Pan-embryo cell dynamics of germlayer formation in zebrafish

Cell movements are coordinated across spatio-temporal scales to achieve precise positioning of organs during vertebrate gastrulation. In zebrafish, mechanisms governing such morphogenetic movements have so far only been studied within a local region or a single germlayer. Here, we present pan-embryo analyses of fate specification and dynamics of all three germlayers simultaneously within a gastrulating embryo, showing that cell movement characteristics are predominantly determined by its position within the embryo, independent of its germlayer identity. The spatially confined fate specification establishes a distinct distribution of cells in each germlayer during early gastrulation. The differences in the initial distribution are subsequently amplified by a unique global movement, which organizes the organ precursors along the embryonic body axis, giving rise to the blueprint of organ formation

Tissue-level Mechanisms Driving Cardiac Progenitor and Extracellular Matrix Movements during Early Vertebrate Heart Development

Vertebrate cardiogenesis involves heart progenitor cell movements from their initial lateral positions to the embryonic midline, where they assemble into a primitive heart. This early heart tube consists of an outer myocardium, a medial extracellular matrix (ECM), and an endocardial lining. Cardiac morphogenesis in avians and mammals is inseparable from development of the foregut, which provides molecular cues to regulate endocardial and myocardial differentiation from mesodermal progenitors. Concomitantly with the initiation of midline-directed cardiac progenitor movements, foregut endoderm undergoes dramatic folding and elongation. Following their initial assembly, the heart and foregut are transiently connected through a mesentery. Previous research focused on the molecular factors involved in guiding cardiac progenitors to the midline, yet cellular and tissue mechanisms coordinating these movements remain poorly understood. This work investigates movements of all three early heart constituents - the endocardial and myocardial progenitors, and surrounding ECM - in live quail embryos using a combination of time-lapse microscopy, chemical and mechanical perturbations, computational analysis and modeling. By visualizing the tissue environment for cell displacements, we distinguish the active (tissue-independent) movements from those cells undergo in a manner coordinated with the surrounding tissues. First, we analyzed the movements of endocardial progenitors and fluorescently-labeled ECM (fibronectin, fibrillin-2) fibrils. We found the bulk of midline-directed movement of pre-endocardial cells is coordinated with their surrounding ECM. Further, that ECM from extracardiac sources is transferred to and incorporated into the growing heart. By assessing the contributions of active cell motility to the observed midline endocardial displacements we found its role to be secondary to that of convective tissue movement within the anterior embryo. Second, we assessed myocardial progenitor movements relative to fibronectin ECM and endoderm. We discovered that observed antero-medial myocardial displacements are driven by a combination of: 1) medial tissue motion, and 2) anterior movement, accomplished via a coordinated deformation of myocardial progenitors, organized into a continuous epithelial sheet. Finally, we investigated the effects of VEGF overexposure on progenitor movements during early cardiogenesis. We found a dramatic VEGF-induced increase in cardiac inflow region size, which affected the coordinated movements/deformations displayed by myocardial progenitors, and resulted in heart tube elongation defects

The role of yolk syncytial layer and blastoderm movements during gastrulation in zebrafish

