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The Role of Frabin (FGD4) in Aggressive Prostate CancerBossan, Alexia M 01 January 2017 (has links)
A major problem in prostate cancer (PCa) management is the development of drug resistance. It is known that there are changes in PCa biology upon prolonged treatment with drugs, including anti-androgen drugs that alter cellular signaling processes leading to the development of castration resistant PCa. MicroRNAs (miRNAs) are regulatory molecules that modulate gene expression through inhibition of protein translation and modulate cellular functions. Altered expression of miRNAs is often noted in drug resistant cancer including PCa. Studies from our laboratory have identified a number of down-regulated miRNAs in PCa, including miR-l 7-92a miRNAs. Frabin (FGD4) is a target of the miR-l 7-92a cluster that was found to be up-regulated in PCa cells. For this paper’s investigation, an FGD4 knockdown approach was used to identify the effects on cell viability, cell cycle progression, cell migration and drug sensitivity. Two PCa cells lines, LNCaP-104S (androgen sensitive) and PC-3 (androgen independent), were used for our studies. MTS assays for both cell lines showed significant reduction in cell viability following knockdown of FGD4 compared to transfection with control siRNAs. Cell cycle analysis revealed an arrest in the G2/M phase of the cells that were transfected with FGD4 siRNAs. Cell migration assays revealed a decrease in migration rate of PC-3 cells after knockdown, which supports the involvement of FGD4 in actin- cytoskeleton rearrangement. Treatments with anti-mitotic drug Docetaxel (PC-3) or androgen receptor antagonist bicalutamide/Casodex (LNCaP-104S) showed improved sensitivity of the FGD4 siRNA treated cells to these drugs. Our results suggest the potential for FGD4 knockdown to be used in combination with currently used drugs, increasing the effectiveness of frontline chemotherapeutics.
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Structural Analysis of microRNAs in Myeloid Cancer Reveals Consensus MotifsDogan, Senol, Spahiu, Emrulla, Cilic, Anis 26 October 2023 (has links)
MicroRNAs (miRNAs) are short non-coding RNAs that function in post-transcriptional
gene silencing and mRNA regulation. Although the number of nucleotides of miRNAs ranges from
17 to 27, they are mostly made up of 22 nucleotides. The expression of miRNAs changes significantly
in cancer, causing protein alterations in cancer cells by preventing some genes from being translated
into proteins. In this research, a structural analysis of 587 miRNAs that are differentially expressed
in myeloid cancer was carried out. Length distribution studies revealed a mean and median of
22 nucleotides, with an average of 21.69 and a variance of 1.65. We performed nucleotide analysis for
each position where Uracil was the most observed nucleotide and Adenine the least observed one
with 27.8% and 22.6%, respectively. There was a higher frequency of Adenine at the beginning of
the sequences when compared to Uracil, which was more frequent at the end of miRNA sequences.
The purine content of each implicated miRNA was also assessed. A novel motif analysis script was
written to detect the most frequent 3–7 nucleotide (3–7n) long motifs in the miRNA dataset. We
detected CUG (42%) as the most frequent 3n motif, CUGC (15%) as a 4n motif, AGUGC (6%) as a
5n motif, AAGUGC (4%) as a 6n motif, and UUUAGAG (4%) as a 7n motif. Thus, in the second
part of our study, we further characterized the motifs by analyzing whether these motifs align at
certain consensus sequences in our miRNA dataset, whether certain motifs target the same genes, and
whether these motifs are conserved within other species. This thorough structural study of miRNA
sequences provides a novel strategy to study the implications of miRNAs in health and disease. A
better understanding of miRNA structure is crucial to developing therapeutic settings.
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SMN promotes mitochondrial metabolic maturation during myogenesis by regulating the MYOD-miRNA axis / SMNは、骨格筋分化においてMYOD-miRNA 経路を制御することにより、ミトコンドリアの機能的成熟を促進するUehara(Ikenaka), Akihiro 24 July 2023 (has links)
京都大学 / 新制・論文博士 / 博士(医学) / 乙第13564号 / 論医博第2291号 / 新制||医||1068(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 齊藤, 博英, 教授 滝田, 順子, 教授 萩原, 正敏 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM
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THE PHYSIOLOGICAL FUNCTION OF THE dsRNA-BINDING PROTEIN PACT/RAX, PROTEIN ACTIVATOR OF PKR AND ITS ROLE IN MOUSE DEVELOPMENTDickerman, Benjamin K. 24 August 2012 (has links)
No description available.
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Targets of Hsa-miR-488* In Human Prostate Carcinoma CellsSlaibi, Jinani Elias 08 June 2010 (has links)
No description available.
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Characterization of a microRNA Harboring Intron for pre-mRNA Splicing and microRNA ProcessingAggarwal, Neha 21 June 2010 (has links)
No description available.
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A NOVEL ANTI-INFLAMMATORY ROLE OF OSTEOACTIVIN/GPNMB INPOST-TRAUMATIC OSTEOARTHRITISAl-Adlaan, Asaad A. 29 November 2017 (has links)
No description available.
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DEVELOPING LIQUID CHROMATOGRAPHY AND MASS SPECTROMETRY APPROACHES FOR STUDYING POSTTRANSCRIPTIONAL MODIFICATIONS IN SMALL RNASCOOMBS, CATHERINE CALLIE 17 July 2006 (has links)
No description available.
