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Regulation of U1 snRNP / 5' splice site interactions during pre-mRNA splicing in saccharomyces cerevisiaeStands, Leah Rae 01 October 2003 (has links)
No description available.
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Interakce proteinů Prp22 a Prp45 ve spliceosomu pučící kvasinky / The interaction of Prp22 and Prp45 proteins in budding yeast spliceosomeSenohrábková, Lenka January 2010 (has links)
Protein Prp22 is a DEAH box RNA helicase, which plays two distinct roles in pre-mRNA splicing: it participates in second transesterification step (ATP independent function) and it releases mature mRNA from the spliceosome (ATP dependent function). Prp45p, yeast ortholog of the human transcription co-regulator SNW/SKIP, is an essential splicing factor, it is included in spliceosome throughout the splicing reaction. Mutant prp45(1-169) genetically interacts with some alleles of NTC complex and second step splicing factors, one of them is also gene PRP22. Here we present, that mutants prp22(-158T) and prp22(-327A), which are synthetically lethal with prp45(1-169), express lower amount of Prp22p due to the mutation in upstream regulation region. Mutants prp22(-158T), prp22(300PPI) and prp22(-327A) affect splicing of pre-mRNA with mutation in 5'ss with respect to sequence of the second exon. N-terminal mutants prp22(∆301) and prp22(∆350) are synthetically lethal with prp45(1-169). Synthetic lethality is possibly caused by lower efficiency of Prp22 recruitment to the spliceosomes, which is no more viable for cells.
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Klíčové faktory při výběru sestřihových míst v kódujících a v dlouhých nekódujících RNA / Determinants of the splice site selection in protein-coding and long non-coding RNAsKrchňáková, Zuzana January 2019 (has links)
In my thesis, I focused on several underexplored areas of RNA splicing regulation. In the first part, I analyzed how chromatin and transcription regulatory elements change pre-mRNA splicing. In the second part, I studied why long non-coding RNAs (lncRNAs) are spliced less efficiently than protein-coding mRNAs. Finally, I was testing the importance of intron for the activating function of lncRNAs. It has been shown that chromatin and promoter identity modulate alternative splicing decisions. Here, I tested whether local chromatin and distant genomic elements that influence transcription can also modulate splicing. Using the chromatin modifying enzymes directly targeted to FOSL1 gene by TALE technology, I showed that changes in histone H3K9 methylation affect constitutive splicing. Furthermore, I provide evidence that deletion of transcription enhancer located several kilobases upstream of an alternative exons changes splicing pattern of the alternative exon. Many nascent lncRNAs undergo the same maturation steps as pre-mRNAs of protein- coding genes (PCGs), but they are often poorly spliced. To identify the underlying mechanisms for this phenomenon, we searched for putative splicing inhibitory sequences. Genome-wide analysis of intergenic lncRNAs (lincRNAs) revealed that, in general, they do not...
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IDENTIFICATION AND CHARACTERIZATION OF COMPONENTS OF THE YEAST SPLICEOSOMEPandit, Shatakshi Shreekant 01 January 2007 (has links)
The spliceosome is a complex, dynamic ribonucleoprotein (RNP) complex that undergoes numerous conformational changes during its assembly, activation, catalysis and disassembly. Defects in spliceosome assembly are thought to trigger active dissociation of faulty splicing complexes. A yeast genetic screen was performed to identify components of the putative discard pathway. This study found that weak mutant alleles of SPP382 suppress defects in several proteins required for spliceosome activation (Prp38p, Prp8p and Prp19p) as well as substrate mutations (weak branch point mutants). This evolutionary conserved protein had been found in both yeast and mammalian splicing complexes. However, its role in splicing had not been elucidated. This study focused on understanding the cellular role of Spp382p in splicing and particularly in the discard pathway. Spp382p was found to be essential for normal splicing and for efficient intron turnover. Since Spp382p binds Prp43p and is required for intron release in vitro, spp382 mediated suppression of splicing factor mutations might reflect lowered Prp43p activity. In agreement with this, we find that prp43 mutants also act as suppressors. This leads us to propose a model in which defects in spliceosome assembly, like those caused by prp38-1, prompt Spp382p-mediated disassembly of the defective complex via Prp43p Bolstering this theory, we find that Spp382p is specifically recruited to defective complexes lacking the 5 exon cleavage intermediate and spp382 mutants suppress other splicing defects. I show by stringent proteomic and two-hybrid analyses that Spp382p interacts with Cwc23p, a DnaJ-like protein present in the spliceosome and co-purified the Prp43p-DExD/H-box protein. In this study, I also show that Cwc23p is itself essential for splicing and normal intron turnover. Enhanced expression of another protein, Sqs1p, structurally related to Spp382p and also found associated with Prp43p is inhibitory to both growth and splicing. Synthetic lethal and dosage suppression studies bolster a functional linkage between Spp382p, Cwc23p, Sqs1p and Prp43p and together, the data support the existence of a Spp382p -dependent spliceosome integrity (SPIN) complex acting to remove defective spliceosomes.
