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EFFECTS OF EPIDERMAL GROWTH FACTOR AND DIET ON CULTURED PANCREATIC ACINAR CELLS.Demarest, Alison Sue. January 1984 (has links)
No description available.
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Effects of diet on amylase content and synthesis in cultured rat acinar cellsJustice, Jill Diane, 1963- January 1989 (has links)
To study adaptation of pancreatic amylase to diet, an affinity adsorbent, alpha-GHI-AH-Sepharose 4B, was used to determine amylase synthesis in cultured pancreatic acinar cells. This adsorbent exhibited a consistent binding capacity and was specific for amylase. Acinar cells from rats fed high fat (HF) or carbohydrate (HC) diets for 7 d were cultured 1-48 h in serum-free medium. Amylase activity remained significantly higher in HC cells than in HF cells through 24 h in culture, despite its decrease with time in culture. The relative synthesis of amylase (3H-phe amylase/3H-phe total protein x 100) was significantly higher in HC than in HF cells at isolation and remained higher during culture. These results demonstrate that this affinity adsorbent can be used to determine amylase synthesis and suggest that the effect of diet on amylase activity and relative synthesis persists in cultured pancreatic acinar cells.
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Cell therapy for Type 1 diabetesMarques de Lima, Maria João January 2013 (has links)
Type 1 diabetes (T1D) is a chronic disease, characterised by the destruction of pancreatic beta cells, which results in lack of insulin expression. Most current therapies rely on the exogenous administration of recombinant insulin. Islet transplantation has been shown to be a more effective alternative treatment, but it is also limited by the lack of available islets for transplantation. The recently awarded work of Yamanaka and colleagues has shown that fully differentiated cells can be reprogrammed towards their pluripotent, undifferentiated state, through overexpression of a simple combination of four key transcritption factors (TFs). The studies presented in this thesis sought to investigate whether a combination of a small group of key pancreatic TFs would be able to drive both mouse embryonic stem cells (mES) and fully differentiated rat and human acinar cells of the pancreas towards insulin-producing cells. When administered in a timely manner to mES cells, the pancreatic TFs Pdx1 and MafA were able to induce the formation of cells that synthesised insulin de novo. Further studies aimed at investigating if a small number of TFs would be able to reprogramme the exocrine pancreatic cells towards insulin expressing cells, since, unlike endocrine cells, exocrine cells are highly abundant in the pancreas. Studies performed in both a rat exocrine cell line (AR42J-B13) and in human exocrine cells demonstrated that the combination of the TFs Pdx1, MafA, Ngn3 and Pax4 was able to generate glucose responsive β-like cells in both models. In addition, Pax4 was found to be determinant for the functionality of the generated β-cells. The functionality of these cells was further demonstrated by their ability to prevent the onset of hyperglycemia upon transplantation into a diabetic mouse model. The work presented in this thesis has shown that cultured exocrine cells may be a promising alternative for generating a replenishable supply of β-cells for transplantation.
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Temporal and spatial Ca'2'+ signals in pancreatic acinar cellsLawrie, Alison M. January 1994 (has links)
No description available.
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Effects of fractionated irradiation on salivary glandsFranzén, Lars January 1992 (has links)
The thesis is a study of the effects of radiation on the salivary glands in an experimental and a clinical study. Irradiation is a cornerstone in the management of head and neck cancer and is as other modalities of cancer treatment, afflicted with adverse reactions. An optimal radiotherapy regime is limited by the sensitivity of the normal tissues with regard to early and late effects. In certain cases the early effects can be so troublesome that it will cause interruption in the irradiation and questioning of the curative intention. Although DNA is the lethal target, other parts of the cell have been proposed as sensitive targets to irradiation. Different in vitro secretory models and quantitative morphological characterization and immunohistochemical evaluation of neuropeptides were performed in rat salivary glands after irradiation. The irradiation was given unilaterally or bilaterally once a day for a five-day schedule with 6 MV photons (total dose 20, 30, 35, 40, 45 Gy) or a two fractions regime in five days with a total dose of 24 or 32 Gy. The contralateral gland served as a control for unilaterally treated animals and parallel analyses were done 10 days or 180 days following the last irradiation dose. An early, dose-dependent effect of fractionated irradiation on noradrenaline-stimulated potassium fluxes (86Rb+ fluxes) was demonstrated. In contrast, the exocytotic