In vitro stimulation of alkaline phosphatase activity in immature embryonic chick pelvic cartilage by adenosine

Cyclic AMP content in embryonic chick pelvic cartilage increases significantly as the embryo ages from 8 to 10 d. This in ovo elevation in cyclic AMP content precedes maximal cartilage alkaline phosphatase activity by some 24 h. We studied whether this temporal relationship may be causally related, using an in vitro organ culture. Incubation of pelvic cartilage from 9- and 10-d embryos in medium containing monobutyryl cyclic AMP (BtcAMP) resulted in significant increases in alkaline phosphatase activity (220 and 66 percent, respectively) as compared to that of cartilages incubated in medium alone. This stimulation was both concentration- and time-dependent with maximal response at 0.5 mM BtcAMP and 4-h incubation, respectively. Similar incubations of cartilage in medium containing 1-methyl-3-isobutyl xanthine (MIX), 0.25 mM, also resulted in increased alkaline phosphatase activity (114 percent). However, pelvic cartilage from 11-d embryos incubated in medium containing BtcAMP or MIX showed no increase in alkaline phosphatase activity. We postulated that developmental age was the factor responsible for this difference in response and that immature cartilage (that with little or no alkaline phosphatase activity) would respond to BtcAMP whereas mature cartilage (that with significant alkaline phosphatase activity) would not. This was tested by incubating end sections of 11-d cartilage, which have little alkaline phosphatase activity, and center sections, which have significantly alkaline phosphatase activity, with both BtcAMP and MIX. Alkaline phosphatase activity in end sections (immature cartilage) was stimulated by BtcAMP and MIX, whereas it was not stimulated in the center sections. Actinomycin D and cycloheximide inhibited BtcAMP and MIX stimulation of alkaline phosphatase activity. Thus, the in vitro data suggest that cyclic AMP is a mediator for the stimulation of alkaline phosphatase activity in embryonic cartilage.     

In vitro analysis of sympathetic neuron differentiation from chick neural crest cells

Sympathetic neuron differentiation was studied using a fluorescence histochemical assay to detect the appearance of cell-bound catecholamines. Results from in vitro organ cultures indicate that chick neural crest cells must interact with both ventral neural tube (defined throughout as the ventral neural tube plus the notochord) and somitic mesenchyme in order to differentiate into sympathoblasts. Somite, ventral neural tube, and crest were cultured transfilter in various combinations to define these tissue interactions more precisely. Results from these experiments indicate that neural crest cells must be contiguous to somite in order to differentiate into sympathoblasts, but ventral neural tube may act across a Millipore filter membrane (type TH, 25 μm thick) either on somite, crest, or both. To distinguish among these possibilities, somite was cultured transfilter to ventral tube for a short period, after which ventral tube was removed and fresh crest was added to the somite. The results from this and other experiments support the hypothesis that the ventral tube does not act directly on crest cells, but elicits a developmental change in somitic mesenchyme, which then promotes sympathoblast differentiation. To study the relationship of nerve growth factor (NGF) to the differentiation of sympathetic neurons, cultures of somite + crest were temporarily exposed transfilter to ventral tube, in the presence or the absence of exogenous NGF. The results of these and other experiments are consistent with the hypothesis that the continued presence of ventral tube is required to ensure the survival of the differentiating sympathetic neurons. With respect to this second function, ventral tube can be replaced by exogenous NGF.     

Hemidesmosome formation by embryonic chick corneal epithelium in vitro

This study was undertaken in order to determine whether 15-day embryonic chick corneal epithelial cells can form hemidesmosomes when cultured on a variety of substrata. It was found that hemidesmosomes were formed on gelatin films, hydrated collagen gels, lens capsule, scraped corneal stroma, matrix produced by corneal endothelial cells and untreated tissue culture plastic. Hemidesmosomes were found after 5 days in cultures produced from either dissociated epithelial cells or whole epithelial explants. Hemidesmosomes occurred both singly and in groups and their morphology varied between well-defined structures with attachment plaques, sub-basal dense plates and connections to intracellular filamentous networks, and more rudimentary forms. The presence of extracellular material was often associated with the hemidesmosomes, although it was also possible to find hemidesmosomes where this material was absent. This work suggests that, in the embryonic chick cornea, extracellular structures such as anchoring filaments and anchoring fibres often associated with mature hemidesmosomes are not essential for hemidesmosome formation.     

Morphology and behaviour of neural crest cells of chick embryo in vitro

Summary Neural primordia of chick embryos were cultured for three days and the behaviour of migrating neural crest cells studied. Somite cells were used as a comparison. Crest cells were actively multipolar with narrow projections which extended and retracted rapidly, contrasting to the gradual extension of somite-cell lamellae. On losing cell contact, somite cells were also more directionally persistent. The rate of displacement of isolated crest cells was particularly low when calculated over a long time base. Both crest and somite cells were monolayered; contact paralysis occurred in somite cell collisions but was not ascertained for crest cells. However, crest cells in a population were far more directionally persistent than isolated cells. Contact duration between crest cells increased with time and they formed an open network. Eventually, retraction clumping occurred, initially and chiefly at the periphery of the crest outgrowth. Crest cells did not invade cultured embryonic mesenchymal or epithelial populations but endoderm underlapped them. No effects were observed on crest cells prior to direct contact. Substrate previously occupied by endoderm or ectoderm caused crest cells to flatten while substrate previously occupied by the neural tube caused them to round up and clump prematurely.     

