Restriction in Cell Fates of Developing Spinal Cord Cells Transplanted to Neural Crest Pathways

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Volume 16, Number 23, Issue of December 1, 1996 pp. 7638-7648
Copyright ©1996 Society for Neuroscience

Restriction in Cell Fates of Developing Spinal Cord Cells Transplanted to Neural Crest Pathways

$Z$ eljka Korade and Eric Frank
Department of Neurobiology, School of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania 15261

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

At early neural tube stages, individual stem cells can generate neural crest cells as well as dorsal or ventral spinal cordcells. To determine whether this pluripotency is lost as developmentproceeds, we back-transplanted quail spinal cells from differentdevelopmental stages and different spinal locations into the crestmigratory pathways of st 16-20 chicken host embryos. The transplantedspinal cells from st 27 dorsal cord and st 18 ventral cord differentiatedwithin the new crest environment into sensory and sympatheticneurons, satellite and Schwann cells, and melanocytes. St 27 ventralcells still generated several crest derivatives but not sensoryor sympathetic neurons. This loss in ability to produce neuronscorrelates with the end of neurogenesis in ventral cord. The endof neurogenesis in the cord, therefore, results from an intrinsicchange in the potential of spinal neuroepithelial cells to generateneurons.
Key words: neuroepithelial cells; cell fate; cell determination; neural crest; spinal cord; transplantation

INTRODUCTION

At early neural tube stages, cells from the most dorsal aspects of the tube migrate into the surrounding tissue where theygive rise to many different cell types, including sensory andautonomic neurons, satellite cells, Schwann cells, and melanocytes(Weston, 1981; Le Douarin, 1982). The emerging view is that atearly neural tube stages individual neuroepithelial cells arepluripotent and can give rise to all types of neural crest (NC)derivatives as well as neurons and glia that remain in the spinalcord (Scherson et al., 1993; Selleck et al., 1993; Artinger etal., 1995). Once crest cells have migrated away from the tube,there is a progressive restriction in their developmental potential(Anderson, 1989; Weston, 1991).

A progressive restriction of cell fates for neuroepithelial cells remaining within the neural tube is less clear. Neuroepithelialcells at stages before neural tube closure are able to generateboth dorsal and ventral phenotypes within the spinal cord as wellas NC derivatives. Placement of a notochord adjacent to the dorsalregion of a newly closed neural tube induces dorsal neuroepithelialcells to express ventral cord markers (Artinger et al., 1995).If the dorsal portion of the neural tube is removed before NCemigration, the remaining ventral portion is able to generatenormal NC derivatives (Scherson et al., 1993). But if the deletionis made shortly after emigration, NC derivatives are not generated(Scherson et al., 1993; Sechrist et al., 1995). When do neuroepithelialcells within the cord become truly restricted in their potentialto generate progeny with crest phenotypes?

The recent demonstration of a second major emigration of neuroepithelial cells away from the neural tube into sensory gangliashows that at least some cells within the tube retain their abilityto develop as crest cells until well after normal crest migration(Sharma et al., 1995). Only the cells within the dorsal half ofthe spinal cord contribute to this late-migrating population,and they contribute only to a subset of possible crest phenotypes.These results, together with those of Bronner-Fraser and coworkers(Scherson et al., 1993; Sechrist et al., 1995), might reflectboth a loss in potential of cells in the ventral cord to developas crest cells and a restriction in the possible crest-like fatesof the dorsal cells.

To test these possibilities, we have transplanted cells from dorsal or ventral spinal cord into the crest migratory pathwayof younger embryos and then followed their development over timeto analyze their phenotypes. Cells from the dorsal spinal cordeven 1-2 d after the end of normal crest emigration continue todivide after transplantation, migrate along the crest migratorypathways, and give rise to a variety of crest derivatives includingperipheral neurons. In contrast, cells from the ventral cord atthe same stage are restricted in their developmental potential.Although they also continue to divide after transplantation, ventralcells migrate less extensively and do not produce peripheral neurons.

