Studies on the Role of Fibroblast Growth Factor Signaling in Neurogenesis Using Conjugated/Aged Animal Caps and Dorsal Ectoderm-Grafted Embryos

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Volume 17, Number 18, Issue of September 15, 1997 pp. 6892-6898
Copyright ©1997 Society for Neuroscience

Studies on the Role of Fibroblast Growth Factor Signaling in Neurogenesis Using Conjugated/Aged Animal Caps and Dorsal Ectoderm-Grafted Embryos

Ren-He Xu¹, Jaebong Kim², Masanori Taira³, Dvora Sredni⁴, and Hsiang-fu Kung²
¹ Intramural Research Support Program, Science Applications International Corporation-Frederick, and ² Laboratory of Biochemical Physiology, Division of Basic Sciences, National Cancer Institute-Frederick Cancer Research and Development Center, Frederick, Maryland 21702-1201, ³ Laboratory of Molecular Embryology, Department of Biological Sciences, Graduate School of Science, University of Tokyo, Tokyo 113, Japan, and ⁴ Interdisciplinary Department, Bar Ilan University, Ramat Gan, Israel 52900

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Basic fibroblast growth factor (bFGF) has been shown to induce neural fate in dissociated animal cap (AC) cells or in AC explantscultured in low calcium and magnesium concentrations. However,long-term disclosure of the cap may cause diffusion of the secretedmolecule bone morphogenetic protein 4 (BMP-4), a neural inhibitorpresent in the AC. This may contribute to the subsequent neurogenesisinduced by bFGF. Here we used conjugated and aged blastula ACto avoid diffusion of endogenous molecules from the AC. Unlikenoggin, bFGF failed to induce neural tissue in this system. However,it enhanced neuralization elicited by a dominant negative BMPreceptor (DN-BR) that inhibits the BMP-4 signaling. Posteriorneural markers were turned on by bFGF in AC expressing DN-BR orchordin. Blocking the endogenous FGF signal with a dominant negativeFGF receptor (XFD) mainly inhibited development of posterior neuraltissue in neuralized ACs. These in vitro studies were confirmedin vivo in embryos grafted with XFD-expressing ACs in the placeof neuroectoderm. Expression of some regional neural markers wasinhibited, although markers for muscle and posterior notochordwere still detectable in the grafted embryos, suggesting thatXFD specifically affected neurogenesis but not the dorsal mesoderm.The use of these in vitro and in vivo model systems provides newevidence that FGF, although unable to initiate neurogenesis onits own, is required for neural induction as well as for posteriorization.
Key words: FGF; BMP; neurogenesis; anteroposterior patterning; Xenopus; embryo

INTRODUCTION

Neural induction occurs in the dorsal ectoderm during gastrulation when the dorsal mesoderm involutes beneath the ectoderm.Three neural inducers, noggin, follistatin, and chordin, havebeen identified in Xenopus (Lamb et al., 1993; Hemmati-Brivanlouet al., 1994; Sasai et al., 1995). All are secreted proteins expressedin the right place (dorsal mesoderm) and at the right time (duringgastrulation) to exert neurogenic effect (Smith and Harland, 1991;Hemmati-Brivanlou et al., 1994; Sasai et al., 1994). However,evidence has shown that both noggin and chordin physically bindbone morphogenetic protein 4 (BMP-4) ligand to block BMP-4 signaling(Piccolo et al., 1996; Zimmerman et al., 1996). Therefore, BMP-4is a crucial molecule for maintaining the ectodermal fate. Neuralizationis a default state of the ectodermal cells that occurs only whenthe BMP-4 signaling is inhibited by these "neural inducers."

Additionally another secreted molecule, fibroblast growth factor (FGF), a well recognized mesoderm inducer, has been suggestedto be a neural inducer (for review, see Doniach, 1995). First,Kengaku and Okamoto (1993, 1995) found that basic FGF (bFGF) inducesdissociated cells of gastrula animal caps (ACs) to differentiateto neurons and melanophores with expression of both anterior andposterior markers. Second, Lamb and Harland (1995) found thatbFGF induces expression of posterior neural markers in the ACthat are excised at stage 9 and aged in low calcium and magnesiumconcentrations (LCMR) before bFGF treatment is started at thegastrula stage. However, the above experimental systems did noteliminate the possibility that the induced neurogenesis mightpartly result from dilution of the neural inhibitor BMP-4 becauseof the AC cell dissociation or long-term disclosure of the AC.

