Global ETD Search

601	Identifying and analysing alternative splice variants by aligning ESTs and mRNAs to the genomic sequence Geirardsdottir, Kristin January 2005 (has links) <p>Questions have been raised about the genomic complexity of the human genome, since it was reported that it only consisted of 32,000 genes. Alternative splicing is considered the explanation of the enormous difference between the number of genes and the number of proteins. Aligning expressed sequence tags (ESTs) to the genomic sequence has become a popular approach for gene prediction, revealing alternative splice variants. The aim in this thesis is to identify and analyse splice variants of the adhesion family of G protein-coupled receptors using EST data. 75% of the genes in the data set of 33 sequences were found to have a total of 51 splice variants. About half of the variants were considered functional.</p> Splice variants alternative splicing expressed sequence tags (ESTs) G protein-coupled receptors (GPCRs) adhesion GPCRs Bioinformatics Bioinformatik
602	Alternative Splicing Regulation in Programmed Cell Death and Neurological Disorders: A Systems Biology Approach Wang, Qingqing 30 June 2015 (has links) Alternative splicing (AS) is a major source of biological diversity and a crucial determinant of cell fate and identity. Characterizing the role of AS regulatory networks in physiological and pathological processes remains challenging. The work presented here addresses this challenge using systems biology analyses of AS regulatory networks in programmed cell death and neurological disorders. The first study describes a genome-wide screen based on splicing-sensitive reporters to identify factors that affect the AS of apoptosis regulators Bclx and Mcl1. The screen identified over 150 factors that affect apoptosis through modulating the pro- and anti-apoptotic splicing variants of these apoptosis regulators. This screen revealed a new functional connection between apoptosis regulation and cell-cycle control through an AS network. It also unearthed many disease-associated factors as AS effectors. The second study describes the functions of the Polyglutamine-binding protein 1 (PQBP1)-mediated AS regulatory network in neurological disorders. PQBP1 is a factor linked to intellectual disability and was unexpectedly identified as an AS effector from the screen described above. We found that PQBP1 influences the splicing of many mRNAs and is associated with a wide range of splicing factors. Depletion of PQBP1 in mouse primary cortical neurons caused defects in neurite outgrowth and altered AS of mRNAs enriched for functions in neuron projection regulation. Disease-mutants of PQBP1 lose associations with splicing factors and cannot complement the aberrant AS patterns and neuron morphology defects in PQBP1 depleted-neurons. This study revealed a novel function of PQBP1 in AS regulation associated with neurite outgrowth and indicated that aberrant AS underlies the pathology of PQBP1-related neurological disorders. A final study examines the dynamics of the Drosophila Sex-lethal AS regulation network using a combination of experimental tools and mathematical modeling. This study demonstrates that the features of Sxl AS regulation have great potentials in building synthetic memory circuits in mammalian cells to track cell fate. Collectively, this work describes the landscape of three diverse AS regulatory networks in various biological processes. The results and methods presented here contribute to our rapidly advancing knowledge of AS regulation in biology and human disease. Biology Neurosciences Molecular biology apoptosis neurological disorders PQBP1 RNA alternative splicing RNA-seq analysis synthetic memory circuit
