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

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(&bgr;). 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.     

Early steps in neural development

We studied early neurulation events in vitro by transplanting quail Hensen's node, central prenodal regions (before the nodus as such develops), or upper layer parts of it on the not yet definitively committed upper layer of chicken anti-sickle regions (of unincubated blastoderms), eventually associated with central blastoderm fragments. We could demonstrate by this quail-chicken chimera technique that after the appearance of a pronounced thickening of the chicken upper layer by the early inductive effect of neighboring endophyll, a floor plate forms by insertion of Hensen's node-derived quail cells into the median part of the groove. This favors, at an early stage, the floor plate "allocation" model that postulates a common origin for notochord and median floor plate cells from the vertebrate's secondary major organizer (Hensen's node in this case). A comparison is made with results obtained after transplantation of similar Hensen's nodes in isolated chicken endophyll walls or with previously obtained results after the use of the grafting procedure in the endophyll walls of whole chicken blastoderms.     

Tsukushi functions as an organizer inducer by inhibition of BMP activity in cooperation with chordin

During chick gastrulation, inhibition of BMP signaling is required for primitive streak formation and induction of Hensen's node. We have identified a unique secreted protein, Tsukushi (TSK), which belongs to the Small Leucine-Rich Proteoglycan (SLRP) family and is expressed in the primitive streak and Hensen's node. Grafts of cells expressing TSK in combination with the middle primitive streak induce an ectopic Hensen's node, while electroporation of TSK siRNA inhibits induction of the node. In Xenopus embryos, TSK can block BMP function and induce a secondary dorsal axis, while it can dorsalize ventral mesoderm and induce neural tissue in embryonic explants. Biochemical analysis shows that TSK binds directly to both BMP and chordin and forms a ternary complex with them. These observations indicate that TSK is an essential dorsalizing factor involved in the induction of Hensen's node.     

Regression of Hensen's node and axial growth of the embryo]

Hensen's node is the gastrulation center in the avian embryo. It is the homologue of the amphibian dorsal blastopore lip and the zebrafish shield. It contains the progeny of all midline cells (floor plate of the neural tube, notochord and dorsal endoderm). However, microsurgical experiments on Hensen's node allow to think that organizer function is due to an extremely limited region situated in the caudal part of Hensen's node which corresponds to the boundary between prospective axial mesoderm rostrally and paraxial mesoderm caudally. This interface is essential for Hensen's node regression and organization of the caudal part of the body.     

Endophyll orients and organizes the early head region of the avian embryo.

By placing endophyll on the caudal area marginalis situated behind Rauber's sickle of avian unincubated blastoderms, we observed after using the quail-chick chimera system and culture the development of a (pre)neural plate or a miniature embryo, head-oriented towards this endophyll. A Rauber's sickle fragment placed in the same conditions gives no reaction. If we place endophyll close to Hensen's node (stage 4 Vakaet, 1962) on an isolated anti-sickle region of an avian unincubated blastoderm in vitro, a similar endophyll-oriented development takes place after culture. Under the same conditions, but in the absence of endophyll, a Hensen's node provokes a thickening of the upper layer in the immediate neighbourhood, eventually with formation of a neural axis, oriented according to the original caudocranial direction of the graft. Our study indicates that avian endophyll (from unincubated blastoderms) can induce in the upper layer a (pre)neural plate, with or without neural folds. By interaction with sickle endoblast coming from Rauber's sickle (the early gastrulation organizer: Callebaut and Van Nueten, 1994), or from Hensen's node (a later avian organizer: Waddington, 1932), it can orient or re-orient the head region and the caudocranial direction of an induced miniature embryo. The conclusions from our embryological experiments are in agreement with the results obtained by recent molecular biology studies.     

Hensen's node,but not other biological signallers,can induce supernumerary digits in the developing chick limb bud

Summary The purpose of this study was to determine whether the organizer regions of early avian and amphibian embryos could induce supernumerary (SN) wing structures to develop when they were grafted to a slit in the anterior side of stage 19–23 chick wing buds. Supernumerary digits developed in 43% of the wings that received anterior grafts of Hensen's node from stage 4–6 quail or chick embryos; in addition, 16% of the wings had rods of SN cartilage, but not recognizable SN digits. The grafted quail tissue did not contribute to the SN structures. When tissue anterior or lateral to Hensen's node or lateral pieces of the area pellucida caudal to Hensen's node were grafted to anterior slits, the wings usually developed normally. No SN structures developed when Hensen's nodes were grafted to posterior slits in chick wing buds. Wings developed normally when pieces of the dorsal lip of the blastopore from stage 10–11.5 frog (Xenopus laevis and Rana pipiens) embryos were grafted to anterior slits. No SN digits developed when other tissues that have limb-inducing activity in adult urodele amphibians [chick otic vesicle, frog (Rana pipiens) lung and kidney] or that can act as heteroinductors in neural induction (rat kidney, lung, submaxillary gland and urinary bladder; mouse liver and submaxillary gland) were grafted to anterior slits in chick wing buds. SN digits also failed to develop following preaxial grafts of chick optic vesicles. These results suggest that although the anteroposterior polarity of the chick wing bud can be influenced by factors other than the ZPA (e.g., Hensen's node, retinoids), the wing is not so labile that it can respond to a wide variety of inductively-active tissues.     