In this study, we used a conjugated and aged blastula AC system to avoid diffusion of endogenous molecules from the explants.Unlike noggin, bFGF failed to induce neural tissue in this system.However, it enhanced neuralization elicited by a dominant negativeBMP receptor (DN-BR) and induced posterior neural tissue in AC-expressingDN-BR or chordin, in agreement with the report by Cox and Hemmati-Brivanlou(1995). However, although they demonstrated that bFGF inducesposterior neural markers in anterior neural tissues (excised atstage 13.5-14) or AC (excised at stage 10.5-11), these explantsmight have received zygotic neuralizing signals such as noggin,chordin, and follistatin, as well as embryonic FGF, before dissection(Smith and Harland, 1991; Isaacs et al., 1992; Hemmati-Brivanlouet al., 1994; Sasai et al., 1994). Then, these signals would synergizewith exogenous FGF in the induction of posterior neural tissue.In contrast, we used ACs dissected at stage 8.5 that should beexempted from the effects of these zygotic neuralizing signals.Furthermore, "loss-of-function" studies are necessary to confirmthe requirement of endogenous FGF activity for neurogenesis. Therefore,we used a dominant negative FGF receptor (XFD) (Amaya et al.,1991) to inhibit FGF signaling and found that XFD mainly inhibiteddevelopment of posterior neural tissue. This was verified in embryosgrafted with XFD-expressing AC in the place of neuroectoderm.

MATERIALS AND METHODS
Agents. DN-BR, noggin, chordin, and $beta$ -galactosidase ( $beta$ -gal) cDNAs were in pSP64T vector. They were linearized and used forin vitro synthesis of capped mRNA using a transcription kit inaccordance with the manufacturer's instructions (Ambion) (Xu etal., 1997). The synthetic RNA was quantitated by ethidium bromidestaining in comparison with a standard RNA. Xenopus noggin proteinwas a kind gift from Dr. R. M. Harland (University of California,Berkeley, CA). Human bFGF protein was obtained from the BiologicalResources Branch of the Frederick Cancer Research and DevelopmentCenter (Frederick, MD).

Embryo injection and explant culture. Xenopus laevis embryos were obtained by in vitro fertilization after induction of femaleswith 500 U of human chorionic gonadotropin. Developmental stageswere designated according to the stages described by Nieuwkoopand Faber (1967). At the two-cell stage, each blastomere was injectedwith synthetic RNA as described in the figure legends. ACs weredissected from the injected embryos at stage 8.5. In some experiments,the ACs from two embryos were sandwiched immediately after explantationand cultured until the equivalent of stage 10.5 when the AC conjugateswere opened, separated, and cultured individually in the presenceof bFGF or noggin before being harvested at stage 24 (see Fig.1A). In other experiments, the injected ACs were cultured aloneand harvested at the tadpole stage. Explants were generally culturedat 22°C in 67% Leibovitz's L-15 medium (Life Technologies, Bethesda,MD) supplemented with 7 mM Tris-HCl, pH 7.5, and gentamicin at50 µg/µl (referred to below as L-15 medium). In some experiments,AC explants were cultured in LCMR (Lamb et al., 1993) to keepthem open until bFGF was added at stage 10.5 to serve as a positivecontrol (Lamb and Harland, 1995). All of the explants were harvestedfor analysis of molecular markers by reverse transcription-PCR(RT-PCR).
Fig. 1. A, Scheme for the AC conjugation system (st., stage). B, Analysis of neuralization. ACs were dissected at stage 8.5 and culturedin the absence (C) or presence of bFGF (F) or noggin (N) at 0.1µg/ml (lanes 1-3). Some ACs were conjugated at stage 8.5, manuallyopened at the equivalent of stage 10.5, and then cultured in L-15medium alone or with bFGF or noggin (lanes 4-6). Alternatively,ACs were cultured in LCMR medium to remain open for control orbFGF treatment at stage 10.5 (lanes 7 and 8). Whole embryos atstage 24 were used as a positive control (lane 9). The same sampleused in lane 8 was processed for RT-PCR in the absence of RT toserve as a negative control (lane 10). ACs were cultured untilstage 24 and analyzed for expression of NCAM and actin by RT-PCR.The expression of EF-1 $alpha$ was detected as an internal control forequal RNA loading.
[View Larger Version of this Image (24K GIF file)]

