Identification de protéines impliquées dans la localisation des ARNm au niveau de l'appareil mitotique

Oré Rodriguez, Sulin

04 1900

La localisation des ARNm au niveau des microtubules et des centrosomes laisse voir le centrosome et le fuseau mitotique comme des complexes ribonucléoprotéiques. Cependant, le mécanisme de localisation des ARNm à ces différentes structures ainsi que leurs fonctions dans la régulation de la mitose restent encore incompris. L’objectif était ici de caractériser des protéines de liaison à l’ARN (RNA Binding Proteins, RBPs) fonctionnellement impliquées dans la localisation des ARNm mitotiques chez la Drosophile et d’évaluer la conservation de la fonction de ces RBPs dans les cellules humaines. La déplétion de RBPs par RNAi générée dans des Drosophiles mutantes résulte en des phénotypes distincts de localisation anormale de l’ARNm centrosomique cen et en des défauts mitotiques différents selon le RBP ciblé, suggérant des fonctions différentes de ces RBPs. De plus, dans les jeunes embryons, les RBPs Bru-2 et Mask semblent être fonctionnellement importants pour la mitose via la régulation de l’ARNm cen, donnant un aperçu de la possible fonction mitotique de RBPs dans la régulation d’un ARN centrosomique. De plus, il a été observé dans un criblage d’immunofluorescence dans des cellules HeLa en métaphase que HNRNPUL1 colocalise au fuseau et aux centrosomes. HNRNPUL1 pourrait être impliqué dans la régulation de l’ARNm CDR2 (orthologue de cen) puisque la déplétion de l’orthologue de HNRNPUL1 dans la Drosophile, CG30122, résulte en une localisation anormale de l’ARNm centrosomique cen. / The localization of mRNA to microtubules and centrosomes has led to the suggestion that the centrosome and mitotic spindle are in fact ribonucleoprotein complexes. However, the mechanism of mRNA localization to those structures and its functional contribution in mitosis regulation remain poorly characterized. The objectives here were to identify RNA Binding Proteins (RBPs) involved in mitotic mRNA localization in Drosophila and to assess the conservation of the function of these RBPs in human cells. RNAi-mediated RBP depletion in Drosophila mutants leads to distinct phenotypes of abnormal localization of the centrosomal cen mRNA, and to different mitotic defects depending on the targeted RBP, suggesting different functions for these RBPs. Moreover, in young embryos, Bru-2 and Mask RBPs seem to be functionally important for mitosis through cen mRNA regulation, giving insight into a possible RBP mitotic function in regulating a centrosomal mRNA. In addition, data from an immunofluorescence screen on HeLa cells at metaphase suggests that HNRNPUL1 colocalizes to the spindle and centrosomes. HNRNPUL1 may be involved in the regulation of CDR2 mRNA (cen ortholog) because depletion of the HNRNPUL1 ortholog in flies, CG30122, disrupted cen mRNA localization.

Localisation d'ARNm

cen

ARNm centrosomique

RBPs mitotiques

Drosophila melanogaster

mRNA localization

cen

Centrosomal mRNA

mitotic RBPs

Discovery and evolutionary dynamics of RBPs and circular RNAs in mammalian transcriptomes

