Project description:Background: Mismatch repair (MMR)-deficiency increases the risk of colorectal tumorigenesis. To determine whether the tumors develop on a normal or disturbed epigenetic background and how radiation affects this, we determined genome-wide histone H3 methylation profiles in macroscopic normal intestinal tissue of young radiated and untreated MMR-deficient VCMsh2LoxP/LoxP (Msh2−/−) mice months before tumor onset. Results: Histone H3 methylation increases in Msh2−/− compared to control Msh2+/+ mice. Activating H3K4me3 and H3K36me3 histone marks frequently accumulate at genes that are H3K27me3 or H3K4me3 modified in Msh2+/+ mice, respectively. The genes recruiting H3K36me3 enrich in gene sets associated with DNA repair, RNA processing, and ribosome biogenesis that become transcriptionally upregulated in the developing tumors. A similar epigenetic effect is present in Msh2+/+ mice 4 weeks after a single-radiation hit, whereas radiation of Msh2−/− mice left their histone methylation profiles almost unchanged. Conclusions: MMR deficiency results in genome-wide changes in histone H3 methylation profiles preceding tumor development. Similar changes constitute a persistent epigenetic signature of radiation-induced DNA damage.

Project description:Epigenetic changes during long term intestinal organoid culture

Project description:The faecal indicator bacterium Escherichia coli K12 was used to study the cellular events that take place at the transcription level using the microarray technology during short-term (physiological) and long-term (genetic) adaptation to slow growth under limited nutrient supply. Short-term and long-term adaptation were assessed by comparing the mRNA levels isolated after 40 or 500 hours of glucose-limited continuous culture at a dilution rate of 0.3 h-1 with those from batch culture with glucose excess. Keywords: glucose-limited continuous culture, adaptation, microarray, high affinity transport systems, transcriptome, Escherichia coli

Project description:Histone post-translational modifications (PTMs) generate a complex combinatorial code that regulate gene expression and nuclear functions, and whose deregulation has been documented in different types of cancers. Therefore, the availability of relevant culture models that can be manipulated and that retain the epigenetic features of the tissue of origin is absolutely crucial for studying epigenetic mechanisms underlying cancer, as well as for testing epigenetic drugs and uncovering possible epigenetic biomarkers. In this study, we took advantage of quantitative mass spectrometry to comprehensively profile histone PTMss in patient tumor tissues, primary cultures and cell lines from two representative tumor models, breast cancer and glioblastoma, revealing a dramatic and systematic rewiring of histone marks in cell culture conditions, which include a decrease of H3K27me3, H3K79me1/me2 and H3K9ac/K14ac, and an increase of H3K36me1/me2. While some changes occurr in short-term primary cultures, most of them are instead time-dependent and appear only in long-term cultures. Remarkably, such change mostly revert in cell line- and primary cell-derived in vivo xenograft models. Our results support the use of short-term cultures and xenografts models as the most representative models of in vivo epigenetic processes, and suggest cautions when using cell lines and long-term primary cultures for epigenetic investigations.

Project description:Background & Aims Patient-derived gastrointestinal organoids are powerful tools for studying human physiology and disease. However, generating organoids requires prompt isolation and culture of fresh tissue, which is labor and time intensive, placing restraints on basic and clinical research. For example organoid biobanking efforts, or the ability to obtain specimens from distant locations that lack the expertise to culture organoids, is limited by current approaches. We sought to develop a method by which tissue biopsies from patients could be cryo-preserved, stored, or shipped, and later thawed in order to establish live organoid cultures. Methods A method for freezing and recovery, along with straightforward isolation methods using readily available materials were developed. Epithelial isolation and culture conditions were optimized to promote cell survival and the establishment of long-term culture post-thawing. Results Patient biopsies from stomach, duodenum, ileum, colon and from adenomateous colonic polyps were frozen, subsequently thawed and used to successfully establish patient-specific epithelium-only organoid cultures with 100% efficiency (n=31 independent patient biopsies from different regions of the GI tract). Frozen tissue could be shipped internationally and across the United States and used to establish successful organoid cultures. Organoid cultures could be expanded, passaged and frozen down for long-term storage. RNA-sequencing demonstrates that organoids derived from fresh tissue or from frozen biopsies are >99% transcriptionally identical. Conclusions Cryo-preservation of human tissue biopsies followed by the establishment of long-term, expandable cultures has negligible effect on transcription when compared to freshly prepared organoids, and will be of immense benefit to research and for clinical applications. This technique will allow for the establishment of biobanks of human tissues that can be revived and cultured in the future as well as transported across the globe for research, therapeutic or diagnostic use in remote labs and/or clinics.