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Investigation into the Saccharomyces cerevisiae U5 snRNP, a core spliceosome componentNancollis, Verity January 2011 (has links)
The U5 snRNP is a major component of the yeast spliceosome, being part of the U4/U6.U5 tri-snRNP, the precatalytic spliceosome and the catalytically activated spliceosome. The U5 snRNP includes, at its heart, the U5 snRNA which contains the invariant Loop 1 that functions in tethering and aligning exons during splicing. The major protein components of the U5 snRNP are the highly conserved Prp8p, the GTPase Snu114p and the helicase Brr2p. These proteins and the U5 snRNA are integral in forming the active site of the spliceosome and regulating the dynamic changes of the spliceosome. The first part of this study aimed to express and purify specific domains of Snu114p to define the structure and function of Snu114p. The N-terminal region of Snu114p was successfully expressed and purified from bacteria. Addition of the Snu114p N-terminal fragment to in vitro splicing assays resulted in a first step splicing defect, indicating a role for the N-terminus in pre-mRNA splicing. NMR studies revealed that the N-terminus of Snu114p exists as an unstructured protein domain. Mutagenesis indicated that the N-terminus of Snu114p is tolerant to mutation. A novel genetic interaction between amino acids in the N-terminus of Snu114p and the 3’ side of the U5 snRNA IL1 was identified. It is proposed here that the N-terminus of Snu114p functions to stabilise interactions of Snu114p with other proteins or snRNAs, possibly the U5 snRNA. Alternatively, the N-terminus of Snu114p may form intramolecular interactions with other regions of Snu114p to regulate Snu114p function in pre-mRNA splicing.Prp8p, Snu114p and Brr2p are known to form a stable complex but their interactions with the specific domains of the U5 snRNA are not known. The second part of this study aimed to investigate the association of Brr2p, Snu114p and Prp8p with the U5 snRNA. Mutants of the U5 snRNA were constructed in the conserved Loop 1 and the Internal Loop 1 (IL1). The influences of the U5 snRNA mutations on interactions of Prp8p, Snu114p or Brr2p with the snRNA were investigated. It was revealed that Loop 1 and both sides of IL1 of the U5 snRNA are important in association of Brr2p, Snu114p and Prp8p. Mutations in the 3’ side of IL1 drastically reduce association of Brr2p, Snu114p and Prp8p with the U5 snRNA, highlighting this region as a potential ‘protein docking’ site within the U5 snRNP. Differences seen in the associations of Brr2p, Snu114p and Prp8p with U5 snRNA mutations demonstrate that although there are intimate interactions between Brr2p, Snu114p and Prp8p, they do not associate with the U5 snRNA as a tri-protein complex. Genetic screening of BRR2 and U5 snRNA mutants reveals an interaction between the N-terminal half of Brr2p and the 3’ side of U5 snRNA IL1. This supports the proposed ‘protein docking’ site at the 3’ side of the U5 snRNA IL1.Data presented in this study increases our understanding of the regions in the U5 snRNA required for association of the essential U5 snRNP proteins, Brr2p, Snu114p and Prp8p, and goes some way to elucidating the organisation of essential proteins within the U5 snRNP.
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The Impact of Mutations and Downmodulation of LUC7L2 and Other Splicing Factors on Alternative Splicing Landscapes in Leukemic Cells and Malignant Bone MarrowHershberger, Courtney E. 07 September 2020 (has links)
No description available.
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Mapování interakcí SART3 se sestřihovými snRNP částicemi / Mapping of SART3 interactions with spliceosomal snRNPsKlimešová, Klára January 2015 (has links)
The splicing of pre-mRNA transcripts is catalyzed by a huge and dynamic machinery called spliceosome. The spliceosomal complex consists of five small nuclear ribonucleoprotein (snRNP) particles and hundreds of non-snRNP proteins. Biogenesis of spliceosomal snRNPs is a multi-step process, the final steps of which take place in a specialized sub-nuclear compartment, the Cajal body. However, molecular details of snRNP targeting to the Cajal body remain mostly unclear. Our previous results revealed that SART3 protein is important for accumulation of U4, U5 and U6 snRNPs in Cajal bodies, but how SART3 binds snRNP particles is elusive. SART3 has been identified as a U6 snRNP interaction partner and U4/U6 di-snRNP assembly factor. Here, we show that SART3 interacts with U2 snRNP as well, and that it binds specifically immature U2 particles. Next, we provide evidence that SART3 associates with U2 snRNP via Sm proteins, which are components of the stable snRNP core and are present in four out of five major snRNPs (i.e. in U1, U2, U4 and U5). We propose that the interaction between SART3 and Sm proteins represents a general SART3-snRNP binding mechanism, how SART3 recognizes immature snRNPs and quality controls the snRNP assembly process in Cajal bodies.
