Role of fibroblast growth factor signalling on the regulation of embryonic stem cells

Freile Vinuela, Paz

January 2008

Fibroblast growth factor (FGF) signalling plays many fundamentally important roles during the development of the mammalian embryo. However, its effects on pluripotent stem cells derived from mouse and human embryos appear to be markedly different. FGF2 is routinely added to culture medium for propagating undifferentiated human (hES) cells, whereas in mouse (mES) cell cultures FGFs have been described as regulators of their differentiated progeny. To assess the effect of FGF signalling on undifferentiated mES cells, the effects of FGF2 and 4 were analysed in the presence of saturating and sub-saturating levels of the inhibitor of differentiation, leukaemia inhibitory factor (LIF). Mouse ES cell self-renewal was quantified by measuring the expression of the stem cell specific reporter Oct4-LacZ in biochemical and fluorometric assays. Treatment with FGF reduced the expression of the OCT4-LacZ reporter, even under saturating concentrations of LIF and this was mirrored by decreased levels of OCT4 protein. Furthermore, treatment with FGF leads to upregulation of the ectodermal differentiation marker Pax6. These results suggest that FGF signalling has a direct impact on undifferentiated mES cells, and actively promotes their differentiation. To asses the effect of FGF signalling on hES cells without the influence of undefined factors, a feeder and serum free system was developed. Cells growing in this conditions for >20 passages maintained expression of surface (SSEA3 and TRA1-60 and 81) and internal (OCT4) markers specific for undifferentiated hES cells. Expression of these markers was dependant on the continuous presence of FGF2. Indeed, withdrawal of FGF2 resulted in a rapid decrease of in hES cell growth and of the emergence of cell flattened morphology and of the surface marker SSEA1, changes typically associated with differentiation. Two important signals activated by FGF in hES cells are the ERK/MAPK and PI3K pathways. To assess their functional relevance, hES cell cultures were treated with the drugs UO126 and LY294002, inhibitors of the MAPK and PI3K pathways respectively. Drug mediated suppression of the phosphorylation of these pathways, correlated with a reduction in cell growth, flattening of the colonies and reduction in SSEA4 expression. Use of SB431542, specific inhibitor of TGFβ/activin type I receptor kinase (Alk5) also resulted in the flattening of the colonies and the appearance of dispersed cells. Therefore, inhibition of MAPK and PI3K appears to impair growth and self-renewal in hES cells and this may be happening in conjunction with TGFβ/Activin pathway. Taken together, these results suggest that FGF signalling has opposite effects in mouse and human ES cells: inducing differentiation in mES and sustaining self-renewal in hES.

571.6

Studies On Embryonic Stem Cells From Enhanced Green Fluorescent Protein Transgenic Mice : Induction Of Cardiomyocyte Differentiation

