Nonself recognition in Neurospora crassa and Cryphonectria parasitica /

Gibbs, Carmen Christine,

January 1900

Thesis (M. Sc.)--Carleton University, 2004. / Includes bibliographical references (p. 137-145). Also available in electronic format on the Internet.

Recrutamento do complexo repressivo polycomb 2 pelo RNA não codificador longo antissenso ANRASSF1 modula a expressão do gene RASSF1A e a proliferação celular / Recruitment of polycomb repressive complex 2 by intronic long noncoding RNA ANRASSF1 modulates RASSF1A expression and cell proliferation

Felipe César Ferrarezi Beckedorff

24 September 2012

O gene supressor tumoral RASSF1A tem sido associado com redução da proliferação celular em diversos tumores. Sua expressão é regulada por eventos epigenéticos que envolvem o complexo repressivo polycomb (PRC2), no entanto os mecanismos moleculares da modulação do recrutamento deste modificador epigenético para este locus ainda são desconhecidos. Neste trabalho identificamos e caracterizamos ANRASSF1, um RNA não codificador longo (lncRNA) intrônico unspliced, que é transcrito na fita oposta do gene RASSF1A, em várias linhagem celulares e tecidos, e se liga a PRC2. ANRASSF1 é transcrito pela RNAPII, possui cap-5´ e cauda poli-A, além de localizar-se no núcleo e possuir uma meia-vida em média quatro vezes menor comparada com outros lncRNAs ligados à PRC2. A super-expressão ectópica de ANRASSF1 reduziu os níveis de RASSF1A e aumentou a taxa de proliferação em células HeLa, enquanto seu silenciamento provocou efeito oposto. Essas mudanças nos níveis de ANRASSF1 não afetaram a abundância da isoforma RASSF1C em nenhuma das condições. A super-expressão de ANRASSF1 provocou um grande aumento tanto da ocupação de PRC2 como da marca de histona repressiva H3K27me3 especificamente na região promotora RASSF1A. Nenhum efeito da super-expressão de ANRASSF1 foi detectado na ocupação de PRC2 e na histona H3K27me3 nas regiões promotoras de RASSF1C e de outros quatro genes vizinhos, incluindo dois genes supressores tumorais bem caracterizados. Além disso, foi demonstrado que ANRASSF1 forma um híbrido de RNA/DNA e recruta SUZ12, um componente do PRC2, para o promotor de RASSF1A. Notavelmente, foi detectado pelo ensaio de RNase-ChIP que a degradação de ANRASSF1 diminui a ocupação de PRC2 neste promotor. Esses resultados demonstram um novo mecanismo de repressão epigenética do supressor tumoral RASSF1A, envolvendo um lncRNA unspliced antissenso, onde ANRASSF1 reprime seletivamente a expressão da isoforma de RASSF1 que sobrepõe o transcrito antissenso de modo local e específico. Considerando uma perspectiva mais ampla, nossos resultados sugerem que outros lncRNAs intrônicos unspliced não caracterizados no genoma humano podem contribuir para uma modulação epigenética local e específica de cada região em que os lncRNAs são transcritos. / Tumor-suppressor RASSF1A gene down-regulation has been implicated in increasing cell proliferation in several tumors. Its expression is regulated by epigenetic events involving polycomb repressive complex 2 (PRC2), however the molecular mechanisms modulating recruitment of this epigenetic modifier to the locus remain largely unknown. Here, we identify and characterize ANRASSF1, an endogenous unspliced long noncoding RNA (lncRNA) that is transcribed from the opposite strand of RASSF1 gene in several cell lines and tissues, and binds to PRC2. ANRASSF1 is transcribed by RNA Polymerase II, 5\'-capped, polyadenylated, displays nuclear localization, and has on average a four-fold shorter half-life compared to other lncRNAs that bind PRC2. ANRASSF1 ectopic overexpression decreases RASSF1A abundance and increases the proliferation rate of HeLa cells, whereas its silencing causes opposite effects. These changes in NRASSF1 levels do not affect RASSF1C isoform abundance. ANRASSF1 overexpression causes a marked increase both in PRC2 occupancy and in histone H3K27me3 repressive mark specifically at the RASSF1A promoter region. No effect of ANRASSF1 overexpression is detected on PRC2 occupancy and on histone H3K27me3 at the promoter regions of RASSF1C and of four other neighbor genes, including two well-characterized tumor suppressor genes. Additionally, we demonstrate that ANRASSF1 forms an RNA/DNA hybrid, and recruits SUZ12, a PRC2 component, to the RASSF1A promoter. Notably, depletion of ANRASSF1 disrupts SUZ12 occupancy on RASSF1A promoter as measured by RNAse-ChIP assay. Together, these results show a new mechanism of epigenetic repression of RASSF1A tumor suppressor gene involving an antisense unspliced lncRNA, in which ANRASSF1 selectively represses expression of the RASSF1 isoform overlapping the antisense transcript in a location-specific manner. In a broader perspective, our findings suggest that other non-characterized unspliced intronic lncRNAs transcribed in the human genome may contribute to a location-specific epigenetic modulation of genes.