During gastrulation, a set of highly coordinated morphogenetic movements creates the shape and internal organization of the embryo. In teleostean fishes, these morphogenetic movements involve not only the embryonic progenitor cells (deep cells) but also two extra-embryonic tissues: an outer sheet of epithelial cells (EVL) and a yolk syncytial layer (YSL). Epiboly is characterized by the spreading of the blastoderm (deep cells and EVL) to cover the large yolk cell, whereas convergence and extension leads, respectively, to mediolateral narrowing and anteroposterior elongation of the embryo. Recent studies have shown that the nuclei of the YSL undergo epiboly and convergence and extension movements similarly to the overlying deep cells, suggesting that these tissues interact during gastrulation. However, it is so far not clear whether and how the movements of YSL nuclei and deep cells influence each other. In the first part of this thesis, the convergence and extension movement of YSL nuclei was quantitatively compared to the movement of the overlying mesendodermal progenitor (or “hypoblast)” cells. This revealed that, besides the similarity in the overall direction of movement, YSL nuclei and hypoblast cell movements display differences in speed and directionality. Next, the interaction between YSL and hypoblast was addressed. The movement of the blastoderm was analyzed when YSL nuclei movement was impaired by interfering with the YSL microtubule cytoskeleton. We found that YSL and blastoderm epiboly were strongly reduced, while convergence and extension were only mildly affected, suggesting that YSL microtubules and YSL nuclei movement are required for epiboly, but not essential for convergence and extension of the blastoderm. We also addressed whether blastodermal cells can influence YSL nuclei movement. In maternal-zygotic one-eyed pinhead (MZoep) mutant embryos, which lack hypoblast cells, YSL nuclei do not undergo proper convergence movement. Moreover, transplantation of wild type hypoblast cells into these mutants locally rescued the YSL nuclei convergence phenotype, indicating that hypoblast cells can control the movement of YSL nuclei. Finally, we propose that the hypoblast influences YSL nuclei movement as a result of shape changes caused by the collective movement of cells, and that this process requires the adhesion molecule E-cadherin

The role of yolk syncytial layer and blastoderm movements during gastrulation in zebrafish

Tese arquivada ao abrigo da Portaria nº 227/2017 de 25 julho.During gastrulation, a set of highly coordinated morphogenetic movements creates the shape and internal organization of the embryo. In teleostean fishes, these morphogenetic movements involve not only the embryonic progenitor cells (deep cells) but also two extra-embryonic tissues: an outer sheet of epithelial cells (EVL) and a yolk syncytial layer (YSL). Epiboly is characterized by the spreading of the blastoderm (deep cells and EVL) to cover the large yolk cell, whereas convergence and extension leads, respectively, to mediolateral narrowing and anteroposterior elongation of the embryo. Recent studies have shown that the nuclei of the YSL undergo epiboly and convergence and extension movements similarly to the overlying deep cells, suggesting that these tissues interact during gastrulation. However, it is so far not clear whether and how the movements of YSL nuclei and deep cells influence each other. In the first part of this thesis, the convergence and extension movement of YSL nuclei was quantitatively compared to the movement of the overlying mesendodermal progenitor (or “hypoblast)” cells. This revealed that, besides the similarity in the overall direction of movement, YSL nuclei and hypoblast cell movements display differences in speed and directionality. Next, the interaction between YSL and hypoblast was addressed. The movement of the blastoderm was analyzed when YSL nuclei movement was impaired by interfering with the YSL microtubule cytoskeleton. We found that YSL and blastoderm epiboly were strongly reduced, while convergence and extension were only mildly affected, suggesting that YSL microtubules and YSL nuclei movement are required for epiboly, but not essential for convergence and extension of the blastoderm. We also addressed whether blastodermal cells can influence YSL nuclei movement. In maternal-zygotic one-eyed pinhead (MZoep) mutant embryos, which lack hypoblast cells, YSL nuclei do not undergo proper convergence movement. Moreover, transplantation of wild type hypoblast cells into these mutants locally rescued the YSL nuclei convergence phenotype, indicating that hypoblast cells can control the movement of YSL nuclei. Finally, we propose that the hypoblast influences YSL nuclei movement as a result of shape changes caused by the collective movement of cells, and that this process requires the adhesion molecule E-cadherin

