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Primitive node

The primitive node, also referred to as Hensen's node in avian embryos, is a transient embryonic structure that emerges at the cranial end of the during the third week of human development, serving as the primary organizer for and the establishment of the three germ layers (, , and ). It forms through the ingression of epiblast cells at a higher rate around the primitive pit, a small depression within the node, initiating epithelial-to-mesenchymal transition and driving the migration of cells to form definitive and while preserving on the surface. This structure is maintained by key transcription factors such as hepatocyte nuclear factor 3β (HNF-3β), encoded by the FOXA2 gene, which regulate its signaling pathways including TGF-β, Wnt, Nodal, and to pattern the . Functionally, the primitive node plays a critical role in axial development by giving rise to the notochordal process, a midline structure that extends cranially from the node toward the and later induces formation through secretion of morphogens like Sonic hedgehog (Shh), (FGF), and (RA). It establishes the embryo's craniocaudal, dorsoventral, and left-right axes, ensuring proper orientation and polarity during early , and its caudal migration during contributes to the regression of the by the end of the fourth week. Disruptions in primitive node formation or function, such as failure to regress, can lead to congenital anomalies including sacrococcygeal teratomas, highlighting its essential role in normal embryonic patterning.

Overview and Definition

Definition and Structure

The is a transient organizer structure located at the anterior end of the in embryos during . It serves as a critical site for embryonic patterning in mammals, analogous to Hensen's node in avian embryos and the Spemann-Mangold organizer in amphibians. Structurally, the primitive node arises as a localized thickening of epiblast cells, forming a distinct primitive knot or node at the cranial terminus of the . This thickening features a central known as the primitive pit, which communicates with the underlying notochordal canal and facilitates cellular movements during early development. The overall morphology presents as a compact, mound-like elevation on the embryonic disc. The cellular composition of the primitive node consists primarily of epiblast-derived cells that have undergone partial epithelial-to-mesenchymal transition. These include presumptive progenitors destined to contribute to the axial midline and organizer cells that maintain the structural integrity of the . In early mammalian embryos, such as those of the , the comprises a small cluster of approximately 200-300 tightly packed cells, exhibiting a diameter on the order of 100-200 μm.

Embryonic Location and Timing

The primitive node is located at the cranial (anterior) end of the , situated on the epiblast surface of the . It lies adjacent to the primitive pit, a slight depression within the node itself, and is positioned between the amniotic cavity superiorly and the inferiorly. This placement positions the node as a key landmark on the dorsal aspect of the early . In human development, the primitive node emerges around days 15-16 post-fertilization, during the third week ( 7-8), coinciding with the initial formation and elongation of the . It remains active throughout much of week 3, facilitating processes such as cell ingression during , before beginning to regress as the notochordal process extends cranially in early week 4. The node is oriented on the side of the embryonic disc, directly opposite the (or primitive endoderm) layer on the ventral side. In preserved embryos, it appears as a distinct nodal thickening, observable through techniques such as scanning electron microscopy, which reveals its surface and cellular organization.

Evolutionary and Comparative Aspects

Diversity Across Species

In mammals such as mice and humans, the primitive node is a compact structure forming at the anterior end of a relatively short , measuring approximately 0.3–0.5 mm in length. This node consists of a small cluster of cells with a central pit from which precursors directly ingress, and it undergoes rapid regression shortly after formation, typically within hours during early stages around embryonic day 6.5–7.5 in mice. In birds, exemplified by chickens, the equivalent structure known as Hensen's node is larger and more prominent, forming a distinct mound up to 300 μm in diameter at the anterior terminus of a longer spanning about 1.2–2 mm. This node migrates posteriorly along the streak over a distance of roughly 2 mm as progresses, allowing for extended cell ingression and contributing to a more prolonged organizational role compared to mammals. Reptiles and monotremes exhibit intermediate morphologies, often featuring variable primitive streak lengths or homologous structures like blastoporal plates rather than a fully elongated streak, reflecting their oviparous nature and larger yolk reserves. In reptiles such as turtles (Trachemys scripta) and chameleons (Chamaeleo calyptratus), gastrulation involves a bi-modal process with a slit- or circular-shaped opening (approximately 50 μm in diameter in chameleons) that facilitates ingression without a pronounced node, though conserved cell fates indicate homology to the primitive node in other amniotes. Monotremes like the platypus develop a primitive streak within the embryonal area of the yolk sac, bridging reptilian and therian mammalian forms, but these remain less studied due to limited accessible embryos. These variations highlight species-specific adaptations, particularly longer persistence of organizer structures in oviparous amniotes like and reptiles to accommodate extended on yolky eggs, in contrast to the swift, compact process in viviparous mammals. Shared patterns, such as those involving Brachyury, further support the of these organizers across amniotes.

