Your search keyword '"axial progenitors"' showing total 25 results

1. Notch signalling influences cell fate decisions and HOX gene induction in axial progenitors.

Author

Cooper, Fay, Souilhol, Celine, Haston, Scott, Gray, Shona, Boswell, Katy, Gogolou, Antigoni, Frith, Thomas J. R., Stavish, Dylan, James, Bethany M., Bose, Daniel, Dale, Jacqueline Kim, and Tsakiridis, Anestis

Subjects

*HOMEOBOX genes, *NOTCH genes, *HUMAN embryonic stem cells, *CELL communication, *GENE expression, *GENETIC regulation

Abstract

The generation of the post-cranial embryonic body relies on the coordinated production of spinal cord neurectoderm and presomitic mesoderm cells from neuromesodermal progenitors (NMPs). This process is orchestrated by pro-neural and pro-mesodermal transcription factors that are co-expressed in NMPs together with Hox genes, which are essential for axial allocation of NMP derivatives. NMPs reside in a posterior growth region, which is marked by the expression of Wnt, FGF and Notch signalling components. Although the importance of Wnt and FGF in influencing the induction and differentiation of NMPs is well established, the precise role of Notch remains unclear. Here, we show that the Wnt/FGF-driven induction of NMPs from human embryonic stem cells (hESCs) relies on Notch signalling. Using hESC-derived NMPs and chick embryo grafting, we demonstrate that Notch directs a pro-mesodermal character at the expense of neural fate. We show that Notch also contributes to activation of HOX gene expression in human NMPs, partly in a noncell-autonomous manner. Finally, we provide evidence that Notch exerts its effects via the establishment of a negative-feedback loopwith FGF signalling. [ABSTRACT FROM AUTHOR]

Published

2024

2. Axial Stem Cells and the Formation of the Vertebrate Body

Author

Dias, André, Aires, Rita, Rodrigues, Gabriela, editor, and Roelen, Bernard A. J., editor

Published

2020

3. Somite development and regionalisation of the vertebral axial skeleton.

Author

Weldon, Shannon A. and Münsterberg, Andrea E.

Abstract

A critical stage in the development of all vertebrate embryos is the generation of the body plan and its subsequent patterning and regionalisation along the main anterior-posterior axis. This includes the formation of the vertebral axial skeleton. Its organisation begins during early embryonic development with the periodic formation of paired blocks of mesoderm tissue called somites. Here, we review axial patterning of somites, with a focus on studies using amniote model systems – avian and mouse. We summarise the molecular and cellular mechanisms that generate paraxial mesoderm and review how the different anatomical regions of the vertebral column acquire their specific identity and thus shape the body plan. We also discuss the generation of organoids and embryo-like structures from embryonic stem cells, which provide insights regarding axis formation and promise to be useful for disease modelling. [ABSTRACT FROM AUTHOR]

Published

2022

4. Restricted Proliferation During Neurogenesis Contributes to Regionalisation of the Amphioxus Nervous System.

Author

Gattoni, Giacomo, Andrews, Toby G. R., and Benito-Gutiérrez, Èlia

Subjects

NERVOUS system, AMPHIOXUS, NEUROGENESIS, CENTRAL nervous system, NEURAL tube

Abstract

The central nervous system of the cephalochordate amphioxus consists of a dorsal neural tube with an anterior brain. Two decades of gene expression analyses in developing amphioxus embryos have shown that, despite apparent morphological simplicity, the amphioxus neural tube is highly regionalised at the molecular level. However, little is known about the morphogenetic mechanisms regulating the spatiotemporal emergence of cell types at distinct sites of the neural axis and how their arrangements contribute to the overall neural architecture. In vertebrates, proliferation is key to provide appropriate cell numbers of specific types to particular areas of the nervous system as development proceeds, but in amphioxus proliferation has never been studied at this level of detail, nor in the specific context of neurogenesis. Here, we describe the dynamics of cell division during the formation of the central nervous system in amphioxus embryos, and identify specific regions of the nervous system that depend on proliferation of neuronal precursors at precise time-points for their maturation. By labelling proliferating cells in vivo at specific time points in development, and inhibiting cell division during neurulation, we demonstrate that localised proliferation in the anterior cerebral vesicle is required to establish the full cell type repertoire of the frontal eye complex and the putative hypothalamic region of the amphioxus brain, while posterior proliferating progenitors, which were found here to derive from the dorsal lip of the blastopore, contribute to elongation of the caudal floor plate. Between these proliferative domains, we find that trunk nervous system differentiation is independent from cell division, in which proliferation decreases during neurulation and resumes at the early larval stage. Taken together, our results highlight the importance of proliferation as a tightly controlled mechanism for shaping and regionalising the amphioxus neural axis during development, by addition of new cells fated to particular types, or by influencing tissue geometry. [ABSTRACT FROM AUTHOR]