Badve, Abhijit

30 March 2015

Indiana University-Purdue University Indianapolis (IUPUI) / RNA-binding proteins (RBPs) are vital post-transcriptional regulatory molecules in transcriptome of mammalian species. It necessitates studying their expression dynamics to extract how post-transcriptional networks work in various mammalian tissues. RNA binding proteins (RBPs) play important roles in controlling the post-transcriptional fate of RNA molecules, yet their evolutionary dynamics remains largely unknown. As expression profiles of genes encoding for RBPs can yield insights about their evolutionary trajectories on the post-transcriptional regulatory networks across species, we performed a comparative analyses of RBP expression profiles across 8 tissues (brain, cerebellum, heart, lung, liver, lung, skeletal muscle, testis) in 11 mammals (human, chimpanzee, gorilla, orangutan, macaque, rat, mouse, platypus, opossum, cow) and chicken & frog (evolutionary outgroups). Noticeably, orthologous gene expression profiles suggest a significantly higher expression level for RBPs than their non-RBP gene counterparts, which include other protein-coding and non-coding genes, across all the mammalian tissues studied here. This trend is significant irrespective of the tissue and species being compared, though RBP gene expression distribution patterns were found to be generally diverse in nature. Our analysis also shows that RBPs are expressed at a significantly lower level in human and mouse tissues compared to their expression levels in equivalent tissues in other mammals: chimpanzee, orangutan, rat, etc., which are all likely exposed to diverse natural habitats and ecological settings compared to more stable ecological environment humans and mice might have been exposed, thus reducing the need for complex and extensive post-transcriptional control. Further analysis of the similarity of orthologous RBP expression profiles between all pairs of tissue-mammal combinations clearly showed the grouping of RBP expression profiles across tissues in a given mammal, in contrast to the clustering of expression profiles for non-RBPs, which frequently grouped equivalent tissues across diverse mammalian species together, suggesting a significant evolution of RBPs expression after speciation events. Calculation of species specificity indices (SSIs) for RBPs across various tissues, to identify those that exhibited restricted expression to few mammals, revealed that about 30% of the RBPs are species-specific in at least one tissue studied here, with lung, liver, kidney & testis exhibiting a significantly higher proportion of species specifically expressed RBPs. We conducted a differential expression analysis of RBPs in human, mouse and chicken tissues to study the evolution of expression levels in recently evolved species (i.e., humans and mice) than evolutionarily-distant species (i.e., chickens). We identified more than 50% of the orthologous RBPs to be differentially expressed in at least one tissue, compared between human and mouse, but not so between human and an outgroup chicken, in which RBP expression levels are relatively conserved. Among the studied tissues (brain, liver and kidney) showed a higher fraction of differentially expressed RBPs, which may suggest hyper- regulatory activities by RBPs in these tissues with species evolution. Overall, this study forms a foundation for understanding the evolution of expression levels of RBPs in mammals, facilitating a snapshot of the wiring patterns of post-transcriptional regulatory networks in mammalian genomes. In our second study, we focused on elucidating novel features of post-transcriptional regulatory molecules called as circRNA from LongPolyA RNA-sequence data. The debate over presence of nonlinear exon splicing such as exon-shuffling or formation of circularized forms has finally come to an end as numerous repertoires have shown of their occurrence and presence through transcriptomic analyses. It is evident from previous studies that along with consensus-site splicing non-consensus site splicing is robustly occurring in the cell. Also, in spite of applying different high-throughput approaches (both computational and experimental) to determine their abundance, the signal is consistent and strongly conforming the plausible circularization mechanisms. Earlier studies hypothesized and hence focused on the ribo-minus non-polyA RNA-sequence data to identify circular RNA structures in cell and compared their abundance levels with their linear counterparts. Thus far, the studies show their conserved nature across tissues and species also that they are not translated and preferentially are without poly (A) tail, with one to five exons long. Much of this initial work has been performed using non-polyA sequencing thus probably underestimates the abundance of circular RNAs originating from long poly (A) RNA isoforms. Our hypothesis is if the circular RNA events are not the artifact of random events, but has a structured and defined mechanism for their formation, then there would not be biases on preferential selection / leaving of polyA tails, while forming the circularized isoforms. We have applied an existing computational pipeline from earlier studies by Memczack et. al., on ENCODE cell-lines long poly (A) RNA-sequence data. With the same pipeline, we achieve a significant number of circular RNA isoforms in the data, some of which are overlapping with known circular RNA isoforms from the literature. We identified an approach and worked upon to identify the precise structure of circular RNA, which is not plausible from the existing computational approaches. We aim to study their expression profiles in normal and cancer cell-lines, and see if there exists any pattern and functional significance based on their abundance levels in the cell.