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Sestřih atypických intronů v S. cerevisiae / Splicing of atypical introns in S. cerevisiaeCit, Zdeněk January 2012 (has links)
Pre-mRNA splicing is a vital process of gene expression important for all eukaryotic organisms. For the proper function of this very complex and dynamic event the presence of few specialized RNA and many proteins that hold a variety of tasks is necessary, not only inside the splicing complex itself, but also beyond this complex. The Prp45 is one of the proteins involved in pre-mRNA splicing in yeast Saccharomyces cerevisiae. Its human homologue, SNW1/SKIP, is involved in splicing but also in other crucial cell processes. The Prp45 protein was reliably reported only to participate in the second transesterification reaction of splicing. But there are also data suggesting its possible involvement in the first transesterification reaction. This work provides further evidences linking protein Prp45 with the first splicing reaction, obtained by the research of cells carrying the mutant allele prp45(1-169). Cells carrying this allele show dropped splicing and accumulation of pre-mRNAs. This thesis therefore also investigated the possible influence of Prp45 protein on the RNA export from the nucleus to the cytoplasm. But no connection between this protein and RNA transport was discovered. Keywords pre-mRNA splicing; Saccharomyces cerevisiae; Prp45; Mer1; Mud2; Prp22; Rrp6; AMA1; SNW1/SKIP
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Funkční analýza mutací hPrp8 spojených s onemocněním retinitis pigmentosa. / Functional analysis of hPrp8 mutations linked to retinitis pigmentosa.Matějů, Daniel January 2013 (has links)
hPrp8 is an essential pre-mRNA splicing factor. This highly conserved protein is a component of the U5 small ribonucleoprotein particle (U5 snRNP), which constitutes one of the building blocks of the spliceosome. hPrp8 acts as a key regulator of spliceosome activation and interacts directly with U5 snRNA and with the regions of pre-mRNA that are involved in the transesterification reactions during splicing. Mutations in hPrp8 have been shown to cause an autosomal dominant form of retinitis pigmentosa (RP), an inherited disease leading to progressive degeneration of retina. In this study, we analyzed the effects of the RP-associated mutations on the function of hPrp8. Using BAC recombineering, we created mutant variants of hPrp8-GFP construct and we generated stable cell lines expressing the recombinant proteins. The mutant proteins were expressed and localized to the nucleus. However, one of the missense mutations affected the localization and stability of hPrp8. Further experiments suggested that RP-associated mutations affect the ability of hPrp8 to interact with other components of the U5 snRNP and with pre-mRNA. We further studied the biogenesis of U5 snRNP. We depleted hPrp8 by siRNA to interfere with U5 snRNP assembly and we observed that the incompletely assembled U5 snRNPs accumulate in...
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Vliv transkripčních regulačních elementů na sestřih pre-mRNA / Influence of transcription regulatory elemets on pre-mRNA splicingVolek, Martin January 2018 (has links)
In the process of pre-mRNA splicing introns are removed from pre-mRNA and exons are joined together. Current studies show, that about 95 % of genes, which contain more than two exons, can undergo alternative splicing. In this process some exons are included in or excluded from the final mRNA. Majority of pre-mRNA splicing take place co- transcriptionaly at this time RNA polymerase II is still attached to pre-mRNA. Alternative splicing is complex process that takes place in a close proximity of DNA and histones that might modulate alternative splicing decisions. Futher studies have validated fibronectin gene (FN1) and his alternative exons EDA and EDB (extra domain A and B) as suitably model for studying alternative splicing. Study using FN1 minigene reporter system, which is composed from EDA exon and two surrounding introns and exons, has proved that insertion of transcription enhancer SV40 infront of promotor, the level of EDA inclusion is decreased. So far, has not been prooved if this mechanism can function in real genome context and if distal transcription elements can influence alternative splicing. In this study, we have predicted transcription enhancer for FN1 gene by using The Ensemble Regulatory Build and FANTOM 5. The predicted transcription enhancer, is located 23,5 kbp upstream of TSS...
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