Survival of xenogeneic grafts of embryonic pigment and carapace rudiments in embryos of Chelydra serpentina

In a study of survival of embryonic grafts in turtles, Chelydra was used as host and Chrysemys and Amyda as donors. Somites and overlying ectoderm with or without adjacent neural tube were transplanted. The operations were unilateral and orthotopic. The involved the anterior portion of the carapace. In other experiments, bilateral neural crest and dorsal neural tube were transplanted orthotopically. In experiments with Chrysemys as donor, pigment cells formed conspicuous red areas ventrally when neural crest was included in the graft. This pigment faded gradually but persisted for three or four years. When somites and adjacent ectoderm of Chrysemys carapace were transplanted, the graft area was lightly pigmented at hatching. This pigmentation increased subsequently. The Chrysemys grafts were either accepted or partially rejected. In cases of apparent complete acceptance, the graft region took on characteristics of the host. When Amyda served as donor of carapace rudiments, the graft area retained characteristics of the donor. At hatching, dark spots on a yellow background were present and scutes were absent. A few months after hatching, the graft area became necrotic. Subsequently, scutes with host characteristics or skin covered the graft area.     

Inductive differentiation of two neural lineages reconstituted in a microculture system from Xenopus early gastrula cells.

Neural induction of ectoderm cells has been reconstituted and examined in a microculture system derived from dissociated early gastrula cells of Xenopus laevis. We have used monoclonal antibodies as specific markers to monitor cellular differentiation from three distinct ectoderm lineages in culture (N1 for CNS neurons from neural tube, Me1 for melanophores from neural crest and E3 for skin epidermal cells from epidermal lineages). CNS neurons and melanophores differentiate when deep layer cells of the ventral ectoderm (VE, prospective epidermis region; 150 cells/culture) and an appropriate region of the marginal zone (MZ, prospective mesoderm region; 5-150 cells/culture) are co-cultured, but not in cultures of either cell type on their own; VE cells cultured alone yield epidermal cells as we have previously reported. The extent of inductive neural differentiation in the co-culture system strongly depends on the origin and number of MZ cells initially added to culture wells. The potency to induce CNS neurons is highest for dorsal MZ cells and sharply decreases as more ventrally located cells are used. The same dorsoventral distribution of potency is seen in the ability of MZ cells to inhibit epidermal differentiation. In contrast, the ability of MZ cells to induce melanophores shows the reverse polarity, ventral to dorsal. These data indicate that separate developmental mechanisms are used for the induction of neural tube and neural crest lineages. Co-differentiation of CNS neurons or melanophores with epidermal cells can be obtained in a single well of co-cultures of VE cells (150) and a wide range of numbers of MZ cells (5 to 100). Further, reproducible differentiation of both neural lineages requires intimate association between cells from the two gastrula regions; virtually no differentiation is obtained when cells from the VE and MZ are separated in a culture well. These results indicate that the inducing signals from MZ cells for both neural tube and neural crest lineages affect only nearby ectoderm cells.     

Developmentally regulated lectin in dark versus white axolotl embryos

The white mutant of the Mexican axolotl, A. mexicanum, involves an ectodermal defect which prevents melanophore colonization. Endogenous lectins have been suggested to function in neural crest-derived melanophore adhesion in other animals. To determine if differences in endogenous lectins exist in dark and white axolotls during melanophore colonization, white and dark ectoderm and carcass tissues have been assayed for lectin activity at premigratory, early migratory, and late migratory neural crest stages. Lectin content (specific for D-glucosamine, N-acetyl-D-glucosamine and D-mannose) increases significantly during early migration only in dark ectoderm and white carcass tissues, whereas white ectoderm and dark carcass lectin activities remain close to premigration levels. Neural crest cells in these embryos are associated with regions of high lectin activity suggesting that the differences in endogenous lectins may be involved in establishment of the dark/white phenotype.     

Genetic and experimental studies on a new pigment mutant in Xenopus laevis.

