Análise dos genes diferencialmente expressos durante a osteodiferenciação induzida por proteínas morfogenéticas de osso (BMP2 e BMP7) em células C2C12 e super-expressão de rhBMP2 e rhBMP7 em células de mamíferos / Analysis of differentially expressed genes during osteodifferentiation induced by bone morphogenetic proteins (BMP2 and BMP7) of C2C12 cells and overexpression of rhBMP2 and rhBMP7 in mammalian cells

Valenzuela, Juan Carlos Bustos

23 April 2008

As BMPs (Bone Morphogenetic Proteins) são membros da superfamília de proteínas TGF-β (Transforming Growth Factor β ), regulam o crescimento e diferenciação de vários tipos celulares em diversos tecidos, e algumas delas desempenham um papel crítico na diferenciação de células de origem mesenquimal em osteoblastos. Particularmente, rhBMP2 e rhBMP7, promovem osteoindução tanto \"in vitro\" como \"in vivo,\" sendo, ambas as proteínas utilizadas terapeuticamente em Ortopedia/Odontologia para reparo ósseo. A expressão diferencial de genes durante a osteodiferenciação de células C2C12 induzida por rhBMP2 e rhBMP7, foi analisada através de microarranjos de DNA, selecionando 31 genes, dos quais 24 foram validados por qPCR, 13 dos quais são relacionados à transcrição, quatro associados a algumas vias de sinalização celular e sete associados à matriz extracelular. Análise funcional destes genes permitirá conhecer, com maiores detalhes, os eventos moleculares que ocorrem durante a diferenciação osteoblástica de células C2C12 induzida por rhBMPs. Em paralelo, foi perseguida a super-expressão de rhBMP2 e rhBMP7 em células HEK293T, demonstrando-se a atividade de rhBMP7, induzindo osteodiferenciação \"in vitro\" e formação de osso \"in vivo\", demonstrando a viabilidade do objetivo de se produzir estas proteínas para futura aplicação como biofármacos no Brasil. / The BMPs (Bone Morphogenetic Proteins) are members of the TGF-β (Transforming Growth Factor β) superfamily of proteins, regulate growth and differentiation of various cell types in various tissues, and some play a critical role in differentiation of mesenchymal cells into osteoblasts. Particularly, rhBMP2 and rhBMP7, promote osteoinduction \"in vitro\" and \"in vivo\" and both proteins are used therapeutically in Orthopedics and Dentistry. The differential expression of genes during osteodifferentiation induced by rhBMP2 and rhBMP7 in C2C12 cells was analyzed through DNA microarrays, allowing the selection of 31 genes, of which 24 were validated by qPCR, 13 of which are related to transcription, four associated with cell signaling pathways and seven are associated with the extracellular matrix. Subsequent functional analysis of these genes should reveal more details on the molecular events which take place during C2C12 cells osteoblastic differentiation induced by rhBMPs In paralel, rhBMPs 2 and 7 were overexpressed in HEK293T cells and BMP7 activity to induce osteodifferentiation \"in vitro\" and bone formation \"in vivo\" was demonstrated, reinforcing the viability of our objective to produce these proteins for future application as biopharmaceuticals in Brazil.

BMPs

BMPs

Bone repair

Cellular differentiation

Diferenciação celular

Diferenciação osteoblástica

Expressão de proteínas recombinantes

Osteoblast differentiation

Osteoblastos

Osteoblasts

Recombinant protein expression

Reparo ósseo

Génération et optimisation de microtissus musculaires 3D in vitro / Generation and optimization of 3D muscle microtissues in vitro