Published

2022

5. Epha1 is a cell-surface marker for the neuromesodermal competent population.

Author

de Lemos, Luisa, Dias, André, Nóvoa, Ana, and Mallo, Moisés

Subjects

*CELL membranes, *FETAL tissues, *EMBRYOLOGY, *NEURAL tube, *PROGENITOR cells

Abstract

The vertebrate body is built during embryonic development by the sequential addition of new tissue as the embryo grows at its caudal end. During this process, progenitor cells within the neuromesodermal competent (NMC) region generate the postcranial neural tube and paraxial mesoderm. Here, we have applied a genetic strategy to recover the NMC cell population from mouse embryonic tissues and have searched their transcriptome for cell-surface markers that would give access to these cells without previous genetic modifications. We found that Epha1 expression is restricted to the axial progenitor-containing areas of the mouse embryo. Epha1- positive cells isolated from the mouse tailbud generate neural and mesodermal derivatives when cultured in vitro. This observation, together with their enrichment in the Sox2+/Tbxt+ molecular phenotype, indicates a direct association between Epha1 and the NMC population. Additional analyses suggest that tailbud cells expressing low Epha1 levels might also contain notochord progenitors, and that high Epha1 expression might be associated with progenitors entering paraxial mesoderm differentiation. Epha1 could thus be a valuable cell-surface marker for labeling and recovering physiologically active axial progenitors from embryonic tissues. [ABSTRACT FROM AUTHOR]

Published

2022

6. A Tgfbr1/Snai1-dependent developmental module at the core of vertebrate axial elongation

Author

André Dias, Anastasiia Lozovska, Filip J Wymeersch, Ana Nóvoa, Anahi Binagui-Casas, Daniel Sobral, Gabriel G Martins, Valerie Wilson, and Moises Mallo

Subjects

snai1, tgfbr1, EMT, axial progenitors, tail bud, axial elongation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Formation of the vertebrate postcranial body axis follows two sequential but distinct phases. The first phase generates pre-sacral structures (the so-called primary body) through the activity of the primitive streak on axial progenitors within the epiblast. The embryo then switches to generate the secondary body (post-sacral structures), which depends on axial progenitors in the tail bud. Here we show that the mammalian tail bud is generated through an independent functional developmental module, concurrent but functionally different from that generating the primary body. This module is triggered by convergent Tgfbr1 and Snai1 activities that promote an incomplete epithelial to mesenchymal transition on a subset of epiblast axial progenitors. This EMT is functionally different from that coordinated by the primitive streak, as it does not lead to mesodermal differentiation but brings axial progenitors into a transitory state, keeping their progenitor activity to drive further axial body extension.

Published

2020

7. The vertebrate tail: a gene playground for evolution.

Author

Mallo, Moisés

Subjects

*TAILS, *BUD development, *SPINAL cord, *HOMEOBOX genes, *PLAYGROUNDS, *GENE regulatory networks, *LEUKAPHERESIS

Abstract

The tail of all vertebrates, regardless of size and anatomical detail, derive from a post-anal extension of the embryo known as the tail bud. Formation, growth and differentiation of this structure are closely associated with the activity of a group of cells that derive from the axial progenitors that build the spinal cord and the muscle-skeletal case of the trunk. Gdf11 activity switches the development of these progenitors from a trunk to a tail bud mode by changing the regulatory network that controls their growth and differentiation potential. Recent work in the mouse indicates that the tail bud regulatory network relies on the interconnected activities of the Lin28/let-7 axis and the Hox13 genes. As this network is likely to be conserved in other mammals, it is possible that the final length and anatomical composition of the adult tail result from the balance between the progenitor-promoting and -repressing activities provided by those genes. This balance might also determine the functional characteristics of the adult tail. Particularly relevant is its regeneration potential, intimately linked to the spinal cord. In mammals, known for their complete inability to regenerate the tail, the spinal cord is removed from the embryonic tail at late stages of development through a Hox13-dependent mechanism. In contrast, the tail of salamanders and lizards keep a functional spinal cord that actively guides the tail's regeneration process. I will argue that the distinct molecular networks controlling tail bud development provided a collection of readily accessible gene networks that were co-opted and combined during evolution either to end the active life of those progenitors or to make them generate the wide diversity of tail shapes and sizes observed among vertebrates. [ABSTRACT FROM AUTHOR]

Published

2020

8. Cdx and T Brachyury Co-activate Growth Signaling in the Embryonic Axial Progenitor Niche

Author

Shilu Amin, Roel Neijts, Salvatore Simmini, Carina van Rooijen, Sander C. Tan, Lennart Kester, Alexander van Oudenaarden, Menno P. Creyghton, and Jacqueline Deschamps

Subjects

mouse embryonic development, elongation of the anteroposterior axis, genetics of posterior tissue generation, axial progenitors, regulatory elements, Biology (General), QH301-705.5

Abstract

In vertebrate embryos, anterior tissues are generated early, followed by the other axial structures that emerge sequentially from a posterior growth zone. The genetic network driving posterior axial elongation in mice, and its disturbance in mutants with posterior truncation, is not yet fully understood. Here, we show that the combined expression of Cdx2 and T Brachyury is essential to establish the core signature of posterior axial progenitors. Cdx2 and T Brachyury are required for extension of a similar trunk portion of the axis. Simultaneous loss of function of these two genes disrupts axial elongation to a much greater extent than each single mutation alone. We identify and validate common targets for Cdx2 and T Brachyury in vivo, including Wnt and Fgf pathway components active in the axial progenitor niche. Our data demonstrate that integration of the Cdx/Hox and T Brachyury transcriptional networks controls differential axial growth during vertebrate trunk elongation.

