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Factors important for Cajal body formation
Roithová, Adriana ; Staněk, David (advisor) ; Valentová, Anna (referee)
This research describes the structure and function of nuclear domains called Cajal bodies (CB). CB contain proteins and factors involved in assembly and modification of snRNPs. These bodies are found in vertebrates and invertebrates and even plants. Not all cell types contain CB. Their number and size depends on the transcription activity of cell and cell cycle phase. This paper discusses the factors that affect the CB formation. One of the most important factors is the level of snRNPs and transcription activity. Recently shows that an important role in CB formation has coilin and other components phosphorylation. Other works show the influence of the environment. There is also discussion regulation of CB biogenesis, witch is not yet fully understood. Key words: Cajal bodies, coilin, cell nucleus, snRNP, pre-mRNA splicing, transcription
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Spliceosome assembly
Hausnerová, Viola ; Staněk, David (advisor) ; Chalupníková, Kateřina (referee)
Pre-mRNA splicing is a process in which introns are removed from eukaryotic transcripts and exons are ligated together. Splicing is catalyzed by spliceosome, a large ribonucleoprotein complex composed of five small nuclear RNAs and more than 100 additional proteins, which recognizes 5' splice site, branch point site and 3' splice site and performs two transesterification reactions to produce mRNA molecules. 5' splice site is recognized by U1 snRNP and U2 auxiliary factor (U2AF) is involved in branch point and 3' splice site recognition in the early splicing complex. There is some evidence of splice sites cooperation during intron recognition in vitro but little is known about the situation in vivo. Using Fluorescence resonance energy transfer (FRET) and RNA immunoprecipitation (RIP) methods, we have investigated the early stages of spliceosome assembly. We have employed splicing reporters based on -globin gene and MS2 stem loops to detect interactions of proteins on RNA molecule directly in the cell nucleus. Results of FRET indicate that intact 5' splice site is required for U2AF35 interaction with 3' splice site and that U1C recruitment to 5' splice site is partially limited upon 3' splice site mutation. We have also confirmed by RIP that U2 snRNP association with pre-mRNA molecule requires presence of 5'...
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Functional analysis of hPrp8 mutations linked to retinitis pigmentosa.
Matějů, Daniel ; Cvačková, Zuzana (advisor) ; Král, Vlastimil (referee)
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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The role of pre-mRNA splicing in human hereditary diseases
Malinová, Anna ; Staněk, David (advisor) ; Vanáčová, Štěpánka (referee) ; Krásný, Libor (referee)
U5 small ribonucleoprotein particle (U5 snRNP) is a crucial component of the spliceosome, the complex responsible for pre-mRNA splicing. Despite the importance of U5 snRNP, not much is known about its biogenesis. When we depleted one of the core U5 components, protein PRPF8, the other U5-specific proteins do not associate with U5 snRNA and the incomplete U5 was accumulated in nuclear structures known as Cajal bodies. To further clarify the role of PRPF8 in U5 snRNP assembly, we studied PRPF8 mutations that cause an autosomal dominant retinal disorder, retinitis pigmentosa (RP). We prepared eight different PRPF8 variants carrying RP-associated mutations and expressed them stably in human cell culture. We showed that most mutations interfere with the assembly of snRNPs which consequently leads to reduced efficiency of splicing. The mutant PRPF8 together with EFTUD2 are stalled in the cytoplasm in a form of U5 snRNP assembly intermediate. Strikingly, we identified several chaperons including the HSP90/R2TP complex and ZNHIT2 as new PRPF8's interactors and potential U5 snRNP assembly factors. Our results further imply that these chaperons preferentially bind the unassembled U5 complexes and that HSP90 is required for stability of...
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Recycling of spliceosomal complexes
Klimešová, Klára ; Staněk, David (advisor) ; Hálová, Martina (referee)
Most human genes are composed of coding sequences (exons) that are interrupted by non-coding sequences (introns). After gene transcription into pre-mRNA, these introns have to be removed in a process called splicing. Splicing is mediated by a very complex and dynamic complex called the spliceosome, which consists of five small nuclear ribonucleoprotein particles (snRNPs) and numerous additional splicing proteins. Each particle contains single small nuclear RNA and a set of specific proteins. SnRNPs are assembled by a stepwise process that takes place both in the nucleus and the cytoplasm and final maturation steps occur in nuclear Cajal bodies. The mature snRNPs interact with pre-mRNA in an ordered pathway and form the spliceosome that catalyzes two trans-esterification reactions leading to intron excision and exons ligation. Subsequently, the spliceosome disassembles again into individual snRNPs that have undergone diverse conformational and compositional transformations during splicing. Thus, before the particles can participate in another round of splicing they have to go through recycling to recover their original form. However, currently the recycling phase of the splicing cycle is surrounded by more questions than answers. The purpose of this work is to discuss latest findings that shed some light on...