A novel antigen is shared by retinal pigment epithelium and pigmented neural crest

 Pigment cells in vertebrate embryos are formed in both the central and peripheral nervous system. The neural crest, a largely pluripotent population of precursor cells derived from the embryonic neural tube, gives rise to pigment cells which migrate widely in head and trunk.The retinal pigment epithelium is derived from the optic cup, which arises from ectoderm of the neural tube. We have generated an antibody, ips6, which stains an antigen common to pigment cells of retinal pigment epithelium and neural crest. Ips6 stains retinal pigment epithelium and choroid as well as a subset of crest cells that migrate in pathways typical of melanoblasts. Immunoreactivity is seen first in the eye and later in a subset of migrating crest cells. Crest cells in the amphibian embryo migrate along specific, stereotyped routes; ips6 immunoreactive cells are found in some but not all of these pathways. In older wild-type embryos, cells expressing ips6 appear coincident with pigment-containing cells in the flank, head, eye and embryonic gut. In older animals, staining in the eye extends to the intraretinal segment of optic nerve and interstices between photoreceptors and cells at the retinal periphery. We suggest that the ips6 antibody defines an antigen common to pigment cells of central and peripheral origin. Received: 22 January 1996/Accepted: 15 July 1996     

Collagen production in vitro by the retinal pigmented epithelium of the chick embryo

Cloned colonies and explants of embryonic chick retinal pigmented epithelium from donors of various embryonic ages were maintained in culture for different periods and examined by electron microscopy. The cells appeared morphologically differentiated and polarized. Basement-membrane material and striated collagen fibrils were identified as extracellular deposits beneath the basal surfaces of the cells. There appeared to be a distinct spatial and temporal correlation between the production of basement-membrane material and collagen fibrils. Increasing donor age correlated positively with increasing average diameter of the collagenous fibrils produced, as well as a widening of the range of fibril sizes.     

VIP stimulation of polarized macromolecule secretion in cultured chick embryonic retinal pigment epithelium.

Vasoactive intestinal peptide (VIP) stimulated macromolecule secretion at the apical membranes of the chick embryonic retinal pigment epithelium cultured on permeable supports in a time- and concentration-dependent manner. VIP stimulated secretion of molecules with MW of 80, 74, 70, 60, 42, 35, 24, 20, and 14 kDa. A 1.9- to 2.6-fold stimulation in secretion of molecules with MW greater than 10 kDa precipitable by 10% trichloroacetic acid was observed after treatment with 1 microM VIP for 15 min. The effect of 1 microM VIP was mimicked by 10 microM dibutyryl cyclic AMP and attenuated by dopamine (1 x 10(-4) M), while colchicine, beta-lumicolchicine, and monensin, all at 1 microM, had no effect.     

Quantitative distribution of chick neural crest cells during gangliogenesis

Summary We have quantitated the distribution of chick neural crest cells after they have completed early migration and are aggregating into ganglia. Variables tested for an influence on the distribution of cells include stage, level of somites, position in each of the primary body axes, and individual embryo. The 11th–15th cervical somites of embryos at stages 30, 35, and 40 somites (s) incubated for 2.5, 3.0, and 3.5 days were labeled with antibody to HNK-1 to detect neural crest cells, and doubly labeled with antibody to HNK-1 and to the 150 kD neurofilament subunit to detect neural crest-derived neurons. Significantly more neural crest cells appear at older stages, but cells are uniformly distributed among the 11th–15th somites at any given stage. Significant differences in the total number of neural crest cells among three embryos sampled at the same stage indicate that the number of cells is independent of the staging series used. As early as the 35 s stage about one-third of the neural crest cells throughout the somite exhibit NF staining. At the 40 s stage, doubly labeled NF cells, as well as HNK-1 labeled cells, aggregate in a circumscribed portion of the mediolateral axis to form presumptive sensory ganglia in the dorsal region of the somites. Also at 40 s a wave of cell aggregation into sympathetic ganglia proceeds anteroposteriorly along the ventral border of the somitic mesenchyme. The results show a sequence of phenotypic expression beginning with neurofilament antigen, then ganglionic aggregation, and finally, in the case of sympathetic neurons, catecholamine transmitter.     