603	Processed small RNAs in Archaea and BHB elements Berkemer, Sarah J., Höner zu Siederdissen, Christian, Amman, Fabian, Wintsche, Axel, Will, Sebastian, Hofacker, Ivo L., Prohaska, Sonja J., Stadler, Peter F. 27 October 2015 (has links) (PDF) Bulge-helix-bulge (BHB) elements guide the enzymatic splicing machinery that in Archaea excises introns from tRNAs, rRNAs from their primary precursor, and accounts for the assembly of piece-wise encoded tRNAs. This processing pathway renders the intronic sequences as circularized RNA species. Although archaeal transcriptomes harbor a large number of circular small RNAs, it remains unknown whether most or all of them are produced through BHB-dependent splicing. We therefore conduct a genome-wide survey of BHB elements of a phylogenetically diverse set of archaeal species and complement this approach by searching for BHB-like structures in the vicinity of circularized transcripts. We find that besides tRNA introns, the majority of box C/D snoRNAs is associated with BHB elements. Not all circularized sRNAs, however, can be explained by BHB elements, suggesting that there is at least one other mechanism of RNA circularization at work in Archaea. Pattern search methods were unable, however, to identify common sequence and/or secondary structure features that could be characteristic for such a mechanism. ringförmig geschlossene RNA-Moleküle Archaea Spleißen struktur-basiert ddc:570 ddc:000
604	Assoziation von Polymorphismen und alternativen Splicevarianten von DNA-Reparaturgenen mit der Entwicklung von malignen Melanomen / Association of Polymorphisms and Alternative Spliceforms of DNA Repair Genes with the Development of Malignant Melanoma Blankenburg, Sandra 07 December 2005 (has links) No description available. MED 481 Medicine Polymorphismen DNA-Reparatur Splicevarianten malignes Melanom 610 Medizin Gesundheit polymorphisms DNA repair alternative splicing malignant melanoma 44.93
605	A Systems-Level Analysis of an Epithelial to Mesenchymal Transition Saunders, Lindsay Rose January 2012 (has links) <p>Embryonic development occurs with precisely timed morphogenetic cell movements directed by complex gene regulation. In this orchestrated series of events, some epithelial cells undergo extensive changes to become free moving mesenchymal cells. The transformation resulting in an epithelial cell becoming mesenchymal is called an epithelial to mesenchymal transition (EMT), a dramatic cell biological change that occurs throughout development, tissue repair, and disease. Extensive <italic>in vitro</italic> research has identified many EMT regulators. However, most <italic>in vitro</italic> studies often reduce the complicated phenotypic change to a binary choice between successful and failed EMT. Research utilizing models has generally been limited to a single aspect of EMT without considering the total transformation. Fully understanding EMT requires experiments that perturb the system via multiple channels and observe several individual components from the series of cellular changes, which together make a successful EMT.</p><p>In this study, we have taken a novel approach to understand how the sea urchin embryo coordinates an EMT. We use systems level methods to describe the dynamics of EMT by directly observing phenotypic changes created by shifting transcriptional network states over the course of primary mesenchyme cell (PMC) ingression, a classic example of developmental EMT. We systematically knocked down each transcription factor in the sea urchin's PMC gene regulatory network (GRN). In the first assay, one fluorescently labeled knockdown PMC precursor was transplanted onto an unperturbed host embryo and we observed the resulting phenotype <italic>in vivo</italic> from before ingression until two hours post ingression using time-lapse fluorescent microscopy. Movies were projected for computational analyses of several phenotypic changes relevant to EMT: apical constriction, apical basal polarity, motility, and de-adhesion. </p><p>A separate assay scored each transcription factor for its requirement in basement membrane invasion during EMT. Again, each transcription factor was knocked down one by one and embryos were immuno-stained for laminin, a major component of basement membrane, and scored on the presence or absence of a laminin hole at the presumptive entry site of ingression. </p><p>The measured results of both assays were subjected to rigorous unsupervised data analyses: principal component analysis, emergent self-organizing map data mining, and hierarchical clustering. This analytical approach objectively compared the various phenotypes that resulted from each knockdown. In most cases, perturbation of any one transcription factor resulted in a unique phenotype that shared characteristics with its upstream regulators and downstream targets. For