Patterns of migration and regulation of trunk neural crest cells in zebrafish (Danio rerio).

Regulation is the replacement of lost, undifferentiated embryonic cells by neighboring cells in response to environmental signals. Neural crest cells, embryonic cells unique to craniates, are good candidates for studies of regulation because they are pluripotent, and thus might be able to alter their behavior in response to environmental signals. This study investigated regulation for the loss of trunk neural crest (TNC) cells, specifically pigment derivatives, in the zebrafish, Danio rerio. The first part of the study clarifies and extends what has previously been described on normal patterns of TNC migration and differentiation. These data were then used to address the hypothesis that there is regulation for loss of TNC, and that regulation would vary with the amount removed, the position or stage of removal. Zebrafish TNC cells are large and numerous. SEM and Dil labeling revealed that TNC cells undergo several successive waves of 'sheet' and 'segmental' migration, beginning as early as the 12 somite stage. Dil-labeled TNC cells often migrated several somite lengths anteriorly and posteriorly along the trunk axis to form glial cells, ganglia, pigment, ectomesenchyme and tail reticular cells. Regulation occurred on a sliding scale, ranging from complete to incomplete. Defects in development and/or pigmentation occurred if large regions of TNC cells were removed, or if cells were removed from anterior (cardiac) and posterior (tail) extremities of the trunk. Melanophores were the cell type most visibly affected by TNC extirpations. Otherwise, pigmentation was remarkably normal. We propose that the completeness of regulation largely depends upon healing of the overlying epidermis.

Development of dermal denticles in skates (Chondrichthyes, Batoidea): patterning and cellular differentiation.

Patterning, cellular differentiation, and developmental sequences of dermal denticles (denticles) are described for the skate Leucoraja erinacea. Development of denticles proceeds caudo-rostrally in the tail and trunk. Once three rows of denticles form in the tail and trunk, denticles begin to appear in the region of the pelvic girdle, medio-caudal to the eyes and on the pectoral fins. Although timing of cellular differentiation of denticles differs among different locations of the body, cellular development of a denticle is identical in all locations. Thickening of the epidermis as a denticle lamina marks initiation of development. A single lamina for each denticle forms, and a small group of mesenchymal cells aggregates underneath it. The lamina then invaginates caudo-rostrally to form the inner- and outer-denticle epithelia (IDE and ODE, respectively). Before nuclei of IDE cells are polarized, enameloid matrix appears between the basement membrane of the IDE and the apical surface of the pre-odontoblasts. Pre-dentin is then laid down along with collagenous materials. Von Kossa stain visualizes initial mineralization of dentin, but not enameloid. During the growth of a denticle, dense fibrous connective tissue of the dermis forms the deep dermal tissue over the dorsal musculature. Attachment fibers and tendons anchor denticles and dorsal musculature, respectively, on deep dermal tissue. Basal tissue of the denticles develops as the denticle crown grows. If the basal tissue is bone of attachment, then the cells along the basal tissue would be osteoblasts. However, these cells could not be distinguished from odontoblasts using immunolocalization of type I pro-collagen (Col I), alkaline phosphatase (APase), and neural cell adhesion molecule (N-CAM). Well-developed dentin, (not pre-dentin), the enameloid matrix (probably when it begins to mineralize), and deep dermal tissue are Verhoeff stain-positive, suggesting that these tissues contain elastin and/or elastin-like molecules. Our study demonstrates that the cellular development of denticles resembles tooth development in elasmobranchs, but that dermal denticles differ from teeth in forming from a single denticle lamina. Whether the basal tissue of denticles is bone of attachment remains undetermined. Confirmation and function of Verhoeff-positive proteins in enameloid, dentin, and deep dermal tissue remain to be determined. We discuss these issues along with an analysis of recent findings of enamel and enameloid matrices.

Regulation of neural crest cell populations: occurrence, distribution and underlying mechanisms.

Regulation is a significant developmental event because successful cell proliferation and migration are critical to shaping young embryos. Regulation -- the replacement of undifferentiated embryonic cells by other cells in response to signals received from the environment -- is distinct from wound healing and regeneration. Investigations on regulation of neural crest cells span all vertebrates and have revealed that regulative ability varies both among classes (even species), and spatially and temporally within individuals. In general, there is greatest regulation for cranial neural crest cells, less for trunk, and virtually none forcardiac. Regulation also appears to be more complete at early embryonic stages. Fate-mapping studies have demonstrated that large regions of neural crest cells must be removed to generate missing or morphologically reduced structures. Recent studies reveal that less extensive neural crest cell extirpations result in normal morphology of cartilaginous and neuronal elements in the head, and normal development of pigmentation in the trunk. Ablation of cardiac neural crest cells frequently generates abnormalities of the heart, great vessels and parasympathetic nerve innervation. Decreased cell death, increased division, change in fate and altered migration are possible cellular mechanisms of regulation. In mostcases, the specific mechanisms of regulation are unknown, but a major premise underlying regulation is that cell potential is greater than cell fate. This concept was born from studies which demonstrated that some cells were able to express alternative fates if transplanted to a new environment. Among the potential cellular mechanisms for regulation, cell migration has received the most attention. Following ablation of neural crest cells, replacement neural crest cells migrate into gaps, most frequently from anterior/posterior locations. Cells from surrounding epidermal and neural ectoderm may have limited regulative ability, while compensation by cells from the ventral neural tube has been demonstrated to an even lesser extent. Regulation by such non-crest cells would require their transformation into neural crest cells. The potential for regulation of neural crest by placodal cells supports a closer relationship between neural crest and placodal ectoderm than previously recognized. Decreased cell death has been discussed primarily with reference to (1) cranial ganglia that have dual contributions from neural crest and placodal cells and (2) programmed cell death in rhombomeres three and five. Increased cell division in response to neural crest ablation is likely more common than has been reported, but this mechanism is difficult to interpret without a 3-D context for viewing how patterns of division differ from normal. Lastly, changes in cell fate may be the driving factor in regulation of embryonic cells. It has been repeatedly demonstrated thatcell potential is greaterthan cell fate. Once reliable mechanisms for assessing cell potential are established, we may find that fates are commonly altered in response to environmental signals. Regulation is therefore significant both as a basic developmental mechanism and as a mechanism for evolutionary change. The more labile the fate of embryonic cells, the more potential there is for maintaining existing characters and for generating new ones. According to Ettensohn (1992, p. 50), further analysis of such systems might <>. With regard to the neural crest, studies on regulation of this vital population of cells provide insight to the origin of the neural crest, to embryonic repair, and to the source of many craniofacial malformations, heart and other embryonic defects. (ABSTRACT TRUNCATED)