Published

2016

9. Human axial progenitors generate trunk neural crest cells in vitro

Author

Thomas JR Frith, Ilaria Granata, Matthew Wind, Erin Stout, Oliver Thompson, Katrin Neumann, Dylan Stavish, Paul R Heath, Daniel Ortmann, James OS Hackland, Konstantinos Anastassiadis, Mina Gouti, James Briscoe, Valerie Wilson, Stuart L Johnson, Marysia Placzek, Mario R Guarracino, Peter W Andrews, and Anestis Tsakiridis

Subjects

axial progenitors, neural crest, pluripotent stem cells, In vitro differentiation, embryonic development, neuromesodermal progenitors, Medicine, Science, Biology (General), QH301-705.5

Abstract

The neural crest (NC) is a multipotent embryonic cell population that generates distinct cell types in an axial position-dependent manner. The production of NC cells from human pluripotent stem cells (hPSCs) is a valuable approach to study human NC biology. However, the origin of human trunk NC remains undefined and current in vitro differentiation strategies induce only a modest yield of trunk NC cells. Here we show that hPSC-derived axial progenitors, the posteriorly-located drivers of embryonic axis elongation, give rise to trunk NC cells and their derivatives. Moreover, we define the molecular signatures associated with the emergence of human NC cells of distinct axial identities in vitro. Collectively, our findings indicate that there are two routes toward a human post-cranial NC state: the birth of cardiac and vagal NC is facilitated by retinoic acid-induced posteriorisation of an anterior precursor whereas trunk NC arises within a pool of posterior axial progenitors.

Published

2018

10. Lineage tracing axial progenitors using Nkx1-2CreERT2 mice defines their trunk and tail contributions.

Author

Albors, Aida Rodrigo, Halley, Pamela A., and Storey, Kate G.

Subjects

*ANATOMICAL axis, *MESODERM, *TRANSGENIC mice

Abstract

The vertebrate body forms by continuous generation of new tissue from progenitors at the posterior end of the embryo. The study of these axial progenitors has proved challenging in vivo largely due to the lack of unique molecular markers to identify them. Here, we elucidate the expression pattern of the transcription factor Nkx1-2 in the mouse embryo and show that it identifies axial progenitors throughout body axis elongation, including neuromesodermal progenitors and early neural and mesodermal progenitors. We create a tamoxifen-inducible Nkx1-2CreERT2 transgenic mouse and exploit the conditional nature of this line to uncover the lineage contributions of Nkx1-2-expressing cells at specific stages. We show that early Nkx1-2- expressing epiblast cells contribute to all three germ layers, mostly neuroectoderm and mesoderm, excluding notochord. Our data are consistent with the presence of some selfrenewing axial progenitors that continue to generate neural and mesoderm tissues from the tail bud. This study identifies Nkx1-2-expressing cells as the source of most trunk and tail tissues in the mouse and provides a useful tool to genetically label and manipulate axial progenitors in vivo. [ABSTRACT FROM AUTHOR]

Published

2018

11. Restricted proliferation during neurogenesis contributes to regionalization of the amphioxus nervous system

Author

Toby Andrews, Giacomo Gattoni, Elia Benito Gutierrez, Andrews, Toby [0000-0002-0685-0300], and Apollo - University of Cambridge Repository

Subjects

neurogenesis, animal structures, EdU pulse-chase, General Neuroscience, proliferation, axial progenitors, chordate evolution, brain development, HCR, amphioxus

Abstract

The central nervous system of the cephalochordate amphioxus consists of a dorsal neural tube with an anterior brain. Two decades of gene expression analyses in developing amphioxus embryos have shown that, despite apparent morphological simplicity, the amphioxus neural tube is highly regionalised at the molecular level. However, little is known about the morphogenetic mechanisms regulating the spatiotemporal emergence of cell types at distinct sites of the neural axis and how their arrangements contribute to the overall neural architecture. In vertebrates, proliferation is key to provide appropriate cell numbers of specific types to particular areas of the nervous system as development proceeds, but in amphioxus proliferation has never been studied at this level of detail, nor in the specific context of neurogenesis. Here, we describe the dynamics of cell division during the formation of the central nervous system in amphioxus embryos, and identify specific regions of the nervous system that depend on proliferation of neuronal precursors at precise time-points for their maturation. By labelling proliferating cells in vivo at specific time points in development, and inhibiting cell division during neurulation, we demonstrate that localised proliferation in the anterior cerebral vesicle is required to establish the full cell type repertoire of the frontal eye complex and the putative hypothalamic region of the amphioxus brain, while posterior proliferating progenitors, which were found here to derive from the dorsal lip of the blastopore, contribute to elongation of the caudal floor plate. Between these proliferative domains, we find that trunk nervous system differentiation is independent from cell division, in which proliferation decreases during neurulation and resumes at the early larval stage. Taken together, our results highlight the importance of proliferation as a tightly controlled mechanism for shaping and regionalising the amphioxus neural axis during development, by addition of new cells fated to particular types, or by influencing tissue geometry., Whitten Trust

Published

2022

12. Cdx and T Brachyury Co-activate Growth Signaling in the Embryonic Axial Progenitor Niche.

Author

Amin, Shilu, Neijts, Roel, Simmini, Salvatore, van Rooijen, Carina, Tan, Sander C., Kester, Lennart, van Oudenaarden, Alexander, Creyghton, Menno P., and Deschamps, Jacqueline

Abstract

Summary In vertebrate embryos, anterior tissues are generated early, followed by the other axial structures that emerge sequentially from a posterior growth zone. The genetic network driving posterior axial elongation in mice, and its disturbance in mutants with posterior truncation, is not yet fully understood. Here, we show that the combined expression of Cdx2 and T Brachyury is essential to establish the core signature of posterior axial progenitors. Cdx2 and T Brachyury are required for extension of a similar trunk portion of the axis. Simultaneous loss of function of these two genes disrupts axial elongation to a much greater extent than each single mutation alone. We identify and validate common targets for Cdx2 and T Brachyury in vivo, including Wnt and Fgf pathway components active in the axial progenitor niche. Our data demonstrate that integration of the Cdx/Hox and T Brachyury transcriptional networks controls differential axial growth during vertebrate trunk elongation. [ABSTRACT FROM AUTHOR]

Published

2016

13. hPSC-derived sacral neural crest enables rescue in a severe model of Hirschsprung's disease.