Homologies with Non-Amniote Organizers

The primitive node in amniotes exhibits functional homologies with the Spemann-Mangold organizer in s, particularly in their roles during . In embryos, the Spemann-Mangold organizer is located at the dorsal lip of the blastopore, where cells ingress to form mesodermal structures and induce the overlying to differentiate into neural tissue. This organizer's capacity for induction mirrors that of the primitive node, which similarly orchestrates the formation of the anterior-posterior through ingression of cells at the anterior end of the primitive streak. In teleost fish such as , the embryonic shield serves as a homologous organizing center, positioned at the dorsal margin of the gastrula where it drives the of cells to establish axial mesendoderm without forming a distinct . The shield induces secondary axis formation and contributes to midline structures, akin to the primitive node's role in amniotes, with both relying on nodal-related signaling for their inductive properties. These homologies reflect evolutionary conservation across vertebrates, where organizers like the primitive node arise from signaling centers analogous to the amphibian Nieuwkoop center, which patterns the dorsal mesoderm via underlying endodermal interactions. Fate-mapping studies further support this, showing that cells from these organizers contribute to shared derivatives, including the and somites, underscoring a common developmental logic. Key evidence for these homologies comes from classical transplantation experiments, beginning with Spemann and Mangold's 1924 work demonstrating that grafting the dorsal blastopore lip induces a complete secondary axis in host embryos. This principle extends to amniotes, where transplanting Hensen's (the equivalent of the primitive ) to ectopic sites induces secondary axes with neural and mesodermal components, as shown in embryos. Similar heterospecific grafts, such as tissue into fish hosts, highlight conserved inductive potential across taxa, though with varying efficiency due to species-specific contexts. patterns, such as overlaps in goosecoid and chordin, provide molecular corroboration for these functional parallels.

Formation and Dynamics

Induction and Initial Formation

The formation of the primitive node in amniote embryos is induced by signaling from the posterior marginal zone (PMZ), a region analogous to the Nieuwkoop center in non-amniotes, which establishes the initial bilateral symmetry breaking and axis formation. In chick embryos, the PMZ emits diffusible signals that promote epiblast competence for gastrulation, preventing streak formation elsewhere in the epiblast. This induction process relies on cooperative interactions between canonical Wnt signaling, which activates downstream targets like brachyury in the posterior epiblast, and Vg1 (a TGF-β family member), which synergizes with Wnt to initiate streak gene expression. FGF signaling further supports this by regulating cell motility and proliferation in the nascent streak, ensuring proper convergence without directly initiating the axis. The hypoblast contributes indirectly by creating inhibitory gradients of Nodal, Wnt, and BMP antagonists (such as Cerberus), which position the streak posteriorly while restricting ectopic induction. Initial cellular events begin with the convergence of epiblast cells toward the posterior midline, driven by polarized cell rearrangements and chemotactic responses to PMZ signals. These cells, originating from the posterior epiblast adjacent to Koller's sickle, accumulate at the prospective anterior end of the emerging , forming a localized thickening through oriented and early ingression via epithelial-to-mesenchymal transition. The first node cells express brachyury (T), a T-box marking nascent mesendoderm, which is activated in this converging population prior to full node maturation. In chick embryos, primitive node formation coincides with primitive streak initiation at Hamburger-Hamilton stage 4, approximately 18-19 hours post-fertilization, when the streak reaches approximately 1.8 mm in length and Hensen's node becomes distinct at its anterior tip. In humans, this process occurs around day 15 post-fertilization, aligning with the onset of the definitive streak in the bilaminar disc. These events establish the node's architecture as a transient organizer, preceding its posterior regression along the streak.

Migration, Regression, and Cellular Changes

Following its initial formation, the in embryos undergoes posterior regression along the , a process that deposits precursors to establish the midline structure of the developing embryo. In the chick, this regression begins around Hamburger-Hamilton () stage 7 and progresses caudally, covering approximately 1-2 mm over 12-18 hours as the node moves from the center of the area pellucida toward the posterior margin. This movement facilitates the sequential addition of axial , contributing to body axis extension in a single sentence. During regression, significant cellular changes occur within the node. Cells ingress through the primitive pit, a central depression in the node, undergoing epithelial-to-mesenchymal transition to form prechordal that migrates anteriorly ahead of the . Concurrently, resident node cells differentiate into the notochordal plate, which later cavitates to form the definitive , while the node's epithelial structure maintains its organizer function. These transformations involve shape changes, such as cells adopting a bottle-like during ingression, increasing local cell density. The regression of the primitive node is primarily driven by differential proliferation and apoptosis at its margins, coupled with convergent cell movements in the underlying mesoderm. Higher proliferation rates in posterior regions of the primitive streak relative to the node promote caudal displacement, while targeted apoptosis refines the structure and prevents overextension. Intercalation of axial mesoderm cells further facilitates this posterior shift by reorganizing the tissue. By the endpoint of , remnants of the primitive node integrate into the tail bud, serving as a source for posterior neuromesodermal progenitors. In the , complete regression occurs by stage 10 (approximately 33 hours post-incubation), while in humans, this process concludes around day 18 post-fertilization at Carnegie stage 9.

