes TSRs from global TSS datasets on a desktop computer. We find support for TSRchitect's annotations in human from a CAGE experiment from the ENCODE (Encyclopedia of DNA Elements) project. Finally, we use TSRchitect to identify TSRs from the transcriptomes of diverse eukaryotes. We investigated the conservation of TSRs among orthologous genes. We frequently identify multiple TSRs for a given gene, suggesting that alternative promoter usage is widespread. Overall, using TSS profiling data derived from separate tissues within mouse and human, we find that the positions of TSRs are relatively stable across tissues surveyed; however, a small fraction of genes exhibit tissue-specific differences in TSR use. As transcriptome profiling information continues to be generated at an rapid pace, computational approaches are increasingly important. It is anticipated that the method and approach we describe within this dissertation will contribute to an improved of gene regulation and promoter architecture in eukaryotes. Bioinformatics Comparative Genomics Promoter annotation Transcription Initiation Transcription Start Site Transcriptome Biology
6	The impacts of the widely used herbicide atrazine on epigenetic processes of meiosis and transgenerational inheritance / Impact d’un herbicide largement utilisé, l’atrazine, sur les régulations épigénétiques de la méiose et l’héritage transgénérationel Hao, Chunxiang 07 July 2016 (has links) Les facteurs environnementaux, tels que les pesticides, peuvent induire des changements phénotypiques dans une variété d'organisme incluant les mammifères. Nous avons étudié chez la souris les effets d'un pesticide largement utilisé, l'atrazine (ATZ), sur la méiose, une étape clé du processus de spermatogenèse. L'utilisation des méthodes de puces à ADN (Gene-Chip) et de séquençage de chromatine immunoprécipité (ChIP-seq) nous a permis de mettre en évidence l'effet de l'ATZ sur une variété de fonctions cellulaires, incluant l'activité GTPase, la fonction mitochondriale et le métabolisme des hormones stéroïdes. De plus, les souris traitées présentent un enrichissement des marques d'histone H3K4me3 au niveau des régions de forte recombinaison (sites de cassures double brin) de gènes très long et une réduction de ces mêmes marques au niveau des régions pseudo-autosomal du chromosome X. Nos données démontrent que l'exposition à l'ATZ interfère avec le déroulement normal de la méiose, ceci affectant la production des spermatozoïdes. Nous avons trouvé que les marques H3K4me3, chez la souris mâle, sont largement affectées par l'ATZ grâce à l'utilisation de technique de séquençage du génome entier. La reprogrammation embryonnaire nécessite l'action coordonnée d'un grand nombre de gène et de facteurs épigénétiques afin de permettre la transition de cellules somatique en cellules germinales. Les modifications épigénétiques imposées pendant la transition des cellules somatiques en cellules germinales et affectées par des expositions nocives, peuvent être héritées et transmises aux générations suivantes via les gamètes. Dans cette étude, nous avons examiné l'héritage des histones modifié aux générations suivantes. Nous avons exposés des femelles gestantes CD1 non consanguines à l'ATZ et les mâles issus de ces femelles ont été croisés pendant trois générations avec des femelles non traitées. Nous avons démontré ici que l'exposition à l'ATZ réduit le nombre de spermatozoïdes sans affecter la morphologie cellulaire ou la proportion des différents types cellulaires constituant l'épithélium séminifère chez les individus issus de la 3ème génération après traitement. Beaucoup de gènes associés avec la réparation de l'ADN, la reproduction et les fonctions mitochondriales sont dérégulés chez les mâles issus de la 3ème génération après traitement. De façon importante, l'exposition à l'ATZ change dramatiquement l'initiation de la transcription, l'épissage et la polyadénylation alternative des ARN. Nous avons aussi observé chez les mâles F3 issus de souris traitées à l'ATZ une altération de la localisation des marques H3K4me3 dans le promoteur de gène associé à la régulation de processus métaboliques cellulaires, à la régulation de la transcription et à la mitose. Les changements de localisation des marques H3K4me3 chez les mâles F3 issus de souris traitées à l'ATZ correspondent à des changements de la localisation de ces marques au niveau de gènes impliqués dans la différenciation des cellules de type souche de la génération F1.Nos données suggèrent que l'héritage transgénérationnel est permis grâce à de multiples voies et repose sur le statut