Author

Fan Y, Hackland J, Baggiolini A, Hung LY, Zhao H, Zumbo P, Oberst P, Minotti AP, Hergenreder E, Najjar S, Huang Z, Cruz NM, Zhong A, Sidharta M, Zhou T, de Stanchina E, Betel D, White RM, Gershon M, Margolis KG, and Studer L

Subjects

Animals, Humans, Mice, Bone Morphogenetic Proteins, Disease Models, Animal, Growth Differentiation Factors, Heterografts, Histones, Neural Crest, Hirschsprung Disease

Abstract

The enteric nervous system (ENS) is derived from both the vagal and sacral component of the neural crest (NC). Here, we present the derivation of sacral ENS precursors from human PSCs via timed exposure to FGF, WNT, and GDF11, which enables posterior patterning and transition from posterior trunk to sacral NC identity, respectively. Using a SOX2::H2B-tdTomato/T::H2B-GFP dual reporter hPSC line, we demonstrate that both trunk and sacral NC emerge from a double-positive neuro-mesodermal progenitor (NMP). Vagal and sacral NC precursors yield distinct neuronal subtypes and migratory behaviors in vitro and in vivo. Remarkably, xenografting of both vagal and sacral NC lineages is required to rescue a mouse model of total aganglionosis, suggesting opportunities in the treatment of severe forms of Hirschsprung's disease., Competing Interests: Declaration of interests L.S. is a scientific co-founder and consultant and has received sponsored research support for work related to this study from Bluerock Therapeutics. L.S. and Y.F. are inventors of a patent application filed by Memorial Sloan Kettering Cancer Center on the methods described in this study., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

14. Compartment-dependent activities of Wnt3a/β-catenin signaling during vertebrate axial extension.

Author

Jurberg, Arnon Dias, Aires, Rita, Nóvoa, Ana, Rowland, Jennifer Elizabeth, and Mallo, Moisés

Subjects

*CELL compartmentation, *WNT proteins, *CATENINS, *EXTENSION (Physiology), *SOMITOGENESIS, *MESODERM, *DEVELOPMENTAL biology

Abstract

Extension of the vertebrate body results from the concerted activity of many signals in the posterior embryonic end. Among them, Wnt3a has been shown to play relevant roles in the regulation of axial progenitor activity, mesoderm formation and somitogenesis. However, its impact on axial growth remains to be fully understood. Using a transgenic approach in the mouse, we found that the effect of Wnt3a signaling varies depending on the target tissue. High levels of Wnt3a in the epiblast prevented formation of neural tissues, but did not impair axial progenitors from producing different mesodermal lineages. These mesodermal tissues maintained a remarkable degree of organization, even within a severely malformed embryo. However, from the cells that failed to take a neural fate, only those that left the epithelial layer of the epiblast activated a mesodermal program. The remaining tissue accumulated as a folded epithelium that kept some epiblast-like characteristics. Together with previously published observations, our results suggest a dose-dependent role for Wnt3a in regulating the balance between renewal and selection of differentiation fates of axial progenitors in the epiblast. In the paraxial mesoderm, appropriate regulation of Wnt/β-catenin signaling was required not only for somitogenesis, but also for providing proper anterior–posterior polarity to the somites. Both processes seem to rely on mechanisms with different requirements for feedback modulation of Wnt/β-catenin signaling, once segmentation occurred in the presence of high levels of Wnt3a in the presomitic mesoderm, but not after permanent expression of a constitutively active form of β-catenin. Together, our findings suggest that Wnt3a/β-catenin signaling plays sequential roles during posterior extension, which are strongly dependent on the target tissue. This provides an additional example of how much the functional output of signaling systems depends on the competence of the responding cells. [ABSTRACT FROM AUTHOR]

Published

2014

15. A Tgfbr1/Snai1-dependent developmental module at the core of vertebrate axial elongation

Author

Anahi Binagui-Casas, Daniel Sobral, Moisés Mallo, Gabriel G. Martins, Anastasiia Lozovska, André Dias, Ana Nóvoa, Filip J. Wymeersch, Valerie Wilson, DCV - Departamento de Ciências da Vida, and UCIBIO - Applied Molecular Biosciences Unit

Subjects

Tail, Epithelial-Mesenchymal Transition, Mouse, QH301-705.5, Neuroscience(all), Science, Receptor, Transforming Growth Factor-beta Type I, Mice, Transgenic, Biology, General Biochemistry, Genetics and Molecular Biology, tail bud, Mesoderm, Mice, snai1, tgfbr1, axial elongation, Immunology and Microbiology(all), Animals, Epithelial–mesenchymal transition, Progenitor cell, Biology (General), Progenitor, Body Patterning, General Immunology and Microbiology, Primitive streak, Biochemistry, Genetics and Molecular Biology(all), General Neuroscience, EMT, Embryo, General Medicine, Embryo, Mammalian, Cell biology, Epiblast, SNAI1, embryonic structures, axial progenitors, Medicine, Snail Family Transcription Factors, Developmental biology, Research Article, Developmental Biology