Fate mapping and cell lineage analysis of Hensen's node in the chick embryo.

Fate maps of chick Hensen's node were generated using DiI and the lineage of individual cells studied by intracellular injection of lysine-rhodamine-dextran (LRD). The cell types contained within the node are organized both spatially and temporally. At the definitive primitive streak stage (Hamburger and Hamilton stage 4), Hensen's node contains presumptive notochord cells mainly in its anterior midline and presumptive somite cells in more lateral regions. Early in development it also contains presumptive endoderm cells. At all stages studied (stages 3-9), some individual cells contribute progeny to more than one of these tissues. The somitic precursors in Hensen's node only contribute to the medial halves of the somites. The lateral halves of the somites are derived from a separate region in the primitive streak, caudal to Hensen's node.     

Hensen's node induces neural tissue in Xenopus ectoderm. Implications for the action of the organizer in neural induction.

The development of the vertebrate nervous system is initiated in amphibia by inductive interactions between ectoderm and a region of the embryo called the organizer. The organizer tissue in the dorsal lip of the blastopore of Xenopus and Hensen's node in chick embryos have similar neural inducing properties when transplanted into ectopic sites in their respective embryos. To begin to determine the nature of the inducing signals of the organizer and whether they are conserved across species we have examined the ability of Hensen's node to induce neural tissue in Xenopus ectoderm. We show that Hensen's node induces large amounts of neural tissue in Xenopus ectoderm. Neural induction proceeds in the absence of mesodermal differentiation and is accompanied by tissue movements which may reflect notoplate induction. The competence of the ectoderm to respond to Hensen's node extends much later in development than that to activin-A or to induction by vegetal cells, and parallels the extended competence to neural induction by axial mesoderm. The actions of activin-A and Hensen's node are further distinguished by their effects on lithium-treated ectoderm. These results suggest that neural induction can occur efficiently in response to inducing signals from organizer tissue arrested at a stage prior to gastrulation, and that such early interactions in the blastula may be an important component of neural induction in vertebrate embryos.     

Tsukushi cooperates with VG1 to induce primitive streak and Hensen's node formation in the chick embryo

Three classes of signaling molecule, VG1, WNT and BMP, play crucial roles in axis formation in the chick embryo. Although VG1 and WNT signals have a pivotal function in inducing the primitive streak and Hensen's node in the embryo midline, their action is complemented by that of BMP antagonists that protect the prospective axial tissue from the inhibitory influence of BMPs secreted from the periphery. We have previously reported that a secreted factor, chick Tsukushi (TSK), is expressed in the primitive streak and Hensen's node, where it works as a BMP antagonist. Here, we describe a new crucial function for TSK in promoting formation of the primitive streak and Hensen's node by positively regulating VG1 activity. We provide evidence that TSK directly binds VG1 in vitro, and that TSK and VG1 functionally interact in axis formation, as shown by biological assays performed in chick and Xenopus embryos. Furthermore, we show that alternative splicing of TSK RNA leads to the formation of two isoforms (TSKA, originally designated as TSK, and TSKB) that differ in their C-terminal region. Biochemical and biological assays indicate that TSKB is a much weaker BMP antagonist than TSKA, although both isoforms efficiently interact with VG1. Remarkably, although both TSKA and TSKB are expressed throughout the early extending primitive streak, their expression patterns diverge during gastrulation. TSKA expression concentrates in Hensen's node, a well-known source of anti-BMP signals, whereas TSKB accumulates in the middle primitive streak (MPS), a region known to work as a node-inducing center where VG1 expression is also specifically localized. Loss-of-function experiments demonstrate that TSKB, but not TSKA, function is required in the MPS for induction of Hensen's node. Taken together, these results indicate that TSK isoforms play a crucial role in chick axis formation by locally modulating VG1 and BMP activities during gastrulation.     

