Project description:Loss of nautilus (MyoD) gene function results in a variable phenotype affecting muscle formation in embryos and larvae, larval movement, pupal eclosion, egg deposition, adult mobility and survival. mir-3 over expression disrupts muscle formation in the embryo while affecting protein production from the dMef2 and tinman genes, global regulators of the muscle transcriptional network. We propose the complex phenotype in the nautilus null is due to the disruption of the regulatory interactions provided by the 8-miR cluster. The results demonstrate that nautilus is an integral regulator of the miRNA circuitry buffering the transcriptional network directing muscle development. Two-condition experiment, wild type (w1118) vs. mutant (mir-3 ectopic expressionl). Biological replicates: 3 wild type, 3 mutants, independently isolated. One of the biological replicate was dye swaped to avoid dye bias.

Project description:Loss of nautilus (MyoD) gene function results in a variable phenotype affecting muscle formation in embryos and larvae, larval movement, pupal eclosion, egg deposition, adult mobility and survival. 8-miR cluster deletion disrupts muscle formation in the embryo while affecting protein production from the nautilus, dMef2 , regulators of the muscle transcriptional network. We propose the complex phenotype in the nautilus null is due to the disruption of the regulatory interactions provided by the 8-miR cluster. The results demonstrate that nautilus is an integral regulator of the miRNA circuitry buffering the transcriptional network directing muscle development.

Project description:To determine if the Drosophila MyoD homolog, nautilus, was activating any miRNA loci, similar to vertebrate MyoD, we compared the miRNA expression profiles between wild-type (w1118) and nautilus null embryos during the window of maximum nautilus expression (6-8hr AEL), using LNA arrays specifically designed to quantify miRNA levels in Drosophila (Exiqon). Expression levels for mir-309, mir-3, mir-286, mir-4, mir-5, and mir-6 from the 8-miR cluster, were significantly decreased in nautilus null embryos. It suggests that the intergenic 8-miR cluster, encoding eight miRNAs, is regulated by nautilus. Two-condition experiment, wild type (w1118) vs. mutant (nautilus null). Biological replicates: 3 wild type, 3 mutants, independently isolated.

Project description:Loss of nautilus (MyoD) gene function results in a variable phenotype affecting muscle formation in embryos and larvae, larval movement, pupal eclosion, egg deposition, adult mobility and survival. mir-3 over expression disrupts muscle formation in the embryo while affecting protein production from the dMef2 and tinman genes, global regulators of the muscle transcriptional network. We propose the complex phenotype in the nautilus null is due to the disruption of the regulatory interactions provided by the 8-miR cluster. The results demonstrate that nautilus is an integral regulator of the miRNA circuitry buffering the transcriptional network directing muscle development.

Project description:To determine if the Drosophila MyoD homolog, nautilus, was activating any miRNA loci, similar to vertebrate MyoD, we compared the miRNA expression profiles between wild-type (w1118) and nautilus null embryos during the window of maximum nautilus expression (6-8hr AEL), using LNA arrays specifically designed to quantify miRNA levels in Drosophila (Exiqon). Expression levels for mir-309, mir-3, mir-286, mir-4, mir-5, and mir-6 from the 8-miR cluster, were significantly decreased in nautilus null embryos. It suggests that the intergenic 8-miR cluster, encoding eight miRNAs, is regulated by nautilus.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:Muscle-specific ablation of miR-1/133a expression leads to increased expression of miR-1/133a target genes at RNA and/or protein level. MEF2A is a direct target of miR-1/133a that is upregulated at the protein level and subsequently activates the expression of the Dlk1-Dio3 cluster in skeletal muscle of miR-1/133a deficient mice. miRNAs encoded in the Dlk1-Dio3 cluster directly repress the expression of multiple genes important for mitochondrial function. The study includes transcriptome analysis of tibialis anterior muscle after muscle-specific deletion of miR-1/133a as well as transcriptome analysis of tibialis anterior muscle after muscle-specific overexpression of Mef2A.

Project description:The study sought to determine whether deletion of individual seed families within the miR-17~92 cluster affected the expression of the remaining microRNAs of the cluster. There were 8 samples analyzed. The reference is the wild-type embryo.

Project description:Clear cell renal cell carcinomas (ccRCC) are characterized by arm-wide chromosomal alterations. Loss at 14q is associated with disease aggressiveness in ccRCC, which responds poorly to chemotherapeutics. The 14q locus contains one of the largest miRNA clusters in the human genome; however, little is known about the contribution of these miRNAs to ccRCC pathogenesis. In this regard, we investigated the expression pattern of selected miRNAs at the 14q32 locus in TCGA kidney tumors and in ccRCC cell lines. We validated that the miRNA cluster is downregulated in ccRCC (and cell lines) as well as in papillary kidney tumors relative to normal kidney tissues and primary renal proximal tubule epithelial (RPTEC) cells. We demonstrated that agents modulating expression of DNMT1 (e.g., 5-Aza-deoxycytidine) could modulate miRNA expression in ccRCC cell lines. Lysophosphatidic acid (LPA, a Lysophospholipid mediator elevated in ccRCC) not only increased labile iron content but also modulated expression of 14q32 miRNAs. Through an overexpression approach targeting a subset of 14q32 miRNAs (specifically at subcluster A: miR-431, miR-432, miR-127, and miR-433) in 769-P cells, we uncovered changes in cellular viability and claudin-1, a tight junction marker. A global proteomic approach was implemented using these miRNA overexpressing cell lines which uncovered ATXN2 as a highly downregulated target, which has a role in chronic kidney disease pathogenesis. Collectively, these findings support a contribution of miRNAs at 14q32 in ccRCC pathogenesis.

Project description:A network of gene regulatory factors such as transcription factors and microRNAs establish and maintain the gene expression pattern during hematopoiesis. In this network transcription factors regulate each other and are involved in regulatory loops with microRNAs.The microRNA cluster miR-17-92 is located within the MIR17HG gene and encodes for six mature microRNAs. It is important for hematopoietic differentiation and plays a central role in malignant disease. However, the transcription factors downstream of miR-17-92 are largely elusive and the transcriptional regulation of miR-17-92 is not fully understood. Here we show that miR-17-92 forms a regulatory loop with the transcription factor TAL1. The miR-17-92 cluster inhibits expression of TAL1 and indirectly leads to decreased stability of the TAL1 transcriptional complex. We found that TAL1 and its heterodimerization partner E47 regulate miR-17-92 transcriptionally. Furthermore, miR-17-92 negatively influences erythroid differentiation, a process that depends on gene activation by the TAL1 complex. Our data give example of how transcription factor activity is fine-tuned during normal hematopoiesis. We postulate that disturbance of the regulatory loop between TAL1 and the miR-17-92 cluster could be an important step in cancer development and progression.