Global ETD Search

1	Perfil de microRNAs presentes no sêmen e embriões bovinos e sua relação com a fertilidade / Profile of microRNAs present in semen and embryos and their relationship to fertility Alves, Maíra Bianchi Rodrigues 11 October 2018 (has links) Dentre outros fatores, a fertilidade depende da qualidade espermática (QE; características morfofuncionais) e dos componentes espermáticos moleculares. Devido à QE nem sempre estar associada à fertilidade, o estudo dos componentes moleculares ganha cada vez mais destaque. Os microRNAs, reguladores pós-transcricionais, estão presentes nos espermatozoides e desempenham funções importantes na espermatogênese, na maturação espermática e no desenvolvimento embrionário. Entretanto, os mecanismos pelos quais estes regulam a fertilidade masculina são pouco conhecidos. Portanto, o objetivo dos estudos aqui presentes foi investigar o papel dos miRNAs na determinação e regulação da fertilidade. No primeiro estudo, partidas de sêmen criopreservado de touros Aberdeen Angus (Bos taurus) com alta (54,3±1,0%; AF; n=3) e baixa fertilidade (41,5±2,3%; BF; n=3) foram submetidas às avaliações da QE; à produção in vitro e coleta de embriões com uma célula, duas células e blastocistos; e à avaliação do perfil de 380 miRNAs. Os genes-alvo dos miRNAs diferentemente abundantes nos espermatozoides e nos embriões dos touros AF e BF foram investigados. O diâmetro, número de células e taxa de proliferação dos blastocistos também foram analisados. Ainda, neste estudo, foi validado um novo modelo para provar que o espermatozoide é capaz de entregar miRNAs ao embrião. Para a análise estatística, foram empregadas as análises de variância (ANOVA) e de Qui-Quadrado. Quando não mencionado, o nível de significância foi de 5%. Dentre os miRNAs avaliados, o miR-216b foi menos abundante nos espermatozoides (P=0,08) e zigotos (P<0,05) dos touros AF. O gene-alvo deste miRNA, KRAS, associado à proliferação celular, foi mais abundante (P<0,05) nos embriões de duas células dos touros AF assim como a taxa de primeira clivagem e o número de células dos blastocistos que foram maiores neste grupo. Ainda, provou-se que o miR-216b é entregue pelo espermatozoide ao embrião. No segundo estudo, seis touros da raça Nelore (Bos indicus) foram utilizados, sendo três submetidos ao estresse térmico testicular (heat stress; HS). O sêmen foi coletado sete dias antes e 21 dias após o estresse. A QE foi avaliada seguida pela análise do perfil de 380 miRNAs espermáticos e exossomais. Os dados foram analisados por ANOVA. O nível de significância foi de 5%. HS apresentou 21 miRNAs espermáticos diferentemente abundantes, mas não apresentou diferença no conteúdo de miRNAs exossomais. Os miR-126-5p e -146a apresentaram menor abundância nos espermatozoides HS assim como apresentaram menor abundância nos espermatozoides dos touros BF do primeiro estudo. Já o miR-216b não apresentou diferença neste segundo estudo. Assim, com base nos dois estudos, podemos concluir que 1) os miRNAs são importantes para a fertilidade; 2) existem miRNAs importantes para a fertilidade que são alterados por injúrias à espermatogênese; e 3) o miR-216b, entregue pelo espermatozoide ao embrião, é importante para o desenvolvimento embrionário inicial regulando de maneira diferente embriões de touros de AF e BF; provando que miRNAs espermáticos possuem papel na regulação e determinação da fertilidade. Estes estudos possuem grande importância na geração de conhecimentos sobre os miRNAs espermáticos e apresentam resultados pioneiros que confirmam que o espermatozoide bovino contribui com mais que o DNA ao desenvolvimento embrionário. / Bulls fertility relies of many factors. In concern to sperm cells, it depends of sperm quality (SQ; morphofunctional features) and sperm molecular components. Due to the fact thatsperm quality is not always related with fertility, the effect of many molecular factors on fertility has been intensively studied. miRNAs, which have post transcriptional action, are present on sperm cells and are important to spermatogenesis, sperm maturation and embryo development. However, the mechanisms by which they regulate male fertility are not completely understood. Thus, the objective of the present studies was to investigate the role of miRNAs on fertility regulation. On the first study, frozen-thawed semen batches of high (54.3±1.0%; HF; n=3) and low fertility (41.5±2.3%; LF; n=3) Aberdeen Angus (Bos taurus) bulls were analyzed in concern to SQ; were used in embryo in vitro production to produce and collect embryos of one cell, two cells and blastocysts; and were analyzed to the profile of 380 sperm miRNAs. The target genes of the miRNAs that presented different abundance levels on sperm cells and embryos of HF and LF bulls were investigated. Blastocysts diameter, cell number and proliferation index were also evaluated. Besides, in this study, we validated a new model to prove that some miRNAs are delivered by sperm cell to embryo. Data were analyzed by analyzes of variance (ANOVA) and Chi-Square. Signicante level was 5% unless otherwise stated. Among miRNAs evaluated, miR- 216b presented less abundance on HF sperm cells (P=0.08) and HF zygotes (P<0.05). miR- 216b target gene, KRAS, that is related with cell proliferation, presented high abundance (P<0.05) on HF two cells embryos such as the first clivage rate and the number of cells on blastocysts that were greater on this group. We also showed that miR-216b is delivered by sperm cells to embryos. On the second study, we used six Nelore (Bos indicus) bulls. Three bulls were submitted to testicular heat stress (HS group). Semen was collected three days before and 21 days after heat stress. Samples were analyzed in concern to SQ and to the profile of 380 miRNAs on sperm cells and on exossomes. Data were