The Opitz syndrome gene MID1 is essential for establishing asymmetric gene expression in Hensen's node

Patterning the avian left-right (L/R) body axis involves the establishment of asymmetric molecular signals on the left and right sides of Hensen's node. We have examined the role of the chick Midline 1 gene, cMid1, in generating asymmetric gene expression in the node. cMid1 is initially expressed bilaterally, but its expression is then confined to the right side of the node. We show that this restriction of cMid1 expression is a result of repression by Shh on the left side of the node. Misexpression of cMid1 on the left side of the node results in bilateral Bmp4 expression and a loss of Shh expression. Correspondingly, downstream left pathway genes are repressed while right pathway genes are ectopically activated. Conversely, knocking down endogenous right-sided cMid1 results in a loss of Bmp4 expression and bilateral Shh expression. This results in an absence of right pathway genes and the ectopic activation of the left pathway on the right. Here, we present a revised model for the establishment of asymmetric gene expression in Hensen's node based on the epistatic interactions observed between Shh, cMid1, and Bmp4.     

Cardiac-Like Action Potentials Recorded from Spontaneously-Contracting Structures Induced in Post-Nodal Pieces of Chick Blastoderm Exposed to an RNA-Enriched Fraction from Adult Heart

In 19–20-h-old chick embryonic blastoderm, the portion anterior to Hensen's node contains the cells which are destined to give rise to the heart, whereas the cells in the portion of the blastoderm posterior to Hensen's node (the post-nodal piece, PNP) normally do not. However, when the PNP was isolated from the blastoderm by cutting 0.6 mm posterior to Hensen's node and the isolated PNP was exposed to an RNA-enriched extract obtained from adult chicken heart, a spontaneously contracting tubular structure was formed in vitro within 1 week. Typical cardiac action potentials, both spontaneous and evoked, were recorded by intracellular microelectrodes from cells within these contracting tubules. Actinomycin D or cycloheximide prevented the inducing effect of the RNA extract. Induction of tubule formation and the appearance of excitability did not occur in untreated controls or in PNPs treated with RNA-containing extracts from adult chicken liver. These results indicate that cells not originally destined to become myocardial cells can be induced to gain many of the properties of heart cells by an RNA-enriched fraction from adult heart, and that this induction is dependent upon protein synthesis. Although it is not known what substance is the active principle, it is likely to be RNA.     

Experimental analyses of the rearrangement of ectodermal cells during gastrulation and neurulation in avian embryos

The rearrangement of ectodermal cells was studied in chimeras in which grafts were transplanted during late gastrula and early neurula stages to heterotopic locations in avian embryos. Three types of experiments were done. In all experiments, Hensen's node was extirpated completely and replaced with an epithelial plug derived from 1 of 3 regions of the prospective ectoderm. In type-1 experiments, Hensen's node was replaced with a plug consisting of precursor cells of the floor plate of the neural tube. In type-2 experiments, Hensen's node was replaced with a plug consisting of precursor cells of the lateral wall of the neural tube. In type-3 experiments, Hensen's node was replaced with a plug consisting of precursor cells of the epidermal ectoderm. In all experiments, the amount and direction of cell rearrangement that occurred in the transplanted ectodermal plug was essentially typical for prospective ectodermal cells normally residing within Hensen's node. That is, transplanted ectodermal cells underwent lateralto-medial cell-cell intercalation and contributed to the ventral midline of the neural tube along its entire rostrocaudal extent. In most embryos, a notochord was reconstituted from host cells, despite the fact that Hensen's node — the prime source of prospective notochordal cells in intact embryos — was extirpated completely; however, a few embryos had long notochordal gaps. In such essentially notochordless embryos, the ventral midline of the neural tube still derived from grafted cells, but it failed to form a floor plate, providing further confirmation of the results of several previous studies that the notochord is required to induce the floor plate. Collectively, our results provide evidence that the rearrangement of ectodermal cells does not require the presence of a trail of prospective floor plate cells (laid down by the regressing Hensen's node), or of a notochordal substrate, and that the continued presence of an organizer per se, ostensibly Hensen's node, is not required. In addition, our results demonstrate that the rearrangement of cells still occurs in the absence of boundaries between ectodermal cells of different phenotypes (e.g., between cells of the floor plate and lateral walls of the neural tube). Finally, our results reveal further that the amount and direction of cellular rearrangement is not regulated in a cell-autonomous fashion, but rather it is determined by the overall magnitude and vector of the displacement of the community of rearranging cells within a developmental field.     

An early marker of axial pattern in the chick embryo and its respecification by retinoic acid.