Abstract

LISBOA-01?0145-FEDER-030254 SCML-MC-60-2014 LISBOA-01-0145-FEDER-022170 PD/BD/128426/2017 PD/BD/128437/2017 MR/S008799/1 MR/ K011200/1 DEV-170806 Formation of the vertebrate postcranial body axis follows two sequential but distinct phases. The first phase generates pre-sacral structures (the so-called primary body) through the activity of the primitive streak on axial progenitors within the epiblast. The embryo then switches to generate the secondary body (post-sacral structures), which depends on axial progenitors in the tail bud. Here we show that the mammalian tail bud is generated through an independent functional developmental module, concurrent but functionally different from that generating the primary body. This module is triggered by convergent Tgfbr1 and Snai1 activities that promote an incomplete epithelial to mesenchymal transition on a subset of epiblast axial progenitors. This EMT is functionally different from that coordinated by the primitive streak, as it does not lead to mesodermal differentiation but brings axial progenitors into a transitory state, keeping their progenitor activity to drive further axial body extension. publishersversion published

Published

2020

16. Cdx mutant axial progenitor cells are rescued by grafting to a wild type environment

Author

Bialecka, Monika, Wilson, Valerie, and Deschamps, Jacqueline

Subjects

*TRANSCRIPTION factors, *EMBRYOLOGY, *GENE expression, *GENETIC mutation, *CELLULAR signal transduction, *LABORATORY mice

Abstract

Abstract: Cdx transcription factors are required for axial extension. Cdx genes are expressed in the posterior growth zone, a region that supplies new cells for axial elongation. Cdx2 +/− Cdx4 −/− (Cdx2/4) mutant embryos show abnormalities in axis elongation from E8.5, culminating in axial truncation at E10.5. These data raised the possibility that the long-term axial progenitors of Cdx mutants are intrinsically impaired in their ability to contribute to posterior growth. We investigated whether we could identify cell-autonomous defects of the axial progenitor cells by grafting mutant cells into a wild type growth zone environment. We compared the contribution of GFP labeled mutant and wild type progenitors grafted to unlabeled wild type recipients subsequently cultured over the period during which Cdx2/4 defects emerge. Descendants of grafted cells were scored for their contribution to differentiated tissues in the elongating axis and to the posterior growth zone. No difference between the contribution of descendants from wild type and mutant grafted progenitors was detected, indicating that rescue of the Cdx mutant progenitors by the wild type recipient growth zone is provided non-cell autonomously. Recently, we showed that premature axial termination of Cdx mutants can be partly rescued by stimulating canonical Wnt signaling in the posterior growth zone. Taken together with the data shown here, this suggests that Cdx genes function to maintain a signaling-dependent niche for the posterior axial progenitors. [ABSTRACT FROM AUTHOR]

Published

2010

17. Human axial progenitors generate trunk neural crest cells in vitro

Author

James Briscoe, Mario Rosario Guarracino, Erin Stout, Mina Gouti, Paul R. Heath, Peter W. Andrews, Stuart L. Johnson, Valerie Wilson, Matthew Wind, Katrin Neumann, Anestis Tsakiridis, Marysia Placzek, Dylan Stavish, Thomas J. R. Frith, Oliver Thompson, Konstantinos Anastassiadis, Daniel Ortmann, James O.S. Hackland, Ilaria Granata, Frith, Thomas Jr [0000-0002-6078-5466], Hackland, James Os [0000-0001-7087-9995], Anastassiadis, Konstantinos [0000-0002-9814-0559], Briscoe, James [0000-0002-1020-5240], Wilson, Valerie [0000-0003-4182-5159], Tsakiridis, Anestis [0000-0002-2184-2990], and Apollo - University of Cambridge Repository

Subjects

In vitro differentiation, sequence analysis, stem cell culture, physiological process, animal cell, anterior-posterior patterning, trunk, fluorescence activated cell sorting, transcription factor NANOG, transcription factor Sox9, 0302 clinical medicine, transcription factor Sox2, retinoic acid, cell elongation, Biology (General), Cells, Cultured, education.field_of_study, Cultured, biology, Neural crest, General Medicine, transcription factor Cdx2, Stem Cells and Regenerative Medicine, Cell biology, catecholamine, real time polymerase chain reaction, Neural Crest, embryonic development, Medicine, dopamine, immunofluorescence test, neural crest, signal transduction, Pluripotent Stem Cells, Cell type, in vitro study, QH301-705.5, Cells, Science, nuclear matrix protein 22, action potential amplitude, adrenergic system, embryo, regenerative medicine, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, developmental biology, stem cells, Humans, human, gastrulation, Progenitor cell, fibroblast growth factor 2, education, protein expression, fibroblast growth factor 4, neuromesodermal progenitors, animal model, flow cytometry, human cell, fibroblast growth factor 8, transcription factor PAX7, 030104 developmental biology, observational study, microarray analysis, transcriptome, 030217 neurology & neurosurgery, Biomarkers, 0301 basic medicine, stimulation, transcription factor GATA 2, transcription factor GATA 3, chick embryo, Induced pluripotent stem cell, cytochrome P450 26A1, receptor upregulation, Axis elongation, cell population, transcription factor Slug, General Neuroscience, Cell Differentiation, biological marker, Wnt5a protein, Stem cell, pluripotent stem cells, Function and Dysfunction of the Nervous System, Research Article, noradrenalin, transcription factor Sox10, animal experiment, Population, reduced nicotinamide adenine dinucleotide phosphate oxidase 2, Biology, image analysis, potassium current, mesoderm, transcription factor MSX2, controlled study, pluripotent stem cell, transcription factor MSX1, sympathetic nerve, cell culture, nonhuman, General Immunology and Microbiology, biological marker, action potential amplitude, cell differentiation, gene expression, membrane potential, physiology, pluripotent stem cell, Biomarkers, Embryonic stem cell, multipotent embryonic cell, axial progenitors

