Global ETD Search

31	Studies on herpes simplex virus infection in Friend erythroleukemia cells Mayman, Barbara Anne. January 1984 (has links) No description available. Herpes simplex virus. Friend virus. RNA -- Synthesis. Proteins -- Synthesis. DNA -- Synthesis.
32	Study of RNA synthesis of hepatitis C virus in vitro and in cells of hepatocarcinoma / Etude de la synthèse de l'ARN du virus de l'hépatite C in vitro et dans des cellules d’hépatocarcinomes Ahmed El Sayed, Neveen 15 December 2011 (has links) La polymérase NS5B du virus de l’hépatite C (VHC) porte une activité ARN polymérase ARN-dépendante essentielle pour la réplication de l'ARN génomique viral. Cette réplication implique la synthèse d'un intermédiaire de réplication de polarité négative. In vitro et probablement in vivo, la NS5B initie la synthèse d'ARN par un mécanisme de novo qui nécessite des interactions spécifiques entre la polymérase virale et des éléments des ARN viraux. Dans une première partie nous avons étudié le rôle du GTP et d’un domaine C-terminal nommé linker de la polymérase. Nos résultats démontrent que des concentrations élevées de GTP sont nécessaires pour la transition de l'initiation à l'élongation de la synthèse de l'ARN. Des mutations dans le linker à la position 556 ne modifient pas la concentration de GTP nécessaire pour la transition. Toutefois, l'initiation de la synthèse d'ARN est augmentée par la mutation S556K. Une analyse structurale menée en parallèle suggère une implication directe du linker dans l'initiation de novo de la synthèse de l'ARN. Dans les deuxièmes et troisièmes parties, nous avons étudié le rôle de motifs ARN dans la traduction et la synthèse de l’'ARN du VHC. Nous avons démontré que la tige boucle SL-E1 formée par la région entre les nt 177 et 222 de l'extrémité 3' de l’ARN (-) est importante pour la synthèse d'ARN in vitro par la NS5B recombinante et dans les cellules Huh7 exprimant le complexe de réplication (RC) du VHC. SL-E1 est impliquée dans l’initiation de la synthèse d’ARN, au moins in vitro. Nous avons également étudié le rôle des tiges boucles SLV et SLVI du gène core. Nos données n'ont pas montré de rôle évident de ces séquences ou de leur complément dans la synthèse de l'ARN in vitro par la NS5B recombinante et en culture cellulaire par le RC du VHC. Nous avons confirmé leur effet négatif sur la traduction IRES dépendante par interaction ARN-ARN longue distance entre SL-VI et le 5'UTR et démontré que le miR122 ne peut pas empêcher cet interaction. Par contre, la présence de SL-VI prévient l’inhibition de la traduction induite par l’interaction entre le domaine III de l’IRES et la tige boucle 5BSL3.2 en 3’ du génome. Ces résultats démontrent la complexité des interactions ARN/ARN et ARN/protéines dans la régulation de la réplication virale. / The hepatitis C virus (HCV) NS5B protein displays a RNA-dependent RNA polymerase activity essential for replication of the viral RNA genome. This replication involves the synthesis of a replication intermediate of negative polarity. In vitro and likely in vivo, the NS5B initiates RNA synthesis by a de novo mechanism which requires specific interactions between the polymerase and viral RNA elements. In the first part of results, we described a combined structural and functional analysis of HCV-NS5B to study the role of a C-terminal segment (termed linker) and of GTP in RNA synthesis. Our results demonstrated that high GTP concentrations are necessary for the transition from the initiation to the elongation of RNA synthesis, and that linker mutations at position S556 did not modify the GTP requirement of NS5B for this transition. However, the initiation of RNA synthesis was greatly enhanced by a S556K mutation. These results together with a structural analysis point to the direct involvement of the linker in the de novo initiation of RNA synthesis. In the second and third parts of results, we studied the role of RNA elements in RNA synthesis. We demonstrated that the SL-E1 stem–loop formed by nucleotides 177–222 from the 3’-end of the HCV (-) RNA is important for RNA synthesis both in vitro by the recombinant NS5B and in Huh7 cells by HCV replication complex (RC). We also showed that SL-E1 is involved in initiation of RNA synthesis, at least in vitro. Then we studied the role of other viral RNA elements in core coding sequences (SLV and SLVI stem loops) and the involvement of the microRNA miR122 in RNA translation and RNA synthesis. For SLV and SLVI, our data did not show any clear