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Úloha nepřekládaných oblastí mRNA v Giardia intestinalis. / The role of untranslated mRNA regions in Giardia intestinalis.Najdrová, Vladimíra January 2013 (has links)
Giardia intestinalis is an anaerobic protozoan pathogen, agent of the disease known as giardiasis. The regulation of gene expression during giardia cell- and life-cycle has been poorly studied so far, with the exception of variable surface proteins, which constitute the immunoprotective coat of the cell. In this diploma thesis, we focus on the possible role of the 3' untranslated region (3'UTR) of mRNA that mediate stability and localization of mRNA transcripts. We use RNA binding proteins of PUF family, which control the function of the target transcripts by their repression, activation or sequestration, to monitor and verify the role of 3'UTRs. These only eukaryotic proteins are highly evolutionarily conserved. Each of them contain highly conserved C-terminal domain, which specificly binds to 3'UTR of mRNAs. We have identified five different PUF proteins in the genome of G. intestinalis (GiPUF), cinfirmed their expression in G. intestinalis trophozoites and located all five proteins in the cytoplasm. GiPUF2, GiPUF3 and GiPUF5 show an additional affinity to the surface of the endoplasmic reticulum. We have identified the C-terminal binding domain in protein sequences of all GiPUF. The most conserved GiPUF4 contain eight binding sites, nearly identical to the binding site of human Pum1 protein,...
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Regulation of Human Papillomavirus Type 16 mRNA Splicing and PolyadenylationZhao, Xiaomin January 2005 (has links)
<p>Human papillomavirus type 16 (HPV-16) is the major causative agent of cervical cancer. The life cycle of this oncogenic DNA tumour virus is strictly associated with the differentiation program of the infected epithelial cells. Expression of the viral capsid genes L1 and L2 can only be detected in the terminally differentiated epithelial cells. The studies here focus on the regulation of HPV-16 late gene expression, which is under tight regulation. </p><p>Our experimental system consisted of almost the full length HPV-16 genome driven by a strong CMV promoter. This plasmid and mutants thereof could be transfected into HeLa cells and RNA levels monitored. Using this system, we identified an hnRNP A1-dependent splicing silencer between positions 178 and 226 of the L1 gene. This silencer inhibited the use of the 3' splice site, located immediately upstream of the L1 AUG. We speculate that this splicing silencer plays an essential role in preventing late gene expression at an early stage of the viral life cycle. We subsequently identified a splicing enhancer located in the first 17 nucleotides of L1 that may be needed to counteract the multiple hnRNP A1 dependent splicing silencers in the L1 coding region. A 55kDa protein specifically bound to this splicing enhancer. We also demonstrated that binding of the cellular factors to the splicing silencer in the L1 coding region had an inhibitory effect on expression from L1 cDNA expression plasmids.</p><p>The HPV-16 genome is divided into the early region and the late region, separated by the early poly(A) signal (pAE). pAE is used preferentially early in infection, thereby efficiently blocking late gene expression. We demonstrated that a 57 nucleotide U-rich region of the early 3’untranslated region (3’eUTR) acted as an enhancing upstream element on the usage of pAE. We demonstrated that this U-rich region specifically interacts with hFip1, CstF-64, hnRNP C1/C2 and PTB, suggesting that these factors were either enhancing or regulating polyadenylation at the HPV-16 pAE. </p><p>In conclusion, two regulatory RNA elements that both act to prevent late gene expression at an early stage in the viral life cycle and in proliferating cells were identified: a splicing silencer in the late region and an upstream u-rich element at the pAE.</p>
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Analysis Of 3' / Utr Shortening Events In Breast CancerBaloglu, Onur 01 January 2013 (has links) (PDF)
Cancer is the collective term used to describe a diverse group of diseases that share certain hallmarks, which in turn enables the affected cells to sustain an uncontrolled cell growth. Despite the increasing efforts and advances in cancer therapies, cancers are still responsible for approximately 10% of all the deaths worldwide. Furthermore, the increase in the average human lifespan will further contribute to the cancer incidences. This brings the necessity to focus our efforts on early detection and effective diagnosis methods. With the advances in high-throughput genomics technologies, gene expression signatures have gained attention as a novel method in cancer diagnostics. These signatures are identified by simply comparing the expression levels of genes in tumor and control samples. Here, we propose an alternative method based on the probe expression level measurement of 3&rsquo / UTR of candidate genes. We chose breast cancer as a model and performed an in silico analysis on publicly available gene expression datasets of Affymetrix chips to analyse 3&rsquo / UTR shortening during breast cancer situation. Overall, our analysis suggests that shortening of 3&rsquo / UTR is a significant mechanism observed in breast cancer .