Abstract

The neural crest (NC) is a multipotent embryonic cell population that generates distinct cell types in an axial position-dependent manner. The production of NC cells from human pluripotent stem cells (hPSCs) is a valuable approach to study human NC biology. However, the origin of human trunk NC remains undefined and current in vitro differentiation strategies induce only a modest yield of trunk NC cells. Here we show that hPSC-derived axial progenitors, the posteriorly-located drivers of embryonic axis elongation, give rise to trunk NC cells and their derivatives. Moreover, we define the molecular signatures associated with the emergence of human NC cells of distinct axial identities in vitro. Collectively, our findings indicate that there are two routes toward a human post-cranial NC state: the birth of cardiac and vagal NC is facilitated by retinoic acid-induced posteriorisation of an anterior precursor whereas trunk NC arises within a pool of posterior axial progenitors.

Published

2018

18. Lineage tracing of axial progenitors using Nkx1-2CreERT2 mice defines their trunk and tail contributions

Author

Rodrigo Albors, Aida, Halley, Pamela A., and Storey, Kate G.

Subjects

Tail, animal structures, Genetic lineage tracing, Nkx1-2, Mice, Transgenic, Mouse embryo, Mesoderm, Axial progenitors, Genes, Reporter, Body axis elongation, Animals, Cell Lineage, Body Patterning, Homeodomain Proteins, Neurons, Integrases, Neuromesodermal progenitors, SOXB1 Transcription Factors, Stem Cells, Nuclear Proteins, Torso, Embryo, Mammalian, Mice, Inbred C57BL, embryonic structures, Research Article, Transcription Factors

Abstract

The vertebrate body forms by continuous generation of new tissue from progenitors at the posterior end of the embryo. The study of these axial progenitors has proved to be challenging in vivo largely because of the lack of unique molecular markers to identify them. Here, we elucidate the expression pattern of the transcription factor Nkx1-2 in the mouse embryo and show that it identifies axial progenitors throughout body axis elongation, including neuromesodermal progenitors and early neural and mesodermal progenitors. We create a tamoxifen-inducible Nkx1-2CreERT2 transgenic mouse and exploit the conditional nature of this line to uncover the lineage contributions of Nkx1-2-expressing cells at specific stages. We show that early Nkx1-2-expressing epiblast cells contribute to all three germ layers, mostly neuroectoderm and mesoderm, excluding notochord. Our data are consistent with the presence of some self-renewing axial progenitors that continue to generate neural and mesoderm tissues from the tail bud. This study identifies Nkx1-2-expressing cells as the source of most trunk and tail tissues in the mouse and provides a useful tool to genetically label and manipulate axial progenitors in vivo., Summary: Changing lineage contributions of axial progenitors to the developing mouse embryo are revealed using a tamoxifen-inducible Cre line under the control of the endogenous Nkx1-2 promoter.

Published

2018

19. A Tgfbr1/Snai1-dependent developmental module at the core of vertebrate axial elongation.

Author

Dias A, Lozovska A, Wymeersch FJ, Nóvoa A, Binagui-Casas A, Sobral D, Martins GG, Wilson V, and Mallo M

Subjects

Animals, Embryo, Mammalian embryology, Mice genetics, Mice, Transgenic, Receptor, Transforming Growth Factor-beta Type I metabolism, Snail Family Transcription Factors metabolism, Tail embryology, Body Patterning, Epithelial-Mesenchymal Transition, Mesoderm embryology, Mice embryology, Receptor, Transforming Growth Factor-beta Type I genetics, Snail Family Transcription Factors genetics

Abstract

Formation of the vertebrate postcranial body axis follows two sequential but distinct phases. The first phase generates pre-sacral structures (the so-called primary body) through the activity of the primitive streak on axial progenitors within the epiblast. The embryo then switches to generate the secondary body (post-sacral structures), which depends on axial progenitors in the tail bud. Here we show that the mammalian tail bud is generated through an independent functional developmental module, concurrent but functionally different from that generating the primary body. This module is triggered by convergent Tgfbr1 and Snai1 activities that promote an incomplete epithelial to mesenchymal transition on a subset of epiblast axial progenitors. This EMT is functionally different from that coordinated by the primitive streak, as it does not lead to mesodermal differentiation but brings axial progenitors into a transitory state, keeping their progenitor activity to drive further axial body extension., Competing Interests: AD, AL, FW, AN, AB, DS, GM, VW, MM No competing interests declared, (© 2020, Dias et al.)