Epigenética

Híbrido RNA-DNA

PRC2

RASSF1A

RNA não codificador longo antissenso

Antisense unspliced long noncoding RNA

Epigenetics

PRC2

RASSF1A

RNA-DNA hybrid

Relações da taxa RNA/DNA e parâmetros morfológicos no crescimento de juvenis de robalo-flecha (Centropomus undecimalis) cultivados / RRelationships RNA/DNA ratio and morphological parameters on growth of juvenile common snook (Centropomus undecimalis) cultivated.

Costa Filho, João

09 July 2013

Made available in DSpace on 2016-12-08T16:24:12Z (GMT). No. of bitstreams: 1 PGCA13MA092.pdf: 472096 bytes, checksum: aa4f745bb7f62d5ae8cd6ad77d0a4c7d (MD5) Previous issue date: 2013-07-09 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The marine fish farming and culture of snook, Centropomus undecimalis, have good prospects for commercial development in Brazil. In this regard, there is a need to expand studies on the evaluation of growth on snook, which can be realized by morphological or biochemical methods. The nutritional status and growth of fish can be influenced by several factors and their interactions, including genetic and environmental conditions, such as diet, different temperatures and salinities. Morphological analysis allows an investigation of the biometric data obtained from the body dimensions which are analyzed based on a mathematical relationship through correlation and linear regression equation. Regarding the biochemical methods, the most used are the quantification of DNA, RNA, proteins and determination of the RNA/DNA, protein/DNA ratios. Once the cell metabolism is usually associated with the nutritional status of the organism higher amounts of these components indicate greater biochemical activity of cells and protein synthesis. The results from this study will provide useful information related to the biology and cultivation of snook, promoting the application of biometric analysis and promoting a jumpstart for the application of biochemical analysis, cellular metabolism involved in the culture snook / A piscicultura marinha e o cultivo do robalo-flecha possuem boas perspectivas para o desenvolvimento comercial no Brasil. Neste sentido, existe a necessidade da ampliação de estudos relacionados com a avaliação do crescimento em robalos, que pode ser realizado por métodos morfológicos ou bioquímicos. A condição nutricional e o crescimento dos peixes podem ser influenciados por vários fatores e suas interações, incluindo a genética e as condições ambientais, como a alimentação, diferentes temperaturas e salinidades. A análise morfológica permite uma investigação das características biométricas, obtidas por meio das dimensões corporais, com base na sua relação matemática pela correlação e equação de regressão linear. Em relação aos métodos bioquímicos, os mais utilizados são a quantificação do DNA, RNA, proteínas e determinação das razões RNA/DNA, proteína/DNA. Uma vez que o metabolismo celular normalmente está relacionado com a situação nutricional do organismo, maiores quantidades desses componentes indicam maior atividade bioquímica das células e síntese proteica. Os resultados deste estudo permitem incrementar informações relacionadas à biologia e ao cultivo dos robalos aperfeiçoando a aplicação das análises biométricas e promovendo um salto inicial para a aplicação de análises bioquímicas, envolvidas com o metabolismo celular, no cultivo do robalo-flecha