analyzed by ANOVA. Signicante level was 5%. HS presented 21 sperm miRNAs diferently abundant, but miRNAs from exossomes were not different between the HS and control groups. miR-126-5p and -146a presented less abundance on HS sperm cells and on BF bulls sperm cells of the first study. miR-216b was not different in the second study. Thus, we can conclude that 1) miRNAs are important to fertility; 2) there are miRNAs that are important to fertility and can be altered by spermatogenesis injuries; and 3) miR-216b is delivered by sperm cells to embryos and is important to initial embryo development regulating HF and LF embryos differently; showing that sperm miRNAs are important molecules for regulation and establishment of fertility. The studies here presented generate knowledge upon sperm miRNAs importance and present novel results that confirm that bull sperm cells contribute with more than DNA to embryo development. Espermatozoides Estresse térmico Exossomes Exossomos Heat stress miRNAs miRNAs ncRNAs ncRNAs Sperm cells
2	RNA-mediated virulence gene regulation in the human pathogen Listeria monocytogenes Loh, Edmund January 2010 (has links) The Gram-positive human pathogen Listeria monocytogenes uses a wide range of virulence factors for its pathogenesis. The majority of its virulence genes are encoded on a 9-kb pathogenicity island and are controlled by the transcriptional activator PrfA. Expression of these genes is maximal at 37°C and minimal at 30°C in a mechanism involving an RNA thermosensor. This thesis brings up different aspects of RNA-mediated regulation, including regulatory RNA structures within coding mRNA controlling expression to 5-untranslated RNA (5´-UTR) that controls downstream genes (cis-acting) as well as small non-coding RNAs (ncRNAs) that bind other target RNA (trans-acting). We investigated the importance of the coding region of the prfA-mRNA for its expression. Various lengths of prfA-mRNA were fused with reporter genes. Our finding suggested that the first 20 codons of prfA-mRNA were essential for efficient translation in Listeria monocytogenes. Translation of the shorter constructs was shown to be reduced. The expression level showed an inverse correlation with the RNA secondary structure stability in the beginning of the coding region. Riboswitches have previously been known to control expression of their downstream mRNA in a cis-acting manner. A trans-acting S-adenosylmethionine-binding riboswitch termed SreA was identified in Listeria monocytogenes. It was found to control the expression of the virulence regulator PrfA, by binding to the prfA-UTR and thereby affecting its translation. We examined the RNA locus encoding different virulence factors in Listeria monocytogenes. Several of them were preceded by 5´-UTRs of various lengths. We speculate that these 5´-UTRs could control expression of the downstream mRNA, provided they are of sufficient length. These findings prompted us to examine where and when Listeria monocytogenes switches on gene expression. Tiling array was used to compare RNAs isolated from wild-type and mutant bacteria grown at different growth conditions. Antisense RNAs covering parts of or whole open-reading frames as well as 29 new ncRNAs were identified. Several novel riboswitches possibly functioning as upstream terminators were also found. My thesis work compiles together a variety of novel RNA-mediated gene regulatory entities. A first coordinated transcriptional map of Listeria monocytogenes has been set up. My work has also revealed that the expression of the virulence regulator PrfA is controlled at several levels, indicating the importance of both the 5´-UTR and the coding RNA for regulated expression. Listeria monocytogenes virulence ncRNAs PrfA 5´-UTRs Molecular biology Molekylärbiologi
3	Function prediction of transcription start site associated RNAs (TSSaRNAs) in Halobacterium salinarum NRC-1 / Predição de função para TSSaRNAs (transcritos associados a sitios de início de transcrição) em Halobacterium salinarum NRC-1 Adam, Yagoub Ali Ibrahim 07 February 2019 (has links) The Transcription Start Site Associated non-coding RNAs (TSSaRNAs) have been predicted across the three domain of life. However, still, there are no reliable annotation efforts to identify their biological functions and their underline molecular machinery. Therefore, this project addresses the question of what are the potential functions of TSSaRNAs regarding their roles in addressing the cellular functions. To answer this question, we aimed to accurately identify TSSaRNAs in the model organism Halobacterium salinarum NRC-1 (an Archean microorganism) that incubated at the standard growth condition. Consequently, we aimed to investigate TSSaRNAs structural stability in the term of the thermodynamic energies. Moreover, we attempted to functionally annotate TSSaRNAs based on Rfam functional classification of non-coding RNAs. Based on the statistical approach we developed an algorithm to predict TSSaRNA using next-generation RNA sequencing data (RNA-Seq). To perform structural annotation of TSSaRNAs, we investigated the structural stability of TSSaRNAs by modeling the secondary structures by minimizing the thermodynamic free energy. We simulated TSSaRNAs tertiary structures based on the secondary structures constrain using the Rosetta-Common RNA tool. The structures of the minimum free energy supposed to be biophysically stable structures. To investigate the higher order structures of TSSaRNAs, we studied the hybridization between TSSaRNAs and their cognate genes as part of RNA based regulation system. Also, based on our hypothesis that TSSaRNAs may bind to protein to trigger their function, we have investigated the interaction between TSSaRNAs and Lsm protein which known as a chaperone protein that mediates