example, Erg is a known regulator of both Hex and FoxN2/3 and all three shared a motility phenotype; additionally, Hex and Erg both regulated apical constriction but Hex additionally affected invasion and FoxN2/3 was the lone regulator of cell polarity. Measured phenotypic changes in conjunction with known GRN relationships were used to construct five unique subcircuits of the GRN that described how dynamic regulatory network states control five individual components of EMT: apical constriction, apical basal polarity, motility, de-adhesion, and invasion. The five subcircuits were built on top of the GRN and integrated existing fate specification control with the morphogenetic EMT control.</p><p>Early in the EMT study, we discovered one PMC gene, Erg, was alternatively spliced. We identified 22 splice variants of Erg that are expressed during ingression. Our Erg knockdown targeted the 5'UTR, present in all spliceoforms; therefore, the knockdown uniformly perturbed all native Erg transcripts (∑Erg). Specific function was demonstrated for the two most abundant spliceoforms, Erg-0 and Erg-4, by knockdown of ∑Erg and mRNA rescue with a single spliceoform; the mRNA expression constructs contained no 5'UTR and were not affected by the knockdown. Different molecular phenotypes were observed, and both spliceoforms targeted Tbr, Tel, and FoxO, only Erg-0 targeted FoxN2/3 and only Erg-4 targeted Hex. Neither targeted Tgif, which was regulated by ∑Erg knockdown sans rescue. Our results suggest the embryo employs a minimum of three unique roles in the GRN for alternative splicing of Erg. </p><p>Overall, these experiments increase the completeness and descriptive power of the GRN with two additional levels of complexity. We uncovered five sub-circuits of EMT control, which integrated into the GRN provide a novel view of how a complex morphogenetic movement is controlled by the embryo. We also described a new functional role for alternative splicing in the GRN where the transcriptional targets for two splice variants of Erg are unique subsets of the total set of ∑Erg targets.</p> / Dissertation Developmental biology Cellular biology Systematic biology alternative splicing EMT epithelial to mesenchymal transition gene regulatory networks GRN sea urchin
606	Comparing mutant p53 and a wild-type p53 isoform, p47 : rationale for the selection of mutant p53 in tumours Marini, Wanda. January 2009 (has links) One of the major unresolved questions in cancer biology is why the majority of tumour cells express mutant p53 proteins. p53 is considered the prototype tumour suppressor protein, whose inactivation is the most frequent single genetic event in human cancer (Bourdon et al., 2005). Genetically-engineered p53-null knockout mice acquire multiple tumours very early on in life and human Li-Fraumeni families who carry germline mutations in p53 are highly cancer-prone (reviewed in Vousden and Lane, 2007). p53 mutant proteins have been found to acquire novel functions that promote cancer cell proliferation and survival, yet exactly why mutant p53s acquire oncogenic activity is still poorly understood. Mutant p53 has also been found to complex with wildtype p53, thus acting in a dominant negative way. However, this inhibition is incomplete since many cancers with mutant p53 alleles also have a loss of the second wild-type p53 allele and thus only express the mutant p53 (Baker et al., 1989). An N-terminal truncated p53 isoform, p47, arising from alternative splicing of the p53 gene (Ghosh et al., 2004) or by alternative initiation sites for translation (Yin et al. , 2002), has been described. Alternative splicing was found to be universal in all human multi-exon genes (Wang et al., 2008) and therefore determining the role of the p47 isoform with respect to the p53 gene is essential. Evidence in this study suggests that mutant p53 (p53RI75H) has a similar structure and function as p47, including the ability to complex with and impair both p53 and p73. Therefore, in addition to expressing a tumour suppressor protein, the p53 gene can also express an onco-protein (p47). This study therefore argues that tumours select for mutant p53 because it has gained the ability to function like p47, a wild-type p53 isoform. Nuclear Proteins -- metabolism. Alternative Splicing.
