Global ETD Search

21	Ecdysone signaling and miRNA let-7 cooperate in regulating the differentiation of the germline stem cell progeny König, Annekatrin 08 May 2014 (has links) No description available. 570 stem cell niche Drosophila germarium miRNA let-7 ecdysone signaling germline stem cell Abrupt H2Bub1 wingless signaling histone modifications differential cell adhesion Biologie (PPN619462639)
22	Influência do envelhecimento das células-tronco mesenquimais na autorrenovação, diferenciação e multipotência de células-tronco hematopoéticas / Mesenchymal stem cells aging influence in the self-renewal, differentiation and multipotency of hematopoietic stem cells Suzana da Silva Benedito 05 September 2016 (has links) O envelhecimento é um processo gradual e intrínseco que ocorre devido a mudanças fisiológicas e fenotípicas com o avanço da idade e que acarreta na diminuição da capacidade de manter a homeostase e reparo tecidual. A perda do controle homeostático e o possível envolvimento de células-tronco e progenitores, provavelmente, é uma das causas das fisiopatologias do sistema hematopoético que acompanham o envelhecimento. O declínio na competência do sistema imune adaptativo, o aumento de doenças mielóides, leucemias e o desenvolvimento de anemias são algumas mudanças significantes e decorrentes do processo de envelhecimento. Durante a transição ontológica, a habilidade de células-tronco hematopoéticas originarem células progenitoras diminui progressivamente, sugerindo perda da capacidade de autorrenovação e diferenciação das células-tronco com o avanço da idade. O microambiente medular se divide em duas áreas distintas: nicho endosteal e nicho vascular, conhecidos por controlar a homeostase das células-tronco hematopoéticas; e é composto por uma mistura heterogênea de células, dentre elas as células-tronco mesenquimais que expressam moléculas que controlam algumas funções das células-tronco hematopoéticas. De acordo com estas observações, este trabalho investiga o papel do envelhecimento das células-tronco mesenquimais no processo de autorrenovação, multipotência e diferenciação das células-tronco hematopoéticas. Neste trabalho, avaliamos a percentagem de células-tronco hematopoéticas Lin-CD34+ e subpopulações em co-cultura com células-tronco mesenquimais derivadas de medula óssea de diferentes idades, bem como sua capacidade de autorrenovação, diferenciação, secreção da quimiocina CXCL-12 e a expressão do receptor CXCR-4. Nossos resultados mostraram diferenças significativas nos parâmetros fenotípicos e funcionais das células-tronco hematopoéticas co-cultivadas com células-tronco mesenquimais de doadores idosos. Estes dados sugerem que o envelhecimento das células-tronco mesenquimais podem influenciar na homeostase do microambiente medular / Certainly, aging is one of the best identified features of the human biology, and is also the least understood. This is largely attributed to the fact that aging is gradual and fundamentally complex, due to all modifications in the physiological and phenotypic aspects occurred during the age advancing. One of the most striking features of aging is the decreased ability to maintain homeostasis and tissue repair. Consistent with those findings, many of the pathophysiological conditions affecting aging, such as anemia, dysplasia, leukemia and anemia suggest an imbalance between cell losses and the ability to self-renew or differentiation. The decline in homeostatic maintenance and regenerative potential of tissues during aging has been associated with changes in stem cells. Increasing evidences point to the stem cells as major accountable for the aging pathophysiology in several tissues. Thus, studies in mammals comprise a careful evaluation of mechanisms connected to stem cells. The increasing age is accompanied by many pathophysiological changes in the hematopoietic system wherein the etiology suggests loss of homeostatic control and a possible involvement of stem and progenitor cells. The clinically relevant changes are related to adaptive immune system diminished competence, the increase of myeloid diseases including leukemia and the onset of anemia in the elderly. The hematopoietic stem cell microenvironment is located in the bone marrow and is divided in two domains: the endosteal niche near to the bone surface and vascular niche associated with the sinusoidal endothelium; the niche consist of several heterogeneous cells types, among them, the mesenchymal stem cells. The mesenchymal stem cells express molecules that control hematopoietic stem cells functions. Therefore, this study investigates the role of mesenchymal stem cells aging in the self-renewal, multipotency and differentiation of hematopoietic stem cells. This study evaluated the percentage of hematopoietic stem cell Lin-CD34+ and subpopulations in co-culture with mesenchymal stem cell bone marrow-derived from donors with different ages, their ability of self-renewal, differentiation, secretion of chemokine CXCL-12 and expression of the CXCR-4 receptor. Our results suggest that the mesenchymal stem cells aging can affect the bone marrow niche homeostasis Células-tronco Células-tronco hematopoéticas Células-tronco mesenquimais Envelhecimento Medula óssea Nicho de células-tronco Aging Bone marrow Hematopoietic stem cells Mesenchymal stem cells Stem cell niche Stem cells
