Significance of cell-to-cell contacts for the directional movement of neural crest cells within a hydrated collagen lattice

Development ◽  
1981 ◽  
Vol 63 (1) ◽  
pp. 29-51
Author(s):  
Edward M. Davis ◽  
J. P. Trinkaus
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Average Rate ◽  
Single Cells ◽  
Neural Crest Cells ◽  
Time Lapse ◽  
Contact Inhibition ◽  
Neural Tubes ◽  
Directional Movement ◽  
Contact Behaviour

Neural tubes whose neural crest had just begun migration were isolated from stage-14 chick embryos, cleaned with 0·1 % trypsin, and cultured in transparent hydrated collagen lattices (HCL) in an effort to stimulate in part the three-dimensional environment through which neural crest cells migrate in situ, in the embryo. The concentration of collagen in the lattices varied from 50µg/ml to 390µg/ml. The mode of movement and contact behaviour of neural crest cells migrating from the neural tube under these conditions were recorded directly with time-lapse cinemicrography. Both their shape and their rate of translocation were dependent on the concentration of collagen in the HCL. In low concentrations (50 µg/ ml to 105 µg/ml), neural crest cells have elongate spindle shapes and translocate at an average rate of 1 µm/min, whereas in high concentrations (190µg/ml to 390µg/ml), their shape is rounded, and they translocate at an average rate of only 0·5µm/min. Neural crest cells migrate from neural tubes in these preparations principally in loose clusters, with a few single cells in the lead. The cells in these groups display leading-to-trailing edge adhesions and form tongues or streams of cells directed away from the neural tube. The paths of migration of both individual cells and groups of cells are aligned with the collagen fibrils of the HCL, which radiate from the neural tube. The classical visible characteristic of contact inhibition of movement, change in direction of cell movement after contact with other! cells, was not observed; neither the rate of translocation nor the time spent migrating away from the tube is dependent on the number of contacts between cells. It is concluded that the directional movement of neural crest cells in HCL cultures does not depend on contact inhibition of movement.

Translocation of neural crest cells within a hydrated collagen lattice

Development ◽  
1980 ◽  
Vol 55 (1) ◽  
pp. 17-31
Author(s):  
Edward M. Davis
Keyword(s):  
Neural Crest ◽  
Growth Medium ◽  
Neural Tube ◽  
Average Rate ◽  
Neural Crest Cells ◽  
Time Lapse ◽  
Culture Conditions ◽  
Serum Free ◽  
Neural Tubes ◽  
Collagen Lattice

Chick neural tubes were cultured either on planar substrata of collagen-coated Falcon plastic in growth medium with serum or within a hydrated collagen lattice (HCL) in growth medium either with or without serum. Using time-lapse cinemicrography, neural crest cells were observed emigrating from neural tubes over the collagen substrata. Once separated from the neural tube, they seldom reunite with it. Though the average rate at which the neural crest cells translocate was the same in the different culture conditions, approximately l·0 μm/min, distinct differences in morphology and mode of translocation were observed. Neural crest cells on collagen-coated culture dishes have a flattened fibroblastic morphology and mode of translocation; in an HC1 with serum, they have a bipolar shape and translocate by advancing a long, narrow leading protrusion and by periodically retracting the attenuated trailing portion of the cell; and in a serum-free HCL, they have a unipolar shape and translocate by advancing a long, narrow, branched leading protrusion and by periodically transferring the cytoplasm of the large, rounded trailing cell body forward, past a bulbous structure, and into the leading protrusion.

scholarly journals Vital dye labelling of Xenopus laevis trunk neural crest reveals multipotency and novel pathways of migration

Development ◽  
1993 ◽  
Vol 118 (2) ◽  
pp. 363-376 ◽  
Author(s):  
A. Collazo ◽  
M. Bronner-Fraser ◽  
S.E. Fraser
Keyword(s):  
Xenopus Laevis ◽  
Neural Crest ◽  
Neural Tube ◽  
Single Cells ◽  
Neural Crest Cell ◽  
Neural Crest Cells ◽  
Pigment Cells ◽  
Spinal Ganglia ◽  
Posterior Portion ◽  
Precise Position

