Project description:DNA sequencing reads of human adult stem cell cultures from liver, colon and small intestine. Including biopsy or blood samples of the donors.

Project description:Mutations of embryonic and fetal origin have the potential to affect a large proportion of adult cells and may alter cancer predisposition or lead to genetic disease syndromes. We have recently shown that human adult-stem cells progressively acquire approximately 40 novel tissue-specific mutations per year throughout postnatal life. Prenatal mutation rates are as yet unknown. Here we determined genome-wide mutation patterns of single stem cells in human development by sequencing of clonally expanded intestinal and liver organoid cultures of 2nd trimester human foetuses. Our results show that mutation rates in fetal stem cells are significantly higher than in adult stem cells.

Project description:Pioneering studies within the last few years have allowed the in vitro expansion of tissue-specific adult stem cells from a variety of endoderm-derived organs, including the stomach, small intestine and colon. Here we derived organoids from mouse gallbladder tissue (gallbladder organoids), from mouse liver (including the extrahepatic biliary ducts and gallbladder; liver organoids) and from mouse small intestine tissue (intestinal organoids). RNA was prepared from these organoids and used to assay expression of 21,258 genes using Affymetrix gene expression arrays. RNA was also prepared from mouse gallbladder, liver and small intestine tissues and used to assay gene expression in these tissues. Finally, gallbladder organoids were induced to differentiate by removing R-spondin 1 and noggin from the culture media and subjected to gene expression array analysis. RNA was extracted from mouse gallbladder organoids, differentiated gallbladder organoids, liver organoids, small intestine organoids, gallbladder tissue, liver tissue and small intestine tissue and then used for hybridization of Affymetrix gene expression microarrays.

Project description:Systematic analyses of genome-wide mutation profiles of cancer cells and cultured cells have recently shown that some anticancer treatments are highly mutagenic. Since most treatments are typically given systemically, any healthy cell in the body exposed to the treatment drug may also accumulate therapy induced mutations. However, quantitative insights of treatment-induced mutations in normal tissues remain elusive. Here, we determine genome-wide mutation patterns in healthy adult stem cells (ASCs) of either the colon or the liver of 14 colorectal cancer patients after treatment with mutagenic anti-cancer therapies. Capecitabine/Oxaliplatin (CAPOX) induces 500-1000 mutations with a platinum-induced footprint in each colon adult stem cell. In contrast, capecitabine, which is metabolized to 5-fluorouracil (5-FU), effects strongly vary between and within patients with some colon ASCs accumulating up to 500 mutations from 5-FU, while most other colon ASCs show a complete absence of 5-FU mutagenesis. Finally, our results show that local radiation therapy induces deletions of >5bp - 10kbp as well as structural rearrangements including reciprocal and multi-breakpoint variants in colon ASCs. Surprisingly and unlike colon ASCs, healthy liver ASCs of systemically treated colon cancer patients show no therapy-related mutations. Taken together, our results reveal that colon ASCs are particularly vulnerable to platinum-based therapies and to a lesser extent to treatments with 5-FU and may explain why platinum-based therapies, and not 5-FU, are associated with secondary malignancies. Consequently, while anticancer treatments are efficient in killing cancer cells, they increase the mutation burden in healthy cells explaining why treatment is an important risk factor for second cancers, but their mutational impact on healthy cells markedly differs between chemodrug and between tissue.

Project description:Clonally expanded human pluripotent and adult (liver + intestine) stem cell clones were subjected to whole genome sequencing to determine the mutational impact of in vitro culture

Project description:Pioneering studies within the last few years have allowed the in vitro expansion of tissue-specific adult stem cells from a variety of endoderm-derived organs, including the stomach, small intestine and colon. Here we derived organoids from mouse gallbladder tissue (gallbladder organoids), from mouse liver (including the extrahepatic biliary ducts and gallbladder; liver organoids) and from mouse small intestine tissue (intestinal organoids). RNA was prepared from these organoids and used to assay expression of 21,258 genes using Affymetrix gene expression arrays. RNA was also prepared from mouse gallbladder, liver and small intestine tissues and used to assay gene expression in these tissues. Finally, gallbladder organoids were induced to differentiate by removing R-spondin 1 and noggin from the culture media and subjected to gene expression array analysis.

Project description:Wnt/b-catenin pathway is a key modulator of intestinal homeostasis by regulating stem cell biology during gut organogenesis and in adult life. DICKKOPF (DKK)-1 is a secreted inhibitor of Wnt/b-catenin signaling from plasma membrane receptors. We found that in human intestine, DKK-1 locates within the nucleus of differentiated enterocytes and enteroendocrine cells but not of proliferating and stem cells at the bottom of the crypts. DKK-1 is also nuclear in colon cancer cells locating at sites of active gene transcription. ChIP-seq and transcriptomic analysis both confirmed that DKK-1 binds chromatin and regulates gene expression. Thus, we demonstrate that DKK-1 is a multifunctional protein that inhibits Wnt/b-catenin signaling at plasma membrane and controls specific genes in the nucleus, suggesting that these functions are relevant for intestinal homeostasis. Analysis of DKK-1 location and associated roles in human colon cancer cells and crypts of small and large bowel.

Project description:Tissue-specific mutation accumulation in human adult stem cells during life

Project description:We developed DNA methylation clocks where ongoing (de)methylation causes the clock to ‘tick-tock’ back-and-forth between methylated and unmethylated states. We identified tick-tock CpG sites using standard methylation arrays and developed a mathematical modelling framework to quantitatively measure human adult stem cell dynamics from these data. Small intestinal crypts were inferred to contain slightly more stem cells than colon (6.5 ± 1.0 vs 5.8 ± 1.7 stem cells/crypt) with slower stem cell replacement in small intestine (0.79 ± 0.5 vs 1.1 ± 0.8 replacements/stem cell/year). Germline APC mutation increased the number of replacements per crypt (13.0 ± 2.4 replacements/crypt/year vs 6.9 ± 4.6 for healthy colon).

Project description:The Wnt target gene Lgr5 marks cycling stem cells in the small intestine, colon and hair-follicle. In the adult stomach, Lgr5 expression is confined to 3-4 proliferating cells at the gland base throughout the pylorus and limited numbers of corpus-type glands adjacent to the esophagus and squamous forestomach. In-vivo lineage tracing reveals that the pyloric Lgr5+ve cells rapidly generate all the major cell-types present in the gastric epithelium and maintain this multipotent stem cell activity over at least 20 months. In-vitro, single adult Lgr5+ve cells efficiently generate gastric units closely resembling mature pyloric glands. We conclude that Lgr5 is marking an active stem cell population at the base of the pyloric glands contributing to the long-term renewal of the adult gastric epithelium. The transcriptome of the adult Lgr5+ve stem cells harbors multiple Wnt target genes, implying a role for Wnt signaling in regulating pyloric stem cell function in-vivo. Conditional deletion of APC in these Lgr5+ve stem cells rapidly initiates tumor formation, supporting a potential role for aberrant Wnt signaling activity in gastric cancer.