The pattern of protein and glycoprotein synthesis in presumptive lens and non-lens ectoderm of the chicken embryo

Summary Lens induction is a classic example of the tissue interactions that lead to cell specialization during early vertebrate development. Previous studies have shown that a large region of head ectoderm, but not trunk ectoderm, of 36 h (stage 10) chicken embryos retains the potential to form lenses and synthesize the protein δ-crystallin under some conditions. We have used polyacrylamide gel electrophoresis and fluorography to examine protein and glycoprotein synthesis in presumptive lens ectoderm and presumptive dorsal (trunk) epidermis to look for differentiation markers for these two regions prior to the appearance of δ-crystallin at 50 h. Although nearly all of the proteins incorporating³H-leucine were shared by presumptive lens ectoderm and trunk ectoderm, these two regions showed more dramatic differences in the incorporation of³H-sugars into glycoproteins. when non-lens head ectoderm that has a capacity for lens formation in vitro was labeled, a hybrid pattern of glycoprotein synthesis was discovered: glycoproteins found in either presumptive lens ectoderm or trunk ectoderm were oftentimes also found in other head ectoderm. Therefore, molecular markers have been identified for three regions of ectoderm committed to different fates (lens and skin), well before features of terminal differentiation begin to appear in the lens.     

BRAIN INDUCTION IN VARIOUSLY AGED PRESUMPTIVE ECTODERMS BY HEAD ORGANIZER IN CYNOPS PYRRHOGASTER

Brain formation in variously aged presumptive ectoderms of Cynops pyrrhogaster under the influence of the head organizer was examined by the sandwich method. The head organizer was obtained from the middle portion of the archenteron roof at the slit-blastopore stage. The presumptive ectoderm was taken from 0- to 36-hr exogastrulae. Exogastrulae were prepared from the earliest gastrulae just before invagination (0-hr embryos). The presumptive neural plate overlying the archenteron roof used as organizer was cultivated in an envelope of belly ectoderm from an early neurula.
The following results were obtained: 1) Brain induction was almost entirely restricted to explants covered with 6-hr ectoderm and its frequency was low. 2) The presumptive neural plate above the head organizer was almost completely determined as neural tissues. 3) The head organizer showed a tendency to differentiate into more endodermal and less mesodermal tissues than those expected from its prospective fate.
Brain induction in normal development and the relationship between neural tissue formation in variously aged presumptive ectoderms and the time necessary for neural induction are discussed.     

Differential cell affinity and sorting of anterior and posterior cells during outgrowth of recombinant avian limb buds

To examine the role of position-specific differences in cell-cell affinity, recombinant limb buds composed of dissociated and reaggregated cells derived from anterior (A) and posterior (P) limb bud fragments were analyzed. Dissociated anterior and/or posterior cells were differentially labeled, and their behavior was analyzed during recombinant limb bud outgrowth. We find that anterior and posterior cells sort out from one another to form alternating anterior and posterior stripes of cells that extend distally along the proximal-distal axis. These alternating stripes are prominent across the A/P axis in whole-mount preparations of recombinant limb buds after 48 h of outgrowth when the presumptive autopod is dorsal-ventrally flattened and digit rudiments are not evident. After 96 h, when digital and interdigital regions are clearly defined, we find evidence that A/P stripes do not follow obvious anatomical boundaries. The formation of A/P stripes is not inhibited by grafts of ZPA tissue, suggesting that polarizing activity does not influence cell-cell affinity early in limb outgrowth. In vitro studies provide evidence that cell sorting is not dependent on the limb bud ectoderm or the AER; however, cells sort out without organizing into stripes. Gene expression studies using anterior-specific (Alx-4) and posterior-specific (Shh, Bmp-2, and Hoxd-13) marker genes failed to reveal expression domains that corresponded to stripe formation. Control recombinant limb buds composed of anterior, central, or posterior mesenchyme formed digits in a position-specific manner. A/P recombinant limb buds that develop to later stages form digits that are characteristic of central recombinant limbs. These data provide the first definitive evidence of A/P cell sorting during limb outgrowth in vivo and suggest that differential cell affinities play a role in modulating cell behavior during distal outgrowth.     