The conjugated and aged AC explants have been tested for neuralization competence. Sharpe et al. (1987) found that Xenopusdorsal and ventral ectoderms have a different competence to beinduced toward neural tissue; i.e., dorsal mesoderm induced neuralmarkers more strongly in dorsal ectoderm than in ventral ectoderm.Otte and Moon (1992) reported that protein kinase C- $alpha$ (PKC- $alpha$ )is predominantly localized in dorsal ectoderm and responsiblefor the higher neuralization competence of the dorsal ectoderm.We tested the PKC- $alpha$ expression in dorsal ectoderm and ventralectoderm excised at stage 10, as well as in dorsal ectoderm orventral ectoderm conjugates aged for 2 hr until stage 10.5. MorePKC- $alpha$ transcripts were detected in dorsal ectoderm than in ventralectoderm whether conjugated and aged or not, indicating the retentionof a dorsoventral (D-V) axis in our explant system. As for theanteroposterior (A-P) axis, it remains in stage 10.5 AC becauseanterior neural marker Otx2 and posterior neural marker HoxB9are expressed on either end of the AC cotreated with noggin andFGF (Lamb and Harland, 1995).

Embryonic transplantation. Two animal blastomeres of donor embryos were injected with 2 ng of XFD or control $beta$ -gal RNA atthe two-cell stage. ACs (approximately the central one-third ofthe whole animal hemisphere tissue) were dissected from the injectedembryos at stage 8. Meanwhile tissues of the dorsal ectoderm,which is the prospective neuroectoderm (from 30° dorsal of theintermediate vertical line of the animal pole to just above thedorsal lip), were removed from recipient stage 10 embryos. Thevacant area in the recipient embryos was covered immediately withthe AC from the injected embryos. The grafted embryos were allowedto develop to stage 30 before being harvested for photographyor RT-PCR analysis. Some injected embryos were not dissected butwere allowed to develop to stage 30 to serve as nontransplantationcontrols.

RT-PCR. Total RNA was extracted from cultured explants with TRIzol reagent (Life Technologies) in accordance with the manufacturer'sinstructions and subsequently was digested with DNase to removegenomic DNA. RT-PCR was performed using a Superscript preamplificationsystem (Life Technologies). Primer sets and PCR conditions formolecular markers, i.e., neural cell adhesion molecule (NCAM),actin, XK81, chordin, CG13, Otx2, En2, Krox20, HoxB9, and EF-1 $alpha$ ,have been described elsewhere (Hemmati-Brivanlou and Melton, 1994;Sasai et al., 1995; Wilson and Hemmati-Brivanlou, 1995; Xu etal., 1997). Although data from individual experiments are shown,the results were confirmed independently in all cases.