Developmental Roles

Gastrulation and Germ Layer Specification

During in the , the primitive node serves as a critical site for the ingression of epiblast cells, which undergo (EMT) primarily at the primitive pit within the node and along the adjacent . This process initiates around embryonic day 6.5 (E6.5), where epiblast progenitors destined for the definitive and migrate toward and through the node, delaminating from the epithelial epiblast layer to become mesenchymal cells. The ingressing definitive cells displace the pre-existing visceral endoderm ( equivalent) layer, progressively replacing it to form the embryonic that will line the gut tube. This displacement occurs as the new endodermal cells intercalate and expand, pushing the visceral endoderm toward extraembryonic regions by E7.5-E8.0. Mesoderm formation similarly depends on the primitive node's role in orchestrating cell ingression, with progenitors from the node's flanks contributing to distinct mesodermal subtypes. Cells ingress through the lateral aspects of the node to generate axial mesoderm (including precursors) and paraxial mesoderm, while more posterior streak regions supply lateral and extraembryonic mesoderm. This orderly allocation ensures that axial mesoderm arises from the earliest ingressions at the node during mid-gastrulation (around E7.0), followed by lateral mesoderm from later ingressions. The at the primitive pit facilitates this by allowing cells to lose epithelial adhesions and gain migratory properties, enabling their dispersal beneath the epiblast. The remaining epiblast cells that do not ingress during differentiate into the layer, which subsequently specifies into neurectoderm and surface ectoderm. By the end of (E7.5), these non-migratory epiblast cells form the dorsal layer of the trilaminar embryonic disc, positioned above the newly formed and . This establishes the three definitive germ layers—, , and —setting the foundation for , with the primitive node's ingression dynamics ensuring precise spatiotemporal allocation of progenitors.

Body Axis Organization and Notochord Formation

The primitive node serves as a key organizer in establishing the anterior-posterior (A-P) axis during mammalian gastrulation. Positioned at the anterior end of the primitive streak, it coordinates the ingression of epiblast cells that give rise to midline structures, thereby defining embryonic polarity. As gastrulation progresses, the primitive node's posterior regression is essential for A-P axis elongation; this movement deposits axial mesoderm along the midline, with the anterior node region specifying head organizers and the posterior node contributing to trunk and tail progenitors. This regression-driven process ensures that the , derived from cells, extends caudally to pattern the A-P , providing a scaffold for somitogenesis and formation. Disruptions in node regression, such as in certain mutants, lead to truncated axes and defective midline . In parallel, the primitive node contributes to dorsal-ventral (D-V) patterning by secreting antagonists, such as noggin and chordin, which inhibit ventralizing BMP signals in the overlying . This localized inhibition promotes dorsal neural fates, preventing epidermal differentiation in the midline region. The node's influence aligns with the default model of , where inhibition defaults ectodermal cells to a neural fate rather than epidermal. This mechanism underlies the formation of the along the midline, with the acting as the primary source of inhibitory signals during early patterning. Central to these organizing functions is the of the from the primitive . Cells ingressing through the primitive pit—a within the —form the notochordal process, a transient rod-like structure that integrates with the . This process subsequently canalizes, detaching to form the definitive , which extends along the embryonic midline. The , once established, induces the floor plate in the ventral , reinforcing D-V patterning and supporting closure. This induction ensures proper ventral midline specification, with the providing sustained signals for floor plate differentiation throughout . These roles of the primitive node in axis organization and formation are conserved across species, reflecting an ancient developmental strategy.