23	Identification and characterization of the progenitor niche of the Merkel cell lineage : from homeostasis to cancer Doucet, Yanne 04 December 2015 (has links) La peau est organisée en niche de cellules souches/progénitrices qui contribuent au maintien des lignées épidermiques pendant l’homéostasie permettant ainsi de conserver l’intégrité du tissue. Les différentes cascades de signalisation qui régulent cet équilibre sont essentielles et la perturbation de ces voix peuvent amener à une différentiation anormale des kératinocytes, pouvant engendrer des cancers de la peau. Le but de cette thèse était d’identifier et de caractériser la population de progéniteurs responsables de la maintenance d’une niche épidermique spécialisée dans la mechanotransduction du toucher léger appelée les cellules de Merkel. Mon étude a porté sur le rôle des progéniteurs épithéliaux localisés dans le dôme du toucher (DT) de l’épiderme dans des conditions d’homéostasie ainsi que sur le développement du carcinome des cellules de Merkel. Basé sur l’analyse de données de microarray, j’ai identifié une nouvelle population de progéniteurs qui expriment de manière spécifique Kératine 17 (K17). Des expériences de traçage de lignées cellulaires démontrent que ces cellules donnent naissance aux cellules de Merkel (CM) ainsi qu’aux cellules squameuses. De plus, l’ablation génétique sélective des progéniteurs des CMs dans le DT a montré que cette niche est isolée et indépendante du reste de l’épiderme. Ces résultats établissent les CMs comme la quatrième lignée cellulaire de la peau. Cette découverte a permis l’établissement de nouveaux outils pour l’étude de conditions pathologiques associées à la lignée des cellules de Merkel, telles que les carcinomes des cellules de Merkel et le déclin du toucher léger avec l’âge. / The skin is organized in highly regionalized stem or progenitor cell niches that are in charge of maintaining all epidermal lineages during homeostasis. Disruption of molecular pathways that tightly regulate this balance leads to abnormal specification and differentiation of keratinocytes, eventually causing skin cancer. The goal of this thesis was to identify and characterize the progenitor population responsible for the maintenance of an epidermal niche specialized for mechanosensory signaling: the Merkel cell lineage. This work focused on the role of the epithelial progenitors located in the touch dome (TD) of hairy skin under homeostatic conditions and in a Merkel cell carcinoma (MCC) context. Based on previous microarray data, I first identified a distinct population of the interfollicular epidermis uniquely expressing Keratin 17 (K17). By lineage tracing analysis, I demonstrated that these cells give rise to the Merkel cell (MC) and squamous lineage. More importantly, selective genetic ablation of K17+ TD keratinocytes (TDKC) showed that the TD is a self-autonomous niche defining it as the 4th lineage of the skin. Interestingly, TDKCs may be involved in maintaining innervation of the Merkel cell-neurite complex. These critical results have established a new plateform for the field to allow studies of pathological skin conditions such as Merkel cell carcinoma and the loss of tactile acuity with age. Dome du toucher Cellules de Merkel Progeniteurs epidermiques Peau Cellules souches Carcinome des cellules de Merkel Touch dome Merkel cells Epidermal progenitors Skin Stem cell niche Merkel cell carcinoma
24	Rôles du locus bric à brac durant la formation des niches de cellules souches germinales dans l'ovaire chez Drosophila melanogaster / Roles of bric à brac locus in germline stem cell niche formation in the Drosophila melanogaster ovary Miscopein Saler, Laurine 21 December 2018 (has links) L’environnement des cellules souches (CS) est appelé la niche. Les interactions entre la niche et les CS doivent être hautement régulées puisqu’un dérèglement de ces interactions peut entrainer la formation de tumeurs ou une stérilité. La découverte récente de niches pré-métastatiques rend l’étude de ces interactions cruciale pour mieux comprendre les processus tumoraux. L’ovaire de drosophile un excellent modèle pour étudier les voies de signalisation contrôlant le maintien des CS par leur niche. C’est dans ce modèle qu’il a été montré pour la première fois que le maintien des CS germinales (CSG) dépend d’un facteur secrété par les niches, Decapentaplegic (Dpp), homologue des protéines BMP (superfamille des TGF-β) chez les mammifères. La régulation fine de cette voie est cruciale pour empêcher une prolifération excessive de CSG (tumeur) ou bien leur perte (stérilité). La formation de ces niches et le recrutement des CSG a lieu durant le développement larvaire. Le locus bric-à-brac (bab) est le premier décrit comme étant nécessaire pour ce processus. Durant ma thèse, j’ai montré que Bab est nécessaire et suffisant pour réguler l’expression de dpp et par conséquent le recrutement des