Kalman, Benoît

06 October 2016

L’ingénierie du tissu musculaire squelettique vise à reconstituer in vitro un tissu fonctionnel aussi physiologique que possible dans le but de mieux comprendre la myogenèse, l’impact de mutations génétiques et tester des médicaments. Ces dernières années, différents modèles de tissus musculaires tridimensionnels ont été développés. Toutefois, l’utilisation prépondérante de cellules murines et la taille de ces modèles restreint leur pertinence pour les études de pathologies humaines et le criblage pharmacologique. Dans le cadre de ce travail de thèse, nous avons donc développé différents modèles de tissus musculaires humains micrométriques pour répondre à ces limitations. Dans un premier temps, nous avons conçu et optimisé par microfabrication une plateforme caractérisée par la présence de microcanaux. Nous avons ainsi généré des tissus musculaires multicouches alignés présentant une organisation proche du muscle natif à partir de myoblastes murins immortalisés C2C12 puis de myoblastes humains immortalisés. Nous avons ainsi montré l’influence de la topographie et de la concentration cellulaire sur l’alignement des myotubes et la maturation du tissu musculaire. Dans un second temps, nous avons développé une plateforme constituée de micropuits contenant chacun deux micropiliers permettant d’analyser la contractilité des tissus. Des microtissus musculaires 3D standardisés ont ainsi été générés avec cette plateforme à partir de myoblastes murins, et de myoblastes C2C12 électroporés avec un gène muté ou non de la desmine. Par la suite, des microtissus ont été générés à partir de myoblastes humains. L’importance du choix de la matrice dans la formation des microtissus et les bénéfices d’une coculture de myoblastes et fibroblastes dans la stabilité des tissus ont ainsi été mis en évidence. La géométrie de micropiliers a aussi été optimisée afin de générer et comparer des microtissus composés de myoblastes isolés de patients sains et malades (dystrophie musculaire de Duchenne). Une preuve de concept démontrant la possibilité d’utiliser cette technologie pour tester des thérapies chimiques et géniques a été établie. Nous avons en effet suivi en temps réel les effets de l’inhibiteur de la kinase Rho-associée Y-27632 sur la contractilité des microtissus, ainsi que la transduction d’un gène rapporteur fluorescent modèle par les cellules composant les microtissus. Les résultats de ce travail de thèse démontrent le potentiel de cette technologie pour l’étude des processus fondamentaux de la myogenèse, l’évaluation des effets fonctionnels de mutations patient-spécifique et le criblage de thérapies chimiques et géniques. / Skeletal muscle tissue engineering aims to build functional and physiological tissues in vitro in order to better understand myogenesis, to investigate the impact of genetic mutations and to screen potential therapies. Over the past few years, bi- and tridimensional models of muscle tissue have been developed, but most of these models are based on the use of murine cells and require large amounts of cells, thus limiting their relevance to study pathologies of human muscles and drug screening assays. Here we aimed at developing different models of human muscle microtissues to address these issues. By using microfabrication techniques, we first engineered a microgrooved platform we used to generate aligned multilayered skeletal muscle tissues from murine C2C12 myoblasts and human immortalized myoblasts. We showed the impact of topography and cell density on the maturation and myotube alignment. We then fabricated a microdevice, consisting of microwells containing two micropillars allowing an easy access to the contractility of muscle tissues. We engineered microtissues from C2C12 and C2C12 myoblasts electroporated with a mutated gene of desmin, and showed some limitation of this technique of transduction. Finally, we generated microtissues from human myoblasts. We investigated the role of the extracellular matrix in the tissue formation and evidenced the benefits of coculturing myoblasts and fibroblasts on the stability of muscle microtissues. Furthermore, we optimized the geometry of the micropillars to engineer and compare microtissues composed of human myoblasts isolated from healthy and diseased (Duchenne muscular dystrophy) patients. A proof of concept of the potential of this technology for screening chemical and gene therapies was established. We were indeed able to analyze in real time the effects of the Rho-associated kinase-inhibitor Y-27632 on the tissue contractility, as well as the transduction of a model fluorescent reporter gene. Altogether, the results of this work demonstrate the potential of this technology to study fundamental muscle biology, examine functional effects of patient-specific mutations or screen chemical and gene therapies.

Ingénierie tissulaire

Muscle squelettique

Différentiation cellulaire

Myoblaste

Culture cellulaire 3D

Coculture

Tissue engineering

Skeletal muscle

Cellular differentiation

Myoblast

3D cell culture

Coculture

620

Isolamento e caracterização de células-tronco obtidas de corações de camundongos adultos.

