Multiple points of interaction between retinoic acid and FGF signaling during embryonic axis formation

doi:10.1242/dev.01129

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):

Home Help Feedback Subscriptions Archive Search Table of Contents

First published online 5 May 2004
doi: 10.1242/dev.01129

Development 131, 2653-2667 (2004)
Published by The Company of Biologists 2004

This Article

	Summary
	Figures Only
	Full Text (PDF)
	All Versions of this Article: dev.01129v1 131/11/2653 most recent
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Email this article to a friend
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager


Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Shiotsugu, J.
	Articles by Blumberg, B.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Shiotsugu, J.
	Articles by Blumberg, B.

Multiple points of interaction between retinoic acid and FGF signaling during embryonic axis formation

Jason Shiotsugu¹^,*, Yu Katsuyama¹^,*^,, Kayo Arima¹, Allison Baxter¹, Tetsuya Koide¹, Jihwan Song², Roshantha A. S. Chandraratna³ and Bruce Blumberg¹^,

¹ Department of Developmental and Cell Biology, University of California, Irvine, CA 92697-2300, USA
² Laboratory of Stem Cell Biology, Cell & Gene Therapy Research Institute, Pochon CHA University College of Medicine, Seoul 135-081, Korea
³ Retinoid Research, Departments of Chemistry and Biology, Allergan, Irvine, CA 92623, USA

Author for correspondence (e-mail: blumberg{at}uci.edu)

Accepted 17 February 2004

SUMMARY

TOP
SUMMARY
Introduction
Materials and methods
Results
Discussion
REFERENCES

Anteroposterior (AP) patterning of the developing CNS is crucialfor both regional specification and the timing of neurogenesis.Several important factors are involved in AP patterning, includingmembers of the WNT and FGF growth factor families, retinoicacid receptors, and HOX genes. We have examined the interactionsbetween FGF and retinoic signaling pathways. Blockade of FGFsignaling downregulates the expression of members of the RAR signalingpathway, RAR ${alpha}$ , RALDH2 and CYP26. Overexpression of a constitutivelyactive RAR ${alpha}$ 2 rescues the effects of FGF blockade on the expressionof XCAD3 and HOXB9. This suggests that RAR ${alpha}$ 2 is required as adownstream target of FGF signaling for the posterior expressionof XCAD3 and HOXB9. Surprisingly, we found that posterior expressionof FGFR1 and FGFR4 was dependent on the expression of RAR ${alpha}$ 2.Anterior expression was also altered with FGFR1 expression beinglost, whereas FGFR4 expression was expanded beyond its normalexpression domain. RAR ${alpha}$ 2 is required for the expression of XCAD3and HOXB9, and for the ability of XCAD3 to induce HOXB9 expression.We conclude that RAR ${alpha}$ 2 is required at multiple points in theposteriorization pathway, suggesting that correct AP neuralpatterning depends on a series of mutually interactive feedbackloops among FGFs, RARs and HOX genes.

Key words: Retinoic acid, FGF, Xenopus, XCAD3

Introduction

TOP
SUMMARY
Introduction
Materials and methods
Results
Discussion
REFERENCES

Anteroposterior (AP) patterning of the developing neural tubeis a crucial early step in the generation of the vertebratenervous system. The isolated animal pole (animal cap) of a blastulastage Xenopus embryo forms epidermal tissue when cultured, althoughdissociated animal cap cells will express neural markers (Sato,1989). Animal caps cultured in the presence of molecules normallyexpressed in Spemann's Organizer such as noggin, follistatinor chordin become neuralized in the absence of mesoderm induction (Hawleyet al., 1995; Hemmati-Brivanlou et al., 1994; Hemmati-Brivanlouand Melton, 1994; Holley et al., 1995; Lamb et al., 1993). Theseneural inducers are required in the ectoderm to block activityof BMP-4, a secreted TGFß growth factor superfamilymember (Hawley et al., 1995; Holley et al., 1995; Xu et al.,1995) that normally acts to repress neural fate. Organizer-expressedneural inducing genes neutralize BMP activity by directly bindingto them, thereby blocking BMP inhibition of neural fate (Fainsodet al., 1997; Piccolo et al., 1996; Zimmerman et al., 1996).

The direct neural inducers described above generate neural tissueof anterior character (Hawley et al., 1995; Hemmati-Brivanlouet al., 1994; Hemmati-Brivanlou and Melton, 1994; Holley et al.,1995; Lamb et al., 1993). These findings support the activation-transformationmodel of neural patterning wherein the initial basal state ofthe neural ectoderm is anterior with additional factors beingrequired to generate the posterior parts of the nervous system(Eyal-Giladi, 1954; Nieuwkoop, 1952). The major components ofthe activation signal are FGF and WNT signals that act beforegastrulation to induce the organizer to secrete inhibitors ofBMP and WNT signaling such as noggin, chordin, cerberus, follistatinand dickkopf during gastrulation (reviewed by Harland, 2000).In turn, these induce the neuroectoderm to adopt an anteriorfate.

The transformation signal has been more elusive and is onlyrecently becoming better understood. It has previously beenshown that basic fibroblast growth factor (bFGF, FGF2) couldposteriorize anterior neuroectoderm in vitro, suggesting anendogenous role for FGFs in neural induction and patterning (Coxand Hemmati-Brivanlou, 1995; Kengaku and Okamoto, 1995; Lamband Harland, 1995) (reviewed by Doniach, 1995). eFGF (FGF4)overexpression posteriorizes the axis via induction of downstreamgenes Xcad3 and Hoxa7 in vivo (Pownall et al., 1996); and inhibitionof FGF signaling via overexpression of the dominant-negativeFGF receptor 1, XFD, reduced the expression of the posteriormarkers HOXA7 and XCAD3 (Pownall et al., 1996). Papalopulu andcolleagues have shown that FGF8 acting through FGFR4 (rather thaneFGF acting through FGFR1) is likely to be the major FGF pathwayin neural posteriorization (Hardcastle et al., 2000).

We and others have shown that signaling through retinoic acidreceptors (RARs) is necessary for correct AP patterning. Hindbrainand posterior patterning is abnormal in vitamin A-deficientquail (Maden et al., 1996) and rats (Dickman et al., 1997; Whiteet al., 1998), and these defects can be reversed by appropriatetemporal administration of retinoic acid (RA). We used overexpressionof a dominant-negative RAR to show that signaling through RARsis required for the expression of the posterior markers HOXB9,N-tubulin and XLIM1 (Blumberg et al., 1997). Positional changeswere observed in the hindbrain along with posterior coordinateshifts in the expression of anterior markers. By contrast, locally increasingRAR signaling yielded the opposite result (Blumberg et al.,1997). Others showed that retinoid signaling was required tospecify positional identity in the hindbrain (Kolm et al., 1997;van der Wees et al., 1998). Overexpression of the Xenopus retinoicacid hydroxylase (CYP26), which targets RA for degradation,leads to expansion of anterior structures (de Roos et al., 1999;Hollemann et al., 1998), whereas inhibition of CYP26 expressionled to expansion of posterior structures (Kudoh et al., 2002).Overexpression of the RA biosynthetic enzyme RALDH2 led to reductionof anterior structures (Chen et al., 2001). RALDH2 loss of functionled to a variety of axial defects in mice, including axial shortening,loss of posterior rhombomere identity, limb buds and a varietyof retinoic acid inducible molecular markers (Niederreitheret al., 1999). Lumsden and colleagues recently showed that RAis the endogenous transforming factor active during hindbrainpatterning and that it acts in a concentration-dependent fashionto specify the identity of rhombomeres 5-8 (Dupe and Lumsden,2001). Together, these results indicate that retinoid signalingthrough RARs is essential for correctly restricting the expressionof anterior genes, and to enable the expression of posteriormarker genes. It should also be noted that RA could posteriorizeanterior neuroectoderm injected with XFD, whereas FGF couldnot (Bang et al., 1997). Therefore, both retinoid and FGF signalingcan posteriorize anterior neural tissue in vitro, perhaps actingsynergistically, as was suggested previously based on transplantationexperiments (Cho and De Robertis, 1990).

