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21	Characterization of C/EBPs in Mammary Epithelial Cell Biology Dearth, Lawrence 20 December 2002 (has links) No description available. Biology, Molecular C/EBPs mammary epithelial cells posttranscriptional regulation posttranslational regulation
22	Effects of Growth Hormone and Insulin-Like Growth Factor-I on Milk Protein Gene Expression and Nutrient Uptake and Cell Proliferation in Clonal Bovine Mammary Epithelial Cells Zhou, Yinli 13 September 2007 (has links) The overall objective of this research was to further understand the mechanism by which growth hormone (GH) stimulates milk production in cattle. Three studies were conducted toward this objective. In the first study, the effects of GH and insulin-like growth factor-I (IGF-I), a major mediator of GH action in vivo, on cell proliferation, nutrient transport, and milk protein gene expression in bovine mammary epithelial cell line MAC-T cells were determined. GH increased (P < 0.01) expression of four major milk protein genes in MAC-T cells transfected with GHR expression plasmid. Cotransfection analyses indicated that GH also stimulated (P < 0.01) luciferase reporter gene expression from the promoters of the four milk protein genes in MAC-T cells. These findings together with the fact that GHR mRNA and protein are expressed in the epithelial cells of the bovine mammary gland suggest that GH may directly stimulate milk protein gene expression in the mammary gland. This study also showed that IGF-I increased the proliferation (P < 0.01) and amino acid transport (P < 0.05) in MAC-T cells. Because GH is known to stimulate IGF-I production in animals, IGF-I-mediated mammary epithelial cell proliferation and amino acid uptake may be additional mechanisms by which GH increases milk production in cattle. In the second study, the role of connective tissue growth factor (CTGF) on IGF-I-stimulated proliferation of MAC-T cells was investigated. A microarray analysis revealed that IGF-I decreased CTGF mRNA expression in MAC-T cells (P < 0.01). This effect of IGF-I was further found to be mediated through the PI-3 kinase/Akt signaling pathway from the IGF-I receptor (IGF-IR). CTGF alone stimulated MAC-T cell proliferation (P < 0.01). However, together with IGF-I, CTGF attenuated the proliferating effect of IGF-I on MAC-T cells, and this attenuation was reversed by additional IGF-I. Therefore, IGF-I inhibition of CTGF expression may benefit IGF-I stimulation of MAC-T cell proliferation. CTGF had no effect on IGF-I-induced phosphorylation of IGF-IR or total IGF-IR expression in MAC-T cells, suggesting that CTGF may attenuate IGF-I stimulation of MAC-T cell proliferation through a postreceptor inhibition of the IGF-IR signaling pathway. In the third study, whether a milk yield-associated T/A polymorphism in exon 8 of the bovine GHR gene affected GHR signaling was determined. It was found that the two corresponding GHR variants did not differ in mediating GH induction of gene expression, suggesting that the two GHR variants are not functionally different and hence are unlikely to mediate different effects of GH on milk production. In summary, the results of this dissertation research suggest that GH may directly stimulate milk protein gene expression and indirectly stimulate mammary epithelial cell proliferation and amino acid uptake through IGF-I, thereby stimulating milk production in cattle. The results also suggest that IGF-I stimulation of mammary epithelia cell proliferation may involve an inhibition of CTGF expression in the cells. / Ph. D. Milk production Mammary epithelial cells Insulin-like growth factor-I Growth hormone
23	Modulation par l'interleukin (IL) -17 de la réponse immunitaire innée des cellules épithéliales mammaires bovines à des composants de Staphylococcus aureus / Modulation by IL-17A and IL-17F of bovine mammary epithelial cell innate immune response to Staphylococcus aureus components Bougarn, Salim 18 March 2011 (has links) L’IL-17 est une cytokine essentielle dans la défense de l’organisme contre de nombreuses bactéries pathogènes extracellulaires, comme Siaphylococcus aureus qui est un agent majeur des mammites des ruminants, en agissant en particulier sur les cellules épithéliales. L’objectif du travail était de tester l’hypothèse d’un rôle de i’IL-17 dans la protection de la mamelle en caractérisant la réponse des cellules épithéliales mammaires bovines (CEMb) à l’IL-17A et à l’IL-17F. Ces cytokines bovines ont été utilisées seules ou en combinaison avec des agonistes du système immunitaire inné produits par S. aureus, le muramyl dipeptide (MDP) et l’acide lipotéichoïque (LTA). Une première étude a montré que le LTA et le MDP exercent un effet synergique dans la mamelle et sur les CEMb en culture. Le tissu mammaire et les CEMb expriment le récepteur pour l’IL-l7A et F, et les CEMb ont répondu à i’lL-l7A et l’IL-l7F, bien que de façon modérée. Les réponses ont été sensiblement augmentées par la combinaison de l’IL-17 avec le LTA ou le MDP. Les réponses se caractérisent par une production de chimiokines capables d’attirer les polynucléaires neutrophiles et les leucocytes mononucléés, ainsi que par une surexpression de gènes à activités antibactériennes. Par contre, les CEMb ne produisent pas de cytokines inflammatoires. Ces résultats indiquent que i’IL-l7 est