Ectodermal patterning in the avian embryo: epidermis versus neural plate

Ectodermal patterning of the chick embryo begins in the uterus and continues during gastrulation, when cells with a neural fate become restricted to the neural plate around the primitive streak, and cells fated to become the epidermis to the periphery. The prospective epidermis at early stages is characterized by the expression of the homeobox gene DLX5, which remains an epidermal marker during gastrulation and neurulation. Later, some DLX5-expressing cells become internalized into the ventral forebrain and the neural crest at the hindbrain level. We studied the mechanism of ectodermal patterning by transplantation of Hensen's nodes and prechordal plates. The DLX5 marker indicates that not only a neural plate, but also a surrounding epidermis is induced in such operations. Similar effects can be obtained with neural plate grafts. These experiments demonstrate that the induction of a DLX5-positive epidermis is triggered by the midline, and the effect is transferred via the neural plate to the periphery. By repeated extirpations of the endoderm we suppressed the formation of an endoderm/mesoderm layer under the epiblast. This led to the generation of epidermis, and to the inhibition of neuroepithelium in the naked ectoderm. This suggests a signal necessary for neural, but inhibitory for epidermal development, normally coming from the lower layers. Finally, we demonstrate that BMP4, as well as BMP2, is capable of inducing epidermal fate by distorting the epidermis-neural plate boundary. This, however, does not happen independently within the neural plate or outside the normal DLX5 domain. In the area opaca, the co-transplantation of a BMP4 bead with a node graft leads to the induction of DLX5, thus indicating the cooperation of two factors. We conclude that ectodermal patterning is achieved by signalling both from the midline and from the periphery, within the upper but also from the lower layers.

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Origins of the avian neural crest: the role of neural plate-epidermal interactions

Development ◽

10.1242/dev.121.2.525 ◽

1995 ◽

Vol 121 (2) ◽

pp. 525-538 ◽

Cited By ~ 39

Author(s):

M.A. Selleck ◽

M. Bronner-Fraser

Keyword(s):

Neural Crest ◽

Neural Crest Cell ◽

Neural Crest Cells ◽

Neural Plate ◽

Neural Tube Closure ◽

Whole Embryo Culture ◽

Early Stages ◽

Tissue Interactions ◽

Neural Ectoderm

We have investigated the lineage and tissue interactions that result in avian neural crest cell formation from the ectoderm. Presumptive neural plate was grafted adjacent to non-neural ectoderm in whole embryo culture to examine the role of tissue interactions in ontogeny of the neural crest. Our results show that juxtaposition of non-neural ectoderm and presumptive neural plate induces the formation of neural crest cells. Quail/chick recombinations demonstrate that both the prospective neural plate and the prospective epidermis can contribute to the neural crest. When similar neural plate/epidermal confrontations are performed in tissue culture to look at the formation of neural crest derivatives, juxtaposition of epidermis with either early (stages 4–5) or later (stages 6–10) neural plate results in the generation of both melanocytes and sympathoadrenal cells. Interestingly, neural plates isolated from early stages form no neural crest cells, whereas those isolated later give rise to melanocytes but not crest-derived sympathoadrenal cells. Single cell lineage analysis was performed to determine the time at which the neural crest lineage diverges from the epidermal lineage and to elucidate the timing of neural plate/epidermis interactions during normal development. Our results from stage 8 to 10+ embryos show that the neural plate/neural crest lineage segregates from the epidermis around the time of neural tube closure, suggesting that neural induction is still underway at open neural plate stages.

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The spatial and temporal dynamics of Sax1 (CHox3) homeobox gene expression in the chick's spinal cord

Development ◽

10.1242/dev.120.7.1817 ◽

1994 ◽

Vol 120 (7) ◽

pp. 1817-1828 ◽

Cited By ~ 7

Author(s):

P. Spann ◽

M. Ginsburg ◽

Z. Rangini ◽

A. Fainsod ◽

H. Eyal-Giladi ◽

...