White lethal (wl) is a recessive mutation affecting the differentiation of the three types of chromatophores in Xenopus laevis and eventually leading to the death of the mutants around stage 50. Melanophores appear at st. 33 but differentiate abnormally, remaining pale grey, and do not proliferate after st. 41. The rare xanthophores present contain only a few differentiated pterinosomes, and the iridophores consist of noniridescent white dots. When the albino gene (ap) is combined with wl, melanophores do not differentiate. Reciprocal heterotopic and orthotopic trunk neural crest grafts have shown that the defect is intrinsic to the neural crest cells but is not due, in the case of melanophores, to a tyrosinase deficiency as revealed by the dopa reaction. The mode of action of the gene, the abnormal pattern, and lethality are discussed.     

Effects of fetal bovine serum and serum-free conditions on white and dark axolotl neural crest explants

Summary Neural crest cells from both white mutant and dark (wildtype) axolotls (Ambystoma mexicanum) were cultured in increasing concentrations of fetal bovine serum (FBS; 2 to 20%). For each explant, the total number of cells that migrated and the percent of differentiated melanophores were recorded. At concentrations of FBS above 2% melanophore differentiation was essentially equivalent (32 to 59%) for both the white and dark neural crest cultures, but subtle differences in cell behavior and differentiation were found between the two phenotypes. By contrast there was a significant difference in the percent melanization of cells in serum-free control cultures, wherein melanophore differentiation in dark neural crest cultures was, on average, 18% compared to 5% in white cultures. Thus, contrary to all previously published work, white and dark neural crest cells are not intrinsically equivalent. Our culture results are discussed with regard to the probable in vivo conditions that cause the white phenotype. This research was supported by grant AR 34478 from the National Institutes of Health, Bethesda, MD, and a University of Kansas Biomedical Science support grant.     

Mechanisms of Melanophore Induction in Amphibian Development

Induction of melanophores was examined by the sandwich method of explantation with embryonic tissues of Xenopus laevis +/+ and the white mutant, a^P/a^P. Interspecific combinations of tissues of Triturus taeniatus and Xenopus borealis were also used. The ectoderm used as the reacting system was taken from embriyos at various stages and combined with various tissues known to be melanogenic inductors. The following results were obtained: 1) The sources of melanophore induction in both +/+ and a^p/a^p studied by sandwich explantation were the same in both retinal pigmented epithelium and dermal melanophores: 2) Melanophores were induced in epidermal material from embryos at stages from the early gastrula to the late tail bud stage: 3) The presence of melanoblasts together with other ectomesenchymal cells in the neural crest is not sine qua non for their determination and differentiation: 4) On isolation of reacting material from the late gastrula, melanophores appeared in all cases. This shows that two hours contact between inductor tissues and the ectoderm is necessary and sufficient for melanophore induction: 5) Melanophore induction is not species-specific, but occurred in Xenopus ectoderm under the action of endomesoderm of Tr. taeniatus or X. borealis , and vice versa. The shapes and structures of melanophores induced were typical for the species from which the ectoderm was taken: 6) Melanogenic activity in the late gastrula stage has a gradient of distribution with a maximum in the prechordal plate: 7) In the mutant only the primary source of melanogenic inductors, the prechordal plate (PrP1), was active in stages both before and after its invagination: 8) Despite the fact that skin melanophores and retinal melanocytes have different genesis in development, all the present data suggest the identity of the mechanisms of melanin synthesizing machinery in the two.     

