Cdx-Hox code controls competence for responding to Fgfs and retinoic acid in zebrafish neural tissue

doi:10.1242/dev.02660

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First published online 1 November 2006
doi: 10.1242/dev.02660

Development 133, 4709-4719 (2006)
Published by The Company of Biologists 2006

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Cdx-Hox code controls competence for responding to Fgfs and retinoic acid in zebrafish neural tissue

Takashi Shimizu, Young-Ki Bae and Masahiko Hibi^*

Laboratory for Vertebrate Axis Formation, Center for Developmental Biology, RIKEN, 2-2-3 Minatojima-minamimachi, Chuo-ku, Kobe, Hyogo 650-0047, Japan.

^* Author for correspondence (e-mail: hibi{at}cdb.riken.jp)

Accepted 26 September 2006

SUMMARY

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Fibroblast growth factor (Fgf) and retinoic acid (RA) signalscontrol the formation and anteroposterior patterning of posteriorhindbrain. They are also involved in development processes inother regions of the embryo. Therefore, responsiveness to Fgfand RA signals must be controlled in a context-dependent manner.Inhibiting the caudal-related genes cdx1a and cdx4 in zebrafishembryos caused ectopic expression of genes that are normallyexpressed in the posterior hindbrain and anterior spinal cord,and ectopic formation of the hindbrain motor and commissureneurons in the posteriormost neural tissue. Combinational markeranalyses suggest mirror-image duplication in the Cdx1a/4-defectiveembryos, and cell transplantation analysis further revealedthat Cdx1a and Cdx4 repress a posterior hindbrain-specific geneexpression cell-autonomously in the posterior neural tissue.Expression of fgfs and retinaldehyde dehydrogenase 2 suggestedthat in the Cdx1a/4-defective embryos, the Fgf and RA signalingactivities overlap in the posterior body and display opposing gradients,compared with those in the hindbrain region. We found that Fgfand RA signals were required for ectopic expression. Expressionof the posterior hox genes hoxb7a, hoxa9a or hoxb9a, which function downstreamof Cdx1a/4, or activator fusion genes of hoxa9a or hoxb9a (VP16-hoxa9a,VP16-hoxb9a) suppressed this loss-of-function phenotype. Thesedata suggest that Cdx suppresses the posterior hindbrain fatethrough regulation of the posterior hox genes; the posteriorHox proteins function as transcriptional activators and indirectlyrepress the ectopic expression of the posterior hindbrain genesin the posterior neural tissue. Our results indicate that theCdx-Hox code modifies tissue competence to respond to Fgfs andRA in neural tissue.

Key words: caudal-related genes, hox, Hindbrain, Fibroblast growth factor, Retinoic acid, Zebrafish

INTRODUCTION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The anteroposterior patterning of neural tissue is establishedthrough various inductive signals. The neuroectoderm is initiallyinduced by signals from the dorsal organizer and subsequentlyreceives a diffusible signal(s) from the non-axial mesodermand endoderm (mesendoderm in zebrafish) that is responsiblefor establishing the anteroposterior axis in the neuroectoderm. Subsequently,the neural tissue receives more defined positional information fromthe mesodermal tissues and the secondary organizing centers.

The hindbrain is a segmented neural structure that containsseven or eight compartments called rhombomeres (r). The formationand anteroposterior patterning of the posterior hindbrain andanterior spinal cord is regulated by fibroblast growth factor(Fgf) and retinoic acid (RA) signaling. r4 is the first-formedrhombomere, and it functions as a secondary signaling centerthat expresses fgf3 and fgf8, which are required for r5 andr6 to form (Maves et al., 2002; Walshe et al., 2002; Waskiewiczet al., 2002; Wiellette and Sive, 2004). The retinaldehyde dehydrogenase2 gene (raldh2) [the aldehyde dehydrogenase 1 family, memberA2 gene (aldh1a2) - Zebrafish Information Network] encodes anenzyme that synthesizes RA from retinaldehyde, the intermediateproduct of vitamin A oxidation (Niederreither et al., 2000); raldh2is expressed in early mesendodermal cells and persists in the lateral/paraxialmesoderm in zebrafish (Begemann et al., 2001; Grandel et al.,2002). Mutations in the raldh2 gene in zebrafish lead to theloss of r7 and the anterior spinal cord (Begemann et al., 2001;Grandel et al., 2002). Inhibition experiments showed that theRA signal is required for the formation of the posterior hindbrain(r5-r7) and anterior spinal cord (Begemann et al., 2001; Grandelet al., 2002); high RA activity is required for the more posteriorregion (anterior spinal cord) and lower RA activity is requiredfor the more anterior one, as reported for other vertebratespecies (Dupe et al., 1999; Dupe and Lumsden, 2001; Gale etal., 1999; Niederreither et al., 2000; Wendling et al., 2001; Whiteet al., 2000). The Fgf and RA signals not only control the formationand patterning of the posterior hindbrain and anterior spinalcord but also regulate other developmental processes. The countergradients of Fgf and RA signals control neurogenesis in theposterior spinal cord and the segmentation of the paraxial mesoderm (Diezdel Corral et al., 2003; Dubrulle et al., 2001; Sawada et al.,2001). It remains to be elucidated how the different tissueresponses to Fgf and RA are controlled.