RNA function and involved in RNA processing. Our pipeline to perform the functional annotation of TSSaRNAs aimed to classify TSSaRNAs into their corresponding Rfam families based on two steps: either through querying TSSaRNAs sequences against the co-variance models of Rfam families or by querying the Rfam sequences against the co-variance models of the consensus secondary structures in TSSaRNAs. The results showed that the prediction algorithm has succeeded to identify a total of 224 TSSaRNAs that expressed in the same strand of the mRNAs and 58 TSSaRNAs that expressed as antisense of the mRNAs. The identified TSSaRNAs molecules showed a median length of 25 nucleotides. Regarding the structural annotation of TSSaRNAs, the results showed that most of TSSaRNAs possessed thermodynamically stable secondary structures and their tertiary structures were capable of forming more complex structures through binding with other biomolecules. About the formation of higher-order structures, we have observed that most of TSSaRNAs (92.2%) were capable of hybridizing into their cognate genes also 55 TSSaRNAs indicated putative interactions with Lsm protein. Furthermore, the computation docking experiments demonstrated the TSSaRNAs-Lsm complexes associated with favorable binding energy of a median of -542900 kcal mole -¹. Regarding the functional annotation of TSSaRNAs, the results showed that the majority of TSSaRNAs (42.05%) considered as potential cis-acting regulators such as cis-regulatory element and sRNAs, but still, there are potential trans-acting regulators to regulate distant molecules such as CRISPR and antisense RNA. Moreover, the results indicated that TSSaRNAs could trigger more complex function as a catalytic function such as Riboswitch or to play a role in the defense against a virus such as CRISPR. As a conclusion; based on the results of this study we could state that TSSaRNAs have several potential functions opening the experimental validation perspective. / Os RNA não codificantes associados ao sítio de início da transcrição - em inglês, transcription start site associated non-coding RNAs (TSSaRNA) - foram observados nos três domínios da vida. No entanto, sem esforço confiável de anotação para identificar suas funções biológicas e seus mecanismos moleculares. Portanto, esse projeto levanta a questão de quais são as funções em potencial dos TSSaRNAs a respeito de seus papeis nas funções celulares. Para responder esta questão, nós objetivamos em identificar de forma eficaz os TSSaRNAs no organismo modelo Halobacterium salinarum NRC-1 (um microrganismo do domínio Arqueia) encubado em uma condição de crescimento padrão. Consequentemente, nós investigamos a estabilidade estrutural dos TSSaRNAs em relação a energias termodinâmicas. Ainda, fizemos a anotação funcional dos TSSaRNAs baseado na classificação funcional Rfam dos RNAs não-codificantes. Baseada em uma abordagem estatística nós desenvolvemos um algoritmo para predizer TSSaRNA usando dados de sequenciamento de RNA de nova geração (RNA-Seq). Para investigar a estabilidade estrutural dos TSSaRNAs nós modelamos as estruturas secundárias minimizando a energia livre termodinâmica para alcançar a estrutura mais estável biofisicamente. Nós simulamos estruturas terciárias de TSSaRNAs baseado nas restrições das estruturas secundárias usando a ferramenta Rosetta-Common RNA. As estruturas de energia livre mínima seriam supostamente estruturas estáveis biofisicamente. Para investigar as estruturas de ordem superior (quaternária) dos TSSaRNAs, nós estudamos a hibridização entre os TSSaRNAs e seus genes cognatos como parte de um possível sistema de regulação baseado em RNA. Ainda, baseada na hipótese que os TSSaRNAs podem ligar à proteína para habilitar sua função, nós investigamos a interação entre TSSaRNAs e proteína Lsm que é conhecida por ser uma proteína chaperone que media função do RNA e está envolvida no processamento do RNA. Nosso pipeline para executar a anotação funcional dos TSSaRNAs objetivou classificar as TSSaRNAs em suas correspondentes classes Rfam baseado em dois passos: por meio de consulta das sequências TSSaRNA em relação a modelos de covariância de famílias Rfam ou por consulta de sequências Rfam em relação a modelos de covariância das estruturas de secundárias de consenso das estruturas secundárias nos TSSaRNAs. Os resultados mostraram que o algoritmo de detecção teve sucesso em identificar um total de 224 TSSaRNAs que expressaram na mesma direção dos mRNAs e 58 TSSaRNAs que expressaram no sentido oposto (antisenso) dos mRNAs. As moléculas TSSaRNAs identificadas mostraram um comprimento mediano de 25 nucleotídeos. A respeito da anotação estrutural dos TSSaRNAs, os resultados mostraram que a maioria dos TSSaRNAs possuíam estruturas secundárias estáveis termodinamicamente e suas estruturas terciárias foram capazes de formar estruturas mais complexas por meio de vínculos com outras biomoléculas. Quanto à formação de estruturas de maior de estruturas de alta ordem nos observamos que a maioria dos TSSaRNAs (92.2%) são capazes, pelo menos em princípio, de hibridizar em seus genes cognatos e, também, 55 TSSaRNAs evidenciaram interagir com a proteína Lsm. Além disso, os experimentos computacionais de docking demonstratam os complexos TSSaRNAs-Lsm associados com energia de ligação favorável com uma média de - 542900 kcal mole -¹. Quanto à anotação funcional dos TSSaRNAs, os resultados mostraram que a maioria dos TSSaRNAs (42.05%) podem ser consideradas potenciais reguladores atuando em cis tais como elemento cis-regulamentar e sRNAs, mas ainda há pontenciais reguladores atuando em trans para regular moléculas em loci distantes, tais como CRISPR e RNA antisense. Além disso, os resultados mostraram que TSSaRNAs podem potencialmente ativar funções mais complexas como uma função catalítica, tal como Riboswitch ou executar um papel de defesa contra vírus, tal como CRISPR. Como conclusão; baseado nos resultados desse estudo, nós podemos afirmar que TSSaRNAs possuem várias funções em potencial abrindo a perspecitiva de validação experimental. Anotação estrutural Anotação funcional Docagem de RNA Estruturas de ncRNAs de ordem superior Estruturas RNA Funções de ncRNAs Functional annotation Halobacterium salinarum NRC-1 Halobacterium salinarum NRC-1 Higher-order ncRNAs structures Interações de RNA Interações de TSSaRNAs-LSm ncRNAs functions ncRNAs prediction Non-coding RNA Predição de ncRNAs Regulação baseada em RNA Rfam Rfam RNA based regulation RNA docking RNA interactions RNA não codificante RNA structures Structural annotation TSSaRNAs TSSaRNAs TSSaRNAs-LSm interactions