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Regulation of Human Papillomavirus Type 16 mRNA Splicing and PolyadenylationZhao, Xiaomin January 2005 (has links)
Human papillomavirus type 16 (HPV-16) is the major causative agent of cervical cancer. The life cycle of this oncogenic DNA tumour virus is strictly associated with the differentiation program of the infected epithelial cells. Expression of the viral capsid genes L1 and L2 can only be detected in the terminally differentiated epithelial cells. The studies here focus on the regulation of HPV-16 late gene expression, which is under tight regulation. Our experimental system consisted of almost the full length HPV-16 genome driven by a strong CMV promoter. This plasmid and mutants thereof could be transfected into HeLa cells and RNA levels monitored. Using this system, we identified an hnRNP A1-dependent splicing silencer between positions 178 and 226 of the L1 gene. This silencer inhibited the use of the 3' splice site, located immediately upstream of the L1 AUG. We speculate that this splicing silencer plays an essential role in preventing late gene expression at an early stage of the viral life cycle. We subsequently identified a splicing enhancer located in the first 17 nucleotides of L1 that may be needed to counteract the multiple hnRNP A1 dependent splicing silencers in the L1 coding region. A 55kDa protein specifically bound to this splicing enhancer. We also demonstrated that binding of the cellular factors to the splicing silencer in the L1 coding region had an inhibitory effect on expression from L1 cDNA expression plasmids. The HPV-16 genome is divided into the early region and the late region, separated by the early poly(A) signal (pAE). pAE is used preferentially early in infection, thereby efficiently blocking late gene expression. We demonstrated that a 57 nucleotide U-rich region of the early 3’untranslated region (3’eUTR) acted as an enhancing upstream element on the usage of pAE. We demonstrated that this U-rich region specifically interacts with hFip1, CstF-64, hnRNP C1/C2 and PTB, suggesting that these factors were either enhancing or regulating polyadenylation at the HPV-16 pAE. In conclusion, two regulatory RNA elements that both act to prevent late gene expression at an early stage in the viral life cycle and in proliferating cells were identified: a splicing silencer in the late region and an upstream u-rich element at the pAE.
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SR proteins in microRNA/mRNA biogenesisWu, Han January 2011 (has links)
<p>SR proteins are a family of splicing factors involved in the regulation of both constitutive and alternative splicing of pre-mRNAs. Despite years of studies, several big questions still remain: how the expression levels of SR proteins are regulated; what are the underlying mechanisms responsible for SR proteins-mediated gene regulation; what are the physiological targets of SR proteins in vivo. In my dissertation study, I am focusing on two members of the family, SF2/ASF and SRp20, to study their functional involvement in regulating microRNA/mRNA biogenesis and their own expression. </p><p>Negative feedback regulation is a common mechanism maintaining the steady-state level of SR proteins (i.e. SC35 and SRp20), and several mechanism may be involved. In order to test if miRNAs are also involved in such negative feedbacks, small RNA sequencing was used to identify differentially expressed miRNAs after SF2/ASF overexpression in an inducible stable cell line system. Among the 40 differentially expressed miRNAs, miR-7 is particularly interesting, because it is also predicted to target SF2/ASF, which forms a negative feedback regulation. This is indeed the case as shown by luciferase reporter assay and overexpression/knocking down of miR-7 in vivo. To our knowledge, this is the first identified negative feedback circuit between a SR protein and a miRNA, which may be a general mechanism in regulating SR protein homeostasis.</p><p>To characterize the mechanism underlying SF2/ASF-enhanced miRNA biogenesis, I have employed a series of molecular and biochemical approaches to pinpoint the key molecular interactions in a minigene system, which is consist of miR-7 embedded intron and the flanking exons of its host gene. By manipulating the splicing pattern of such minigene, I have uncovered a splicing-independent function of SF2/ASF in regulating miRNA biogenesis. Directly binding between SF2/ASF protein and pri-miR-7 was demonstrated by Cross-linking and immunoprecipitation assay (CLIP) and RNA affinity purification. The precise binding site was then pinpointed by combining computational prediction and mutagenesis assay. Finally, by using in vitro pri-miRNA processing assay, I showed that SF2/ASF can promote the Drosha cleavage step of pri-miR-7 through directly association with the predicted binding site. So far, this is the first SR protein discovered, which is directly involved in miRNA biogenesis. Moreover, our preliminary data also suggested that SF2/ASF may promote miRNA biogenesis in other steps after Drosha cleavage; and different SR proteins can regulate miRNA biogenesis in a substrate-specific manner. Taken together, SR family of splicing factors may be broadly involved in miRNA biogenesis through direct interactions.