607	Identification and Characterization of an Arginine-methylated Survival of Motor Neuron (SMN) Interactor in Spinal Muscular Atrophy (SMA) Tadesse, Helina 19 December 2012 (has links) Spinal Muscular Atrophy (SMA) is a neuronal degenerative disease caused by the mutation or loss of the Survival Motor Neuron (SMN) gene. The cause for the specific motor neuron susceptibility in SMA has not been identified. The high axonal transport/localization demand on motor neurons may be one potentially disrupted function, more specific to these cells. We therefore used a large-scale immunoprecipitation (IP) experiment, to identify potential interactors of SMN involved in neuronal transport and localization of mRNA targets. We identified KH-type splicing regulatory protein (KSRP), a multifunctional RNA-binding protein that has been implicated in transcriptional regulation, neuro-specific alternative splicing, and mRNA decay. KSRP is closely related to chick zipcode-binding protein 2 and rat MARTA1, proteins involved in neuronal transport/localization of beta-actin and microtubule-associated protein 2 mRNAs, respectively. We demonstrated that KSRP is arginine methylated, a novel SMN interactor (specifically with the SMN Tudor domain; and not with SMA causing mutants). We also found this protein to be misregulated in the absence of SMN, resulting in increased mRNA stability of KSRP mRNA target, p21cip/waf1. A role for SMN as an axonal chaperone of methylated RBPs could thus be key in SMA pathophysiology. Spinal Muscular Atrophy (SMA) Survival Motor Neuron (SMN) Neurodegenerative Disease Arginine Methylation
608	Functional Characterization of the Evolutionarily Conserved Adenoviral Proteins L4-22K and L4-33K Östberg, Sara January 2014 (has links) Regulation of adenoviral gene expression is a complex process directed by viral proteins controlling a multitude of different activities at distinct phases of the virus life cycle. This thesis discusses adenoviral regulation of transcription and splicing by two proteins expressed at the late phase: L4-22K and L4-33K. These are closely related with a common N-terminus but unique C-terminal domains. The L4-33K protein is an alternative RNA splicing factor inducing L1-IIIa mRNA splicing, while L4-22K is stimulating transcription from the major late promoter (MLP). The L4-33K protein contains a tiny RS-repeat in its unique C-terminal end that is essential for the splicing enhancer function of the protein. Here we demonstrate that the tiny RS-repeat is required for localization of the protein to the nucleus and viral replication centers. Further, we describe an auto-regulatory loop where L4-33K enhances splicing of its own intron. The preliminary characterization of the responsive RNA-element suggests that it differs from the previously defined L4-33K-responsive element activating L1-IIIa mRNA splicing. L4-22K lacks the ability to enhance L1-IIIa splicing in vivo, and here we show that the protein is defective in L1-IIIa or other late pre-mRNA splicing reactions in vitro. Interestingly, we found a novel function for the L4-22K and L4-33K proteins as regulators of E1A alternative splicing. Both proteins selectively upregulated E1A-10S mRNA accumulation in transfection experiments, by a mechanism independent of the tiny RS-repeat. Although L4-22K is reported to be an MLP transcriptional enhancer protein, here we show that L4-22K also functions as a repressor of MLP transcription. This novel activity depends on the integrity of the major late first leader 5’ splice site. The model suggests that at low concentrations L4-22K activates MLP transcription while at high concentrations L4-22K represses transcription. So far, characterizations of the L4-22K and L4-33K proteins have been limited to human adenoviruses 2 or 5 (HAdV-2/5). We expanded our experiments to include HAdV-3, HAdV-4, HAdV-9, HAdV-11 and HAdV-41. The results demonstrated that the transcription- or splicing-enhancing properties of L4-22K and L4-33K, respectively, are evolutionarily conserved and non-overlapping. Thus, the sequence-based conservation is mirrored by the functions, as expected for functionally important proteins. L4-22K L4-33K RNA splicing adenovirus nuclear localization replication transcription evolution SR protein MLP promoter E1A serotypes
