<i>Trans</i>-splicing of nematode pre-messenger RNA

Hannon, Gregory James

January 1992

No description available.

Biology, Molecular

RNA splicing

Nematodes

Structural and Thermodynamic Characterization of an Alternative Splicing Regulatory Element in HIV-1

Mishler, Clay H. J.

26 August 2011

No description available.

Biochemistry

HIV

alternative splicing

RNA

Molecular architecture of SF3B and the structural basis of splicing modulation

Cretu, Constantin

26 June 2018

No description available.

572

pre-mRNA splicing

spliceosome

human SF3B

splicing modulators

splicing modulation

pladienolide B

An experimental and genomic approach to the regulation of alternative pre-mRNA splicing in Drosophila rnp-4f

Fetherson, Rebecca A.

January 2005

Thesis (M.S.)--Miami University, Dept. of Zoology, 2005. / Title from first page of PDF document. Document formatted into pages; contains [1], ix, 75 p. : ill. Includes bibliographical references (p. 69-75).

Histonmodifieringar och alternativ splicing / Histone modifications and alternative splicing

Berggren, Jenny

January 2011

Alternativ splicing av pre-mRNA ger upphov till proteindiversitet. Histonmodifieringar kopplas till den alternativa splicingens reglering genom adaptorsystem som overfor den epigenetiska informationen direkt till splicingfaktorerna. De cis- agerande RNA- elementen pa exoner och introner med tillhorande trans- reglerande splicingfaktorer paverkas darfor direkt av specifika histonmodifieringar. En sammankopplande integrerad modell over en rad DNA- baserade processer foreslas. Denna komplexa modell ger en bild av interaktioner och paverkan mellan dessa delar. Kromatin remodellering kravs for bildandet av eukromatin. Nukleosomers placering vid exonrika regioner med specifika modifieringsmonster pekar ut exonerna samt mojliggor inbindning av RNA polymeras II som med sin CTD doman rekryterar bade splicing- och modifieringsfaktorer. Transkriptionshastigheten paverkas av nukleosomplaceringen vilket i sin tur paverkar rekrytering av spliceosomens komponenter, andra trans- agerande regulatorer och aven pre-mRNA sekvensens sekundarstruktur. Kromatin- adaptorkomplex laser av specifika histonmodifieringar och overfor informationen till splicingapparaten. Detta skapar mojlighet till den viktiga cell- och vavnadsspecifika alternativa splicingens reglering. I den integrerade modellen blir komplexiteten tydligare dar alla dessa processer interagerar med varandra och de cis- regulatoriska sekvenserna pa premRNA transkriptet. / Alternative splicing of pre-mRNA generates protein diversity. Histone modifications are connected to the regulation of alternative splicing through adaptor systems that transfers the epigenetic information directly to the splicing factors. The cis- acting RNA elements on the exons and introns together with the trans- regulating splicing factors are therefore directly affected of specific histone modifications. An integrated model over several DNA process mechanisms is suggested. This complex model explains the interactions of the different parts and how they affect each other. Chromatin remodelers are required to obtain euchromatin. Nucleosome positioning at exon rich regions with a specific modification pattern point out where the exons are, and this enable the RNA polymerase II to find and bind to the DNA. It’s CTD domain recruits both splicing- and modifications factors. The transcription rate is also affected of the nucleosome positioning and that in turn affects the recruitment of the components of the spliceosomen, other trans- acting regulators and even the formation of the secondary structure of the pre-mRNA transcript. Chromatin- adaptor complex reads specific histone modifications and transfers this information to the splicing apparatus. All this creates the possibility to regulate important cell- and tissue specific alternative splicing patterns. The integrated model makes the complex processes more clearer when all these integrates with each other and the cis- acting regulating elements on the pre-mRNA transcript.

Alternative splicing

Histone modifications

exon

intron

pre-mRNA splicing

splicing regulation

chromatin- adaptor system

integrated model

Alternativ splicing

Histonmodifieringar

exon

intron

pre-mRNA splicing

splicing regulering

kromatin- adaptor system

integrerad modell

Biology

Biologi

The Multifunctional Nature of the Adenovirus L4-22K Protein

Lan, Susan

January 2016

The adenovirus major late transcription unit (MLTU) encodes for most of the mRNAs that are translated into the structural proteins of the virus capsid. Transcription from the MLTU is directed by the major late promoter (MLP), which is highly activated during the late phase of infection. This thesis discusses how the adenovirus-encoded L4-22K protein regulates the MLP at both the level of transcription and pre-mRNA splicing. The study shed new light on the complex regulation of the early to late shift of adenoviral gene expression. Here we show that the L4-22K protein has opposing effects on MLP transcription, functioning both as an activator and a repressor protein. The stimulatory effect mainly depends on the direct interaction of the L4-22K protein with the downstream element (DE element) located approximately 100 nucleotides downstream of the transcription initiation site. In addition to the DE element we also show that the promoter-proximal upstream element (UPE) acts as an L4-22K responsive enhancer element in the MLP. Preliminary data suggests that the activation of MLP transcription via DE and UPE differs mechanistically. The transactivation domain of the L4-22K protein is localized to the conserved carboxy-terminus of the protein. Our results also defined a novel low affinity L4-22K binding site, the R1 region, which functions as a repressor element in MLP transcription. At high concentrations L4-22K binds to R1 and recruits the cellular transcription factor Sp1 to a DNA segment covering the major late first leader 5´ splice site that is embedded in the R1 region. Sp1 binding to R1 results in a suppression of L4-22K-mediated activation of MLP transcription. This self-limiting effect on MLP transcription might have a function to fine-tune the MLTU gene expression. Interestingly, the L4-22K protein binds with the same sequence specificity to both the R1 double-stranded DNA and R1 single-stranded RNA (ssRNA). L4-22K binds to the R1 ssRNA with the same polarity as the MLTU nascent RNA. This binding results in the recruitment of U1 snRNA to the major late first leader 5´ splice site. This enhanced U1 snRNA recruitment leads to a suppression of MLP transcription and simultaneously an increase of major late first intron splicing.

