Mechanical cell properties in germ layer progenitor migration during zebrafish gastrulation / Mechanische Eigenschaften der Keimblatt-Vorläuferzellen während der Migration in der Zebrafisch-Gastrulation

Arboleda-Estudillo, Yoana

07 April 2010

Gastrulation leads to the formation of the embryonic germ layers, ectoderm, mesoderm and endoderm, and is the first key morphogenetic process that occurs in development. Gastrulation provides a unique developmental assay system in which to study cellular movements and rearrangements in vivo. The different cell movements occurring during gastrulation take place in a highly coordinated spatial and temporal manner, indicating that they must be controlled by a complex interplay of morphogenetic and inductive events. Generally, cell movement constitutes a highly integrated program of different cellular behaviors including sensing, polarization, cytoskeletal reorganization, and changes in adhesion and cell shape. During migration, these different behaviors require a continuous regulation and feedback control to direct and coordinate them. In this work, we analyze the cellular and molecular mechanisms underlying the different types of cell behaviors during gastrulation in zebrafish. Specifically, we focus on the role of the adhesive and mechanical properties of germ layer progenitors in the regulation of gastrulation movements. In the first part of the project, we investigated the role of the adhesive and mechanical properties of the different germ layer progenitor cell types for germ layer separation and stratification. In the second part of this study, we applied the same methodology to determine the function of germ layer progenitor cell adhesion in collective cell migration. Tissue organization is thought to depend on the adhesive and mechanical properties of the constituent cells. However, it has been difficult to determine the precise contribution of these different properties due to the lack of tools to measure them. Here we use atomic force microscopy (AFM) to quantify the adhesive and mechanical properties of the different germ layer progenitor cell types. Applying this methodology, we demonstrate that mesoderm and endoderm progenitors are more adhesive than ectoderm cells and that E-cadherin is the main adhesion molecule regulating this differential adhesion. In contrast, ectoderm progenitors exhibit a higher actomyosin-dependent cell cortex tension than mesoderm and endoderm progenitors. Combining these data with tissue self-assembly in vitro and in vivo, we provide evidence that the combinatorial activities of cell adhesion and cell cortex tension direct germ layer separation and stratification. It has been hypothesized that the directionality of cell movement during collective migration results from a collective property. Using a single cell transplantation assay, we show that individual progenitor cells are capable of normal directed migration when moving as single cells, but require cell-cell adhesion to participate in coordinated and directed migration when moving collectively. These findings contribute to the understanding of the gastrulation process. Cell-cell adhesion is required for collective germ layer progenitor cell migration, and cell cortex tension is critical for germ layer separation and stratification. However, many questions still have to be solved. Future studies will have to explore the interaction between the adhesive and mechanical progenitor cell properties, as well as the role of these properties for cell protrusion formation, cell polarization, interaction with extracellular matrix, and their regulation by different signaling pathways.

zebrafish

gastrulation

germ layer progenitor cell migration

adhesion

tension

E-cadherin

myosin

Nodal

Zebrafisch

Gastrulation

Keimblattvorläuferzellen-Migration

Adhäsion

Zelloberflächenspannung

E-cadherin

Myosin

Nodal

ddc:570

rvk:WG 2100

Mechanical cell properties in germ layer progenitor migration during zebrafish gastrulation

