Project description:Despite reduced function and volume of the exocrine pancreas in type 1 diabetes, literature describing the histology and the molecular biological profile in this area is limited. Here, the density of acinar cells was examined adjacent to and at varying distances from islets and the transcriptome was analyzed on laser capture microdissected (LCM) tissue from organ donors with and without type 1 diabetes. We demonstrate preserved acinar nuclei density in type 1 diabetes and find no support of acinar atrophy in pancreata devoid of insulin. The density of acinar nuclei was unaltered in type 1 diabetes. Principal component analysis of the transcriptomes of acinar tissue extracted from various areas of the pancreas showed no apparent clustering based on disease status, and few differentially expressed genes were discovered. However, when performing GSEA, transcriptional alterations were present in the acinar tissue independently of the distance from islets. Two gene sets were enriched in all exocrine regions; Myc Targets V2 and Estrogen Response Early. The alteration of these is a possible link to the increased incidence of pancreatic cancer in type 1 diabetes. Taken together, these new data shed light on the pathogenesis of type 1 diabetes and its involvement of the entire pancreas.

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:Genetic risk variants identified in genome-wide association studies (GWAS) of complex disease are primarily non-coding, and translating risk variants into mechanistic insight requires detailed gene regulatory maps in disease-relevant cell types. Here, we combined a GWAS of type 1 diabetes (T1D) in 520,580 samples with candidate cis-regulatory elements (cCREs) in pancreas and peripheral blood mononuclear cell types defined using single nucleus ATAC-seq (snATAC-seq) of 131,554 nuclei. T1D risk variants were enriched in cCREs active in T cells and additional cell types, including acinar and ductal cells of the exocrine pancreas. Risk variants at multiple T1D signals overlapped exocrine-specific cCREs linked to genes with exocrine-specific expression. At the CFTR locus, T1D risk variant rs7795896 mapped in a ductal-specific cCRE which regulated CFTR, and the risk allele reduced transcription factor binding, enhancer activity and CFTR expression in ductal cells. These findings support a role for the exocrine pancreas in T1D pathogenesis and highlight the power of large-scale GWAS and single cell epigenomics for understanding the cellular origins of complex disease.

Project description:deBack2012 - Lineage Specification in Pancreas Development This model of two neighbouring pancreas precursor cells, describes the exocrine versus endocrine lineage specification process. To account for the tissue scale patterns, this couplet model has been extended to hundreds of coupled cells. This model is described in the article: On the role of lateral stabilization during early patterning in the pancreas de Back W., Zhou JX, Brusch L J. R. Soc. Interface 6 February 2013 vol. 10 no. 79 20120766 Abstract: The cell fate decision of multi-potent pancreatic progenitor cells between the exocrine and endocrine lineages is regulated by Notch signalling, mediated by cell–cell interactions. However, canonical models of Notch-mediated lateral inhibition cannot explain the scattered spatial distribution of endocrine cells and the cell-type ratio in the developing pancreas. Based on evidence from acinar-to-islet cell transdifferentiation in vitro, we propose that lateral stabilization, i.e. positive feedback between adjacent progenitor cells, acts in parallel with lateral inhibition to regulate pattern formation in the pancreas. A simple mathematical model of transcriptional regulation and cell–cell interaction reveals the existence of multi-stability of spatial patterns whose simultaneous occurrence causes scattering of endocrine cells in the presence of noise. The scattering pattern allows for control of the endocrine-to-exocrine cell-type ratio by modulation of lateral stabilization strength. These theoretical results suggest a previously unrecognized role for lateral stabilization in lineage specification, spatial patterning and cell-type ratio control in organ development. This model is hosted on BioModels Database and identified by: MODEL1211010000 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:NGN3 is a transcription factor whose transient expression during pancreatic development is vital for the generation of endocrine pancreatic cells, including beta cells. NGN3 stabilisation has been shown to induce exocrine-to-endocrine cell plasticity in the murine pancreas, making it a viable target for therapies aiming to replenish beta cells after immune-mediated destruction in type 1 diabetes patients. Here, we set out to identify new interactors of NGN3 that could play a role in its post-translational regulation. We transfected HEK293A cells with HA-tagged NGN3 and carried out immunoprecipitation of the HA-tag, followed by analysis of co-immunoprecipitated interactors via LC-MS/MS.

Project description:Dysbiosis of the gut microbiota has been linked to disease pathogenesis in type 1 diabetes (T1D), yet the functional consequences to the host of this dysbiosis is unknown. Here, we have performed a metaproteomic analysis of 103 stool samples from subjects that either had recent-onset T1D, were high-risk autoantibody positive or low-risk autoantibody negative relatives of individuals with beta cell autoimmunity or healthy individuals to identify signatures in host and microbial proteins associated with disease risk. Multivariate modelling analysis demonstrated that both human host proteins and microbial derived proteins could be used to differentiate new-onset and seropositive individuals from low-risk and healthy controls. Significant alterations were identified between subjects with T1D or islet autoimmunity versus autoantibody negative and control subjects in the prevalence of individual host proteins associated with exocrine pancreas function, inflammation and mucosal function. Data integrationIntegrative analysis combining the metaproteomic data with bacterial abundance showed that taxa that were depleted in new-onset T1D patients were positively associated with host proteins involved in maintaining function of the mucous barrier, microvilli adhesion and exocrine pancreas. These data support the notion that T1D patients have increased intestinal inflammation and decreased barrier function. They also confirmed that pancreatic exocrine dysfunction occurs in new-onset T1D patients and show for the first time that this dysfunction is present in high-risk individuals prior to disease onset. Our data has identified a unique T1D-associated signature in stool that may be useful as a means to monitor disease progression or response to therapies aimed at restoring a healthy microbiota.

