Global ETD Search

21	NUCLEAR TRANSLOCATION OF WT1-INTERACTING PROTEIN IN RESPONSE TO PODOCYTE INJURY Rico-Salas, Maria Isabel 08 April 2005 (has links) No description available. Kidney Podocyte Glomerulus Proteinuria Dedifferentiation Plasticity Gene Expression Nuclear translocation WT-1 WTIP ZO-1 Adhesion Differentiation
22	Modulation of the Progenitor Cell and Homeostatic Capacities of Müller Glia Cells in Retina : Focus on α2-Adrenergic and Endothelin Receptor Signaling Systems Harun-Or-Rashid, Mohammad January 2016 (has links) Müller cells are major glial cells in the retina and have a broad range of functions that are vital for the retinal neurons. During retinal injury gliotic response either leads to Müller cell dedifferentiation and formation of a retinal progenitor or to maintenance of mature Müller cell functions. The overall aim of this thesis was to investigate the intra- and extracellular signaling of Müller cells, to understand how Müller cells communicate during an injury and how their properties can be regulated after injury. Focus has been on the α2-adrenergic receptor (α2-ADR) and endothelin receptor (EDNR)-induced modulation of Müller cell-properties after injury. The results show that α2-ADR stimulation by brimonidine (BMD) triggers Src-kinase mediated ligand-dependent and ligand-independent transactivation of epidermal growth factor receptor (EGFR) in both chicken and human Müller cells. The effects of this transactivation in injured retina attenuate injury-induced activation and dedifferentiation of Müller cells by attenuating injury-induced ERK signaling. The attenuation was concomitant with a synergistic up-regulation of negative ERK- and RTK-feedback regulators during injury. The data suggest that adrenergic stress-signals modulate glial responses during retinal injury and that α2-ADR pharmacology can be used to modulate glial injury-response. We studied the effects of this attenuation of Müller cell dedifferentiation on injured retina from the perspective of neuroprotection. We analyzed retinal ganglion cell (RGC) survival after α2-ADR stimulation of excitotoxically injured chicken retina and our results show that α2-ADR stimulation protects RGCs against the excitotoxic injury. We propose that α2-ADR-induced protection of RGCs in injured retina is due to enhancing the attenuation of the glial injury response and to sustaining mature glial functions. Moreover, we studied endothelin-induced intracellular signaling in Müller cells and our results show that stimulation of EDNRB transactivates EGFR in Müller cells in a similar way as seen after α2-ADR stimulation. These results outline a mechanism of how injury-induced endothelins may modulate the gliotic responses of Müller cells. The results obtained in this thesis are pivotal and provide new insights into glial functions, thereby uncovering possibilities to target Müller cells by designing neuroprotective treatments of retinal degenerative diseases or acute retinal injury. Alpha2-adrenergic receptor Brimonidine Brn3a Dedifferentiation Endothelin EGFR ERK1/2 Neuroprotection NMDA MIO-M1 human Müller cell Müller cells Retina Retinal ganglion cells Src-kinase Transactivation.
23	La semicarbazide-sensitive amine oxydase : son rôle dans la différenciation cellulaire des chondrocytes et des cellules musculaires lisses vasculaires et son implication dans des pathologies articulaires et cardiovasculaires / Semicarbazide-sensitive amine oxidase : its role in cell differentiation of chondrocytes and vascular smooth muscle cells and its involvement in joint and cardiovascular diseases Filip, Anna 10 December 2014 (has links) La « semicarbazide-sensitive amine oxidase » (SSAO) catalyse la déamination oxydative des amines primaires en aldéhyde, peroxyde d’hydrogène et ammoniac. Elle participe à la différenciation cellulaires, l’inflammation et la transmigration leucocytaire à travers l’endothélium lymphatique. Nos objectifs ont été d’étudier le rôle de la SSAO (i) dans la différenciation chondrocytaire hypertrophique, en relation avec le développement de l’arthrose en utilisant des chondrocytes de rat en culture primaire et des genoux arthrosiques de patients (ii) dans le développement de l’athérosclérose en invalidant des souris ApoE-/- qui développent naturellement l’athérosclérose pour le gène de la SSAO. Au niveau articulaire, la SSAO a été détectée dans le cartilage de rat et humain. In vitro, la SSAO (activité et expression) augmentent au cours de la différenciation terminale de chondrocytes de rat. Son inhibition par