MATERIALS AND METHODS
Transplantation experiments. White Leghorn chick embryos (SPAFAS) were used as hosts and quail embryos as donors in all experiments.Host and donor embryos were staged according to Hamburger andHamilton (1951). St 17-28 quail spinal cords were separated intodorsal and ventral halves with tungsten needles. Donor cells weredissociated by incubation for 10 min in calcium/magnesium-free(CMF)-trypsin solution (0.1 mg/ml) at 22°C followed by triturationwith a fire-polished Pasteur pipette. After centrifugation, thecell pellet was resuspended in MEM with 0.01% Fast Green for visualizationduring transplantation. Approximately 200-500 cells were drawninto a polished glass electrode (tip diameter 10-30 µm) in 0.5µl of solution. Chick embryo hosts (st 16-20) were exposed fortransplantation by opening the vitelline membrane. The tip ofthe electrode was then positioned just beneath the host ectodermand just lateral to the neural tube in the cranial half of a somite,and the cells were injected with pressure pulses under visualcontrol. All transplantations were made at the level of the wingbud. Eggs were then sealed with cellophane tape and returned tothe incubator.

Immunohistochemistry. Host embryos were killed 1-10 d after transplantation (st 20-40). Embryos up to st 25 were processedas described by Oakley and Tosney (1991). Older embryos were perfusedtranscardially with 4% paraformaldehyde in PBS. The brachial regionwas separated and post-fixed for 4-10 hr in the same fixative.Alternate serial 20 µm cryostat sections were collected on separateslides. One set of sections was used to locate and count donorcells by staining with a quail-specific antibody, QPN (DevelopmentalHybridoma Bank) using the staining protocol described in Sharmaet al. (1994). The second set was stained with anti-tubulin antibody,TuJ1 (a gift from Dr. Anthony Frankfurter, University of Virginia),to identify small peripheral nerves in muscles (see Fig. 3C) orwith a quail-specific neuron-specific antibody, QN (a gift fromDr. Hideaki Tanaka, Kumamoto University) to identify neuronaldonor cells (see Fig. 3A,B,D-F). Staining protocols have beendescribed previously (Moody et al., 1989; Tanaka et al., 1990;Sharma et al., 1995).
Fig. 3. Phenotypes of transplanted cells within host embryos. A and B show transplanted dorsal cells stained with QN (quail-specificneuron-specific Ab) that differentiated into peripheral neuronswithin the host DRG (arrows point to stained neurites). C, Transplanteddonor cells (black-stained with Q/CPN) associated with the branchof a small muscle nerve (gray-stained with TuJ1). Two transplanteddorsal cells (arrows) have the morphology of Schwann cells; theother two are out of focus (arrowheads). D-F show transplantedyounger ventral cells (stained with QN Ab) within the host DRGthat also differentiated into neurons. Arrows point to stainedneurites. Scale bar, 10 µm.
[View Larger Version of this Image (110K GIF file)]

Identification of donor cell phenotypes. The phenotypes of donor cells were classified in st 34-40 host embryos, 7-10 d aftertransplantation. Donor melanocytes were easily recognized by theircharacteristic quail pigmentation in the white chicken hosts (seeFig. 4). Quail cells with elongated, QPN-positive nuclei andlocated in peripheral nerves and spinal roots were classifiedas Schwann cells (see Figs. 2E, 3C), because they appeared identicalto Schwann cells in normal quail embryos (Fig. 2F). The possibilityexists, however, that these cells were oligodendrocytes ratherthan Schwann cells. The antibody QN was a useful marker for quailperipheral neurons at these stages (Tanaka et al., 1990; Sharmaet al., 1995) (our unpublished observations). By st 30, developingwhite matter tracts in the quail spinal cord are QN-positive,as well as sensory axons in dorsal roots, but no neuronal somatain the spinal cord or peripheral ganglia are stained. Many quailDRG and sympathetic neuronal somata become QN-positive by st 34,and this staining persists until at least st 39-40. Throughoutthis time period, however, neuronal somata within the spinal cordshow only background levels of staining for QN. No chicken cellswere QN-positive through st 40.
Fig. 4. Quail melanocytes in chicken host and normal quail embryos. A, Quail pigmentation is visible in feathers of host embryos abovethe transplantation site. Arrows point to the clusters of melanocyteswithin the feathers. B, A melanocyte derived from a transplanteddonor cell within host skin. The black granules within the cellare characteristic of quail melanocytes. C, Quail melanocytesin a normal quail embryo for comparison with those in chick hosts.Scale bars: A, 300 µm; B, C, 20 µm.
[View Larger Version of this Image (54K GIF file)]