Chick Ghox 2.9 protein, a homeodomain-containing polypeptide, is first detected in the mid-gastrula stage embryo and its levels increase rapidly in the late gastrula. At this time, the initially narrow band of expression along the primitive streak expands laterally to form a shield-like domain that encompasses almost the entire posterior region of the embryo and extends anteriorly as far as Hensen's node. We have found that this expression domain co-localizes with a morphological feature that consists of a stratum of refractile, thickened mesoderm. Antibody-staining indicates that Ghox 2.9 protein is present in all cells of this mesodermal region. In contrast, expression within the ectoderm overlying the region of refractile mesoderm varies considerably. The highest levels of expression are found in ectoderm near the streak and surrounding Hensen's node, regions that recent fate mapping studies suggest that primarily destined to give rise to neurectoderm. At the definitive streak stage (Hamburger and Hamilton stage 4) the chick embryo is especially sensitive to the induction of axial malformations by retinoic acid. Four hours after the treatment of definitive streak embryos with a pulse of retinoic acid the expression of Ghox 2.9 protein is greatly elevated. This ectopic expression occurs in tissues anterior to Hensen's node, including floor plate, notochord, presumptive neural plate and lateral plate mesoderm, but does not occur in the anteriormost region of the embryo. The ectopic induction of Ghox 2.9 is strongest in ectoderm, and weaker in the underlying mesoderm. Endoderm throughout the embryo is unresponsive. At stage 11, Ghox 2.9 is normally expressed at high levels within rhombomere 4 of the developing hindbrain. In retinoic-acid-treated embryos which have developed to this stage, typical rhombomere boundaries are largely absent. Nevertheless, Ghox 2.9 is still expressed as a discrete band, but one that is widened and displaced to a more anterior position.     

Distribution of Acid Phosphatase in Chick Hensen's Node

Acid phosphatase distribution and yolk drop infrastructure in Hensen's node of chick blastoderm at Hamburger-Hamilton stages 3 and 4 are described. At stage 3 large deposits of the reaction product are localised in type-A yolk drops, where signs of intensive degradation are seen. It seems that during this degradation lipid droplets are being formed in the degrading yolk drops. Partly digested yolk drops with a vesicular appearance are extruded from the cells, especially in deeper layers of the node. The phosphatase reaction product is also distributed into intercellular spaces. At stage 4 the cells of the node are more vacuolated and contain acid phosphatase and electron-dense yolk drops in lesser amounts. The possible physiological role of acid phosphatase in Hensen's node during g'astrulation is discussed.     

The determination of myogenic and cartilage cells in the early chick embryo and the modifying effect of retinoic acid

Summary The time of determination of cartilage and skeletal muscle was studied by making chimeric grafts or explants of small tissue pieces from several stages of early chick or quail embryos. Chondrogenesis was assessed by histology or with antibodies directed against type II collagen or cartilage proteoglycan, while myogenesis was detected immunohistochemically with antibodies directed against 3 different muscle markers, including muscle myosin. Grafts from Hensen's node, primitive streak and segmental plate of donor embryos of Stage 3–5 (Hamburger and Hamilton) were transplanted under the ectoderm in the extraembryonic area of Stage 12 host embryos. In addition, explants and mesodermal cells were cultured on glass in DMEM+F12 medium supplemented with 10% FCS. The results showed that determined myogenic cells could first be detected in Hensen's node and the primitive streak at Stage 3⁺–4 and that they developed from mesodermal cells located between the epiblast and hypoblast. Myogenic cells also appeared in grafted and explanted segmental plate with or without notochord from Stage 5 embryos. On the other hand, cartilage cells only formed in grafted and explanted segmental plate that also contained notochord. RA (1 ng/ml) could induce the formation of cartilage cells in the explanted primitive streak without Hensen's node or notochord taken from Stage 3–5 embryos and could also promote the differentiation of myogenic cells in primitive streak from Stage 3 embryo. Thus RA can substitute for Hensen's node or the notochord in the induction of cartilage cells and has some stimulatory effects on the differentiation of myogenic cells. Additional evidence indicates that the hypoblast might play an inductive role in the formation of the notochord which may subsequently promote the differentiation of cartilage cells. Offprint requests to: M. Solursh     

FGF receptor signalling is required to maintain neural progenitors during Hensen's node progression

Previous analyses of labelled clones of cells within the developing nervous system of the mouse have indicated that descendants are initially dispersed rostrocaudally followed by more local proliferation, which is consistent with the progressing node's contributing descendants from a resident population of progenitor cells as it advances caudally. Here we electroporated an expression vector encoding green fluorescent protein into the chicken embryo near Hensen's node to test and confirm the pattern inferred in the mouse. This provides a model in which a proliferative stem zone is maintained in the node by a localized signal; those cells that are displaced out of the stem zone go on to contribute to the growing axis. To test whether fibroblast growth factor (FGF) signalling could be involved in the maintenance of the stem zone, we co-electroporated a dominant-negative FGF receptor with a lineage marker, and found that it markedly alters the elongation of the spinal cord primordium. The results indicate that FGF receptor signalling promotes the continuous development of the posterior nervous system by maintaining presumptive neural progenitors in the region near Hensen's node. This offers a potential explanation for the mixed findings on FGF in the growth and patterning of the embryonic axis.