Role of interstitial cell migration in generating position-dependent patterns of nerve cell differentiation in Hydra

The role of interstitial cell migration in the formation of newly differentiated nerve cells was examined during head regeneration in Hydra magnipapillata. When distal tissue was removed from the body of a wild-type strain (105), nerve cell differentiation occurred at a rapid rate during the first 48 hr of regeneration, slowing after this point. Rapid nerve cell differentiation was due primarily to migration of interstitial cells, some of which appeared to be nerve cell precursors, into the regenerating head. The migration decreased considerably after the first 48 hr of regeneration. In reg-16, a mutant strain deficient in head regeneration, no migration of interstitial cells and hence no new nerve cell differentiation were observed in the regenerating tip. However, the interstitial cells of reg-16 were observed to migrate into regenerating tissue of strain 105. These observations suggest that the migration of nerve cell precursors plays an important role when the new nerve net is being established during head regeneration.     

A re-examination of lens induction in chicken embryos: in vitro studies of early tissue interactions

Early studies on lens induction suggested that the optic vesicle, the precursor of the retina, was the primary inducer of the lens; however, more recent experiments with amphibians establish an important role for earlier inductive interactions between anterior neural plate and adjacent presumptive lens ectoderm in lens formation. We report here experiments assessing key inductive interactions in chicken embryos to see if features of amphibian systems are conserved in birds. We first examined the issue of specification of head ectoderm for a lens fate. A large region of head ectoderm, in addition to the presumptive lens ectoderm, is specified for a lens fate before the time of neural tube closure, well before the optic vesicle first contacts the presumptive lens ectoderm. This positive lens response was observed in cultures grown in a wide range of culture media. We also tested whether the optic vesicle can induce lenses in recombinant cultures with ectoderm and find that, at least with the ectodermal tissues we examined, it generally cannot induce a lens response. Finally, we addressed how lens potential is suppressed in non-lens head ectoderm and show an inhibitory role for head mesenchyme. This mesenchyme is infiltrated by neural crest cells in most regions of the head. Taken together, these results suggest that, as in amphibians, the optic vesicle cannot be solely responsible for lens induction in chicken embryos; other tissue interactions must send early signals required for lens specification, while inhibitory interactions from mesenchyme suppress lens-forming ability outside of the lens area.     

Clonal and molecular analysis of the prospective anterior neural boundary in the mouse embryo

In the mouse embryo the anterior ectoderm undergoes extensive growth and morphogenesis to form the forebrain and cephalic non-neural ectoderm. We traced descendants of single ectoderm cells to study cell fate choice and cell behaviour at late gastrulation. In addition, we provide a comprehensive spatiotemporal atlas of anterior gene expression at stages crucial for anterior ectoderm regionalisation and neural plate formation. Our results show that, at late gastrulation stage, expression patterns of anterior ectoderm genes overlap significantly and correlate with areas of distinct prospective fates but do not define lineages. The fate map delineates a rostral limit to forebrain contribution. However, no early subdivision of the presumptive forebrain territory can be detected. Lineage analysis at single-cell resolution revealed that precursors of the anterior neural ridge (ANR), a signalling centre involved in forebrain development and patterning, are clonally related to neural ectoderm. The prospective ANR and the forebrain neuroectoderm arise from cells scattered within the same broad area of anterior ectoderm. This study establishes that although the segregation between non-neural and neural precursors in the anterior midline ectoderm is not complete at late gastrulation stage, this tissue already harbours elements of regionalisation that prefigure the later organisation of the head.     

Patterning in hydra cell aggregates without the sorting of cells from different axial origins.

Aggregates of Hydra cells were studied to find out how the primary centers that form new heads are generated in a system of cells in which the original pattern has been destroyed. Since cells that originate near the heads (apical cells) temporarily maintain a high level of head activation potential during aggregate formation and may contribute to pattern formation, their distribution in the aggregates was investigated. The mutual distances between labeled epithelial cells were followed by vitally staining apical cells with DAPI. The distribution was random during early regeneration stages (3, 6, 24 hr). These results show that epithelial cells originating from apical regions do not sort. That is, dynamic cell movement to generate rudiments of new heads is not necessary for head formation in aggregates. A possible explanation of the mechanism is discussed.     

Transplantation stimulates interstitial cell migration in hydra

Migration of interstitial cells and nerve cell precursors was analyzed in Hydra magnipapillata and Hydra vulgaris (formerly Hydra attenuata). Axial grafts were made between [3H]thymidine-labeled donor and unlabeled host tissue. Migration of labeled cells into the unlabeled half was followed for 4 days. The results indicate that the rate of migration was initially high and then slowed on Days 2-4. Regrafting fresh donor tissue on Days 2-4 maintained high levels of migration. Thus, migration appears to be stimulated by the grafting procedure itself.     