A role for WNT signaling in posteriorizing the embryonic axishas been suggested by studies showing that overexpression ofXWNT3A posteriorized anterior neuroectoderm (McGrew et al.,1997; McGrew et al., 1995). Blockade of XWNT8 signaling causedloss of posterior fates (Bang et al., 1999; Fekany-Lee et al.,2000; McGrew et al., 1997), whereas inappropriate activationof WNT target genes caused by loss of the headless/Tcf3 generesulted in severe anterior defects in zebrafish (Kim et al.,2000). The combination of ectopic FGF or WNT signaling and suppressionof RA by overexpression of CYP26 has been shown to leave thepresumptive neuroectoderm without any AP identity (Kudoh etal., 2002). Loss-of-function and genetic analysis has shownthat WNT8 is an important transforming factor in zebrafish andXenopus, and that either WNT8, or a factor crucially dependenton WNT8 for its expression is an endogenous neural transformingfactor (Erter et al., 2001; Lekven et al., 2001). It has recentlybeen shown that WNT8 signaling is required, together with BMPand nodal, for formation of the tail organizer in zebrafish (Agathonet al., 2003). Krumlauf and colleagues recently showed thatthe WNT/ß-catenin pathway posteriorizes Xenopus neuraltissue via an indirect mechanism requiring FGF signaling, suggestingthat the posteriorization pathway might be WNT $->$ FGF $->$ XCAD3 $->$ posteriorHOX genes (Domingos et al., 2001). This model does not accountfor the observation that inhibiting RAR signaling blocks theexpression of posterior neural markers, while FGF and WNT signaling arepresumably normal (Blumberg, 1997; Blumberg et al., 1997). Therefore,we aimed to determine where RAR signaling fits into the schemeof neural posteriorization.

We hypothesized that as both FGF (Isaacs et al., 1998; Pownallet al., 1996) and retinoid signaling (Blumberg et al., 1997)are required for the expression of posterior markers, these pathwaysmight converge on one or more common target genes. XCAD3 is akey downstream gene in the FGF-mediated posteriorization pathway (Isaacset al., 1998; Pownall et al., 1996) and retinoids have beenshown to influence the expression of caudal family genes inother systems (Allan et al., 2001; Houle et al., 2000; Prinoset al., 2001). Therefore, we tested the effects of modulatingretinoid signaling on the expression of XCAD genes. XCAD3 isupregulated by increasing RAR signaling and downregulated byinhibiting RAR signaling or the expression of RAR ${alpha}$ . Morpholinoantisense oligonucleotide (MO) mediated inhibition of RAR ${alpha}$ 2 expressionled to loss of XCAD3 and HOXB9 expression, confirming that RARsare required for posterior gene expression. Epistasis experimentsshowed that FGF8 overexpression could not rescue the effectsof RAR loss of function on XCAD3 or HOXB9 expression. However, overexpressionof a constitutively active RAR (but not RA treatment) rescuedthe effects of FGF gene loss of function on XCAD3 and HOXB9.This suggests that FGF signaling is not downstream of RAR signalingbut that RAR might be downstream of FGF. FGF receptor functionwas required for the expression RAR ${alpha}$ , RALDH2 and CYP26 in wholeembryos, and FGF8 microinjection induced expression of RAR ${alpha}$ ,CYP26 and RALDH2 in the animal cap assay. Taken together, theseresults suggest that RAR is downstream of FGF signaling. However,we also found that RAR is required for the correct expressionof FGF8, FGFR4 and FGFR1, and that RA induces expression ofFGF8, FGFR1 and FGFR4 in animal caps, arguing against a simplelinear pathway. Co-injection of XCAD3 mRNA and an MO directedagainst RAR ${alpha}$ 2.2 (RAR-MO) showed that regulation of HOXB9 expressionby XCAD3 requires RAR ${alpha}$ 2 function, thus placing RAR ${alpha}$ 2 both upstreamand downstream of XCAD3. Last, we show that XCAD3 expressionrequires RAR function for its correct expression at stage 16but not at stage 26. These data suggest the existence of a mutuallyreinforcing feedback loop among FGF8/FGFR4, XRAR ${alpha}$ and XCAD3.Thus, it appears that RAR signaling is required at multiplesteps in the embryonic posteriorization pathway, suggestingthat RAR and FGF signaling have multiple points of interactionrather than being in a simple linear pathway.

Materials and methods

TOP
SUMMARY
Introduction
Materials and methods
Results
Discussion
REFERENCES

Embryos
Xenopus eggs were fertilized in vitro as described (Koide etal., 2001) and embryos staged according to Nieuwkoop and Faber (Nieuwkoopand Faber, 1967). Treatments with RAR agonists and antagonistswere performed as described (Blumberg et al., 1996; Blumberget al., 1997; Koide et al., 2001).

Microinjection
Morpholino antisense oligonucleotides (MO) used in this studywere the following: XRAR ${alpha}$ 2.1, AAC TGA CCA TAG AGT GGA ACC GAG C;XRAR ${alpha}$ 2.2, ATC CAA AGG AAG GTG AGT GTG TGT G. In all experimentsusing MO, control embryos were injected with 20 ng of standard controlMO CCT CTT ACC TCA GTT ACA ATT TAT A (GeneTools). The following plasmidswere constructed by PCR amplification of the protein-codingregions of the indicated genes and cloning into the expressionvector pCDG1 or pCDG1-VP16: XRAR ${alpha}$ 2.2 (Sharpe, 1992) and XCAD3(Northrop and Kimelman, 1994). mRNA was prepared from theseplasmids as well as pSP36T-XFD (Amaya et al., 1993) and pCS2-FGF8(Hardcastle et al., 2000) using mMessage Machine (Ambion).

Whole-mount in situ hybridization
Whole-mount in situ hybridization was performed as described (Koideet al., 2001). Probes used in this study were the following:HOXB9 (Sharpe et al., 1987), XCAD1, XCAD2 (Blumberg et al., 1991)XCAD3 (Northrop and Kimelman, 1994), RAR ${alpha}$ (Blumberg et al., 1992), FGF8(Hardcastle et al., 2000), FGFR4 (Hongo et al., 1999), FGFR1(Amaya et al., 1993), XRALDH2 (Chen et al., 2001) and CYP26(de Roos et al., 1999). Lineage analysis using 100 pg/embryoof ß-galactosidase was performed as described (Blumberget al., 1997), except that the chromogenic substrate was 5-bromo-6-chloro-3-indolyl ß-D-galactopyranoside(magenta-gal, Biosynth AG), which produces an insoluble redprecipitate after cleavage by ß-galactosidase (Sambrookand Russell, 2001).