role of these core-coding sequences or of their complement in the (-) RNA in RNA synthesis both in vitro by the recombinant NS5B and in cell culture by HCV-RC. We confirmed their negative effect on HCV-IRES translation through long range RNA-RNA interaction between SL-VI sequences and the 5’UTR and demonstrated that miR122 cannot disrupted this interaction and switches the region to an open conformation. Conversely, our data indicated that the SL-VI domain can counteract the negative effect of the interaction between the domain III of IRES and the 5BSL3.2 stem loop localized at the 3’end of the genome. These results point to the complexity of RNA/RNA and RNA/proteins interactions in the HCV replication cycle. Virus de l'hépatite C Synthèse de l'ARN Polymérase du VHC GTP Hepatitis C virus RNA synthesis Polymerase of HCV GTP
33	Análise estrutural e funcional de cofatores do exossomo em Saccharomyces cerevisiae e Pyrococcus / Structural and functional analysis of exosome cofactors in Saccharomyces cerevisiae and Pyrococcus Juliana Silva da Luz 25 August 2006 (has links) A síntese ribossomal é uma das maiores atividades em células eucarióticas. Este processo inicia-se no nucléolo e é finalizado após a exportação das subunidades 40S e 60S para o citoplasma. Três dos RNAs ribossomais de eucariotos (18S, 5.8S e 25S) são sintetizados como um transcrito primário de 35S, o qual é processado através de uma complexa e ordenada série de modificações nucleotídicas e clivagens endo e exonucleolíticas. Estas reações dependem de aproximadamente 170 proteínas, 80 small nucleolar RNAs e de seqüências no pré-rRNA. Os fatores trans-atuantes envolvidos no processamento podem ser agrupados como RNA-helicases, endonucleases, snoRNPs (small nucleolar ribonucleoprotein complexes) e exonucleases, que incluem o complexo exossomo. O exossomo de levedura é formado por 10 proteínas essenciais que atuam na maturação de rRNAs, snRNAs, snoRNAs, além da degradação de mRNAs incorretamente processados. A estrutura do exossomo de archaea foi descrita recentemente, mas ainda não existem muitas informações sobre a regulação deste complexo e sobre a participação de cofatores que interagem de forma transiente com o exossomo. Diante disso, este trabalho visou a caracterização funcional das proteínas que formam o anel de RNases PH em Saccharomyces cerevisiae, assim como a caracterização estrutural e funcional de possíveis cofatores do exossomo de Saccharomyces cerevisiae, Nop17p e Ylr022p, e do exossomo de Pyrococcus, Pab418p, Pab1135p e aNip7p. Os dados obtidos evidenciam que a atividade exonucleolítica do exossomo de levedura, assim como o de archaea, é dependente da formação de heterodímeros; Ylr022p, uma proteína de levedura com função não caracterizada, liga inespecificamente RNA in vitro, mas mais eficientemente alguns RNAs in vivo. Dentre as proteínas de archaea, Pab418p e aNip7p também ligam RNA, e como demonstrado aqui, aNip7p influencia significativamente a atividade do exossomo de archaea. / The synthesis of ribosomes is one of the major metabolic pathways in eukaryotic cells. This process starts in the nucleolus and ends with the export and final maturation of the ribosomal subunits 40S and 60S in the cytoplasm. Three eukaryotic ribosomal RNAs (18S, 5.8S and 25S) are synthesized as a 35S primary transcript (35S pre-rRNA), which is then processed by a complex and ordered series of nucleotide modifications and endo- and exonucleolytic cleavage reactions. These processing reactions depend on 170 proteins, 80 small nucleolar RNAs and specific pre-rRNA sequences. The trans-acting factors, that take part in the processing can be grouped as RNA-helicases, endonucleases, snoRNPs (small nucleolar ribonucleoprotein complexes) and exonucleases, including the exosome. The yeast exosome is composed of 10 essential proteins that function in the processing of rRNAs, snRNAs, snoRNAs and in the degradation of aberrant mRNAs. Recently, the archaeal exosome structure was determined, but no information is yet available on the regulation of the exosome function or on the possible role of the cofactors that transiently interact with it. The main goals of this work were the functional characterization of the protein components of the Saccharomyces cerevisiae exosome RNase PH ring, as well as the structural and functional characterization of the possible cofactors of that complex, Nop17p and Ylr022p. Since the recent characterization of the Pyrococcus exosome, the study of the archaeal