piscicultura

características biométricas

razões RNA/DNA e proteína/DNA

fish farm

biometric characteristics

RNA/DNA and protein/DNA ratios

Recrutamento do complexo repressivo polycomb 2 pelo RNA não codificador longo antissenso ANRASSF1 modula a expressão do gene RASSF1A e a proliferação celular / Recruitment of polycomb repressive complex 2 by intronic long noncoding RNA ANRASSF1 modulates RASSF1A expression and cell proliferation

Beckedorff, Felipe César Ferrarezi

24 September 2012

O gene supressor tumoral RASSF1A tem sido associado com redução da proliferação celular em diversos tumores. Sua expressão é regulada por eventos epigenéticos que envolvem o complexo repressivo polycomb (PRC2), no entanto os mecanismos moleculares da modulação do recrutamento deste modificador epigenético para este locus ainda são desconhecidos. Neste trabalho identificamos e caracterizamos ANRASSF1, um RNA não codificador longo (lncRNA) intrônico unspliced, que é transcrito na fita oposta do gene RASSF1A, em várias linhagem celulares e tecidos, e se liga a PRC2. ANRASSF1 é transcrito pela RNAPII, possui cap-5´ e cauda poli-A, além de localizar-se no núcleo e possuir uma meia-vida em média quatro vezes menor comparada com outros lncRNAs ligados à PRC2. A super-expressão ectópica de ANRASSF1 reduziu os níveis de RASSF1A e aumentou a taxa de proliferação em células HeLa, enquanto seu silenciamento provocou efeito oposto. Essas mudanças nos níveis de ANRASSF1 não afetaram a abundância da isoforma RASSF1C em nenhuma das condições. A super-expressão de ANRASSF1 provocou um grande aumento tanto da ocupação de PRC2 como da marca de histona repressiva H3K27me3 especificamente na região promotora RASSF1A. Nenhum efeito da super-expressão de ANRASSF1 foi detectado na ocupação de PRC2 e na histona H3K27me3 nas regiões promotoras de RASSF1C e de outros quatro genes vizinhos, incluindo dois genes supressores tumorais bem caracterizados. Além disso, foi demonstrado que ANRASSF1 forma um híbrido de RNA/DNA e recruta SUZ12, um componente do PRC2, para o promotor de RASSF1A. Notavelmente, foi detectado pelo ensaio de RNase-ChIP que a degradação de ANRASSF1 diminui a ocupação de PRC2 neste promotor. Esses resultados demonstram um novo mecanismo de repressão epigenética do supressor tumoral RASSF1A, envolvendo um lncRNA unspliced antissenso, onde ANRASSF1 reprime seletivamente a expressão da isoforma de RASSF1 que sobrepõe o transcrito antissenso de modo local e específico. Considerando uma perspectiva mais ampla, nossos resultados sugerem que outros lncRNAs intrônicos unspliced não caracterizados no genoma humano podem contribuir para uma modulação epigenética local e específica de cada região em que os lncRNAs são transcritos. / Tumor-suppressor RASSF1A gene down-regulation has been implicated in increasing cell proliferation in several tumors. Its expression is regulated by epigenetic events involving polycomb repressive complex 2 (PRC2), however the molecular mechanisms modulating recruitment of this epigenetic modifier to the locus remain largely unknown. Here, we identify and characterize ANRASSF1, an endogenous unspliced long noncoding RNA (lncRNA) that is transcribed from the opposite strand of RASSF1 gene in several cell lines and tissues, and binds to PRC2. ANRASSF1 is transcribed by RNA Polymerase II, 5\'-capped, polyadenylated, displays nuclear localization, and has on average a four-fold shorter half-life compared to other lncRNAs that bind PRC2. ANRASSF1 ectopic overexpression decreases RASSF1A abundance and increases the proliferation rate of HeLa cells, whereas its silencing causes opposite effects. These changes in NRASSF1 levels do not affect RASSF1C isoform abundance. ANRASSF1 overexpression causes a marked increase both in PRC2 occupancy and in histone H3K27me3 repressive mark specifically at the RASSF1A promoter region. No effect of ANRASSF1 overexpression is detected on PRC2 occupancy and on histone H3K27me3 at the promoter regions of RASSF1C and of four other neighbor genes, including two well-characterized tumor suppressor genes. Additionally, we demonstrate that ANRASSF1 forms an RNA/DNA hybrid, and recruits SUZ12, a PRC2 component, to the RASSF1A promoter. Notably, depletion of ANRASSF1 disrupts SUZ12 occupancy on RASSF1A promoter as measured by RNAse-ChIP assay. Together, these results show a new mechanism of epigenetic repression of RASSF1A tumor suppressor gene involving an antisense unspliced lncRNA, in which ANRASSF1 selectively represses expression of the RASSF1 isoform overlapping the antisense transcript in a location-specific manner. In a broader perspective, our findings suggest that other non-characterized unspliced intronic lncRNAs transcribed in the human genome may contribute to a location-specific epigenetic modulation of genes.