Singh, Gurbind

06 1900

Genesis of life begins with the fusion of female and male haploid gametes through a process of fertilization leading to the formation of a diploid cell, the zygote. This undergoes successive cleavage divisions forming 2-, 4- and 8- cell embryos and their individual cells (blastomeres) are totipotent. As development proceeds, there is a gradual restriction in their totipotency, resulting in the generation of two distinct cell lineages i.e., the differentiated trophectoderm (TE) cells and the undifferentiated, inner cell mass (ICM) during blastocyst morphogenesis (Rossant and Tam 2009). During the course of development, the ICM cells can give rise to all cell types of an organism and can also provide embryonic stem (ES)-cells when cultured in vitro (Evan and Kaufman 1981). ES-cells are pluripotent cells, having the ability to self-renew indefinitely and differentiate into all the three primary germ layers (ectoderm, mesoderm and endoderm) derived-cell types. ES-cells are an excellent developmental model system to understand basic mechanisms of self-renewal, cell differentiation and function of various genes in vitro and in vivo (Capecchi 2001). Importantly, their cell derivatives could potentially be used for experimental cell-based therapy for a number of diseases. Although, human ES-cell lines have been successfully derived and differentiated to various cell types (Thomson et al., 1998; Odorico et al., 2001), their cell-therapeutic potential is far from being tested, in view of the lack of our understanding of lineage-specific differentiation, homing and structural-functional integration of differentiated cell types in the host environment. To understand these mechanisms, it is desirable to have fluorescently-marked ES-cells and their differentiated cell-types, which could facilitate experimental cell transplantation studies. In this regard, our laboratory has earlier generated enhanced green fluorescent protein (EGFP)-expressing FVB/N transgenic ‘green’ mouse, under the control of ubiquitous chicken -actin promoter (Devgan et al., 2003). This transgenic mouse has been an excellent source of intrinsically green fluorescent cell types. We have been attempting to derive ES-cell line from this transgenic mouse. Because the derivation of ES-cell line is genetic strain-dependent, with some strains being relatively permissible for ES-cell derivation while others are quite resistant (non permissive), it has been extremely difficult to derive ES-cell line from the FVB/N mouse strain. There is a need to evolve experimental strategies to derive ES-cell line from FVB/N mouse, a strain extensively used for transgenesis. Thus, the aims of the study described in the thesis are to: (1) develop an experimental system to derive EGFP-expressing fluorescently-marked ES-cell line from a non-permissive FVB/N mouse strain; (2) characterize the established ES-cell line; (3) achieve differentiation of various cell types from EGFP-expressing ES-cell line and (4) understand role of FGF signaling in cardiac differentiation from the established ES-cell line. In order to have an appropriate and relevant literature background, the 1st chapter in this thesis describes a comprehensive up-to-date review of literature, pertaining to the early mammalian development and differentiation of blastocyst, followed by origin and properties of ES-cells. Various ES-cell derivation strategies from genetically permissive and non-permissive mouse strains are described and also the ES-cell differentiation potential to various progenitors and differentiated cell types. Subsequently, details on molecular basis of cardiac differentiation and the therapeutic potential of ES-cell derived differentiated cell types to treat disease(s) are described. This chapter is followed by three data chapters (II-IV). Chapter-II describes the issues related to non-permissiveness of FVB/N strain for ES-cell derivation and strategies to overcome this hurdle. This is followed by detailed results pertaining to generation of homozygous EGFP-expressing transgenic mice and development of a two-pronged ES-cell derivation approach to successfully establish a permanent ES-cell line (named ‘GS-2’ ES-cell line) from the EGFP-transgenic ‘green’ mouse. This chapter also provides results pertaining to detailed characterization of the ‘GS-2’ ES-cell line which includes colony morphology, expansion efficiency, alkaline phosphatase staining, expression analysis of pluripotent markers by RT-PCR and immunostaining approaches and karyotyping. Following this, the outcome of results and significance in the context of reported information are discussed in detail. Having successfully derived the ‘GS-2’ ES-cell line, it is necessary to thoroughly assess the differentiation competence of the ‘GS-2’ ES-cell line. Therefore, the Chapter-III describes detailed assessment of the in vitro and in vivo differentiation potential of the ‘GS-2’ ES-cell line. For in vitro differentiation, results pertaining to ES-cell derived embryoid body (EB) formation and their differentiation to ectodermal, mesodermal and endodermal cell types, expressing nestin, BMP-4 and α-fetoprotein, respectively, are described. Besides, the robustness of adaptability of ‘GS-2’ ES-cells to various culture conditions for their maintenance and differentiation are described. Also shown in the chapter is the relatively greater propensity of this cell line to cardiac differentiation. For in vivo differentiation, the ‘GS-2’ ES-cell derived teratoma formation in nude mice and its detailed histological analysis showing three germ layer cell types and their derivatives are described. Last part of the data described in this chapter, pertains to generation of chimeric blastocysts by aggregation method. Because the ‘GS-2’ ES-cell line exhibited a robust differentiation potential, including an efficient cardiomyocyte differentiation, it is of interest to enhance the efficiency of cardiomyocyte differentiation by exogenous addition of one of the key growth factors i.e., FGF8b since this has been implicated to be critical for cardiogenesis in non-mammalian verterbrate species. Therefore, Chapter-IV is focused on assessing the ability of ‘GS-2’ ES-cell line for its cardiomyocyte differentiation property with particular emphasis on the FGF-induced cardiac differentiation. Results pertaining to the expressions of various FGF ligands and their receptors during differentiation of ES-cells are described. Besides, increases in the cardiac efficiency, following FGF8b treatment and the associated up-regulation of cardiac-specific markers such as GATA-4, ISL-1 and α-MHC are shown. At the end of data chapters, separate sections are devoted for ‘Summary and Conclusion’ and for ‘Bibliography’.

Experimental Research

Stem Cells

Transgenic Mice

Cardiomyocyte Differentiation

Embryonic Stem Cells

Fibroblast Growth Factor (FGF)

Embryonic Stem Cell Line

ES-cells

Molecular Biology

Apical Ectodermal Ridge (AER) activity and limb outgrowth during vertebrate development11