le LJP1586 entraîne un retard de différenciation chondrocytaire. La SSAO augmente également dans les zones arthrosiques du cartilage humain parallèlement à l’augmentation de l’hypertrophie. La SSAO jouerait donc un rôle dans la différenciation terminale des chondrocytes (hypertrophie) possiblement via le transport de glucose et dans le développement de la maladie. Au niveau vasculaire, les souris femelles ApoE-/-SSAO-/- de 25 semaines présentent une augmentation de la surface des plaques d’athérome par rapport aux ApoE-/-. Ceci est associée à une diminution de l’expression d’α-actine dans le média sous les plaques et de smMHC dans l’aorte abdominale (AA) sans modification ni de l’infiltration des lymphocytes T; ni des monocytes/ macrophages dans la paroi artérielle, ni du profil cytokinique pro-/anti-inflammatoire dans la rate. A 15 semaines, les souris femelles ApoE-/-SSAO-/-, sm-MHC a diminué dans les AA de ces souris par rapport aux ApoE-/- ainsi qu’une réorientation du trafic des cellules immunitaires vers la paroi aortique sans modification significative de la surface des plaques a été détecté. La SSAO jouerait donc un rôle précoce dans le développement de l’athérosclérose via une modification du trafic des cellules immunitaires et du phénotype des CML dans la paroi / The semicarbazide-sensitive amine oxidase (SSAO) catalyzes the oxidative deamination of primary amines into aldehydes, hydrogen peroxide and ammonia. The SSAO was implicated in cellular differentiation, inflammation and transmigration of leukocyte through the lymphatic. The objectives of this work were to study the role of SSAO (i) in chondrocyte differentiation and in the development of osteoarthritis using rat chondrocyte primary cell culture and osteroarthritic samples from patients. (ii) in the development of atherosclerosis using ApoE-/- mice, which develop naturally atherosclerosis, invalidated for the SSAO gene. Concerning the articulation, the SSAO (expression and activity) was detected in the rat and human cartilage. In vitro, SSAO increases during chondrocyte terminal differentiation (hypertrophy) and the inhibition of its activity by LJP1586, decreases the level of differentiation. In human arthritic cartilage, SSAO was higher that in healthy cartilage, in association with an increase in hypertrophic markers. The SSAO plays a role in the terminal differentiation of chondrocytes and might be involved in the development of osteoarthritis. At the vascular level, 25 week-old female ApoE-/-SSAO-/- mice presented a 50% increase in plaque surface associated with an 80% decrease in α-actin expression in the media of aortic sinus and a decrease in sm-MCH in abdominal aortas (AA) compared to ApoE-/- mice. These results were not due neither to a modification of monocytes/ macrophages, Tcell infiltration in the plaque nor in a pro- or anti-inflammatory cytokine change in spleen. In 15 week-old ApoE-/-SSAO-/- mice, even if no modification of plaque surface was found, a decrease in sm-MHC was noticed in the AA from ApoE-/-SSAO-/- compare to ApoE-/- mice. More over, the immune cell trafficking was increased in the aortic wall of ApoE-/-SSAO-/- compared to ApoE-/- mice. Thus, SSAO is involved in the early development of atherosclerosis in changing the immune cell trafficking and the VSMC phenotype SSAO/VAP-1 Hypertrophie chondrocytaire Arthrose Athérosclérose SSAO/VAP-1 Cellular differentiation Chondrocyte Osteoarthritis Atherosclerosis 612.015 572.36 547.04
24	Einfluss von all-trans-Retinsäure (ATRA) auf die Expression von Differenzierungsmarkern bei humanen Mastzellen unterschiedlicher Reifegrade Thienemann, Friedrich 07 August 2006 (has links) Mastzellen (MZ) reifen zu terminal differenzierten Zellen erst in peripheren Geweben. ATRA ist ein wesentlicher Regulator der Hämatopoese und kann auf positive wie auf negative Weise deren Differenzierung beeinflussen – die Qualität ist dabei häufig abhängig vom Reifegrad. Die Arbeit beschäftigte sich daher mit der Frage, ob die Effekte von ATRA auf MZ ebenfalls abhängig von deren Reifegrad sind. Unreife HMC-1 5C6 Zellen, differenziertere LAD 2 Zellen und reife kutane MZ (KMZ) wurden mit ATRA behandelt und die Effekte auf spezifische Mastzellmarker auf Protein- und mRNA-Ebene untersucht. Die Proteinexpression von c-kit, FceRI, Tryptase und Chymase wurde bei allen drei Zellsystemen herunterreguliert. Änderungen der Proteinexpression wurden qualitativ, wenngleich nicht immer quantitativ auf mRNA-Ebene reflektiert, d.h. es gab Marker, bei denen die Herunterregulation auf der einen oder