Regional specification of the endoderm in the early chick embryo

In the avian embryo, the endoderm, which forms a simple flat-sheet structure after gastrulation, is regionally specified in a gradual manner along the antero-posterior and dorso-ventral axes, and eventually differentiates into specific organs with defined morphologies and gene expression profiles. In our study, we carried out transplantation experiments using early chick embryos to elucidate the timing of fate establishment in the endoderm. We showed that at stage 5, posteriorly grafted presumptive foregut endoderm expressed CdxA , a posterior endoderm marker, but not cSox2 , an anterior endoderm marker. Conversely, anteriorly grafted presumptive mid-hindgut endoderm expressed cSox2 but not CdxA . At stage 8, posteriorly grafted presumptive foregut endoderm also expressed CdxA and not cSox2 , but anteriorly grafted presumptive mid-hindgut endoderm showed no changes in its posterior-specific gene expression pattern. At stage 10, both posteriorly grafted foregut endoderm and anteriorly grafted mid-hindgut endoderm maintain their original gene expression patterns. These results suggest that the regional specification of the endoderm occurs between stages 8 and 10 in the foregut, and between stages 5 and 8 in the mid-hindgut.     

An early requirement for FGF signalling in the acquisition of neural cell fate in the chick embryo

BACKGROUND: In Xenopus embryos, fibroblast growth factors (FGFs) and secreted inhibitors of bone morphogenetic protein (BMP)-mediated signalling have been implicated in neural induction. The precise roles, if any, that these factors play in neural induction in amniotes remains to be established. RESULTS: To monitor the initial steps of neural induction in the chick embryo, we developed an in vitro assay of neural differentiation in epiblast cells. Using this assay, we found evidence that neural cell fate is specified in utero, before the generation of the primitive streak or Hensen's node. Early epiblast cells expressed both Bmp4 and Bmp7, but the expression of both genes was downregulated as cells acquired neural fate. During prestreak and gastrula stages, exposure of epiblast cells to BMP4 activity in vitro was sufficient to block the acquisition of neural fate and to promote the generation of epidermal cells. Fgf3 was also found to be expressed in the early epiblast, and ongoing FGF signalling in epiblast cells was required for acquisition of neural fate and for the suppression of Bmp4 and Bmp7 expression. CONCLUSIONS: The onset of neural differentiation in the chick embryo occurs in utero, before the generation of Hensen's node. Fgf3, Bmp4 and Bmp7 are each expressed in prospective neural cells, and FGF signalling appears to be required for the repression of Bmp expression and for the acquisition of neural fate. Subsequent exposure of epiblast cells to BMPs, however, can prevent the generation of neural tissue and induce cells of epidermal character.     

Involvement of fibroblast growth factor (FGF)18-FGF8 signaling in specification of left-right asymmetry and brain and limb development of the chick embryo

To elucidate roles of fibroblast growth factors (FGF)18 during vertebrate development, we examined expression patterns of Fgf18 in chick embryos and observed effects of FGF18 protein on the Hensen's node, isthmus, and limb buds. Fgf18 is expressed on the right side of the node before the expression of Fgf8 starts. FGF18 protein can induce expression of Fgf8 on the left side of the node, indicating involvement of both FGFs in specification of left-right asymmetry. In the developing brain, Fgf18 is expressed in the isthmus, following the Fgf8 expression. Since Fgf18 is induced ectopically during formation of the second midbrain by FGF8 protein, both FGFs also elaborate midbrain development. In the limb bud, Fgf18 is expressed in the mesenchyme and ectopic application of FGF18 protein inhibits bone growth in the limb. FGF18 is thus likely an endogenous ligand of FGF receptor 3, whose mutation causes bone dysplasia in humans. These results demonstrate that the FGF18-FGF8 signaling is involved in various organizing activities and the signaling hierarchies between FGF18 and FGF8 seem to change during patterning of different structures.     

Fine-grained fate maps for the ophthalmic and maxillomandibular trigeminal placodes in the chick embryo

Vertebrate cranial ectodermal placodes are transient, paired thickenings of embryonic head ectoderm that are crucial for the formation of the peripheral sensory nervous system: they give rise to the paired peripheral sense organs (olfactory organs, inner ears and anamniote lateral line system), as well as the eye lenses, and most cranial sensory neurons. Here, we present the first detailed spatiotemporal fate-maps in any vertebrate for the ophthalmic trigeminal (opV) and maxillomandibular trigeminal (mmV) placodes, which give rise to cutaneous sensory neurons in the ophthalmic and maxillomandibular lobes of the trigeminal ganglion. We used focal DiI and DiO labelling to produce eight detailed fate-maps of chick embryonic head ectoderm over approximately 24 h of development, from 0-16 somites. OpV and mmV placode precursors arise from a partially overlapping territory; indeed, some individual dyespots labelled both opV and mmV placode-derived cells. OpV and mmV placode precursors are initially scattered within a relatively large region of ectoderm adjacent to the neural folds, intermingled both with each other and with future epidermal cells, and with geniculate and otic placode precursors. Although the degree of segregation increases with time, there is no clear border between the opV and mmV placodes even at the 16-somite stage, long after neurogenesis has begun in the opV placode, and when neurogenesis is just beginning in the mmV placode. Finally, we find that occasional cells in the border region between the opV placode and mmV placode express both Pax3 (an opV placode specific marker) and Neurogenin1 (an mmV placode specific marker), suggesting that a few cells are responding to both opV and mmV placode-inducing signals. Overall, our results fill a large gap in our knowledge of the early stages of development of both the opV and mmV placodes, providing an essential framework for subsequent studies of the molecular control of their development.     