QRT-PCR
Embryo RNA was isolated using Trizol reagent (InVitrogen Life Technologies),DNAse treated and LiCl precipitated, then reverse transcribed usingSuperscript II reverse transcriptase according to the manufacturer-suppliedprotocol (InVitrogen Life Technologies). QRT-PCR was performedas described (Tabb et al., 2003) using the following primersets: FGF8, 5' AATCCTGGCGAACAAGAAGA and 3' TAACCAGTCTCCGCACCTTT;FGFR4, 5' GCCAGCTGGTAACACAGTCA and 3' TGATGGAACCACACTCTCCA;eFGF, 5' GTTTTACCGGACGGAAGGAT and 3' TCCATACAGCTTCCCCTTTG; FGFR1,5' GGTGTCCAGCAAATGGAACT and 3' ATGGGACAACGGAATCCATA; XCAD1,5' CAGCCTTGTGTTGGGGTATT and 3' GGTTTCCTGAGCCATTCGTA; XCAD2,5' ACCAGCGCCTTGAATTAGAA and 3' GAGTGGTTGTTGAGGCCTGT; XCAD3,5' AAGGGCAGCCTATGGAGTTT and 3' GTCCCAGATGGATGAGGAGA; XRAR ${alpha}$ , 5'ATCAAGACGGTGGAATTTGC and 3' CAGTCCGTCAGAGAACGTCA; RALDH2, 5'GCCCTTTTGATCCCACTACA and 3' TCTTCCCAATGCTTTTCCAC; CYP26, 5'TGTTCGTGGTGGAATTGTGT and 3' TTAGCGGGTAGGTTGTCCAC; Histone H4,5' AACATCCAGGGCATCACCAA and 3' AGAGCGTACACCACATCCAT.

Each primer set was found to amplify only a single band as determinedby gel electrophoresis and melting curve analysis.

Results

TOP
SUMMARY
Introduction
Materials and methods
Results
Discussion
REFERENCES

Expression patterns of RAR ${alpha}$ in early Xenopus development
RAR ${alpha}$ is expressed as two major isoforms during early development,XRAR ${alpha}$ 1 and XRAR ${alpha}$ 2 (Sharpe, 1992). These isoforms are the resultof alternative promoter usage in most vertebrates (reviewedby Chambon, 1996). Both RAR ${alpha}$ 1 and RAR ${alpha}$ 2 are expressed maternally;however, only RAR ${alpha}$ 2 is expressed zygotically in Xenopus (Blumberg etal., 1992; Koide et al., 2001; Sharpe, 1992). XRAR ${alpha}$ 2 is expressedas two different forms, XRAR ${alpha}$ 2.1 and XRAR ${alpha}$ 2.2 that are presumablythe product of the pseudotetraploid nature of the Xenopus laevisgenome (Sharpe, 1992). We performed a detailed analysis of thetemporal and spatial expression of XRAR ${alpha}$ using whole-mount insitu hybridization. Although, the probe used for in situ hybridizationcan detect all isoforms of RAR ${alpha}$ , its temporal expression patternindicates that the detected signal is derived from XRAR ${alpha}$ 2 (Koideet al., 2001; Sharpe, 1992). Zygotic expression of RAR ${alpha}$ 2 wasdetected at as early as stage 9 and by stage 10 as a faint signalin the involuting surface layer surrounding the blastopore (Fig. 1E),and became stronger as gastrulation proceeded (Fig. 1G,I) (Koideet al., 2001). During neurula stages (stage 14-18), RAR ${alpha}$ expressionwas detected predominantly in the posterior neural tube withweaker staining throughout the embryo (Fig. 1B,D,F,H). As previouslyreported (Sharpe, 1992) the strong staining of XRAR ${alpha}$ 2 has a sharpanterior border (Fig. 1J). Lower level expression continuesanteriorly with prominent later expression in the developingeyes (Fig. 1J).

View larger version (71K):
[in this window]
[in a new window]

Fig. 1. Developmental expression of XRAR ${alpha}$ . Whole-mount in situ hybridization was performed on embryos from stage 9 to stage 25 using a probe that recognizes all isoforms of XRAR ${alpha}$ . (A) Dorsal (left) and ventral (right) view of a stage 9 embryo. (B,D,F,H,J) Frontal views. (C) A dorsal view of the stage 10 embryo. (E) A vegetal view of the stage 10 embryo. Note the sharp anterior border of strong staining.

RAR ${alpha}$ loss-of-function causes anterior and posterior truncations
To investigate the function of RAR ${alpha}$ 2, we used morpholino antisense oligonucleotide-mediatedloss-of-function analysis (Heasman et al., 2000

; Koide et al.,2001

). MO were prepared to specifically inhibit the expressionof either XRAR ${alpha}$ 2.1 or XRAR ${alpha}$ 2.2. Microinjection of the XRAR ${alpha}$ 2.1MO was nontoxic and did not elicit a phenotype at doses up to20 ng/embryo (data not shown). By contrast, microinjection ofthe XRAR ${alpha}$ 2.2 MO (hereafter RAR-MO) affected both anterior andposterior development in the Xenopus tadpole (Fig. 2) (Koideet al., 2001

). Injection of the RAR-MO into both blastomeresof the two-cell embryo produced a dose-dependent spectrum ofphenotypes; microinjection of 10 ng RAR-MO/embryo consistentlygave rise to observable phenotypes with varying severity (Fig. 2A-C).We used co-injection of ß-galactosidase lineagetracer to correlate the observed phenotypes with RAR-MO distributionand found that the phenotypic variation was related to the distributionof the RAR-MO in the affected embryos. The most severe phenotypeswere observed when the RAR-MO was distributed dorsally (n=41/50)(Fig. 2A). Mild phenotypes resulted when the RAR-MO was widelydistributed (n=6/50) (Fig. 2b) and no abnormalities were observedwhen the lineage tracer was observed in the ventral or lateralparts of the embryo (n=3/50) (Fig. 2c). This lack of a phenotypefrom lateral or ventral distribution of the lineage tracer was confirmedby targeted injection into the marginal zone of the two-cellstage embryos (n=19/21) (not shown). These observations suggestthat XRAR ${alpha}$ 2.2 function is predominantly required for developmentof the dorsal parts of the Xenopus embryo, consistent with thezygotic expression pattern of this gene (Fig. 1) (Koide et al.,2001

; Sharpe, 1992

). Co-injection of 1 ng RAR ${alpha}$ 2 mRNA with RAR-MOconsistently rescued the morphological abnormalities (Fig. 2D) (Koideet al., 2001

). Doses higher than 20 ng of RAR-MO/embryo werelethal and injection of more than 10 ng per embryo could notbe rescued by co-injection of the rescue construct. Therefore,we used 10 ng of RAR-MO and 1 ng of rescue construct per whole embryo(or 5 ng of RAR-MO for unilateral injections) for the experiments describedbelow.

View larger version (78K):
[in this window]
[in a new window]

Fig. 2. XRAR ${alpha}$ 2.2 loss-of-function leads to axial truncations and reduction of HOXB9 expression. (A-D) Microinjection of RAR-MO causes anterior and posterior truncations at highest frequency when expressed in the head region (A) or dorsally (B). (C) Phenotypes are mild to undetectable when the lineage tracer is distributed laterally or ventrally. (D) Phenotypes are rescued by co-injection of XRAR ${alpha}$ 2 mRNA, irrespective of where the lineage tracer is located. (E,F) Neither XBRA (E) nor XWNT8 (F) expression is affected by RAR-MO injection. (G-K) Effects of RAR-MO on the expression of HOXB9. (H-J) The types of phenotypes obtained. (K) HOXB9 expression was restored by co-injecting XRAR mRNA and RAR-MO.