anderen Ebene überwog. Eine genaue Quantifizierung der ATRA-Effekte auf die Tryptase und Chymase zeigte eine prozentual erheblich stärkere Herunterregulation der mRNA als des Proteins. Invers dazu war der Effekt bei c-kit, ein Effekt, der besonders deutlich bei HMC-1 5C6 auszumachen war. Zur Klärung, welcher Mechanismus der von der mRNA-Ebene unabhängigen Herunterregulation des c-kit-Proteins zugrunde liegt, wurden HMC-1 5C6 zusätzlich zu ATRA mit Inhibitoren fundamentaler Zellfunktionen inkubiert. Cycloheximid allein war dabei in der Lage, die Wirkung von ATRA zu imitieren. Es kann also vermutet werden, dass die starke Herunterregulation des Proteins im Vergleich zur mRNA einem translationellen Mechanismus folgt. Betrachtet man alle Effekte gemeinsam, so zeigte ATRA den stärksten Einfluss auf das am weitesten differenzierte Mastzellsystem, nämlich KMZ. Geringer waren die Effekte bei LAD 2, wohingegen bei HMC-1 5C6 das schwächste Ansprechpotential gegenüber ATRA gefunden wurde. Dies ist von besonderem Interesse, weil ATRA normalerweise wesentlich potenter auf unreif-proliferierende Systeme wirkt. ATRA hat auf humane MZ einen deutlich dedifferenzierenden Effekt, der weitgehend unabhängig vom Reifegrad der Zellen operiert. Die Effekte scheinen dabei in Abhängigkeit vom betrachteten Marker nicht auf die transkriptionelle Ebene beschränkt zu sein, sondern könnten auch einem translationellen Mechanismus unterliegen. / Mast cells (MC) are of hematopoietic origin but complete their differentiation exclusively within tissues. A large number of mediators positively or negatively affect the maturation process of MC. ATRA is a potential master regulator of haematopoiesis, where it primarily affects immature and proliferative leukocytes. Here, the effects of ATRA (3-7d) on MC that span different stages of maturation, i. e. immature-leukemic HMC-1 5C6 cells, intermediately matured LAD 2 cells, and terminally differentiated skin MC were analyzed. The expression of the lineage markers c-kit, FceRI, tryptase, chymase und histidindecarboxylase (HDC) was studied in parallel at protein level by flow-cytometric analysis and at mRNA level by RT-PCR. ATRA exposure led to a down-regulation at protein and at mRNA level of c-kit, FceRI, tryptase and chymase by all MC subtypes. Comparing protein and transcript levels, however, substantial differences between c-kit and the proteases were noted. c-kit down-regulation was more pronounced at protein level, whereas the opposite was found with proteases. Further analysis revealed the existence of a second mechanism of c-kit down modulation that proceeded rapidly and independently of mRNA changes. This pathway was restricted to immature MC and could be mimicked by cycloheximide, suggesting that altered translation may account for the phenomenon. Taken together, the study indicates that MC are significant target cells of ATRA throughout their lifespan, but that the molecular events underlying down-regulation of lineage markers may be shifted in the course of MC differentiation. The strongest effects of ATRA were observed in mature MC, while this accounts to a lesser degree for LAD 2 cells. In contrast, the immature and highly proliferating HMC-1 5C6 cells presented even less sensitive to ATRA. Therefore, ATRA has dedifferentiating potential towards human MC that is most pronounced in mature MC. Depending on the specific marker, protein down regulation can underlie various mechanisms. In this regard, c-kit seems to follow a translational rather than transcriptional inhibitory process. Mastzelle Dedifferenzierung Vitamin A Retinoide retinoic acid mast cell dedifferentiation vitamin A 610 Medizin 33 Medizin XG 9304 XG 9322 YF 2104 YF 2114 YF 2122 ddc:610
25	Individual and age-related differences in face-cognition Hildebrandt, Andrea 01 September 2010 (has links) Experimentelle und neurophysiologische Studien weisen auf eine Spezifität der Gesichterkognition hin. In der differentiellen Psychologie wird ein Schwerpunkt auf die Differenzierbarkeit sozio-kognitiver Leistungen von akademischen Fähigkeiten gelegt. Dabei werden bislang kaum Versuche unternommen, Messmodelle zu etablieren, die in neurokognitiven Modellen verankert sind. Basierend auf neuartigen Versuchen zur Etablierung solcher Modelle ist es das Ziel dieser Dissertation, die Robustheit dieser Modelle aus einer entwicklungspsychologischen Perspektive zu betrachten und diese zu erweitern. Zudem werden altersbedingte Leistungsunterschiede in der Gesichterkognition auf der Ebene latenter Faktoren ermittelt und die