adaptée à un fonctionnement en milieu septique et ales capacités pour jouer un rôle dans la protection de la mamelle contre les infections staphylococciques. / Through its activity on epithelial cells, interleukin-17 is a pivotai cytokine for the host defense against several extracellular pathogens, such as Siaphylococcus aureus that is a major agent of mastitis of ruminants. The investigation aimed at evaluating the role of IL-17 in udder protection by characterizing the response of bovine mammary epithelial cells (bMEC) to IL-17A and IL-17F. These bovine cytokines were used either alone or in combination with one of two innate immune system agonists associated with S. aureus, muramyldipeptide (MDP) or lipoteichoic acid (LTA). The first study showed that LTA synergized with MDP to recruit neutrophils in the mammary gland and to stimulate bMEC. A second study established that mammary tissue and bMEC in culture express the IL-17 receptor, and that bMEC respond to IL-17A and IL-17F, although with a moderate intensity. The response was noticeably augmented by the combination of IL-17 with LTA or MDP. The response was characterized by the production of chemokines able to attract neutrophils but also mononuclear leukocytes, as well as by an overexpression of genes endowed with antibacterial activity. Remarkably, bMEC did not release pro inflammatory cytokines. These results indicate that IL-17A and IL-17F are well suited for operating in a septic environment and have the potential to play a role in udder protection against staphylococcal infections. Interleukine-17 Immunité innée Cellules épithéliales mammaires Staphylococcus aureus Interleukine-17 Innate immunity Mammary epithelial cell Staphylococcus aureus.
24	L’exfoliation des cellules épithéliales mammaires : mécanismes de régulation, rôle dans la détermination du nombre de cellules dans la glande mammaire et influence sur la production laitière / The exfoliation process : regulatory mechanisms, role in regulating the number of cells in the mammary gland and in milk yield variations. Hervé, Lucile 08 December 2017 (has links) Le lait est produit par les cellules épithéliales mammaires (CEM). La quantité de lait produit est déterminée par le nombre de CEM et leur activité métabolique. Le nombre de CEM dépend de l’équilibre entre la prolifération cellulaire et l’apoptose. Le processus d’exfoliation, défini comme le décrochage des CEM de l’épithélium mammaire et leur évacuation dans le lait, a été proposé comme participant aussi à la régulation du nombre de CEM. Les objectifs de cette thèse étaient d’identifier les mécanismes biologiques impliqués dans la régulation de ce processus et d’étudier son rôle dans la régulation du nombre de CEM et son influence sur la production laitière. Nos résultats montrent qu’une partie des CEM est exfoliée entre deux traites consécutives.Cependant, la majorité des CEM sont exfoliées au moment de la traite suite à la contraction des cellules myoépithéliales et à la perte d’intégrité de l’épithélium induites par la décharge d’ocytocine. Le cortisol, au contraire, participerait à la restauration de l’intégrité de l’épithélium mammaire après la fin de la traite et limiterait l’exfoliation. Nous avons montré que les variations du taux d’exfoliation étaient opposées aux variations de production laitière dans le cas d’une restriction alimentaire et après la fin d’un traitement à l’hormone de croissance mais pas dans le cas d’un changement de fourrage, de l’inhibition de la prolactine et pendant un traitement à l’hormone de croissance. Le processus d’exfoliation des CEM participe donc à la régulation de la production laitière mais pas de façon systématique. / Milk is synthesized by mammary epithelial cells (MEC). Milk yield is determined by the number of MEC in the mammary gland and the metabolic activity of these cells. It is well known that MEC number depends on the balance between cell proliferation and apoptosis. The MEC exfoliation process, defined as the shedding of MEC from the mammary epithelium into milk, is another process that might participate in the regulation of MEC number in the udder and thus in milk yield variations. The aims of this thesis were to identify the mechanisms that regulate the exfoliation process and to study the potential role of this process in regulating the number of MEC and milk yield.Our results showed that some MEC are exfoliated between milkings. Most of the MEC are, however, exfoliated during milking as a consequence of the myoepithelial cell contraction and the disruption of mammary epithelium integrity, both of which are caused by milking-induced oxytocin release. Cortisol may play a role in limiting MEC exfoliation by restoring mammary epithelium integrity after milking. We showed that the exfoliation process participates in regulating milk yield during feed restriction and after a treatment with bovine growth hormone but did not participate in regulating milk yield when forage in the ration was changed, when prolactin secretion was inhibited, or during a treatment with bovine growth hormone. These results suggest that the MEC exfoliation process likely participates in regulating milk yield but not systematically. Vache laitière Cellule épithéliale mammaire Exfoliation Ocytocine Prolactine Cortisol Dairy cow Mammary epithelial cell Exfoliation Oxytocin Prolactin Cortisol.