Molecular Mechanisms

Key Genes and Expression Patterns

The primitive node, as the mammalian equivalent of the Spemann-Mangold organizer, exhibits spatially restricted expression of core transcription factors that delineate its subregions and functional domains. Goosecoid (Gsc) is prominently expressed in the central and anterior portions of the node during mid-gastrulation (around embryonic day 6.5-7.0 in mice), marking cells destined for head organizer activity. In contrast, Brachyury (T) shows strong expression in the posterior node and adjacent primitive streak, identifying nascent paraxial and lateral mesoderm progenitors that ingress during gastrulation. Notochord precursors within the node's pit and emerging midline express characteristic markers that persist into axial elongation. Sonic hedgehog (Shh) initiates in the pit at early stages, delineating the midline domain, while Foxa2 (also known as HNF-3β) is co-expressed in the same region, overlapping with Shh to specify definitive axial mesendoderm. These patterns highlight the node's role in generating midline structures. Distinct expression zones further subdivide the node along its anterior-posterior axis. The anterior node compartment features BMP antagonists such as Chordin and Noggin, which are restricted to organizer cells fated for prechordal mesoderm and neural plate induction. Posteriorly, Fgf8 and Wnt3a are enriched, promoting primitive streak elongation and posterior mesoderm specification through localized signaling gradients. Expression dynamics in the node evolve with progression, particularly during posterior regression. Genes like Shh and Foxa2 exhibit upregulation as node cells migrate caudally to form the , ensuring sustained midline patterning. These spatiotemporal patterns are largely conserved across amniotes, with similar anterior-posterior gradients observed in chick Hensen's node.

Signaling Pathways and Interactions

The primitive node orchestrates embryonic patterning through interconnected signaling pathways, primarily involving TGF-β family members, antagonists, Wnt/FGF ligands, and signals. These pathways exhibit cross-talk and form gradients that specify cell fates and guide tissue organization during . Nodal signaling, a core TGF-β pathway, operates via an autocrine loop within the to sustain organizer activity and epiblast competence. In mouse embryos, Nodal expression in the is positively autoregulated through enhancers like the asymmetric enhancer (ASE), ensuring persistent signaling that induces proprotein convertases such as and Pace4, which in turn activate Nodal ligands to form feedback loops supporting extension. Nodal gradients, extending up to 500 μm from the , pattern the along the anteroposterior axis by differentially activating mesendodermal genes, with high anterior levels promoting organizer maintenance and lower posterior levels driving streak elongation; these gradients are modulated by inhibitors like Lefty to prevent ectopic signaling. BMP inhibition is a critical emanating from the to promote neural induction by antagonizing ventralizing BMP4 signals in the overlying . Noggin and Chordin, secreted from node cells, directly bind and sequester BMP4, reducing its activity and allowing default neural fate specification in the ; in Noggin mutants, initial formation occurs, but subsequent growth and ventral patterning are impaired due to unchecked BMP signaling. This antagonism integrates with Nodal pathways, as node-derived signals prime ectodermal responsiveness to BMP blockade, forming a cooperative gradient for broad neural competence during early stages. Wnt and FGF pathways intersect at the to regulate specification and migration. Posterior Wnt3a expression in the , influenced by signals, promotes paraxial formation by stabilizing β-catenin and activating T-box transcription factors, while -derived FGF8 drives epithelial-to-mesenchymal transition and directed migration of mesodermal progenitors away from the streak; Fgf8 null mice exhibit arrested cell exodus from the primitive streak, preventing maturation and axial structure development. This ensures posterior mesoderm identity, with FGF8 gradients overlapping Wnt domains to coordinate streak regression and somitogenesis onset. Sonic hedgehog (Shh) signaling from the primitive node establishes ventral midline identities and induces floor plate formation through interactions with Gli transcription factors. Shh secreted by node cells creates a ventral-high gradient that activates Gli2 in midline progenitors, specifying floor plate fate during early somitogenesis; transient high Shh levels (≥4 nM) are required for floor plate elaboration, after which signaling attenuates to prevent conversion to neuronal progenitors, with FoxA2 mediating this down-regulation. Gli3 acts repressively in adjacent domains, sharpening the ventral boundary and integrating Shh with BMP/Wnt signals for dorsoventral patterning. Recent studies highlight heterogeneity in primitive node subpopulations, influencing signaling potency and pathway integration. Single-cell analyses reveal dynamic shifts in node cellular composition, with anterior Gsc-positive cells dominating early inductive phases for cephalic fates via enhanced Nodal/BMP antagonism, while posterior Lmo1-positive cells prevail during regression, boosting Wnt/FGF outputs for trunk ; these changes modulate overall organizer potency, as experiments show subpopulation-specific outcomes. Complementary work positions the as a of signaling subsets, each expressing distinct ligands (e.g., Fgf8-enriched groups), whose heterogeneity ensures robust cross-talk across pathways for neural and axial .