Hypothese altersbedingter kognitiver Dedifferenzierung mit modernen Methoden kritisch untersucht. Das Hauptziel ist die Erbringung entwicklungspsychologischer Evidenz für die Spezifität der Gesichterkognition. In einem ersten - primär methodologischen - Manuskript wird erstmalig in der Literatur die Implementierung von Funktionen der Beobachtungsgewichtung aus der nicht-parametrischen Regression für Strukturgleichungsanalysen vorgeschlagen. Diese Methode ergänzt Multigruppenanalysen bei der Untersuchung kognitiver Dedifferenzierung. Weitere vier Manuskripte adressieren Fragestellungen zur Gesichterkognition und zeigen: 1) Gesichterwahrnehmung, Gesichtergedächtnis und die Schnelligkeit der Gesichtererkennung sind separierbare Prozesse über die gesamte erwachsene Lebensspanne; 2) die Schnelligkeit der Gesichtererkennung kann nicht von der Schnelligkeit der Emotions- und Objekterkennung faktoriell getrennt werden; 3) Gesichterwahrnehmung und Gesichtergedächtnis können bis zum späten Alter von allgemeinen kognitiven Fähigkeiten getrennt werden, und 4) eine leichte Dedifferenzierung zwischen Objekt- und Gesichterkognition tritt auf der Ebene von Akkuratheitsmessungen auf. Implikationen sind in den Manuskripten ausführlich diskutiert und im Epilog zusammengefasst. / Cognitive-experimental and neuropsychological studies provided strong evidence for the specificity of face cognition. In individual differences research, face tasks are used within a broader variety of tasks, usually with the intention to measure some social skills. Contemporary individual differences research still focuses on the distinction between social-emotional vs. academic intelligence, rather than establishing measurement models with a solid basis in experimental and neuropsychological work. Building upon recent efforts to establish such measurement models this dissertation aimed to extend available models and assess their robustness across age. Furthermore, it investigates mean age differences for latent factors, critically looks at phenomena of dedifferentiation with novel and innovative analytic methods, and attempts to provide more evidence on the uniqueness and communalities of face cognition throughout adulthood. In a first primarily methodological manuscript, we propose for the first time in the literature an implementation of functions to weight observations used in nonparametric regression approaches into structural equation modeling context, which can fruitfully complement traditionally used multiple-group approaches to investigate factorial dedifferentiation. In the following four manuscripts, we investigated individual and age-differences in face cognition. Results show that: 1). Face perception, face memory and the speed of face cognition remain differentiable throughout adulthood; 2). The speed of face cognition is not differentiable from the speed of perceiving emotional expressions in the face and complex objects, like houses; 3). Face perception and memory are clearly differentiable from abstract cognition throughout adulthood; and 4). A slight dedifferentiation occurs between face and object cognition. Implications are discussed in the manuscripts and the epilogue. Dedifferenzierung Gesichterkognition Altersunterschiede Lokal-Gewichtete Strukturmodelle Face cognition Age-related differences Dedifferentiation Local Structural Equation Models 150 Psychologie 11 Psychologie ddc:150
26	Regulatory Effects of TGF-β Superfamily Members on Normal and Neoplastic Thyroid Epithelial Cells Franzén, Åsa January 2002 (has links) <p>Thyroid growth and function is partly regulated by growth factors binding to receptors on the cell surface. In the present thesis, the transforming growth factor-β (TGF-β) superfamily members have been studied for their role in regulation of growth and differentiation of both normal and neoplastic thyroid epithelial cells.</p><p>TGF-β1 is a negative regulator of thyrocyte growth and function. However, the importance of other TGF-β superfamily members has not been fully investigated. TGF-β1, activin A, bone morphogenetic protein (BMP)-7 and their receptors were found to be expressed in porcine thyrocytes. In addition to TGF-β1, activin A was also found to be a negative regulator of thyroid growth and function, and both stimulated phosphorylation and nuclear translocation of Smad proteins. Furthermore, TGF-β1 and epidermal growth factor (EGF) demonstrated a synergistic negative effect on thyrocyte differentiation. Simultaneous addition of the two factors resulted in a loss of the transepithelial resistance and expression of the epithelial marker E-cadherin. This was followed by a transient expression of N-cadherin.