Silva, Daniela Nascimento

January 2014

Submitted by Ana Maria Fiscina Sampaio (fiscina@bahia.fiocruz.br) on 2014-07-21T17:48:02Z No. of bitstreams: 1 Daniela Nascimento Siilva, Isolamento e caracterização... 2014a.pdf: 1250843 bytes, checksum: 1e4824ac04c822156d7a910d485dbc6b (MD5) / Made available in DSpace on 2014-07-21T17:48:02Z (GMT). No. of bitstreams: 1 Daniela Nascimento Siilva, Isolamento e caracterização... 2014a.pdf: 1250843 bytes, checksum: 1e4824ac04c822156d7a910d485dbc6b (MD5) Previous issue date: 2014 / Fundação Oswaldo Cruz. Centro de Pesquisa Gonçalo Moniz. Salvador, BA, Brasil / O uso de células-tronco representa uma alternativa para o tratamento das doenças que acometem o coração, devido à capacidade que essas células indiferenciadas têm de preservar sua própria população e de se diferenciar em células dos diversos tecidos, incluindo o cardíaco. Nesse trabalho comparamos as características de células-tronco isoladas a partir do tecido cardíaco e da medula óssea de camundongos transgênicos para a proteína fluorescente verde (GFP). As células-tronco cardíacas e da medula óssea apresentaram característica morfológica fibroblastóide e imunofenotípica de células-tronco mesenquimais, com alta expressão dos marcadores CD44, CD90, CD73, Sca-1 e baixa expressão dos marcadores de células hematopoiéticas. A análise citogenética revelou um cariótipo poliplóide a partir da terceira passagem das células-tronco isoladas do coração e da medula-óssea. A capacidade de diferenciação em vários tipos celulares, tais como adipócitos, osteócitos e condrócitos, também foi avaliada nas células-tronco de ambas as fontes. Tanto as células-tronco isoladas do coração como da medula óssea foram capazes de se diferenciar nessas três linhagens. Quando estimuladas com 5’azacitidina para testar o potencial cardiomiogênico das células isoladas do coração e da medula óssea, apenas as células-tronco cardíacas passaram a expressar alguns marcadores de cardiomiócitos, tais como troponina T cardíaca e GATA-4. As células-tronco cardíacas GFP+ foram injetadas na parede lateral do ventrículo esquerdo de camundongos C57BL/6. Nenhum animal morreu durante o procedimento, e os parâmetros funcionais cardíacos mantiveram-se inalterados. Após 48 horas e uma semana depois da injeção foi possível observar células GFP+ em secções do miocárdio. Os resultados indicam que células-tronco isoladas do coração e da medula óssea possuem características similares, porém o potencial cardiomiogênico das células-tronco cardíacas é maior. A injeção intramiocárdica mostrou-se segura podendo ser candidata à via de administração de células no miocárdio. Novos estudos no campo da medicina regenerativa que visam a utilização de células-tronco cardíacas poderão ser úteis para demonstrar sua aplicação clínica como opção de tratamento para as doenças cardíacas. / Stem cells are undifferentiated cells with the ability of self-renewal and differentiation into different cell types, with the potential to treat heart diseases. In the present study we compared the characteristics of stem cells isolated from the heart to bone marrow stem cells, both obtained from EGFP transgeneic mice. Cardiac and bone marrow stem cells presented fibroblastic morphology and an immunophenotype compatible with mesenchymal stem cells – high expression of CD44, CD90, CD73, Sca-1 and low expression of of hematopoietic lineage markers. Cytogenetic analysis demonstrated polyploid karyotypes after the third passage of the stem cells isolated from heart and bone marrow. Both bone marrow and heart stem cells were able to differentiate into adipocytes, osteocytes and chondrocytes. In order to test the potential of differentiation into cardiomyocytes, cells were stimulated with 5’azacytidine and only cardiac stem cells expressed heart-specific markers: cardiac T troponin and GATA-4. GFP+ cardiac stem cells were injected into the lateral wall of the left ventricule of C57bl/6 mice. The procedure did not alter the functional cardiac parameters or induced mortality. GFP+ cells were observed in the heart 48 hours and seven days after the intramyocardial injection. The results indicate that cardiac stem cells and bone marrow stem cells are similar cell populations, although cardiac stem cells appear to have an increased cardiomyogenic potential. Intramyocardial injection was a safe and useful procedure for the transplantation of cardiac stem cells. New studies in the field of regenerative medicine aimed at the use of cardiac stem cells may be useful to demonstrate its clinical application as a treatment option for heart disease.

Coração

Medula óssea

Células-tronco mesenquimais

Caracterização

Diferenciação celular

Injeção intramiocárdica

Heart

Bone marrow

Mesenchymal stem cells

Characterization

Cellular differentiation

Intramyocardial injection

Análise dos genes diferencialmente expressos durante a osteodiferenciação induzida por proteínas morfogenéticas de osso (BMP2 e BMP7) em células C2C12 e super-expressão de rhBMP2 e rhBMP7 em células de mamíferos / Analysis of differentially expressed genes during osteodifferentiation induced by bone morphogenetic proteins (BMP2 and BMP7) of C2C12 cells and overexpression of rhBMP2 and rhBMP7 in mammalian cells

