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

Immunoglobulin superfamily receptor Junctional adhesion molecule 3 (Jam3) requirement for melanophore survival and patterning during formation of zebrafish stripes

Adhesive interactions are essential for tissue patterning and morphogenesis yet difficult to study owing to functional redundancies across genes and gene families. A useful system in which to dissect roles for cell adhesion and adhesion-dependent signaling is the pattern formed by pigment cells in skin of adult zebrafish, in which stripes represent the arrangement of neural crest derived melanophores, cells homologous to melanocytes. In a forward genetic screen for adult pattern defects, we isolated the pissarro (psr) mutant, having a variegated phenotype of spots, as well as defects in adult fin and lens. We show that psr corresponds to junctional adhesion protein 3b (jam3b) encoding a zebrafish orthologue of the two immunoglobulin-like domain receptor JAM3 (JAM-C), known for roles in adhesion and signaling in other developing tissues, and for promoting metastatic behavior of human and murine melanoma cells. We found that zebrafish jam3b is expressed post-embryonically in a variety of cells including melanophores, and that jam3b mutants have defects in melanophore survival. Jam3b supported aggregation of cells in vitro and was required autonomously by melanophores for an adherent phenotype in vivo. Genetic analyses further indicated both overlapping and non-overlapping functions with the related receptor, Immunoglobulin superfamily 11 (Igsf11) and Kit receptor tyrosine kinase. These findings suggest a model for Jam3b function in zebrafish melanophores and hint at the complexity of adhesive interactions underlying pattern formation.

The different effects on cranial and trunk neural crest cell behaviour following exposure to a low concentration of alcohol in vitro

Embryonic neural crest cells give rise to large regions of the face and peripheral nervous system. Exposure of these cells to high alcohol concentrations leads to cell death in the craniofacial region resulting in facial defects. However, the effects of low concentrations of alcohol on neural crest cells are not clear. In this study, cranial neural crest cells from Xenopus laevis were cultured in an ethanol concentration approximately equivalent to one drink. Techniques were developed to study various aspects of neural crest cell behaviour and a number of cellular parameters were quantified. In the presence of alcohol, a significant number of cranial neural crest cells emigrated from the explant on fibronectin but the liberation of individual cells was delayed. The cells also remained close to the explant and their morphology changed. Cranial neural crest cells did not grow on Type 1 collagen. For the purposes of comparison, the behaviour of trunk neural crest cells was also studied. The presence of alcohol correlated with increased retention of single cells on fibronectin but left other parameters unchanged. The behaviour of trunk neural crest cells growing on Type 1 collagen in the presence of alcohol did not differ from controls. Low concentrations of alcohol therefore significantly affected both cranial and trunk neural crest cells, with a wider variety of effects on cells from the cranial as opposed to the trunk region. The results suggest that low concentrations of alcohol may be more detrimental to early events in organ formation than currently suspected.

Confrontation of developing melanophore bars of dark and white axolotls with endogenous dark-embryo mannose-binding lectin correlates with melanophore bar disruption

Lectins are carbohydrate-binding proteins suggested to be important in embryonic cell adhesion/differentiation. Dark and white axolotls contain an endogenous mannose-binding lectin that is especially prevalent during larval melanophore pattern formation (Martha et al., 1990). To determine if this lectin can alter melanophore patterning, lectin extracts have been isolated from Dark embryos by affinity chromatography. The main protein band is 44K on SDS-PAGE. Dark and white embryos at the early chromatophore migration stage have been confronted with Dark lectin or its nonmetabolized inhibitor, 2-deoxyglucose (2-DG). The barred melanophore pattern of both genotypes is disrupted by lectin or 2-DG treatment suggesting that endogenous mannose-binding lectin and its receptor participate in bar formation.

Probing the functions of endogenous lectins: effects of a monoclonal antibody against the neural crest-stage lectin of Xenopus laevis on trunk development

Trunk neural crest of Xenopus laevis has been confronted prior to migration with whole or fragments of a monoclonal antibody raised against the carbohydrate-binding site of the endogenous neural crest-stage galactoside binding lectin (Milos et al.: Anat. Embryol., 182:319-327 '90). External fin formation was inhibited in confronted regions but extensive internal matrix develops suggesting interiorization of fin tissue. In the regions of missing fin, the myotomes overgrew the neural tube and dorsal root ganglion neuronal numbers became more variable. Melanophore numbers in regions of missing fin did not change but a significantly greater proportion of the pigment cells localized on the muscle surface that had overgrown the neural tube suggesting that the pigment cell population redistributed itself to occupy a greater myotomal area.

Changing complexity of endogenous lectin activities during juvenile development of Xenopus laevis

Galactoside-binding lectin has been isolated from whole Xenopus laevis embryos and tadpoles at four development stages: st. 24-26, 32, 41 and 47. The main lectin activity at st. 24-26 is β-galactoside specific, producing a 34/35.5K doublet on SDS-PAGE. Later in development, lectin activities specific for a wide range of other sugars appear concommitant with the detection of a number of new protein bands on SDS-PAGE gels. The greatest variety of new lectin activities exists at st. 32 when lectins specific for all of the main sugar families found in nature are detected. After this stage and up to st. 47 (the beginning of metamorphosis), fewer different lectin activities are again detected. The results suggest that a complex, developmentally regulated battery of different lectins are present during early Xenopus development, perhaps with stage-specific roles to play in the control of tissue morphogenesis.

Localization of endogenous galactoside-binding lectin during morphogenesis of Xenopus laevis

A monoclonal antibody has been produced against Xenopus laevis galactoside-binding neural-crest-stage lectin. This antibody inhibits lectin-mediated hemagglutination. Using this antibody in conjunction with immunohistochemical techniques, lectin deposition has been studied in embryos and tadpoles at different stages of morphogenesis, from initial neural crest migration, up to the formation of a swimming tadpole. Lectin levels change during development in different regions of the embryo and tadpole, decreasing in migratory cells, and increasing in sites where cells become more adhesive to one another. The results suggest that galactoside-binding lectins may be an important class of cellular adhesion molecules during these stages of development.

Studies on cellular adhesion of Xenopus laevis melanophores: pigment pattern formation and alteration in vivo by endogenous galactoside-binding lectin or its sugar hapten inhibitor

We have studied the development of Xenopus laevis tail melanophores and the effects on these cells on confrontation with endogenous X. laevis galactoside-binding lectin or its sugar hapten inhibitor thiodigalactoside (TDG). An initial population of unpigmented cells differentiates into melanophores on the dorsal surface of the neural tube, and on the dorsal and ventral apices of the myotomes, forming the larval pattern. Melanophores secondarily populate the flank, forming a spaced arrangement which is later transformed into a dorsal and ventral strip. A technique has been developed for confrontation of premigratory neural crest with purified lectin or TDG. These molecules impact on tail melanophores. With lectin treatment melanophore numbers decrease, and cell morphologies and arrangements change. TDG treatment, however, primarily affects pigment cell morphology. These results suggest that both galactoside-bearing receptors for this lectin and the lectin itself can affect melanophores in this species of frog.

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.