</p><p>Despite the extremely malignant character of anaplastic thyroid carcinoma (ATC) tumor cells, established cell lines are still responsive to TGF-β1. A majority of the cell lines were also found to be growth inhibited by BMP-7. BMP-7 induced cell cycle arrest of the ATC cell line HTh 74 in a dose- and cell density-dependent manner. This was associated with upregulation of p21<sup>CIP1</sup> and p27<sup>KIP1</sup>, decreased cyclin-dependent kinase (Cdk) activity and hypophosphorylation of the retinoblastoma protein (pRb). TGF-β1, and to some extent also BMP-7, induced the expression of N-cadherin and matrix metalloproteinase (MMP)-2 and -9. Stimulation of HTh 74 cells with TGF-β1 increased the migration through a reconstituted basement membrane indicating an increased invasive phenotype of the cells.</p><p>Taken together, these data show that TGF-β superfamily members not only affect growth and function of normal thyroid follicle cells but may also, in combination with EGF, play a role in cell dedifferentiation. This study additionally suggests that the TGF-β superfamily members may be important for the invasive properties of ATC cells.</p> Genetics activin BMP cadherin carcinoma cell cycle arrest dedifferentiation EGF growth inhibition invasion Smad TGF-β thyroid Genetik Clinical genetics Klinisk genetik
27	Regulatory Effects of TGF-β Superfamily Members on Normal and Neoplastic Thyroid Epithelial Cells Franzén, Åsa January 2002 (has links) Thyroid growth and function is partly regulated by growth factors binding to receptors on the cell surface. In the present thesis, the transforming growth factor-β (TGF-β) superfamily members have been studied for their role in regulation of growth and differentiation of both normal and neoplastic thyroid epithelial cells. TGF-β1 is a negative regulator of thyrocyte growth and function. However, the importance of other TGF-β superfamily members has not been fully investigated. TGF-β1, activin A, bone morphogenetic protein (BMP)-7 and their receptors were found to be expressed in porcine thyrocytes. In addition to TGF-β1, activin A was also found to be a negative regulator of thyroid growth and function, and both stimulated phosphorylation and nuclear translocation of Smad proteins. Furthermore, TGF-β1 and epidermal growth factor (EGF) demonstrated a synergistic negative effect on thyrocyte differentiation. Simultaneous addition of the two factors resulted in a loss of the transepithelial resistance and expression of the epithelial marker E-cadherin. This was followed by a transient expression of N-cadherin. Despite the extremely malignant character of anaplastic thyroid carcinoma (ATC) tumor cells, established cell lines are still responsive to TGF-β1. A majority of the cell lines were also found to be growth inhibited by BMP-7. BMP-7 induced cell cycle arrest of the ATC cell line HTh 74 in a dose- and cell density-dependent manner. This was associated with upregulation of p21CIP1 and p27KIP1, decreased cyclin-dependent kinase (Cdk) activity and hypophosphorylation of the retinoblastoma protein (pRb). TGF-β1, and to some extent also BMP-7, induced the expression of N-cadherin and matrix metalloproteinase (MMP)-2 and -9. Stimulation of HTh 74 cells with TGF-β1 increased the migration through a reconstituted basement membrane indicating an increased invasive phenotype of the cells. Taken together, these data show that TGF-β superfamily members not only affect growth and function of normal thyroid follicle cells but may also, in combination with EGF, play a role in cell dedifferentiation. This study additionally suggests that the TGF-β superfamily members may be important for the invasive properties of ATC cells. Genetics activin BMP cadherin carcinoma cell cycle arrest dedifferentiation EGF growth inhibition invasion Smad TGF-β thyroid Genetik Clinical genetics Klinisk genetik