25	Caractérisation de biomarqueurs cellulaires pour étudier la plasticité mammaire au cours de la lactation chez la vache laitière. / Characterization of cell biomarkers for studying mammary gland plasticity throughout lactation in dairy cattle. Arevalo turrubiarte, Magdalena 28 September 2016 (has links) La recherche sur la fonction de lactation est indispensable pour la filière laitière. La glande mammaire est un organe composé de cellules épithéliales, de cellules myoépithéliales, de fibroblastes, d’adipocytes et de cellules endothéliales. L’identification et l’évolution en dynamique des populations cellulaires dans la glande mammaire bovine au cours la lactation reste encore à ce jour méconnues. Les objectifs de cette thèse ont été 1) l’obtention d’un panel des biomarqueurs pour identifier les différentes cellules dans la glande mammaire bovine et 2) le suivi de leur évolution au cours d’un cycle de lactation. Les biomarqueurs de surface (CD49f, EpCAM, CD24 et CD10) ont permis de phénotyper deux lignées mammaires bovines. Nous avons également utilisé ces biomarqueurs pour phénotyper les cellules dans la glande mammaire bovine au cours d’un cycle de lactation.Dans cet objectif, des biopsies ont été prélevées sur 5 vaches laitières primipares à quatre étapes durant la lactation. Après la digestion des biopsies, les cellules obtenues ont été marquées et phénotypées par cytométrie en flux. L’analyse des résultats montre des corrélations positives entre les populations cellulaires CD49f+ et CD49f+/CD24- avec la production laitière. Nous avons mis en évidence une population cellulaire CD49f-/EpCAM- qui augmente au cours de la lactation. Ces résultats suggèrent qu’à partir de l’utilisation de biomarqueurs il est possible d’identifier et phénotyper l’évolution de différentes cellules pendant la lactation dans la glande mammaire bovine. / Research of lactation function of the bovine mammary gland remains essential in dairy farming. The mammary gland is an organ composed of epithelial cells, myoepithelial cells, fibroblasts, adipose cells and endothelial cells. The identification and evolution of cell populations in the bovine mammary gland during lactation is currently unknown. The objectives of this thesis were 1) to obtain a panel of biomarkers capable of identifying different cells within the mammary gland 2) to follow the evolution of these cells throughout a lactation cycle. The cell surface biomarkers (CD49f, CD24, CD10 and EpCAM) allowed us to phenotype two bovine mammary cell lines. We also used these cell biomarkers to phenotype cell populations during lactation.For this objective mammary gland explants were obtained by biopsies taken on 5 primiparous lactating cows at four different times during lactation. After the biopsies were digested, the cells obtained were phenotyped by flow cytometry. Analysis of the results revealed a positive correlation between the CD49f+ and CD49f+/CD24- cell populations and milk yield. We also found evidence that one cell population (CD49f-EpCAM-) was increased during lactation. In general these results suggest that biomarker expression can be utilized to identify the phenotype and the evolution of different cell types during lactation in the bovine mammary gland. Cellule épithéliale mammaire (CEM) Biomarqueurs Glande mammaire Lactation Vache laitière. Mammary epithelial cell (MEC) Biomarkers Mammary gland Lactation Dairy cow.
