Primitive Streak and Tail Bud Progenitor Populations drive Patterning of the Anteroposterior and Mediolateral Axes

A spinal cord fate map in the avian embryo: while regressing, Hensen's node lays down the notochord and floor plate thus joining the spinal cord lateral walls

Development ◽

10.1242/dev.122.9.2599 ◽

1996 ◽

Vol 122 (9) ◽

pp. 2599-2610 ◽

Cited By ~ 22

Author(s):

M. Catala ◽

M.A. Teillet ◽

E.M. De Robertis ◽

M.L. Le Douarin

Keyword(s):

Spinal Cord ◽

Primitive Streak ◽

Floor Plate ◽

Dorsal Side ◽

Avian Embryo ◽

Tail Bud ◽

Fate Map ◽

In Ovo ◽

Somite Stage ◽

Lateral Walls

The spinal cord of thoracic, lumbar and caudal levels is derived from a region designated as the sinus rhomboidalis in the 6-somite-stage embryo. Using quail/chick grafts performed in ovo, we show the following. (1) The floor plate and notochord derive from a common population of cells, located in Hensen's node, which is equivalent to the chordoneural hinge (CNH) as it was defined at the tail bud stage. (2) The lateral walls and the roof of the neural tube originate caudally and laterally to Hensen's node, during the regression of which the basal plate anlage is bisected by floor plate tissue. (3) Primary and secondary neurulations involve similar morphogenetic movements but, in contrast to primary neurulation, extensive bilateral cell mixing is observed on the dorsal side of the region of secondary neurulation. (4) The posterior midline of the sinus rhomboidalis gives rise to somitic mesoderm and not to spinal cord. Moreover, mesodermal progenitors are spatially arranged along the rest of the primitive streak, more caudal cells giving rise to more lateral embryonic structures. Together with the results reported in our study of tail bud development (Catala, M., Teillet, M.-A. and Le Douarin, N.M. (1995). Mech. Dev. 51, 51–65), these results show that the mechanisms that preside at axial elongation from the 6-somite stage onwards are fundamentally similar during the complete process of neurulation.

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The histogenetic capacity of tissues in the caudal end of the embryonic axis of the mouse

Development ◽

10.1242/dev.82.1.253 ◽

1984 ◽

Vol 82 (1) ◽

pp. 253-266

Author(s):

P. P. L. Tam

Keyword(s):

Developmental Stages ◽

Primitive Streak ◽

Mouse Embryos ◽

Embryonic Axis ◽

Tail Bud ◽

Germ Layers ◽

Kidney Capsule ◽

Caudal Region ◽

Caudal Portion ◽

Adult Body

The caudal end of the embryonic axis consists of the primitive streak and the tail bud. Small fragments of this caudal tissue were transplanted from mouse embryos of various developmental stages to the kidney capsule in order to test their histogenetic capacity. The variety of mature tissues obtained from these small fragments was similar to that obtained by grafting a larger caudal portion of the embryo. Initially, the grafted tissue broke up into loose masses of embryonic mesenchyme and this was later re-organized into more compact tissues and into cysts that were lined with various types of epithelia. After 14 days in the ectopic site, grafted tissues coming from embryos of the primitive-streak, the early-somite and the forelimb-bud stages differentiated into structures that has presumably originated from the three embryonic germ layers. Many of these structures were related to the caudal region of the adult body, such as the mid- and hindgut segments and urogenital derivatives. The histogenetic capacity for endodermal tissues and urogenital organs was lost when the grafted tissue consisted entirely of the tail bud of the hindlimb-bud-stage embryos. The behaviour of the caudal tissues suggested that (1) the primordia for the various parts of embryonic body were derived from a small progenitor population in the primitive streak and the tail bud, and (2) the histogenetic capacity of this population changed during development.

