Project description:gene expression profiles in fly brains between wildtype and miR-34 null flies gene expression profiles in fly brains, wild type (3d, 20d) and miR-34 null flies (3d, 20d)

Project description:Cy3-labeled cDNA from brains of neonatal C57BL Cx43 null, Cx43 heterozygous and Cx32 null mice were compared among themselves and to Cy3-labeled cDNA from brains of neonatal C57BL wildtype mice through Cy5-labeled sample reference prepared at once for the entire experiment from aorta, brain, heart, kidney, liver, lung, ovary/testicles, spleen, and stomach - equal amounts from adult male and female C57BL mice.

Project description:CG3875 is a young duplicate gene of kep1 family originated recently in Drosophila melanogaster (D. melanogaster) species complex (including D. melanogaster, D. simulans, D. mauritiana and D. sechellia) after it split from D. yakuba. It encodes an RNA-binding protein containing a single maxi-KH domain. Characterization of loss-of-function phenotypes of CG3875 mutants generated by gene targeting demonstrated that CG3875 null males display a seriously reduced fertility compared with wildtype males and most of the null males are completely sterile. Further cytological identification of CG3875 null males suggested that CG3875 plays an important role in spermiogenesis processes including sperm individualization and sperm coiling. In addition, CG3875 is also essential for the formation of outer dynein arm of sperm axoneme. In order to identify the molecular mechanism responsible for the involvement of CG3875 in spermiogenesis and structural integrity of sperm axoneme, we performed microarray analysis to identify transcripts whose levels are altered in the testes of CG3875 null males. We compared gene expression profiles between testes of 0-2 day CG3875 null mutants and wildtype flies, respectively. For the sake of an identical genetic background between knockout flies and wildtype flies, the wildtype stock used here is wildtype recombinant line created during gene targeting. Seminal vesicles were removed from the testes during dissection. Two independent RNA extractions and hybridizations were conducted for each sample.

Project description:Cy3-labeled cDNA from brains of neonatal C57BL Cx43 null, Cx43 heterozygous and Cx32 null mice were compared among themselves and to Cy3-labeled cDNA from brains of neonatal C57BL wildtype mice through Cy5-labeled sample reference prepared at once for the entire experiment from aorta, brain, heart, kidney, liver, lung, ovary/testicles, spleen, and stomach - equal amounts from adult male and female C57BL mice.

Project description:This SuperSeries is composed of the following subset Series: GSE24992: Drosophila brain microRNA expression with age: miRNA profiling GSE25007: Drosophila brain gene expression with age: mRNA profiling GSE25008: Drosophila brain gene expression between wildtype and miR-34 null flies Refer to individual Series. Aging is the most prominent risk factor for human neurodegenerative disease, but underlying mechanisms that connect two processes are less well characterized. With age, the brain undergoes functional decline and perhaps degeneration. Such decline may not just contribute to normal aging, but also enhance susceptibility to and progression of age-related neurodegenerative diseases. Therefore, defining intrinsic factors and pathways that underline the normal integrity of the adult nervous system may lead to insights that potentially link aging and neurodegeneration. Here, we report a highly conserved microRNA (miRNA), miR-34, as a modulator of aging and neurodegeneration. Using Drosophila, we show that fly miR-34 expression is brain-enriched and strikingly upregulated with age. Functional studies reveal that, whereas animals without miR-34 are normal as young adults, upon aging, they gradually show late-onset deficits characteristic of accelerated brain aging; these include a transcriptional signature of aged animals, coupled with rapid functional decline, loss of brain integrity, followed by a catastrophic decline in adult viability. Moreover, upregulation of miR-34 protects against neurodegeneration induced by pathogenic human polyglutamine (polyQ) disease protein. We next reveal a dramatic effect of miR-34 to silence the Eip74EF gene of steroid hormone pathways in the adult, which is crucial to maintain the normal aging. Collectively, these data define a miR-34-mediated mechanism that specifically affects long-term integrity of the adult nervous system. miR-34 function in Drosophila may thus present a link that functionally connects aging and neurodegeneration. Our studies implicate essential roles of miRNA- dependent pathways in maintenance of the adult brain, disease pathogenesis and healthy aging.

Project description:Cy3-labeled cDNA obtained from four pools of three hearts of neonatal C57BL Cx43 null mice were compared to Cy3-labeled cDNA obtained from four pools of three hearts of neonatal C57BL wildtype mice through Cy5-labeled sample reference prepared at once for the entire experiment from aorta, brain, heart, kidney, liver, lung, ovary/testicles, spleen, and stomach - equal amounts from adult male and female C57BL mice. Keywords = Cx32 null vs wildtype neonatal mouse heart Keywords: parallel sample

Project description:This RNAseq data was generated by comparing kidney tissue from Fnip1 null mice versus Wildtype Mice

Project description:Drosophila brain gene expression between wildtype and miR-34 null flies

Project description:To obtain a more complete picture of gene expression changes induced by deletion of VWA8 null cells, Affymetrix microarray analysis of gene expression was carried out using RNA isolated from wildtype and VWA8-null AML12 cells.

Project description:CG3875 is a young duplicate gene of kep1 family originated recently in Drosophila melanogaster (D. melanogaster) species complex (including D. melanogaster, D. simulans, D. mauritiana and D. sechellia) after it split from D. yakuba. It encodes an RNA-binding protein containing a single maxi-KH domain. Characterization of loss-of-function phenotypes of CG3875 mutants generated by gene targeting demonstrated that CG3875 null males display a seriously reduced fertility compared with wildtype males and most of the null males are completely sterile. Further cytological identification of CG3875 null males suggested that CG3875 plays an important role in spermiogenesis processes including sperm individualization and sperm coiling. In addition, CG3875 is also essential for the formation of outer dynein arm of sperm axoneme. In order to identify the molecular mechanism responsible for the involvement of CG3875 in spermiogenesis and structural integrity of sperm axoneme, we performed microarray analysis to identify transcripts whose levels are altered in the testes of CG3875 null males.