26	Expression and function of drug transporters in an in vitro model of the mammary epithelial barrier (BME-UV) Al-Bataineh, Mohammad M. January 1900 (has links) Doctor of Philosophy / Department of Diagnostic Medicine/Pathobiology / Ronette Gehring / Milk composition has a dynamic nature, and the composition varies with stage of lactation, age, breed, nutrition and health status of the udder. The changes in milk composition seem to match the changes in the expression of membrane proteins in secretory mammary epithelial cells that are needed for the movement of molecules from blood to milk and vice versa (Nouws and Ziv, 1982). Thus, an understanding of transporter expression, function and regulation in mammary epithelial cells can provide insight into mammary gland function and regulation. The goal of this project was to elucidate (molecularly and functionally) the role of drug transporters in the barrier function of an epithelial monolayer cultured from an immortalized bovine mammary epithelial cell line (BME-UV). To characterize the regulation (expression and function) of these drug transporters in BME-UV cells after exposure to cytokine TNF-α for selected periods of time. Representative members of drug transporters of the SLC (OCT and OAT) and ABC (P-glycoprotein) superfamilies were chosen for this project. In the first study, the involvement of a carrier-mediated transport system in the passage of organic cation (TEA) and anion (EsS) compounds was elucidated across the BME-UV monolayer. In the second study, molecular and functional expression of bOAT isoforms in BME-UV cells were studied. The final study characterized the effects of cytokine TNF-α on the expression and function of P-glycoprotein, an efflux pump, in BME-UV cells. Cytokine TNF-α exposure induced the expression of ABCB1 mRNA and increased P-glycoprotein production in BME-UV cells, resulting in a greater efflux of digoxin, a known P-glycoprotein substrate, back into the apical fluid. The expression, function, and regulation of these transporters in the mammary gland has important implications for understanding the barrier function of the mammary epithelium and, in more specific, for characterizing the role of these transporters in the accumulation and/or removal of specific substrates from milk and/or plasma. Moreover, this study provides an in vitro cell culture model of mammary epithelium to characterize mammary epithelial cell function during inflammation. Mammary epithelial cell Drug transporters Pharmacokinetic Tumor necrosis factor-alpha Biology, Cell (0379) Biology, Veterinary Science (0778) Health Sciences, Pharmacology (0419)
27	Mammary Epithelial Cells Cultured onto Non-Woven Nanofiber Electrospun Silk-Based Biomaterials to Engineer Breast Tissue Models Maghdouri-White, Yas 09 April 2014 (has links) Breast cancer is one of the most common types of cancer affecting women in the world today. To better understand breast cancer initiation and progression modeling biological tissue under physiological conditions is essential. Indeed, breast cancer involves complex interactions between mammary epithelial cells and the stroma, both extracellular matrix (ECM) and cells including adipocytes (fat tissue) and fibroblasts (connective tissue). Therefore, the engineering of in vitro three-dimensional (3D) systems of breast tissues allows a deeper understanding of the complex cell-cell and cell-ECM interactions involved during breast tissue development and cancer initiation and progression. Furthermore, such 3D systems may provide a viable alternative to investigate new drug or drug regimen and to model and monitor concurrent cellular processes during tumor growth and invasion. The development of suitable 3D in vitro models relies on the ability to mimic the microenvironment, the structure, and the functions of the breast tissue. Different approaches to develop a novel 3D breast model have been investigated. Most models use gel scaffolds, including Matrigel® and collagen to generate breast tissue-like structures. However, the physicochemical, mechanical, and geometrical properties of these scaffolds only partially meet the mechanical, physical, and chemical parameters of the breast tissue matrix. In the present studies, we investigated the overall hypothesis that electrospun SF-derived scaffolds promote mammary cell growth and the formation of mammary-like structures depending on the composition and/or coating of the scaffolds with ECM proteins. Through an extensive literature search (1) the importance of 3D modeling of tissues and organs in vivo, (2) 3D modeling of the mammary tissue and currently available models, (3) the properties and applications of SF in tissue modeling and regeneration were reviewed (Chapter 1). Our studies provide evidence of the effects of various concentrations (Chapter 2) of SF along with different electrospinning techniques (Chapter 3) on the structure of electrospun scaffolds and whether those