épigénétique de gènes impliqués dans la différenciation des cellules de type souches tels que Pou5f1 et Sox2, l'action des facteurs de transcription et la rétention d'histones dans le sperme. / Environmental factors such as pesticides can cause phenotypic changes in various organisms, including mammals. We studied the effects of the widely used herbicide atrazine (ATZ) on meiosis, a key step of gametogenesis, in male mice. We demonstrate that exposure to ATZ reduces testosterone levels and the number of spermatozoa in the epididymis and delays meiosis. Using Gene-Chip and ChIP-Seq analysis of H3K4me3 marks, we found that a broad range of cellular functions, including GTPase activity, mitochondrial function and steroid-hormone metabolism, are affected by ATZ. Furthermore, treated mice display enriched histone H3K4me3 marks in regions of strong recombination (double-strand break sites), within very large genes and reduced marks in the pseudoautosomal region of X chromosome. Our data demonstrate that atrazine exposure interferes with normal meiosis, which affects spermatozoa production.We found that the H3K4me3 marks in male mice are broadly affected by the widely used herbicide atrazine with genome wide ChIP-sequencing. Embryonic reprogramming requires the coordinated action of many genes and epigenetic factors to perform somatic to germline transition. The epigenetic modifications imposed during somatic to germline transition and affected by harmful exposure can be inherited and transferred to subsequent generations via the gametes. In this study, we examine the inheritance of altered histone modifications by subsequent generations. We exposed pregnant outbred CD1 female mice to the widely used herbicide atrazine (ATZ), and the male progeny were crossed for three generations with untreated females. We demonstrate here that exposure to ATZ reduces the number of spermatozoa without changing the cell morphology or types in testis tissue in the third generation after treatment. Many genes associated with DNA repair, reproduction and mitochondrial function became dysregulated in the third generation (F3) of males after treatment. Importantly, exposure to ATZ dramatically changes the transcription initiation, splicing and alternative polyadenylation of RNA. We also observed altered occupancy of H3K4me3 markers in the F3 generation of ATZ-derived males in gene promoters associated with the regulation of cellular metabolic processes, transcriptional regulation and mitosis. The changes in H3K4me3 occupancy in F3 ATZ-derived males correspond to changes in the H3K4me3 occupancy of stem cell differentiation genes in the F1 generation. Our data suggest that transgenerational inheritance is accomplished through multiple pathways and relies on the epigenetic state of stem cell differentiation genes such as Pou5f1 and Sox2, transcription factor action and sperm histone retention. ChIP-Seq H3K4me3 ARN-Seq L'héritage transgénérationnel ChIP-Seq H3K4me3 RNA-Seq Alternative transcription initiation Transgenerational inheritance
7	Vliv promotorové sekvence na využití NAD+ jako substrátu pro iniciaci transkripce RNA polymerázou / Effect of promoter sequence on utilization of NAD+ as a substrate for transcription initiation by RNA polymerase Pinkas, Daniel January 2018 (has links) For a long time, 5' cap has been thought to be privilege only for eukaryotic organisms in form of 7-methylguanosine cap at the end of mRNA. This was changed only a few years ago. By using methods liquid chromatography and mass spectrometry a new molecule associated with RNA of Escherichia coli has been found. This molecule turned out to be nicotinamide adenine dinucleotide (NAD+ ) attached to 5' end of some small regulatory RNAs (sRNA). Later it has been shown, that RNA polymerase can attach NAD+ at 5' of RNA ab initio, meaning that RNA polymerase can utilize NAD+ as a substrate for transcription initiation. To some extent substrate for transcription initiation is chosen based on promoter sequence. Crucial requirement is presence of adenine at +1 position of DNA coding strand. This thesis focuses on promoter sequence requirements for transcription initiation with NAD+ . As a template for transcription four promoters with different modifications and their chimeras are used: RNA1, Pveg, lac UV5 and rrnB P1. Also, I tried to compare RNA polymerase from E. coli and B. subtilis in terms of transcription initiation substrate usage. Lastly, I describe here isolation of NudC, enzyme that cleaves NAD+ to nicotinamide mononucleotide (NMN) and adenosine monophosphate (AMP). NudC will be used for upcoming...