XRAR ${alpha}$ is expressed in the region surrounding the blastopore ingastrulating embryos (Fig. 1E,G), overlapping the reported expressionpatterns of XWNT8 and XBRA (Christian and Moon, 1993

; Smithet al., 1991

). Therefore, we examined XWNT8 and XBRA expressionin RAR-MO-injected embryos because embryos lacking either ofthese genes showed posterior truncations similar to those wefound (Conlon et al., 1996

; Hoppler et al., 1996

). Embryos wereco-injected with 5 ng RAR-MO and 100 pg ß-galactosidasemRNA lineage tracer unilaterally at the two-cell stage, allowedto develop until stage 11 then fixed and processed for in situhybridization. Expression of XWNT8 and XBRA were not alteredin the ß-galactosidase positive regions of the embryo(Fig. 2E,F) indicating that XRAR ${alpha}$ 2.2 is not required for their expression.Therefore, it is unlikely that the posterior truncations elicited bydownregulating XRAR ${alpha}$ 2.2 expression with the RAR-MO resulted fromeffects on XWNT8 or XBRA expression.

We have previously shown that overexpression of a dominant negative RAR ${alpha}$ 1suppressed expression of the spinal cord marker, HOXB9 and theposterior markers XLIM1 and N-tubulin (Blumberg et al., 1997).As the dominant-negative RAR ${alpha}$ used in those experiments can alsoinhibit expression from RARß and RAR ${gamma}$ target genes (Blumberg,1997; Damm et al., 1993), we tested whether RAR ${alpha}$ was requiredfor HOXB9 expression using RAR-MO injected embryos. Five or10 ng of RAR-MO were injected bilaterally into the animal poleof two-cell embryos that were allowed to develop until stage18 then fixed for whole-mount in situ hybridization. HOXB9 expression wasinhibited in a dose-dependent manner (Fig. 2H-J) and showeda range of phenotypes that could be classified into three groups.Class I embryos (n=5/23 for 5 ng MO, n=0/30 for 10 ng MO) showedweaker HOXB9 staining than controls (Fig. 2G) and the presumptiveposterior neural tube region (marked by HOXB9 expression) waswider than that of control embryos (Fig. 2H). HOXB9 expressionin class II embryos (10/23 for 5 ng MO, 5/30 for 10 ng MO) was weakeryet and the expression boundary was shifted posteriorly (Fig. 2I).Class III embryos expressed HOXB9 only in the posteriorterminus of the embryo (5/23 for 5 ng MO, 25/30 for 10 ng MO)(Fig. 2I). Complete suppression of HOXB9 expression by injectionof 10 ng RAR-MO was not obtained (n>100). Co-injection of1 ng XRAR ${alpha}$ 2 mRNA rescued HOXB9 expression (26/32 embryos werenormal, 6/32 were class I) (Fig. 2J). Based on these observations,we conclude that signaling through XRAR ${alpha}$ 2.2 is indispensablefor the expression of HOXB9, in accord with previous studiesusing a dominant-negative Xenopus RAR (Blumberg et al., 1997).

RA signaling is required for XCAD3 expression
The homeobox gene XCAD3 has been implicated in the posteriorizationpathway as a downstream target of eFGF (FGF4) signaling (Isaacset al., 1998; Pownall et al., 1998; Pownall et al., 1996). The embryonicexpression pattern of XCAD3 is strikingly similar to that ofHOXB9 (Northrop and Kimelman, 1994). We identified XCAD3 ina screen to identify RAR target genes (R. Niu and B. Blumberg,unpublished), which led us to hypothesize that XCAD3 might bea common target for retinoid and FGF signaling upstream of HOXB9.Two approaches were taken to investigate this possibility. First,embryos were treated with either the synthetic retinoid agonistTTNPB, which specifically activates all three subtypes of RAR orthe antagonist AGN193109, which specifically blocks the abilityof RARs to activate transcription (Koide et al., 2001). Thesereagents were chosen because they affect RARs but not RXRs (Boehmet al., 1994; Johnson et al., 1995). TTNPB treatment enhancedthe expression of XCAD3 in the posterior neural tube (Fig. 3M),whereas significant differences were not observed for XCAD1 (Fig. 3C)or XCAD2 (Fig. 3H) compared with control embryos. Conversely,AGN193109 treatment suppressed XCAD3 expression (Fig. 3K), butdid not alter expression of XCAD1 (Fig. 3A) or XCAD2 (Fig. 3F).QRT-PCR analysis showed that XCAD3 was slightly upregulatedby TTNPB (1.3-fold) and strongly downregulated by antagonist (2.5-fold).XCAD1 was downregulated by both TTNPB and 193109 (indicatinga non-specific effect on gene expression) and XCAD2 was slightlydownregulated by TTNPB (1.5 fold) but not affected by AGN193109(1.07 fold up) (data not shown).

View larger version (83K):
[in this window]
[in a new window]

Fig. 3. Modulating retinoid signaling affects the expression of XCAD3 but not XCAD1 or XCAD2. (A-C,F-H,K-M) Embryos were treated with the indicated compound or ethanol solvent controls from the early blastula stage (stage 7) until harvesting when control embryos reached stage 18. Embryos were fixed and processed for whole-mount in situ hybridization with the indicated probes. (A,F,K) 10^–6 M AGN193109 (RAR-selective antagonist), (B,G,L) ethanol solvent control, (C,H,M) 10^–6 M TTNPB (RAR-selective agonist). RAR-MO was injected unilaterally at the two-cell stage with ß-galactosidase lineage tracer alone (D,I,N) or together with 1 ng XRAR ${alpha}$ 2 mRNA (E,J,O). Embryos were fixed when controls reached stage 18, stained for ß-galactosidase activity and processed for whole-mount in situ hybridization with the indicated probes. Some embryos were used for RNA extraction and QRT-PCR analysis as described in the text.

We next tested the requirements for XRAR ${alpha}$ 2.2 signaling on XCADgene expression using RAR-MO mediated loss-of-function. Two-cellembryos were unilaterally injected with 5 ng RAR-MO and 100pg ß-galactosidase mRNA, fixed when controls reachedthe late neurula stage (stage 16-18), and stained for ß-galactosidaseactivity. Embryos exhibiting appropriate ß-galactosidasestaining were selected for in situ hybridization. XCAD3 expressionwas suppressed in 10/12 RAR-MO injected embryos (Fig. 3N) andwas rescued by co-injection of XRAR ${alpha}$ 2 mRNA (Fig. 3O). In agreementwith the retinoid treatments, expression of XCAD1 (n=12) and XCAD2(n=12) showed no significant differences between the injectedside and the uninjected contralateral control (Fig. 3D,E,I,J).These results indicate that only XCAD3 is regulated by RA inearly Xenopus embryos.