609	Potential use of the Oncorhynchus mykiss checkpoint proteins Rad1 and Hus1 as genotoxicity biomarkers Bozdarov, Johny 15 December 2010 (has links) Cell-cycle checkpoint proteins help maintain genomic integrity by sensing damaged DNA and initiating DNA repair or apoptosis. Checkpoint protein activation to cell-cycle damaging agents can involve post-translational modifications and these alterations provide a means to determine whether DNA in a cell is damaged or not. Steinmoeller et al. (2009) showed that checkpoint proteins are suitable biomarkers for detecting genotoxins in Oncorhynchus mykiss (rainbow trout). In this project, two evolutionarily conserved checkpoint proteins, Rad1 and Hus1, have been cloned from rainbow trout and antibodies against these proteins were developed. This is the first time that either Rad1 or Hus1 has been characterized in rainbow trout. For rtRad1, it was determined that the open-reading frame was 840bp, which encodes 279aa with a predicted protein size of 31kDa. The rtRad1 amino-acid sequence is highly conserved and contains conserved exonuclease and leucine zipper domains. RT-PCR was used to identify alternatively spliced variants of rtRad1 and it appears that these variants encode different sized Rad1 proteins that are tissue and cell-line specific. A Rad1 splice variant that encodes an 18kDa protein appears to be abundant only in heart tissue and in the RTgill-W1 and RTbrain-W1 cell-lines. A genotoxicity study was completed where RTgill-W1 and RTbrain-W1 cells were treated with bleomycin, which induces double-stranded DNA breaks. In RTgill-W1, levels of an 18kDa Rad1 protein increased in a dose-dependent manner while in RTbrain-W1 the Rad1 levels remained the same. It appears that this 18kDa Rad1 protein may be directly involved in maintaining genomic integrity and shows potential to be used as a genotoxicity biomarker. This is the first time that an isoform of Rad1 has shown to be modified in the presence of a damaging agent. Both Rad1 and Hus1 need to be further characterized to determine their usefulness as genotoxicity biomarkers. genotoxicity biomarker Rad1 Hus1 rainbow trout alternative splicing 9-1-1 complex aquatic toxicology cell-cycle checkpoints Biology
610	Neuroendocrine control of puberty in vertebrates : characteriization of the kisspeptin system in flatfish Mechaly, Alejandro S. 27 June 2011 (has links) The recently discovered decapeptide kisspeptin and its G-protein coupled receptor form a signaling system expressed ubiquitously and are implicated in a variety of still poorly characterized functions. In the brain, kisspeptin is secreted by specific neurons and its receptor is localized in GnRH neurons. Kisspeptin signaling has been fully established in the control of the onset of puberty in vertebrates, from fish to mammals. In this study, we characterized the kisspeptin gene in the Senegalese sole and characterized the kisspeptin receptor genes in both the Senegalese sole and in the Atlantic halibut. In contrast to other fish species, the two species analyzed here showed only the presence of one ligand and one receptor, probably as a consequence of the genome reduction characteristic of Pleuronectiformes. However, in both cases we found an alternative splicing mechanism based on intron retention that produces also non-functional isoforms, but whether this is part of a mechanism to control abundance of the active gene product is still not known. We document spatial and temporal changes of expression of kisspeptin and its receptor in the brain, pituitary and gonads related to the annual reproductive cycle. Finally, we present the first evidence of a possible link between energy balance and reproduction mediated by kisspeptin signaling in a non-mammalian vertebrate. / El recentment descobert decapèptid kisspeptina i el seu receptor associat a una proteïna G formen un sistema que s’expressa ubiqüitament i que està implicat en diverses funcions, moltes de les quals encara no estan ben caracteritzades. En el cervell, la kisspeptina és secretada per neurones específiques, mentre que el seu receptor es troba a les neurones GnRH. Aquest sistema s’ha relacionat amb el control de l’inici de la pubertat en diferents vertebrats, des de peixos fins a mamífers. En aquest estudi, hem caracteritzat el gen de la kisspeptina en el llenguado senegalès, i els gens del receptor de la kisspeptina tant a llenguado senegalès com en l’Halibut de l’Atlàntic. Al contrari del que ocorre en moltes altres espècies de peixos, aquestes dues espècies només presenten un gen pel lligand i un gen pel recep- tor. Aquest fet és probable que estigui relacionat amb la reducció de la mida del genoma que han sofert els Pleuronectiformes. Tot i així, en les dues espècies s’hi troba un mecanisme d’empalmament alternatiu conseqüència d’una retenció intrónica que produeix una isoforma no funcional. Ara bé, si aquest mecanisme està relacionat amb el control de l’abundància dels trànscrits de la isoforma funcional encara està per esbrinar. Per altra banda, hem trobat canvis en l’expressió gènica tant en l’espai com en el temps durant un cicle reproductiu dels gens de la kisspeptina i el seu receptor en el cervell, pituïtària i gònades. Finalment, també presentem la primera evidència, en un vertebrat no mamífer, d’una possible relació entre el balanç energètic i la reproducció controlada pel sistema kisspeptina. Alternative splicing Atlantic halibut Pleuronectiformes Puberty Senegalese sole Expressió gènica Sistema kisspeptina Llenguado senegalès Peixos teleostis Empalmament alternatiu 57

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