Published

2020

20. Tail Bud Progenitor Activity Relies on a Network Comprising Gdf11, Lin28, and Hox13 Genes.

Author

Aires, Rita, de Lemos, Luisa, Nóvoa, Ana, Jurberg, Arnon Dias, Mascrez, Bénédicte, Duboule, Denis, and Mallo, Moisés

Subjects

*EPIBLAST, *ECTODERM, *GENE expression, *PROGENITOR cells, *STEM cells

Abstract

Summary During the trunk-to-tail transition, axial progenitors relocate from the epiblast to the tail bud. Here, we show that this process entails a major regulatory switch, bringing tail bud progenitors under Gdf11 signaling control. Gdf11 mutant embryos have an increased number of such progenitors that favor neural differentiation routes, resulting in a dramatic expansion of the neural tube. Moreover, inhibition of Gdf11 signaling recovers the proliferation ability of these progenitors when cultured in vitro. Tail bud progenitor growth is independent of Oct4 , relying instead on Lin28 activity. Gdf11 signaling eventually activates Hox genes of paralog group 13, which halt expansion of these progenitors, at least in part, by down-regulating Lin28 genes. Our results uncover a genetic network involving Gdf11 , Lin28 , and Hox13 genes controlling axial progenitor activity in the tail bud. Graphical Abstract Highlights • Gdf11 mutant tail buds have an enlarged progenitor pool biased toward neural fates • Different gene networks regulate axial progenitor activity at trunk and tail levels • Tail bud progenitors do not rely on Oct4 for axial extension • Lin28 genes promote and Hox13 genes restrict tail bud progenitor expansion Aires et al. show that different gene networks regulate axial progenitors at the trunk versus tail levels. After Gdf11-induced transition from trunk to tail development, Lin28 genes promote axial progenitor expansion until activation of Hox13 genes overrides this activity. [ABSTRACT FROM AUTHOR]

Published

2019

21. Compartment-dependent activities of Wnt3a/β-catenin signaling during vertebrate axial extension

Author

Ana Nóvoa, Arnon Dias Jurberg, Moisés Mallo, Jennifer E. Rowland, and Rita Aires

Subjects

animal structures, Cellular differentiation, Mice, Transgenic, Biology, Mice, Axial progenitors, Somitogenesis, Wnt3A Protein, Paraxial mesoderm, Compartment (development), Mouse development, Animals, Molecular Biology, beta Catenin, Body Patterning, Genetics, Microscopy, Confocal, Wnt signaling pathway, Cell Differentiation, Cell Biology, Wnt signaling, Cell biology, Patterning, Epiblast, Mesoderm formation, embryonic structures, Developmental Biology, Signal Transduction

Abstract

Extension of the vertebrate body results from the concerted activity of many signals in the posterior embryonic end. Among them, Wnt3a has been shown to play relevant roles in the regulation of axial progenitor activity, mesoderm formation and somitogenesis. However, its impact on axial growth remains to be fully understood. Using a transgenic approach in the mouse, we found that the effect of Wnt3a signaling varies depending on the target tissue. High levels of Wnt3a in the epiblast prevented formation of neural tissues, but did not impair axial progenitors from producing different mesodermal lineages. These mesodermal tissues maintained a remarkable degree of organization, even within a severely malformed embryo. However, from the cells that failed to take a neural fate, only those that left the epithelial layer of the epiblast activated a mesodermal program. The remaining tissue accumulated as a folded epithelium that kept some epiblast-like characteristics. Together with previously published observations, our results suggest a dose-dependent role for Wnt3a in regulating the balance between renewal and selection of differentiation fates of axial progenitors in the epiblast. In the paraxial mesoderm, appropriate regulation of Wnt/β-catenin signaling was required not only for somitogenesis, but also for providing proper anterior-posterior polarity to the somites. Both processes seem to rely on mechanisms with different requirements for feedback modulation of Wnt/β-catenin signaling, once segmentation occurred in the presence of high levels of Wnt3a in the presomitic mesoderm, but not after permanent expression of a constitutively active form of β-catenin. Together, our findings suggest that Wnt3a/β-catenin signaling plays sequential roles during posterior extension, which are strongly dependent on the target tissue. This provides an additional example of how much the functional output of signaling systems depends on the competence of the responding cells. Fundação para a Ciência e a Tecnologia: (PTDC/BIA-BCM/110638/2009, PTDC/SAU-BID/110640/2009, SFRH/BD/33562/2008, SFRH/BD/51876/2012).

Published

2013

22. FGF Modulates the Axial Identity of Trunk hPSC-Derived Neural Crest but Not the Cranial-Trunk Decision.

Author

Hackland JOS, Shelar PB, Sandhu N, Prasad MS, Charney RM, Gomez GA, Frith TJR, and García-Castro MI

Subjects

Cell Differentiation genetics, Cells, Cultured, Fibroblast Growth Factors metabolism, Gene Expression Regulation, Developmental drug effects, Humans, Microscopy, Fluorescence, Neural Crest cytology, Neural Crest metabolism, Neurogenesis genetics, Pluripotent Stem Cells cytology, Pluripotent Stem Cells metabolism, Signal Transduction drug effects, Signal Transduction genetics, Skull cytology, Skull embryology, Skull metabolism, Cell Differentiation drug effects, Fibroblast Growth Factors pharmacology, Neural Crest drug effects, Neurogenesis drug effects, Pluripotent Stem Cells drug effects

Abstract

The neural crest is a transient embryonic tissue that gives rise to a multitude of derivatives in an axially restricted manner. An in vitro counterpart to neural crest can be derived from human pluripotent stem cells (hPSCs) and can be used to study neural crest ontogeny and neurocristopathies, and to generate cells for therapeutic purposes. In order to successfully do this, it is critical to define the specific conditions required to generate neural crest of different axial identities, as regional restriction in differentiation potential is partly cell intrinsic. WNT and FGF signaling have been implicated as inducers of posterior fate, but the exact role that these signals play in trunk neural crest formation remains unclear. Here, we present a fully defined, xeno-free system for generating trunk neural crest from hPSCs and show that FGF signaling directs cells toward different axial identities within the trunk compartment while WNT signaling is the primary determinant of trunk versus cranial identity., (Copyright © 2019 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2019