RNA-protein interactions -- Research

Evolutionary genetics -- Research

Genomics -- Research

Gene expression -- Research

Genetic regulation -- Research

Computational biology -- Research

Genetic translation -- Research

Bioinformatics -- Research

Genetic transcription -- Regulation

RNA splicing

Nucleotide sequence -- Research

Transcriptional and translational dynamics of the human heart

Schneider-Lunitz, Valentin

21 July 2022

Die Genexpression wurde bisher hauptsächlich auf Transkriptions- und Proteinebene untersucht, wobei der Einfluss der Translation, die die Proteinhäufigkeit direkt beeinflusst, weitgehend außer Acht gelassen wurde. Um diese Rolle besser zu verstehen, habe ich Ribosomen-Profiling-Daten (Ribo-seq) verwendet, um die Translationsregulation zu untersuchen und neue Translationsvorgänge in 65 linksventrikulären Proben von DCM-Patienten im Endstadium und 15 Nicht-DCM-Kontrollen zu identifizieren. Dieser Datensatz half dabei, die Transkriptions- und Translationsregulation zwischen erkrankten und nicht betroffenen menschlichen Herzen zu sezieren und enthüllte Gene und Prozesse, die rein unter Translationskontrolle stehen. Darüber hinaus habe ich neue kardiale Proteine vorhergesagt, die von langen nicht-kodierenden RNAs (lncRNAs) und zirkulären RNAs (circRNAs) translatiert werden. Computergestützte Analysen dieser evolutionär jungen Proteine legten eine Beteiligung an verschiedenen molekularen Prozessen nahe, mit einer besonderen Anreicherung für den mitochondrialen Energiestoffwechsel. Schließlich identifizierte ich RNA-bindende Proteine (RBPs), deren Expression die Menge der Ziel-mRNA oder die Frequenz der Translationseffizienz (TE) beeinflusst. Für eine Untergruppe von 21 RBPs habe ich die Regulation auf beiden quantitativen Merkmalen beobachtet, was zu einer unterschiedlichen mechanistischen Basis der Expressionskontrolle für unabhängige Gensätze führte. Obwohl die genaue Umschaltung der RBP-Funktion wahrscheinlich durch eine Kombination von mehreren Faktoren erreicht wird, haben wir für drei Kandidaten eine starke Abhängigkeit von der Zielgenlänge und der 5'-UTR-Struktur beobachtet. Diese Arbeit präsentiert einen Katalog von neu identifizierten Translationsereignissen und einen quantitativen Ansatz zur Untersuchung der Translationsregulation im gesunden und kranken menschlichen Herzen. / Gene expression has primarily been studied on transcriptional and protein levels, largely disregarding the extent of translational regulation that directly influences protein abundance. To elucidate its role, I used ribosome profiling (Ribo-seq) data, obtained through ribosome profiling, to study translational regulation and identify novel translation events in 65 left ventricular samples of end-stage DCM patients and 15 non-DCM controls. This dataset helped dissect transcriptional and translational regulation between diseased and unaffected human hearts, revealing genes and processes purely under translational control. These would have remained undetected by only looking at the transcriptional level. Furthermore, I predicted novel cardiac proteins translated from long non-coding RNAs (lncRNAs) and circRNAs. Computational analysis of these evolutionary young proteins suggested involvement in diverse molecular processes with a particular enrichment for mitochondrial processes. Finally, I identified RNA-binding proteins (RBPs) whose expression influences target mRNA abundance or translational efficiency (TE) rates. For a subset of 21 RBPs, I have observed regulation on both quantitative traits, which resulted in different mechanistic basis expression control for independent sets of genes. Though the precise switch in RBP function is likely achieved by a combination of multiple factors, for three candidates we have observed a strong dependency on target length and 5’ UTR structure. This work presents a catalogue of newly identified translation events and a quantitative approach to study translational regulation in the healthy and failing human heart.

lange nichkodirende RNA

lncRNA

RNA-bindende Proteine

RBP

Translation

Regulation

long noncoding RNA

lncRNA

RNA-binding proteins

RBPs

translation

regulation

570 Biologie

WG 1920

WD 5355

WW 7700

ddc:570