RA and FGF signaling converge on XCAD3
Slack, Isaacs and colleagues have shown that XCAD3 is a direct targetfor FGF signaling and that an important embryonic posteriorization pathwaybegins with eFGF (FGF4) activation of XCAD3, which induces expressionof HOXA7 and other posterior HOX genes (Isaacs et al., 1998; Pownallet al., 1996). They showed that XCAD3 was necessary and sufficientto activate posterior HOX genes (Isaacs et al., 1998). Our previousresults (Blumberg et al., 1997) and those described above showthat RAR signaling is also required for the expression of posteriormarkers such as HOXB9 and XCAD3. As both retinoid and FGF signalingappear to be important for the expression of posterior genes,we carried out epistasis experiments designed to reveal therelationship between RAR and FGF signaling.

bFGF (FGF2) treatment of neuralized Xenopus animal cap explantsinduces posterior gene expression (Bang et al., 1997; Papalopuluand Kintner, 1996). Recent publications suggested that FGF8is likely to be the bona fide posteriorizing FGF acting in theearly embryo (Christen and Slack, 1997; Hardcastle et al., 2000; Hongoet al., 1999); hence, we next tested the effects of microinjectingFGF8 mRNA, RAR-MO or both together. Bilateral microinjectionof 25 pg FGF8 mRNA into two-cell embryos led to ectopic andenhanced expression of XCAD3 and HOXB9 in anterior neural tissues(n=16/19; Fig. 4C,H). The observed anterior expansion of XCAD3and HOXB9 was similar to that observed for eFGF overexpression (Pownallet al., 1996). We next asked whether FGF signaling is downstreamof RAR signaling by testing whether FGF8 overexpression couldrescue the effects of the RAR-MO on posterior gene expression.Injection of RAR-MO (10 ng) suppressed expression of XCAD3 (n=8/11)and HOXB9 (n=10/11) (Fig. 4B,G). Co-injection of as much as50 pg of FGF8 mRNA could not rescue expression of either gene (n=10/11for each gene; Fig. 4D,I). Lineage traced, unilateral microinjectionsconfirmed this observation (Fig. 4E,J). Therefore, we inferthat FGF8 signaling is not downstream of RAR signaling.

View larger version (58K):
[in this window]
[in a new window]

Fig. 4. FGF8 cannot rescue the effects of XRAR ${alpha}$ 2.2 loss-of-function on posterior marker genes. Embryos were microinjected at the two-cell stage with the indicated reagents, allowed to develop until controls reached stage 18 and processed for whole-mount in situ hybridization with either HOXB9 (A-E) or XCAD3 (F-J) probes.

It has previously been shown that expression of a dominant-negativeFGF receptor 1 (FGFR1) mutant (XFD) in early Xenopus embryossuppressed expression of HOXB9 and XCAD3 (Pownall et al., 1998

).We confirmed this observation by microinjecting 1 ng XFD mRNAtogether with 100 pg of ß-galactosidase mRNA intoone blastomere of two- or four-cell embryos. Embryos were fixedand stained for ß-galactosidase activity when untreatedsiblings reached stage 18. XFD injection typically delays morphogenesisduring gastrulation and neurulation leaving the dorsal sideof the embryos open, showing endodermal cells that would otherwisebe covered by the mesodermal and ectodermal layers during gastrulaand neurula stages (Amaya et al., 1991

) (Fig. 5). As the closingedge of the ectodermal layer of XFD-overexpressing embryos isthe presumptive posterior neural tube region, we selected embryosshowing ß-galactosidase staining in this region forin situ analysis. HOXB9 and XCAD3 expression were unaffectedin the uninjected side whereas the neural tube region of theinjected side did not express either HOXB9 or XCAD3 (n=40/40) (Fig. 5A,D).Treatment of XFD-overexpressing embryos with 10^–6M all-trans-RA did not rescue expression of either HOXB9 or XCAD3in the injected side (n=12/12) (Fig. 5B,E). Co-injection of1 ng XRAR ${alpha}$ 2.2 mRNA with XFD partially rescued HOXB9 (n=4/10)and XCAD3 (n=2/10) expression (data not shown). Co-injectionof the constitutively active VP16-XRAR ${alpha}$ 2 (Blumberg, 1997

; Koideet al., 2001

) yielded nearly complete rescue of both HOXB9 (n=14/16)and XCAD3 (n=16/16) (Fig. 5C,F). Complete rescue by the constitutivelyactive (ligand-independent) RAR and partial rescue by the wild-typeRAR suggests that both the expression of XRAR ${alpha}$ 2.2 and the synthesisof RA are deficient in XFD injected embryos. These results suggestthat retinoid signaling through XRAR ${alpha}$ 2.2 is required for FGFsignaling to induce posterior genes in the neural ectoderm,which may place RAR downstream of FGF signaling in neural patterning.

View larger version (101K):
[in this window]
[in a new window]

Fig. 5. A constitutively active RAR, but not RA, can rescue the effects of FGF gene loss-of-function on posterior markers. Embryos were microinjected unilaterally at the two cell stage with ß-galactosidase mRNA as lineage tracer and (A,D) 1 ng of XFD mRNA, (B,E) 1 ng of XFD mRNA then treated with 10^–6 M atRA, or (C,F) 1 ng of XFD and 1 ng VP16-XRAR ${alpha}$ 2 mRNA. When control embryos reached stage 18, the embryos were fixed, stained for ß-galactosidase activity and processed for whole-mount in situ hybridization with either HOXB9 (A-C) or XCAD3 (D-F) probes.

FGF signaling is required for the expression of RA signaling pathway components
One possible explanation for the results described above isthat FGF signaling regulates the RAR signaling pathway. Therefore,we examined the effects of XFD-mediated FGF loss-of-functionon the expression of mRNAs encoding XRAR ${alpha}$ , the RA-synthesizingenzyme RALDH2 and the RA-degrading enzyme CYP26. Embryos werefixed at stage 11 and those showing ß-gal expressionin the region of the blastopore were selected for in situ analysis.As previously reported, XFD blocks XCAD3 expression at thisstage (Pownall et al., 1998

; Pownall et al., 1996

) (Fig. 6B).XRAR ${alpha}$ and XCAD3 are expressed in similar patterns at stage 11and we found that XFD also inhibits the expression of XRAR ${alpha}$ (Fig. 6d).Strikingly, XFD also led to the downregulation of RALDH2 (Fig. 6F)in the injected cells. These results are consistent withthe rescue experiments shown in Fig. 5. CYP26 is normally expresseddorsally and in the lateral mesoderm of gastrula embryos (deRoos et al., 1999

; Hollemann et al., 1998

). XFD did not inhibitthe dorsal expression of CYP26 but strongly inhibited it in thelateral and ventral regions of the embryo (Fig. 6H).

View larger version (66K):
[in this window]
[in a new window]

Fig. 6. FGF gene loss of function alters the expression of RAR signaling pathway components in microinjected embryos. Embryos were microinjected unilaterally into one blastomere at the two- or four-cell stage with 1 ng of XFD mRNA and ß-galactosidase mRNA as lineage tracer. Embryos were allowed to develop until controls reached stage 11 then fixed and processed for whole-mount in situ hybridization with the probes (A,B) XCAD3, (C,D) XRAR ${alpha}$ , (E,F) RALDH2 or (G,H) CYP26.