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Determinants of the splice site selection in protein-coding and long non-coding RNAs
Krchňáková, Zuzana ; Staněk, David (advisor) ; Svoboda, Petr (referee) ; Blažek, Dalibor (referee)
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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Molecular mechanism of quality control during snRNP biogenesis
Klimešová, Klára ; Staněk, David (advisor) ; Krásný, Libor (referee) ; Vomastek, Tomáš (referee)
The spliceosome is one of the largest and most dynamic molecular machines in the cell. The central part of the complex is formed by five small nuclear ribonucleoproteins (snRNPs) which are generated in a multi-step biogenesis pathway. Moreover, the snRNPs undergo extensive rearrangements during the splicing and require reassembly after every intron removal. Both de novo assembly and post-splicing recycling of snRNPs are guided and facilitated by specific chaperones. Here, I reveal molecular details of function of two snRNP chaperones, SART3 and TSSC4. While TSSC4 is a previously uncharacterized protein, SART3 has been described before as a U6 snRNP-specific factor which assists in association of U6 and U4 particles into di-snRNP, and is important for the U4/U6 snRNP recycling. However, the mechanism of its function has been unclear. Here, I provide an evidence that SART3 interacts with a post-splicing complex and propose that SART3 could promote its disassembly. Our data further suggest that SART3 binds U6 snRNP already within the post-splicing complex and thus participates in the whole recycling phase of U6 snRNP. Then, I show that TSSC4 is a novel U5 snRNP-specific chaperone which promotes an assembly of U5 and U4/U6 snRNPs into a splicing-competent tri-snRNP particle. We identified...
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The role of pre-mRNA splicing in human hereditary diseases
Malinová, Anna
U5 small ribonucleoprotein particle (U5 snRNP) is a crucial component of the spliceosome, the complex responsible for pre-mRNA splicing. Despite the importance of U5 snRNP, not much is known about its biogenesis. When we depleted one of the core U5 components, protein PRPF8, the other U5-specific proteins do not associate with U5 snRNA and the incomplete U5 was accumulated in nuclear structures known as Cajal bodies. To further clarify the role of PRPF8 in U5 snRNP assembly, we studied PRPF8 mutations that cause an autosomal dominant retinal disorder, retinitis pigmentosa (RP). We prepared eight different PRPF8 variants carrying RP-associated mutations and expressed them stably in human cell culture. We showed that most mutations interfere with the assembly of snRNPs which consequently leads to reduced efficiency of splicing. The mutant PRPF8 together with EFTUD2 are stalled in the cytoplasm in a form of U5 snRNP assembly intermediate. Strikingly, we identified several chaperons including the HSP90/R2TP complex and ZNHIT2 as new PRPF8's interactors and potential U5 snRNP assembly factors. Our results further imply that these chaperons preferentially bind the unassembled U5 complexes and that HSP90 is required for stability of...
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The role of pre-mRNA splicing in human hereditary diseases
Malinová, Anna
U5 small ribonucleoprotein particle (U5 snRNP) is a crucial component of the spliceosome, the complex responsible for pre-mRNA splicing. Despite the importance of U5 snRNP, not much is known about its biogenesis. When we depleted one of the core U5 components, protein PRPF8, the other U5-specific proteins do not associate with U5 snRNA and the incomplete U5 was accumulated in nuclear structures known as Cajal bodies. To further clarify the role of PRPF8 in U5 snRNP assembly, we studied PRPF8 mutations that cause an autosomal dominant retinal disorder, retinitis pigmentosa (RP). We prepared eight different PRPF8 variants carrying RP-associated mutations and expressed them stably in human cell culture. We showed that most mutations interfere with the assembly of snRNPs which consequently leads to reduced efficiency of splicing. The mutant PRPF8 together with EFTUD2 are stalled in the cytoplasm in a form of U5 snRNP assembly intermediate. Strikingly, we identified several chaperons including the HSP90/R2TP complex and ZNHIT2 as new PRPF8's interactors and potential U5 snRNP assembly factors. Our results further imply that these chaperons preferentially bind the unassembled U5 complexes and that HSP90 is required for stability of...
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Determinants of the splice site selection in protein-coding and long non-coding RNAs
Krchňáková, Zuzana ; Staněk, David (advisor) ; Svoboda, Petr (referee) ; Blažek, Dalibor (referee)
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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