Viegas Tomás, Ana Raquel

11 January 2011

Limb outgrowth is controlled by a specialized group of cells called the apical ectodermal ridge (AER), a thickening of the limb epithelium, at its distal tip. This specialized thickening of ectodermal cells is responsible for maintaining the underlying mesenchymal cells in an undifferentiated and proliferative state, and its structure is preserved through a fine-tuned balance between proliferation and apoptosis. This equilibrium is genetically controlled but little is known about the molecules involved in this process. Several authors have been shown that both fibroblast growth factor (FGF) and Erk pathway activation are crucial for AER function. Recently, FLRT3, a transmembrane protein able to interact with FGF receptors, has been implicated in the triggering of ERK activity by FGFs. In this thesis, we show that flrt3 expression is restricted to the AER, co-localizing its expression with fgf8 and pERK activity. Loss-of-function studies demonstrate that silencing of flrt3 affects the integrity of the AER and, subsequently, its proper function during limb bud outgrowth. Our data also indicate that flrt3 expression is not regulated by FGF activity in the AER, whereas ectopic WNT3A is able to induce flrt3 expression. Overall, our findings confirm flrt3 as a key player during chicken limb development, being necessary but not sufficient for proper AER formation and maintenance under the control of BMP and WNT signalling. During limb bud development, AER structure is maintained through a fine-tuned balance between proliferation and programmed cell death and this equilibrium is genetically controlled, although little is known about the molecules involved in that process. In this thesis we present evidences involving oct4, required to establish and maintain the pluripotent cell population necessary for embryogenesis in mouse and human, in the control of the proliferative balance within the AER cells. Overexpression of otc4 in the limb ectoderm disrupts the ratio apoptosis/proliferation and, moreover, oct4 expression is under the control of wnt-canonical pathway. We also describe a special localization and behaviour of proliferating cells in the AER in response to oct4 activity. We, therefore, describe a role for oct4 as a factor able to maintain a niche of cells that is responsible for the renewal of the AER. / El crecimiento del esbozo de la extremidad está controlado por un grupo especializado de células denominado Cresta Ectodérmica Apical (CEA), un engrosamiento del epitelio del miembro en su borde más distal. Este engrosamiento es responsable del mantenimiento de las células del mesodermo distal en un estado indiferenciado y proliferativo. Diferentes estudios muestran que la actividad de los factores de crecimiento fibroblástico (FCF) y de la vía Erk son cruciales para la correcta funcionalidad de la CEA. Recientemente se ha implicado a FLRT3, una proteína transmembranal capaz de interaccionar con los receptores de los FCF, en la activación de la vía Erk por los mismos. En esta tesis describimos cómo la expresión de flrt3 se restringe a la CEA, colocalizándose su expresión con fgf8 y la actividad de la vía Erk. Los experimentos de pérdida de función demuestran que la inhibición de flrt3 afecta la integridad de la CEA y, consecuentemente, a su función durante el desarrollo del esbozo del miembro. Nuestros datos también indican que la expresión de flrt3 no está regulada a través de los FCF en la CEA, sin embargo, la activación ectópica de WNT3A es capaz de inducir la expresión de flrt3. En conjunto, nuestros resultados demuestran que flrt3 es una molécula clave durante el desarrollo de las extremidades de pollo, siendo necesaria, pero no suficiente, para la correcta formación y mantenimiento de la CEA bajo el control de la señalización a través de BMP y WNT. Durante el desarrollo de las extremidades, la estructura de la CEA se mantiene a través de un fino control del balance entre la proliferación y apoptosis. Este equilibrio se encuentra genéticamente controlado aunque se sabe muy poco acerca de las moléculas involucradas en este proceso. En esta tesis presentamos evidencias en las que oct4, molécula necesaria para establecer y mantener la población de células pluripotentes necesarias durante la embriogénesis en ratón y humanos, controla la tasa de proliferación en las células de la CEA. La expresión ectópica de oct4 en el ectodermo del esbozo de la extremidad perturba la razón entre la apoptosis y la proliferación y, además, su expresión está controlada por la actividad de la vía canónica de los Wnt. También describimos en este trabajo la localización y comportamiento especiales de las células de la CEA en proliferación como respuesta a la actividad de oct4. Por consiguiente, podemos inferir que el rol de oct4 será el de un factor necesario para mantener un nicho celular responsable por la renovación de la CEA.

AER structure

Apical Ectodermal Ridge (AER)

Apoptosis

BMP signalling

Chicken limb development

Fibroblast growth factor (FGF)

Limb outgrowth

Epithelial renewal

Cresta Ectodérmica Apical (CEA)

Desarrollo de la extremidad

Señalización a través de WNT

FLRT3

Oct4

612

An Approach to Lens Regeneration in Mice Following Lentectomy and the Implantation of a Biodegradable Hydrogel Encapsulating Iris Pigmented Tissue in Combination with Basic Fibroblast Growth Factor

Baddour, Joelle

11 May 2012

No description available.

Biology

Biomedical Engineering

Biomedical Research

Chemical Engineering

Developmental Biology

Lens Regeneration

Iris Pigmented Epithelial Cells

Lens Epithelial Cells

Transdifferentiation

Differentiation

Fibroblast Growth Factor (FGF)

Hydrogel

Poly-&949

-caprolactone (PCL)

Nanofibers

Mouse