Limbness in the early chick embryo lateral plate

In order for the limb to be useful in the evaluation of early determinants of morphogenesis, it is necessary to understand some of the characteristics associated with "limbness" and, more importantly at the beginning at least, it is necessary to know what regions of the early embryo exhibit limbness qualities. Previous investigators have assumed, without direct experimental evidence, that the flank does not have limbness qualities, even at early stages of development. However, there are a few studies suggesting that the early flank does possess limbness qualities. The purpose of the present study was to determine how extensively the qualities of limbness exist in the early chick embryo. Tissues from the future neck, wing, flank, and leg regions were grafted to host celoms and evaluated for their abilities to form limbs. Limbs developed from all four regions of stage 11-14 embryos, but after stage 14 only grafts from the wing and leg regions formed limbs.     

Serum protein synthesis in the early chick embryo

Isolated yolk-sacs of chick embryos secreted serum proteins when incubated in buffered chick Ringer's solution. The presence of serum transferrin, two embryo-specific alpha-globulins, and a prealbumin were demonstrated by acrylamide gel analysis. Yolk-sacs from embryos explanted at 11-13 somites (40 hr preincubation) and cultured for 48 hr secreted in addition a protein with the mobility of serum albumin. Incubation of yolk-sacs in the presence of radioactive valine indicated that serum proteins were synthesized as early as the primitive streak stage. By incubating isolated yolk-sacs and embryos from 48-hr explants in the presence of radioactive valine, the synthesis of serum proteins was found to be restricted to the yolk-sac at this stage of development. Culturing explants on various nutrient proteins as well as protein starvation medium altered the relative synthesis of several serum proteins. We have proposed that morphological and biochemical changes in embryos resulting from altered nutrition may be mediated by the proteins of the serum.     

FGF signaling is required for determination of otic neuroblasts in the chick embryo

The interplay between intrinsic and extrinsic factors is essential for the transit into different cell states during development. We have analyzed the expression and function of FGF10 and FGF-signaling during the early stages of the development of otic neurons. FGF10 is expressed in a highly restricted domain overlapping the presumptive neurogenic region of the chick otic placode. A detailed study of the expression pattern of FGF10, proneural, and neurogenic genes revealed the following temporal sequence for the onset of gene expression: FGF10>Ngn1/Delta1/Hes5>NeuroD/NeuroM. FGF10 and FGF receptor inhibition cause opposed effects on cell determination and cell proliferation. Ectopic expression of FGF10 in vivo promotes an increase in NeuroD and NeuroM expression. BrdU incorporation experiments showed that the increase in NeuroD-expressing cells is not due to an increase in cell proliferation. Inhibition of FGF receptor signaling in otic explants causes a severe reduction in Neurogenin1, NeuroD, Delta1, and Hes5 expression with no change in non-neural genes like Lmx1. However, it does not interfere with NeuroD expression within the CVG or with neuroblast delamination. The loss of proneural gene expression caused by FGF inhibition is not caused by decreased cell proliferation or by increased cell death. We suggest that FGF signaling in the otic epithelium is required for neuronal precursors to withdraw from cell division and irreversibly commit to neuronal fate.     

Pattern formation: Regional specification in the early C. elegans embryo

Recent findings suggest that C. elegans, albeit displaying an invariant cell lineage for embryonic development, uses the same basic strategy for embryogenesis as other organisms. The early embryo is regionalised by cell-cell interactions.     

Membrane-cytoskeletal interactions in the early mouse embryo

Differentiation in the early mouse embryo begins at the 8-cell stage when the blastomeres flatten against each other by active spreading movements and surface and cytoplasmic elements become concentrated in the apical (uncontacted) region of the cells. A ring of cortical myosin marks the demarcation between the contacted and the uncontacted cellular domains. The organization of the cortical contractile apparatus in the blastomeres bears a formal resemblance to that of other cells that are engaged in similar motile activities. It has been proposed that a flow of cortical filaments could provide the motor that powers these movements. The applicability of such a cortical flow model to the early embryo and the implications for cell flattening and cell polarization are discussed in this review.     

Lead-induced early lesions in the brain of the chick embryo

A single dose consisting of a solution of lead nitrate containing 1 mg lead in 0.1 ml distilled water was injected into the air chamber of chicken eggs on the tenth day of incubation. The injected embryos were killed 24, 48, or 72 hours after the injection. Control embryos were injected with a similar volume of distilled water or of an equimolar calcium nitrate solution on the tenth day and killed 72 hours after. Portions of the optic lobes were processed for their electron microscopic study. Multiple hemorrhagic foci appeared 24 hours after the administration of lead. Red blood cells were found to exit the blood vessels through the spaces between otherwise normal-looking endothelial cells; tight junctions were always found blocking the interendothelial spaces except during the migration of red blood cells through them. Vacuolization of the cytoplasm and mitochondrial swelling and disorganization were observed in the endothelial cells only during the third day after the injection. Similarly, histological and ultrastructural alterations of nerve cells were only found on the third day after the treatment. Hemorrhagic foci were never found in control embryos. Our observations are consistent with the idea that the hemorrhages constitute the primary lesion produced by lead. They also suggest that the hemorrhages are not the result of rupture of previously altered endothelial walls but occur by diapedesis through the interendothelial clefts.