23. Cdx mutant axial progenitor cells are rescued by grafting to a wild type environment

Author

Jacqueline Deschamps, Valerie Wilson, Monika Bialecka, and Hubrecht Institute for Developmental Biology and Stem Cell Research

Subjects

Primitive Streak, Mutant, Green Fluorescent Proteins, Biology, Mouse embryogenesis, Green fluorescent protein, Mesoderm, Posterior growth zone, Mice, Axial progenitors, Animals, CDX2 Transcription Factor, Progenitor cell, CDX2, Axis elongation, Molecular Biology, beta Catenin, Body Patterning, Cell Proliferation, Genetics, Homeodomain Proteins, Cell growth, Stem Cells, Wnt signaling pathway, Wild type, Gene Expression Regulation, Developmental, Cell Biology, Embryo, Mammalian, Cell biology, Posterior axial extension, Mutation, Developmental Biology, Cdx genes, Transcription Factors

Abstract

Cdx transcription factors are required for axial extension. Cdx genes are expressed in the posterior growth zone, a region that supplies new cells for axial elongation. Cdx2+/−Cdx4−/− (Cdx2/4) mutant embryos show abnormalities in axis elongation from E8.5, culminating in axial truncation at E10.5. These data raised the possibility that the long-term axial progenitors of Cdx mutants are intrinsically impaired in their ability to contribute to posterior growth. We investigated whether we could identify cell-autonomous defects of the axial progenitor cells by grafting mutant cells into a wild type growth zone environment. We compared the contribution of GFP labeled mutant and wild type progenitors grafted to unlabeled wild type recipients subsequently cultured over the period during which Cdx2/4 defects emerge. Descendants of grafted cells were scored for their contribution to differentiated tissues in the elongating axis and to the posterior growth zone. No difference between the contribution of descendants from wild type and mutant grafted progenitors was detected, indicating that rescue of the Cdx mutant progenitors by the wild type recipient growth zone is provided non-cell autonomously. Recently, we showed that premature axial termination of Cdx mutants can be partly rescued by stimulating canonical Wnt signaling in the posterior growth zone. Taken together with the data shown here, this suggests that Cdx genes function to maintain a signaling-dependent niche for the posterior axial progenitors.

Published

2010

24. Lineage tracing of axial progenitors using Nkx1-2CreER T2 mice defines their trunk and tail contributions.

Author

Rodrigo Albors A, Halley PA, and Storey KG

Subjects

Animals, Body Patterning, Embryo, Mammalian cytology, Embryo, Mammalian metabolism, Genes, Reporter, Mesoderm cytology, Mice, Inbred C57BL, Mice, Transgenic, Neurons cytology, Neurons metabolism, SOXB1 Transcription Factors metabolism, Tail cytology, Cell Lineage, Homeodomain Proteins metabolism, Integrases metabolism, Nuclear Proteins metabolism, Stem Cells cytology, Tail embryology, Torso embryology, Transcription Factors metabolism

Abstract

The vertebrate body forms by continuous generation of new tissue from progenitors at the posterior end of the embryo. The study of these axial progenitors has proved to be challenging in vivo largely because of the lack of unique molecular markers to identify them. Here, we elucidate the expression pattern of the transcription factor Nkx1-2 in the mouse embryo and show that it identifies axial progenitors throughout body axis elongation, including neuromesodermal progenitors and early neural and mesodermal progenitors. We create a tamoxifen-inducible Nkx1-2CreER T2 transgenic mouse and exploit the conditional nature of this line to uncover the lineage contributions of Nkx1-2 -expressing cells at specific stages. We show that early Nkx1-2 -expressing epiblast cells contribute to all three germ layers, mostly neuroectoderm and mesoderm, excluding notochord. Our data are consistent with the presence of some self-renewing axial progenitors that continue to generate neural and mesoderm tissues from the tail bud. This study identifies Nkx1-2 -expressing cells as the source of most trunk and tail tissues in the mouse and provides a useful tool to genetically label and manipulate axial progenitors in vivo ., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

25. Human axial progenitors generate trunk neural crest cells in vitro.

Author

Frith TJ, Granata I, Wind M, Stout E, Thompson O, Neumann K, Stavish D, Heath PR, Ortmann D, Hackland JO, Anastassiadis K, Gouti M, Briscoe J, Wilson V, Johnson SL, Placzek M, Guarracino MR, Andrews PW, and Tsakiridis A

Subjects

Biomarkers, Cells, Cultured, Humans, Cell Differentiation, Neural Crest physiology, Pluripotent Stem Cells physiology

Abstract

The neural crest (NC) is a multipotent embryonic cell population that generates distinct cell types in an axial position-dependent manner. The production of NC cells from human pluripotent stem cells (hPSCs) is a valuable approach to study human NC biology. However, the origin of human trunk NC remains undefined and current in vitro differentiation strategies induce only a modest yield of trunk NC cells. Here we show that hPSC-derived axial progenitors, the posteriorly-located drivers of embryonic axis elongation, give rise to trunk NC cells and their derivatives. Moreover, we define the molecular signatures associated with the emergence of human NC cells of distinct axial identities in vitro. Collectively, our findings indicate that there are two routes toward a human post-cranial NC state: the birth of cardiac and vagal NC is facilitated by retinoic acid-induced posteriorisation of an anterior precursor whereas trunk NC arises within a pool of posterior axial progenitors., Competing Interests: TF, IG, MW, ES, OT, KN, DS, PH, DO, JH, KA, MG, JB, VW, SJ, MP, MG, PA, AT No competing interests declared, (© 2018, Frith et al.)

Published

2018