Fig. 2. Distribution of transplanted dorsal cells within a host embryo. A, Camera lucida reconstruction of the distribution of st28 dorsal quail cells 8 d after transplantation into a st 17 hostembryo. This composite drawing shows dorsal cells (indicated bydots) found within one segment of the host embryo. Donor cellsare located in the DRG, sympathetic ganglia, peripheral nerves,and muscle (total number 6932 quail cells, not including melanocytes).All sections in B-F were stained with QPN. B, Transplanted dorsalcells within the dorsal root have elongated nuclei characteristicof differentiated Schwann cells (compare with E and F). C, Donorcells within the DRG include neurons (solid arrows), satellitecells, and Schwann cells (arrowheads). D, Donor cells in a sympatheticganglion. E, Most donor cells within peripheral nerves are Schwanncells. F, Schwann cells in a normal st 40 quail peripheral nerve.Scale bars: A, 100 µm; B, 25 µm; C, D, 50 µm; E, F, 15 µm.
[View Larger Version of this Image (72K GIF file)]

Labeling of dividing cells. Bromodeoxyuridine (BrdU) was used to label dividing cells. A 100 µl aliquot of 50 mg/ml BrdU inPBS was applied to the host chorioallantoic membrane 4-8 hr beforekilling. In control experiments, we found this protocol sufficientto maximize the number of labeled cells and, therefore, likelyto label all dividing cells. Donor quail cells were identifiedby double labeling with QPN. Sections were treated in 2N HClfor 40 min, incubated in blocking buffer for 30 min, and thenincubated in QPN hybridoma supernatant for 1 hr. A Cy3-labeledgoat anti-mouse IgG secondary antibody was applied for 1 hr, afterwhich the sections were fixed for 30 min in 4% paraformaldehyde,rinsed, and incubated in blocking buffer for 30 min. Sectionswere then incubated in monoclonal anti-BrdU antibody (Sigma, St.Louis, MO) for 1 hr followed by FITC-labeled goat anti-mouse IgGsecondary antibody. The fraction of donor cells that continuedto divide after transplantation was calculated in chimeric embryosexposed to BrdU as the fraction of QPN-positive cells that werealso BrdU-positive (refer to example in Fig. 7A).
Fig. 7. Transplanted donor cells divide within host embryos. A, Double labeling of transplanted quail cells that incorporated BrdUafter transplantation. The host embryo received BrdU 64 hr aftertransplantation and was fixed at 72 hr. Transplanted donor cellsare red (QPN, arrow), and host cells that divided are green(anti-BrdU, star). Double-labeled cells are yellow (arrowheads).Arrow indicates a transplanted donor cell with a morphology characteristicfor Schwann cells. Scale bar, 10 µm. B, Division of donor cellsafter transplantation. BrdU was injected into host embryos 16,40, or 64 hr after transplantation, and the embryos were fixed8 hr later. Both dorsal and ventral cells continue to divide 1and 2-3 d after transplantation.
[View Larger Version of this Image (55K GIF file)]

Analysis. A complete camera lucida reconstruction of the location and number of donor cells was made for each case using thealternate sections stained with QPN. A representative sectionfrom the center of the transplant region was used as a schematic,and individual donor cells were indicated as dots on this schematicdrawing. Examples of these reconstructions are shown in Figures2, 5, and 6. The total number of donor cells (see Table 2) wascalculated as 2 times the number of QPN-positive cells countedin the alternate sections. The cell counts do not include quailmelanocytes, which were scored separately and only semiquantitativelybecause of their large numbers.
Fig. 5. Distribution of dorsal versus older ventral donor cells 3 d after transplantation. Transplanted st 28 dorsal cells have migratedextensively at this time (A), whereas st 27 ventral cells remainclustered near the site of injection (B). The total number ofdonor cells was 558 in A and 340 in B. Scale bar, 100 µm.
[View Larger Version of this Image (15K GIF file)]

Fig. 6. Distribution of older (A, B) versus younger (C, D) ventral donor cells 8-10 d after transplantation. In A, older ventral cellshave settled in the DRG, peripheral nerve, and connective tissuesurrounding the DRG, whereas in B they are located only withinthe dorsal ramus nerve branch and the intervertebral muscle. Thedistribution of older ventral cells is restricted compared tothat of dorsal cells (compare with Fig. 2A). In C, younger ventralcells have settled in DRG, sympathetic ganglia, peripheral nerves,and muscle, whereas in D they are located within DRG and the longissimusmuscle. The total number of donor cells was 222 in A, 576 in B,1976 in C, and 1590 in D. Scale bar, 100 µm.
[View Larger Version of this Image (32K GIF file)]

Table 2. Total numbers of donor cells in host embryos

Embryo number Dorsal Older ventral Younger ventral

1 10 26 30

2 62 32 60

3 90 56 202

4 148 156 272

5 224 222 500

6 480 256 1590

7 504 290 1976

8 518 296 2892

9 568 576 3838

10 1208 684 16000

11 1308 1220 16100

12 2294 1294

13 2692 1718

14 3712 1874

15 6932

Includes all cases in which donor cells were injected into st 16-20 host embryos, the embryos developed to st 34-40, and somedonor cells were found in at least one crest target tissue. Countsexclude melanocytes (see Materials and Methods).