28	Studying the Molecular Mechanisms for Generating Progenitor Cells during Tail Regeneration in Ambystoma mexicanum / Studien der molekularen Mechanismen zur Herstellung von Vorläuferzellen während der Schwanzregeneration in Ambystoma mexicanum Schnapp, Esther 10 May 2005 (has links) (PDF) The present thesis is a contribution to unravel the molecular mechanisms that underlie urodele regeneration. Urodele amphibians (newts and salamanders) are among the few vertebrates with the remarkable ability to regenerate lost body appendages, like the limbs and the tail. Urodele tail and limb regeneration occurs via blastemal epimorphic regeneration. A blastema is a mound of progenitor cells that accumulates at the amputation plane and eventually gives rise to the missing structures. It is known today that dedifferentiating muscle fibers at the amputation plane contribute to the blastema cell pool, but how this process occurs on the cellular and molecular level is hardly understood, which is in part due to the lack of molecular methods to test gene function in urodeles. Furthermore, little is known about how coordinated growth and patterning occurs during urodele regeneration, and if the patterning mechanisms in regeneration are related to the ones in development. The goal of this study was to better understand these processes on the molecular level. To address these questions, I first established several methods in our model systems, which are the mexican salamander Ambystoma mexicanum (axolotl) and a cell line derived from the newt Notophthalmus viridescens. In order to monitor gene expression on a cellular level during regeneration, I worked out a good in situ hybridization protocol on axolotl tissue cryosections. To be able to test gene function, I established electroporation conditions to both overexpress genes in the cultured newt cells and to deliver morpholinos into axolotl cells in vivo and newt cells in culture. I demonstrate here that morpholinos are an effective tool to downregulate protein expression in urodele cells in vivo and in culture. Testing the role of two candidate genes in muscle fiber dedifferentiation, the homeobox containing transcription factor Msx1 and Rad, a GTP-binding protein of a new Ras-related protein family, revealed that neither seems to play a major role in muscle dedifferentiation, both in culture and in vivo. In addition to testing gene function I have examined the muscle dedifferentiation process in more detail. I show here that dedifferentiating muscle fiber nuclei undergo morphological changes that are likely due to chromatin remodeling events. I also demonstrate that the axolotl spinal cord expresses embryonic dorsoventral (d/v) patterning markers of the neural tube. The transcription factors Msx1, Pax7 and Pax6 are expressed in their respective d/v domains in both the differentiated and the regenerating axolotl spinal cord. Furthermore, the secreted signaling molecule sonic hedgehog (Shh) is expressed in the floor plate in both the differentiated and the regenerating cord. Using a chemical inhibitor (cyclopamine) and an activator of the hedgehog pathway, I discovered that hedgehog signaling is required for overall tail regeneration. Blocking hedgehog signaling does not only result in d/v patterning defects of the regenerating spinal cord, but it also strongly reduces blastema cell proliferation. In addition, I identified cartilage and putative muscle progenitor cells in the blastema, marked by the expression of the transcription factors Sox9 and Pax7, respectively. Both progenitor populations are reduced in the blastema in the absence of hedgehog signaling. The continuous expression of marker genes for embryonic progenitor cell domains in the mature axolotl may be related to their ability to regenerate. Amphibien Axolotl Regeneration Blastema Sonic Hedgehog Dedifferenzierung amphibian axolotl regeneration blastema sonic hedgehog muscle dedifferentiation ddc:570 rvk:WG 3700 Axolotl Blastem Dedifferenzierung Hedgehog Regeneration
29	Pancreatic Acinar Cell Plasticity. Senescense, epitelial-mesenchymal transition and p53 Pinho, Andreia V. 14 July 2011 (has links) Pancreatic acinar cells display plasticity to acquire distinct differentiation programs, being involved in diseases as chronic pancreatitis and pancreatic ductal adenocarcinoma. This work shows that acinar cells cultured in suspension undergo dedifferentiation, acquiring a pancreatic embryonic progenitor phenotype. Dedifferentiated cells turn on a senescent program, associated with activation of p53 and Ras pathways. A similar progenitor‐like phenotype with activation of senescence is present in experimental chronic pancreatitis. Acinar cultures lacking p53 overcome growth arrest and lose the pancreatic phenotype, undergoing an epithelial‐mesenchymal transition, while maintaining the expression of pre‐pancreatic endoderm and stem cell markers. In experimental acute pancreatitis, absence of p53 results in increased acinar cell proliferation and delayed regeneration. Our findings support a role for acinar cell dedifferentiation in the initiation of