8	TRANSLATIONAL REGULATORY MECHANISMS OF THE RAT AND HUMAN MULTIDRUG RESISTANCE PROTEIN 2 Zhang, Yuanyuan 01 January 2008 (has links) Multidrug resistance protein 2 (MRP2) is the second member the C subfamily in the superfamily of adenosine triphosphate (ATP)-binding cassette (ABC) efflux transporters. MRP2 is a critical player for generation of bile acidindependent bile flow and biliary excretion of glutathione, glucuronate and sulfate conjugates of endo- and xenobiotics. Dysfunctional expression of MRP2 is associated with Dubin-Johnson Syndrome. Pathological and physiological states or xenobiotics change the MRP2 expression level. Under some conditions, expression of the human MRP2 and rat Mrp2 proteins are regulated at the translation level. There are several transcription initiation sites in MRP2/Mrp2 gene. The 5’ untranslated regions (5’UTRs) of MRP2/Mrp2 contains multiple translation start codons. The focus of this study, therefore, was investigation of the translational regulatory mechanisms mediated by the upstream open reading frames (uORF) of MRP2/Mrp2. Using in vitro translation assays and transient cotransfection assays in HepG2 cells, we showed that the rat uORF1 starting at position -109 (relative to the ATG of Mrp2) and the human uORF2 starting at position -105 (relative to the ATG of MRP2) are two major cis-acting inhibitors of translation among the rat and human multiple uORFs, respectively. Translational regulation mediated by the uORFs in the rat Mrp2 mRNA is a combined effect of the leaky scanning model and the reinitiation model, and also results from interaction of the multiple uORFs. In addition, by Ribonuclease Protection Assays (RPA), we detected multiple transcription initiation sites of MRP2/Mrp2 gene in tissues. We also found that the relative abundance of the rat Mrp2 mRNA isoforms with different 5’UTRs differed in the rat liver, kidney, jejunum, ileum, placenta, and lung. This is the first study on the translational regulatory mechanisms of the MRP2/Mrp2 gene. Multidrug resistance protein 2 (MRP2) Translational regulation 5' Untranslated region (5'UTR) Upstream open reading frame (uORF) Transcription initiation sites Medical Toxicology
9	Structural analysis of DNA wrapping in bacterial transcription initiation complex by transmission electron microscopy and single particle analysis / Análise estrutural do enovelamento do DNA no complexo da iniciação de transcrição bacteriano usando microscopia eletrônica de transmissão e análise de partículas isoladas Ariza, Alfredo Jose Florez 17 July 2018 (has links) The transcription initiation is the first step in gene expression and an important regulation step in all living organisms. In bacteria, it has been proposed that DNA bending and its wrapping on the surface of E. coli RNAP might facilitate the opening of the transcription bubble, which is necessary for the initiation of gene transcription. In this work, it is shown the first structural study to evaluate a DNA wrapping model, including its length and the relative position in the bacterial transcription initiation complex (RP complex), assembled between RNA polymerase-σ70 holoenzyme (RNAP) and a λPR promoter (-100 to +30 wild type). RP complex was prepared and negatively stained with 2% uranyl acetate on a thin-carbon coated grid and the data acquisition of 500 images was performed in a JEM-2100 (JEOL, Japan) microscope equipped with an F-416 CMOS camera (TVIPS, Germany). Single particle analysis of 16,015 particles, grouped in 666 class-averages, was conducted using IMAGIC 4D software (Image Science, Germany) to obtain a three-dimensional model of the RP complex at 20Å resolution. After the rigid-body fitting of the RNAP crystallographic structure (PDB 4YG2) and the modeled DNA promoter, it was observed that the regions 1.2 and 4.2 of the σ70 subunit interacts with the consensus zones, -10 and -35 hexamers of the promoter. Furthermore, it was possible to observe that αCTDs (C-terminal domain) in both alpha subunits would be oriented to facilitate the interaction with the first and second UP-elements regions, respectively (centered around –50 and -75 positions in the promoter). These was enabled by the presence of the characteristics motifs helix-hairpin-helix in these domains. In addition, the downstream DNA, from the transcription bubble, appears to be inside the protein main channel, oriented in a way to enable interactions with the RNAP clamp and jaws. Finally, it was observed that the DNA wrapping has ~32 nm of total length and involves a promoter bent of ~255° around the RNAP surface. The 3D-model obtained in this study is the very first direct structural confirmation of the DNA promoter wrapping in a bacterial transcription initiation complex. / A iniciação da transcrição é o primeiro passo na expressão gênica e importante ponto de regulação em todos os organismos vivos. Em bactérias, foi proposto que o enovelamento do DNA na superfície da RNAP de E. coli pode facilitar a abertura da bolha de transcrição, necessária para o início da transcrição gênica. Neste trabalho, é apresentado o primeiro estudo estrutural direto para avaliar o comprimento do enovelamento do DNA e sua posição no complexo de iniciação da transcrição bacteriana (complexo RP), montado entre a holoenzima RNA polimerase-σ70 (RNAP) e um promotor λPR (-100 para +30, tipo selvagem). Amostras do complexo RP foram preparadas e