An estimate of the extent of donor cell migration was made by calculating the average number of crest target tissues thesecells occupied in each chimeric embryo for each type of transplant(st 26-28 dorsal cells, st 26-28 ventral cells, and st 17-20 ventralcells). The seven crest target tissues are listed in the columnsof Table 1 and include DRG, sympathetic ganglia, dorsal and ventralroots, peripheral nerves, muscle, and skin.

Table 1. Locations of transplanted cells within crest target tissues

Cases^a Transplanted dorsal cells

DRG Sym DorN PerN DR VR Mus Skin

1 x

1 x

1 x x

1 x x

2 x x x

1 x x x

1 x x x

1 x x x x

1 x x x x

1 x x x x x

1 x x x x x

1 x x x x x x

1 x x x x x x x

1 x x x x x x x

1 x x x x x x x x

Transplanted older ventral cells

DRG Sym DorN PerN DR VR Mus Skin

1^b

3 x

2 x

2 x x

1 x x

1 x x

2 x x x

1 x x x

1 x x x

1 x x x x

1 x x x x

1 x x x x x x

1 x x x x x x x

Transplanted younger ventral cells

DRG Sym DorN PerN DR VR Mus Skin

1^c

1 x

1 x x

1 x x x

1 x x x x

1 x x x x x

1 x x x x x

1 x x x x x

1 x x x x x

1 x x x x x x

2 x x x x x x

DRG, Dorsal root ganglia; Sym, sympathetic ganglia; DorN, dorsal ramus of spinal nerve; PerN, main spinal nerve; DR, dorsalroot; VR, ventral root; Mus, muscle.

^a Number of embryos.

^b All cells were within spinal cord.

^c All cells were within connective tissue.

RESULTS
The ability of neuroepithelial (NE) cells within the spinal cord to develop as neural crest cells was determined by back-transplantingquail cells into the crest migratory pathway in chicken host embryos.The transplantation of donor cells to host embryos is shown schematicallyin Figure 1A. To minimize possible influences of the transplantedcells on the host environment, we injected relatively small numbers(200-500) of dissociated cells. The normal period of neural crestmigration is between st 13 and 22, so donor cells were injectedinto st 16-20 host chicken embryos. Shortly after injection (0.25-6hr, n = 5), transplanted cells were found clustered near the dorsolateralquadrant of the neural tube, below the ectoderm and medial tothe dermomyotome (Fig. 1B). In this position, they were in thehost migratory pathway and among migrating host neural crest cells.
Fig. 1. Transplantation procedure. A, Chimeric embryos were created using quail spinal cord cells transplanted into chicken embryohosts. Dissociated cells from the dorsal or ventral halves ofquail spinal cords were pressure-injected into the neural crestmigratory pathway in st 16-20 chick hosts. B, Donor cells stainedwith QPN (quail-specific perinuclear Ab) 30 min after transplantationare located adjacent to the dorsolateral neural tube just ventralto dorsal ectoderm. Scale bar, 50 µm.
[View Larger Version of this Image (62K GIF file)]

Dorsal cells migrate and differentiate as normal crest cells
The first issue was to determine whether the limited phenotypes of normal late-migrating spinal cells in DRG (Sharma et al.,1995) result from an intrinsic limitation in the developmentalpotential of these cells. Late-migrating cells originate fromthe dorsal spinal cord at the level of the dorsal root entry zoneand migrate out of the cord into DRG between st 26 and 29. Wetherefore used dorsal spinal cells from st 26-28 quail embryosbut placed them into a st 16-20 host environment where normalcrest cells are actively migrating and developing.

Unlike late-migrating cells, transplanted dorsal cells migrated well beyond the bounds of the DRG and differentiated intoa variety of crest-type phenotypes. A serial reconstruction ofan embryo in which st 28 dorsal cells were transplanted into ast 17 host and allowed to develop until st 37 is illustrated inFigure 2A. At this stage, donor cells had probably achieved theiradult pattern of distribution. Although donor dorsal cells remainedlargely confined to one spinal segment, as do normal crest cells,they migrated ventrally, dorsally, and laterally into the dermis(see Fig. 4A), dorsal root (Fig. 2B), DRG (Fig. 2C), sympatheticganglia (Fig. 2D), and peripheral nerves (Fig. 2E).