4	Identificação de RNAs não codificadores expressos no epitélio olfatório / Identification of noncoding RNAs expressed in the olfactory epithelium Nascimento, João Batista Placido do 15 May 2018 (has links) Odorantes são detectados por centenas de receptores olfatórios (ORs) que pertencem à superfamília dos receptores acoplados à proteína G. Estes receptores são expressos nos neurônios sensoriais olfatórios localizados na cavidade nasal. Cada neurônio sensorial olfatório expressa um único alelo de gene OR de uma grande família de genes OR. Este padrão característico da expressão de genes OR resulta na formação de um mapa olfatório espacial no bulbo olfatório, que é necessário para a discriminação de odorantes pelo sistema olfatório. Os mecanismos envolvidos nesta regulação ainda não são bem conhecidos. O DNA genômico em neurônios olfatórios é coberto com marcas repressivas de metilação de histonas, indicando que a regulação da estrutura da cromatina deve desempenhar um papel importante na regulação da expressão de genes OR. Trabalhos anteriores demonstraram que RNAs não codificadores (ncRNAs) estão envolvidos na deposição de marcas de histonas em determinados genes. No entanto, os ncRNAs expressos no epitélio olfatório ainda não são conhecidos. Neste trabalho, identificamos e catalogamos o repertório completo de ncRNAs anotados, incluindo os miRNAs, expressos no epitélio olfatório de camundongos recémnascidos e adultos. Muitos destes, apesar de já anotados como ncRNAs, ainda não foram descritos na literatura como expressos no MOE. Identificamos ao todo 1161 miRNAs e 295 lincRNAs expressos no epitélio olfatório, e pudemos verificar como os níveis de expressão destes RNAs variam durante o desenvolvimento. A partir deste repertório, selecionamos lincRNAs que são preferencialmente expressos no epitélio olfatório quando comparados a outros tecidos de camundongo. Dez destes lincRNAs foram selecionados para validação utilizando-se RT-PCR. Cinco lincRNAs foram validados e analisados quanto à sua expressão em diferentes tecidos. Nosso trabalho estabelece uma plataforma de dados que permitirá o estudo do papel desempenhado por ncRNAs no epitélio olfatório. Além disto, os nossos resultados mostram que a abordagem utilizada permite a identificação de novos lincRNAs que apresentam expressão restrita ou preferencial no epitélio olfatório, e que, portanto, devem apresentar uma função relevante para o olfato. / Odorants are detected by hundreds of odorant receptors (ORs) which belong to the superfamily of G protein-coupled receptors. These receptors are expressed in the olfactory sensory neurons of the nose. Each olfactory sensory neuron expresses one single OR gene allele from a large family of OR genes. This characteristic pattern of OR gene expression results in the formation of a spatial olfactory map in the olfactory bulb, which is required for odorant discrimination by the olfactory system. The mechanisms involved in this regulation are unknown. OR genomic DNA in olfactory neurons is covered with repressive histone methylation marks, indicating that the chromatin structure should play an important role in the regulation of OR gene expression. Previous studies suggest that noncoding RNAs (ncRNAs) are involved in the deposition of histone marks in certain genes. However, the ncRNAs expressed in the olfactory epithelium are completely unknown. In this work, we used RNA-seq to identify and catalogue the complete repertoire of ncRNAs, including miRNAs, expressed in the olfactory epithelium from newborn and adult mice. In this way, we were able to identify 1161 miRNAs and 295 lincRNAs and analyze how their levels of expression varies during development. Out of these repertoire, we selected lincRNAs that are preferentially expressed in the olfactory epithelium when compared to other mouse tissues. Ten out of these lincRNAs were selected for validation by using RTPCR, and five of them could be validated and further analyzed. Our work establishes a data platform which will enable the study of the role played by ncRNAs in the olfactory epithelium. In addition, our results show that our approach can be successfully used to identify ncRNAs that are restrictedly or preferentially expressed in the olfactory epithelium, and which therefore must be relevant for olfaction. Epitélio Olfatório Expressão gênica lincRNAs lincRNAs miRNAs miRNAs ncRNAs ncRNAs Odorant receptors Olfactory epithelium Receptores olfatórios RNA-seq Sequenciamento de DNA em larga escala