FGF signaling and cell state transitions during organogenesis

Organogenesis is a complex choreography of morphogenetic processes, patterns and dynamic shape changes as well as the specification of cell fates. Although several molecular actors and context-specific mechanisms have already been identified, our general understanding of the fundamental principles that govern the formation of organs is far from comprehensive. The application of the concept of ‘rebuild it to understand it’ from synthetic biology represents a promising alternative to the classical approach of ‘break it to understand it’ in order to distill biological understanding from complex developmental processes. According to this ‘rebuilding’ concept, in this study we sought to develop an experimental approach to induce the formation of organs from progenitor cells ‘on demand’ and to investigate the minimum requirements for such a process. The zebrafish lateral line chain cells are a powerful in vivo model for our study because they are a group of naïve multipotent progenitor cells that display mesenchyme-like features. In order to bring these cells to form organs, we used the well-known role of the FGF signaling pathway as a driver of organogenesis in the lateral line and developed an inducible and constitutively active form of the fibroblast growth factor receptor 1a (chemoFGFR). The cell-autonomous induction of this chemoFGFR in chain cells effectively triggered the formation of fully mature organs and thus enabled spatial and temporal control of the organogenesis process. Next, we asked what it takes to form an organ de novo. We used a combination of real-time microscopy, single cell tracking, polarity quantification, and mosaic analysis to study the cell behaviors that result from chemoFGFR induction. The picture that emerges from these analyses is that de novo organs form through a genetically encoded self-assembly process that is based on the pattern of chemoFGFR induction. In this scenario, cells expressing chemoFGFR aggregate into clusters and epithelialize as they sort out of non-expressing cells. We found that this sorting process occurs through cell rearrangement and slithering, which involves an extensive remodeling of the cell-cell contacts. Chain cells that do not express chemoFGFR can envelop these chemoFGFR expressing cell clusters and form a rim at the cluster periphery. This multi-stage process leads to the establishment of the inside-outside pattern of de novo organs, which is used as a blueprint for cell differentiation. In summary, in this study we provide insights into the mechanisms involved in the self-assembly of organs from a naïve population of progenitor cells

Mechanical cell properties in germ layer progenitor migration during zebrafish gastrulation

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

A Yap-dependent mechano-regulatory loop directs cell migration for embryo axis assembly

Programa de Doctorado en Biotecnología, Ingeniería y Tecnología QuímicaLínea de Investigación: Biología del DesarrolloClave Programa: DBICódigo Línea: 107Gastrulation is a decisive process that occurs during embryonic development, in which a relatively homogenous group of cells is transformed into an embryo with established body axes and presenting the three germ layers. This is achieved through complex cell rearrangements that are tightly controlled by the interplay of the different types of morphogenetic inputs. In the animal kingdom, striking divergences exist in embryonic development, as they evolve and adapt to different environments, egg architecture and speed of development. However, even though large differences can be found among the different species, the underlying logic and principles governing the gastrulation movements are conserved. The set of cell movements observed during gastrulation is not exclusive to this process, as they are also generally involved in organogenesis, tissue regeneration, and cancer progression. Therefore, understanding how the gastrulation movements are coordinated and controlled is essential not only to understand axis formation, but also how tissues and organs are build, and even which are the mechanism underlying oncogenic growth and metastasis. The key role of mechanical inputs during tissue morphogenesis is becoming increasingly evident, however little is known about how these inputs shape and regulate gastrulation. Among the most well-known transcriptional activators that cells use to interpret mechanical signals are YAP proteins, yet their role in gastrulation remains elusive. Our detailed analysis of yap1 and yap1b double mutants in medaka fish shows that these mechanosensors are required for the assembly of the primary embryo axis: a key event for the establishment of the vertebrate body plan. Using quantitative imaging and live-sensors, we show that Yap activity is required for the proper migration of dorsally converging cells towards the embryo midline. Thus, mutant cells display reduced velocity and migratory persistence resulting in shorter cell displacements in many cases insufficient to reach the midline. Combining RNA-seq with previous DamID-seq data, we characterize the transcriptional program directly activated by Yap proteins, which mostly entails the recruitment of actin cytoskeleton regulators, ECM molecules and focal adhesion components. Moreover, we show that Yap activation depends itself on intracellular tension, closing a positive feedback loop that maintains directed cell migration.Universidad Pablo de Olavide de Sevilla. Departamento de Biología Molecular e Ingeniería Bioquímic