CSG ; et certains de mes résultats suggèrent également que le recrutement des CSG au sein de leur niche est régulé par un mécanisme différent de celui impliqué dans leur maintien (Miscopein-Saler et al,. en préparation). / The interactions between stem cells (SC) and their microenvironment called a niche are known to be crucial for SC behaviour. These interactions need to be highly regulated since abnormal SC behaviour is a leading cause of developmental diseases and tumourigenesis. The discovery of pre-metastatic niches makes the study of niche-to-SC interactions a crucial step for our understanding of cancer biology. The powerful genetic tools available render the Drosophila ovary an excellent model to study the signalling controlling germline SC (GSC) maintenance by a niche in an adult tissue. Using this model, it was shown for the first time that SC maintenance was dependent on a factor emanating from the niche. This factor is Decapentaplegic (Dpp), a Drosophila homolog of BMP proteins (family of TGF-β signalling molecules) and a tight regulation of this signalling pathway is very important to avoid an excess of GSC-like cells (tumour) or a loss of GSCs (sterility). Formation of the GSC niches occurs during the larval stages and the bric-à-brac (bab) locus was first discovered as being necessary for niche morphogenesis. During my doctoral studies, I have shown that Bab1 and Bab2 are necessary and sufficient for GSC recruitment by regulating dpp expression, and some of my results alos suggest that GSC recruitment might occurs according to a different mechanism that the one involved in their maintenance (Miscopein-Saler et al,. in preparation). Morphogenèse d'un tissu Niche de cellules souches Voies de signalisation Déterminisme cellulaire Drosophile Micro-environnement Organogenèse Tissue morphogenesis Stem cell niche Signaling pathways Cellular identity Drosophila Micro-environement Organogenesis
25	Visualization of cell-to-cell communication by advanced microscopy techniques Raabe, Isabel 01 July 2015 (has links) In order to maintain a multicellular organism cells need to interact and communicate with each other. Signalling cascades such as the Bone Morphogenic Protein (BMP) and Hedgehog (Hh) signalling pathways therefore play essential roles in development and disease. Intercellular signalling also underlies the function of stem cell niches, signalling microenvironments that regulate behaviour of associated stem cells. Range and intensity of the niche signal controls stem cell proliferation and differentation and must therefore be strictly regulated. The testis and ovary of the fruit fly Drosophila melanogaster are established models of stem cell niche biology. In the apical tip of the testis, germ line stem cell (GSCs) and somatic cyst stem cells (CySCs) are arranged around a group of postmitotic somatic cells termed hub. While it is clear which signals regulate GSC maintenance it is unclear how these signals are spatially regulated. Here I show that BMP signalling is specifically activated at the interface of niche and stem cells. This local activation is possible because the transport of signalling and adhesion molecules is coupled and directed towards contact sites between niche and stem cells. I further show that the generation of the BMP signal in the wing disc follows the same mechanism. Hh signalling controls somatic stem cell populations in the Drosophila ovary and the mammalian testis. However, it was unknown what role Hh might play in the fly testis, where the components of this signalling cascade are also expressed. Here I show that overactivation of Hh signalling leads to an increased proliferation and an expansion of the cyst stem cell compartment. Finally, while the major components of the Hh signalling pathway are known, detailed knowledge of how signal transduction is implemented at the cell biological level is still lacking. Here, I show that localisation of the key signal transducer Smo to the plasma membrane is sufficient for phosphorylation of its cytoplasmic tail and downstream pathway activation. Using advanced, microscopy based biophysical methods I further demonstrate that Smo clustering is, in contrast to the textbook model, independent of phosphorylation.:Summary 1 List of publications 3 1 Introduction 9 Aims of the thesis 15 2 Generation of a local BMP signal in testis and wing disc 17 2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 2.1.1 Stem cells and stem cell niches . . . . . . . . . . . . . . 19 2.1.2 The Drosophila testis stem cell niche . . . . . . . . . . 20 2.1.3 BMP signalling in the fly . . . . . . . . . . . . . . . . . 23 2.2 Results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 2.2.1 The BMP niche signal is transduced locally at adherens junctions 25 2.2.2 Generation of the local BMP niche signal . . . . . . . . 30 2.2.3 Exocyst involvement in long-range BMP signalling . . 34 2.3 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 3 Hedgehog pathway overactivation in the testicular niche 41 3.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 3.1.1 The role of Hedgehog in the fly . . . . . . . . . . . . . 