amylase release displayed no obvious alterations, and morphologically no changes were seen. Regarding late effects (180 days) the noradrenaline-stimulated electrolyte secretion was decreased at least for the higher doses of irradiation. Amylase content and loss of acini was also dose-dependently decreased. At 10 days after bilateral irradiation there was a marked increase in the expression of the neuropeptides substance P, leu-enkephalin and bombesin in the ganglionic cells associated with the submandibular glands and in nerve fibers of the glandular parenchyme. In addition, a clinical prospective evaluation of 25 patients was performed before, during radiotherapy and 6, 12 and 18 months after the end of treatment. A great interindividual variation in the recovery was demonstrated with regard to salivary flow rate. Irradiation doses about 40-50 Gy caused generally reversible changes; sometimes salivary secretion was almost completely restored 6-18 months after the end of radiotherapy. Doses exceeding 65 Gy induced almost irreversible alterations. Even if DNA is the target for the lethal effect of irradiation, other constituents, such as the cell membrane or neuropeptide expression can be significantly affected by irradiation and cause important physiological changes. / <p>S. 1-43: sammanfattning, s. 47-164: 6 uppsatser</p> / digitalisering@umu
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Elucidating the Regulation of Pancreatic Acinar to Ductal MetaplasiaLi, Alina Lin January 2024 (has links)
Pancreatic ductal adenocarcinoma (PDAC) is the 3rd deadliest cancer in the United States with a projected 12% 5-year survival rate. Acinar cells have been proposed as a potential cell-of-origin for PDAC after undergoing acinar to ductal metaplasia (ADM). In the absence of oncogenic mutations (e.g. Kras), ADM lesions form as an adaptive response and eventually resolve to regenerate the acinar compartment, which we term as adaptive ADM. However, in the presence of oncogenic Kras mutations, the ADM lesions can transform to a pre-invasive state called pancreatic intraepithelial neoplasia (PanIN). Thus, a normally adaptive metaplastic response becomes maladaptive, which we term as oncogenic ADM. The mechanisms that drive PanIN formation in the context of injury and oncogenic mutations are poorly understood, resulting in an absence of targets to combat persistent ADM.
This thesis investigates the role of FRA1 (gene name Fosl1) in acinar cell de-differentiation, PanIN transformation, and eventual PDAC tumorigenesis. Through CUT&RUN sequencing of mice undergoing recovery from caerulein-induced acute pancreatitis, we identify FRA1 as the most active transcription factor during KrasG12D mediated acute pancreatitis- mediated injury. We have elucidated a functional role of FRA1 by generating an acinar-specific Fosl1 knockout mouse expressing KrasG12D. Using a gene regulatory network and pseudotime trajectory inferred from single nuclei ATAC-seq and bulk-RNA seq, we hypothesize a regulatory model of the acinar-ADM-PanIN continuum and experimentally validate that Fosl1 knockout mice are delayed in the onset of ADM and PanIN.
Furthermore, deletion of Fosl1 in an autochthonous PDAC mouse model revealed that this ADM-initiated delay eventually culminates in a significant survival advantage and a less aggressive tumor phenotype. Through investigation of upstream regulators of FRA1, we identified G-CSF as an ADM-promoting cytokine. Fosl1 depletion prevented the pro-inflammatory effects of G-CSF, indicating that the G-CSF/FRA1 signaling axis can modulate ADM. Using ex vivo acinar cultures, we also showed that G-CSF can induce FRA1 through MEK/ERK signaling. Our findings reveal that FRA1 is a mediator of acinar cell plasticity and contributes to acinar cell de-differentiation and malignant transformation.
Although the majority of this thesis focuses on oncogenic ADM, we also include a chapter on the role of Prrx1 in adaptive ADM. Our comprehensive and unbiased approach identified previously the Paired-Related homebox1 (Prrx1) as the most upregulated transcription factor in the intersection of pancreatic ductal development, regeneration, and evolution of PanIN. We have demonstrated previously that Prrx1 can promote a ductal phenotype by binding the Sox9 promotor and inducing its expression during pancreatitis. In this body of work, we present a novel mechanism by which Prrx1 regulates maintenance of adaptive ADM. Using novel mouse models and ex vivo acinar culture systems, we demonstrate that Prrx1 can induce TGFβ signaling and reduce E-Cadherin expression to promote ADM. We do not know if there is any potential epistatic interaction between FRA1 and PRXX1.
Overall, we reveal the rippling effects of FRA1 can have during the early stages of pre-neoplasia, and we unveil an alternative function of PRRX1 for stimulating an adaptive response to stress. This thesis presents a new understanding of how acinar cell de-differentiation occurs in the pancreas by revealing novel roles of two transcription factors, FRA1 and PRRX1, and furthers our understanding of tissue regeneration in an injured pancreas.