caudal-related homeobox (cdx) genes are members of the ParaHoxcluster, a cluster of homeobox genes closely related to theHox cluster that function in the formation of the posteriorbody in vertebrate and invertebrate species (Deschamps and van Nes,2005; Lohnes, 2003). Cdx proteins directly regulate the expressionof the posterior hox genes through direct binding to the cis-regulatoryelements of the hox genes (Charite et al., 1998; Gaunt et al.,2004; Isaacs et al., 1998; Pownall et al., 1996; Subramanianet al., 1995). Zebrafish cdx4/kugelig mutant embryos have areduced posterior body and reduced expression of the posteriorhox genes (Davidson et al., 2003; Hammerschmidt et al., 1996). Inhibitionof both Cdx1a and Cdx4 leads to loss of the hoxb7a and hoxa9aexpression at the early segmentation stage and causes a more severeposterior truncation than does the inhibition of Cdx4 alone (Davidsonand Zon, 2006; Shimizu et al., 2005).

Here, we show that the inhibition of Cdx1a and Cdx4 inducesectopic expression of the posterior hindbrain and anterior spinalcord markers in the posteriormost neural tissue in zebrafish.Both Fgf and RA signals are required for this ectopic expression,which can be suppressed by expression of the posterior hox genes.Our results reveal an essential role for the Cdx-Hox code inmodifying tissue responsiveness to Fgf and RA signaling.

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Fig. 1. Loss of posterior hox expression in embryos lacking Cdx1a/4. Expression of hoxb5a (A,B), hoxb6a (C,D), hoxb7a (E,F) or hoxa9a (G,H) in wild-type controls (wt) (A,C,E,G) and in embryos that received an injection of 1 ng cdx1aMO and 1 ng cdx4MO (B,D,F,H) at 22 hpf. hoxb5a, hoxb6a, hoxb7a and hoxa9a are expressed in the spinal cord. hoxb5a is expressed at the level of somite 1 and posterior to it. hoxb6a is expressed at the level of somite 2 and posterior to it. hoxb7a and hoxa9a are expressed at the level of somite 4 and posterior to it. In the cdx1a/4 morphant embryos, hoxb5a or hoxa6a-negative domains were detected in the posterior neural tissue (arrowhead in B and D). Scale bar: 100 µm.

	MATERIALS AND METHODS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Fish embryos
Wild-type zebrafish (Danio rerio) embryos were obtained from naturalcrosses of fish with the AB/India genetic background. The islet1-GFP transgenicline Tg(isl1:GFP) was used for the analysis of cranial motoneurons(Higashijima et al., 2000

). The embryos were incubated at 28.5°C.The morphant embryos and inhibitor-treated embryos showed aberrantdevelopment. Developmental stages were determined as hours postfertilization (hpf).

Antisense morpholino oligonucleotides and transcript detection
The antisense morpholino oligonucleotides (MOs) for cdx1a, cdx4, raldh2,fgf3, fgf8, wnt3a and wnt8 and the preparation of morphant embryoswere previously published (Begemann et al., 2001; Davidson etal., 2003; Shimizu et al., 2005; Wiellette and Sive, 2004).The expression patterns of krox20 (egr2b - Zebrafish Information Network),valentino, hoxb1a, hoxa2b, hoxb4a, hoxb5a, hoxb6a, hoxb7a, hoxa9a,fgf3, fgf8, raldh2 and cyp26a1 have been reported (Begemannet al., 2001; Davidson et al., 2003; Emoto et al., 2005; Furthaueret al., 1997; Grandel et al., 2002; Koshida et al., 2002; Princeet al., 1998a; Prince et al., 1998b; Reifers et al., 1998; Shimizuet al., 2005; Shinya et al., 2001; Walshe and Mason, 2003).BM Purple and FastRed (Roche) were used for whole-mount in situhybridization. Images were taken using an AxioPlan2 microscopeequipped with an AxioCam CCD camera (Zeiss).

Immunostaining and transplantation
Commissure neurons in the hindbrain were stained with the monoclonal antibodyzn-5 (Trevarrow et al., 1990; provided by the Zebrafish InternationalResource Center) and Alexa 488-conjugated antibodies (Invitrogen/MolecularProbes). Transplantation was performed principally as describedpreviously (Ho and Kane, 1990). Briefly, FITC-dextran (Invitrogen/MolecularProbes) was injected with cdx1aMO and cdx4MO into one-cell-stageembryos. Cells were harvested from the donor embryos and transplantedinto the blastoderm of sibling recipient embryos at the spherestage. After the embryos were fixed, the transcripts were detectedby in situ hybridization using BM Purple, and FITC-dextran was detectedby immunostaining with an alkaline phosphatase-conjugated anti-FITC antibody(Roche) and FastRed.

