Summary: Activation of the evolutionarily conserved, developmental Wnt pathway has been reported during maladaptive cardiac remodeling. Although the function of Wnt-transcriptional activation in development is well described, the consequences of Wnt pathway activation, as well as its cardiac-specific regulatory role in the adult heart, is largely unknown. We show that ß-catenin and Transcription factor 7-like 2 (TCF7L2), the main nuclear components of the Wnt-transcriptional cascade, and their transcriptional activity are increased upon pathological remodeling in both murine and human hearts. To understand the consequences of increased Wnt signaling pathway activity, we utilized an in vivo mouse model in which ß-catenin is acutely stabilized in adult cardiomyocytes (CM), leading to increased ventricular TCF7L2 expression and activation of its target genes. Mice with stabilized ß-catenin displayed cardiac hypertrophy, increased mortality, reduced cardiac function and altered calcium homeostasis, similar to experimentally induced hypertrophy. Moreover, we observed a re-activation of Wnt-dependent developmental gene programs including activation of the Wnt/ß-catenin-independent pathway, increased CM cell cycling with poly-nucleation and cytoskeletal disorganization, underscoring a central role in adult tissue remodeling. By integrating transcriptome analyses and genome-wide occupancy (ChIP-seq) of the endogenous ventricular TCF7L2, we show that upon aberrant Wnt activation, TCF7L2 induces context and Wnt-specific gene regulation in pathological remodeling. Interestingly, ß-catenin stabilized ventricles showed increased histone H3 lysine 27 acetylation (H3K27ac) and TCF7L2 recruitment to novel disease-associated gene-specific enhancers. Importantly, using integrative motif analyses and experimental evidences, our data uncovered a role for GATA4 as a cardiogenic regulator of TCF7L2/ß-catenin complex and established a paradigm for cell-specific effects of Wnt signaling. Altogether, our studies unraveled the nuclear Wnt-TCF7L2-associated chromatin landscape and its role in adult tissue remodeling leading to heart failure. Purpose: The aim of this study was to compare transcriptome profiles (RNA-seq) of normal (containing a Cre recombinase positive locus- Cre "positive" control with a WT ß-catenin locus; to eliminate effects of Cre-mediated cardiac toxicity) and ß-catenin stabilized murine adult cardiac ventricles. Methods: Adult cardiac tissue mRNA profiles for normal and Wnt-activated mice were obtained using deep sequencing, in triplicates, using Illumina HiSeq2000. The sequence reads that passed quality filters were analyzed at the transcript isoform level with TopHat followed by DESeq2. qPCR validation was performed using TaqMan and SYBR Green assays Conclusions: Our study represents the first detailed analysis of the processes triggered upon Wnt activation in the adult heart, which was so far, not investigated. We report that this Wnt activation in the adult heart maintains its developmental function; however due to the lack of adequate developmental plasticity in the adult heart, culminates in pathological remodeling. Overall design: Gene expression profiling from cardiac ventricles of 15 weeks-old mice with wild type and ß-catenin stabilized mice
A context-specific cardiac β-catenin and GATA4 interaction influences TCF7L2 occupancy and remodels chromatin driving disease progression in the adult heart.
Age, Cell line, Subject
View SamplesThe lung host immune responses following M.tuberculosis infection in the mouse model of tuberculosis were assayed by studying the gene expression profiles at day 0, day 12, 15 and 21 post infection
Profiling early lung immune responses in the mouse model of tuberculosis.
Specimen part, Time
View SamplesThis study provides a comprehensive evaluation of changes in gene expression during treatment with Genistein in vitro.
Dose- and Time-Dependent Transcriptional Response of Ishikawa Cells Exposed to Genistein.