Neural fold and neural crest movement in the Mexican salamander Ambystoma mexicanum

In studies of amphibian neurulation, the terms "neural ridge," "neural fold," and "neural crest" are sometimes used as synonyms. This has occasionally led to the misconception that grafting of the neural crest is equivalent to grafting of the neural fold. The neural fold, however, is composed of three parts: the neural crest, prospective neural tube tissue, and epidermis. In order to investigate how these neural fold components move during neurulation, time-lapse photography, electron microscopy, and grafting were performed. Ambystoma mexicanum embryos were photographed during neurulation at regular intervals. The photographs were analyzed to find the position of those cells at beginning of neurulation that end up on the line of fusion as the neural folds close. Posteriorly, these cells are already on the emerging neural fold. In the anterior neural folds, however, these cells are located in the lateral epidermis. Electron microscopy of the neural folds confirms the presence of epidermis. To follow the movement of the cells differentiating into melanophores (neural crest), neural fold parts were grafted into albino hosts. The crest cells differentiating into melanophores following ectopic grafting are located in the flank of the neural fold that is in contact with the neural plate. In grafts from the outside (distal) flank, no melanophores developed. Semithin sections show that the third part of the neural fold consists of apically constricted cells known to differentiate into neural tissue. Because the neural folds consist of epidermis, neural tissue, and neural crest, neural fold and neural crest cannot be used as synonyms.     

Inhibition of neural crest cell differentiation by embryo ectodermal extract.

The white mutation in Mexican axolotls has long been thought to be a defect associated with the embryonic extracellular environment, but not with embryonic neural crest cells. Thus it was believed that pigment cells in white axolotls disappear from the skin during early development, not because they are intrinsically defective but because they have no choice but to move into an unfavorable environment. We present evidence to suggest that: (1) white neural crest cells are in fact intrinsically different from dark (wild-type) cells, and (2) an inhibitor is produced in white embryonic ectoderm that actively suppresses the migration, differentiation, and survival of pigment cells in this animal. How these observations fit into the existing body of literature on the white mutant and a model for how the white phenotype might develop are discussed.     

Neural crest cell behavior in white and dark embryos of Ambystoma mexicanum: Epidermal inhibition of pigment cell migration in the white axolotl

Melanophores in larvae of the white (dd) strain of the Mexican axolotl (Ambystoma mexicanum) are confined to the dorsal midline of the trunk and dorsal posterior part of the head, whereas those in dark larvae (D_-) are distributed over the flank as well. Our results show that this phenotype of white larvae is the result of the failure of the melanophores or their neural crest precursor cells to migrate laterally due to an inhibition of or a failure in the support of their migration in the subepidermal space by the overlying epidermis. Correlated light and scanning electron microscopy of dissected larvae showed melanophores occupying the subepidermal space on the flank of dark larvae, whereas these cells were restricted to the dorsal midline of white larvae. Grafting experiments in which patches of epidermis, the underlying mesoderm, or both, were exchanged between dark and white embryos suggested that white epidermis alone can prevent the integration of pigment cells on the flank of dark larvae and, conversely, that grafts of dark epidermis alone can support their migration on the flank of white larvae. Mesoderm, when grafted alone, could not be shown to have similar effects.     

Rohon-Beard sensory neurons are induced by BMP4 expressing non-neural ectoderm in Xenopus laevis

Rohon-Beard mechanosensory neurons (RBs), neural crest cells, and neurogenic placodes arise at the border of the neural- and non-neural ectoderm during anamniote vertebrate development. Neural crest cells require BMP expressing non-neural ectoderm for their induction. To determine if epidermal ectoderm-derived BMP signaling is also involved in the induction of RB sensory neurons, the medial region of the neural plate from donor Xenopus laevis embryos was transplanted into the non-neural ventral ectoderm of host embryos at the same developmental stage. The neural plate border and RBs were induced at the transplant sites, as shown by expression of Xblimp1, and XHox11L2 and XN-tubulin, respectively. Transplantation studies between pigmented donors and albino hosts showed that neurons are induced both in donor neural and host epidermal tissue. Because an intermediate level of BMP4 signaling is required to induce neural plate border fates, we directly tested BMP4′s ability to induce RBs; beads soaked in either 1 or 10 ng/ml were able to induce RBs in cultured neural plate tissue. Conversely, RBs fail to form when neural plate tissue from embryos with decreased BMP activity, either from injection of noggin or a dominant negative BMP receptor, was transplanted into the non-neural ectoderm of un-manipulated hosts. We conclude that contact between neural and non-neural ectoderm is capable of inducing RBs, that BMP4 can induce RB markers, and that BMP activity is required for induction of ectopic RB sensory neurons.     