contrastadas negativamente com 2% de acetato de uranila em uma grade com filme fino de carbono e a aquisição de 500 imagens foi realizada em um microscópio JEM-2100 (Jeol, Japão) equipado com uma câmera CMOS F-416 (TVIPS, Alemanha). A análise de partículas isoladas de 16.015 partículas, agrupadas em 666 médias de classe, foi conduzida usando o software IMAGIC 4D (Image Science, Alemanha) para obter um modelo tridimensional do complexo RP, a 20Å de resolução, estimado pelo critério de ½ bit. Após o ajuste de corpo rígido da estrutura cristalográfica da RNAP (PDB 4YG2) e do promotor de DNA modelado, observou-se que as regiões 1.2 e 4.2 da subunidade σ70 interagem com as zonas de consenso, hexâmeros -10 e -35, do promotor. Além disso, foi possível observar que os αCTDs (domínio C-terminal) em ambas as subunidades alfa estariam orientados para facilitar uma possível interação com a primeira e segundas regiões dos elementos UP, respectivamente (centradas em torno das posições –50 e -75 do promotor). Estas seriam possíveis devido à presença de alguns motivos de características hélice-grampo-hélice nesses domínios. Além disso, a região do promotor, downstream da bolha de transcrição, parece estar dentro do canal principal da proteína, orientado de forma a possibilitar interações com o clamp e jaw da RNAP. Finalmente, foi observado que o comprimento total do enovelamento de DNA envolve cerca de 32 nm e 255° de rotação do DNA ao redor da superfície da RNAP. Portanto, este modelo 3D é a primeira confirmação estrutural direta do enovelamento de DNA em um complexo bacteriano de iniciação da transcrição. Análise de partículas isoladas Complexo da iniciação da transcrição DNA wrapping Enovelamento do DNA Microscopia eletrônica de transmissão RNA polimerase RNA polymerase Single particle analysis Transcription initiation Complex Transmission electron Microscopy
10	Transcriptional regulation by the mammalian stress-activated protein kinase p38 Ferreiro Neira, Isabel 07 October 2011 (has links) Regulation of transcription by Stress Activated Protein Kinases (SAPKs) is an essential aspect for adaptation to extracellular stimuli. In mammals, the activation of the p38 SAPK results in the regulation of gene expression through the direct phosphorylation of several transcription factors. However, how p38 SAPK regulates the proper gene expression program of adaptation to stress as well as the basic mechanisms used by the SAPK remains uncharacterized. The results displayed in this manuscript show that the p38 SAPK plays a central role in the regulation of gene expression upon stress, as up to 80% of the upregulated genes are p38 SAPK dependent. Moreover, we also observed that a specific set of genes were upregulated in response to each specific stimuli, and just a small set of genes were commonly up-regulated by several stresses, which involves mainly transcription factors. In addition, we observed that, to proper regulate gene transcription, the p38 SAPK is recruited to stress-induced promoters via its interaction with transcription factors. Additionally, p38 activity allows the recruitment of RNA polymerase II and the MAPKK MKK6 to stress-responsive promoters. The presence of active p38 SAPK at open reading frames also suggests the involvement of the SAPK in elongation. Altogether, the results showed in this manuscript establish the p38 SAPK as an essential regulator in the transcriptional response to stress, as well as define new roles for p38 in the regulation of transcription in response to stress. / La regulación de la transcripción por las Proteínas Quinasas activadas por Estrés (SAPKs) es un aspecto esencial para la adaptación a los estímulos extracelulares. En mamíferos, la activación de la SAPK p38 da lugar a la regulación de la expresión génica a través de la fosforilación de varios factores de transcripción. Sin embargo, cómo p38 SAPK regula el programa de expresión génica de adaptación al estrés así como los mecanismos utilizados por la SAPK permanece sin caracterizar. Los resultados presentados en este manuscrito muestran que p38 SAPK juega un rol central en la regulación de la expresión génica en respuesta a estrés, ya que hasta el 80% de los genes inducidos son dependientes de p38 SAPK. También observamos que en respuesta a cada tipo de estrés se induce un grupo de genes específicos, y sólo hay una pequeña respuesta de genes comunes a los diferentes tipos de estrés la cual engloba principalmente factores de transcripción. Además, hemos observado que para regular la transcripción, p38 se recluta a los promotores de respuesta a estrés a través de su interacción con factores de transcripción. Asimismo, la actividad de p38 permite el reclutamiento de la RNA Polimerasa II y de la MAPKK MKK6 a los promotores inducidos por estrés. La presencia de p38 activa en las regiones codificantes sugiere su participación durante la elongación. En conjunto, los resultados mostrados en este manuscrito establecen a p38 como un regulador esencial de la transcripción en respuesta a estrés, así como definen nuevas funciones de p38 en la regulación de la transcripción en respuesta a estrés. p38 SAPK transcription initiation gene expression transcription factors cell stress RNA Polymerase II iniciación de la transcripción expresión génica factores de transcripción estrés celular RNA Polimerasa II 575

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