Although the Xenopus embryo has served as an important model system for both molecular and cellular studies of vertebrate development, comparatively little is known about its neural crest. Here, we take advantage of the ease of manipulation and relative transparency of Xenopus laevis embryos to follow neural crest cell migration and differentiation in living embryos. We use two techniques to study the lineage and migratory patterns of frog neural crest cells: (1) injections of DiI or lysinated rhodamine dextran (LRD) into small populations of neural crest cells to follow movement and (2) injections of LRD into single cells to follow cell lineage. By using non-invasive approaches that allow observations in living embryos and control of the time and position of labelling, we have been able to expand upon the results of previous grafting experiments. Migration and differentiation of the labelled cells were observed over time in individual living embryos, and later in sections to determine precise position and morphology. Derivatives populated by the neural crest are the fins, pigment stripes, spinal ganglia, adrenal medulla, pronephric duct, enteric nuclei and the posterior portion of the dorsal aorta. In the rostral to mid-trunk levels, most neural crest cells migrate along two paths: a dorsal pathway into the fin, followed by presumptive fin cells, and a ventral pathway along the neural tube and notochord, followed by presumptive pigment, sensory ganglion, sympathetic ganglion and adrenal medullary cells. In the caudal trunk, two additional paths were noted. One group of cells moves circumferentially within the fin, in an arc from dorsal to ventral; another progresses ventrally to the anus and subsequently populates the ventral fin. By labelling individual precursor cells, we find that neural tube and neural crest cells often share a common precursor. The majority of clones contain labelled progeny cells in the dorsal fin. The remainder have progeny in multiple derivatives including spinal ganglion cells, pigment cells, enteric cells, fin cells and/or neural tube cells in all combinations, suggesting that many premigratory Xenopus neural crest precursors are multipotent.

Neural crest emigration from the neural tube depends on regulated cadherin expression

Development ◽  
1998 ◽  
Vol 125 (15) ◽  
pp. 2963-2971 ◽  
Author(s):  
S. Nakagawa ◽  
M. Takeichi
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Critical Role ◽  
Neural Crest Cells ◽  
Migration Pattern ◽  
Dominant Negative ◽  
Expression Vectors ◽  
Neural Tubes ◽  
Neuroepithelial Cells

During the emergence of neural crest cells from the neural tube, the expression of cadherins dynamically changes. In the chicken embryo, the early neural tube expresses two cadherins, N-cadherin and cadherin-6B (cad6B), in the dorsal-most region where neural crest cells are generated. The expression of these two cadherins is, however, downregulated in the neural crest cells migrating from the neural tube; they instead begin expressing cadherin-7 (cad7). As an attempt to investigate the role of these changes in cadherin expression, we overexpressed various cadherin constructs, including N-cadherin, cad7, and a dominant negative N-cadherin (cN390), in neural crest-generating cells. This was achieved by injecting adenoviral expression vectors encoding these molecules into the lumen of the closing neural tube of chicken embryos at stage 14. In neural tubes injected with the viruses, efficient infection was observed at the neural crest-forming area, resulting in the ectopic cadherin expression also in migrating neural crest cells. Notably, the distribution of neural crest cells with the ectopic cadherins changed depending on which constructs were expressed. Many crest cells failed to escape from the neural tube when N-cadherin or cad7 was overexpressed. Moreover, none of the cells with these ectopic cadherins migrated along the dorsolateral (melanocyte) pathway. When these samples were stained for Mitf, an early melanocyte marker, positive cells were found accumulated within the neural tube, suggesting that the failure of their migration was not due to differentiation defects. In contrast to these phenomena, cells expressing non-functional cadherins exhibited a normal migration pattern. Thus, the overexpression of a neuroepithelial cadherin (N-cadherin) and a crest cadherin (cad7) resulted in the same blocking effect on neural crest segregation from neuroepithelial cells, especially for melanocyte precursors. These findings suggest that the regulation of cadherin expression or its activity at the neural crest-forming area plays a critical role in neural crest emigration from the neural tube.

Regulation of the onset of neural crest migration by coordinated activity of BMP4 and Noggin in the dorsal neural tube

Development ◽  
1999 ◽  
Vol 126 (21) ◽  
pp. 4749-4762 ◽  
Author(s):  
D. Sela-Donenfeld ◽  
C. Kalcheim
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Specific Inhibitor ◽  
Neural Crest Cells ◽  
Concomitant Treatment ◽  
Neural Tubes ◽  
Dorsal Neural Tube ◽  
Dependent Inhibition ◽  
Neural Crest Migration

For neural crest cells to engage in migration, it is necessary that epithelial premigratory crest cells convert into mesenchyme. The mechanisms that trigger cell delamination from the dorsal neural tube remain poorly understood. We find that, in 15- to 40-somite-stage avian embryos, BMP4 mRNA is homogeneously distributed along the longitudinal extent of the dorsal neural tube, whereas its specific inhibitor noggin exists in a gradient of expression that decreases caudorostrally. This rostralward reduction in signal intensity coincides with the onset of emigration of neural crest cells. Hence, we hypothesized that an interplay between Noggin and BMP4 in the dorsal tube generates graded concentrations of the latter that in turn triggers the delamination of neural crest progenitors. Consistent with this suggestion, disruption of the gradient by grafting Noggin-producing cells dorsal to the neural tube at levels opposite the segmental plate or newly formed somites, inhibited emigration of HNK-1-positive crest cells, which instead accumulated within the dorsal tube. Similar results were obtained with explanted neural tubes from the same somitic levels exposed to Noggin. Exposure to Follistatin, however, had no effect. The Noggin-dependent inhibition was overcome by concomitant treatment with BMP4, which when added alone, also accelerated cell emigration compared to untreated controls. Furthermore, the observed inhibition of neural crest emigration in vivo was preceded by a partial or total reduction in the expression of cadherin-6B and rhoB but not in the expression of slug mRNA or protein. Altogether, these results suggest that a coordinated activity of Noggin and BMP4 in the dorsal neural tube triggers delamination of specified, slug-expressing neural crest cells. Thus, BMPs play multiple and discernible roles at sequential stages of neural crest ontogeny, from specification through delamination and later differentiation of specific neural crest derivatives.