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The control of somitogenesis in mouse embryos

Development ◽

10.1242/dev.65.supplement.103 ◽

1981 ◽

Vol 65 (Supplement) ◽

pp. 103-128

Author(s):

P. P. L. Tam

Keyword(s):

Body Size ◽

Primitive Streak ◽

Mouse Embryos ◽

The Body ◽

Whole Body ◽

Axis Formation ◽

Presomitic Mesoderm ◽

Tail Bud ◽

Somite Formation ◽

Somitic Mesoderm

Somitogenesis in the mouse embryo commences with the generation of presumptive somitic mesoderm at the primitive streak and in the tail-bud mesenchyme. The presumptive somitic mesoderm is then organized into somite primordia in the presomitic mesoderm. These primordia undergo morphogenesis leading to the segmentation of somites at the cranial end of the presomitic mesoderm. Somite sizes at the time of segmentation vary according to the position of the somite in the body axis: the size of lumbar and sacral somites is nearly twice that of upper trunk somites and of tail somites. The size of the presomitic mesoderm, which is governed by the balance between the addition of cells at the caudal end and the removal of somites at the cranial end, changes during embryonic development. Somitogenesis is disturbed during the compensatory growth of mouse embryos which have suffered a drastic size reduction at the primitive-streak and early-organogenesis stages. The formation of somites is retarded and the upper trunk somites are formed at a smaller size. The embryo also follows an entirely different growth profile, but a normal body size is restored by the early foetal stage. The somite number is regulated to normal and this is brought about by an altered rate of somite formation and the adjustment of somite size in proportion to the whole body size. It is proposed that axis formation and somitogenesis are related morphogenetic processes and that embryonic growth controls the kinetics of somitogenesis, namely by regulating the number of cells allocated to each somite and the rate of somite formation.

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The somitogenetic potential of cells in the primitive streak and the tail bud of the organogenesis-stage mouse embryo

Development ◽

10.1242/dev.115.3.703 ◽

1992 ◽

Vol 115 (3) ◽

pp. 703-715 ◽

Cited By ~ 27

Author(s):

P.P. Tam ◽

S.S. Tan

Keyword(s):

Primitive Streak ◽

Mouse Embryos ◽

Paraxial Mesoderm ◽

Tail Bud ◽

Matrix Interaction ◽

Cell Matrix ◽

Age Related ◽

Somite Formation ◽

Lateral Mesoderm ◽

Host Embryo

The developmental potency of cells isolated from the primitive streak and the tail bud of 8.5- to 13.5-day-old mouse embryos was examined by analyzing the pattern of tissue colonization after transplanting these cells to the primitive streak of 8.5-day embryos. Cells derived from these progenitor tissues contributed predominantly to tissues of the paraxial and lateral mesoderm. Cells isolated from older embryos could alter their segmental fate and participated in the formation of anterior somites after transplantation to the primitive streak of 8.5-day host embryo. There was, however, a developmental lag in the recruitment of the transplanted cells to the paraxial mesoderm and this lag increased with the extent of mismatch of developmental ages between donor and host embryos. It is postulated that certain forms of cell-cell or cell-matrix interaction are involved in the specification of segmental units and that there may be age-related variations in the interactive capability of the somitic progenitor cells during development. Tail bud mesenchyme isolated from 13.5-day embryos, in which somite formation will shortly cease, was still capable of somite formation after transplantation to 8.5-day embryos. The cessation of somite formation is therefore likely to result from a change in the tissue environment in the tail bud rather than a loss of cellular somitogenetic potency.

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Continuing organizer function during chick tail development

Development ◽

10.1242/dev.125.10.1791 ◽

1998 ◽

Vol 125 (10) ◽

pp. 1791-1801 ◽

Cited By ~ 2

Author(s):

V. Knezevic ◽

R. De Santo ◽

S. Mackem

Keyword(s):

Molecular Basis ◽

Neural Tissue ◽

Primitive Streak ◽

Host Cells ◽

Tail Bud ◽

Lumbosacral Region ◽

Present Evidence ◽

Tail Development ◽

Spatial Domains ◽

Organizer Activity

Development of the posterior body (lumbosacral region and tail) in vertebrates is delayed relative to gastrulation. In amniotes, it proceeds with the replacement of the regressed node and primitive streak by a caudal blastema-like mass of mesenchyme known as the tail bud. Despite apparent morphological dissimilarities, recent results suggest that tail development in amniotes is in essence a continuation of gastrulation, as is the case in Xenopus. However, this has been inferred primarily from the outcome of fate mapping studies demonstrating discrete, regionalized cell populations in the tail bud, like those present at gastrulation. Our analysis of the tail bud distribution of several molecular markers that are expressed in specific spatial domains during chick gastrulation confirms these results. Furthermore, we present evidence that gastrulation-like ingression movements from the surface continue in the early chick tail bud and that the established tail bud retains organizer activity. This ‘tail organizer’ has the expected properties of being able to recruit uncommitted host cells into a new embryonic axis and induce host neural tissue with posteriorly regionalized gene expression when grafted to competent host cells that are otherwise destined to form only extra-embryonic tissue. Together, these results indicate that chick tail development is mechanistically continuous with gastrulation and that the developing tail in chick may serve as a useful experimental adjunct to investigate the molecular basis of inductive interactions operating during gastrulation, considering that residual tail organizing activity is still present at a surprisingly late stage.