RESULTS

bFGF alone does not induce neural fate in gastrula stage AC
In the study of the role of FGF in neurogenesis, a conjugated AC system was used to avoid diffusion of endogenous moleculesfrom the explants that is likely to occur in the LCMR culturesystem (Lamb and Harland, 1995) and in the cell dissociation system(Kengaku and Okamoto, 1993, 1995). ACs were dissected and conjugatedat stage 8.5 and cultured until the equivalent of stage 10.5 inL-15 medium. Then, they were manually opened and exposed to bFGFor noggin at 0.1 µg/ml and cultured until stage 24 (Fig. 1A).Expression of pan-neural marker NCAM (Kintner and Melton, 1987)was detected in noggin-treated caps but not in bFGF-treated caps(Fig. 1B, lanes 5,6). To confirm that the bFGF used was biologicallyactive, we treated some ACs from stage 8.5 (just after explantation)with bFGF or noggin at the same concentration (0.1 µg/ml). bFGFagain failed to induce NCAM expression but did induce expressionof muscle actin (Fig. 1B, lane 2), which is consistent with itsmesoderm-inducing activity. In contrast, noggin induced expressionof NCAM but not of actin, which is in agreement with its neurogeniceffect in the ectoderm. A much lower level of NCAM expressionwas induced by noggin when added to the AC culture at stage 10.5than when added at stage 8.5 (Fig. 1B, lanes 3,6). This mightbe caused by a decrease in AC competence to neural induction orby accumulation of neural inhibitors such as BMP-4 in the stage10.5 AC. Some ACs were cultured in LCMR to keep them open untilbFGF was added at stage 10.5, and NCAM but not actin transcriptswere detected in the bFGF-treated caps (Fig. 1B, lane 8). TheseACs served as a positive control to ensure that stage 10.5 ACswere competent for neurogenesis in LCMR medium (Lamb and Harland,1995) in response to FGF, although these ACs failed to generateneural tissue in L-15 medium. The L-15 medium contains calciumand magnesium ions at normal concentrations and allows explantsto heal rapidly. It is possible that the difference in neuralizationcompetence might result from the diffusion of the neural inhibitorBMP-4 from the open AC cultured at low calcium and magnesium concentrations.This was based on the report that dispersed AC cells culturedin calcium- and magnesium-free medium undergo a cell-autonomousneuralization instead of epidermalization, and the neuralizationcan be reversed by addition of BMP-4 to the culture (Wilson andHemmati-Brivanlou, 1995). Although ACs cultured in LCMR did notexpress NCAM (Fig. 1B, lane 7), dilution of BMP-4 in this mediummight facilitate the neuralization triggered by bFGF treatment.To test this possibility, we used DN-BR in the subsequent experiments.

bFGF enhances neural induction by DN-BR
We used DN-BR to inhibit endogenous BMP-4 signaling (Graff et al., 1994; Maeno et al., 1994; Suzuki et al., 1994; Xu et al.,1996), a consequence similar to that resulting from dilution ofBMP-4 concentration in ACs. DN-BR RNA at increasing doses (0,0.01, 0.05, 0.1, and 0.5 ng/embryo) was injected into the animalpole area of the two-cell-stage embryos. ACs were dissected andconjugated at stage 8.5 and were cultured until the equivalentof stage 10.5 in L-15 medium. Then, they were manually openedand exposed to medium with bFGF at 0.1 µg/ml or to medium aloneand cultured until stage 24 (Fig. 1A). Without bFGF treatment,NCAM expression was absent in ACs injected with 0, 0.01, and 0.05ng of DN-BR RNA but was present in ACs injected with 0.1 and 0.5ng of DN-BR RNA (Fig. 2). In conjunction with bFGF treatment,DN-BR RNA at as low as 0.01 ng was able to induce NCAM. The sensitivityincreased 10-fold. At higher doses such as 0.1 and 0.5 ng of DN-BRRNA, NCAM expression was remarkably enhanced by bFGF treatment.Muscle actin was not detected in any of these ACs with or withoutbFGF treatment, thus excluding mesoderm involvement during neuralinduction. These data demonstrate that (1) neurogenesis does notoccur in response to bFGF unless BMP-4 signaling is blocked; and(2) bFGF enhances neurogenesis induced by DN-BR. Therefore, wepostulate that dilution of BMP-4 may be responsible for neurogenesisin ACs cultured in LCMR medium in the presence of bFGF.
Fig. 2. FGF synergizes with DN-BR in neural induction. DN-BR RNA at increasing doses (0, 0.01, 0.05, 0.1, and 0.5 ng/embryo) was injectedinto the animal pole area of the two-cell-stage embryos. ACs weredissected and conjugated at stage 8.5 and were cultured untilthe equivalent of stage 10.5 in L-15 medium. Then they were manuallyopened and exposed to medium with bFGF at 0.1 µg/ml (+) or tomedium alone ( $-$ ) and cultured until stage 24 (see Fig. 1A). Thetreated ACs were harvested for RT-PCR analysis to detect expressionof NCAM, actin, and EF-1 $alpha$ .
[View Larger Version of this Image (42K GIF file)]