Antisense unspliced long noncoding RNA

Epigenética

Epigenetics

Híbrido RNA-DNA

PRC2

PRC2

RASSF1A

RASSF1A

RNA não codificador longo antissenso

RNA-DNA hybrid

Genotoxic stress: novel biomarkers and detection methods : uncovering RNAs role in epigenetics of carcinogenesis /

Bajak, Edyta Zofia,

January 2005

Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 6 uppsatser.

Development and validation of statistical potential functions for the prediction of protein/nucleic-acid interactions from structure /

Robertson, Timothy Allen,

January 2007

Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 122-138).

Mapping of conserved RNA secondary structures predicts thousands of functional noncoding RNAs in the human genome

Washietl, Stefan, Hofacker, Ivo L., Lukasser, Melanie, Hüttenhofer, Alexander, Stadler, Peter F.

12 October 2018

In contrast to the fairly reliable and complete annotation of the protein coding genes in the human genome, comparable information is lacking for noncoding RNAs (ncRNAs). We present a comparative screen of vertebrate genomes for structural noncoding RNAs, which evaluates conserved genomic DNA sequences for signatures of structural conservation of base-pairing patterns and exceptional thermodynamic stability. We predict more than 30,000 structured RNA elements in the human genome, almost 1,000 of which are conserved across all vertebrates. Roughly a third are found in introns of known genes, a sixth are potential regulatory elements in untranslated regions of protein-coding mRNAs and about half are located far away from any known gene. Only a small fraction of these sequences has been described previously. A comparison with recent tiling array data shows that more than 40% of the predicted structured RNAs overlap with experimentally detected sites of transcription. The widespread conservation of secondary structure points to a large number of functional ncRNAs and cis-acting mRNA structures in the human genome.

Biochemistry, RNA, DNA, Genome

info:eu-repo/classification/ddc/576.5

ddc:576.5

Divergence of Conserved Non-Coding Sequences: Rate Estimate and Relative Rate Tests

Wagner, Günter P., Fried, Claudia, Prohaska, Sonja J., Stadler, Peter F.

