Project description:Pancreatic ductal adenocarcinoma (PDAC) is believed to arise from the accumulation of a series of somatic mutations and is also frequently associated with pancreatic intraepithelial neoplasia (PanIN) lesions. However, there is still debate as to whether the cell-type-of-origin of PanINs and PDACs is acinar or ductal. As cell type identity is maintained epigenetically, DNA methylation changes during pancreatic neoplasia can provide a compelling perspective to examine this question, but DNA methylation sequencing has not yet been performed genome-wide on purified exocrine and neoplastic cell types in the pancreas. Thus, we performed genome-wide DNA methylation sequencing on acini, non-neoplastic ducts, PanIN lesions, and PDAC lesions. We found that: 1) both global methylation profiles and block DMRs clearly implicate an acinar origin for PanINs; 2) at the gene level, PanIN lesions exhibit an intermediate acinar-ductal phenotype resembling acinar-to-ductal metaplasia (ADM); and 3) PanINs are epigenetically primed to progress to PDAC. Thus, epigenomic analysis complements histopathology to define molecular progression toward PDAC.

Project description:Acinar and ductal cells are the major epithelial cell types in the exocrine pancreas, but which of these serves as the cell-of-origin in human PDAC has been debated. Our mouse models have demonstrated that oncogenic Kras expression and Trp53 loss in pancreatic acinar or ductal cells can lead to pancreatic cancer. Here, we performed gene expression profiling of bulk acinar cell-derived and ductal cell-derived mouse pancreatic tumors to identify the transcriptomic profiles.

Project description:The exocrine compartment of the pancreas consisting of ducts and acini makes up most of the pancreatic tissue and is the site of origin for pancreatitis and pancreatic ductal adenocarcinoma (PDAC). Our understanding of the initiation and progression of human PDAC is limited because of challenges associated with maintaining acinar cells in culture. Here we report the commitment of human pluripotent stem cells towards pancreatic duct-like and acini-like organoids that express properties of the neonatal exocrine pancreas. The expression of PDAC-oncogenes KRasG12D or GNASR201C induced cell lineage-specific effects where GNASR201C was more effective in ductal compared to acinar organoids. KRasG12D was more effective in modeling cancer in vivo when expressed in acinar cells and was associated with acinar to ductal metaplastic changes in culture and in vivo. Thus we demonstrate lineage tropism and plasticity in the human exocrine pancreas and identify a renewable source of ductal and acinar epithelia for understanding exocrine development and diseases.

Project description:We used in vitro mouse pancreatic 3-D organoid model to screen for possible compounds that inhibit or reverse Acinar-to-Ductal Metaplasia, which is a known intial stage of pancreatic ductal adenocarcinoma (PDAC). This model has higher translational value due to the harbored KRASG12D mutation which is common in PDAC patients and is considered a driving mutatrion for cancer development. Observed transcriptomic differences with select hit compounds compared to vehicle control could be very useful for future targeted therapy approach, as well as for further understanding of the driving mechanisms involved in pancreatic metaplasia and PDAC. Some of the hit compounds are already FDA approved drugs that could be easily re-purposed for PDAC treatment or prevention.

Project description:Pancreatic acinar cells can dedifferentiate upon tissue injury and acquire ductal characteristics. This acquisition of duct cell features is critical in tumor development. Nevertheless, duct cells themselves are less prone for development of PDAC (pancreatic ductal adenocarcinoma) than dedifferentiated acini. We aimed to clarify which genes are unique for dedifferentiated acini. Mixed exocrine preparations of acinar and duct cells were obtained from human pancreatic donor organs and cultured to induce dedifferentiation. We lineage-labeled and FACS-purified these human dedifferentiated acinar cells and compared them to duct cells from the same donor (n=5).

Project description:Global microRNA expression profiling of microdissected pancreatic tissues were collected using Agilent miRNA microarrays (G4470B, Sanger 10.1) carrying 723 individual human miRNA probes. Four different sources of RNA were analyzed: microdissected normal pancreatic ductal cells (ND, n=4),microdissected acinar cells (AC, n=4), macrodissected chronic pancreatitis (CP, n=5) and micordissected xenograft tissues derived from primary pancreatic ductal adenocarcinomas (PDAC, n=5). Four condition (AZ, ND, PDAC, CP), each condition is represented by 4 to 5 biological replicates