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Axial progenitors with extensive potency are localised to the mouse chordoneural hinge

Development ◽

10.1242/dev.129.20.4855 ◽

2002 ◽

Vol 129 (20) ◽

pp. 4855-4866 ◽

Cited By ~ 17

Author(s):

Noemí Cambray ◽

Valerie Wilson

Keyword(s):

Stem Cells ◽

Cell Model ◽

Primitive Streak ◽

Serial Passage ◽

Small Population ◽

Lineage Tracing ◽

Tail Bud ◽

Apparent Loss ◽

Stem Cell Model ◽

Successive Generations

Elongation of the mouse anteroposterior axis depends on a small population of progenitors initially located in the primitive streak and later in the tail bud. Gene expression and lineage tracing have shown that there are many features common to these progenitor tissues throughout axial elongation. However, the identity and location of the progenitors is unclear. We show by lineage tracing that the descendants of 8.5 d.p.c. node and anterior primitive streak which remain in the tail bud are located in distinct territories: (1) ventral node descendants are located in the widened posterior end of the notochord; and (2) descendants of anterior streak are located in both the tail bud mesoderm, and in the posterior end of the neurectoderm. We show that cells from the posterior neurectoderm are fated to give rise to mesoderm even after posterior neuropore closure. The posterior end of the notochord, together with the ventral neurectoderm above it, is thus topologically equivalent to the chordoneural hinge region defined in Xenopus and chick. A stem cell model has been proposed for progenitors of two of the axial tissues, the myotome and spinal cord. Because it was possible that labelled cells in the tail bud represented stem cells, tail bud mesoderm and chordoneural hinge were grafted to 8.5 d.p.c. primitive streak to compare their developmental potency. This revealed that cells from the bulk of the tail bud mesoderm are disadvantaged in such heterochronic grafts from incorporating into the axis and even when they do so, they tend to contribute to short stretches of somites suggesting that tail bud mesoderm is restricted in potency. By contrast, cells from the chordoneural hinge of up to 12.5 d.p.c. embryos contribute efficiently to regions of the axis formed after grafting to 8.5 d.p.c. embryos, and also repopulate the tail bud. These cells were additionally capable of serial passage through three successive generations of embryos in culture without apparent loss of potency. This potential for self-renewal in chordoneural hinge cells strongly suggests that stem cells are located in this region.

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The chicken CdxA homeobox gene and axial positioning during gastrulation

Development ◽

10.1242/dev.118.2.553 ◽

1993 ◽

Vol 118 (2) ◽

pp. 553-562 ◽

Cited By ~ 3

Author(s):

A. Frumkin ◽

R. Haffner ◽

E. Shapira ◽

N. Tarcic ◽

Y. Gruenbaum ◽

...

Keyword(s):

Marginal Zone ◽

Homeobox Gene ◽

Primitive Streak ◽

Immunohistochemical Localization ◽

Tail Bud ◽

E Coli ◽

Tissue Sections ◽

Whole Mount ◽

Anterior Posterior

The chicken homebox containing gene, CdxA (formerly CHox-cad), was previously shown to be expressed during gastrulation. Localization of CdxA transcripts by in situ hybridization to tissue sections revealed that, during gastrulation, expression of this gene exhibits a posterior localization along the primitive streak. The transcripts are localized to epiblast cells in the vicinity of the primitive streak, to cells of the primitive streak itself and in the definitive endoderm as it replaces the hypoblast. In order to study in greater detail the pattern of expression of the CdxA gene during gastrulation, we expressed the full-length CdxA protein as a fusion protein in E. coli and generated monoclonal antibodies against it. Chicken embryos at different stages of gastrulation were processed for whole-mount immunohistochemical localization of the protein using anti-CdxA antibodies. Once the pattern of expression in the whole embryo was determined, the same embryos were sectioned to determine the identity of the cells expressing the CdxA protein. Detailed analysis of the CdxA protein in embryos, from the onset of primitive streak formation to the beginning of the tail bud stage (stages 2 to 10), has shown different patterns of expression during primitive streak elongation and regression. The CdxA protein is initially detected at the posterior marginal zone and the expression moves rostrally into the primitive streak during mid-streak stages. As the primitive streak elongates, the CdxA stripe of expression moves anteriorly. By definitive streak stages, the CdxA stripe of expression delineates a position along the anterior-posterior axis in the primitive streak. CdxA, like its Drosophila homologue cad, is expressed during gastrulation in a stripe localized to the posterior region of the embryo. These observations suggest that CdxA as a homebox gene may be part of a regulatory network coupled to axial determination during gastrulation in the early chick embryo.