43 3.2 Results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 3.2.1 Overexpression of Hh increases the CySC number and expands their range 45 3.3 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 4 Visualization of Smo phosphorylation and biophysical detection of Smo clustering 49 4.1 Introduction (part I) . . . . . . . . . . . . . . . . . . . . . . . 51 4.1.1 Hedgehog signalling in the fly . . . . . . . . . . . . . . 51 4.1.2 Reception and transduction of the Hh signal by Ptc and Smo 54 4.2 Results (part I) . . . . . . . . . . . . . . . . . . . . . . . . . . 56 4.2.1 A fluorescent reporter for Drosophila Smo tail phosphorylation 56 4.2.2 Smo phosphorylation and localisation in the salivary gland 61 4.2.3 Smo localisation in cultured insect cells . . . . . . . . . 63 4.2.4 Smo membrane localisation and phosphorylation . . . . 65 4.3 Introduction (part II) . . . . . . . . . . . . . . . . . . . . . . . 67 4.3.1 Fluorescence correlation spectroscopy (FCS) . . . . . . 67 4.3.2 Dual-color fluorescence cross-correlation spectroscopy (FCCS) 72 4.3.3 Artefacts in FCS/FCCS . . . . . . . . . . . . . . . . . 73 4.4 Results (part II) . . . . . . . . . . . . . . . . . . . . . . . . . . 79 4.4.1 Smo clustering measured by FCCS . . . . . . . . . . . 79 4.5 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 info:eu-repo/classification/ddc/570 ddc:570
26	Adhesion and Single Cell Tracking of Hematopoietic Stem Cells on Extracellular Matrices Franke, Katja 19 September 2011 (has links) The local microenvironment of hematopoietic stem cells (HSCs) in the bone marrow -referred to as stem cell niche- is thought to regulate the balance of stem cell maintenance and differentiation by a complex interplay of extrinsic signals including spatial constraints, extracellular matrix (ECM) components and cell-cell interactions. To dissect the role of niche ECM components, a set of well-defined matrix biomolecular coatings including fibronectin, laminin, collagen IV, tropocollagen I, heparin, heparan sulphate, hyaluronic acid and co-fibrils of collagen I with heparin or hyaluronic acid were prepared and analyzed with respect to adhesive interactions of human CD133+ HSCs in vitro. ECM molecule dependent adhesion areas as well as fractions of adherent HSCs were assessed by reflection interference contrast microscopy and differential interference contrast microscopy. HSCs, so far mostly classified as suspension cells, exhibited intense adhesive interactions with fibronectin, laminin, collagen IV, heparin, heparan sulphate, and collagen I based co-fibrils. An integrin mediated adhesion on fibronectin and a L-selectin mediated adhesion on heparin pointed to specific interactions based on different adhesion mechanisms. As a consequence of HSC adhesion to molecules of the vascular and the endosteal regions, both regions were confirmed as possible stem cell niches and adhesive signals were suggested as potential regulators of stem cell fate. Furthermore, the impact of a spatially organized ECM on the HSC behavior was analyzed by single cell tracking. These studies required the development of engineered three-dimensional, ECM coated microcavities with the option for single cell tracking. A semi-automated cell-tracking tool was established to accelerate data access from time-lapse image sequences. From this analysis it was possible to reveal the genealogy, localization, morphology and migration of single HSCs over a time period of 4 days. A decreased cycling frequency was observed depending on the HSC localization in the spatially constraining microcavities. Besides the revealed impact of spatial constraints on HSC fate, the newly engineered ECM-coated microcavity setup and the semi-automated cell tracking tool provide new options to study the cell fate in engineered microenvironments at single cell level for other cell types ex vivo. / Die lokale Mikroumgebung von Blutstammzellen (BSZ) im Knochenmark, bezeichnet als Stammzellnische, reguliert das Gleichgewicht von Stammzellerhaltung und -differenzierung durch ein komplexes Zusammenspiel von extrinsischen Signalen wie räumliche Beschränkungen, Komponenten der extrazellulären Matrix (EZM) und Zell-Zell Wechselwirkungen. Um die Rolle der EZM-Komponenten zu analysieren, wurden definierte Beschichtungen von Fibronektin, Laminin, Kollagen IV, monomerem Kollagen I, Heparin, Heparan Sulphat, Hyaluronsäure und Co-Fibrillen aus Kollagen I und Heparin oder Hyaluronsäure hergestellt und in vitro bezüglich der adhäsiven Wechselwirkungen von humanen CD133+ BSZ untersucht. Die Adhäsionsflächen und der Anteil adhärenter Zellen wurden in Abhängigkeit von der EZM-Beschichtung mittels Reflexions- Interferenz-Kontrast-Mikroskopie und Differentieller Interferenz Kontrast Mikroskopie bestimmt. BSZ, bisher als Suspensionszellen definiert, zeigten intensive adhäsive Wechselwirkungen mit Fibronektin, Laminin, Kollagen IV, Heparin, Heparan Sulphat und den Co-Fibrillen. Eine Integrin abhängige Adhäsion auf Fibronektin und eine L-Selektin abhängige Adhäsion auf Heparin, wiesen auf spezifische Wechselwirkungen hin, die auf unterschiedlichen Mechanismen basieren. Aufgrund