bFGF posteriorizes neural tissue
Next, we tested what kind of neural tissue was induced in AC treated with both DN-BR and bFGF, because DN-BR induces onlythe anterior type of neural tissue (Hawley et al., 1995; Xu etal., 1995). Injection of RNA encoding either DN-BR (1 ng) or chordin(1.5 ng) induced the anterior neural marker Otx2 (Blitz and Cho,1995; Pannese et al., 1995) but not the hindbrain marker Krox20(Bradley et al., 1993) nor the spinal cord marker HoxB9 (knownpreviously as XlHbox6) (Wright et al., 1990) in AC cultured untilstage 24 (Fig. 3, lanes 2,4). However the injected AC, when treatedwith bFGF at 0.1 µg/ml starting at stage 10.5, expressed the posteriormarkers Krox20 and HoxB9 (Fig. 3, lanes 3,5). Again, muscle actinwas not induced after the bFGF treatment (Fig. 3), nor was theearly mesodermal marker Xbra when tested on AC treated with bFGFuntil stage 12 (data not shown), thus excluding the involvementof mesoderm induction. As a control, $beta$ -gal RNA-injected ACs expressednone of these markers (Fig. 3, lane 1). Based on these data, wepropose that bFGF is able to posteriorize neural tissue inducedby DN-BR or chordin. This is in agreement with the observationby Cox and Hemmati-Brivanlou (1995) that bFGF induces posteriorneural fate in AC neuralized by a dominant negative activin receptorand follistatin. Both of these induce neural tissue of anteriortype in ACs (Hemmati-Brivanlou and Melton, 1994; Hemmati-Brivanlouet al., 1994). However, the posteriorization they observed wason AC excised from embryos during gastrulation when neurogenesishad started. Therefore, the A-P axis in the prospective neuroectodermmight have been prepatterned before dissection, making it difficultto attribute posteriorization to bFGF alone. In contrast, we usedACs dissected from blastula stage embryos. They were conjugatedand aged until the equivalent of gastrula stage and then openedwith exposure to bFGF. Thus, posteriorization observed in thissystem can be directly credited to bFGF.
Fig. 3. FGF posteriorizes anterior neural tissue induced by DN-BR or chordin. RNA encoding DN-BR (1 ng) or chordin (1.5 ng) was injectedinto the animal pole area of the two-cell-stage embryos. ACs weredissected, treated with FGF, and processed as described in Figure2. Expression of NCAM, Otx2, Krox20, HoxB9, actin, and EF-1 $alpha$ wastested by RT-PCR.
[View Larger Version of this Image (39K GIF file)]

XFD inhibits neurogenesis
To elucidate the role of endogenous FGF in neurogenesis, we used XFD to block the FGF signaling in ACs expressing noggin,chordin, or DN-BR. Coinjection of XFD RNA downregulated NCAM expressioninduced by each of these neuralizing agents, whereas coinjectionof d50, a defective FGF receptor mutant, failed to do this (Fig.4A). Injection with a mixture of RNAs encoding a wild-type FGFreceptor, XFD, and DN-BR rescued the NCAM expression from theXFD inhibition (data not shown). All of these neural-inducingagents have been known to elicit neural tissue of an anteriortype in AC cells (Lamb et al., 1993; Hemmati-Brivanlou et al.,1994; Hawley et al., 1995; Sasai et al., 1995; Xu et al., 1995).To address the fate of cells that were inhibited from neuralizationby XFD, we tested for expression of the keratin marker gene XK81in the above samples. As shown in Figure 4A, the neuralized explantsexpressed more NCAM and less XK81 whereas cotreatment with XFDreversed the ratio of NCAM to XK81. This suggests that XFD simplyinhibits the neural fate and allows the cells to commit to thealternative epidermal fate, action similar to that of the neuralinhibitor BMP-4 (Wilson and Hemmati-Brivanlou, 1995).
Fig. 4. A, XFD inhibits neurogenesis while enhancing epidermalization in AC cells induced by noggin, chordin, and DN-BR. Various RNAswere injected into the animal pole area of the two-cell-stageembryos. ACs were dissected at stage 8.5 from the injected embryosand cultured until stage 24 before being harvested for RT-PCRanalysis to detect expression of NCAM, XK81, and EF-1 $alpha$ . Lane 1,AC derived from embryo injected with RNA-encoding $beta$ -gal (3 ng);lane 2, noggin (0.5 ng) and d50 (2 ng); lane 3, noggin (0.5 ng)and XFD (2 ng); lane 4, chordin (1.5 ng) and d50 (2 ng); lane5, chordin (1.5 ng) and XFD (2 ng); lane 6, DN-BR (1 ng) and d50(2 ng); and lane 7, DN-BR (1 ng) and XFD (2 ng). B, XFD inhibitsexpression of midbrain-hindbrain boundary marker En2. Lane 1,ACs were dissected from embryos injected with RNA-encoding $beta$ -gal(3 ng); lane 2, DN-BR (1 ng); and lane 3, DN-BR (1 ng) and XFD(2 ng). ACs were cultured until stage 24, and expression of NCAM,CG13, Otx2, En2, and EF-1 $alpha$ was detected by RT-PCR.
[View Larger Version of this Image (55K GIF file)]