Project description:We previously established long-term 3D organoid culture systems for several murine tissues (intestine, stomach, pancreas and liver) as well as human intestine and pancreas. Here, we describe culture conditions to generate long-term 3D culture from human gastric stem cells. The technology can be applied to study the epithelial response to infection with Helicobacter pylori. Human gastric cultures can expand indefinitely in 3D Matrigel. Cultures can be generated from normal tissue, from single sorted stem cells, or from tumor tissue. Organoids maintain many characteristics of the respective tissue in terms of histology, marker expression and euploidy. Organoids from normal tissue express markers of four lineages of the stomach and self-organize in gland and pit-domains. They can be directed to specifically express either lineages of the gastric gland, or the gastric pit by addition of Nicotinamide and withdrawal of Wnt. While gastric pit lineages react marginally to bacterial infection, gastric gland lineages mount a strong inflammatory response. The gastric culture system provides a unique tool to study gastric pathologies. We generated 2 sets of experiments. The first set contains organoids in 4 conditions: (1) organoids in expansion condition ENRWFGNiTi ("gland-type organoids") from 3 donors, (2) organoids as in 1 but differentiated for 4 days in differentiation condition ENR_FGNiTi ("pit'type organoids"), (3) organoids as in 1 but infected with Helicobacter pylori strain P12 MOI 50 for 2 h, (4) organoids as in 2 but infected as in 3. All 4 conditions were tested on the same organoid line in parallel. This experiment was conducted independently with cultures from 3 different donors. The second set of experiments compares freshly isolated glands with organoids. Samples from 2 patients were analyzed. Each patient received a total gastrectomy. From each patient, glands from corpus region or pyloric antrum were isolated. From each isolation, one aliquod was stored for microarray analysis and one aliquod used to generate organoids. Organoids and glands were subsequently lysed and analyzed in parallel.

Project description:Long-term culture of human telencephalic organoids cultured in the presence or absence of exogenous ECM. To evaluate how ECM supplementation influences organoid development, we supplied exogenous ECM in the form of Matrigel at the beginning of neuroepithelialisation (day 10, D10), either as a solid droplet that provides long-term exposure to a polymerized network of ECM proteins (droplet embedding - condition "drop" in the metadata table), or transiently dissolved in the culture medium (concentration of 2%V/V ) from D10 to D13 (liquid embedding - "liq"). These protocols were compared to one without exposure to exogenous ECM ("no"). Organoids were processed at 120 days of culture, when mature cortical tissue is present.

Project description:Despite the impact of bile duct disorders, treatment options remain very limited. Poor access to biliary tissue and restrictions in long-term culture or significant expansion of primary cholangiocytes have posed major challenges for research in the field. These limitations have so far precluded large scale experiments such as transcriptomic and genome-wide analyses which are urgently needed to better understand biliary physiology and pathophysiology. To address this issue, we have developed a novel system for the isolation and propagation of primary cholangiocytes from the extrahepatic bile ducts. The resulting Extrahepatic Cholangiocyte Organoids (ECOs) maintain their genetic stability, transcriptomic profile and function over long term culture and are compatible with regenerative medicine applications such as biliary reconstruction. We established a novel protocol for the isolation and propagation of primary cholangiocytes from the extrahepatic biliary tree in the form of extrahepatic cholangiocyte organoids (ECOs). The aim of this experiment was to provide in depth characterisation of the transcriptome of ECOs during long term culture. We compare the transcriptome of ECOs cultured for 1 passage (P1), 10 passages (P10) and 20 passages (P20) with freshly isolated primary cholangiocytes from the common bile duct. Embryonic Stem Cells (ES) cells are used as a negative control=

Project description:Epigenetic drift during long-term culture of cells in vitro

Project description:Epigenetic drift during long-term culture of cells in vitro