The migratory pathway of neural crest cells into the skin of mouse embryos

The migration of neural crest derived melanoblasts into the skin of mice was studied by the ectoderm-mesoderm recombination technique. Dorsolateral skin from albino and black mouse embryos at the time of initial melanoblast invasion was separated into ectoderm and mesoderm components, recombined with each other, and grown in the chick embryo coelom for a sufficient period to allow melanin formation. Recombined skin from embryos 11 days old formed pigment only when the mesodermal component was from a genetically black embryo. The black ectoderm-albino mesoderm recombinations failed to produce pigment in all cases. At this critical age when melanoblasts were first entering the skin, they were present exclusively in the mesodermal component. Skin recombinations made from 12-day mouse embryos showed a spread of melanoblasts into the ectodermal component, and by 13 and 14 days both dermal mesoderm and epidermal ectoderm were populated by melanoblasts.     

Grafting analysis of the periodic albino mutant of Xenopus laevis

The differentiation of normal and mutant (a^P/a^P) Xenopus laevis melanophores in chimerae was analyzed to determine the tissues affected by this mutation. Normal melanophores in mutant host tissue differentiate in mutant host tissue prior to those of the mutant host. These normal melanophores were initially normal in appearance, but, after the differentiation of the mutant host's melanophores, they became indistinguishable from their host's melanophores. These normal melanophores persist in more than normally punctate form after the disappearance of the mutant host's melanophores in late larval life. Parabiosis and head transplants between mutant and normal embryos did not affect the character of either type of melanophore developing in tissue of its own genotype, indicating that the hormonal control of melanophore differentiation is not affected by the mutation. Therefore, the periodic albino mutant affects the capacity of the mutant melanophore to differentiate and the ability of the mutant skin to support normal melanophore differentiation.     

Lateral line placodes are induced during neurulation in the axolotl

In order to determine the time window for induction of lateral line placodes in the axolotl, we performed two series of heterotopic and isochronic transplantations from pigmented to albino embryos at different stages of embryogenesis and assessed the distribution of pigmented neuromasts in the hosts at later stages. First, ectoderm from the prospective placodal region was transplanted to the belly between early neurula and mid tailbud stages (stages 13-27). Whereas grafts from early neurulae typically differentiated only into epidermis, grafts from late neural fold stages on reliably resulted in differentiation of ectopic pigmented neuromasts. Second, belly ectoderm was transplanted to the prospective placodal region between early neurula and tailbud stages (stages 13-35). Normal lateral lines containing pigmented neuromasts formed in most embryos when grafts were performed prior to early tailbud stages (stage 24) but not when they were performed later. Our findings indicate that lateral line placodes, from which neuromasts originate, are already determined at late neural fold stages (first series of grafts) but are inducible until early tailbud stages (second series of grafts). A further series of heterochronic transplantations demonstrated that the decline of inducibility at mid tailbud stages is mainly due to the loss of ectodermal competence.     

A developmental study of murine epidermal Langerhans cells

Prospective skin prior to invasion by neural crest cells was dissected from 10.5-day mouse embryos and cultivated in chick embryo hosts. The graft tissue was prepared for the demonstration of both mouse and chick cells, pigment cells, and Langerhans cells. Chick cells were not found in the graft mouse epidermis; however, ATPase-positive and osmium iodide-positive cells were present. Electron microscopic examination revealed that, in younger grafts, only indeterminate cells could be found among the keratinocytes. In older grafts, both indeterminate cells and Langerhans cells with granules were seen. The evidence affirms that epidermal Langerhans cells are not related to pigment cells.Based on the developmental nature of Birbeck (Langerhans) granules from the cytomembrane, it is proposed that the granule no longer be considered as specific to and characteristic of epidermal Langerhans cells. Rather, Langerhans cells should be defined as ATPase-positive, desmosome-free cells within stratified squamous, potentially keratinizing, epithelia. Thus epidermal, ATPase-positive indeterminate cells and such cells with Birbeck granules both should be considered as components of the Langerhans cell series.Normal chick skin does not show ATPase-positive cells. However, when 10.5-day mouse embryo ectoderm was inserted under the ectoderm of chick embryos, the resulting chimeric epidermis possessed ATPase-positive cells. It is proposed that epidermal Langerhans cells are of ectodermal origin.     