5	A Small RNA and DNA Binding Protein Contribute to Biofilm Development in <em>Bartonella henselae</em> Okaro, Udoka 02 July 2019 (has links) A biofilm, which is associated with 80% of chronic infections in humans, is formed when bacteria aggregate, attach to a substrate and secrete a matrix protecting the bacteria from host cell defenses and antibiotics. Bartonella henselae (B. henselae) is the causative agent of cat scratch disease, persistent bacteremia, and one of the most frequently reported causes of blood-culture negative endocarditis (BCNE) in patients. The ability of B. henselae to adhere to the heart valve, form a biofilm and vegetation to cause endocarditis increases the morbidity and mortality rate in infected patients. The presence of a trimeric autotransporter adhesin (TAA) called Bartonella adhesin A (BadA) has been linked to biofilm formation in B. henselae. BadA is a protein of 3036 amino acids and a member of the TAAs found in Bartonella and other Gram-negative bacteria. The function of BadA has been studied in vitro and is critical for agglutination, host cell adhesion and activation of a pro-angiogenic host response. However, very little is known about badA gene regulation or the molecular basis of biofilm formation. This work aims to determine whether BadA is necessary for the establishment of biofilms and how the bacteria regulate badA expression. Using genetic mutations, real-time cell adhesion assay, RT-qPCR, and microscopy, it was shown that BadA is required for biofilm formation. Using an in-frame complete deletion strain of badA, a reduced ability to form a biofilm was observed which was restored in the deletion strain complemented with a partial badA. Analysis of the B. henselae transcriptome shows nine highly transcribed, homologous RNAs, termed Bartonella regulatory transcript (Brt1-9). The Brts are short-sized (<200 >nucleotides), highly expressed, and located in an intergenic region indicative of small RNAs (sRNA). The Brts are predicted to form a stable stem and loop structure with a potential terminator/riboswitch region on the 3′ end. Located ~20 nucleotides downstream of each Brt is a poorly transcribed helix-turn-helix DNA binding protein gene termed transcriptional regulatory protein (trps 1-9). High brt transcription stops just before the start of the trp implicating the 3’ loop of the Brt as a terminating loop. Replacement of the trp with a gfp reporter gene shows that in the absence of the 3′ end of Brt1, gfp is transcribed. Also consistent with our findings, an increase in both the transcription of trp1 and badA and the formation of a biofilm in mutants of the brt1 gene was observed. Furthermore, to determine the role of the Trp in regulating badA, an electrophoretic mobility shift assay was carried out. The data confirms that Trp1 binds the promoter region of badA gene to regulate gene expression. In summary, the brt1/trp1 regulon affects badA transcription and biofilm formation in B. henselae. Understanding the mechanism and condition(s) by which the brt/trp regulatory system regulates badA is a plausible approach to the development of treatments that target the formation of biofilm-related diseases and persistent bacteremia in humans. ncRNAs Transcriptional regulator Auto-transporter adhesin Trans-acting RNA Biochemistry Microbiology
6	The Synaptic RNAome - identification, interactions and intercellular transfer Epple, Robert 01 March 2022 (has links) No description available. 570 Synapse local translation neuronal plasticity astrocytes sequencing extracellular vesicles RNA regulation ncRNAs microRNAs intercellular RNA transfer Biologie (PPN619462639)
7	Identification And Characterization Of A Virus Inducible Non Coding RNA (VINC) Sreenivasa Murthy, U M 02 1900 (has links) Non-protein coding eukaryotic genome sequences often referred to as junk DNA are estimated to encode several non-coding RNAs (ncRNAs) which may account for nearly 98% of all genomic output in humans. The output of such a wide spread transcription in eukaryotes consists of intronic, antisense and small RNAs. In addition to the classical ncRNAs such as rRNA, tRNA and small nucleolar RNAs, the eukaryotic genome encodes two distinct categories of ncRNAs, referred to as small ncRNAs and long mRNA–like ncRNAs (mlncRNAs). The long ncRNAs, which are transcribed by RNA Polymerase II, spliced and polyadenylated, are implicated in a number of regulatory processes such as imprinting, X-chromosome inactivation, DNA demethylation, transcription, RNA interference, chromatin structure dynamics and antisense mediated regulation. Expression of noncoding RNAs is altered during stress conditions and a large number of such transcripts have been identified of late. This study has identified a novel ncRNA whose expression is upregulated during viral infection of mouse brain. While we have named this RNA as VINC or virus inducible ncRNA, others have named it as NEAT1 (Hutchinson et al., 2007) and Men (Sunwoo et al., 2008). VINC/NEAT1/Men is associated with a distinct nuclear domain called paraspeckles Using a cell line as well as an animal model system we have investigated VINC in great detail and based on these studies we report that VINC is a nuclear ncRNA that localizes to paraspeckles and it interacts with the paraspeckle protein, P54nrb in both cell line model system as well as in animal tissues by a combination of in vitro and in vivo methods. We have also mapped the domains within VINC that are involved in P54nrb interactions. Till date, the only other RNA known to localise to paraspeckles is CTN-RNA. While CTN-RNA is a protein coding RNA, VINC does not code for a protein and thus VINC is the first ncRNA to be localized to paraspeckles. Further, the mechanism of nuclear retention of these two paraspeckle RNAs appears to be distinct. In case of CTN-RNA, it has been clearly shown that it is A-I edited and such hyperedited RNAs are retained by the p54/nrb mediated complex in nucleus (Zhang and Carmichael, 2001). However the mechanism by which VINC is retained in nucleus is not clear. There is apparently no A-I editing in VINC and hence VINC retention in the nucleus by binding to nuclear proteins such as p54/nrb might involve a different mechanism. It is well established of late that nuclear matrix retains RNAs and that there is