Early tissue interactions leading to embryonic lens formation in Xenopus laevis

Our previous research has demonstrated that lens induction in Xenopus laevis requires inductive interactions prior to contact with the optic vesicle, which classically had been thought to be the major lens inductor. The importance of these early interactions has been verified by demonstrating that lens ectoderm is specified by the time it comes into contact with the optic vesicle. It has been argued that the tissues which underlie the presumptive lens ectoderm during gastrulation and neurulation, dorsolateral endoderm and mesoderm, are the primary early inductors. We show here, however, that these tissues alone cannot elicit lens formation in Xenopus ectoderm. Evidence is presented that presumptive anterior neural plate tissue (which includes the early eye rudiment) is an essential early lens inductor in Xenopus. The presence of dorsolateral mesoderm appears to enhance this response. These findings support a model in which an essential inductive signal passes through the plane of ectoderm during gastrula and early neurula stages from presumptive anterior neural tissue to the presumptive lens ectoderm. Since there is evidence for such interactions within a tissue layer in mesodermal and neural induction as well, this may be a general feature of the initial stages of determination of many tissues.     

水螅摄食中的特殊行为

取经中性红活染后的杆吻虫喂水螅,仔细观察了水螅的摄食行为.结果表明,水螅垂唇端部能够相互识别出同类;水螅的垂唇与胃区能协力把杆吻虫吞入胃腔,触手经常随食物进入胃腔;吞食时经常出现头部内翻或外翻;个体间及其成体与芽体间常出现争夺食物的现象,当垂唇端部互不相触时,体型较大的个体常常把较小个体或芽体连同食物一起吞食;垂唇内胚层腺细胞对食物有消化作用,对同类无伤害;水螅的神经系统已有初步的整合功能.     

Inductive interactions in the spatial and temporal restriction of lens-forming potential in embryonic ectoderm of Xenopus laevis

The process of lens cell determination in amphibians is currently viewed as one involving a series of inductive interactions. On the basis of previous investigations, these interactions are thought to begin during gastrulation when the presumptive foregut endoderm and then the heart mesoderm come into contact with the presumptive lens ectoderm. This earlier period of induction is followed by the later interaction of the optic vesicle with the lens-forming ectoderm. Transplantation experiments were performed to determine the relative significance of the early and later periods of induction in the process of lens cell determination in the anuran Xenopus laevis. Various ectodermal tissues were transplanted either into the lens-forming region of open neural plate stage host embryos or over the newly formed optic vesicle of later neurula stage embryos. All transplanted tissues were labeled with the intracellular marker horseradish peroxidase to assess the exact origins of any induced lens structures. The results indicate that all nonneural ectodermal tissues have some lens-forming potential early during gastrulation; however, this potential is restricted to the lens-forming region, and perhaps nearby regions, later in development during the time of neurulation. Furthermore, the results show that the optic vesicle is not a substantial inductor of the lens in tissues that have not been previously exposed to the earlier series of inductive interactions that take place during gastrulation and neurulation. Since the optic vesicle does not appear to be a sufficient inductor of the lens, these earlier inductive interactions are, therefore, essential in the process of lens cell determination in Xenopus. These earlier inductive interactions lead to a steady increase in what may be called a lens-forming bias in the presumptive lens ectoderm during this period of development. The eventual loss in the ability of nonlens ventral ectoderm to respond to these lens inductors is presumably the result of other determinative processes that occur in this tissue.     

Sonic hedgehog in the pharyngeal endoderm controls arch pattern via regulation of Fgf8 in head ectoderm

Fgf8 signalling is known to play an important role during patterning of the first pharyngeal arch, setting up the oral region of the head and then defining the rostral and proximal domains of the arch. The mechanisms that regulate the restricted expression of Fgf8 in the ectoderm of the developing first arch, however, are not well understood. It has become apparent that pharyngeal endoderm plays an important role in regulating craniofacial morphogenesis. Endoderm ablation in the developing chick embryo results in a loss of Fgf8 expression in presumptive first pharyngeal arch ectoderm. Shh is locally expressed in pharyngeal endoderm, adjacent to the Fgf8-expressing ectoderm, and is thus a candidate signal regulating ectodermal Fgf8 expression. We show that in cultured explants of presumptive first pharyngeal arch, loss of Shh signalling results in loss of Fgf8 expression, both at early stages before formation of the first arch, and during arch formation. Moreover, following removal of the endoderm, Shh protein can replace this tissue and restore Fgf8 expression. Overexpression of Shh in the non-oral ectoderm leads to an expansion of Fgf8, affecting the rostral-caudal axis of the developing first arch, and resulting in the formation of ectopic cartilage. Shh from the pharyngeal endoderm thus regulates Fgf8 in the ectoderm and the role of the endoderm in pharyngeal arch patterning may thus be indirectly mediated by the ectoderm.     