Juan Carlos Bustos Valenzuela

23 April 2008

As BMPs (Bone Morphogenetic Proteins) são membros da superfamília de proteínas TGF-β (Transforming Growth Factor β ), regulam o crescimento e diferenciação de vários tipos celulares em diversos tecidos, e algumas delas desempenham um papel crítico na diferenciação de células de origem mesenquimal em osteoblastos. Particularmente, rhBMP2 e rhBMP7, promovem osteoindução tanto \"in vitro\" como \"in vivo,\" sendo, ambas as proteínas utilizadas terapeuticamente em Ortopedia/Odontologia para reparo ósseo. A expressão diferencial de genes durante a osteodiferenciação de células C2C12 induzida por rhBMP2 e rhBMP7, foi analisada através de microarranjos de DNA, selecionando 31 genes, dos quais 24 foram validados por qPCR, 13 dos quais são relacionados à transcrição, quatro associados a algumas vias de sinalização celular e sete associados à matriz extracelular. Análise funcional destes genes permitirá conhecer, com maiores detalhes, os eventos moleculares que ocorrem durante a diferenciação osteoblástica de células C2C12 induzida por rhBMPs. Em paralelo, foi perseguida a super-expressão de rhBMP2 e rhBMP7 em células HEK293T, demonstrando-se a atividade de rhBMP7, induzindo osteodiferenciação \"in vitro\" e formação de osso \"in vivo\", demonstrando a viabilidade do objetivo de se produzir estas proteínas para futura aplicação como biofármacos no Brasil. / The BMPs (Bone Morphogenetic Proteins) are members of the TGF-β (Transforming Growth Factor β) superfamily of proteins, regulate growth and differentiation of various cell types in various tissues, and some play a critical role in differentiation of mesenchymal cells into osteoblasts. Particularly, rhBMP2 and rhBMP7, promote osteoinduction \"in vitro\" and \"in vivo\" and both proteins are used therapeutically in Orthopedics and Dentistry. The differential expression of genes during osteodifferentiation induced by rhBMP2 and rhBMP7 in C2C12 cells was analyzed through DNA microarrays, allowing the selection of 31 genes, of which 24 were validated by qPCR, 13 of which are related to transcription, four associated with cell signaling pathways and seven are associated with the extracellular matrix. Subsequent functional analysis of these genes should reveal more details on the molecular events which take place during C2C12 cells osteoblastic differentiation induced by rhBMPs In paralel, rhBMPs 2 and 7 were overexpressed in HEK293T cells and BMP7 activity to induce osteodifferentiation \"in vitro\" and bone formation \"in vivo\" was demonstrated, reinforcing the viability of our objective to produce these proteins for future application as biopharmaceuticals in Brazil.

BMPs

Diferenciação celular

Diferenciação osteoblástica

Expressão de proteínas recombinantes

Osteoblastos

Reparo ósseo

BMPs

Bone repair

Cellular differentiation

Osteoblast differentiation

Osteoblasts

Recombinant protein expression

The role of CFP1 in murine embryonic stem cell function and liver regeneration

Mahadevan, Jyothi

11 May 2015

Indiana University-Purdue University Indianapolis (IUPUI) / CXXC finger protein 1 (Cfp1), a component of the Set1 histone methyltransferase complex, is a critical epigenetic regulator of both histone and cytosine methylation. Murine embryos lacking Cfp1 are unable to gastrulate and Cfp1-null embryonic stem (ES) cells fail to undergo cellular differentiation in vitro. However, expression of wild type Cfp1 in Cfp1-null ES cells rescues differentiation capacity, suggesting that dynamic epigenetic changes occurring during lineage specification require Cfp1. The domain structure of Cfp1 consists of a DNA binding CXXC domain and an N-terminal plant homeodomain (PHD). PHDs are frequently observed in chromatin remodeling proteins, functioning as reader modules for histone marks. However, the histone binding properties and underlying functional significance of Cfp1 PHD are largely unknown. My research revealed that Cfp1 PHD directly and specifically binds to histone H3K4me1/me2/me3 marks. A point mutation that abolishes binding to methylated H3K4 (W49A) does not affect rescue of cellular differentiation, but, point mutations that abolish both methylated H3K4 (W49A) and DNA (C169A) binding result in defective in vitro differentiation, indicating that PHD and CXXC exhibit redundant functions. The mammalian liver has the unique ability to regenerate following injury. Previous studies indicated that Cfp1 is essential for hematopoiesis in zebrafish and mice. I hypothesized that Cfp1 additionally plays a role in liver development and regeneration. To understand the importance of Cfp1 in liver development and regeneration, I generated a mouse line lacking Cfp1 specifically in the liver (Cfp1fl/fl Alb-Cre+). Around 40% of these mice display a wasting phenotype and die within a year. Livers of these mice have altered global H3K4me3 levels and often exhibit regenerative nodules. Most importantly, livers of these mice display an impaired regenerative response following partial hepatectomy. Collectively, these findings establish Cfp1 as an epigenetic regulator essential for ES cell function and liver homeostasis and regeneration.