Another approach to show the dependence of RAR on FGF relieson the ability of FGF8 to modulate the expression of RAR pathwaycomponents in animal cap explants. Embryos were injected bilaterallyat the two-cell stage with 50 pg of mRNA encoding FGF8 and animalcaps were cut at or before stage 9 (Sive et al., 2000

). The isolatedanimal caps were either cultured in MBS or MBS containing 10^–6M all-trans RA and allowed to develop until untreated siblingsreached stage 18 when RNA was prepared from the caps. The expression ofXCAD3, XRAR ${alpha}$ 2, RALDH2, CYP26 and the control histone H4 wereevaluated using QRT-PCR in untreated caps whereas XCAD3, eFGF,FGF8, FGFR1 and histone H4 were evaluated in RA-treated caps (Fig. 7).FGF8 upregulated the expression of XCAD3, XRAR ${alpha}$ 2, RALDH2and CYP26 (Fig. 7A). Taken together with the loss-of-functionexperiments described above, this suggests that the expressionof components in the RAR signaling pathway, in vivo, dependson FGF signaling.

View larger version (16K):
[in this window]
[in a new window]

Fig. 7. FGF8 and RA induce members of the other signaling pathways in animal caps. Embryos were microinjected with mRNA encoding FGF8 mRNA. Caps were cut from FGF8 or control embryos at or before stage 9 and allowed to develop until untreated sibling embryos reached stage 20 in the presence or absence of 10^–6 M all-trans RA. RNA was prepared from the caps and control embryos and QRT-PCR analysis performed with the indicated primer sets. Experiments were performed in triplicate and reproduced in independent experiments (Student's paired t-test). P<0.03 for all data sets.

RAR ${alpha}$ regulates FGF signaling
Although it is clear from the results shown above that the expressionof RAR signaling pathway components requires FGF function, theeffects of removing FGF and RAR function were not identical(compare Fig. 2 with Fig. 5), which cannot be explained by asimple linear pathway. RA treatment led to upregulation of FGFR1,FGFR4 and FGF8 compared with controls in animal caps (Fig. 7B).We detected small amount of eFGF in whole stage 18 embryos butwere unable to detect it in animal caps (data not shown). Itis possible that RAR signaling is required for the initiationor maintenance of the components in the FGF pathway; therefore,we decided to test the effects of the RAR-MO on FGF signaling pathwaycomponents.

RAR-MO was unilaterally microinjected into two-cell embryostogether with ß-galactosidase lineage tracer. Embryoswere fixed when controls reached stage 18-20, stained for ß-galactosidaseactivity then processed for whole-mount in situ hybridization.The RAR-MO elicited an increase in the size and staining intensityof the anterior lateral epidermal crescent expression domainof FGF8 (Christen and Slack, 1997) (Fig. 8B), which was restoredby microinjection of XRAR ${alpha}$ 2 mRNA (Fig. 8C). Posterior expressionnear the blastopore was slightly enhanced and extended anteriorlyin RAR-MO injected embryos (Fig. 8E) and rescued by co-injectionof XRAR ${alpha}$ 2 mRNA (Fig. 8F). Overall, we observed relatively minor,but reproducible changes in the expression of FGF8 in RAR-MOinjected embryos.

View larger version (75K):
[in this window]
[in a new window]

Fig. 8. XRAR ${alpha}$ 2.2 loss-of-function alters the expression of FGF8, FGFR4 and FGFR1. Embryos were microinjected unilaterally with ß-galactosidase mRNA plus 10 ng RAR-MO or 10 ng RAR-MO plus 1 ng XRAR ${alpha}$ 2 mRNA. Embryos were fixed when control uninjected embryos reached stage 18, stained for ß-galactosidase activity and then processed for in situ hybridization with FGF8 (A-F), FGFR4 (G-L) or FGR1 (M-R) probes.

In contrast to the modest effects on FGF8 mRNA expression, RAR-MO injectionled to strong effects on FGFR4 and FGFR1 expression. In theanterior region, RAR-MO led to a lateral expansion of FGFR4with a concomitant loss of regional boundaries seen in control embryos(Fig. 8G) or in the uninjected contralateral side (Fig. 8H).Strikingly, posterior expression of FGFR4 in the spinal cordwas strongly inhibited by RAR-MO injection (Fig. 8K). FGFR1was strongly downregulated throughout the embryo by RAR-MO injection (Fig. 8N,Q).The effects of microinjecting the RAR-MO could be rescuedby co-injection of XRAR ${alpha}$ 2 mRNA, demonstrating its specificity (Fig. 8I,L,O,R).These results suggest that signaling through XRAR ${alpha}$ 2is required for the correct expression of these FGF signalingpathway components.

RA signaling is required both upstream and downstream of XCAD3
It has been suggested that posterior HOX genes are regulatedby caudal family genes based on the effects of XCAD3 loss offunction (Isaacs et al., 1998) and the identification of CDX-bindingmotifs in HOX gene promoters (Subramanian et al., 1995). Knockoutand transgenic mouse studies with caudal family genes showed alterationsin HOX gene expression (Charite et al., 1998; Subramanian etal., 1995). Posterior HOX genes are also known to be sensitiveto RA in cell culture (Simeone et al., 1991; Simeone et al.,1990; Simeone et al., 1995), and in mouse (Gavalas and Krumlauf, 2000;Kessel, 1992; Kessel and Gruss, 1991; Ogura and Evans, 1995a;Ogura and Evans, 1995b) and Xenopus embryos (Durston et al.,1998; Godsave et al., 1998; van der Wees et al., 1998). Onepossible inference that can be drawn from the experiments describedabove is that RAR regulates HOXB9 through the function of XCAD3,because XCAD3 expression requires XRAR ${alpha}$ (Figs 3, 4). However,those experiments do not rule out the possibility that RAR signalingdirectly regulates the expression of HOXB9 and perhaps otherHOX genes. Several known and putative retinoic acid responseelements have been identified in HOX genes (Dupe et al., 1997; Huanget al., 2002; Huang et al., 1998; Marshall et al., 1994; Oguraand Evans, 1995a; Zhang et al., 1997) suggesting that RAR mayact in concert with XCAD3 and perhaps other factors, insteadof acting upstream of XCAD3 within a strict hierarchy. Therefore,we examined this possibility by co-injecting the RAR-MO togetherwith XCAD3 mRNA. If XCAD3 is strictly downstream of XRAR ${alpha}$ 2 inthe regulation of HOXB9, microinjection of XCAD3 mRNA should rescuethe effects of RAR-MO on HOXB9. XCAD3 overexpression induced ectopicanterior neural expression of HOXB9 (n=8/8; Fig. 9C) as previouslyreported (Isaacs et al., 1998; Pownall et al., 1998). Injectionof the RAR-MO alone led to strong downregulation of HOXB9 together witha posterior shift in its expression boundary (Fig. 9B). Co-injectionof the RAR-MO and XCAD3 mRNA led to a substantial reductionin the intensity of HOXB9 staining compared with XCAD3 or controlembryos (n=10/10) (Fig. 9D,E) although HOXB9 expression wasnever completely eliminated. Unilateral injections confirmedthat HOXB9 expression was reduced by the RAR-MO, even in thepresence of overexpressed XCAD3 (Fig. 9F). These results suggestthat XRAR ${alpha}$ 2 is required both upstream and downstream of XCAD3.