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TCreERT2, a Transgenic Mouse Line for Temporal Control of Cre-Mediated Recombination in Lineages Emerging from the Primitive Streak or Tail Bud

PLoS ONE ◽

10.1371/journal.pone.0062479 ◽

2013 ◽

Vol 8 (4) ◽

pp. e62479 ◽

Cited By ~ 15

Author(s):

Matthew J. Anderson ◽

L. A. Naiche ◽

Catherine P. Wilson ◽

Cindy Elder ◽

Deborah A. Swing ◽

...

Keyword(s):

Transgenic Mouse ◽

Primitive Streak ◽

Mouse Line ◽

Temporal Control ◽

Tail Bud ◽

Transgenic Mouse Line

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A TgfβRI/Snai1-dependent developmental module at the core of vertebrate axial elongation

10.1101/2020.03.09.983809 ◽

2020 ◽

Author(s):

André Dias ◽

Anastasiia Lozovska ◽

Filip J. Wymeersch ◽

Ana Nóvoa ◽

Anahi Binagui-Casas ◽

...

Keyword(s):

Epithelial To Mesenchymal Transition ◽

Primitive Streak ◽

Body Axis ◽

Tail Bud ◽

Mesenchymal Transition ◽

Axial Elongation ◽

The Core ◽

Primary Body ◽

Transitory State

ABSTRACTFormation 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 (PS) 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 developmental module, concurrent but functionally different to that generating the primary body. This module is triggered by convergent TgfβRI and Snai1 activities that promote an incomplete epithelial to mesenchymal transition (EMT) on a subset of epiblast axial progenitors. This EMT is functionally different to that coordinated by the PS, 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.

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Defining subregions of Hensen's node essential for caudalward movement, midline development and cell survival

Development ◽

10.1242/dev.126.21.4771 ◽

1999 ◽

Vol 126 (21) ◽

pp. 4771-4783 ◽

Cited By ~ 6

Author(s):

J.B. Charrier ◽

M.A. Teillet ◽

F. Lapointe ◽

N.M. Le Douarin

Keyword(s):

Primitive Streak ◽

Floor Plate ◽

Paraxial Mesoderm ◽

Avian Embryo ◽

Tail Bud ◽

Anterior Portion ◽

T Box ◽

Endodermal Cells ◽

Further Development ◽

Midline Development

Hensen's node, also called the chordoneural hinge in the tail bud, is a group of cells that constitutes the organizer of the avian embryo and that expresses the gene HNF-3(β). During gastrulation and neurulation, it undergoes a rostral-to-caudal movement as the embryo elongates. Labeling of Hensen's node by the quail-chick chimera system has shown that, while moving caudally, Hensen's node leaves in its wake not only the notochord but also the floor plate and a longitudinal strand of dorsal endodermal cells. In this work, we demonstrate that the node can be divided into functionally distinct subregions. Caudalward migration of the node depends on the presence of the most posterior region, which is closely apposed to the anterior portion of the primitive streak as defined by expression of the T-box gene Ch-Tbx6L. We call this region the axial-paraxial hinge because it corresponds to the junction of the presumptive midline axial structures (notochord and floor plate) and the paraxial mesoderm. We propose that the axial-paraxial hinge is the equivalent of the neuroenteric canal of other vertebrates such as Xenopus. Blocking the caudal movement of Hensen's node at the 5- to 6-somite stage by removing the axial-paraxial hinge deprives the embryo of midline structures caudal to the brachial level, but does not prevent formation of the neural tube and mesoderm located posteriorly. However, the whole embryonic region generated posterior to the level of Hensen's node arrest undergoes widespread apoptosis within the next 24 hours. Hensen's node-derived structures (notochord and floor plate) thus appear to produce maintenance factor(s) that ensures the survival and further development of adjacent tissues.

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