exosome cofactors, Pab418p, Pab1135p and aNip7p, was also included in this work, in order to correlate the data on the complex of these different organisms. Our results show that the exonucleolytic activity of the yeast exosome is dependent on the heterodimers formation, as described for archaea. Although it is not clear how Nip7p affects the exosome function in yeast, aNip7p binds RNA and inhibits a-exosome activity in vitro. Yeast Ylr022p binds RNA inespecificaly in vitro, but coprecipitates specific RNAs more efficiently from total cell extracts. Its archaeal orthologue, Pab418p, also binds RNA, but does not affect significantly a-exosome function. exossomo proteína/purificação pyrococcus RNA/síntese Saccharomyces cerevisae Exosome protein/purification pyrococcus RNA/synthesis Saccharomyces cerevisiae
34	Synthèse d'ARN en conditions prébiotiques / RNA synthesis in prebiotic conditions Da Silva, Laura 01 December 2016 (has links) L'une des questions essentielles concernant l'origine de la vie est de comprendre les étapes de l'évolution ayant permis le passage d’une chimie prébiotique complexe aux premières étapes biologiques. Les constituants cellulaires actuels nous permettent de suivre le lien des produits chimiques aux métabolites biochimiques, de l'ancien au monde moderne. De nombreuses preuves soutiennent l'hypothèse du "monde à ARN" stipulant qu’au début de l'évolution de la vie, l'ARN était responsable à la fois du stockage et du transfert de l'information génétique mais aussi de la catalyse de réactions biochimiques. Dans cette thèse, j’ai étudié la synthèse non-enzymatique d’ARN dans des conditions prébiotiques. Ces conditions simulent les processus hydrothermaux qui se produisent dans les sources chaudes hydrothermales modernes et étaient vraisemblablement omniprésentes sur la Terre primitive. J’ai ensuite recherché les conditions optimales permettant la synthèse de longs polymères d’ARN et montré que la présence d’une matrice cristalline augmente de manière significative le rendement et la longueur des polymères synthétisés. Enfin, j’ai examiné la stabilité des polymères nouvellement synthétisés dans ces conditions hydrothermales and comparé la dégradation par dépurination des nucléotides et polymères en présence des deux agents organisateurs favorisant la polymérisation, soit des phospholipides, soit des sels cristallins. Nous avons conclu que, bien que la décomposition des nucléotides ait lieu dans ces conditions, des nucléotides puriques sont toujours disponibles pour participer à la synthèse de polymères et que la présence de phospholipides protège les nucléotides contre la dégradation. / One remaining crucial point in the early life history is to understand how evolution passed from complex prebiotic chemistry to simple biology. Current cellular facts allow us to follow the link from chemical to biochemical metabolites, from the ancient to the modern world. A substantial weight of evidence supports the “RNA world” hypothesis stipulating that the earliest forms of life passed through a phase in which RNA served both for the storage and transfer of genetic information and for the catalysis of biochemical reactions. In this thesis, we studied the non-enzymatic synthesis of RNA under simulated prebiotic conditions. These conditions simulated hydrothermal processes that commonly occur in volcanic hydrothermal fields today and were presumably ubiquitous on the primitive Earth. We then looked for optimal conditions allowing synthesis of long RNA-like polymers and showed that the presence of crystalline matrix significantly increases the yield and length of synthesized polymers. Finally, we investigated the stability of the synthesized polymers under hydrothermal conditions and compared the degradation by depurination of nucleotides and polymers in the presence of two organsing agents that promotes polymerisation, either phospholipids or salts crystals. We concluded that although decomposition of nucleotides occurs in these simulated conditions, purine nucleotides are still available to participate in polymers synthesis and the presence of phospholipids protects nucleotides against degradation. Conditions hydrothermales Monde à ARN Synthèse d'ARN Hydrothermal fields RNA world RNA synthesis
35	Studies on herpes simplex virus infection in Friend erythroleukemia cells Mayman, Barbara Anne. January 1984 (has links) No description available. DNA -- Synthesis. Friend virus. Proteins -- Synthesis. Herpes simplex virus. RNA -- Synthesis.
