Project description:The preferential localization of some neoplasms, such as serrated polyps, in specific areas of the intestine suggests that non-genetic factors may be important for their development. To test this hypothesis, we took advantage of transgenic mice that expressed HB-EGF throughout the intestine, but develop serrated polyps only in the cecum. Here we show that a host-specific microbiome was associated with serrated polyps, and that alterations of the microbiota induced by antibiotic treatment or by embryo-transfer rederivation markedly inhibited the formation of serrated polyps in the cecum. Mechanistically, development of serrated polyps was associated with a local decrease in epithelial barrier-function, bacterial invasion, production of antimicrobials, and increased expression of several inflammatory factors such as IL-17, Cxcl2, Tnf-M-NM-1, and IL-1. Increased number of neutrophils were found within the serrated polyps, and their depletion significantly reduced polyp growth. Together these results indicate that non-genetic factors contribute to the development of serrated polyps and suggest that the development of these intestinal neoplasms in the cecum is driven by the interplay between genetic changes in the host, an inflammatory response, and a host-specific microbiota. Paired design; Surrounding and SP samples were obtained from the same mouse (n=3; mouse 1, 2, 3)

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

Project description:Prostate cancer (PrCa) is one of the most common malignancies in Western countries. However, the pathways that promote invasion, especially in late-stage castration-resistant PrCa (CRPC), are poorly understood. Heat shock factors (HSFs) are transcriptional regulators essential for cell survival upon proteotoxic stress, and HSF1 is also identified as a driver of oncogenesis. Here, our aim was to elucidate the molecular mechanisms that contribute to CRPC and invasion. In silico analyses showed that high HSF1 expression levels correlate with poor survival and high Gleason score in PrCa. In the same data set, HSF2, which has not previously been linked to cancer, displayed decreased expression. Using 3-dimensional (3D) organotypic PrCa cultures that spontaneously undergo an invasive conversion, opposite effects of HSF1 and HSF2 were observed; tumor spheroids lacking HSF1 grew slowly, were polarized and devoid of invasive structures, and depletion of HSF2 potentiated invasiveness. In the in vivo xenograft chorioallantoic membrane model, HSF1 silencing caused tumor regression and fibrosis, and knockdown of HSF2 generated large invasive tumors, verifying the results from the 3D-cultures. Gene expression profiling revealed enrichment of genes connected to translational control when either HSF1 or HSF2 was silenced. HSF1-specific targets were associated with progression of tumorigenesis, whereas HSF2 targets were involved in focal adhesion, critical for invasion. This study provides the first evidence for HSF2 functioning in cancer, i.e. as a tumor suppressor. Moreover, human PrCa tissue microarrays demonstrated increased nuclear HSF1 expression, which significantly correlated with high-grade Gleason score. Cytoplasmic HSF1 was detected in a subset of tumors and intriguingly, correlated with decreased disease-specific survival. This was most pronounced in intermediate Gleason score 7 tumors and in metastases. We propose the use of HSF1 as a biomarker to predict PrCa outcome, thus facilitating clinical decision-making and supporting individualized treatment choices. HSF1 and HSF2 siRNA transfection was performed in triplicates (biological replicates), for 5 and 8 days prior to harvesting total RNA; and compared to PC-3 cells transfected with scrambled control siRNAs for 5 and 8 days, respectively.

Project description:Preeclampsia is one of the leading causes of maternal death worldwide. While the root cause is still unknown, the underlying biology of the disorder is becoming more clear. We recently published a study showing large, significant differences in DNA methylation in 3rd trimester placental samples associated with early-onset preeclampsia (EOPET) compared to controls. In this study, to identify DNA methylation differences associated with preeclampsia that occur early in pregnancy and to further delineate common EOPET-associated differences, we utilized a genetic defect, trisomy 16 (T16), that is predisposing to preeclampsia. We ran T16 placental samples from the 1st trimester (n=5) and 3rd trimester (n=10) against gestational age matched controls on the Illumina Infinium HumanMethylation450 BeadChip. Third trimester samples were from pregnancies with T16 confined to the placenta (confined placental mosaicism 16;CPM16), and consisted of samples that were and were not associated with EOPET (n=5 each). We identified a large number of DNA methylation differences in CPM16 samples compared to controls using stringent criteria (n=2254;False Discovery Rate <0.01, ->0.15). Several of these differences (11%) overlapped differences observed in chromosomally normal EOPET using similarly stringent criteria (FDR<0.01;->0.125). Isolating EOPET-associated probes produced a similar - distribution amongst CPM16 samples, although samples associated with EOPET showed a tendency towards larger DNA methylation differences. We also identified 262 DNA methylation differences between 1st trimester T16 and 1st trimester controls. Of these, 77 overlapped differences seen in 3rd trimester CPM16. Investigating these 77 T16/CPM16 specific DNA methylation differences, we identified three probes near two genes (ARGHEF37 and JUNB) that were also present as EOPET-associated methylation differences. In summary, we identified significant overlapping DNA methylation profiles of placentas with T16 and chromosomally normal placentas associated with EOPET. Specific DNA methylation marks within these profiles may be of future clinical utility in early identification of pregnancies susceptible to EOPET. Bisulfite converted DNA from 5 1st trimester trisomy 16 placentas, 5 chromosomally normal 1st trimester placentas, 10 third trimester placentas from confined placental mosaicism placentas and 10 chromosomally normal 3rd trimester placentas