Sox10 regulates enteric neural crest cell migration in the developing gut

Concurrent Sessions 1: 1.3 - Organs to organisms: Models of Human Diseases: abstract no. 1417th ISDB 2013 cum 72nd Annual Meeting of the Society for Developmental Biology, VII Latin American Society of Developmental Biology Meeting and XI Congreso de la Sociedad Mexicana de Biologia del Desarrollo. The Conference's web site is located at http://www.inb.unam.mx/isdb/Sox10 is a HMG-domain containing transcription factor which plays important roles in neural crest cell survival and differentiation. Mutations of Sox10 have been identified in patients with Waardenburg-Hirschsprung syndrome, who suffer from deafness, pigmentation defects and intestinal aganglionosis. Enteric neural crest cells (ENCCs) with Sox10 mutation undergo premature differentiation and fail to colonize the distal hindgut. It is unclear, however, whether Sox10 plays a role in the migration of ENCCs. To visualize the migration behaviour of mutant ENCCs, we generated a Sox10NGFP mouse model where EGFP is fused to the N-terminal domain of Sox10. Using time-lapse imaging, we found that ENCCs in Sox10NGFP/+ mutants displays lower migration speed and altered trajectories compared to normal controls. This behaviour was cell-autonomous, as shown by organotypic grafting of Sox10NGFP/+ gut segments onto control guts and vice versa. ENCCs encounter different extracellular matrix (ECM) molecules along the developing gut. We performed gut explant culture on various ECM and found that Sox10NGFP/+ ENCCs tend to form aggregates, particularly on fibronectin. Time-lapse imaging of single cells in gut explant culture indicated that the tightly-packed Sox10 mutant cells failed to exhibit contact inhibition of locomotion. We determined the expression of adhesion molecule families by qPCR analysis, and found integrin expression unaffected while L1-cam and selected cadherins were altered, suggesting that Sox10 mutation affects cell adhesion properties of ENCCs. Our findings identify a de novo role of Sox10 in regulating the migration behaviour of ENCCs, which has important implications for the treatment of Hirschsprung disease.postprin

Analysis of craniofacial defects in Six1/Eya1-associated Branchio-Oto-Renal Syndrome

Poster Session I - Morphogenesis: 205/B10117th ISDB 2013 cum 72nd Annual Meeting of the Society for Developmental Biology, 7th Latin American Society of Developmental Biology Meeting and 11th Congreso de la Sociedad Mexicana de Biologia del Desarrollo.Branchio-Oto-Renal (BOR) syndrome patients exhibit craniofacial and renal anomalies as well as deafness. BOR syndrome is caused by mutations in Six1 or Eya1, both of which regulate cell proliferation and differentiation. The molecular mechanism underlying the craniofacial and branchial arch (BA) defects in BOR syndrome is unclear. We have found that Hoxb3 is up-regulated in the second branchial arch (BA2) of Six1-/- mutants. Moreover, Hoxb3 over-expression in transgenic mice leads to BA abnormalities which are similar to the BA defects in Six1-/- or Eya1-/- mutants, suggesting a regulatory relationship among Six1, Eya1 and Hoxb3 genes. The aim of this study is to investigate the molecular mechanism underlying abnormal BA development in BOR syndrome using Six1 and Eya1 mutant mice. Two potential Six1 binding sites were identified on the Hoxb3 gene. In vitro and in vivo Chromatin IP assays showed that Six1 could directly bind to one of the sites specifically. Furthermore, using a chick in ovo luciferase assay we showed that Six1 could suppress gene expression through one of the specific binding sites. On the other hand, in Six1-/- mutants, we found that the Notch ligand Jag1 was up-regulated in BA2. Similarly, in Hoxb3 transgenic mice, ectopic expression of Jag1 could be also detected in BA2. To investigate the activation of Notch signaling pathway, we found that Notch intracellular domain (NICD), a direct indicator of Notch pathway activation, was up-regulated in BAs of Six1-/-; Eya1-/- double mutants. Our results indicate that Hoxb3 and Notch signaling pathway are involved in mediating the craniofacial defects of Six1/Eya1-associated Branchio-Oto-Renal Syndrome.postprin