scaffolds provide suitable microenvironments for mammary epithelial cells as determined by MCF10A cell attachment, viability, and structure formation. Further, we investigated the effects of the key ECM proteins collagen I (Chapter 4) and laminin (Chapter 5) used to blend or coat, respectively, SF scaffolds on the attachment, viability and structure formation of mammary epithelial cells. Our studies first highlight the mechanical and physical properties of the different SF-derived scaffolds through various SF concentrations and electrospinning techniques. Second, the biocompatibility of these SF electrospun scaffolds was defined based on MCF10A cell survival and adhesion. Third, our data indicate that scaffolds derived from blended and/or coated SF with collagen I also promoted human mammary cell survival and adhesion. Lastly, our observations suggest that on laminin-coated SF scaffolds MCF10A mammary cells, in the presence of lactogenic hormones, differentiated forming acinus-like structures. Overall, these studies provide evidence that SF electrospun scaffolds closely mimic the structure of the ECM fibers and allow many advantages such as; physical and chemical modification of the microenvironment by varying electrospinning parameters and addition of various proteins, hormones, and growth factors, respectively. Further, coating these SF scaffolds with essential ECM proteins, in particular laminin, promote cell-ECM interactions necessary for cell differentiation and formation of growth-arrested structures, through providing cell integrin binding sites and appropriate chemical cues. Breast Tissue Engineering Electrospinning Nanofibers Silk Fibroin Mammary Epithelial Cells Laminin Three-Dimensional Models Scaffolds Extracellular Matrix Collagen Air-Flow Electrospinning MCF10A Engineering
28	Stress Signaling In Development And Carcinogenesis : Role Of AMP-Activated Protein Kinase Kumar, Hindupur Sravanth 10 1900 (has links) (PDF) Rapidly growing tumor cells outgrow their blood supply resulting in a microenvironment with reduced oxygen and nutrients. Using an in vitro transformation model we found that cancer cells expressing the SV40 ST antigen (+ST cells) are more resistant to glucose deprivation-induced cell death than cells lacking the SV40 ST antigen (−ST cells). Mechanistically, we found that the ST antigen mediates this effect by activating a nutrient-sensing kinase, AMP-activated protein kinase (AMPK). We further show that AMPK mediates its effects, at least in part, by inhibiting mTOR (mammalian target of rapamycin), thereby shutting down protein translation, and by inducing autophagy as an alternate energy source. Resistance to anoikis upon anchorage-deprivation is yet another form of stress tolerated by both normal stem/progenitor cells of various tissues in our body and by cancer cells. Using mammospheres as a model to enrich for stem/progenitor cells we found that mammosphere formation is accompanied with increased activation of AMPK. Concomitant with AMPK activation, we detected increased phosphorylation of the anti-apoptotic protein PED/PEA15. We further demonstrate that AMPK directly interacts with and phosphorylates PEA15 at Ser116, thus establishing PEA15 as a new AMPK target. Thus, our study has identified AMPK-PEA15 signaling as a key component of sphere formation by both normal and cancerous breast tissues. During metastasis, epithelial cells lose attachments to their neighbors, acquire a mesenchymal-like morphology, a process termed as epithelial-mesenchymal transition (EMT) and become motile. Our results indicate that AMPK regulates EMT by both transcriptional and post-translational modification of EMT-inducing transcription factor, Twist. Thus, our study has identified a role for AMPK in nutrient deprivation, anchorage-independent growth, and epithelial-mesenchymal transition involved in metastasis. In addition, we have identified two novel substrates of AMPK, PEA15 and Twist, that may play key roles in cancer progression. Thus, our study suggests that targeting AMPK, or its newly identified substrates, can be explored as possible anti-cancer mechanisms. Carcinoma Protein Protein Kinase AMP-Activated Protein Kinase Autophagy Metastasis Epithelial-Mesenchymal Transition Carcinogenesis AMPK Signaling AMPK Phosphorylates Human Mammary Epithelial Cells Molecular Biology
29	Ets2 and Pten regulate ErbB2-driven mammary tumorigenesis from stromal fibroblasts Balakrishnan, Subhasree 12 September 2016 (has links) No description available. Molecular Biology Cellular Biology
30	Characterization and regulation of C/EBPδ in human mammary epithelial cell G0 growth arrest Sivko, Gloria S., BS, DV M 19 May 2004 (has links) No description available. Biology, Molecular human mammary epithelial cells cytokine breast cancer CCAAT/Enhancer Binding Protein (C/EBP) CCAAT/Enhancer Binding Protein &948 (C/EBP&948 ) G0 Growth Arrest

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