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Cross-Talk Between Epigenetic Regulation And Mir-17~92 Cluster Expression In Idiopathic Pulmonary Fibrosis (IPF)Dakhlallah, Duaa 18 March 2011 (has links)
No description available.
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Workflows for the Large-Scale Assessment of miRNA Evolution: Birth and Death of miRNA Genes in TunicatesVelandia Huerto, Cristian Arley 01 August 2022 (has links)
As described over 20 years ago with the discovery of RNA interference (RNAi), double-stranded RNAs occupied key roles in regulation and as defense-line in animal cells. This thesis focuses on metazoan microRNAs (miRNAs). These small non-coding RNAs are distinguished from their small-interfering RNA (siRNA) relatives by their tightly controlled, efficient and flexible biogenesis, together with a broader flexibility to target multiple mRNAs by a seed imperfect base-pairing. As potent regulators, miRNAs are involved in mRNA stability and post-transcriptional regulation tasks, being a conserved mechanism used repetitively by the evolution, not only in metazoans, but plants and unicellular organisms.
Through a comprehensive revision of the current animal miRNA model, the canonical pathway dominates the extensive literature about miRNAs, and served as a scaffold to understand the scenes behind the regulatory landscape performed by the cell. The characterization of a diverse set of non-canonical pathways has expanded this view, suggesting a diverse, rich and flexible regulatory landscape to generate mature miRNAs. The production of miRNAs, derived from isolated or clustered transcripts, is an efficient and highly conserved mechanism traced back to animals with high fidelity at family level. In evolutionary terms, expansions of miRNA families have been associated with an increasing morphological and developmental complexity. In particular, the Chordata clade
(the ancient cephalochordates, highly derived and secondary simplified tunicates, and the well-known vertebrates) represents an interesting scenario to study miRNA evolution. Despite clearly conserved miRNAs along these clades, tunicates display massive restructuring events, including emergence of highly derived miRNAs.
As shown in this thesis, model organisms or vertebrate-specific bias exist in current animal miRNA annotations, misrepresenting more diverse groups, such as marine invertebrates. Current miRNA databases, such as miRBase and Rfam, classified miRNAs under different definitions and possessed annotations that are not simple to be linked. As an alternative, this thesis proposes a method to curate and merge those annotations, making use of miRBase precursor/mature annotations and genomes together with Rfam predicted sequences. This approach generated structural models for shared miRNA families, based on the alignment of their correct-positioned mature sequences as anchors. In this process, the developed structural curation steps flagged 33 miRNA families from the Rfam as questionable.
Curated Rfam and miRBase anchored-structural alignments provided a rich resource for constructing predictive miRNA profiles, using correspondent hidden Markov (HMMs) and covariance models (CMs). As a direct application, the use of those models is time-consuming, and the user has to deal with multiple iterations to achieve a genome-wide non-overlapping annotation. To resolve this, the proposed miRNAture pipeline provides an automatic and flexible solution to annotate miRNAs. It combines multiple homology approaches to generate the best candidates validated at sequence and structural levels. This increases the achievable sensitivity to annotate canonical miRNAs, and the evaluation against human annotation shows that clear false positive calls are rare and additional counterparts lie in retained-introns, transcribed lncRNAs or repeat families. Further development of miRNAture suggests an inclusion of multiple rules to distinguish non-canonical miRNA families.
This thesis describes multiple homology approaches to annotate the genomic information from a non-model chordate: the colonial tunicate Didemnum vexillum. Detected high levels of genetic variance and unexpected levels of DNA degradation were evidenced through a comprehensive analysis of genome-assembly methods and gene annotation. Despite those challenges, it was possible to find candidate homeobox and skeletogenesis- related genes. On its own, the ncRNA annotation included expected conserved families, and an extensive search of the Rhabdomyosarcoma 2-associated transcript (RMST) lncRNA family traced-back at the divergence of deuterostomes. In addition, a complete study of the annotation thresholds suggested variations to detect miRNAs, later implemented on the miRNAture tool. This chapter is a showcase of the usual workflow that should follow comprehensive sequencing, assembly and annotation project, in the light of the increasing research approaching DNA sequencing.
In the last 10 years, the remarkable increment in tunicate sequencing projects boosted the access to an expanded miRNA annotation landscape. In this way, a comprehensive homology approach annotated the miRNA complement of 28 deuterostome genomes (including current 16 reported tunicates) using miRNAture. To get proper structural models as input, corrected miRBase structural alignments served as a scaffold for building correspondent CMs, based on a developed genetic algorithm. By this means, this automatic approach selected the set of sequences that composed the alignments, generating 2492 miRNA CMs. Despite the multiple sources and associated heterogeneity of the studied genomes, a clustering approach successfully gathered five groups of similar assemblies and highlighted low quality assemblies. The overall family and loci reduction on tunicates is notorious, showing on average 374 microRNA (miRNA) loci, in comparison to other clades: Cephalochordata (2119), Vertebrata (3638), Hemichordata (1092) and Echinodermata
(2737). Detection of 533 miRNA families on the divergence of tunicates shows an expanded landscape regarding currently miRNA annotated families. Shared sets of ancestral, chordates, Olfactores, and specific clade-specific miRNAs were uncovered using a phyloge- netic conservation criteria. Compared to current annotations, the family repertories were expanded in all cases. Finally, relying on the adjacent elements from annotated miRNAs, this thesis proposes an additional syntenic support to cluster miRNA loci. In this way, the structural alignment of miR-1497, originally annotated in three model tunicates, was expanded with a clear syntenic support on tunicates.
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