pancreatic diseases. A p53‐ dependent control of cell growth and epithelial differentiation constitutes a tumor suppressive mechanism that may limit PDAC development. / Las células pancreáticas acinares poseen plasticidad que les permite adquirir distintos programas de diferenciación, estando implicadas en enfermedades como la pancreatitis crónica y el adenocarcinoma ductal pancreático. En este trabajo hemos demostrado que las células acinares cultivadas en suspensión se desdiferencian, adquiriendo un fenotipo de progenitores pancreáticos embrionarios. En estas células se induce un programa de senescencia asociado con la activación de las vías de p53 y Ras. Un fenotipo similar se evidencia en modelos de pancreatitis crónica experimental. Cultivos acinares en los que se ha inactivado p53 sobrepasan el bloqueo de crecimiento y pierden el fenotipo pancreático, presentando una transición epitelio‐mesenquimal y manteniendo la expresión de marcadores de endodermo pre‐pancreático y de células madre. Durante la inducción de una pancreatitis aguda experimental, la ausencia de p53 resulta en un incremento de la proliferación acinar y en un retraso en la regeneración. Nuestros resultados demuestran que la desdiferenciación de las células acinares participa en el desarrollo de enfermedades pancreáticas. El control del crecimiento celular y de la diferenciación pancreática epitelial dependiente de p53 constituye un mecanismo de supresión tumoral que puede limitar el desarrollo del PDAC. Pancreatic acinar cells chronic pancreatitis dedifferentiation epithelial‐mesenchymal transition p53 Células pancreáticas acinares adenocarcinoma ductal pancreático pancreatitis crónica transición epitelio‐mesenquimal senescencia 57
30	Molecular Characterization of Early Dedifferentiation in Newt Forelimb Regeneration Vanstone, Jason January 2013 (has links) Newts have the incredible ability to regenerate many different organs and tissues as adults, including the limbs. Limb regeneration occurs via the dedifferentiation of stump tissue and the formation of a blastema, which provides the majority of cells for the regenerate. Despite all that we have learned about dedifferentiation and blastema formation, the cellular and molecular mechanisms underlying these processes are still poorly understood. We used representational difference analysis (RDA) to identify genes involved in the early dedifferentiation process in newt forelimb regeneration. Our analysis identified approximately 410 unique genes that were differentially regulated during this process. Microarray analysis was used to determine the expression profile of these genes throughout limb and tail regeneration. We used quantitative PCR (qPCR) to validate the expression of a subset of these genes [β-catenin, wntless, dapper, thymosin-β 4 (Tβ4), and thymosin-β 10/15 (Tβ10/15)] in regenerating limb and tail tissue, as well as in differentiating newt myoblasts. We also verified the expression of these genes in the regenerating newt limb using immunohistochemistry (IHC) and in situ hybridization (ISH). Finally, we performed a functional analysis on β-catenin, wntless, dapper, and Tβ4 by overexpressing these genes in mouse myoblasts to examine their effects on differentiation and potential roles in dedifferentiation. Quantitative PCR verified the expression of β-catenin, wntless, dapper, and Tβ4 during limb regeneration and IHC/ISH localized the β-catenin and Tβ4 proteins to the blastema during regeneration. Tβ10/15 was shown by qPCR to be expressed in the tail during regeneration. Overexpression of newt β-catenin, wntless, dapper, and Tβ4 in mouse myoblasts showed that each of these genes has an inhibitory effect on the differentiation of myoblasts into myotubes and, therefore, may play a role in promoting or maintaining the dedifferentiated state. Our work has identified a large number of genes with potential roles in regulating the dedifferentiation process during newt forelimb regeneration. We have also laid a framework from which much more work can be done by drawing on the genes we have identified and the microarray data, which indicate ideal follow-up candidates. Our analysis of specific genes has also increased our understanding of the molecular events occurring during the dedifferentiation process in the regenerating newt limb. regeneration newt Notophthalmus viridescens limb regeneration representational difference analysis microarray gene expression salamander dedifferentiation regeneration profile wnt thymosin beta subtractive hybridization

Search results