Keyword(s):

Temporal Dynamics ◽

Homeobox Gene ◽

Primitive Streak ◽

Neural Plate ◽

Transverse Plane ◽

Posterior Border ◽

Anterior Border ◽

Spatial And Temporal Dynamics ◽

Specific Localization

Sax1 (previously CHox3) is a chicken homeobox gene belonging to the same homeobox gene family as the Drosophila NK1 and the honeybee HHO genes. Sax1 transcripts are present from stage 2 H&H until at least 5 days of embryonic development. However, specific localization of Sax1 transcripts could not be detected by in situ hybridization prior to stage 8-, when Sax1 transcripts are specifically localized in the neural plate, posterior to the hindbrain. From stages 8- to 15 H&H, Sax1 continues to be expressed only in the spinal part of the neural plate. The anterior border of Sax1 expression was found to be always in the transverse plane separating the youngest somite from the yet unsegmented mesodermal plate and to regress with similar dynamics to that of the segregation of the somites from the mesodermal plate. The posterior border of Sax1 expression coincides with the posterior end of the neural plate. In order to study a possible regulation of Sax1 expression by its neighboring tissues, several embryonic manipulation experiments were performed. These manipulations included: removal of somites, mesodermal plate or notochord and transplantation of a young ectopic notochord in the vicinity of the neural plate or transplantation of neural plate sections into the extraembryonic area. The results of these experiments revealed that the induction of the neural plate by the mesoderm has already occurred in full primitive streak embryos, after which Sax1 is autonomously regulated within the spinal part of the neural plate.

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Bimodal functions of Notch-mediated signaling are involved in neural crest formation during avian ectoderm development

Development ◽

10.1242/dev.129.4.863 ◽

2002 ◽

Vol 129 (4) ◽

pp. 863-873 ◽

Cited By ~ 6

Author(s):

Yukinori Endo ◽

Noriko Osumi ◽

Yoshio Wakamatsu

Keyword(s):

Neural Crest ◽

Plate Boundary ◽

Neural Crest Cells ◽

Neural Plate ◽

Mutual Interaction ◽

Notch Ligand ◽

Bmp4 Expression ◽

Notch Activation

Neural crest is induced at the junction of epidermal ectoderm and neural plate by the mutual interaction of these tissues. In previous studies, BMP4 has been shown to pattern the ectodermal tissues, and BMP4 can induce neural crest cells from the neural plate. In this study, we show that epidermally expressed Delta1, which encodes a Notch ligand, is required for the activation and/or maintenance of Bmp4 expression in this tissue, and is thus indirectly required for neural crest induction by BMP4 at the epidermis-neural plate boundary. Notch activation in the epidermis additionally inhibits neural crest formation in this tissue, so that neural crest generation by BMP4 is restricted to the junction.

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Head induction in the chick by primitive endoderm of mammalian, but not avian origin

Development ◽

10.1242/dev.126.4.815 ◽

1999 ◽

Vol 126 (4) ◽

pp. 815-825 ◽

Cited By ~ 5

Author(s):

H. Knoetgen ◽

C. Viebahn ◽

M. Kessel

Keyword(s):

Lower Layer ◽

Homeobox Gene ◽

Primitive Streak ◽

Neural Plate ◽

Visceral Endoderm ◽

Avian Origin ◽

Bmp Antagonist ◽

Rabbit Embryos ◽

Inductive Potential ◽

Anterior Visceral Endoderm

Different types of endoderm, including primitive, definitive and mesendoderm, play a role in the induction and patterning of the vertebrate head. We have studied the formation of the anterior neural plate in chick embryos using the homeobox gene GANF as a marker. GANF is first expressed after mesendoderm ingression from Hensen's node. We found that, after transplantation, neither the avian hypoblast nor the anterior definitive endoderm is capable of GANF induction, whereas the mesendoderm (young head process, prechordal plate) exhibits a strong inductive potential. GANF induction cannot be separated from the formation of a proper neural plate, which requires an intact lower layer and the presence of the prechordal mesendoderm. It is inhibited by BMP4 and promoted by the presence of the BMP antagonist Noggin. In order to investigate the inductive potential of the mammalian visceral endoderm, we used rabbit embryos which, in contrast to mouse embryos, allow the morphological recognition of the prospective anterior pole in the living, pre-primitive-streak embryo. The anterior visceral endoderm from such rabbit embryos induced neuralization and independent, ectopic GANF expression domains in the area pellucida or the area opaca of chick hosts. Thus, the signals for head induction reside in the anterior visceral endoderm of mammals whereas, in birds and amphibia, they reside in the prechordal mesendoderm, indicating a heterochronic shift of the head inductive capacity during the evolution of mammalia.