16 October 2018

In many eukaryotic genomes only a small fraction of the DNA codes for proteins, but the non-protein coding DNA harbors important genetic elements directing the development and the physiology of the organisms, like promoters, enhancers, insulators, and micro-RNA genes. The molecular evolution of these genetic elements is difficult to study because their functional significance is hard to deduce from sequence information alone. Here we propose an approach to the study of the rate of evolution of functional non-coding sequences at a macro-evolutionary scale. We identify functionally important non-coding sequences as Conserved Non-Coding Nucleotide (CNCN) sequences from the comparison of two outgroup species. The CNCN sequences so identified are then compared to their homologous sequences in a pair of ingroup species, and we monitor the degree of modification these sequences suffered in the two ingroup lineages. We propose a method to test for rate differences in the modification of CNCN sequences among the two ingroup lineages, as well as a method to estimate their rate of modification. We apply this method to the full sequences of the HoxA clusters from six gnathostome species: a shark, Heterodontus francisci; a basal ray finned fish, Polypterus senegalus; the amphibian, Xenopus tropicalis; as well as three mammalian species, human, rat and mouse. The results show that the evolutionary rate of CNCN sequences is not distinguishable among the three mammalian lineages, while the Xenopus lineage has a significantly increased rate of evolution. Furthermore the estimates of the rate parameters suggest that in the stem lineage of mammals the rate of CNCN sequence evolution was more than twice the rate observed within the placental amniotes clade, suggesting a high rate of evolution of cis-regulatory elements during the origin of amniotes and mammals. We conclude that the proposed methods can be used for testing hypotheses about the rate and pattern of evolution of putative cis-regulatory elements.

info:eu-repo/classification/ddc/570

ddc:570

Multiple sequence alignments of partially coding nucleic acid sequences

Stocsits, Roman R., Hofacker, Ivo L., Fried, Claudia, Stadler, Peter F.

16 October 2018

High quality sequence alignments of RNA and DNA sequences are an important prerequisite for the comparative analysis of genomic sequence data. Nucleic acid sequences, however, exhibit a much larger sequence heterogeneity compared to their encoded protein sequences due to the redundancy of the genetic code. It is desirable, therefore, to make use of the amino acid sequence when aligning coding nucleic acid sequences. In many cases, however, only a part of the sequence of interest is translated. On the other hand, overlapping reading frames may encode multiple alternative proteins, possibly with intermittent non-coding parts. Examples are, in particular, RNA virus genomes.

info:eu-repo/classification/ddc/572.8

ddc:572.8

The application of nucleic acid interaction structure prediction

Newman, Tara

26 August 2022

Motivation: Understanding how nucleic acids interact is essential for understanding their function. Controlling these interactions, for example, can allow us to detect diseases and create new therapeutics. During quantitative reverse-transcription polymerase chain reaction (qRT-PCR) testing, having nucleic acids interact as designed is essential for ensuring accurate test results. Accurate testing is an important consideration during the detection of COVID-19, the disease caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Results: I introduced the program DinoKnot (Duplex Interaction of Nucleic acids with pseudoKnots) that follows the hierarchical folding hypothesis to predict the secondary structure of two interacting nucleic acid strands (DNA/RNA) of similar or different type. DinoKnot is the first program that utilizes stable stems in both strands as a guide to find the structure of their interaction. Using DinoKnot, I predicted the interaction structure between the SARS-CoV-2 genome and nine reverse primers from qRT-PCR primer-probe sets. I compared these results to an existing tool RNAcofold and highlighted an example to showcase DinoKnot’s ability to predict pseudoknotted structures. I investigated how mutations to the SARS-CoV-2 genome may affect the primer interaction and predicted three mutations that may prevent primer binding, reducing the ability for SARS-CoV-2 detection. Interaction structure results pre- dicted by DinoKnot that showed disruption of primer binding were consistent with a clinical example showing detection issues due to mutations. DinoKnot has the potential to screen new SARS-CoV-2 variants for possible detection issues and support existing applications involving DNA/RNA interactions, such as microRNA (miRNA) target site prediction, by adding structural considerations to the interaction to elicit functional information. / Graduate

Nucleic acid structure

Pseudoknot

DNA/RNA interaction

RNA/RNA interaction

RNA/DNA hetero-dimers

homo-dimers