der Adhäsion von BSZ sowohl zu Molekülen der vaskulären als auch der endostealen Knochenmarkregion, wurden beide Bereiche als mögliche Stammzellnische bestätigt. Adhäsive Signale sind potentielle Regulatoren der Stammzellentwicklung. Im Weiteren wurde der Einfluss einer räumlich beschränkenden EZM auf das Verhalten der BSZ durch Einzelzellverfolgung untersucht. Diese Studien erforderten die Entwicklung von dreidimensionalen EZM-beschichteten Mikrokavitäten, die das Verfolgen einzelner Zellen ermöglichten. Es wurde ein halbautomatischer Algorithmus für die Zellverfolgung etabliert, um die Datengenerierung von den Zeitreihenaufnahmen zu beschleunigen. Die Analysen ermöglichten Aussagen über die Genealogie, Lokalisierung, Morphologie und Migration einzelner BSZ während einer Analysenzeit von 4 Tagen. Eine verringerte Zellteilungsaktivität wurde in Abhängigkeit von der BSZ Lokalisierung innerhalb der räumlich einschränkenden Mikrokavitäten festgestellt. Neben diesen Erkenntnissen bieten die entwickelten Mikrokavitäten und die etablierte Einzelzellverfolgung neue Möglichkeiten auch andere Zelltypen auf Einzelzellniveau ex vivo zu untersuchen. info:eu-repo/classification/ddc/620 ddc:620
27	Electric Stimuli as Instructive Cues to Guide Cellular Differentiation on Electrically Conductive Biomaterial Substrates in vitro Greeshma, T January 2015 (has links) (PDF) Directing differential cellular response by manipulating the physical characteristics of the material is regarded as a key challenge in biomaterial implant design and tissue engineering. In developing various biomaterials, the influence of substrate properties, like surface topography, stiffness and wettability on the cell functionality has been investigated widely. However, such study to probe into the influence of substrate conductivity on cell fate processes is rather limited. The need for such an understanding is based on the fact that specific tissues in the body are electrically active in nature, such as in brain, heart and skeletal muscle. These tissues make use of electrical conductivity as an effective cue for tissue homeostasis, development, regeneration and so on. Moreover, understanding the importance of underlying conductivity in basic biological processes is essential in developing electrically conductive biomaterials with the ability to simulate normal electrophysiology of the body by interfacing with bioelectric fields in cells and tissues. Electrical stimulation and charge conduction can regulate numerous intracellular signalling pathways, can interact with cytoskeleton proteins to modulate the morphology, increase protein synthesis and on the more can favor the ECM protein conformational changes. On these grounds, the present dissertation illustrates that persistent electrical activation influences the multipotency of hMSCs and acts like a promoter towards selective differentiation of hMSCs into neural/cardiomyogenic or osteogenic lineage. Besides, continual exposure to electric field stimulated conducting culture environments lead to growth arrest while enhancing differentiation. In total, this dissertation suggests the dominant role of conductivity in inducing my oblast differentiation and hMSc lineage commitment that involves EF stimulated in vitro culture conditions. Also, a knowledge base with qualitative and quantitative understanding of stem cells and their response to substrate physical properties and external field effect was developed through this comprehensive study. Such an improved understanding of the ability of hMSCs in sensing electrical conductivity may lead to the development of culture additives/conditions that better induce directed stem cell differentiation. Tissue and Organ Culture Biomaterial Substrates Electroactive Ceramic Substrates Electroactive Nano Particles Stem Cells Stem Cell Niche Myoblast Cell Proliferation Osteogenesis Human Mesenchymal Stem Cell Stem Cell Differentiation Nano Science and Engineering
28	Neural precursor cells: interaction with blood-brain barrier and neuroprotective effect in an animal model of cerebellar degeneration Chintawar, Satyan 26 November 2009 (has links) Adult neural precursor cells (NPCs) are a heterogeneous population of mitotically active, self-renewing multipotent cells of both adult and developing CNS. They can be expanded in vitro in the presence of mitogens. The B05 transgenic SCA1 mice, expressing human ataxin-1 with an expanded polyglutamine tract in cerebellar Purkinje cells (PCs), recapitulate many pathological and behavioral characteristics of the neurodegenerative disease spinocerebellar ataxia type 1 (SCA1), including progressive ataxia and PC loss. We transplanted neural precursor cells (NPCs) derived from the subventricular zone of GFP-expressing adult mice into the cerebellar white matter of SCA1 mice when they showed absent (5 weeks), initial (13 weeks) and significant PC loss (24 weeks). A stereological count demonstrates that mice with significant cell loss exhibit highest survival of grafted NPCs and migration to the vicinity of PCs as compared to wt and younger grafted animals. These animals showed improved