In st 34-40 embryos (n = 16), we could identify some phenotypes simply by comparing the QPN (quail-specific Ab) stainingof donor cells in host embryos with QPN staining of normal quailembryos (compare the staining of Schwann cells in Fig. 2E and2F). To confirm that large QPN-positive cells within DRG wereperipheral neurons, we compared QPN staining with staining forQN (a second quail-specific antibody) in alternate sections. Asdescribed in Materials and Methods, QN stains the somata of manyDRG and sympathetic neurons but does not stain cell bodies (ofneurons or glia) within the spinal cord. It therefore providesa useful marker for peripheral, and thus crest-derived, quailneurons. QN staining indicated that many dorsal spinal cord cellswithin DRG and sympathetic ganglia had differentiated into peripheralneurons (Fig. 3A,B). Of 933 quail cells within DRG (checked in4 embryos), 190 (20%) were QN-positive. DRG also contained quailSchwann cells (identified by their elongated nuclei) and satellitecells (small nuclei adjacent to neurons). Schwann cells were presentwithin peripheral nerves (Fig. 2E) and dorsal and ventral roots(Fig. 2B). Melanocytes within the skin were also common (Fig.4A,B). In some cases, the characteristic quail pigmentation wasmacroscopically visible in the host embryos above the site oftransplantation (Fig. 4A). Many donor cells were also presentin muscle. Based on their elongated shape and location withinnerve branches (identified by staining for $beta$ -tubulin), many ofthese were Schwann cells (Fig. 3C). There were also donor cellsthat could not be classified both within muscles and in connectivetissue around the DRG and between muscle masses.

The overall distribution of transplanted dorsal cells in different structures of host embryos is shown in the top of Table1. The major conclusion is that there was widespread distributionof these cells to various neural crest target tissues. In 6 of16 cases, dorsal cells were present in five or more crest tissues,and in only 2 of 16 cases were they present in fewer than twotarget tissues. Individual cases with larger numbers of cellswere more likely to have cells distributed in all crest targettissues (data not shown), as would be expected by chance. On average,dorsal donor cells were found in four different crest target tissuesin each chimeric embryo.

Migration of ventral spinal cells depends on the stage of the donor
Transplanted dorsal spinal cells from st 26-28 donors migrate in synchrony with host neural crest cells and adopt phenotypescharacteristic of normal crest cells. These cells include thesubpopulation of late-migrating cells that normally contributeto the DRG. Could ventral cells, which normally do not contributeto crest derivatives, also migrate and adopt crest phenotypeswhen transplanted into the crest pathway? We tested this possibilityby transplanting ventral cord cells into st 16-20 host embryos,using the same protocol as for dorsal cells. In contrast to theresults with dorsal cells, however, ventral cells at a similarstage in development (st 26-28) migrated much less extensivelythan normal crest cells. This difference in migration was apparenteven at short times after transplantation, as illustrated in Figure5, A and B. Three days after transplantation into st 16-20 hostembryos, dorsal cells had already migrated into DRG and peripheralnerve (Fig. 5A; n = 9), but st 26-28 ventral cells (hereaftercalled older ventral cells) remained clustered near the injectionsite (Fig. 5B; n = 7).

Older ventral cells remained more restricted than dorsal cells even by st 34-40, 7-10 d after transplantation (n = 18). Twoexamples of host embryos at these later stages with older ventraldonor cells are shown in Figure 6, A and B, and the distributionof these cells is summarized in the middle of Table 1. Althougholder ventral cells could be found in any of the crest targettissues we examined, they typically occupied fewer of these targetsin any one embryo. In 5 of 18 cases, older ventral cells werepresent in fewer than two crest derivatives, and in only 2 of18 cases were they present in five or more target tissues. Onaverage, old ventral cells were found in two to three target tissues,compared with four for dorsal cells. Moreover, the progeny ofolder ventral cells were less likely to be found in DRG (only28% of embryos with older ventral cells vs 81% with dorsal cells).

