PIWI proteins and their bound piRNAs form the core of a gonad specific small RNA silencing pathway in animals that protects the genome against the deleterious activity of transposable elements. Recent studies linked the piRNA pathway to TUDOR biology, where TUDOR domains of various proteins recognize and bind symmetrically methylated Arginine residues in PIWI proteins. We systematically analyzed the Drosophila TUDOR protein family and identified three previously not characterized TUDOR domain-containing genes (CG4771, CG14303 and CG11133) as essential piRNA pathway members. We characterized CG4771 (Avocado) in detail and demonstrate a critical role for this protein during primary piRNA biogenesis in somatic and germline cells of the ovary. Avocado physically and/or genetically interacts with the primary pathway components Piwi, Armitage, Yb and Zucchini. Avocado also interacts with the Tdrd12 orthologs CG11133 and CG31755, which are essential for primary piRNA biogenesis in the germline and probably functionally replace the related and soma specific factor Yb. Overall design: small RNA libraries were prepared from total RNA isolation of 8 different genotypes
A systematic analysis of Drosophila TUDOR domain-containing proteins identifies Vreteno and the Tdrd12 family as essential primary piRNA pathway factors.
Specimen part, Subject
View SamplesHost defense by the innate immune system requires the establishment of antimicrobial states allowing cells to cope with microorganisms before the onset of the adaptive immune response. Interferons (IFN) are of vital importance in the establishment of cell-autonomous antimicrobial immunity. Speed is therefore an important attribute of the cellular response to IFN. With much of the antimicrobial response being installed de novo, this pertains foremost to gene expression, the rapid switch between resting-state and active-state transcription of host defense genes. Our results show how mRNA expression changes upon IFNb or IFNg treatment in wild typ and Irf9-/- bone marrow derived macrophages. Overall design: Methods: Bone marrow derived macrophage mRNA of wild-type (WT) and Irf9 knock out mice (IRF9-/-) untreated, as well as 2h IFNb and IFNg treated were generated by deep sequencing, in triplicate, using Illumina sequencing.
A molecular switch from STAT2-IRF9 to ISGF3 underlies interferon-induced gene transcription.
Specimen part, Cell line, Treatment, Subject
View SamplesHost defense by the innate immune system requires the establishment of antimicrobial states allowing cells to cope with microorganisms before the onset of the adaptive immune response. Interferons (IFN) are of vital importance in the establishment of cell-autonomous antimicrobial immunity. Speed is therefore an important attribute of the cellular response to IFN. With much of the antimicrobial response being installed de novo, this pertains foremost to gene expression, the rapid switch between resting-state and active-state transcription of host defense genes. Our results show how mRNA expression changes upon IFNb treatment in wild type and Irf9-/- mouse embryonic fibroblasts. Overall design: Methods: Mouse embryonic fibroblast (MEF) mRNA of wild-type (WT) and Irf9 knock out mice (IRF9-/-) untreated, as well as 2h IFNb treated were generated by deep sequencing, in triplicate, using Illumina sequencing.
A molecular switch from STAT2-IRF9 to ISGF3 underlies interferon-induced gene transcription.
Subject
View SamplesHost defense by the innate immune system requires the establishment of antimicrobial states allowing cells to cope with microorganisms before the onset of the adaptive immune response. Interferons (IFN) are of vital importance in the establishment of cell-autonomous antimicrobial immunity. Speed is therefore an important attribute of the cellular response to IFN. With much of the antimicrobial response being installed de novo, this pertains foremost to gene expression, the rapid switch between resting-state and active-state transcription of host defense genes. Our results show how mRNA expression changes upon IFNb treatment in wild type and Irf9-/- THP1 cells. Overall design: Methods: mRNA of untreated and IFNb treated wild-type (WT) and Irf9 knock out (IRF9-/-) human monocytic THP1 cells were analyzed by deep sequencing, in triplicate, using Illumina sequencing.
A molecular switch from STAT2-IRF9 to ISGF3 underlies interferon-induced gene transcription.
Subject
View SamplesThe non-coding Xist RNA triggers silencing of one of the two female X chromosomes during X inactivation in mammals. Gene silencing by Xist is restricted to special developmental contexts found in cells of the early embryo and specific hematopoietic precursors. The absence of critical silencing factors might explain why Xist cannot silence outside these contexts. Here, we show that Xist can also initiate silencing in a lymphoma model. Using the tumor context we identify the special AT rich binding protein SATB1 as an essential silencing factor. We show that loss of SATB1 in tumor cells abrogates the silencing function of Xist. In normal female lymphocytes Xist localizes along SATB1 filaments and, importantly, forced Xist expression can relocalize SATB1 into the Xist cluster. This reciprocal influence on localization suggests a molecular interaction between Xist and SATB1. SATB1 and its close homologue SATB2 are expressed during the initiation window for X inactivation in embryonic stem cells and are recruited to surround the Xist cluster. Furthermore, ectopic expression SATB1 or SATB2 enables gene silencing by Xist in embryonic fibroblasts, which normally do not provide an initiation context. Thus, SATB1 functions as a crucial initiation factor and may act to organize genes for silencing by Xist during the initiation of X inactivation.