motor skills as compared to sham animals. Confocal analysis and profiling shows that many of implanted cells present in the cerebellar cortex have formed gap junctions with host PCs and express connexin43. Grafted cells did not adopt characteristics of PCs, but stereological and morphometric analysis of the cerebellar cortex revealed that grafted animals had more surviving PCs and a better preserved morphology of these cells than the control groups. Perforated patch clamp recordings revealed a normalization of the PC basal membrane potential, which was abnormally depolarized in sham-treated animals. No significant increase in levels of several neurotrophic factors was observed, suggesting, along with morphological observation, that the neuroprotective effect of grafted NPCs was mediated by direct contact with the host PCs. In this study, evidence for a neuroprotective effect came, in addition to motor behavior improvement, from stereological and electrophysiological analyses and suggest that timing of stem cell delivery is important to determine its therapeutic effect.<p>In a brain stem cell niche, NSCs reside in a complex cellular and extracellular microenvironment comprising their own progeny, ependymal cells, numerous blood vessels and various extracellular matrix molecules. Recently, it was reported that blood vessel ECs-NSCs crosstalk plays an important role in tissue homeostasis. Bloodstream offers a natural delivery vehicle especially in case of diffuse neurodegenerative diseases which require widespread distribution of exogenous cells. As NSCs are confronted with blood-brain barrier endothelial cells (BBB-ECs) before they can enter into brain parenchyma, we investigated their interaction using primary cultures in an in vitro BBB model. We isolated human fetal neural precursor cells (hfNPCs) from aborted fetal brain tissues and expanded in vitro. We showed that in an in vitro model, human BBB endothelium induces the rapid differentiation of hfNPCs and allows them to cross the endothelial monolayer, with the differentiated progeny remaining in close contact with endothelial cells. These results are not reproduced when using a non-BBB endothelium and are partly dependent on the cytokine MCP1. Our data suggest that, in the presence of attractive signals released by a damaged brain, intravascularly administered NPCs can move across an intact BBB endothelium and differentiate in its vicinity. Overall, our findings have implications for the development of cellular therapies for cerebellar degenerative diseases and understanding of the brain stem cell niche. / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished Disciplines biomédicales diverses Médecine pathologie humaine Cerebellum -- Degeneration Cerebellar ataxia Neural stem cells Neurons Cervelet -- Dégénérescence Ataxie cérébelleuse Cellules souches neurales Neurones neuroprotection stem cell niche brain endothelium transplantation spinocerebellar ataxia cerebellum neural precursor cells
29	Micro-structuration de la surface des matériaux avec ligands bioactifs pour mimer la matrice extra-cellulaire osseuse / Micro-engineered substrates as bone extracellular matrix mimics Bilem, Ibrahim 31 August 2016 (has links) Actuellement, il est largement reconnu que la décision des cellules souches de maintenir leur caractère souche ou se différencier vers une lignée spécialisée dépend particulièrement de la nature de leur microenvironnement, appelé niche cellulaire. Une des composantes essentielles de cette niche cellulaire est la matrice extracellulaire (MEC), qui au-delà de sa fonction de support cellulaire, détermine le devenir des cellules souches en fonction de sa composition biochimique, sa structure et sa localisation. D’un point de vue rationnel, un biomatériau destiné à remplacer la fonction d’un tissu endommagé doit non seulement jouer le rôle d’échafaudage cellulaire mais également mimer les propriétés de la MEC dans son ensemble. Malheureusement, il est extrêmement difficile de concevoir des biomatériaux mimétiques de la MEC naturelle tenant compte de sa complexité structurelle et fonctionnelle. Pour pallier à cette problématique, il semble nécessaire d’effectuer un travail en amont de déconstruction/reconstruction de la complexité de la MEC en étudiant l’effet individuel puis combiné de ses propriétés sur la différenciation des cellules souches. Ce projet de doctorat rentre dans le cadre de ce travail et vise à déterminer le rôle spécifique ou concomitant de différentes propriétés inhérentes à la MEC sur la différenciation ostéoblastique des cellules souches mésenchymateuses humaines (hCSMs). En effet, nous avons évalué l’effet de la composition biochimique de la MEC et la distribution spatiale des ligands sur la différenciation des hCSMs, en fonctionnalisant la surface d’un matériau modèle avec les peptides RGD et/ou BMP-2, distribués d’une manière aléatoire ou structurée. / Actually, it is well-established that maintaining the stemness character of stem cells or eliciting their lineage-specific differentiation is closely related to the nature of their microenvironment, known as stem cell niche. The