The phenotypes of older ventral cells were most commonly those characteristic of crest cells in the tissues they occupied.For example, 83% of embryos with ventral cells had donor melanocytesin the skin overlying the injection site, compared to 50% of theembryos with dorsal cells (Fig. 8A,C, Table 1). When quail cellswere present in DRG, some QPN-positive nuclei had the elongatedshape characteristic of Schwann cells. The other quail nucleiin DRG were round and of small to medium diameter. Based on theirsize and shape, these cells could be either satellite cells orsmall- to medium-sized neurons. Particularly striking, however,was the paucity of peripheral neurons after ventral spinal transplants.None of the older ventral donor cells within DRG was stained withQN (0 of 172 DRG cells in all 5 embryos), although we did detecttwo QN-positive axons in the DRG of one embryo. In contrast, 20%of dorsal donor cells were QN-positive. Older ventral cells withinspinal roots and peripheral nerves, including small nerves withinmuscle, had the nuclear morphology of Schwann cells. A numberof donor cells located within muscle could not be classified and,as with dorsal donor cells, some embryos (5 of 18) had older ventralcells in connective tissue. Thus, although ventral spinal cellsretain the ability to generate some crest-like phenotypes (Schwanncells and melanocytes) as late as st 26-28, the cells do not migrateas well as dorsal cells on crest pathways and none of the progenyare peripheral neurons.
Fig. 8. Summary of the distribution of transplanted spinal cells. The timeline summarizes the timing of developmental events in dorsaland ventral spinal cord and indicates the stages at which dorsaland ventral spinal cells were taken from donor embryos. The threeschematic drawings summarize the distribution of the three classesof donor cells. Numbers in these drawings indicate the percentageof embryos with donor cells in various locations. Dorsal cellsfrom st 26-28 and younger ventral cells from st 17-20 have a similardistribution, but st 26-28 ventral cells behave differently. Theolder ventral cells are less likely to be located in DRGs andsympathetic ganglia and are more commonly found as melanocytesin skin.
[View Larger Version of this Image (29K GIF file)]

At much earlier developmental stages (st 10-12), ventral cord cells can be induced to migrate and populate crest derivativesby signals arising from the dorsal ectoderm (Sechrist et al.,1995). Even at st 17-20, ventral cells are still generating neuronalprecursors (Langman and Haden, 1970; Hollyday and Hamburger, 1977)(see timeline in Fig. 8), so we tested the potential of ventralcells at these stages (hereafter called younger ventral cells)to migrate and generate crest derivatives when transplanted intoa st 16-20 crest pathway. As shown in the reconstructions in Figure6, C and D, younger ventral spinal cells migrated like normalcrest cells and were found in the same range of crest derivativesas dorsal spinal cells (n = 12; data summarized in bottom of Table1). In 7 of 12 cases, younger ventral cells were present in fiveor more crest derivatives, and in only 1 of 12 cases were theypresent in fewer than two target tissues. The distribution ofyounger ventral cells was similar to that of dorsal cells; onaverage, they occupied four crest target tissues in each chimericembryo. Staining with QN showed that 27% of transplanted youngerventral cells within DRG were peripheral neurons (156 of 567 DRGcells in 3 embryos; Fig. 3D-F), similar to the result with dorsaldonor cells. Ventral cord cells, therefore, retain the abilityto develop a wide range of crest phenotypes, including peripheralneurons, at least until st 17-20.

Dorsal and ventral cells divide after transplantation
The reduced developmental plasticity of older ventral cells might be because they failed to divide after transplantation.The ratio of dividing ventral to dorsal cells at the time of transplantationis ~0.5 (Corliss and Robertson, 1963; Hamburger, 1948). We confirmedthat fewer ventral cells had recently divided shortly before transplantationby labeling donor embryos at these stages with BrdU 4 hr beforespinal cells were isolated and then counting the percentage ofBrdU-labeled donor cells 1 d after transplantation. Over one-halfof the dorsal cells (58 ± 10%; n = 9) but only one-third of olderventral cells (32 ± 15%; n = 3) were labeled. If some postmitoticcells die after transplantation (for example, neurons deprivedof needed trophic support), the actual difference in the numberof transplanted mitotically active cells would be even greater.

Despite this difference in the dorsal versus older ventral populations of transplanted cells, a significant fraction of thesurviving cells in both populations continued to divide aftertransplantation. This was demonstrated by injecting BrdU at varioustimes after transplantation and fixing the embryos 4 hr later.Approximately 20% of the donor cells were dividing, whether BrdUwas injected 1, 2, or 3 d after transplantation (Fig. 7). Thefraction of dividing cells was nearly the same for older ventraland dorsal donor cells. A straightforward interpretation of theseseemingly contradictory results concerning mitotic activity beforeand after transplantation is that nondividing cells were morelikely to die after transplantation. This would tend to equalizethe fraction of dividing cells in the two populations.