Cellular differentiation

Chromatin

Epigenetics

Histones

Liver regeneration

DNA-protein interactions

Chromatin

Methyltransferases

Thymidlylate synthase

Histones

Liver -- Regeneration

Embryonic stem cells

Mice as laboratory animals

Cell Cycle Regulation and Cellular Differentiation in the Developing Ocular Lens

Chaffee, Blake Richard

23 July 2015

No description available.

Biology

Developmental Biology

Molecular Biology

Genetics

Cyclin Dependent kinase 1

CDK1

Phosphatase and tensin homolog

Pten

Fibroblast growth factor receptors

ocular lens

cellular differentiation

cell cycle regulation

Modélisation de la réponse Immunitaire T-CD8 : analyse mathématique et modèles multiéchelles / Modeling the CD8 T-cell Immune Response : Mathematical Analysis and Multiscale Models

Girel, Simon

13 November 2018

L'infection d'un organisme par un agent pathogène déclenche l'activation des lymphocytes T-CD8 et l'initiation de la réponse immunitaire. Il s'ensuit un programme complexe de prolifération et de différenciation des lymphocytes T-CD8, contrôlé par l'évolution de leur contenu moléculaire. Dans ce manuscrit, nous présentons deux modèles mathématiques de la réponse T-CD8. Le premier se présente comme une équation différentielle à impulsions grâce à laquelle nous étudions l'effet du partage inégal des protéines lors des divisions cellulaires sur la régulation de l'hétérogénéité moléculaire. Le second est un modèle à base d'agents couplant la description d'une population discrète de lymphocytes T-CD8 à celle du contenu moléculaire de ces derniers. Ce modèle s'avère capable de reproduire les différentes phases caractéristiques de la réponse T-CD8 aux échelle cellulaire et moléculaire. Ces deux travaux supportent l'hypothèse que la dynamique cellulaire observée in vivo est le reflet de l'hétérogénéité moléculaire qui structure la population de lymphocytes T-CD8 / Infection of an organism by a pathogen triggers the activation of the CD8 T-cells and the initiation of the immune response. The result is a complex program of proliferation and differentiation of the CD8 T-cells, controlled by the evolution of their molecular content. In this manuscript, we present two mathematical models of the CD8 T-cell response. The first one is presented as an impulsive differential equation by which we study the effect of unequal molecular partitioning at cell division on the regulation of molecular heterogeneity. The second one is an agent-based-model that couples the description of a discrete population of CD8 T-cells and that of their molecular content. This model can reproduce the different typical phases of the CD8 T-cell response at both the cellular and the molecular scales. These two studies support the hypothesis that the cell dynamics observed in vivo is a consequence of the molecular heterogeneity structuring the CD8 T-cell population

Modèle à base d’agents

Équation différentielle à impulsions

Modèle multiéchelle

Convexité du flot

Réponse immunitaire

Différenciation cellulaire

Agent-based model

Impulsive differential equation

Multiscale modeling

Flow convexity

Immune response

Random partitioning of molecular content

Cellular differentiation

510

Sulfated hyaluronan alters fibronectin matrix assembly and promotes osteogenic differentiation of human bone marrow stromal cells

Vogel, Sarah, Arnoldini, Simon, Möller, Stephanie, Hempel, Ute, Schnabelrauch, Matthias

28 March 2017

Extracellular matrix (ECM) composition and structural integrity is one of many factors that influence cellular differentiation. Fibronectin (FN) which is in many tissues the most abundant ECM protein forms a unique fibrillary network. FN homes several binding sites for sulfated glycosaminoglycans (sGAG), such as heparin (Hep), which was previously shown to influence FN conformation and protein binding. Synthetically sulfated hyaluronan derivatives (sHA) can serve as model molecules with a well characterized sulfation pattern to study sGAG-FN interaction. Here is shown that the low-sulfated sHA (sHA1) interacts with FN and influences fibril assembly. The interaction of FN fibrils with sHA1 and Hep, but not with non-sulfated HA was visualized by immunofluorescent co-staining. FRET analysis of FN confirmed the presence of more extended fibrils in human bone marrow stromal cells (hBMSC)-derived ECM in response to sHA1 and Hep. Although both sHA1 and Hep affected FN conformation, exclusively sHA1 increased FN protein level and led to thinner fibrils. Further, only sHA1 had a pro-osteogenic effect and enhanced the activity of tissue non-specific alkaline phosphatase. We hypothesize that the sHA1-triggered change in FN assembly influences the entire ECM network and could be the underlying mechanism for the pro-osteogenic effect of sHA1 on hBMSC.

info:eu-repo/classification/ddc/520

ddc:520