extracellular matrix (ECM), a key component of stem cell niche, not only provides a support function for stem cells but also dictates their fate decision. From a rational point of view, a biomaterial intended to replace a damaged tissue should mimic the natural ECM in all its aspects, including its biochemistry, 3D structure, topography, porosity, rigidity…. etc. Unfortunately, the design of biomaterials that fully mimic the natural ECM is still a big challenge, due to its high structural and functional complexity. Towards the development of finely-tuned biomaterials, it seems important to start by deconstructing and then reconstructing the complexity of the ECM. In this context, the thesis project, herein, seeks to evaluate both the individual and the synergistic effect of different properties inherent to the natural ECM on human mesenchymal stem cells (hMSCs) osteogenic differentiation. Indeed, we investigated whether the biochemical composition of the ECM and the spatial distribution of its components modulate hMSCs osteogenesis. This was achieved by creating different artificial ECMs, in vitro, containing RGD and/or BMP-2 mimetic peptides, distributed randomly or as specific micropatterns on the surface of a model material. Matrice extracellulaire biomimétique Peptides mimétiques BMP-2 Cellules souches Ostéogenèse Chemical micropatterning Bioactive surfaces Mimetic peptides BMP-2 Mesenchymal stem cells Stem-cell niche Osteo-genesis
30	Targeting the leukemic stem cell niche: An opportunity for novel therapeutic treatment options Fusenig, Maximilian 09 June 2022 (has links) Acute myeloid leukemia (AML) presents the deadliest form of blood cancer which leads to abrupt, premature deaths. Current therapeutic treatment options in AML are unspecific, resulting in high relapse rates and poor clinical responses in patients. Therapy-resistant, stem cell-like AML cells are believed to be protected by proximal stromal cells in their microenvironment, the leukemic stem cell niche. In part A of this work, an innovative first-of-its-kind arrayed endoribonuclease-prepared siRNA (esiRNA) screen was established for the targeted identification of stromal-derived, AML-supportive genes. Immortalized bone-marrow derived mesenchymal stromal cells (SCP-1) were subjected to individual esiRNA-mediated target gene knockdowns (KD) and subsequently cocultured with AML cell lines MV4-11, OCI-AML3, MOLM-13 and HL-60. AML proliferation and therapy resistance to cytostatic agents Cytarabine or Daunorubicin and tyrosine kinase inhibitor Midostaurin were assessed in direct cocultures. In SCP-1, several secreted, membrane-associated and intracellular molecules were identified which, upon esiRNA-mediated KD, resulted in proliferation inhibition and enhanced treatment response of cocultured AML cells. Carbonic anhydrase 9 (CA9), a stabilizer of intracellular pH, was identified as a supportive factor in proliferation and resistance of leukemic cells to Daunorubicin treatment whilst CA9-KD exerted only a comparably low toxicity in SCP-1 cells. Excitingly, published data by Chen and colleagues (Blood, 2017, Vol. 130, Suppl. 1, 2521) indicated an upregulation of CA9 in hypoxic ex vivo cultures of leukemic cells, measured an anti-leukemic effect of pharmacological CA9 inhibition and identified a synergistic effect on leukemic cells via combinatorial treatment of CA9-inhibition and Cytarabine under hypoxic culture conditions. Taken together, an arrayed esiRNA screen identified CA9 and other stromal-derived factors which potentially open up new avenues for selective therapeutic treatments targeting the leukemic microenvironment in AML. Currently, preclinical leukemia research relies on artificial suspension cultures of AML cells and highly sophisticated, patient-derived xenograft (PDX) mouse models that are marked by suboptimal translation of findings of PDX experiments into the clinic. Recent developments in complex three-dimensional (3D) hydrogel star-shaped poly(ethylene glycol) (starPEG)-heparin cocultures of leukemic and stromal cells of human origin showed promising results in proliferation and drug response studies. Therefore, in part B of this work, a high throughput screening (HTS)-compatible 3D hydrogel culture setup of human stromal cells was established in 384-well plates. Implementation of design of experiments (DoE) enabled an efficient, cost-effective optimization of hydrogel monocultures of human umbilical vein endothelial cells (HUVECs). Optimized culture conditions favored angiogenic sprouting of hydrogel-embedded HUVECs which responded to angiogenic inhibitors Axitinib, AZD4547 and Bevacizumab in a dose-dependent manner. A coculture with bone marrow derived MSCs altered the angiogenic network formation of endothelial CD31+ vessel-like structures. The hydrogel coculture was further stabilized by extensive hydrogel degradation and ECM deposition of MSCs. Stromal MSC networks were illustrated as highly interconnected and elongated F-Actin filament structures (CD31- F-Actin+) that were closely associating with CD31+ F-Actin+ endothelial vessel-like structures. Excitingly, the established 