Analysis of molecular markers in AC coexpressing DN-BR and XFD (Fig. 4B) showed that expression of the most anterior ectodermalmarker, CG13, which is expressed in cement gland and induced byneighboring neural or dorsal mesodermal tissue (Jamrich and Sato,1989), was upregulated by XFD, whereas expression of En2, a markerof the midbrain-hindbrain boundary (Hemmati-Brivanlou et al.,1991), was totally inhibited by XFD. Similar results were observedalso in AC coexpressing XFD and noggin or chordin (data not shown).However, XFD had no clear effect on Otx2 expression (Fig. 4B),which is contradictory to the report that XFD totally inhibitsOtx2 expression in neuralized AC (Launay et al., 1996). This differencemay be explained as follows. According to the two-step model proposedfor neurogenesis by Nieuwkoop et al. (1952) and Saxén and Toivonen(1961), the CNS development may include an activation (neuralinduction) step and a transformation (posteriorization) step.Low FGF may cooperate with the activation step (then higher XFDis required to block it), whereas higher FGF may mimic the transformationsignal (then lower XFD is required to block it). Therefore, variousamounts of XFD protein derived from the RNA injection may resultin differential effects on neural induction and posteriorization.We might have used a low dose of XFD that only inhibited the posteriorizationstep, thus leaving Otx2 expression less affected. Nevertheless,both the gain-of-function (Fig. 3) and loss-of-function (Fig.4) experiments agree on the posteriorizing role of FGF in AC neurogenesis.

FGF signaling is required for posteriorization of the CNS in embryo
To advance our understanding of the role of FGF in neurogenesis that was obtained from the above explant systems to a livingembryo, we used an AC transplantation system. Tissues of the dorsalectoderm, which is the prospective neuroectoderm (from 30° dorsalof the intermediate vertical line of the animal pole to just abovethe dorsal lip), were removed from stage 10 embryos. The vacantarea in the embryos was covered immediately with the AC expressingXFD or $beta$ -gal. The grafted embryos were allowed to develop to stage30. This system avoided the influence of XFD on the dorsal mesoderm(the source of neural inducers in vivo). Some injected embryoswere not dissected but were allowed to develop as nontransplantationcontrols. The embryos grafted with $beta$ -gal-expressing ACs (Fig.5A) developed in a similar manner to $beta$ -gal RNA-injected embryos(data not shown). The XFD-AC-grafted embryos completed gastrulationnormally with a closed blastopore at neurula stage, whereas theXFD-injected embryos failed to complete gastrulation with an openblastopore (data not shown) as described by Amaya et al. (1991).At tail bud stage, the XFD-AC-grafted embryos lacked the posteriortrunk (Fig. 5B), similar to XFD-injected embryos (Amaya et al.,1991). This suggests that XFD selectively expressed in the transplantedneuroectoderm also leads to posterior body truncation similarto that of XFD expressed ectopically. However, analysis of molecularmarkers suggested that muscle tissue still developed in the XFD-AC-graftedembryos. As shown in Figure 5C, expression of NCAM and posteriorneural makers Krox20 and HoxB9 (but not anterior neural markersOtx2 and En2) was attenuated by XFD in both AC-grafted and nongraftedembryos, whereas expression of the dorsal marker muscle actin(Stutz and Spohr, 1986) and the posterior mesodermal marker chordinthat is expressed exclusively in the posterior notochord and tailbudhinge (Sasai et al., 1994) was inhibited only in XFD-injectedembryos but not in XFD-AC-grafted embryos. This implies that agraft of the XFD AC did not affect dorsal and posterior mesodermdevelopment in the embryo, and posterior body axis truncationonly resulted from the inhibition of posterior neural tissue byXFD. This model, therefore, may best reflect the physiologicalrole of FGF in the neuroectoderm: posteriorization of the CNS.
Fig. 5. XFD inhibits posterior neural tissue in vivo. Two animal blastomeres of donor embryos were injected with 2 ng of XFD or control $beta$ -gal RNA at the two-cell stage. ACs were dissected from the injectedembryos at stage 8 and transplanted to the site of neuroectodermin recipient stage 10 embryos (+TP), which were allowed to developto stage 30. Some XFD or $beta$ -gal RNA-injected embryos were not dissectedand were allowed to develop to stage 30 as nontransplantationcontrols ( $-$ TP). Then, all embryos were harvested for photography(A, B) or RT-PCR analysis to detect expression of NCAM, Otx2,En2, Krox20, HoxB9, actin, chordin, and EF-1 $alpha$ (C). A, $beta$ -Gal and+TP; B, XFD and +TP. Photographs for XFD and $-$ TP and for $beta$ -galand $-$ TP are not shown.
[View Larger Version of this Image (71K GIF file)]