36	Evidence for post-transcriptional regulation of induction of NADP- specific glutamate dehydrogenase by accumulation of its mRNA in uninduced synchronous Chlorella cells Turner, Katherine Jane January 1980 (has links) The mRNA coding for the ammonium inducible NADP-specific glutamate dehydrogenase (NADP-GDH) from Chlorella was studied in induced and uninduced cells to determine the molecular mechanisms which regulate the cellular levels of this enzyme. A procedure for isolation of a high yield of total undegraded cellular polysomes was developed. The crosslinking reagent, dimethyl suberimidate, was employed to prepare a stable NADP-GDH-crosslinked-Sepharose-4B antigen affinity column for the purification of rabbit anti-NADP-GDH IgG. Binding studies with ¹²⁵I-labelled antibody and total polysomes, isolated from induced and uninduced cells, showed that the NADP-GDH was being synthesized on polysomes from both types of cells. When poly(A)- containing RNA was extracted from polysomes isolated from induced and uninduced cells, and translated in an mRNA-dependent in vitro translation system, NADP-GDH antigen was synthesized from the RNA from both sources. Based on sucrose density gradient analysis, Chlorella NADP-GDH mRNA has a sedimentation coefficient of 18 Comparison of the amounts of NADP-GDH synthesized in vitro from poly(A)-containing RNA and non-poly(A)-containing RNA showed the NADP-GDH mRNA contained polyadenylic acid sequence. By use of an indirect immunoadsorption procedure, the NADP-GDH mRNA was purified five- to sevenfold from total poly(A)-containing RNA. The overall purification of the NADP-GDH mRNA from total polysomal RNA was approximately two hundred-fold. Complementary DNA was synthesized from the partially purified RNA with reverse transcriptase. The cDNA sequences hybridized to the least abundant class of mRNA sequences present in total poly(A)-containing RNA. In vitro translation of total poly(A)-containing RNA showed that NADP-GDH synthesis was 0.1% of total protein synthesis. Upon addition of inducer to previously uninduced, synchronous cells, the amount of translatable NADP-GDH mRNA increased in a linear fashion after 30 min of the induction period. A change in rate of NADP-GDH mRNA accumulation was observed after 30 min of the induction period. The results support the prediction that since the NADP-GDH enzyme is unstable in vivo, during periods of NADP-GDH accumulation, the NADP-GDH mRNA accumulates. When poly(A)-containing RNA, isolated from uninduced synchronous cells was translated in vitro, NADP-GDH antigen was synthesized at each time in the cell cycle examined. The amount of translatable NADP-GDH mRNA increased throughout the cell cycle with a rate change occuring during the S-phase. This pattern of NADP-GDH mRNA accumulation is consistent with the hypothesis that NADP-GDH mRNA accumulates in uninduced cells at a rate proportional to gene dosage. These results provide one explanation for the observed pattern of enzyme potential in synchronous cells cultured in the absence of inducer. The data are consistent with the possibility that a single mRNA, which is subject to post-transcriptional modification by the inducer, codes for NADP-GDH. / Ph. D. LD5655.V856 1980.T976 Transfer RNA RNA -- Synthesis Genetic translation Genetic transcription Eukaryotic cells
37	Determinants of Core Shell Dependent Rotavirus Polymerase Activity Steger, Courtney Long 22 February 2019 (has links) Rotaviruses (RVs) are medically significant gastrointestinal pathogens and are a leading cause of childhood mortality in many countries. The RV RNA-dependent RNA polymerase, VP1, synthesizes RNA during viral replication only in the presence of another RV protein, VP2, which comprises the innermost core shell layer of the virion. Though these VP1-VP2 interactions are essential for RV replication, the mechanism by which the core shell regulates polymerase activity remains incompletely understood. Here, we sought to identify and characterize specific regions of both VP1 and VP2 that are required for core shell dependent polymerase activity. First, we used bioinformatics approaches to analyze VP1 and VP2 sequence diversity across many RV strains and identify positional locations of critical amino acid changes within the context of known structural domains and motifs. We next tested how the identified sequence differences influenced VP2-dependent VP1 activity in vitro. These data revealed that VP1 and VP2 