Treatment
View SamplesFOXE3 is a lens specific transcription factor that has been associated with anterior segment ocular dysgenesis. To determine the transcriptional target(s) of FOXE3 that are indispensable for the anterior segment development, we examined the transcriptome and the proteome of cells expressing truncated FOXE3 responsible for Peters anomaly identified through linkage-coupled next-generation whole exome sequencing. We found that DNAJB1, an autophagy-associated protein, was the only candidate exhibiting differential expression in both screens. We confirmed the candidacy of DNAJB1 through chromatin immunoprecipitation and luciferase assays while knockdown of DNAJB1 in human lens epithelial cells resulted in mitotic arrest. Subsequently, we targeted dnajb1a in zebrafish through injection of a splice-blocking morpholino. The dnajb1a morphants exhibited underdeveloped cataractous lenses with persistent apoptotic nuclei. In conclusion, we have identified DNAJB1 as a transcriptional target of FOXE3 in a novel pathway that is crucial for development of the anterior segment of the eye. Overall design: Human Embryonic Kidney (HEK293FT) cells were transfected with the expression vector (pT-RexTM-DEST30) harboring either the wild type or the mutant (C240*) FOXE3 ORF (open reading frame). The experimental design included a total of eight biological replicates of cells expressing the wild type and eight replicates of mutant FOXE3 along with eight non-transfected controls. Cells were harvested 24-hour post-transfection and subjected to total RNA isolation for the preparation of whole transcriptome next-generation sequencing libraries. Initially, we examined the quality of transcriptome libraries on a MiSeq genome analyzer. Subsequent to confirmation of the quality, all libraries were paired-end sequenced (2 x 100 bp) using Illumina TruSeq Cluster V3 flow cell at a concentration of 13.0 pM in two separate lanes (12 bar-coded mRNA pooled libraries in each lane) on a HiSeq 2000 genome analyzer.
FOXE3 contributes to Peters anomaly through transcriptional regulation of an autophagy-associated protein termed DNAJB1.
No sample metadata fields
View SamplesWe have determined the gene expression profile induced by 17 alpha-ethynyl estradiol (EE) in Ishikawa cells, a human uterine-derived estrogen-sensitive cell line, at various doses (1 pM, 100 pM, 10 nM, and 1 microM) and time points (8, 24, and 48 h). The transcript profiles were compared between treatment groups and controls (vehicle-treated) using high-density oligonucleotide arrays to determine the expression level of approximately 38,500 human genes. By trend analysis, we determined that the expression of 2560 genes was modified by exposure to EE in a dose- and time-dependent manner (p </= 0.0001). The annotation available for the genes affected indicates that EE exposure results in changes in multiple molecular pathways affecting various biological processes, particularly associated with development, morphogenesis, organogenesis, cell proliferation, cell organization, and biogenesis. All of these processes are also affected by estrogen exposure in the uterus of the rat. Comparison of the response to EE in both the rat uterus and the Ishikawa cells showed that 71 genes are regulated in a similar manner in vivo as well as in vitro. Further, some of the genes that show a robust response to estrogen exposure in Ishikawa cells are well known to be estrogen responsive, in various in vivo studies, such as PGR, MMP7, IGFBP3, IGFBP5, SOX4, MYC, EGR1, FOS, CKB, and CCND2, among others. These results indicate that transcript profiling can serve as a viable tool to select reliable in vitro systems to evaluate potential estrogenic activities of target chemicals and to identify genes that are relevant for the estrogen response.
The genomic response of a human uterine endometrial adenocarcinoma cell line to 17alpha-ethynyl estradiol.
No sample metadata fields
View SamplesThis study provides a comprehensive evaluation of changes in gene expression during treatment with Bisphenol A in vitro.
The genomic response of Ishikawa cells to bisphenol A exposure is dose- and time-dependent.
Cell line, Treatment
View SamplesPurpose: Identify genes and pathways affected in tuft embryos with NTDs Results: Expression of genes associated with neural tube closure and components of non-canonical WNT signaling/PCP pathways were affected Conclusions: TET1 regulates genes associated with neural tube closure Overall design: RNA pooled from the rostrums of E9 (18-22 somites) tuft/tuft embryos with NTD compared with respective wildtype background strain
A mutation in the tuft mouse disrupts TET1 activity and alters the expression of genes that are crucial for neural tube closure.