SATB1 defines the developmental context for gene silencing by Xist in lymphoma and embryonic cells.
Specimen part
View SamplesDrosophila neuroblasts have emerged as a model for stem cell biology that is ideal for genetic analysis but is limited by the lack of cell-type specific gene expression data. Here, we describe a methodology to isolate large numbers of pure neuroblasts and differentiating neurons that retain both cell cycle and lineage characteristics. We determine transcriptional profiles by mRNA sequencing and identify 28 predicted neuroblast specific transcription factors, which can be arranged in a network containing hubs for Notch signaling, growth control and chromatin regulation. Overexpression and RNAi for these factors identify Klumpfuss as a regulator of self-renewal. We show that loss of Klu function causes premature differentiation while overexpression results in the formation of transplantable brain tumors. Our data represent a valuable resource for Drosophila developmental neurobiology and we describes methodology that can be applied to other invertebrate stem cell lineages as well. Overall design: comparison of transcriptomes of Drosophila melanogaster larval neuroblasts and their differentiated daughter cells (neurons)
FACS purification and transcriptome analysis of drosophila neural stem cells reveals a role for Klumpfuss in self-renewal.
Specimen part, Subject
View SamplesBone marrow derived macrophages were infected with Listeria monocytogenes for 4 hours. We investigated differently expressed genes in the absence of DDX3X upon infection and also in steady state conditions. Overall design: Investigation of gene expression in wt and Ddx3x deficient bone marrow derived macrophages in response to Listeria monocytogenes infection.
The RNA helicase DDX3X is an essential mediator of innate antimicrobial immunity.
Sex, Specimen part, Subject
View SamplesFibroblasts from PRDM12 patients and unaffected wildtype relatives were cultured until near confluency. The transcriptional profile of those cells was determined by mRNA sequencing and uncovered differential expression in several known pain and neurodevelopmental genes. Overall design: Transcriptome comparison of human PRDM12 mutant and wildtype fibroblasts
The evolutionarily conserved transcription factor PRDM12 controls sensory neuron development and pain perception.
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View SamplesDiabetes is prevalent worldwide and associated with severe health complications, including blood vessel damage that leads to cardiovascular disease and death. Here we report the development of a 3D blood vessel organoid culture system from human pluripotent stem cells. These human blood vessel organoids contain endothelial cells and pericytes that self-assemble into interconnected capillary networks enveloped by a basement membrane. Human blood vessel organoids transplanted into mice form a stable, perfused human vascular tree, including human arteries, arterioles and venules. Exposure of blood vessel organoids to hyperglycemia and inflammatory cytokines in vitro induced thickening of the basal membrane, a hallmark of human diabetic microangiopathy. Human blood vessel, exposed in vivo to a diabetic milieu in mice, also mimick the microvascular changes in diabetic patients. We finally performed a drug screen and uncovered ?-secretase and DLL4-Notch3 as key drivers of “diabetic” vasculopathy in human blood vessels in vitro and in vivo. Thus, organoids derived from human stem cells faithfully recapitulate the structure and function of human blood vessels and are amenable to model and identify drug targets for diabetic vasculopathy, which affects hundreds of millions of patients. Overall design: Vascular organoids were differentiated from iPSC cells and cultured in control, diabetic or diabetic media supplemented with the gamma-secretase inhibitor DAPT. Endothelial cells (CD31 positive) and pericytes (PDGFRbeta positive) were isolated by FACS and subjected to RNA Seq. Accordingly, CD31 positive endothelial cells and PDGFRbeta positive pericytes differentiated from iPS cells in 2D as a well as primary endothelial (HUVECS) and pericytes (Placenta) were FACS sorted and subjected to RNA Seq.
Human blood vessel organoids as a model of diabetic vasculopathy.
Sex, Specimen part, Cell line, Subject
View SamplesDiabetes is prevalent worldwide and associated with severe health complications, including blood vessel damage that leads to cardiovascular disease and death. We report the development of 3D blood vessel organoids from human embryonic and induced pluripotent stem cells. These human blood vessel organoids contain endothelium, perivascular pericytes, and basal membranes, and self-assemble into lumenized interconnected capillary networks. We treat these vascular organoids with hyperglycemia and inflammatory cytokines in vitro, which leads to basement membrane thickening, a structural hallmark of diabetic patient. To compare differential gene expression we performed RNAseq on endothelial cells, derived from control (NG) or diabetic (DI) vascular organoids. Overall design: Vascular organoids were differentiated from human iPS cells and treated for 3 weeks with a diabetic media containing 75mM Glucose, 1ng/mL TNF-a, 1ng/mL IL6 (DI) or left untreated in 17mM Glucose (NG). Endothelial cells were FACS sorted for CD31 directly into Trizol and stored at -80°C before RNA preparation. The 2 NG and 2 DI are pools of sorted endothelial cells from multiple vascular organoids (>100) from 2 independent differentiations/treatments.
Human blood vessel organoids as a model of diabetic vasculopathy.
Sex, Specimen part, Cell line, Subject
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