Arboleda-Estudillo, Yoana

25 March 2010

Gastrulation leads to the formation of the embryonic germ layers, ectoderm, mesoderm and endoderm, and is the first key morphogenetic process that occurs in development. Gastrulation provides a unique developmental assay system in which to study cellular movements and rearrangements in vivo. The different cell movements occurring during gastrulation take place in a highly coordinated spatial and temporal manner, indicating that they must be controlled by a complex interplay of morphogenetic and inductive events. Generally, cell movement constitutes a highly integrated program of different cellular behaviors including sensing, polarization, cytoskeletal reorganization, and changes in adhesion and cell shape. During migration, these different behaviors require a continuous regulation and feedback control to direct and coordinate them. In this work, we analyze the cellular and molecular mechanisms underlying the different types of cell behaviors during gastrulation in zebrafish. Specifically, we focus on the role of the adhesive and mechanical properties of germ layer progenitors in the regulation of gastrulation movements. In the first part of the project, we investigated the role of the adhesive and mechanical properties of the different germ layer progenitor cell types for germ layer separation and stratification. In the second part of this study, we applied the same methodology to determine the function of germ layer progenitor cell adhesion in collective cell migration. Tissue organization is thought to depend on the adhesive and mechanical properties of the constituent cells. However, it has been difficult to determine the precise contribution of these different properties due to the lack of tools to measure them. Here we use atomic force microscopy (AFM) to quantify the adhesive and mechanical properties of the different germ layer progenitor cell types. Applying this methodology, we demonstrate that mesoderm and endoderm progenitors are more adhesive than ectoderm cells and that E-cadherin is the main adhesion molecule regulating this differential adhesion. In contrast, ectoderm progenitors exhibit a higher actomyosin-dependent cell cortex tension than mesoderm and endoderm progenitors. Combining these data with tissue self-assembly in vitro and in vivo, we provide evidence that the combinatorial activities of cell adhesion and cell cortex tension direct germ layer separation and stratification. It has been hypothesized that the directionality of cell movement during collective migration results from a collective property. Using a single cell transplantation assay, we show that individual progenitor cells are capable of normal directed migration when moving as single cells, but require cell-cell adhesion to participate in coordinated and directed migration when moving collectively. These findings contribute to the understanding of the gastrulation process. Cell-cell adhesion is required for collective germ layer progenitor cell migration, and cell cortex tension is critical for germ layer separation and stratification. However, many questions still have to be solved. Future studies will have to explore the interaction between the adhesive and mechanical progenitor cell properties, as well as the role of these properties for cell protrusion formation, cell polarization, interaction with extracellular matrix, and their regulation by different signaling pathways.

info:eu-repo/classification/ddc/570

ddc:570

CYTOKINE MODULATION OF PROGENITOR CELL MIGRATION

Punia, Navneet

10 1900

<p><strong>Rationale: </strong>Lung-homing of bone marrow (BM)-derived progenitor cells is associated with inflammatory and remodeling changes in asthma. Stromal cell derived factor-1α (SDF-1α) is a potent progenitor cell chemoattractant and its local production in the lung promotes lung homing of progenitor cells. The role of pro-inflammatory cytokines in promoting traffic of progenitor cells to the site of inflammation in asthma has not been investigated. The TH2 cytokines, interleukin (IL)-4 and IL-13, are key regulators of asthma pathology.</p> <p><strong>Objective: </strong>To investigate the role of IL-4 and IL-13 in modulating the trans-migrational responses of hemopoietic progenitor cells (HPC).</p> <p><strong>Methods: </strong>HPC were isolated from cord blood (CB) and peripheral blood (PB) and migrational and adhesive responses were assessed using transwell migration assays and adhesion to fibronectin-coated wells, respectively. Responding cells were enumerated by flow cytometry.</p> <p><strong>Results: </strong>IL-4 and IL-13 had no direct effect on progenitor cell migration. Pre-incubation with each of these cytokines primed SDF-1α stimulated migration of CB and PB-derived HPC (CD34+45+ cells) but not eosinophil-lineage committed progenitors (CD34+45+IL- 5Rα+ cells) or mature eosinophils to SDF-1α. For HPC, priming effects of IL-4 (0.1ng/ml) and IL-13 (0.1ng/ml) were detectable within 1hr and optimal at 18hr post- incubation and IL-4 was the more effective priming agent. Disruption of lipid rafts inhibited IL-4 priming of SDF-1α stimulated migration of HPC indicating that increased incorporation of CXCR4 into membrane lipid rafts mediates the cytokine primed migrational response of HPC. This was confirmed by confocal fluorescent microscopy.</p> <p><strong>Conclusions: </strong>IL-4 and IL-13 prime the migrational response of HPC to SDF-1α by enhancing the incorporation of CXCR4 into lipid rafts. The priming effect of these cytokines is specific to primitive HPC. These data suggest that increased local production of IL-4 and IL-13 within the lungs may promote increased SDF-1α mediated homing of BM-derived HPC to the airways in asthma.</p> / Master of Science in Medical Sciences (MSMS)

Progenitor cell migration

Priming

Interleukin-4

Interleukin-13

Stromal cell-derived factor-1α

Medical Immunology