Experimental Models and Insights

Studies in Model Organisms

Studies in model organisms have been instrumental in elucidating the of the , drawing from classical transplantation experiments and modern genetic tools to demonstrate its role as an organizer in embryonic axis formation and patterning. Foundational work by and Hilde Mangold in 1924 established the concept of the embryonic organizer through transplantation experiments in embryos, where grafting the dorsal lip of the blastopore (analogous to the primitive node) induced a secondary axis, revealing inductive capacities that pattern the . This discovery laid the groundwork for identifying organizer homologs across vertebrates, influencing subsequent studies on node . In chick embryos, Hensen's node serves as the avian equivalent of the primitive node and has been extensively studied via transplantation assays. In the 1930s, Conrad Hal Waddington demonstrated organizer activity by transplanting Hensen's node to ectopic sites, inducing secondary neural structures and confirming its inductive role in embryos. More recent experiments, such as those using vital dyes to label node cells, have traced their contributions to , somites, and floor plate, highlighting the node's role in generating midline structures during . Additionally, techniques enable targeted in Hensen's node; for instance, introducing morpholinos or RNAi constructs disrupts specific pathways, leading to axis elongation defects and providing insights into nodal regulation. Mouse models have advanced understanding through genetic manipulation and lineage tracing of the . Null mutants of the Nodal gene (Nodal^{-/-}) exhibit severe axis defects, including failure of formation and absence of anterior structures, underscoring Nodal signaling's essential role in node specification and function. Node-specific lines, such as Noto-Cre, allow precise lineage tracing of node-derived cells, revealing their contributions to the and while avoiding off-target labeling in other lineages. These tools have facilitated conditional knockouts, confirming the node's organizer properties in mammals akin to those in other vertebrates. In , the embryonic acts as the functional analog to the primitive node, amenable to experiments that mirror classical organizer assays. Transplantation of the to ventral regions induces ectopic axes, demonstrating its inductive capacity for dorsal and neural tissue formation, as shown in microsurgical studies at early-shield stages. These approaches, building on earlier work by Jane Oppenheimer in , have clarified the 's role in movements and body axis establishment, providing a transparent model for live imaging of node-like dynamics.

Recent Advances and Clinical Relevance

Recent studies from 2020 to 2025 have elucidated the cellular heterogeneity within the primitive node, highlighting its dynamic composition during . In avian embryos, Hensen's node, the equivalent organizer structure, undergoes temporal changes where early stages are enriched with anterior definitive cells that drive , while later stages incorporate posterior progenitors contributing to axial elongation. This segregation shapes the node's inductive capacity and has been characterized through of microdissected tissues. In vitro modeling using human pluripotent stem cells (hPSCs) has advanced the understanding of and formation, particularly for generating progenitors. A 2024 protocol induces anterior patterning in hPSCs via sequential activation of , Wnt, and Nodal signaling, yielding FOXA2+ -like cells that mimic node-derived lineages and enable high-throughput analysis of human . These models reveal transcriptional trajectories from epiblast to organizer cells, bypassing ethical constraints of natural embryos. Live imaging techniques have provided insights into transcription factor dynamics during early fate segregation relevant to node specification. A 2025 study employed endogenously tagged reporters in embryos to track Nanog, , and Gata6 fluctuations, demonstrating oscillatory patterns that bias epiblast toward primitive endoderm fates prior to emergence. Such dynamics inform the regulatory networks active in nascent cells. Dysfunctions in primitive node signaling contribute to human developmental disorders, notably neural tube defects (NTDs) like through disrupted Sonic hedgehog (Shh) pathway activation. The node-derived induces ventral neural tube patterning via Shh secretion; impairments in this axis, often linked to genetic variants in Shh regulators, lead to incomplete neural tube closure. Sonic hedgehog signaling plays a critical role in floor plate induction and NTD etiology. Primitive node errors also underlie , where defective Nodal signaling disrupts left-right asymmetry. Cilia-driven Nodal flow in the node establishes asymmetric (e.g., left-sided Nodal and Pitx2); mutations in Nodal or its effectors cause randomized organ situs. Recent analyses link these to variants affecting node monocilia. Stem cell-based embryo models, including blastoids and gastruloids, recapitulate primitive node formation and hold promise for drug screening in node-related pathologies. Blastoids, derived from naive hPSCs, form primitive streak-like structures with organizer gene expression (e.g., Brachyury, Goosecoid), enabling toxicity assays for NTD therapeutics. Gastruloids further model post-node axial patterning, supporting high-content screens for Shh modulators. A 2025 overview of peri-gastrulation models emphasizes their scalability for identifying teratogens.