protein diversity correlates with functional differences between avian and mammalian RV strains. Then, we used these sequential and functional incompatibilities to map key regions of VP1 important for mediating RNA synthesis. To pinpoint critical interacting regions of VP1 and VP2, we used site directed mutagenesis to engineer several modified VP1 and VP2 proteins. Then, we employed an in vitro RNA synthesis assay to test how the introduced mutations influenced VP2-dependent VP1 activity. Altogether, our results revealed several functionally important VP1 residues critical for in vitro VP2-dependent VP1 activity, either individually or in combination with neighboring residues, including E265/L267, R614, and D971/S978/I980. Structural analyses show VP2 interactions at these surface-exposed VP1 sites, which altogether supports a direct contact model of core shell dependent RV polymerase activity. Moreover, recombinant VP1 proteins containing multiple mutations at buried residues were incapable of facilitating RNA synthesis in vitro under the assay conditions, indicating that an extensive intramolecular signaling network exists to mediate VP1 activity. Taken together, these results suggest that VP2 binding at the VP1 surface may induce intramolecular interactions critical for VP1 activity. Overall, results from these studies provide important insight into VP1-VP2 binding interface(s) that are necessary for RV replication. / Ph. D. / Rotaviruses (RVs) are clinically-significant gastrointestinal pathogens that cause severe diarrhea and dehydration in children. RVs encode a specialized polymerase enzyme, called VP1, which functions to synthesize RNA during viral replication. RNA synthesis activities of VP1 are tightly regulated by another RV protein, VP2, which comprises the innermost core shell layer of the virion. Though these VP1-VP2 interactions are essential for viral replication, the mechanism by which the core shell supports polymerase activity remains poorly understood. Here, we sought to identify and characterize specific regions of both VP1 and VP2 that are essential for polymerase activity in a test tube (i.e., in vitro). First, we analyzed VP1 and VP2 sequence diversity across many RV strains. Then, we tested how the identified sequence differences influenced VP2-dependent VP1 activation in vitro. To pinpoint critical regions of VP1 and VP2, we next engineered and assayed several mutant proteins. Altogether, our results revealed several functionally important residues of VP1 and VP2, which raises new ideas about VP1-VP2 binding interface(s) that are important for viral replication. Moreover, results from these studies may provide a scientific platform for the rational design of next-generation RV vaccines or antiviral therapeutics. rotavirus RNA-dependent RNA polymerase core shell protein RNA synthesis genome replication
38	Insights into the RNA polymerase activity of the dengue virus NS5 Potisopon, Supanee 04 July 2014 (has links) Le virus de la dengue cause une maladie de type grippal qui peut dans certains cas évoluer vers des fièvreshémorragiques mortelles. Mon projet de thèse porte sur la réplication de ce virus. Je focalise sur la compréhension du mécanisme d'action de la protéine NS5 de ce virus. La protéine contient 2 domaines : 1) domaine méthyltransférase, essentiel pour la traduction des protéines virales, 2) domaine polymérase, synthétisant le génome ARN du virus. Premièrement, nous avons démontré que la polymérase joue un rôle principal dans la conservation de l'extrémité 3' et 5' du génome et de l'anti-génome. Puis, j'ai caractérisé l'influence du domaine méthyltransférase sur l'activité polymérase de la protéine NS5. J'ai développé un système d'études mécanistiques en utilisant des techniques biochimiques de cinétique pré-stationnaire pour la protéine NS5, et obtenu des paramètres cinétiques et thermodynamiques de cette protéine envers ses substrats. Avec ce même système, j'ai pu tester des activités de la polymérase NS5 avec des ARN coiffés et triphosphates de différente longueur, mimant les séquences à l'extrémité 5' du génome du virus de la dengue. L'activité polymérase de NS5 est influencée par la présence de la coiffe de l'ARN, ce qui m'a permis de proposer une distance physique correspondant à environ 13 nucléotides entre les sites actifs domaines méthyltransférase et polymérase. Mes travaux ouvrent la voie à la détermination de la structure 3D de NS5 avec ses ARN et des