L4-22K

MLP

RNA

transcription

splicing

adenovirus

Brr2 RNA helicase and its protein and RNA interactions

Hahn, Daniela

January 2011

The dynamic rearrangements of RNA and protein complexes and the fidelity of pre-mRNA splicing are governed by DExD/H-box ATPases. One of the spliceosomal ATPases, Brr2, is believed to facilitate conformational rearrangements during spliceosome activation and disassembly. It features an unusual architecture, with two consecutive helicase-cassettes, each comprising a helicase and a Sec63 domain. Only the N-terminal cassette exhibits catalytic activity. By contrast, the C-terminal half of Brr2 engages in protein interactions. Amongst interacting proteins are the Prp2 and Prp16 helicases. The work presented in this thesis aimed at studying and assigning functional relevance to the bipartite architecture of Brr2 and addressed the following questions: (1) What role does the catalytically inert C-terminal half play in Brr2 function, and why does it interact with other RNA helicases? (2) Which RNAs interact with the different parts of Brr2? (1) In a yeast two-hybrid screen novel brr2 mutant alleles were identified by virtue of abnormal protein interactions with Prp2 and Prp16. Phenotypic characterization showed that brr2 C-terminus mutants exhibit a splicing defect, demonstrating that an intact C-terminus is required for Brr2 function. ATPase/helicase deficient prp16 mutants suppress the interaction defect of brr2 alleles, possibly indicating an involvement of the Brr2 C-terminus in the regulation of interacting helicases. (2) Brr2-RNA interactions were identified by the CRAC approach (in vivo Crosslinking and analysis of cDNA). Physical separation of the N-terminal and C-terminal portions and their individual analyses indicate that only the N-terminus of Brr2 interacts with RNA. Brr2 cross-links in the U4 and U6 snRNAs suggest a step-wise dissociation of the U4/U6 duplex during catalytic activation of the spliceosome. Newly identified Brr2 cross-links in the U5 snRNA and in pre-mRNAs close to 3’ splice sites are supported by genetic analyses. A reduction of second step efficiency upon combining brr2 and U5 mutations suggests an involvement of Brr2 in the second step of splicing. An approach now described as CLASH (Cross-linking, Ligation and Sequencing of Hybrids) identified Brr2 associated chimeric sequencing reads. The inspection of chimeric U2-U2 sequences suggests a revised secondary structure for the U2 snRNA, which was confirmed by phylogenentic and mutational analyses. Taken together these findings underscore the functional distinction of the N- and C-terminal portions of Brr2 and add mechanistic relevance to its bipartite architecture. The catalytically active N-terminal helicase-cassette is required to establish RNA interactions and to provide helicase activity. Conversely, the C-terminal helicase-cassette functions solely as protein interaction domain, possibly exerting regulation on the activities of interacting helicases and Brr2 itself.

572.85

Molecular characterisation of the PRP8 protein on Saccharomyces cerevisiae and identification of an analogue in HeLa cells

Anderson, Gordon James

January 1989

No description available.

572.8

Protein-encoding genes][RNA splicing

IDENTIFICATION AND CHARACTERIZATION OF COMPONENTS OF THE YEAST SPLICEOSOME

Pandit, Shatakshi Shreekant

01 January 2007

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.

REGULATION OF LOW DENSITY LIPOPROTEIN RECEPTOR SPLICING EFFICIENCY

Ling, I-Fang

01 January 2009

Low density lipoprotein receptor (LDLR) is an apolipoprotein E (apoE) receptor and may play a role in Alzheimer’s disease (AD) development. A single nucleotide polymorphism (SNP), rs688, that has been identified to modulate the splicing efficiency of LDLR exon 12 and is associated with higher cholesterol and AD in some case-control populations. The exon 12 deleted mRNA is predicted to produce a soluble form of LDLR that fails to mediate apoE uptake. To gain additional insights, in this study, I seek to understand the regulation of LDLR splicing efficiency. To identify functional cis-elements within LDLR exon 12, I mutated several conserved putative exonic splicing enhancers (ESEs) to neutralize their affinity to serine/arginine-rich (SR) proteins. Transfection of wild type (WT) or mutant LDLR minigenes in HepG2 cells was performed, and splicing efficiency evaluated by quantitative RT-PCR. The results showed that two functional ESEs within exon 12, near rs688, are critical to LDLR splicing. To identify splicing factors that modulate exon 12 splicing, I co-transfected an LDLR minigene and vectors encoding different SR proteins and heterogeneous nuclear ribonucleoproteins (hnRNPs). After quantifying the splicing efficiency, I found that SRp20 and SRp38 increased exon 11- skipping. Moreover, ectopic expression of SRp38-2 and hnRNP G increased exon 11&12-skipping. Interestingly, the actions of hnRNP G did not require its RNA recognition motif (RRM). To further investigate the role of theses splicing factors on LDLR splicing, I quantified the expression level of these splicing factors as well as LDLR splicing efficiency in human brain and liver. I found that SRp38 mRNA expression is associated with LDLR splicing efficiency. In conclusion, this study discovered that rs688 is located close to the two functional ESEs within LDLR exon 12, and revealed a role of SRp38 in LDLR splicing efficiency.

LDLR|SNP|Splicing|ESE|SRp38

Medical Physiology