Behavior of neural crest cells on embryonic basal laminae

Neural crest cells separate from the neural epithelium in a region devoid of a basal lamina and migrate along pathways bordered by intact basal laminae. The distribution of basal laminae suggests that they might have an important role in the morphogenesis of the neural crest by acting as a barrier to migration. The experiments reported here have tested directly whether neural crest cells can penetrate a basal lamina. Isolated neural tubes, neural crest cells cultured for 24 hr, or pigmented neural crest cells were explanted onto human placental amnions from which the epithelium had been removed to expose the basal lamina. In no case did neural crest cells or crest derivatives penetrate the basal lamina to invade the underlying stroma. If crest cells were grown on the stromal side of the amnion, they invaded the connective tissue. Pigmented neural crest derivative and [3H]thymidine-labeled nonpigmented crest cells were also confronted with chick embryonic basal laminae by grafting the cells into the lumen of the neural tube at the axial levels where host crest migration had commenced. Most of the grafted cells invaded the neural epithelium and accumulated after 24 hr at the basal surface of the neural tube. A few crest cells escaped through the dorsal surface of the neural tube and entered the overlying ectoderm, presumably through the wound created during the grafting procedure. Some of these grafted cells, located initially by light microscopy, were examined at the higher magnification and resolution offered by the transmission electron microscope to determine the relationship of the grafted cells to the basal lamina. In 50% (14 total) of the cases, the crest cells never reached the basal lamina of the neural tube, but were trapped by cell junctions between the neural epithelial cells. Of the remaining grafted cells that were relocated in the TEM (50%, total 15) all were spread on the basal lamina, but were not seen penetrating it. Likewise, in the three cases where crest cells were found in the epidermal ectoderm, all were in contact with the basal lamina of the ectoderm but did not have any processes extending through it. In three cases, at the level of the light microscope, crest cells were found to extend through the basal surface of the neural tube. In all these instances, the cells followed the dorsal root nerve exiting through a region of the neural tube that is devoid of a basal lamina.(ABSTRACT TRUNCATED AT 400 WORDS)     

Invasive characteristics of neural crest cells in vitro

An investigation of the invasiveness of avian neural crest cells and neural crest-derived melanocytes through a human amniotic basement membrane (BM) was undertaken. Avian neural tube explants or derived melanocyte populations were seeded directly onto BMs in membrane invasion culture system (MICS) chambers for periods of 24, 48, and 72 h. In 36 experimental trials for each group, neither neural crest nor neural crest-derived melanocytes were observed to have invaded the BMs. In concert with these studies, coculturing of B16F10 murine melanoma cells with avian neural crest-derived melanocytes was performed in MICS chambers. Under these experimental conditions, the neural crest-derived melanocytes were able to successfully invade the BMs and to a greater extent than the B16F10 tumor cells. These data suggest that neural crest cells and neural crest-derived melanocytes do not have the ability to invade the BM alone; however, they can be induced to be invasive when cocultured in the presence of B16F10 cells. Alternatively, the B16F10 cells may create weaknesses within the BM that facilitate migration of the pigmented crest cells.     

In vitro morphogenesis of chick embryo hypertrophic cartilage

Dedifferentiated chick embryo chondrocytes (Castagnola, P., G. Moro, F. Descalzi-Cancedda, and R. Cancedda, 1986, J. Cell Biol., 102:2310-2317), when transferred to suspension culture on agarose-coated dishes in the presence of ascorbic acid, aggregate and remain clustered. With time in culture, clusters grow in size and adhere to each other, forming structures that may be several millimeters in dimension. These structures after 7 d of culture have the histologic appearance of mature hypertrophic cartilage partially surrounded by a layer of elongated cells resembling the perichondrium. Cells inside the aggregates have ultrastructural features of stage I (proliferating) or stage II (hypertrophic) chondrocytes depending on their location. Occurrence and distribution of type I, II, and X collagens in the in vitro-formed cartilage at different times of culture, show a temporal and spatial distribution of these antigens reminiscent of the maturation events occurring in the cartilage in vivo. A comparable histologic appearance is shown also by cell aggregates obtained starting with a population of cells derived from a single, cloned, dedifferentiated chondrocyte.     

In vitro differentiation of transplantable neural precursors from human embryonic stem cells.

The remarkable developmental potential and replicative capacity of human embryonic stem (ES) cells promise an almost unlimited supply of specific cell types for transplantation therapies. Here we describe the in vitro differentiation, enrichment, and transplantation of neural precursor cells from human ES cells. Upon aggregation to embryoid bodies, differentiating ES cells formed large numbers of neural tube-like structures in the presence of fibroblast growth factor 2 (FGF-2). Neural precursors within these formations were isolated by selective enzymatic digestion and further purified on the basis of differential adhesion. Following withdrawal of FGF-2, they differentiated into neurons, astrocytes, and oligodendrocytes. After transplantation into the neonatal mouse brain, human ES cell-derived neural precursors were incorporated into a variety of brain regions, where they differentiated into both neurons and astrocytes. No teratoma formation was observed in the transplant recipients. These results depict human ES cells as a source of transplantable neural precursors for possible nervous system repair.