DISCUSSION

FGF is required for neural induction and posteriorization
To date, all known neural-inducing agents, including DN-BR, noggin, follistatin, and chordin, only induce an anterior typeof neural tissue in ectodermal explants (Lamb et al., 1993; Hemmati-Brivanlouet al., 1994; Hawley et al., 1995; Sasai et al., 1995; Xu et al.,1995). The mechanism by which the posterior neural tissue is formedremains primarily unknown. Although bFGF does not induce neuraltissue in AC cells, blockage of FGF signaling by XFD attenuatedneurogenesis induced by noggin and DN-BR (Fig. 4A). But we failedto see inhibition of expression of anterior neural marker Otx2by XFD (Fig. 4B), a result different from that reported by Launayet al. (1996). A likely explanation, as suggested above, attributesthis controversy to different XFD doses injected by differentinvestigators. FGF signaling may generally be required for neuralinduction as well as for posteriorization. Theoretically, cellsof an anterior neural type if not posteriorized should remainin the anterior type. However, expression of the epidermal markerXK81 but not the anterior neural marker Otx2 was enhanced by XFDat the expense of the posterior neural tissue (Figs. 4A, 5C),suggesting that FGF-posteriorized cells can be derived from adifferent group of cells rather than directly from the anteriorcells; they are epidermalized if not instructed otherwise.

Additional evidence of the posteriorizing activity of FGF comes from the findings by Taira et al. (1997) that the embryonicFGF-inducible gene Xbra (Smith et al., 1991; Isaacs et al., 1994)can posteriorize the anterior neural tissue induced by the activatedform of the organizer homeobox gene Xlim-1 (Taira et al., 1994).Thus, although FGF alone does not initiate neurogenesis, it maywork in concert with neural inducers to induce posterior neuraltissue. Factors with this posteriorizing activity have long beensought since the proposition of the two-step neural-patterningmodel (Nieuwkoop et al., 1952; Saxén and Toivonen, 1961), forwhich FGF has been suggested as a top candidate (Doniach, 1995;Sasai and De Robertis, 1997). However, opposite results negatingthe role of FGF in neural development have been reported by Krolland Amaya (1996); they found that transgenic embryos with XFDcontain well patterned nervous systems despite the severe defectof mesoderm development. This controversy may be (1) because theXFD expression by a transgene may not be sufficient to inhibitneuralization; or (2) because of different sensitivities to XFDbetween neuralization and mesodermalization (the latter may bemore sensitive to XFD).

FGF posteriorizes neural tissue independent of mesoderm
FGF has been found to signal through proto-oncogenes Ras, Raf-1, MAPK, and AP-1 and to be responsible for the formation ofthe posterior mesoderm (Whitman and Melton, 1992; MacNicol etal., 1993; Isaacs et al., 1994; LaBonne et al., 1995; Umbhaueret al., 1995; Dong et al., 1996). It has been shown that posteriordorsal mesoderm has caudalizing activity on prospective anteriorneural tissue (Cox and Hemmati-Brivanlou, 1995). Therefore, demonstrationof whether FGF caudalizes the anterior neural tissue requiresa mesoderm-free system.