</p><p>In order to study the general involvement of SR proteins in RNA biogenesis, one important step stone is to have a better profile of their targets in vivo. To achieve this, I focused on SRp20, another classic SR protein. Photoactivatable-Ribonucleoside-Enhanced Cross-linking and immunoprecipitation assay combined with deep sequencing (PAR-CLIP-seq) was used to identify the binding partners of SRp20 globally, which is subsidized by candidate gene validations. Consistent with the literature, I found that SRp20 primarily targets exonic regions for splicing regulation, and such interactions are likely to be sequence dependent on the CWWCW motif. Surprisingly, I also observed extensive binding between SRp20 and the 3' UTRs of mRNA, which may affect the choice of alternative polyadenylation sites. The underlying mechanisms are being investigated by a variety of molecular methods. </p><p>In summary, I have identified a subset of miRNAs, the expression of which can be regulated by SF2/ASF in a splicing independent manner. This is the first SR protein identified in regulating miRNA biogenesis. One of the upregulated miRNAs, miRNA-7 can form a negative feedback with SF2/ASF by negatively regulating the expression of SF2/ASF on translational level. By using PAR-CLIP method, I have identified the genome-wide binding partners of SRp20 in vivo. When SRp20 binds to the exonic regions, it potentially affects the alternative splicing patterns of nearby introns. Interestingly, the 3' end choices for a subset of genes may be regulated by SRp20 through directly binding, which may be a new mechanism for the regulation of 3' end processing.</p> / Dissertation
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Structural and Functional Investigations of Conformationally Interconverting RNA PseudoknotsStammler, Suzanne 2009 August 1900 (has links)
The biological function of RNA is often linked to an ability to adopt one or more
mutually exclusive conformational states or isomers, a characteristic that distinguishes
this biomolecule from proteins. Two examples of conformationally inconverting RNAs
were structurally investigated. The first is found in the 3' untranslated region (UTR) of
the coronavirus mouse hepatitis virus (MHV). A proposed molecular switch between
mutually exclusive stable stem loop and pseudoknot conformations was investigated
using thermal unfolding methods, NMR spectroscopy, sedimentation velocity
ultracentrifugation and fluorescence resonance energy transfer (FRET) spectroscopy.
Utilizing a "divide and conquer" approach we establish that the independent subdomains
are folded as predicted by the proposed model and that a pseudoknotted conformation is
accessible. Using the subdomains as spectral markers for the investigation of the intact
3' UTR RNA, we show that the 3' UTR is indeed a superposition of a double stem
conformation and a pseudoknotted conformation in the presence of KCl and MgCl2. In
the absence of added salt however, the 3' UTR adopts exclusively the double stem
conformation. Analysis of the pseudoknotted stem reveals only a marginally stable folded state (deltaG25 = 0.5 kcal mol-1, tm = 31 oC) which makes it likely that a viral or host
encoded protein(s) is required to stabilize the pseudoknotted conformation.
A second conformationally interconverting RNA system investigated is an RNA
element that stimulates -1 programmed ribosomal frameshifting in the human Ma3 gene.
Structural analysis of the frameshifting element reveals a dynamic equilibrium between a
functionally inactive double stem loop conformation and the active pseudoknotted
conformation. Thermal melting and NMR spectroscopy reveal that the double stem loop
is the predominant conformation in the absence of added KCl or MgCl2. The addition of
KCl and MgCl2 results in the formation of a pseudoknot conformation. This
conformation is dominant in solution only when the competing double stem loop
conformation is abrogated by mutation. Functional studies of the Ma3 pseudoknot
reveal that abrogation of double stem conformation increases frameshift stimulation by
2-fold and indicates that the pseudoknot is the active conformation.