Older ventral cells also gave rise to smaller total numbers of cells than dorsal cells did. The number of donor cells in individualembryos of both groups varied over a wide range (Table 2), presumablyreflecting variability in the number of cells successfully injectedinto the crest pathway and/or surviving the transplantation procedure.Nevertheless, although approximately equal numbers of donor cellswere injected for each type of transplantation, cell counts ofall donor cells (excluding melanocytes) in st 34-40 embryos wereabout half as large when using older ventral versus dorsal cells(median 293 vs 518 cells; n = 15 for each group). This differenceis consistent with the smaller number of older ventral cells thatwere dividing at the time of transplantation, and it supportsfurther the suggestion that a significant fraction of postmitotictransplanted cells may die in the host embryo. Despite these caveats,however, these results show that by st 26-28, ventral cord cellsthat continue to divide after transplantation have neverthelesslost the ability to respond to environmental cues required forthe acquisition of the full complement of crest phenotypes. Inparticular, their progeny migrate less extensively and are unlikelyto become peripheral neurons.

DISCUSSION
During embryonic development, neural crest cells emigrate from the most dorsal region of the neural tube and produce a widevariety of cell types that populate the peripheral nervous system.In chicken embryos, their emigration is complete by st 22 (Serbedzijaet al., 1989; Oakley et al., 1994). Our results show that NE cellsleft within the spinal cord after this emigration is completealso retain the ability to differentiate into cells with crest-likephenotypes, including sensory and sympathetic neurons, satellitecells, Schwann cells, and melanocytes. Even 2 d after normal crestcell emigration has ceased, spinal cells back-transplanted intoa crest migratory pathway migrate and develop as normal crestcells. The transplanted cells follow the temporal and spatialpattern of the host crest cells and differentiate into variouscell types appropriate for the host neural crest environment.

Earlier experiments had shown that NE cells leaving the spinal cord at st 26-28 gave rise to a limited number of phenotypes,specifically neurons and non-neuronal cells in DRG (Sharma etal., 1995). The present results show that this limitation in phenotypicdiversity does not reflect an intrinsic restriction of developmentalpotential because when these cells are transplanted into a youngercrest migratory pathway they differentiate with a wider varietyof crest phenotypes. Instead, the limited phenotypes of the late-migratingcells are probably a consequence of the temporally changing environmentof the crest pathway. Our experiments show that the end of thenormal period of crest cell emigration away from the neural tubeis not caused by a depletion of appropriate progenitor cells withinthe tube because cells there remain competent to produce crest-likeprogeny for several more developmental stages. A likely alternativeexplanation is that further emigration is halted by the developmentof a barrier around the tube that is not permissive for migration(Newgreen and Erickson, 1986). Late-migrating NE cells avoid thisbarrier by leaving the cord via the dorsal roots rather than movingdirectly away from the spinal cord (Sharma et al., 1995). Migrationthrough ventral roots at these later stages has also been reported(Lunn et al., 1987).

One function of this emigration barrier might be to prevent stem cells from entering the periphery at a time when the crestpathway no longer supports appropriate differentiation. In thepresent experiments, when spinal cord cells were transplantedinto host embryos at st 21-24, near the end of normal crest emigration,the cells migrated less extensively and did not populate sympatheticganglia, as for normal crest cells at these stages (data not shown).The restricted pathway of the late-migrating (st 26-28) spinalNE cells within dorsal roots leads them to the DRG, which supportsthe genesis of sensory neurons and satellite cells until st 35(Carr and Simpson, 1978).

The ability of ventral spinal cells to produce crest phenotypes has been demonstrated previously but only at earlier stagesof development. When the lateral neural plate, which will formthe dorsal neural tube, is removed from the hindbrain region atst 10, remaining cells in the medial plate migrate from the tubeand express characteristic crest cell markers (Scherson et al.,1993; Sechrist et al., 1995). Contact of neural plate cells withoverlying ectoderm is sufficient to induce neural crest characteristics(Dickinson et al., 1995); members of the TGF $beta$ family present withinthe dorsal ectoderm, particularly BMP4 and BMP7, are capable ofcausing this induction (Liem et al., 1995). In the present experiments,it is likely, therefore, that proximity of the transplanted spinalcells to the dorsal ectoderm induced the crest phenotypes. Theseexperiments extend earlier results by showing that spinal cellsretain the ability to develop crest phenotypes even at relativelylate embryonic stages (st 26-28 vs st 10-12). They reinforce theidea (Selleck et al., 1993) that neural crest progenitors do notrepresent a specialized subpopulation of cells within the neuraltube and that some cells within the tube retain the ability togive rise to crest-type progeny well after normal crest cell emigration.