Specimen part, Cell line, Subject
View SamplesBud endodormancy induction response of two genotypes (Seyval a hybrid white wine grape and V. riparia, PI588259 a native north american species) was compared under long and short photoperiod. Three separate replicates (5 plants/replicate) were treated in each of 2 separate years (2007 and 2008) to generate paradormant (LD) and same aged endodormancy-induced (SD) buds for transcriptomic, proteomic and metabolomic analysis. Potted, spur-pruned two to six-year-old vines were removed from cold storage (Seyval 3-19-07, 3/18/08; V. riparia 3/26/07, 3/24/08) and grown under a LD (15 h) at 25/20 + 3C day/night temperatures (D/N). When vines reached 12-15 nodes they were randomized into groups for differential photoperiod treatments. On 4/30/07 and 4/28/08 LD and SD (13 h) treatments were imposed with automated photoperiod system (VRE Greenhouse Systems). Temperatures were maintained at 25/20 + 3C D/N. Three replications (5 vines/replication) were harvested between 5/07-6/07 and then again in 5/08-6/08. At 1, 3, 7, 14, 21, 28 and 42 days of differential photoperiod treatment, buds were harvested from nodes 3 to 12 (from the base of the shoot) of each separate replicate, immediately frozen in liquid nitrogen, and placed at -80C for future RNA, protein and metabolite extraction. These time points encompass early reversible phases as well as key time points during transition to irreversible endodormancy development. After photoperiod treatments and bud harvests, all pruned vines were returned to LD and monitored for bud endodormancy. The endodormant vines were identified after 28 days and moved to cold storage. The nondormant vines were allowed to grow again and induced into dormancy at a later date. Acknowledgement:This study was funded by NSF Grant DBI0604755 and funds from the South Dakota Agriculture Experiment Station. ****[PLEXdb(http://www.plexdb.org) has submitted this series at GEO on behalf of the original contributor, Anne Fennell. The equivalent experiment is VV18 at PLEXdb.]
Short day transcriptomic programming during induction of dormancy in grapevine.
Age, Specimen part
View SamplesGene expression of P. aerruginosa changes after short-term exposure to ciprofloxacin at sub-inhibitory concentrations but the effect of long-term exposure which select for the most fitted subpopulations is not known.
The phenotypic evolution of Pseudomonas aeruginosa populations changes in the presence of subinhibitory concentrations of ciprofloxacin.
No sample metadata fields
View SamplesTheiler's murine encephalomyelitis virus (TMEV) induces different diseases in the central nervous system (CNS) and heart, depending on the mouse strains and time course, where cytokines play a key role for viral clearance and immune-mediated pathology (immunopathology). In SJL/J mice, TMEV infection causes chronic TMEV-induced demyelinating disease (TMEV-IDD) in the spinal cord around 1 month post infection (p.i.). Unlike other immunopathology models, both pro-inflammatory and anti-inflammatory cytokines can play dual roles in TMEV-IDD. Pro-inflammatory cytokines play a beneficial role in viral clearance while they also play a detrimental role in immune-mediated demyelination. Anti-inflammatory cytokines suppress not only protective anti-viral immune responses but also detrimental autoreactive immune responses. On the other hand, in C3H mice, TMEV infection induces a non-CNS disease, myocarditis, with three phases: phase I, viral pathology with interferon and chemokine responses; phase II, immunopathology mediated by acquired immune responses; and phase III, cardiac fibrosis. Although the precise mechanism how a single virus, TMEV, induces the distinct diseases in different organs is unclear, principal component analysis (PCA) of transcriptome data allows us to identify the key factors contributing to distinct immunopathology. The PCA demonstrated that in vitro infection of a cardiomyocyte cell line could reproduce the transcriptome profile of phase I in TMEV-induced myocarditis; distinct interferon/chemokine-related responses were induced in vitro in infected cardiomyocytes, but not in infected neuronal cells. In addition, the PCA of in vivo CNS transcriptome data showed that decreased lymphatic marker expression was associated with inflammation in TMEV infection. Here, dysfunction of lymphatic vessels may contribute to immunopathology by delaying clearance of cytokines and immune cells from the inflammatory site, although this might confine the virus at the site, preventing virus spread via lymphatic vessels. On the other hand, in the heart, dysfunction of lymphatics was associated with reduced lymphatic muscle contractility by pro-inflammatory cytokines. Therefore, TMEV infection could induce different cytokine expressions as well as lymphatic vessel dysfunction by the distinct mechanism between the CNS and heart, which might contribute to organ-specific immunopathology. Overall design: Transcriptome analysis of spinal cords from TMEV-infected mice at 4, 7, and 35 days post infection.
Bioinformatics Analysis of Gut Microbiota and CNS Transcriptome in Virus-Induced Acute Myelitis and Chronic Inflammatory Demyelination; Potential Association of Distinct Bacteria With CNS IgA Upregulation.
Sex, Specimen part, Cell line, Subject, Time
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