nucléotides 5'-triphosphate.Elucider son mécanisme d'action, c'est être capable d'inhiber son action et donc de pouvoir proposer des molécules capables d'arrêter la prolifération virale lors d'une infection. / Dengue virus causes dengue fever, which may evolve towards life-threatening hemorrhagic fever. My research projectfocuses on dengue replication, and more precisely on the mechanism of NS5 at the molecular/atomic level. NS5 is a bifunctionalenzyme containing two domains: 1) a methyltransferase domain essential for translation of viral proteins, 2) apolymerase domain synthesizing the viral RNA genome. First, we demonstrated the main role of the polymerase in theconservation of 5' and 3' ends of dengue genome and anti-genome RNAs. Next, I showed the influence of themethyltransferase domain on the activity of the polymerase domain. I also developed a system allowing mechanistic studiesusing pre-steady state kinetics to characterize NS5 in depth. I have made use of this system to determine the catalyticparameters of NS5 towards its substrates. Using the same pre-steady state system, I was able to test the polymerase activityof NS5 with capped and uncapped 5'-triphosphate RNAs of different lengths corresponding to the 5'-end of the dengue RNAgenome. The polymerase activity of NS5 is significantly affected by the presence of the 5'-cap, which allowed me to designan experimental set-up pointing to a minimal physical distance of around 13 nucleotides between the methyltransferase andpolymerase active sites. My work will be useful to characterize the biophysics of NS5 in complex with its RNA and NTPsubstrates, and then to determine the crystal structure of such complex at play during viral RNA synthesis. Knowing thedetailed NS5 mechanism paves the way to inhibit its action and thus design drugs aiming at stopping a viral infection. Mot clés : virus de la dengue Ns5 Polymérase Méthyltransférase Synthèse de l'ARN Réplication Dengue virus Ns5 Polymerase Methyltransferase RNA synthesis Replication
39	miRQuest: um middleware para investigação de miRNAs / miRQuest: a middleware for miRNA research Ambrosio, Rosana Ressa Aguiar 30 September 2015 (has links) RNAs não codificadores são RNAs transcritos, mas não traduzidos, que possuem funções importantíssimas para a regulação dos processos biológicos celulares. Dentre as diversas classes de ncRNAs, a dos miRNAs é a que desperta maior interesse de pesquisa pela comunidade científica atualmente. miRNAs são pequenos RNAs, que contêm cerca de 22 nucleotídeos (nt), que atuam como inibidores/silenciadores pós-transcricionais. Dada sua importância, identificar essa classe de ncRNA permite descobrir possíveis novos microRNAs, bem como seu papel regulatório que pode estar ligado a diversos processos biológicos. A bioinformática, por meio da análise in silico dos microRNA, via abordagens de reconhecimento de padrões, por exemplo, contribuiu muito para identificação e anotação dessa classe de ncRNA. Isso permitiu o desenvolvimento de novas técnicas, métodos e abordagens computacionais que fossem capazes de contribuir, de maneira mais eficiente, com as análises e interpretação da grande massa de dados biológicos que vêm sendo gerados com maior frequência, principalmente nos últimos anos. Apesar de existir grande variedade de abordagens computacionais descritas para a identificação de microRNAs, em sua grande maioria, estas apresentam algum tipo de limitação (e.g. desatualizadas, não mais disponíveis). Desse modo, este trabalho apresenta o miRQuest, um sistema integrado que foi construído, utilizando-se um padrão de desenvolvimento em camadas, via tecnologia de middleware, em uma plataforma web para a investigação miRNA que contém duas funções principais: (i) a integração de diferentes ferramentas de previsão miRNA para identificação miRNA em um ambiente amigável; e (ii) a comparação entre essas ferramentas de previsão. O miRQuest não introduz um novo modelo computacional para predição de miRNAs, mas, sim, uma nova metodologia que permite executar simultaneamente diferentes técnicas de identificação de miRNA. / miRNA belongs to the class of small RNAs non-coding (ncRNAs), been the target of several studies in the literature for his role in the regulation of mRNA levels (messenger RNA) in cells. Representing an class of endogenous RNAs of approximately 22 nucleotides (mature), that act as inhibitors/silencers post-transcriptional. Discovered at the end of last century in Caenorhabditis