Contact inhibition/collapse and pathfinding of neural crest cells in the zebrafish trunk

Development ◽  
1996 ◽  
Vol 122 (1) ◽  
pp. 381-389 ◽  
Author(s):  
S. Jesuthasan
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Neural Crest Cells ◽  
Growth Cones ◽  
Contact Inhibition ◽  
Resolution Imaging ◽  
Vertebrate Embryos ◽  
Neuronal Growth Cones ◽  
Detailed Picture

Neural crest cells in the trunk of vertebrate embryos have a choice of pathways after emigrating from the neural tube: they can migrate in either the medial pathway between somites and neural tube, or the lateral pathway between somites and epidermis. In zebrafish embryos, the first cells to migrate all choose the medial pathway. High resolution imaging of cells in living embryos suggests that neural crest cells do so because of repulsion by somites: cells take the medial pathway because the lateral somite surface triggers a paralysis and retraction of protrusions (contact inhibition or collapse) when the medial surface does not. Partial deletion of somites, using the spadetail mutation allows precocious entry into the lateral pathway, but only where somites are absent, supporting the notion that an inhibitory cue on somites delays entry. Growth cones of Rohon-Beard cells enter the lateral pathway before neural crest cells, demonstrating that there is no absolute barrier to migration. These data, in addition to providing a detailed picture of neural crest cells migrating in vivo, suggest that neural crest cells, like neuronal growth cones, are guided by a specific cue that triggers ‘collapse’ of active protrusions.

scholarly journals In ovo time-lapse analysis after dorsal neural tube ablation shows rerouting of chick hindbrain neural crest

Development ◽  
2000 ◽  
Vol 127 (13) ◽  
pp. 2843-2852 ◽  
Author(s):  
P. Kulesa ◽  
M. Bronner-Fraser ◽  
S. Fraser
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Neural Crest Cell ◽  
Neural Crest Cells ◽  
Time Lapse ◽  
Cell Interactions ◽  
In Ovo ◽  
Relative Contribution ◽  
Crest Cell ◽  
Cell Cell

Previous analyses of single neural crest cell trajectories have suggested important roles for interactions between neural crest cells and the environment, and amongst neural crest cells. To test the relative contribution of intrinsic versus extrinsic information in guiding cells to their appropriate sites, we ablated subpopulations of premigratory chick hindbrain neural crest and followed the remaining neural crest cells over time using a new in ovo imaging technique. Neural crest cell migratory behaviors are dramatically different in ablated compared with unoperated embryos. Deviations from normal migration appear either shortly after cells emerge from the neural tube or en route to the branchial arches, areas where cell-cell interactions typically occur between neural crest cells in normal embryos. Unlike the persistent, directed trajectories in normal embryos, neural crest cells frequently change direction and move somewhat chaotically after ablation. In addition, the migration of neural crest cells in collective chains, commonly observed in normal embryos, was severely disrupted. Hindbrain neural crest cells have the capacity to reroute their migratory pathways and thus compensate for missing neural crest cells after ablation of neighboring populations. Because the alterations in neural crest cell migration are most dramatic in regions that would normally foster cell-cell interactions, the trajectories reported here argue that cell-cell interactions have a key role in the shaping of the neural crest migration.

scholarly journals Developmental potential of trunk neural crest cells in the mouse

Development ◽  
1994 ◽  
Vol 120 (7) ◽  
pp. 1709-1718 ◽  
Author(s):  
G.N. Serbedzija ◽  
M. Bronner-Fraser ◽  
S.E. Fraser
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Mouse Embryo ◽  
Dorsal Root ◽  
Single Cells ◽  
Neural Crest Cell ◽  
Experimental System ◽  
Neural Crest Cells ◽  
Pigment Cells ◽  
Developmental Potential