References

  1. [1]
    Embryology, Gastrulation - StatPearls - NCBI Bookshelf - NIH
    Apr 23, 2023 · Notochord. Progenitor cells from the primitive node and primitive pit migrate to initiate notochord formation. Epiblast cells from the floor ...
  2. [2]
    Embryology: 3rd week of development - Kenhub
    The primitive node (and streak) is maintained by the hepatocyte nuclear factor 3β (HNF-3 β; a product of the FOXA2 gene). The presence of this protein is also ...
  3. [3]
    Primitive Knot - an overview | ScienceDirect Topics
    The cranial end of the primitive streak forms a thickening known variously as the primitive knot, the primitive node, or Hensen's node. The primitive pit forms ...
  4. [4]
    https://www.cell.com/current-biology/fulltext/S0960-9822(00)00675-8
  5. [5]
    Hensen's Node | Embryo Project Encyclopedia
    Jun 21, 2011 · A node, or primitive knot, is an enlarged group of cells located in the anterior portion of the primitive streak in a developing gastrula.
  6. [6]
    Primitive Pit - an overview | ScienceDirect Topics
    As the notochord develops, the primitive pit extends into it to form the notochordal canal (a lumen).
  7. [7]
    Embryology, Week 2-3 - StatPearls - NCBI Bookshelf
    At the rostrum of the primitive streak, a group of cells forms the primitive node which establishes the left/right axis of the embryo. Epiblast cells ...
  8. [8]
    Week 3 - UNSW Embryology
    Mar 16, 2020 · ExpandWeek 3 - Human Embryo Stages and Events (GA week 5). Embryo ... gastrulation primitive node (Hensen's node, primitive knot) The ...
  9. [9]
    https://embryology.med.unsw.edu.au/embryology/index.php/Week_3
  10. [10]
    The primitive streak and cellular principles of building an amniote ...
    Dec 3, 2021 · We provide evidence that the primitive streak is not a conserved feature in amniote development and that the mammalian and avian primitive ...
  11. [11]
    The development of the amnion in mice and other amniotes - PMC
    Oct 17, 2022 · The rotated and tilted embryo shapes in (b,c) show only epiblast/embryonic ectoderm, primitive streak and amniotic ectoderm. Embryo shapes ...
  12. [12]
    Induction and patterning of the primitive streak, an organizing center ...
    Jan 28, 2004 · The primitive streak is the organizing center for amniote gastrulation. It defines the future embryonic midline and serves as a conduit of cell migration for ...Missing: size | Show results with:size
  13. [13]
    Bi‐modal strategy of gastrulation in reptiles - Stower
    Jun 19, 2015 · (2) Amniotes, such as chick and mouse, form a trough-like structure termed the primitive-streak that runs centripetally from the margin to the ...
  14. [14]
    The evolution of gastrulation morphologies | Development
    Apr 17, 2023 · (A) The increase in yolk size ... A. (. 2021. ). The primitive streak and cellular principles of building an amniote body through gastrulation.
  15. [15]
    Early development and embryology of the platypus - Journals
    The primitive streak develops within an embryonal area as part of the superficial wall of the yolk–sac, a feature also shared with marsupials, birds and ...
  16. [16]
    [PDF] Induction of Embryonic Primordia by Implantation of Organizers from ...
    Facsimile reproduction of the cover of an original reprint of the 1924 article by Hans. Spemann and Hilde Mangold, with a handwritten dedication by H. ... 1924 ...
  17. [17]
    The Fate of Spemann's Organizer - BioOne Complete
    In mice, the primitive streak is a homologous structure of this ring (De Robertis et al., 1994). It has been proved that gsc which is a marker of the dorsal ...
  18. [18]
    microsurgical analysis at the early-shield stage | Development
    Apr 1, 1996 · Homotopic grafting experiments confirmed the fates of cells within the embryonic shield region, showing descendants in the hatching gland, head ...
  19. [19]
    The Organizer and Its Signaling in Embryonic Development - PMC
    Nov 1, 2021 · In the mouse embryo, anterior endoderm emerges from a primitive streak (an organizer homologue) that differentiates into the foregut [153].
  20. [20]
    Molecular Interactions Continuously Define the Organizer during the ...
    We identify a “node inducing center” in the primitive streak, which, like the Nieuwkoop center, is defined by the overlap of the Vg1 and Wnt signaling pathways.
  21. [21]
    Axis development in avian embryos: the ability of Hensen's node to ...
    A series of experiments consisting of transplantation of Hensen's nodes has been conducted to examine axis development in avian embryos.
  22. [22]
    Secondary axis induction by heterospecific organizers in zebrafish
    Grafted Hensen's node did not dif- ferentiate or participate in the secondary axis. It also did not induce a secondary notochord or ex- pression of the genes ...
  23. [23]
    On the nature and function of organizers - PMC - PubMed Central
    For example, we find that there is little evidence for functional or structural homology between the node and the Spemann organizer. ... node and primitive streak ...
  24. [24]
    Induction of primitive streak and Hensen's node by the posterior ...