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Studies on the Evolution and Function of Introns in 5' Untranslated RegionsCenik, Can January 2011 (has links)
The function and evolution of introns have been topics of great interest since introns were discovered in the 1970s. Introns that interrupt protein-coding regions have the most obvious potential to affect coding sequences; therefore, their evolution have been studied most intensively. Splicing of introns within untranslated regions does not contribute directly to the diversity of proteins, yet ~35% of human transcripts contain introns within the 5' untranslated region (UTR). The evolution and possible functions of 5'UTR introns (5UIs) remain largely unexplored. Here we undertook a genome-wide functional analysis of 5UIs. Our main results are as follows: First, the distribution of these introns in the human genome is nonrandom. While genes with regulatory roles are enriched in having 5UIs, genes encoding proteins that are targeted to the endoplasmic reticulum and mitochondria are surprisingly depleted of these introns. Second, we offered and supported a model whereby gene encoding secretory and nuclear-encoded mitochondrial proteins share a common regulatory mechanism at the level of mRNA export, which is dependent on the absence of 5'UTR introns. Specifically, the upstream element in a given transcript, be it an intron or RNA elements near the 5' end of coding sequences (CDS), dictates the mRNA export pathway used. Finally, we discovered a strong correlation between existence of 5'UTR introns and sequence features near the 5' end of CDS. We developed an integrated machine-learning framework that can predict absence of 5UIs using solely the sequence near the 5' end of CDS. Our model achieved >80% accuracy when validated against nuclear-encoded mitochondrial transcripts. Specific RNA elements predictive of 5UI absence are found in ~40% of human transcripts spanning a wide spectrum of functions. By analyzing hundreds of large-scale datasets, we functionally characterized the transcripts with these RNA elements; revealing their association with translational regulation. These RNA elements were bound by proteins interacting with the Exon Junction Complex in vivo suggesting a molecular mechanism that links these elements to their downstream effects in mRNA export and translational regulation. While some 5'UTR introns might be evolving neutrally, our results, taken together, suggest that complex evolutionary forces are acting on this distinct class of introns.
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A role for RNA localization in the human neuromuscular disease myotonic dystrophyCroft, Samantha Brooke 13 June 2011 (has links)
RNA localization, a regulated step of gene expression, is fundamentally important in development and differentiation. In multidisciplinary experiments, we discovered that RNA (mis)localization underlies the human disease myotonic dystrophy (DM). DM, the most prevalent adult muscular dystrophy, is caused independently by two alleles: DM1 is characterized by a (CTG)n expansion in the DM kinase (DMPK) gene 3' untranslated region while DM2 has a mutation in a small presumptive RNA binding protein. These analyses were guided by disease characteristics and have provided insights to DM's cytopathology, cell biology and molecular genetics. Examining muscle biopsies, it is demonstrated here that DM kinase mRNA is specifically subcellularly localized within normal human muscle and that DM kinase mRNA harboring the 3’UTR mutation (DM1) is mislocalized in DM patient muscle to cytoplasmic areas characteristic of DM disease pathology. Thus, the disease mutation alters the cellular distribution of the effected message. DMPK mRNA mislocalization causes altered DM kinase protein localization, correlates with novel phosphoprotein appearance and can account for DM’s diseased phenotype. While we were fortunate to access DM patient tissue to establish these key findings, the system does not lend itself to experimental manipulation. Hence, I established a disease- relevant tissue culture system, which recapitulates DMPK trafficking, Employing this system; I elucidate a complementary role for the DM2 gene product as a localization factor for DMPK mRNA (DM1 gene product). Comprehensive RNA-protein interaction experiments reveal the DM2 protein specifically and selectively recognizes a small, definitive area within the DMPK RNA 3'UTR. Detailed biochemical, cytological and functional experiments reveal 1) the DM2 protein colocalizes with DMPK mRNA, 2) the small area of the DMPK 3’UTR bound by pDM2 acts to properly localize a reporter construct and 3) disruption of the DM2 protein results in DMPK mRNA mislocalization. These data establish mRNA localization as a vital process underlying human disease etiology. Moreover, they reveal DM1 and DM2 gene products function in the same molecular pathway and that mutation of either causes DMPK mRNA mislocalization, leading to disease. These data have apparent application to several neuromuscular disorders and open a plethora of novel research avenues, both basic and applied. / text