Structural and compositional divergencies in the extracellular matrix encountered by neural crest cells in the white mutant axolotl embryo

The skin of the white mutant axolotl larva is pigmented differently from that of the normal dark due to a local inability of the extracellular matrix (ECM) to support subepidermal migration of neural crest-derived pigment cell precursors. In the present study, we have compared the ECM of neural crest migratory pathways of normal dark and white mutant embryos ultrastructurally, immunohistochemically and biochemically to disclose differences in their structure/composition that could be responsible for the restriction of subepidermal neural crest cell migration in the white mutant axolotl. When examined by electron microscopy, in conjunction with computerized image analysis, the structural assembly of interstitial and basement membrane ECMs of the two embryos was found to be largely comparable. At stages of initial neural crest cell migration, however, fixation of the subepidermal ECM in situ with either Karnovsky-ruthenium red or with periodate-lysine-paraformaldehyde followed by ruthenium red-containing fixatives, revealed that fibrils of the dark matrix were significantly more abundant in associated electron-dense granules. This ultrastructural discrepancy of the white axolotl ECM was specific for the subepidermal region and suggested an abnormal proteoglycan distribution. Dark and white matrices of the medioventral migratory route of neural crest cells had a comparable appearance but differed from the corresponding subepidermal ECMs. Immunohistochemistry revealed only minor differences in the distribution of fibronectin, laminin, collagen types I, and IV, whereas collagen type III appeared differentially distributed in the two embryos. Chondroitin- and chondroitin-6-sulfate-rich proteoglycans were more prevalent in the white mutant embryo than in the dark, especially in the subepidermal space. Membrane microcarriers were utilized to explant site-specifically native ECM for biochemical analysis. Two-dimensional gel electrophoresis of these regional matrices revealed a number of differences in their protein content, principally in constituents of apparent molecular masses of 30-90,000. Taken together our observations suggest that local divergences in the concentration/assembly of low and high molecular mass proteins and proteoglycans of the ECM encountered by the moving neural crest cells account for their disparate migratory behavior in the white mutant axolotl.     

A critical period for conversion of ectodermal cells to a neural crest fate

Previously, we found that interactions between neural and nonneural ectoderm can generate neural crest cells, with both the ectodermal and the neuroepithelial cells contributing to induced population (M. A. J. Selleck and M. Bronner-Fraser, 1995, Development 121, 525-538). To further characterize the ability of ectodermal cells to form neural crest, we have challenged their normal fate by transplanting them into the neural tube. To ensure that the ectoderm was from nonneural regions, we utilized extraembryonic ectoderm (the proamnion) and transplanted it into the presumptive midbrain of 1. 5-day-old chick embryos. We observed that the grafted ectoderm has the capacity to adopt a neural crest fate, responding within a few hours of surgery by turning on neural crest markers HNK-1 and Slug. However, the competence of the ectoderm to respond to neural crest-inducing signals is time limited, declining rapidly in donors older than the 10-somite stage. Similarly, the inductive capacity of the host midbrain declines in a time-dependent fashion. Our results show that extraembryonic ectoderm has the capacity to form neural crest cells given proper inducing signals, expressing both morphological and molecular markers characteristic of neural crest cells.     