View larger version (98K):
[in this window]
[in a new window]

Fig. 9. XRAR ${alpha}$ 2.2 is required for XCAD3-mediated upregulation of HOXB9. Embryos were microinjected with 10 ng RAR-MO (B), 1 ng XCAD3 mRNA (C) or 10 ng RAR-MO plus 1 ng XCAD3 mRNA (D-F), then allowed to develop until untreated embryos reached stages 18 (A-D,F) or 23 (E), fixed and processed for whole mount in situ hybridization with HOXB9.

Temporal requirement for RAR signaling in posterior gene expression
Although the results presented above clearly demonstrate thatRAR signaling is required for the expression of XCAD3 and HOXB9,there are published data from other laboratories suggestingthat retinoid signaling is not required for posterior gene expression(see Discussion). One possible explanation for these disparateresults is that posterior gene expression occurs in two phases.The first would require early retinoid signaling for the establishmentof posterior gene expression, whereas the second phase wouldbe retinoid independent. In this scenario, the stage at whichembryos are analyzed would play an important role in determiningwhether or not posterior markers were expressed. To test thispossibility, we treated embryos with either TTNPB or AGN193109continuously from the blastula stage (stage 9) and then evaluated XCAD3expression at early (stage 16) and late (stage 26) stages. In accordancewith our model, antagonist treatment led to a substantial downregulationof XCAD3 at stage 16 (Fig. 10I,J) whereas the expression ofXCAD3 appeared essentially normal at stage 26 (Fig. 10K,L).TTNPB treatment led to an increase in XCAD3 expression at stage16 (Fig. 10E,F), whereas the expression had normalized by stage26, save for the apparent loss of XCAD3 expression in the extremeposterior of the embryo (Fig. 10G,H). Interestingly, this isthe same region where CYP26 is normally expressed (Hollemannet al., 1998

). We infer from these results that the early expressionof XCAD3 requires retinoid signaling whereas later expressiondoes not.

View larger version (47K):
[in this window]
[in a new window]

Fig. 10. XCAD3 expression requires RAR at early but not late stages. Embryos were treated with either TTNPB (E-H) or AGN193109 (I-L) at the blastula stage and cultured until controls (A-D) reached the indicated stages, fixed and processed for in situ hybridization with XCAD3. (A,C,E,G,I,K) Lateral views; (B,D,F,H,J,L) dorsal views.

	Discussion

TOP SUMMARY Introduction Materials and methods Results Discussion REFERENCES

RA and FGF signaling in neural posteriorization
Activities of three distinct types of intercellular signalingpathways (WNTs, FGFs and retinoids) contribute to the transforming(posteriorizing) signal in Nieuwkoop's activation-transformationmodel. Loss-of-function analyses indicate that these factorsare all required for posterior patterning but the interrelationshipsand dependencies among the pathways were unclear. We focusedon the relationship between RA and FGF signaling in specifying posteriorneural structures. The observations that both FGF (Isaacs etal., 1998

; Pownall et al., 1996

) and retinoid signaling (Blumberget al., 1997

) are required for the expression of posterior HOXgenes led us to hypothesize that these pathways converge onone or more common target genes. XCAD3 is a key downstream genein the FGF-mediated posteriorization pathway and retinoids havebeen shown to influence the expression of caudal family genesin other systems (Allan et al., 2001

; Houle et al., 2000

; Prinoset al., 2001

), making XCAD genes likely targets for both retinoidand FGF signaling. Indeed, we found that modulating retinoidsignaling with RAR agonists or antagonists predictably alteredthe expression of XCAD3 (Fig. 3) and that RAR ${alpha}$ 2.2 is requiredfor the expression of XCAD3 (Figs 3, 4) and HOXB9 (Figs 2, 4).

Overexpression of the dominant-negative FGF receptor 1 (XFD)mRNA suppresses mesoderm formation (Amaya et al., 1993) andthe expression of posterior neural genes (Fig. 5) (Pownall etal., 1998; Pownall et al., 1996). Microinjection of the constitutivelyactive VP16-XRAR ${alpha}$ 2 completely rescued XCAD3 and HOXB9 expressionin XFD-injected embryos, whereas XRAR ${alpha}$ 2 led to partial rescueand RA treatment did not rescue at all (Fig. 5). Therefore,we infer that XFD is downregulating a crucial component of retinoid signaling.The failure of RA to rescue the effects of XFD overexpressionsuggests that expression of the receptor itself is the key missingcomponent, although the incomplete rescue elicited by the wild-type receptoralso implicates retinoid synthesis. The constitutively active receptordoes not require endogenous RARs or RA, and therefore wouldbe expected to rescue if retinoid is downstream of FGF signaling.

Inhibition of posterior gene expression by RAR-MO-mediated XRAR ${alpha}$ 2.2loss of function could not be overcome by overexpressing FGF8(Fig. 4) or XCAD3 (Fig. 9). The suppression of genes involvedin RA signaling such as XRAR ${alpha}$ 2, RALDH2 and CYP26 by XFD injection(Fig. 6) is consistent with a model wherein FGF signaling modulatesRAR signaling by regulating the availability of components inthe RAR signaling pathway. Zygotic expression of XRAR ${alpha}$ , RALDH2and CYP26 is detectable from the onset of gastrulation in theperiblastoporal region (Fig. 6) where various FGF signalingpathway components are also expressed (Golub et al., 2000; Hongoet al., 1999; Isaacs et al., 1995; Lombardo et al., 1998; Songand Slack, 1994; Song and Slack, 1996). We note that XRAR ${alpha}$ , XRAR ${gamma}$ and bioactive retinoids are all present in the unfertilizedegg (Blumberg et al., 1992). As RAR signaling is required forthe expression of FGF receptors in neural tissue (Fig. 9), itis possible that the maternally expressed RAR genes are permissivefor FGF signaling which is, in turn, instructive for the zygotic expressionof RAR pathway components.

FGF gene and XFD overexpression experiments using Xenopus embryossuggested that FGF signaling is essential for neural posteriorization (Coxand Hemmati-Brivanlou, 1995; Kengaku and Okamoto, 1995; Lamband Harland, 1995). Analysis of transgenic frogs overexpressingXFD yielded somewhat conflicting results with one group suggestingthat FGF signaling is involved in gastrulation, but not in posteriorization (Krolland Amaya, 1996), and another demonstrating an absolute requirementfor FGF signaling in neural posteriorization (Pownall et al., 1998).The discrepancy between mRNA injections and the two transgenicstudies could be due to the different timing and levels of XFD proteinproduced from the transgenic promoters, as opposed to the relatively earlierexpression of protein from the microinjected mRNA relative tothe transgenic promoters. XFD protein might not be producedat sufficient levels early enough in the transgenic Xenopusembryo to completely block the zygotic expression of the genesrequired for RAR signaling. Our observations that inhibitionof FGF signaling affected the expression of mRNAs encoding RA pathwaycomponents in the early gastrula (Fig. 6) and that RAR-MO injectionalters the expression of FGF8, FGFR1 and FGFR4 (Fig. 8) suggeststhat RAR and FGF signaling crossregulate each other. The observationthat RA upregulates FGF8, FGFR1 and FGFR4 while FGF8 upregulates RAR ${alpha}$ ,RALDH2 and CYP26 in animal cap experiments (Fig. 7) supports theexistence of a feedback loop that allows these posteriorizingfactors to maintain each other's expression. The loss of FGF8and FGF3 expression in Raldh2^–/– mice (Niederreitheret al., 1999) is also consistent with our findings.