By using the conjugated and aged AC explants, we have shown that XFD can inhibit expression of the midbrain-hindbrain boundarymarker En2 (Fig. 4B). In the in vivo system, XFD selectively expressedin ACs grafted in place of neuroectoderm also inhibited expressionof En2 as well as of hindbrain marker Krox20 and spinal cord markerHoxB9, leaving mesodermal development unaffected (Fig. 5). Onthe other hand, addition of bFGF into cultures of stage 10.5 ACsexpressing DN-BR or chordin induced expression of Krox20 and HoxB9but not of the dorsal mesodermal marker muscle actin (Fig. 3).These results suggest that FGF acts directly on neural tissueto promote posteriorization.

New models used in these studies
As mentioned above, we used conjugated blastula stage ACs and cultured them to the gastrula stage before exposing them tobFGF to reduce the possibility of BMP-4 diffusion from the explants.The use of this system is therefore a more direct approach toaddressing the FGF effect than is the use of slow-healing AC explantsor dispersed AC cells. More importantly, we extended our studyfrom the in vitro system to an in vivo system by using a novelAC transplantation system, which seemed to be physiologicallysignificant in elucidating the role of endogenous FGF signaling.

There are only a few reported embryonic systems used for the study of neural development. The AC explant culture and dispersedAC cell culture are two frequently used in vitro systems. However,results derived from these model systems are often not very conclusive.It is difficult to address the physiological significance of theresults because of the existence of complex interactions betweenthe neuroectoderm and its neighboring tissues, such as dorsalmesoderm, ventral ectoderm, ventral mesoderm, and endoderm. Inthese in vitro systems, not only are all of these interactionsignored, but the vertical and planar signals present within theneural tissue are also aberrant (in AC explants) or absent (indissociated AC cells). Therefore, the need for establishment ofan in vivo embryonic system to study neurogenesis has become important.

One major concern for establishing an in vivo system is to exclude the influence of tested agents on the development of dorsalmesoderm, because defect of the dorsal mesoderm can also leadto abnormality of neural induction and patterning. One way isinjection of a single target cell in 32-cell-stage embryos tospecifically express a gene of interest in a neural progenitorcell such as A1. However, not all A1 daughter cells will differentiateto neurons; some, although a small fraction, will participatein the formation of dorsal mesodermal tissues (Dale and Slack,1987; Moody, 1987). Therefore, the involvement of the dorsal mesodermcannot be completely eliminated. Another classic method for invivo studies is implantation of ectodermal folds into the dorsalectoderm of gastrula embryos in which the folds are induced toform neural tissue and can be assayed for their A-P properties(Nieuwkoop et al., 1952). However, there is not full contact betweenthe implanted ectoderm explant (AC) and the dorsal mesoderm; therefore,it is hard to mimic all functions of neural-inducing signals travelingbetween the tissues.

In our studies, ACs were transplanted flatly to the site of the neuroectoderm, coming into full contact with the involutingdorsal mesoderm, and thus should best reflect the physiologicalprocess. This system also avoided the influence of XFD on thedorsal mesoderm, providing a more specific and direct approachto understanding the role of FGF in neural differentiation. Therefore,with this in vivo system, as well as with the conjugated and agedAC system, our paper demonstrates advances in techniques for studyingXenopus neurogenesis in addition to the role of FGF in neurogenesis.

FOOTNOTES

Received Jan. 28, 1997; revised June 9, 1997; accepted July 1, 1997.

This work was partly supported by the Shiffman Program for Clinical and Basic Research between Bar Ilan University of Israeland the National Cancer Institute of the United States. We thankDr. R. M. Harland for the noggin cDNA and protein and Drs. Y.Sasai and E. M. De Robertis for the chordin cDNA. We also thankDr. D. L. Newton for synthesis of the oligonucleotides used inthe RT-PCR experiments and Dr. Magaret Beckwith and Mrs. AnnieRogers for editing this manuscript.

Correspondence should be addressed to Dr. Hsiang-fu Kung, Laboratory of Biochemical Physiology, Building 567, Room 152, Frederick,MD 21702-1201.

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Copyright ©1997 Society for Neuroscience   0270-6474/1997/176892-07$05.00/0

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