    Sep 1, 1998 · We conclude that the marginal zone posterior to Koller's sickle can induce a streak and node, without contributing cells to the induced streak.INTRODUCTION · MATERIALS AND METHODS · RESULTS · DISCUSSION
  25. [25]
    Interactions between Wnt and Vg1 signalling pathways initiate ...
    Aug 1, 2001 · Interactions between Wnt and Vg1 signalling pathways initiate primitive streak formation in the chick embryo Available. Isaac Skromne ...
  26. [26]
    Cell movement during chick primitive streak formation - PMC
    The formation of the primitive streak, a condensation of cells in the epiblast, is the first visible sign of gastrulation in the chick embryo (Eyal-Giladi and ...
  27. [27]
    Analysis of tissue flow patterns during primitive streak formation in ...
    The formation of the primitive streak is one of the most striking phenomena in the early development of the chick embryo. The streak forms from epiblast cells ...
  28. [28]
    Hamburger Hamilton Stages - Embryology
    Aug 24, 2018 · Introduction ; 1 · 2 ; 6-7 hr ; Preprimitive streak (embryonic shield) · Initial primitive streak, 0.3-0.5 mm long ...
  29. [29]
    Early Development in Birds - Developmental Biology - NCBI Bookshelf
    At the anterior end of the primitive streak is a regional thickening of cells called the primitive knot or Hensen's node. The center of this node contains a ...Missing: comparative | Show results with:comparative
  30. [30]
    The roles of node regression and elongation of the area pellucida in ...
    Jun 1, 1984 · The rate of regression of Hensen's node was estimated from measurements of the distance between the posterior edge of somite 2 and the primitive ...Missing: driven | Show results with:driven
  31. [31]
    The embryonic node behaves as an instructive stem cell niche for ...
    Hensen's node is part of this growth zone. Rather than defining a distinct cell population arising very early in development, the node represents a dynamic ...
  32. [32]
    The chick embryo late primitive streak and head process studied by ...
    Changes in cell shape during the formation of the head process and regression of Hensen's node have been examined by scanning electron microscopyMissing: distance | Show results with:distance
  33. [33]
    Differential sensitivity of midline development to mitosis during and ...
    Jun 12, 2025 · Despite embryonic size reduction upon mitotic arrest, NC formation persisted together with HN/PS regression and retained their length ...2 Results · 4.9 Imaging Of Chick Embryo · 4.10. 2 Embryo Area And...
  34. [34]
    Regulation of cell migration during chick gastrulation - ScienceDirect
    Regression of the node is most likely driven by the intercalation of axial mesoderm cells and possibly the overlying floor plate and is facilitated by the ...
  35. [35]
    Human gastrulation: The embryo and its models - ScienceDirect.com
    The embryonic disc has become an oval about 1.5–2.5 ​mm in length and displays a recognizable outline of the body plan in the form of raised headfolds at the ...Human Gastrulation: The... · 1. Introduction · 1.1. Embryology: Cellular...<|control11|><|separator|>
  36. [36]
    Definitive endoderm of the mouse embryo: Formation, cell fates, and ...
    Jun 2, 2006 · The definitive endoderm forms during gastrulation and replaces the extraembryonic visceral endoderm. It participates in the complex morphogenesis of the gut ...
  37. [37]
    Sequential allocation and global pattern of movement of the ...
    Jan 15, 2007 · The newly recruited definitive endoderm rapidly expands to displace the pre-existing visceral endoderm to extraembryonic sites. In addition, we ...
  38. [38]
    Cell fate and morphogenetic movement in the late mouse primitive ...
    A prospective fate map of the late gastrulation mouse primitive streak has been charted in 8.5 dpc mouse embryos developed in culture.
  39. [39]
    The orderly allocation of mesodermal cells to the extraembryonic ...
    Nov 1, 1999 · The prospective fate of cells in the primitive streak was examined at early, mid and late stages of mouse gastrula development to determine the order of ...
  40. [40]
    Mouse gastrulation: coordination of tissue patterning, specification ...
    Starting at E6.25 the primitive streak can be identified morphologically as cells begin to undergo epithelial-to-mesenchymal transition (EMT) and delaminate ...
  41. [41]
    Notochord Morphogenesis in Mice: Understanding & Questions
    The notochord is the structure which defines chordates. It is a rod-like mesodermal structure that runs the anterior-posterior length of the embryo, adjacent ...<|control11|><|separator|>
  42. [42]
    Mechanics of anteroposterior axis formation in vertebrates - PMC - NIH
    Jul 31, 2020 · The vertebrate anteroposterior (AP) axis forms through elongation of multiple tissues during embryonic development.
  43. [43]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC7534585/
  44. [44]
    Gastrulation and Body Axes Formation: A Molecular Concept and Its ...
    Cells arising from the anterior most of the primitive streak create the axial mesoderm, which later develops into the notochord, according to fate-mapping ...<|control11|><|separator|>