RA signaling is involved in multiple steps of neural posteriorization
The alteration in the expression of FGF signaling componentsby the RAR-MO (Fig. 8) together with the requirement for FGFsignaling to express RAR pathway components (Fig. 6) supportsthe existence of such a mutual feedback loop. Isaacs and colleaguesshowed that XCAD3 upregulates HOXB9 expression in Xenopus embryosusing gain- and loss-of-function experiments (Isaacs et al.,1998; Pownall et al., 1998; Pownall et al., 1996). Their modelwas further supported by the identification of caudal/Cdx homeodomain-bindingsites in the promoters of region of mouse and chick HOX genes(Charite et al., 1998; Subramanian et al., 1995). We noted thatectopic expression of HOXB9 induced by XCAD3 overexpressionis restricted to the neural tube (Fig. 9C) and next examinedthe role of XRAR ${alpha}$ in HOXB9 expression. Injection of XCAD3 mRNAalone induced ectopic expression of HOXB9 anterior to whereit is normally expressed (Fig. 9C). Co-injection of the RAR-MOled to severely reduced expression of HOXB9 throughout the embryo(Fig. 9D-F), suggesting that RAR function is required for XCAD3to induce expression of HOXB9. Expression of HOXB9 (Fig. 9C)is limited to neural regions after XCAD3 overexpression, suggestingthat other factors are responsible for permitting or restrictingHOXB9 expression to the developing neural tube.

RAR signaling and regional boundaries within the developing CNS
The expression of XCAD3 and HOXB9 is reduced by RAR antagonistsand receptor loss of function. Loss of XCAD3 and HOXB9 expressionresulting from XFD-mediated blockade of FGF signaling can berescued by co-injection of the constitutively active VP16-XRAR ${alpha}$ 2(Fig. 5). Therefore, we infer that RAR functions in the spinalcord region as a transcriptional activator, downstream of FGFsignaling. This function for RAR is consistent with the restrictedexpression of the RA-synthesizing enzyme, RALDH2, in the spinalcord and lateral mesoderm of early frog embryos (Chen et al.,2001) and with RA rescue of posterior gene expression in XFDtreated zebrafish embryos (Kudoh et al., 2002) or Xenopus animalcap explants (Bang et al., 1997). Increasing RAR signaling bymicroinjecting VP16-XRAR ${alpha}$ 1 (Blumberg, 1997), treating embryoswith RA or microinjecting XRALDH2 (Chen et al., 2001) inducesan anterior shift in the expression boundaries of midbrain andhindbrain markers. However, the position of the anterior borderof HOXB9 and XCAD3 expression is unaffected by increases inRAR signaling (Fig. 5) (Blumberg, 1997; Chen et al., 2001) suggesting thatRAR signaling is not responsible for setting this boundary.When expression of HOXB9 (Fig. 5C) or XCAD3 (Fig. 5F) is rescuedby XRAR ${alpha}$ 2 or VP16-XRAR ${alpha}$ 2 in XFD injected embryos, the anterior borderof the rescued expression is similar to that in the uninjectedcontrol side of the embryo. This argues that FGF signaling isprobably not involved in regulating the anterior boundary ofposterior marker expression. FGF8 and XCAD3 overexpression canelicit ectopic HOXB9 expression in the anterior (Fig. 4). Both arerequired for XRAR ${alpha}$ expression but also need XRAR ${alpha}$ 2.2 to exerttheir effects on downstream genes such as HOXB9. The insufficiencyof VP16-XRAR ${alpha}$ 2 (which activates transcription of RAR target genesstrongly in the absence of retinoid ligands) to ectopically induceHOXB9 or XCAD3, argues against CYP26 (which degrades RA) beingthe major factor blocking the expression of posterior genesin the head, as has been suggested for the zebrafish (Kudohet al., 2002).

Inhibition of RAR signaling using an RAR antagonist or dominant-negative RARled to the upregulation of anterior markers (Koide et al., 2001)and a caudal shift in the expression boundaries of anteriorand hindbrain markers in frog embryos (Blumberg et al., 1997).Similar results were obtained by overexpressing the RA catabolizingenzyme CYP26 (de Roos et al., 1999; Hollemann et al., 1998;Maden, 1999) in frog embryos or treating chick embryos withRAR antagonists (Dupe and Lumsden, 2001). Kudoh and colleaguesrecently showed that knockdown of CYP26 expression led to downregulationof the anterior marker OTX2 and anterior expansion of HOXB1B,MEIS3 and IRO3 (Kudoh et al., 2002). We previously reportedthat unlike the hindbrain and spinal cord, which require RARas a transcriptional activator, RAR ${alpha}$ is required as a transcriptionalrepressor to allow anterior patterning (Koide et al., 2001).This aspect of RAR function coincides with the expression ofthe RA degrading enzyme CYP26 in regions anterior to the hindbrain (deRoos et al., 1999; Hollemann et al., 1998). Taken together,these results suggest that a delicate balance exists between RAR-mediatedrepression of target genes in the head that is required for anteriorpatterning and the RAR-mediated activation of target genes thatis indispensable for the expression of posterior neural markers.The expression of region-specific markers in the hindbrain isexquisitely sensitive to alterations in RA signaling (Godsaveet al., 1998; Kolm et al., 1997; van der Wees et al., 1998).Lumsden and colleagues showed convincingly that RA acts as aclassic morphogen in the hindbrain but that it appeared to begenerated locally at precise levels rather than forming a long-rangegradient (Dupe and Lumsden, 2001). In the absence of retinoidsignaling the hindbrain develops as a default R4, whereas increasingRA-signaling yields posterior rhombomeres in a concentration-dependentfashion (Dupe and Lumsden, 2001).

Is there a role for retinoids and retinoid receptors other than in the hindbrain?
Although it is now well established that position in the hindbrainis set by precisely delivered levels of RA (Bel-Vialar et al.,2002; Chen et al., 2001; Dupe and Lumsden, 2001; Godsave etal., 1998; Hollemann et al., 1998; Kolm et al., 1997; van derWees et al., 1998) the role of retinoids and retinoid receptorsanterior and posterior to the hindbrain remains controversial.For example, we showed that inhibition of RAR function by overexpressinga dominant negative XRAR ${alpha}$ 1 led to posterior expansion of theforebrain marker OTX2, a posterior shift in the expression ofthe midbrain marker EN2, a posterior shift in the rhombomere3 expression and loss of the rhombomere 5 expression of the hindbrainmarker KROX20 and downregulation of the posterior markers HOXB9,XLIM1 and N-tubulin (Blumberg et al., 1997). By contrast, increasingRAR function by microinjecting the constitutively active VP16-XRAR ${alpha}$ 1led to the opposite effect: a decreased and anterior shift inthe expression border of OTX2 and rostral shifts in EN2 andKROX20 expression although the anterior boundary of HOXB9 expressionwas unaffected (Blumberg et al., 1997). Thus, we concluded thatRARs were required for correct positional specification alongthe entire AP axis (Blumberg, 1997; Blumberg et al., 1997).

In contrast to our results, Sive and colleagues used a dominant-negative XenopusRAR ${alpha}$ 2.2 to show that interfering with retinoid signaling alteredhindbrain pattering in Xenopus but had no observable effectson anterior (XCG, OTX2) or posterior (HOXB9) gene expression(Kolm et al., 1997). Durston and colleagues used a dominant-negative chickenRAR ${alpha}$ 2 and came to a similar conclusion: that inhibition of