Project description:Several miRNAs have tissue-specific patterns consistent with crucial functions in many biological processes and are candidate biomarkers of disease. Yet, there is limited knowledge about the role of pancreas-specific miRNAs in pancreatic pathologies. Here, we show that miR-216a is a conserved, pancreas-specific miRNA with important roles in pancreatic islet and acinar cells. By profiling miRNAs from human islets and subsequent systematic tissue analysis we found that miR-216a is highly enriched in endocrine and exocrine pancreas. Deletion of miR-216a in mice lead to a reduction in islet size, β-cell mass and insulin levels. RNA-sequencing indicated that cell cycle and proliferation were the most significantly regulated biological processes in miR-216 knockout pancreata. miR-216a was induced by TGF-β signalling and inhibition of miR-216a increased apoptosis and decreased cell proliferation in both β- and exocrine cells. Deletion of miR-216a in the pancreatic cancer prone mouse line Kras G12D ;Ptf1a CreER reduced the propensity of pancreatic cancer precursor lesions. Notably, circulating miR-216a levels were elevated in both mice and humans with pancreatic cancer. Collectively, our study gives insights into how β-cell mass and acinar cell growth are modulated by a pancreas-specific miRNA but also suggests miR-216a as a promising biomarker for diagnosis of pancreatic diseases.

Project description:Several miRNAs have tissue-specific patterns consistent with crucial functions in many biological processes and are candidate biomarkers of disease. Yet, there is limited knowledge about the role of pancreas-specific miRNAs in pancreatic pathologies. Here, we show that miR-216a is a conserved, pancreas-specific miRNA with important roles in pancreatic islet and acinar cells. By profiling miRNAs from human islets and subsequent systematic tissue analysis we found that miR-216a is highly enriched in endocrine and exocrine pancreas. Deletion of miR-216a in mice lead to a reduction in islet size, β-cell mass and insulin levels. RNA-sequencing indicated that cell cycle and proliferation were the most significantly regulated biological processes in miR-216 knockout pancreata. miR-216a was induced by TGF-β signalling and inhibition of miR-216a increased apoptosis and decreased cell proliferation in both β- and exocrine cells. Deletion of miR-216a in the pancreatic cancer prone mouse line Kras G12D ;Ptf1a CreER reduced the propensity of pancreatic cancer precursor lesions. Notably, circulating miR-216a levels were elevated in both mice and humans with pancreatic cancer. Collectively, our study gives insights into how β-cell mass and acinar cell growth are modulated by a pancreas-specific miRNA but also suggests miR-216a as a promising biomarker for diagnosis of pancreatic diseases.

Project description:Stem and progenitor cells in the adult human pancreas provide an under-explored resource for regenerative medicine. Using micro-manipulation and methylcellulose-containing colony/organoid assays, we identified cells within the human cadaveric exocrine pancreas that fulfill the definition of a stem cell: able to self-renew and differentiate. Exocrine tissues were collected after the isolation of endocrine cells, dissociated into single cells, and plated into a 3-dimensional semisolid medium. We found that some pancreatic ductal cells gave rise to cystic colonies/organoids containing pancreatic duct, acinar, and endocrine lineage cells. These cells self-renewed and expanded approximately 300-fold over 9 weeks. When transplanted into diabetic mice, colonies/organoids lowered blood glucose levels and gave rise to insulin-expressing endocrine cells. Thus, stem/progenitor-like cells capable of self-renewal and differentiation either preexist in the adult human pancreas or readily adapt in culture. These human cells have implications for therapy in diabetes patients.

Project description:MafA and MafB transcription factors have been shown to be key regulators of insulin and glucagon transcription. MafB is essential for alpha and beta cell differentiation, as MafB deficient mice produced fewer insulin+ and glucagon+ cells during development, with MafA expressed in remaining insulin+ cells. In contrast, beta cell development was reported to be normal in a total MafA knock out, although the animals developed beta cell dysfunction and diabetes as adults. However, we have found that MafB expression is elevated during development and retained in adult insulin+ cells after conditional removal of MafA in the pancreas. These studies will evaluate the broader significance of these insulin and glucagon regulators in alpha and beta cell development and function. Our efforts will focus on determining if the concerted actions of MafA and MafB factors are significant to beta cell formation, and we specifically plan to: Determine how alpha and beta cell differentiation is affected in MafA/MafB compound mutant mice during pancreas development. cDNA microarray studies (pancchip 6.0) with wild type, MafAKO, MafB-/-, and MafAKOMafB-/- mutant E18.5 pancreata will be performed to comprehensively identify genes controlled by MafA and MafB in developing alpha and beta cells.