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European Black Grouse : MHC Genetic Diversity and Population StructureStrand, Tanja January 2011 (has links)
Black grouse Tetrao tetrix is a bird species composed of large, continuous as well as severely reduced and fragmented populations, making it an optimal species to investigate how genetic diversity is affected by habitat fragmentation. I have focused on genetic diversity in the Major Histocompatibility Complex (MHC) to measure the ability of the black grouse to respond to environmental changes. I partly characterized MHC class II in black grouse and found striking similarities with chicken MHC class II. I demonstrated that black grouse possess a similar compact MHC as chicken with few MHC class II B (BLB) and Y (YLB) loci. I did not find evidence of balancing selection in YLB so I concentrated further studies on BLB. I developed a PCR-based screening method for amplifying and separating expressed BLB alleles in European black grouse populations. Small fragmented populations had lost neutral genetic diversity (based on microsatellites and SNPs) compared to samples from the historical distribution and contemporary large populations. There was also a trend, albeit less pronounced, for reduced MHC diversity in these populations. Neutral markers in small isolated populations were affected by increased levels of genetic drift and were therefore genetically differentiated compared to other populations. MHC markers on the other hand, were not subjected to genetic drift to the same extent probably due a long historic process of balancing selection. Inferences of heterozygosity and evolutionary patterns as well as detailed correlations to reproductive success and diseases cannot be performed until MHC can be amplified in a locus-specific manner. Therefore, I developed a single locus sequence-based typing method for independently amplifying MHC class II B loci (BLB1 and BLB2). I found that BLB1 and BLB2 were duplicated in a common ancestor to chickens and black grouse and that these loci are subjected to homogenizing concerted evolution due to inter-genetic exchange between loci after species divergence. I could also verify that both BLB1 and BLB2 were transcribed in black grouse and under balancing selection. This collection of work has significance for future conservation of black grouse as well as research and management of zoonotic diseases.
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The Functional Evolution of Human microRNA FamiliesJanuary 2016 (has links)
abstract: MicroRNAs (miRNAs) are short non-coding RNAs that play key roles during metazoan development, and are frequently misregulated in human disease. MiRNAs regulate gene output by targeting degenerate elements primarily in the 3´ untranslated regions of mRNAs. MiRNAs are often deeply conserved, but have undergone drastic expansions in higher metazoans, leading to families of miRNAs with highly similar sequences. The evolutionary advantage of maintaining multiple copies of duplicated miRNAs is not well understood, nor has the distinct functions of miRNA family members been systematically studied. Furthermore, the unbiased and high-throughput discovery of targets remains a major challenge, yet is required to understand the biological function of a given miRNA.
I hypothesize that duplication events grant miRNA families with enhanced regulatory capabilities, specifically through distinct targeting preferences by family members. This has relevance for our understanding of vertebrate evolution, as well disease detection and personalized medicine. To test this hypothesis, I apply a conjunction of bioinformatic and experimental approaches, and design a novel high-throughput screening platform to identify human miRNA targets. Combined with conventional approaches, this tool allows systematic testing for functional targets of human miRNAs, and the identification of novel target genes on an unprecedented scale.
In this dissertation, I explore evolutionary signatures of 62 deeply conserved metazoan miRNA families, as well as the targeting preferences for several human miRNAs. I find that constraints on miRNA processing impact sequence evolution, creating evolutionary hotspots within families that guide distinct target preferences. I apply our novel screening platform to two cancer-relevant miRNAs, and identify hundreds of previously undescribed targets. I also analyze critical features of functional miRNA target sites, finding that each miRNA recognizes surprisingly distinct features of targets. To further explore the functional distinction between family members, I analyze miRNA expression patterns in multiple contexts, including mouse embryogenesis, RNA-seq data from human tissues, and cancer cell lines. Together, my results inform a model that describes the evolution of metazoan miRNAs, and suggests that highly similar miRNA family members possess distinct functions. These findings broaden our understanding of miRNA function in vertebrate evolution and development, and how their misexpression contributes to human disease. / Dissertation/Thesis / Doctoral Dissertation Molecular and Cellular Biology 2016
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