Project description:Pancreatic ductal adenocarcinoma (PDAC) is a deadly disease when diagnosed at a late stage, however patient survivorship significantly increases when the disease is detect prior to metastasis. To study the earliest events leading to PDAC initiation, we developed a genetically engineered mouse model of PDAC utilizing a tamoxifen-inducible Cre Recombinase knocked into the transcription factor Ptf1a locus to induce expression of oncogenic KrasG12D and Trp53R270H alleles in adult pancreatic acinar cells. Mice of the genotype KrasLSL-G12D/+; Trp53LSL-R270H/+; Ptf1aCreERTM/+ (KPT) developed PDAC following tamoxifen injection while control Cre recombinase negative KrasLSL-G12D/+; Trp53LSL-R270H/+; (KP) mice injected with tamoxifen did not develop PDAC. Acinar cells comprising the pancreata of tamoxifen treated KPT mice we observed to undergo acinar to ductal metaplasia (ADM), and formed precancerous lesions. We used laser capture microdissection (LCM) and RNA sequencing to generate, to our knowledge, the first transcriptional profile of an enriched population of metaplastic acinar cells in situ. Comparing the transcriptional profile of metaplastic acinar cells with the transcriptional profile of healthy pancreatic tissue identified differentially expressed genes associated with ADM. Ingenuity pathway analysis revealed transcriptional regulators and canonical signaling pathways involved in ADM. LCM was used to generate a transactional profile of cancer cells isolated from pancreatic tumors, and differential gene expression analysis revealed a subset of genes which are overexpressed in both ADM and PDAC relative to healthy pancreas. Further analysis of genes expressed in both pancreatic cancer precursor ADM lesions and invasive PDAC may lead to the identification of novel biomarkers of PDAC.

Project description:Pancreatic ductal adenocarcinoma (PDAC) is an aggressive, painful disease with a 5-year survival rate of only 9%. Recent evidence indicates that distinct epigenomic landscapes underlie PDAC progression, identifying the H3K9me pathway as important to its pathobiology. Here, we delineate the role of Euchromatic Histone-lysine N-Methyltransferase 2 (EHMT2), the enzyme that generates H3K9me, as a downstream effector of oncogenic KRAS during PDAC initiation and pancreatitis-associated promotion. EHMT2 inactivation in pancreatic cells reduces H3K9me2 and antagonizes KrasG12D mediated acinar-to-ductal metaplasia (ADM) and PanIN formation in both the Pdx1-Cre and P48+/-Cre KrasG12D mouse models. Ex vivo acinar explants also show impaired EGFR-KRAS-MAPK pathway mediated ADM upon EHMT2 deletion. Notably, KrasG12D increases EHMT2 protein levels and EHMT2-EHMT1-WIZ complex formation. Transcriptome analysis reveals that EHMT2 inactivation upregulates a cell cycle inhibitory gene expression network that converges on the Cdkn1a/p21-Chek2 pathway. Congruently, pancreas tissue from KrasG12D animals with EHMT2 inactivation have increased P21 protein levels and enhanced senescence. Furthermore, loss of EHMT2 reduces inflammatory cell infiltration typically induced during KrasG12D-mediated initiation. The inhibitory effect on KrasG12D-induced growth is maintained in the pancreatitis-accelerated model, while simultaneously modifying immunoregulatory gene networks that also contribute to carcinogenesis. This study outlines the existence of a novel KRAS-EHMT2 pathway that is critical for mediating the growth-promoting and immunoregulatory effects of this oncogene in vivo, extending human observations to support a pathophysiological role for the H3K9me pathway in PDAC.

Project description:Accumulation of genetic mutations is thought to be a primary cause of cancer. However, a set of genetic mutations sufficient for cancer development remains unclear in most cancers, including pancreatic cancer. Here, we examined the effect of in vivo reprogramming on Kras-induced cancer development. We first demonstrate that Kras and p53 mutations are insufficient to induce activation of ERK signaling and cancer development in the pancreas. We next show that short transient expression of reprogramming factors (1-3 days) in pancreatic acinar cells results in repression of acinar cell enhancers and reversible loss of acinar cell properties. Notably, the transient expression of reprogramming factors in Kras mutant mice is sufficient to induce robust and persistent activation of ERK signaling in acinar cells and rapid formation of pancreatic ductal adenocarcinoma (PDAC). In contrast, forced expression of acinar cell-related transcription factors inhibits pancreatitis-induced activation of ERK signaling and development of precancerous lesions in Kras-mutated acinar cells.

Project description:Accumulation of genetic mutations is thought to be a primary cause of cancer. However, a set of genetic mutations sufficient for cancer development remains unclear in most cancers, including pancreatic cancer. Here, we examined the effect of in vivo reprogramming on Kras-induced cancer development. We first demonstrate that Kras and p53 mutations are insufficient to induce activation of ERK signaling and cancer development in the pancreas. We next show that short transient expression of reprogramming factors (1-3 days) in pancreatic acinar cells results in repression of acinar cell enhancers and reversible loss of acinar cell properties. Notably, the transient expression of reprogramming factors in Kras mutant mice is sufficient to induce robust and persistent activation of ERK signaling in acinar cells and rapid formation of pancreatic ductal adenocarcinoma (PDAC). In contrast, forced expression of acinar cell-related transcription factors inhibits pancreatitis-induced activation of ERK signaling and development of precancerous lesions in Kras-mutated acinar cells.