Not all dividing cells within the cord retain the ability to generate a wide variety of crest phenotypes until late stages,however. Back-transplantation of dissociated cells from the ventralhalf of st 26-28 cords resulted in a restricted pattern of migrationeven though the migratory pathway promoted extensive migrationof dorsal spinal cord cells. Transplanted dorsal cells migratedextensively from the injection site to normal crest target areas,whereas older ventral cells were usually located nearer the siteof injection. Moreover, older ventral cells were less likely topopulate DRG (compare Fig. 8A with 8C) and gave rise to virtuallyno peripheral neurons even when they were located there. Ventralcord cells from earlier developmental stages (st 17-20) did migrateextensively, however, and gave rise to a variety of crest phenotypes,including peripheral neurons. In all respects we measured, thest 17-20 ventral spinal cells were indistinguishable from st 26-28dorsal spinal cells after transplantation into the crest pathway(Fig. 8B). The inability of older ventral spinal cord cells togenerate peripheral neurons parallels their changing role in thespinal cord. After st 23, genesis of motoneurons is complete,and virtually all ventral cord neurons have been generated byst 26 (Hollyday and Hamburger, 1977). The present results showthat the end of neurogenesis in the ventral spinal cord is notsimply because the environment of the ventral cord no longer supportsneurogenesis; instead, there is an intrinsic change in the abilityof ventral cord cells to generate neurons.

Many donor cells found in host embryos at st 34-40 resulted from cell division after transplantation. Injection of BrdU intohost embryos after transplantation labeled ~20% of the donor cellsindependent of their source (older ventral vs dorsal cord). Moreover,many of these cells continued to divide repeatedly because thelabeling index was the same whether BrdU was injected 1, 2, or3 d after the transplantation. The smaller number of dividingcells in older ventral versus dorsal cord was probably responsiblefor the smaller total numbers of donor cells in host embryos.Many motoneurons are normally dying at these stages (st 26-28),so it is likely that many postmitotic ventral cells, which includemotoneurons, are also dying after transplantation. The continueddivision of a substantial number of older ventral cells aftertransplantation coupled with the probable loss of many postmitoticcells argues strongly that dividing cells made a substantial contributionto the final population of donor cells in host embryos. Thus,the inability of older ventral donor cells to produce neuronsand to migrate extensively is not because they are postmitotic.

Transplanted progenitor cells from other parts of the CNS also give rise to progeny in accord with their host environment(McConnell, 1988; Eisen, 1991; Brüstle et al., 1995). In theneocortex, the ability of a cell to migrate to the appropriatehost layer depends on its position within the cell cycle at thetime of transplantation (McConnell and Kaznowski, 1991). Becausemany of the late ventral cells that we transplanted continuedto divide, one might have expected them to develop crest phenotypesappropriate for their host tissue; yet they did not. Interestingly,cortical progenitors also lose this ability at late stages ofdevelopment. The progeny of stem cells from the subplate regionof postnatal day 1 ferrets transplanted into younger hosts migrateaccording to the age of the donor, not the host (McConnell, 1995).Apparently, there is a progressive temporal restriction in theability of certain CNS progenitor populations to generate phenotypesappropriate for a novel spatiotemporal environment.

FOOTNOTES

Received Aug. 7, 1996; accepted Sept. 5, 1996.

Support for this work and for $Z$ .K. was provided by National Institutes of Health Grant NS24373 and a McKnight InvestigatorAward to E.F. We thank Dr. Cynthia Lance-Jones for advice duringthese experiments and on this manuscript, Dr. Anthony Frankfurterfor the TuJ1 antibody, Dr. Hideaki Tanaka for the QN antibody,and Dr. Kamal Sharma for help with the initial experiments. Ms.Xiaoping Chen provided technical assistance. The cell line producingQPN was obtained from the Developmental Hybridoma Bank.

Correspondence should be addressed to Dr. Eric Frank, Department of Neurobiology, BST W1452, University of Pittsburgh Schoolof Medicine, Pittsburgh, PA 15261.

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Copyright ©1996 Society for Neuroscience   0270-6474/1996/167638-11$05.00/0

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