a population of poly (A) RNA that is retained in nucleus (Huang et al.,1994 ; Carter et al.,1991). However the significance of such retention is not clear but it is believed that it might be important for some constitutive functions in nucleus (Nickerson et al., 1989). More investigations are needed to understand the exact functions of nuclear RNAs such as VINC in supporting the nuclear architecture. P54nrb is a multi functional nuclear protein that mediates most of its functions in association with PSF (Shav-Tal and Zipori, 2002). Phosphorylation status of P54nrb is a key determinant for its localisation to various nuclear regions. P54nrb is a multiphosphorylated protein during mitosis and its phosphorylation is mediated by PIN-1 at its C-terminus (Proteau et al., 2005). Tyrosine phosphorylation of P54nrb is essential for it to be retained in nuclear matrix (Otto et al., 2001). The N-terminal phosphorylation is speculated but not much has been investigated. The protein has two distinct RNA recognition motifs (RRMs) in its N-terminus that are responsible for its RNA binding activity. The significance of the p54/nrb-PSF heterodimer cannot be undermined as they have been shown to be important during HIV replication. The dimer is recruited by viral machinery and P54nrb has been shown to be exported to cytosol for binding to replicative complexes (Zolotukhin et al., 2003). During adenoviral replication in nucleus many SR proteins are recruited to viral replication foci and rearrangement of speckle components happen. It has been shown with respect to speckles that nuclear domains are highly dynamic and exchange of proteins depends upon the transcriptional status of cell (Lamond and Spector, 2003). Flaviviral replication complexes are hosted in nucleus and ~20% of this complex docks in nucleus and serves as an alternate site for viral replication. The presence of viral replicative complexes alters the nuclear organisation and hence modulation of gene expression is expected (Uchil et al., 2006). The up regulation of nuclear ncRNA such as VINC is definitively one of those events associated with viral replication and definitively one needs to study the various changes carefully to understand the role of VINC in virus life cycle and/or viral pathogenesis. VINC interaction with the multi-functional nuclear protein P54nrb raises interesting aspects related to function of P54nrb in JEV infection. Knockdown of P54nrb in human myeloid cell line results in abnormal size of paraspeckles and impairs chondrogenesis (Hata et al., 2008). PSF-P54nrb complex can divert many of HIV gag RNA complexes to paraspeckles thus trying to restrict viral replication. However the exact relationship between paraspeckles and its constituent proteins is not clear. The presence of ncRNA adds another new dimension to paraspeckles. It is unclear whether the ncRNA VINC is essential for paraspeckle structure but a recent study indicates that Men (VINC/NEATI) RNA may be essential for paraspeckle formation (Sunwoo et al., 2008). The exact function VINC in neuronal as well as non-neuronal cell nuclei remains elusive and more investigations are need to understand these aspects. Virus Inducible Non Coding RNA RNA (Ribonucleic Acid) RNA-Protein Interactions Non-Coding RNAs Gene Expression Nuclear RNA-binding Protein VINC Non-coding RNAs (ncRNAs) Biochemical Genetics
8	O transcritoma antisense primário de Halobacterium salinarum NRC-1 / The antisense primary transcriptome of Halobacterium salinarum NRC-1 João Paulo Pereira de Almeida 04 September 2018 (has links) Em procariotos, RNAs antisense (asRNAs) constituem a classe de RNAs não codificantes (ncRNAs) mais numerosa detectada por métodos de avaliação de transcritoma em larga escala. Apesar da grande abundância, pouco se sabe sobre mecanismos regulatórios e aspectos da conservação evolutiva dessas moléculas, principalmente em arquéias, onde o mecanismo de degradação de RNAs dupla fita (dsRNAs) é um fenômeno pouco conhecido. No presente estudo, utilizando dados de dRNA-seq, identificamos 1626 inícios de transcrição primários antisense (aTSSs) no genoma de Halobacterium salinarum NRC-1, importante organismo modelo para estudos de regulação gênica no domínio Archaea. Integrando dados de expressão gênica obtidos a partir de 18 bibliotecas de RNA-seq paired-end, anotamos 846 asRNAs a partir dos aTSSs mapeados. Encontramos asRNAs em ~21% dos genes anotados, alguns desses relacionados a importantes características desse organismo como: codificadores de proteínas que constituem vesículas de gás e da proteína bacteriorodopsina, além de vários genes relacionados a maquinaria de tradução e transposases. Além desses, encontramos asRNAs em genes pertencentes a sistemas de toxinas-antitoxinas do tipo II e utilizando dados públicos de dRNA-seq, evidenciamos que esse é um fenômeno que ocorre em bactérias e arquéias. A interação de um ncRNA com seu RNA alvo pode ser dependente de proteínas, em arquéias, a proteína LSm é uma chaperona de RNA homóloga a Hfq de bactérias, implicada no controle pós-transcricional. Utilizamos dados de RIP-seq de RNAs imunoprecipitados com LSm e identificamos 91 asRNAs interagindo com essa proteína, para 81 desses, o mRNA do gene sense também foi encontrado interagindo. Buscando por aTSSs presentes nas mesmas regiões de genes ortólogos, identificamos 160 aTSSs que dão origem a asRNAs em H. salinarum possivelmente conservados em Haloferax volcanii. A expressão dos asRNAs anotados foi avaliada ao longo de uma curva de crescimento e em uma linhagem knockout de um gene que codifica uma RNase R, possível degradadora de dsRNAs em arquéias. Encontramos um total de 144 asRNAs diferencialmente expressos ao longo da curva de crescimento, para 56 desses o gene sense também está diferencialmente expresso, caracterizando