The availability of naturally occurring and engineered mutations in mice which affect the neural crest makes the mouse embryo an important experimental system for studying neural crest cell differentiation. Here, we determine the normal developmental potential of neural crest cells by performing in situ cell lineage analysis in the mouse by microinjecting lysinated rhodamine dextran (LRD) into individual dorsal neural tube cells in the trunk. Labeled progeny derived from single cells were found in the neural tube, dorsal root ganglia, sympathoadrenal derivatives, presumptive Schwann cells and/or pigment cells. Most embryos contained labeled cells both in the neural tube and at least one neural crest derivative, and numerous clones contributed to multiple neural crest derivatives. The time of injection influenced the derivatives populated by the labeled cells. Injections at early stages of migration yielded labeled progeny in both dorsal and ventral neural crest derivatives, whereas those performed at later stages had labeled cells only in more dorsal neural crest derivatives, such as dorsal root ganglion and presumptive pigment cells. The results suggest that in the mouse embryo: (1) there is a common precursor for neural crest and neural tube cells; (2) some neural crest cells are multipotent; and (3) the timing of emigration influences the range of possible neural crest derivatives.

Induction of melanocyte precursors from neural crest cells surrounding the neural tube-like structures developed in vitro using mouse ES cell culture

2007 ◽  
Vol 27 (1) ◽  
pp. 45-52
Author(s):  
Koh-ichi Atoh ◽  
Manae S. Kurokawa ◽  
Hideshi Yoshikawa ◽  
Chieko Masuda ◽  
Erika Takada ◽  
...  
Keyword(s):  
Cell Culture ◽  
Neural Crest ◽  
Neural Tube ◽  
Neural Crest Cells ◽  
Es Cell ◽  
Mouse Es Cell

An experimental study on neural crest migration in Barbus conchonius (Cyprinidae, Teleostei), with special reference to the origin of the enteroendocrine cells

Development ◽  
1981 ◽  
Vol 62 (1) ◽  
pp. 309-323
Author(s):  
C. H. J. Lamers ◽  
J. W. H. M. Rombout ◽  
L. P. M. Timmermans
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Ganglion Cells ◽  
Neural Crest Cells ◽  
Enteroendocrine Cells ◽  
Pigment Cells ◽  
Transplantation Technique ◽  
Spinal Ganglion Cells ◽  
Neural Crest Origin ◽  
Neural Crest Migration

A neural crest transplantation technique is described for fish. As in other classes ofvertebrates, two pathways of neural crest migration can be distinguished: a lateroventral pathway between somites and ectoderm, and a medioventral pathway between somites and neural tube/notochord. In this paper evidence is presented for a neural crest origin of spinal ganglion cells and pigment cells, and indication for such an origin is obtained for sympathetic and enteric ganglion cells and for cells that are probably homologues to adrenomedullary and paraganglion cells in the future kidney area. The destiny of neural crest cells near the developing lateral-line sense organs is discussed. When grafted into the yolk, neural crest cells or neural tube cells appear to differentiate into ‘periblast cells’; this suggests a highly activating influence of the yolk. Many neural crest cells are found around the urinary ducts and, when grafted below the notochord, even within the urinary duct epithelium. These neural crest cells do not invade the gut epithelium, even when grafted adjacent to the developing gut. Consequently enteroendocrine cells in fish are not likely to have a trunkor rhombencephalic neural crest origin. Another possible origin of these cells will be proposed.

scholarly journals Role of FGF signalling in neural crest cell migration during early chick embryo development

Zygote ◽  
2018 ◽  
Vol 26 (6) ◽  
pp. 457-464 ◽  
Author(s):  
Xiao-tan Zhang ◽  
Guang Wang ◽  
Yan Li ◽  
Manli Chuai ◽  
Kenneth Ka Ho Lee ◽  
...  
Keyword(s):  
Neural Crest ◽  
Neural Tube ◽  
Neural Crest Cell ◽  
Dominant Negative ◽  
Neural Tubes ◽  
Dorsal Neural Tube ◽  
Neural Crest Cell Migration ◽  
Fgf Signalling ◽  
Crest Cell

SummaryFibroblast growth factor (FGF) signalling acts as one of modulators that control neural crest cell (NCC) migration, but how this is achieved is still unclear. In this study, we investigated the effects of FGF signalling on NCC migration by blocking this process. Constructs that were capable of inducing Sprouty2 (Spry2) or dominant-negative FGFR1 (Dn-FGFR1) expression were transfected into the cells making up the neural tubes. Our results revealed that blocking FGF signalling at stage HH10 (neurulation stage) could enhance NCC migration at both the cranial and trunk levels in the developing embryos. It was established that FGF-mediated NCC migration was not due to altering the expression of N-cadherin in the neural tube. Instead, we determined that cyclin D1 was overexpressed in the cranial and trunk levels when Sprouty2 was upregulated in the dorsal neural tube. These results imply that the cell cycle was a target of FGF signalling through which it regulates NCC migration at the neurulation stage.

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