3D hydrogel HTS platform of primary human stromal cells enables future addition of patient-derived leukemic cells for targeted leukemic vulnerability screens in an ex vivo cell culture model of the perivascular stem cell niche. / Akute myeloische Leukämie (AML) gilt als die tödlichste Form der Blutkrebserkrankungen, welche untherapiert zum abrupten, vorzeitigen Tod führt. Etablierte therapeutische Verfahren der AML sind unspezifisch, welche durch heterogene Behandlungseffekte gekennzeichnet sind und zu hohen Rückfallquoten führen. Man vermutet, dass therapie-resistente, stammzellähnliche leukämische Zellen von proximal residierenden Stromazellen in ihrem Mikromilieu, in der sogenannten leukämischen Stammzellnische, vor therapeutischen Behandlungen geschützt werden. In Teil A dieser Arbeit wurde ein innovativer, neuartiger Screen basierend auf Endoribonuklease-generierten kleinen, interferierenden Ribonukleinsäuren (esiRNAs) für eine gezielte Identifikation von AML-supportiven, stromalen Faktoren etabliert. Immortalisierte, mesenchymale Stromazellen aus dem Knochenmark (SCP-1) wurden in einem Array mit spezifischen esiRNAs transfiziert, um esiRNA-basierende inhibierende Effekte (Knockdown) auf die Genexpression von Zielgenen in SCP-1 zu studieren und indirekte Auswirkungen auf Proliferationsrate und Therapieresistenz von kokultivierten leukämischen Zelllinien, MV4-11, OCI-AML3, MOLM-13 und HL-60, bei Behandlung mit Cytarabin, Daunorubicin und Midostaurin, zu studieren. Mehrere sezernierte, membranständige und intrazelluläre Faktoren wurden in SCP-1 identifiziert, deren esiRNA-vermittelter Knockdown zu einer Proliferationsminderung sowie verstärkten Toxizitätseffekten von applizierten Therapeutika in Leukämiezellen führten. Beispielhaft wurde Carboanhydrase (CA9), ein Enzym welches den intrazellularen pH einer Zelle stabilisert, als Target identifiziert. Ein Knockdown von CA9 in SCP-1 resultierte in einer Proliferationsminderung von kokultivierten Leukämiezellen, welche des Weiteren in einer Behandlung mit Daunorubicin verstärkt abgetötet wurden. Publizierte Daten von Chen et al. (Blood, 2017, Vol. 130, Suppl. 1, 2521) zeigten, dass CA9 in hypoxischen ex vivo Kulturen in leukämischen Zellen hochreguliert war und, dass dessen pharmakologische Inhibition einen anti-leukämischen Effekt aufwies. Zudem wurde ein synergistischer Therapieffekt, bei einer Kombinationstherapie mit einem CA9-Inhibitor und Cytarabin, auf AML Zellen in hypoxischer Zellkultur festgestellt. Zusammenfassend wurden in einem esiRNA-Screen CA9 und weitere stromal-exprimierte Faktoren identifiziert, die das Potential besitzen neuartige Therapiestrategien zu ermöglichen, welche auf die leukämische Stammzellnische als Zielstruktur ausgerichtet sind. In der präklinischen Forschung von hämatologischen Erkrankungen werden vorrangig artifizielle zweidimensionale Suspensionskulturen von Leukämiezellen verwendet oder ausgefeilte, patienten-derivierende Xenograft (PDX) Mausmodelle eingesetzt. Bedauerlicherweise weisen Erkenntnisse aus Mausmodellen eine geringe Translationseffizienz in die klinische Forschung auf. Neuste Entwicklungen mit komplexen, dreidimensionalen Hydrogelkulturen, bestehend aus sternförmigem Polyethylenglykol (starPEG) und Heparin, von stromalen und leukämischen Zellen humanen Ursprungs zeigten vielversprechende Ergebnisse in präklinischen Proliferations- und Vulnerabilitätsstudien. Daher wurde in Teil B dieser Arbeit ein hochdurchsatzfähiges dreidimensionales Kultursystem von humanen Stromazellen in Hydrogelen entwickelt. Per statistischer Versuchsplanung wurde eine effiziente, kostengünstige Optimierung von etablierten Hydrogelkulturen für die Hochdurchsatz-kompatible Kultur von humanen venösen Endothelzellen aus Nabelschnuren (HUVECs) durchgeführt. Optimierte Kulturbedingungen führten zur Angiogenese von Hydrogel-eingebetteten HUVECs, welche des Weiteren auf die Angiogenese-Inhibitoren Axitinib, AZD4547 und Bevacizumab in einer konzentrationsabhängigen Weise mit verminderter Bildung von gefäßähnlichen Strukturen reagierten. Eine Kokultur von HUVECs mit primären, mesenchymalen Stromazellen aus dem Knochenmark (MSCs) beeinflusste die Bildung von CD31+ gefäßähnlichen Strukturen. Die Hydrogel-Kokultur wurde des Weiteren durch verstärkte Degradation des Hydrogels und Deposition von Komponenten der extrazellulären Matrix via MSCs verändert und dadurch zusätzlich stabilisiert. Geformte Netzwerkstrukturen von MSCs und HUVECs wurden mittels F-Actin Färbung identifiziert, wodurch ersichtlich wurde, dass Strukturen von MSCs (CD31- F-Actin+) in enger räumlicher Distanz zu HUVEC Strukturen (CD31+ F-Actin+) gebildet wurden. Spannenderweise ermöglicht die, in dieser Arbeit etablierte, Hochdurchsatz-kompatible Kokultur von humanen Stromazellen die Möglichkeit auch leukämische Zellen in die Hydrogelmatrix einzubetten. Eine humane AML-Stroma Kokultur in Hydrogelen wird gezielte Vulnerabilitätsscreens von AML Zellen in einem komplexen ex vivo Zellkulturmodel der perivaskulären Stammzellnische ermöglichen. info:eu-repo/classification/ddc/610 ddc:610

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