Project description:Down syndrome (DS) is the most frequent cause of human congenital mental retardation. Cognitive deficits in DS result from perturbations of normal cellular processes both during development and in adult tissues, but the mechanisms underlying DS etiology remain poorly understood. To assess the ability of iPSCs to model DS phenotypes, as a prototypical complex human disease, we generated bona-fide DS and wild-type (WT) non-viral iPSCs by episomal reprogramming. DS iPSCs selectively overexpressed chromosome 21 genes, consistent with gene dosage, which was associated with deregulation of thousands of genes throughout the genome. DS and WT iPSCs were neurally converted at >95% efficiency, and had remarkably similar lineage potency, differentiation kinetics, proliferation and axon extension at early time points. However, at later time points DS cultures showed a two-fold bias towards glial lineages. Moreover, DS neural cultures were up to two times more sensitive to oxidative stress induced apoptosis, and this could be prevented by the anti-oxidant N-acetylcysteine. Our results reveal a striking complexity in the genetic alterations caused by trisomy-21 that are likely to underlie DS developmental phenotypes, and indicate a central role for defective early glial development in establishing developmental defects in DS brains. Furthermore, oxidative stress sensitivity is likely to contribute to the accelerated neurodegeneration seen in DS, and we provide proof of concept for screening corrective therapeutics using DS iPSCs and their derivatives. Non-viral DS iPSCs can therefore recapitulate features of complex human disease in vitro, and provide a renewable and ethically unencumbered discovery platform. Control (WT) and Down Syndrome iPSC lines were generated via episomal reprogramming of human donor fibroblasts. Two iPSC clones conforming to iPS criteria (determined by immunocytochemistry detection of pluripotency markers) were developed from each fibroblast donor. Two control (WT) and DS lines each were further characterized and underwent neural differentiation. Multiple biological replicates of donor fibroblast and iPSC from both control (WT) and DS lines, including 3 euploid DS samples and 3 MEL1 hESC controls (total 54 samples) were hybridized to Illumina HT-12 v4 microarray for gene expression analysis.

Project description:Analysis of gene expression in macrophages infected with influenza A virus or non-infected and treated with the saliphenylhalamide, obatoclax, expressing wild type NS1 protein or its mutant R38A, K41A. The hypothesis tested was that R38 and K41 residues within viral NS1 protein are essential for transctiptional control of cellluar gene expression. Cells were infected with influenza A/WSN/33 viruses expressing wild type NS1 protein (WT), its R38A, K41A mutant (RK/AA) or non-infected (Mock) Total RNA isolated from macrophages 8 hours post stimuation.

Project description:Analysis of the cystic fibrosis gene Cftr in the colon and small intestine of Cftr-deficient murine model. The hypothesis was loss of Cftr altered expression of genes important in intestinal homeostasis and oncogenic signaling pathways. The results identified potential roles of Cftr in up- or down-regulating major gene clusters that belong to groups of immune response, ion channel, intestinal stem cell and other growth regulators. Total RNA was isolated from the normal intestine of three Apc wildtype Cftr wildtype and three Apc Cftr-deficient mice. For the colon intestinal epithelia from the same region of the distal colon of each mouse was separated from the rest of the intestine prior to RNA isolation. Therefore RNA was obtained from only epithelial cells. For the small intestine, a section of the mid-duodenum from each mouse was sheared of villi prior to RNA isolation. Therefore RNA was obtained from whole duodenum (minus villi), containing epithelia cells but also stromal and other cells. RNA Seq was then conducted on all samples, with at least two replicates for each biological sample.

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

Project description:The aim of the study was to investigate whether environmental factors like S-adenosylmethionine (SAM) via affecting epigenome could alter cocaine-induced gene expression and locomotor sensitization in mice. Using mouse nucleus accumbens (NAc) tissue, whole-genome gene expression profiling revealed that repeated SAM treatment affected a limited number of genes, but significantly modified cocaine-induced gene expression by blunting nonspecifically the cocaine response. At the gene level, we discovered that SAM modulated cocaine-induced DNA methylation by inhibiting both promoter-associated CpG-island hyper- and hypomethylation in the NAc but not in the reference tissue cerebellum. Total RNA was extracted from the mouse nucleus accumbens (NAc) tissue. Two tissues were combined to a sample, 4 samples per group used. RNA quality and quantity were assessed using the Nano-Drop -1000 spectrophotometer and the Agilent 2100 Bioanalyzer.

Project description:This study aimed to examine gene expression in human ES cells (the RUNX1C GFP reporter line) differentiated towrads hameatopoietic mesoderm in a defined serum free medium. At day 7 of differentiation, the cells were sorted into fractions based on CD34 and CD41 expression and the four fractions analysed by microarray. The total number of samples analysed was 13. Undifferentiated hESC (RUNX1C GFP/w, based on the HES3 cell line) plus samples from d1 to d8 of differentiation comprised one experiment (9 samples) and four flow sorted fractions from d7 differentiated cells (CD34-CD41-, CD34lo CD41-, CD34hi CD41- and CD34lo CD41lo) comprised the second experiment. The parent cell line was maintained on mouse feeder cells in KOSR containing medium supplemented with 10 ng/ml FGF2. Differentiation was performed as spin EBs in APEL medium (Ng et al Nature Protocols 2008). For the first 4 days, medium was supplemented with BMP4, VEGF, SCF and Activin. Medium was changed at d4 to fresh APEL medium supplemented with BMP4, VEGF, SCF, FGF2 and IGF2.