possíveis mecanismos de regulação em cis por esses RNAs. Na linhagem knockout, encontramos cinco asRNAs diferencialmente expressos e apenas para um desses o gene sense também está diferencialmente expresso, resultado que não nos permitiu inferir um possível papel de degradação de dsRNAs da RNAse R em H. salinarum NRC-1. Nesse trabalho apresentamos um mapeamento completo do transcritoma antisense primário de H. salinarum NRC-1 com resultados que consistem em um importante passo na direção da compreensão do envolvimento da transcrição antisense na regulação gênica pós-transcricional desse organismo modelo do terceiro domínio da vida. / Antisense RNAs (asRNAs) constitute the most numerous class of non-coding RNAs (ncRNAs) detected by transcriptome highthroughput methods in prokaryotes. Despite this abundance, little is known about regulatory mechanisms and evolutionary aspects of these molecules, mainly in archaea, where the mechanism of double-strand RNA (dsRNA) degradation remains poorly understood. In this study, using dRNA-seq data, we identified 1626 antisense transcription start sites (aTSSs) in the genome of Halobacterium salinarum NRC-1, an important model organism for gene expression regulation studies in Archaea. By integrating gene expression data from 18 RNA-seq paired-end libraries, we were able to annotate 846 asRNAs from mapped aTSSs. We found asRNAs in ~21% of annotated genes including genes related to important characteristics of this organism, such as: gas vesicle proteins, bacteriorhodopsin, translation machinery and transposases. We also found asRNAs in type II toxin-antitoxin systems and using public dRNA-seq data, we show evidences that this phenomenon might be conserved in archaea and bacteria. The interaction of a ncRNA with its target may depend on intermediary proteins action. In archaea, the LSm protein is a RNA chaperone homologous to bacterial Hfq, involved in post-transcriptional regulation. We used RIP-seq data from RNAs immunoprecipitated with LSm and identified 91 asRNAs interacting with this protein, for 81 of these the mRNA of the sense gene is also interacting. We searched for aTSSs present in the same region of orthologous genes in the Haloferax volcanii. We found 160 aTSSs that originated asRNAs in H. salinarum NRC-1 that might be conserved in this two archaea. The expression of annotated asRNAs was analyzed over a growth curve and in a knockout strain for RNase R gene. We found 144 asRNA differentially expressed over the growth curve, for 56 of these the sense gene was also differentially expressed, characterizing possible cis regulators asRNAs. In the knockout strain we found five differentially expressed asRNAs and only one asRNA/gene pair, this result does not allow us to infer a dsRNA degradation in vivo activity for this RNase in H. salinarum NRC- 1. This work contributes to the discovery of the antisense transcriptome in H. salinarum NRC- 1 a relevant step to uncover the post-transcriptional gene regulatory network in this archaeon. Archaea Differential RNA-seq (dRNA-seq) Halobacterium salinarum Lsm RNAs antisense (asRNAs) RNAs dupla fita (dsRNAs) RNAs não codificantes (ncRNAs) RNAse R Sistemas toxinas-antitoxinas (TAs) Antisense RNAs (asRNAs) Archaea Differential RNA-seq (dRNA-seq) Double-strand RNAs (dsRNAs) Halobacterium salinarum LSm Non-coding RNAs (ncRNAs) RNAse R Toxins-antitoxins systems (TAs) Transcription start sites (TSSs)
9	O transcritoma antisense primário de Halobacterium salinarum NRC-1 / The antisense primary transcriptome of Halobacterium salinarum NRC-1 Almeida, João Paulo Pereira de 04 September 2018 (has links) Em procariotos, RNAs antisense (asRNAs) constituem a classe de RNAs não codificantes (ncRNAs) mais numerosa detectada por métodos de avaliação de transcritoma em larga escala. Apesar da grande abundância, pouco se sabe sobre mecanismos regulatórios e aspectos da conservação evolutiva dessas moléculas, principalmente em arquéias, onde o mecanismo de degradação de RNAs dupla fita (dsRNAs) é um fenômeno pouco conhecido. No presente estudo, utilizando dados de dRNA-seq, identificamos 1626 inícios de transcrição primários antisense (aTSSs) no genoma de Halobacterium salinarum NRC-1, importante organismo modelo para estudos de regulação gênica no domínio Archaea. Integrando dados de expressão gênica obtidos a partir de 18 bibliotecas de RNA-seq paired-end, anotamos 846 asRNAs a partir dos aTSSs mapeados. Encontramos asRNAs em ~21% dos genes anotados, alguns desses relacionados a importantes características desse organismo como: codificadores de proteínas que constituem vesículas de gás e da proteína bacteriorodopsina, além de vários genes relacionados a maquinaria de tradução e transposases. Além desses, encontramos asRNAs em genes pertencentes a sistemas de toxinas-antitoxinas do tipo II e utilizando dados públicos de dRNA-seq, evidenciamos que esse é um fenômeno que ocorre em bactérias e arquéias. A interação de um ncRNA com seu RNA alvo pode ser dependente de proteínas, em arquéias, a proteína LSm é uma chaperona de RNA homóloga a Hfq de bactérias, implicada no controle pós-transcricional. Utilizamos dados de RIP-seq de RNAs imunoprecipitados com LSm e identificamos 91 asRNAs interagindo com essa proteína, para 81 desses, o mRNA do gene sense também foi encontrado interagindo. Buscando por aTSSs presentes nas mesmas regiões de genes ortólogos, identificamos 160 aTSSs que dão origem a asRNAs em H. salinarum possivelmente conservados em Haloferax volcanii. A expressão dos asRNAs anotados foi avaliada ao longo de uma curva de crescimento e em uma linhagem knockout de um gene que codifica uma RNase R, possível degradadora de dsRNAs em arquéias. Encontramos um total de 144 asRNAs diferencialmente expressos ao longo da curva de crescimento, para 56 desses o gene sense