elegans, miRNAs are now recognized as key regulators of gene expression in plants and animals, among many eukaryotic organisms. According to the scientific literature, this is one of the most studied classes of ncRNAs by the scientific community nowadays. According to the scientific literature, this is one of the most studied classes of ncRNAs by nowadays scientific community. Given its importance, identify this class of ncRNA becomes of great interest as it allows to discover possible new microRNAs, as well as its regulatory role that can be connected to multiple biological processes. Bioinformatics, through in silico analysis of microRNA, either via pattern recognition approaches, for example, greatly contributes to the identification and annotation of this class ncRNA. This allowed the development of new techniques, methods and computational approaches that were able to contribute more effectively to the analysis and interpretation of the great mass of biological data, which has been generated at a higher frequency, especially in recent years. Although there are a variety of computational approaches described for the identification of microRNA, for the most part, these have some sort of limitation (eg outdated, no longer available). Thus, this work presents the miRQuest; an integrated system was built using a standard developing layer, through middleware, in a web platform for miRNA research that has two main functions: (i) the integration of different miRNA prediction tools to identify miRNA in a friendly environment; and (ii) benchmarking between these predictive tools. The miRQuest does not introduce a new computer model to predict miRNAs, but rather, a new methodology that permits simultaneously run different miRNA identification techniques. CNPQ::CIENCIAS EXATAS E DA TERRA Bioinformática Ácido ribonucleico - Síntese Teoria da previsão Bioinformatics RNA - Synthesis Prediction theory Ciência da Computação
40	Generation of cDNA chips from the black widow spider, latrodectus hesperus, for gene discovery and expression profiling using microarray technology, and molecular characterization of a novel silk glue protein Vasanthavada, Keshav 01 January 2005 (has links) eDNA microarray technology has generated a tremendous amount of interest among biologists because of its promise to monitor the entire genome on a single chip, thus enabling researchers to have a better picture of the interaction among thousands of genes simultaneously. In the current study, this technology was used to print over 3,000 unknown genes from various silk glands of the black widow spider to profile their expression patterns and to identify novel candidates. Spiders are remarkable creatures because of their ability to make different silks, each with a specific function. Some of these silks have amazing mechanical properties, comparable to those of the finest synthetic materials. Several silk genes have been cloned from various spiders over the last few years, and the contribution of each of those genes in silk production has been identified. However, the majority of cellular and biochemical processes involved in silk manufacture remain a mystery. In our research, we attempt to identify genes that might be involved in silk assembly, on a global scale and investigate more about those genes and their interplay with other key biological molecules involved in silk manufacture. Our study showed that silking spiders for a certain period of time resulted in down-regulation of two important silk genes, ECP-1 and ECP-2. Both these genes are key molecules implicated for their role in maintaining the egg case architecture in the black widow spider.,-and we believe that these genes are also directly or indirectly involved in the manufacture of dragline silk. Microarray analyses also enable the discovery of several other interesting molecules, two of which could be accessory proteins involved in silk formation. Furthermore, in a separate study we also characterized a novel silk glue protein with unique ensemble repeats. In conclusion, we believe that the findings of this study will indeed be significant to silk researchers and material scientists alike and it will enhance our knowledge in understanding the mystery behind silk production. RNA Synthesis Black widow spider DNA microarrays Genetic transcription Proteins Synthesis Gene expression Spiders Genetics Biology Life Sciences

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