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Fates and migratory routes of primitive streak cells in the chick embryo

Development ◽

10.1242/dev.122.5.1523 ◽

1996 ◽

Vol 122 (5) ◽

pp. 1523-1534 ◽

Cited By ~ 18

Author(s):

D. Psychoyos ◽

C.D. Stern

Keyword(s):

Chick Embryo ◽

Primitive Streak ◽

Final Position ◽

Fate Map ◽

Early Chick Embryo ◽

Carbocyanine Dyes ◽

Early Stages ◽

Migratory Routes ◽

Pass Through ◽

Different Tissues

We have used carbocyanine dyes to fate map the primitive streak in the early chick embryo, from stages 3+ (mid-primitive streak) to 9 (8 somites). We show that presumptive notochord, foregut and medial somite do not originate solely from Hensen's node, but also from the anterior primitive streak. At early stages (4- and 4), there is no correlation between specific anteroposterior levels of the primitive streak and the final position of their descendants in the notochord. We describe in detail the contribution of specific levels of the primitive streak to the medial and lateral halves of the somites. To understand how the descendants of labelled cells reach their destinations in different tissues, we have followed the movement of labelled cells during their emigration from the primitive streak in living embryos, and find that cells destined to different structures follow defined pathways of movement, even if they arise from similar positions in the streak. Somite and notochord precursors migrate anteriorly within the streak and pass through different portions of the node; this provides an explanation for the segregation of notochord and somite territories in the node.

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The fate map of the cephalic neural primordium at the presomitic to the 3-somite stage in the avian embryo

Development ◽

10.1242/dev.103.supplement.101 ◽

1988 ◽

Vol 103 (Supplement) ◽

pp. 101-113 ◽

Cited By ~ 24

Author(s):

GÉrard Couly ◽

Nicole M. Le Douarin

Keyword(s):

Experimental Design ◽

Chick Embryo ◽

Developmental Stage ◽

Developmental Stages ◽

Morphological Changes ◽

Neural Plate ◽

Avian Embryo ◽

Fate Map ◽

Marker System ◽

Anterior Neural Plate

The fate map of the early neural plate and neural fold has been established at the cephalic level by using the quail–chick marker system (Le Douarin, 1969, 1973). The experimental design comprised the replacement of definite territories belonging to the neural plate and neural folds in the chick embryo by their counterparts from quail embryos at the same developmental stage. This technique is referred to as the isotopic and isochronic exchange of preneural tissues between these two species. The various types of experiments that were carried out are schematized in Fig. 2. The possibility of distinguishing quail from chick cells by the structure of their nuclei allowed the fate of the grafted territories to be recognized at later developmental stages ranging from 3 to 9 days of incubation (E3–E9). Fig. 1 illustrates the morphological changes in the anterior neural plate and neural ridges in the chick embryo at the early somitic stages.

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Zebrafish narrowminded suggests a genetic link between formation of neural crest and primary sensory neurons

Development ◽

10.1242/dev.126.18.3969 ◽

1999 ◽

Vol 126 (18) ◽

pp. 3969-3979 ◽

Cited By ~ 3

Author(s):

K.B. Artinger ◽

A.B. Chitnis ◽

M. Mercola ◽

W. Driever

Keyword(s):

Neural Crest ◽

Sensory Neurons ◽

Cell Formation ◽

Plate Boundary ◽

Neural Crest Cell ◽

Neural Crest Cells ◽

Neural Plate ◽

Crest Cell

In the developing vertebrate nervous system, both neural crest and sensory neurons form at the boundary between non-neural ectoderm and the neural plate. From an in situ hybridization based expression analysis screen, we have identified a novel zebrafish mutation, narrowminded (nrd), which reduces the number of early neural crest cells and eliminates Rohon-Beard (RB) sensory neurons. Mosaic analysis has shown that the mutation acts cell autonomously suggesting that nrd is involved in either the reception or interpretation of signals at the lateral neural plate boundary. Characterization of the mutant phenotype indicates that nrd is required for a primary wave of neural crest cell formation during which progenitors generate both RB sensory neurons and neural crest cells. Moreover, the early deficit in neural crest cells in nrd homozygotes is compensated later in development. Thus, we propose that a later wave can compensate for the loss of early neural crest cells but, interestingly, not the RB sensory neurons. We discuss the implications of these findings for the possibility that RB sensory neurons and neural crest cells share a common evolutionary origin.

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