Gonadal morphogenesis and sex differentiation in the viviparous fish Chapalichthys encaustus (Teleostei, Cyprinodontiformes, Goodeidae)

This study describes the structural and ultrastructural characteristics of gonadal sex differentiation and expression of Vasa, a germline marker, in different developmental stages of embryos and newborn fry of the barred splitfin Chapalichthys encaustus, a viviparous freshwater teleost endemic to Mexico. In stage 2 embryos, the gonadal crest was established; gonadal primordia were located on the coelomic epithelium, formed by scarce germ and somatic cells. At stage 3, the undifferentiated gonad appeared suspended from the mesentery of the developing swimbladder and contained a larger number of germ and somatic cells. At stages 4 and 5, the gonads had groups of meiotic and non-meiotic germ cells surrounded by somatic cells; meiosis was evident from the presence of synaptonemal complexes. These stages constituted a transition towards differentiation. At stage 6 and at birth, the gonad was morphologically differentiated into an ovary or a testis. Ovarian differentiation was revealed by the presence of follicles containing meiotic oocytes, and testicular differentiation by the development of testicular lobules containing spermatogonia in mitotic arrest, surrounded by Sertoli cells. Nuage, electron-dense material associated with mitochondria, was observed in germ cells at all gonadal stages. The Vasa protein was detected in all of the previously described stages within the germ-cell cytoplasm. This is the first report on morphological characteristics and expression of the Vasa gene during sexual differentiation in viviparous species of the Goodeidae family. Chapalichthys encaustus may serve as a model to study processes of sexual differentiation in viviparous fishes and teleosts.     

Studies on cellular adhesion of Xenopus laevis melanophores: modulation of cell-cell and cell-substratum adhesion in vitro by endogenous Xenopus galactoside-binding lectin

We have investigated cell-cell and cell-substratum adhesion of Xenopus laevis neural crest cells at various stages of melanophore differentiation. Single-cell suspensions were obtained by trypsinization and aggregated in a cell-cell adhesion assay. Unpigmented cells did not adhere while the rate of adhesion of melanophores correlated with the degree of melanization. Melanophore cell-cell adhesion decreased significantly in the presence of beta-galactosidase, which suggests that cell-surface galactose is involved. Beta-galactoside-binding lectin has been isolated and purified from embryos at the stage of neural crest migration. When added to aggregating cells smaller, looser clusters formed compared to controls. When lectin was added to cells in stationary culture to test cell-substratum adhesion, melanophores spread more smoothly and formed more regular spacing patterns. These results suggest that this lectin can modulate receptors used in cell-cell and cell-substratum adhesion of melanophores.     

Neural crest development in the Xenopus laevis embryo, studied by interspecific transplantation and scanning electron microscopy

The Xenopus borealis quinacrine marker and scanning electron microscopy have been used to study the appearance, migration, and homing of neural crest cells in the embryo of Xenopus. The analysis shows that the primordium of the neural crest develops from the nervous layer of the ectoderm and consists of three segments at early neurula stages. This primordium is located in the lateral halves of the neural folds behind the prospective eye vesicles. The histological and experimental evidence shows that the neural crest cells also originate from the medial portion of the neural folds. The neural crest segments in the cephalic region start to migrate just before the closure of the neural tube. Isotopic and isochronic unilateral grafts of X. borealis neural crest into X. laevis embryos were performed in order to map the fate of the cranial crest segments and the vagal-truncal neural crest. The analysis of the X. laevis host embryos shows that the mandibular crest segment contributes to the lower jaw (Meckel's cartilage), quadrate, and ethmoid-trabecular cartilages, as well as to the ganglionic and Schwann cells of the trigeminus nerve, the connective tissues, the mesenchymal and choroid layers of the eye, and the cornea. The hyoid crest segment is located in the ceratohyal cartilage and in ganglia VII and VIII. The branchial crest segment migrates from the caudal part of the otic vesicle and divides into two portions which contribute to the cartilages of the gills. The vagal-truncal neural crest starts to migrate later at stage 25. It migrates by means of the vagus complex in a ventral direction and penetrates into the splanchnic layer of the digestive tract. The trunk neural crest cells disperse into three different pathways which differ from those of the avian embryo at this level.