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Regulation of receptor-mediated phosphatidylinositol hydrolysis in AR42J rat carcinoma cellsSiwik, Steven Anthony, 1963- January 1989 (has links)
Receptor-activated phosphatidylinositol (PtdIns) hydrolysis was examined in AR42J rat pancreatic acini. Cholecystokinin-octapeptide (CCK₈) and bombesin induced a dose-dependent accumulation of [³H] inositol monophosphate ([³H]InsP₁). Manganese (Mn²⁺), a known calcium channel blocker, did not alter basal PtdIns hydrolysis. In contrast, when added 5 minutes prior to the addition of agonists for 60 minutes, Mn²⁺ markedly inhibited secretagogue-mediated [³H]InsP1 formation. Mn²⁺ also attenuated the CCK₈-mediated increase in biologically active inositol 1,4,5-trisphosphate and inositol 1,3,4,5-tetrakisphosphate. These inhibitory effects of Mn²⁺ were mimicked by lanthanum and by EGTA. Addition of calcium to EGTA-treated cells abolished the inhibitory effects of extracellular calcium depletion. Mn²⁺, La³⁺ and EGTA exerted similar inhibitory effects on PtdIns hydrolysis in pancreatic acini. These findings suggest that receptor-activated calcium influx is required for full activation of the CCK₈-mediated signal transduction pathway that is coupled to PtdIns hydrolysis.
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The embryonic epidermis of Xenopus tropialis: developing a model system for the study of mucociliary epitheliaDubaissi, Eamon January 2011 (has links)
Mucociliary epithelia are found in the human airways and act as the first line of defence against inhaled foreign agents. Mucus traps potentially damaging particles and the cilia transport the mucus away from the airways to remove the threat. Modelling mucociliary epithelia for research purposes is challenging. This is because the airways are enclosed and are thus difficult to study directly. Instead, tissue is extracted or in vitro techniques are employed. Whilst these systems are useful, there is a need for accessible in vivo models to complement them. In this thesis I assess a new model system for studying mucociliary epithelia. This system is the larval epidermis of the amphibian, Xenopus tropicalis. Its epidermis comprises multi-ciliated cells that beat in a polarised direction reminiscent of those found in the human airways. It is also proposed to have a number of other cell types including mucus-secreting cells, but very little is known about them. The epidermis is open and accessible to manipulation meaning that it has great potential to be used in the study of mucociliary epithelia in live, native conditions. Such a system would be a valuable addition to the current models employed. However, the epidermis has not been thoroughly characterized before so its utility as a model system remains speculative.To develop and evaluate this new model, I fully characterize the epidermis, showing that it has five distinguishable cell types. This includes a population of cells called ionocytes that are shown to be essential for the health and function of the epidermis. I also test for the presence of mucins, the structural component of mucus, secreted from the epidermis in order to evaluate the proposal that mucus-secreting cells are present in the epidermis. A mucin-like protein called otogelin is identified. After characterizing the epidermal cell types, I compare them to the human mucociliary epithelium and consider potential applications and future perspectives for this model.
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Confidentiel / ConfidentielNapolitano, Tiziana 19 December 2017 (has links)
Confidentiel / Confidentiel
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Understanding the Role of Hypusine Biosynthesis in Endocrine-Exocrine CrosstalkDale, Dorian J. 08 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Traditionally, the exocrine and endocrine cellular compartments of the pancreas have been considered distinct functional systems. However, recent studies suggest a more intricate relationship between the exocrine and endocrine, which may impact pancreatic growth and health. Additionally, translational control mechanisms have been linked to organ development. Our lab has shown that the mRNA translation factor eukaryotic initiation factor 5A (eIF5A), when in its post-translationally modified “hypusinated” form, plays a role in pancreas development. The hypusination of eIF5A requires the rate-limiting enzyme deoxyhypusine synthase (Dhps) to post- translationally modify a critical lysine residue which in turn produces the active form of eIF5A that functions in mRNA translation. When we generated animals with a deletion of Dhps in the pancreatic progenitor cells, there was no alteration in islet mass but significant exocrine insufficiency at embryonic (E) day 18.5 concomitant with downregulation of proteins required for exocrine pancreas development and function. Resultantly these animals died by 6 weeks-of-age. These observations prompted the question, is the phenotype caused by the absence of hypusinated eIF5A or the increase of unhypusinated eIF5A? To address this, we generated a mouse model wherein Eif5a is deleted in the pancreas (eIF5A∆PANC) and these mutant animals also display exocrine insufficiency. Interestingly, beta cell mass is increased at E18.5, and the mutant animals maintain euglycemia and survive up to 2 years. Ongoing analyses are interrogating the differences between these animal models with the goal to determine if mRNA translation facilitates cellular communication between the exocrine and endocrine pancreas.
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