Single particle tracking of surface receptor movement during cell division

We have used fluorescent latex beads to label membrane receptors on cultured NRK cells. Movement of individual beads during cell division was recorded with digital imaging techniques. Surface-bound beads showed no organized movement during metaphase but started to migrate toward the equator approximately 1 min after anaphase onset, when chromosomes moved out of the equatorial region to create the interzone. The movement was most active in the central region of the cell near separating chromosomes, while beads located near the poles of the cell underwent primarily random motion. Most beads showed a surge in speed upon the passage of chromosomes, suggesting a possible link between chromosome separation and cortical reorganization. Furthermore, treatment of anaphase cells with cytochalasin D induced a rapid, simultaneous collapse of beads and cortical actin filaments into aggregates, indicating that the movement of beads was closely related to the reorganization of the actin cortex. In contrast to normal directional movement, cytochalasin-induced movement occurred in random directions and caused some beads in the equatorial region to move toward poles. Our results indicate that cytokinesis involves contractile activities, not only along the equator, but over a wide area of the actin-containing cortex. In addition, organized cortical activities appear to be temporally activated at anaphase onset, and spatially modulated by the spindle interzone or separating chromosomes.     

A head signal influences apical migration of interstitial cells in Hydra vulgaris

Although interstitial cells of hydra can migrate either apically or basally along the body column, there is a distinct bias toward apical cell accumulation. This apical bias could be produced by a local vectorial property of the tissue or it may be controlled by a more global property, such as a signal from the apical head region. The migration behavior of BrdU-labeled interstitial cells was examined in several types of grafts to distinguish between these two general types of migration control. Grafting BrdU-labeled midgastric region tissue into a host in either the normal or the reverse orientation had no effect on the apical bias, indicating that a local vectorial cue was probably not guiding cells apically. In grafts with heads or with feet at both ends of the body column, there was no directional bias in migration if the labeled tissue was equidistant from both ends. In the two-headed grafts, if the labeled tissue was closer to one end, there was a bias in the direction of the closer head. The results suggest that a graded signal emanating from the head creates the apical bias and may attract cells via chemotaxis. The apical bias is enhanced in decapitated animals regenerating a head, indicating that the attracting signal is present and is possibly stronger in regenerating heads. The signal for cell migration may be involved in a patterning process underlying head regeneration.     

Modulation of neural commitment by changes in target cell contacts in Pleurodeles waltl

In amphibian development, neural structures arise from the presumptive ectoderm at the gastrula stage by an inductive interaction with the chordamesoderm. It has been previously reported that early gastrula presumptive ectoderm can be neuralized when it is dissociated into single cells. A similar result is reported here with regard to Pleurodeles waltl presumptive ectoderm. Using this experimental model system we demonstrate: first, that neuronal and glial lineages can be specified from the presumptive ectoderm without any intervention of the natural inducing tissue; and second, that whereas rupture of cell-cell contacts evoked neural induction, dissociation immediately followed by reaggregation reduces the neuralizing response, pointing toward an active role played by cell-cell contacts of presumptive ectodermal cells in the modulation of neural commitment.     

The head organizer in Hydra

Organizers and organizing centers play critical roles in axis formation and patterning during the early stages of embryogenesis in many bilaterians. The presence and activity of an organizer was first described in adult Hydra about 100 years ago, and in the following decades organizer regions were identified in a number of bilaterian embryos. In an adult Hydra, the cells of the body column are constantly in the mitotic cycle resulting in continuous displacement of the tissue to the extremities where it is sloughed. In this context, the head organizer located in the hypostome is continuously active sending out signals to maintain the structure and morphology of the head, body column and foot of the animal. The molecular basis of the head organizer involves the canonical Wnt pathway, which acts in a self-renewing manner to maintain itself in the context of the tissue dynamics of Hydra. During bud formation, Hydra's mode of asexual reproduction, a head organizer based on the canonical Wnt pathway is set up to initiate and control the development of a new Hydra. As this pathway plays a central role in vertebrate embryonic organizers, its presence and activity in Hydra indicate that the molecular basis of the organizer arose early in metazoan evolution.