  45. [45]
    Vertebrate Axial Patterning: From Egg to Asymmetry - PMC
    In human embryology, Hensen's node is referred to as the primitive node/knot ... BMP inhibition initiates neural induction via FGF signaling and Zic genes.<|control11|><|separator|>
  46. [46]
    Induction of a Second Neural Axis by the Mouse Node - PubMed
    The ectopic notochord formed is derived solely from the donor node which suggests that the node can serve as a 'stem cell' source of axial mesoderm. This is ...
  47. [47]
    goosecoid is not an essential component of the mouse gastrula ...
    Sep 1, 1995 · In the mouse, gsc-expressing cells are found transiently at the anterior end of the primitive streak of the gastrula between E6.4 and E6.8 (Blum ...
  48. [48]
    Charting Brachyury-mediated developmental pathways during early ...
    Mar 10, 2014 · During early mouse gastrulation, Brachyury (T), a classical enhancer-binding transcription factor (TF), has been reported to be required for the ...
  49. [49]
    Microarray analysis of Foxa2 mutant mouse embryos reveals novel ...
    Oct 30, 2008 · We identified 10 novel expression patterns in the node and 5 in the definitive endoderm. We also found significant reduction of markers ...
  50. [50]
    Targeted disruption of Fgf8 causes failure of cell migration in the ...
    Abstract. Fgf8 and Fgf4 encode FGF family members that are coexpressed in the primitive streak of the gastrulating mouse embryo.
  51. [51]
    Nodal signaling: developmental roles and regulation | Development
    Mar 15, 2007 · The Nodal signaling pathway is integral to processes of pattern formation and differentiation that take place during the pre-gastrulation and gastrulation ...Missing: autocrine | Show results with:autocrine
  52. [52]
    Noggin-mediated antagonism of BMP signaling is required for ...
    Noggin is not essential for neural induction but is required for normal growth and patterning of the neural tube and somite. Thus, inhibition of endogenous BMP ...
  53. [53]
    Neural induction: New insight into the default model and an ...
    Mar 19, 2025 · All of these data indicate that in amniotes, neural induction begins prior to the formation of the primitive node, and this node may stabilize ...
  54. [54]
    Distinct Sonic Hedgehog signaling dynamics specify floor plate and ...
    This suggests that FoxA2 is involved, directly or indirectly, in the down-regulation of Shh signaling within midline cells that is necessary for FP development.
  55. [55]
    Changes in cellular composition shape the inductive properties of ...
    Aug 22, 2025 · The node forms at the anterior end of the primitive streak in the early gastrula and subsequently moves posteriorly during neurulation. Fate ...
  56. [56]
    The organizer as a cooperative of signaling cells for neural induction
    Mar 6, 2025 · The tip of the chick primitive streak has full neural inducing activity from stages(21) (HH) 3+−4, after which the node starts to lose its ...<|control11|><|separator|>
  57. [57]
    Spemann-Mangold Organizer | Embryo Project Encyclopedia
    Jan 12, 2012 · To explore neural plate induction, Spemann first performed a transplant experiment that was nearly identical to the later organizer experiment.
  58. [58]
    "Experiments on the Development of Chick and Duck Embryos ...
    Nov 8, 2007 · Waddington used these experiments to show that the higher vertebrates did have tissues equivalent to an organizer. This tissue was centered ...
  59. [59]
    Fates and migratory routes of primitive streak cells in the chick embryo
    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).
  60. [60]
    Specific and effective gene knock-down in early chick embryos ...
    Electroporation of different gene silencing vectors causes ectopic expression and/or loss of preplacodal, placodal or neural markers. These effects are not ...
  61. [61]
    Tracing notochord-derived cells using a Noto-cre mouse
    Jan 1, 2012 · Expression of Noto is detected at E7.5 within the ventral node, with the onset of primitive streak formation. Between E8.0 and E9.0, Noto is ...
  62. [62]
    In vitro modelling of anterior primitive streak patterning with human ...
    In vitro modelling of anterior primitive streak patterning with human pluripotent stem cells identifies the path to notochord progenitors Open Access Icon for ...
  63. [63]
    Integrative Analysis of Key Signalling Pathways in Neural Tube ...
    Sep 2, 2025 · This article comprehensively reviews the underlying mechanisms of three crucial signalling pathways associated with neural tube development: ...Missing: primitive node
  64. [64]
    Nodal activity in the node governs left-right asymmetry - PMC - NIH
    Embryos lacking Nodal in the node fail to initiate molecular asymmetry in the left lateral plate mesoderm and exhibit multiple left-right patterning defects.Missing: knockout | Show results with:knockout
  65. [65]
    Human Blastoid: A Next-Generation Model for Reproductive ...
    The formation of the primitive streak is a key stage in early embryonic ... Blastoids also hold great promise as a platform for drug screening and ...Missing: node | Show results with:node