também está diferencialmente expresso, caracterizando possíveis mecanismos de regulação em cis por esses RNAs. Na linhagem knockout, encontramos cinco asRNAs diferencialmente expressos e apenas para um desses o gene sense também está diferencialmente expresso, resultado que não nos permitiu inferir um possível papel de degradação de dsRNAs da RNAse R em H. salinarum NRC-1. Nesse trabalho apresentamos um mapeamento completo do transcritoma antisense primário de H. salinarum NRC-1 com resultados que consistem em um importante passo na direção da compreensão do envolvimento da transcrição antisense na regulação gênica pós-transcricional desse organismo modelo do terceiro domínio da vida. / Antisense RNAs (asRNAs) constitute the most numerous class of non-coding RNAs (ncRNAs) detected by transcriptome highthroughput methods in prokaryotes. Despite this abundance, little is known about regulatory mechanisms and evolutionary aspects of these molecules, mainly in archaea, where the mechanism of double-strand RNA (dsRNA) degradation remains poorly understood. In this study, using dRNA-seq data, we identified 1626 antisense transcription start sites (aTSSs) in the genome of Halobacterium salinarum NRC-1, an important model organism for gene expression regulation studies in Archaea. By integrating gene expression data from 18 RNA-seq paired-end libraries, we were able to annotate 846 asRNAs from mapped aTSSs. We found asRNAs in ~21% of annotated genes including genes related to important characteristics of this organism, such as: gas vesicle proteins, bacteriorhodopsin, translation machinery and transposases. We also found asRNAs in type II toxin-antitoxin systems and using public dRNA-seq data, we show evidences that this phenomenon might be conserved in archaea and bacteria. The interaction of a ncRNA with its target may depend on intermediary proteins action. In archaea, the LSm protein is a RNA chaperone homologous to bacterial Hfq, involved in post-transcriptional regulation. We used RIP-seq data from RNAs immunoprecipitated with LSm and identified 91 asRNAs interacting with this protein, for 81 of these the mRNA of the sense gene is also interacting. We searched for aTSSs present in the same region of orthologous genes in the Haloferax volcanii. We found 160 aTSSs that originated asRNAs in H. salinarum NRC-1 that might be conserved in this two archaea. The expression of annotated asRNAs was analyzed over a growth curve and in a knockout strain for RNase R gene. We found 144 asRNA differentially expressed over the growth curve, for 56 of these the sense gene was also differentially expressed, characterizing possible cis regulators asRNAs. In the knockout strain we found five differentially expressed asRNAs and only one asRNA/gene pair, this result does not allow us to infer a dsRNA degradation in vivo activity for this RNase in H. salinarum NRC- 1. This work contributes to the discovery of the antisense transcriptome in H. salinarum NRC- 1 a relevant step to uncover the post-transcriptional gene regulatory network in this archaeon. Antisense RNAs (asRNAs) Archaea Archaea Differential RNA-seq (dRNA-seq) Differential RNA-seq (dRNA-seq) Double-strand RNAs (dsRNAs) Halobacterium salinarum Halobacterium salinarum LSm Lsm Non-coding RNAs (ncRNAs) RNAs antisense (asRNAs) RNAs dupla fita (dsRNAs) RNAs não codificantes (ncRNAs) RNAse R RNAse R Sistemas toxinas-antitoxinas (TAs) Toxins-antitoxins systems (TAs) Transcription start sites (TSSs)
10	RNA Exosome & Chromatin: The Yin & Yang of Transcription: A Dissertation Rege, Mayuri 12 November 2015 (has links) Eukaryotic genomes can produce two types of transcripts: protein-coding and non-coding RNAs (ncRNAs). Cryptic ncRNA transcripts are bona fide RNA Pol II products that originate from bidirectional promoters, yet they are degraded by the RNA exosome. Such pervasive transcription is prevalent across eukaryotes, yet its regulation and function is poorly understood. We hypothesized that chromatin architecture at cryptic promoters may regulate ncRNA transcription. Nucleosomes that flank promoters are highly enriched in two histone marks: H3-K56Ac and the variant H2A.Z, which make nucleosomes highly dynamic. These histone modifications are present at a majority of promoters and their stereotypic pattern is conserved from yeast to mammals, suggesting their evolutionary importance. Although required for inducing a handful of genes, their contribution to steady-state transcription has remained elusive. In this work, we set out to understand if dynamic nucleosomes regulate cryptic transcription and how this is coordinated with the RNA exosome. Remarkably, we find that H3-K56Ac promotes RNA polymerase II occupancy at a large number of protein coding and noncoding loci, yet neither histone mark has a significant impact on steady state mRNA levels in budding yeast. Instead, broad effects of H3-K56Ac or H2A.Z on levels of both coding and ncRNAs are only revealed in the absence of the nuclear RNA exosome. We show that H2A.Z functions with H3-K56Ac in chromosome folding, facilitating formation of Chromosomal Interaction Domains (CIDs). Our study suggests that H2A.Z and H3-K56Ac work in concert with the RNA exosome to control mRNA and ncRNA levels, perhaps in part by regulating higher order chromatin structures. Together, these chromatin factors achieve a balance of RNA exosome activity (yin; negative) and Pol II (yang; positive) to maintain transcriptional homeostasis. chromatin H3-K56Ac H2A.Z ncRNAs RNA exosome chromosome interaction domains Dissertations, UMMS Chromatin Exosomes Homeostasis Nucleosomes RNA, Messenger Saccharomyces cerevisiae RNA, Long Noncoding Transcription Factors Biochemistry Molecular Biology Molecular Genetics Structural Biology

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