Inhibitors for RA and Fgf signaling, and FGF8b treatment
DEAB (Wako) and SU5402 (Calbiochem) were dissolved in DMSO at100 mmol/l and 20 mmol/l, respectively. Recombinant mouse FGF8bproteins were purchased from R&D Systems. Embryos were treatedwith 50 µmol/l DEAB and/or 300 µmol/l SU5402, or100 ng/ml of mFGF8b in the presence of 1 µg/ml heparin inembryonic medium from the shield stage to 22 hpf.

Plasmid construction and synthetic RNAs
To construct expression vectors for hoxb7a, hoxa9a, hoxb9a,hoxb1a and hoxb1b, the full open reading frames of these geneswere amplified by PCR and inserted into pCS2+MT. Plasmids forVP16 fusion proteins VP-Hoxb9a and VP-Hoxb9b were constructedby inserting the PCR fragments containing hoxb9a (encoding aminoacids 156-251) or hoxb9b (amino acids 162-256) into pCS2+NLSVP16AD, which contains the transcriptional activation domainof VP16 (amino acid 412-490) (Shimizu et al., 2002). Plasmidsfor the Engrailed fusion proteins En-Hoxb9a and En-Hoxb9b were constructedby inserting the hoxb9a or hoxb9b fragments into pCS2+En, whichcontains the repressor domain of Drosophila Engrailed (aminoacids 1-226) (Shimizu et al., 2002). To make synthetic cappedRNAs for these genes, the plasmids were linearized with NotIand transcribed with SP6 RNA polymerase.

RESULTS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cdx1a and Cdx4 are required for formation of the posterior spinal cord
We investigated the roles of Cdx1a and Cdx4 in the anteroposterior patterningof neural tissue. We first examined the expression of the hoxgenes hoxb5a, hoxb6a, hoxb7a and hoxa9a, which display region-specificexpression in the spinal cord (Prince et al., 1998a), in cdx1a/cdx4MO-injectedembryos (cdx1a/4 morphant embryos), at 22 hpf (correspondingto the 26-somite stage for the control embryos). In wild-typeembryos, the expression domains of these hox genes extended anteriorlyin the neural tube no further than the level of somite (s) 1for hoxb5a, s2 for hoxb6a and s4 for both hoxb7a and hoxa9a(Fig. 1A,C,E,G), as reported previously (Prince et al., 1998a).In the cdx1a/4 morphant embryos, no hoxb7a or hoxa9a was detected(Fig. 1F,H); the expression domains of hoxb5a and hoxb6a extendednoticeably less far posteriorly than they normally do; and ahoxb5a- and hoxb6a-negative region was observed in the posteriormostdomain of the neural tube (Fig. 1B,D). Seen in this light, bothCdx1a and Cdx4 are required for the expression of the posteriorhox genes, which are normally expressed in the poster spinalcord.

Inhibition of Cdx1a and Cdx4 leads to posterior, mirror-image duplication of posterior hindbrain and anterior spinal cord
We next examined the expression of hindbrain markers in the cdx1a/4morphant embryos (Fig. 2A) (Prince et al., 1998b). Unexpectedly,we observed the ectopic expression of krox20 (a marker for r3and r5, n=30/31), hoxb1a (r4, n=21/22), hoxa2b (r2-5, n=7/10)and valentino (r5, 6, n=19/19) in the posteriormost region of theneural tube, in addition to their normal expression domainsin the hindbrain region (Fig. 2B-I). The ectopic expressionof valentino, krox20 and hoxb1a was detected as early as 11,13 and 15 hpf, respectively, in the cdx1a/4 morphant embryos(Fig. 2R-W). We did not detect the ectopic expression of krox20(n=0/17), hoxb1a (n=0/19), or valentino (n=0/17) in the embryosthat received cdx1aMO alone (cdx1a morphant embryos, Fig. 2O-Q). Co-stainingfor krox20 and hoxb4a, which labels r7 and posterior (r7-),hoxb1a, or valentino revealed that the cdx1a/4 morphant embryosshowed a hoxb1a-expressing r4 identity in the posteriormostregion (Fig. 2E,L), and, from posterior to anterior, a krox20⁺valentino⁺r5 identity (Fig. 2C,I,M; note that the expression domains ofkrox20 and valentino overlapped in the insets of Fig. 2M), a krox20^-valentino⁺ r6 identity (Fig. 2M; also hoxb4a^- in Fig. 2K), anda hoxb4a-expressing r7 identity (Fig. 2K). The cdx1a/4 morphantembryos expressed the anterior spinal cord markers hoxb5a andhoxb6a in the region anterior to the krox20-expressing regionin the posterior-most region (data not shown). These resultssuggest that the cdx1a/4 morphant embryos display ectopic formationof the posterior hindbrain and the anterior spinal cord, andthe anteroposterior polarity of the ectopic tissue is oppositeto that of the normal one (Fig. 7B).

In addition to its neural expression, hoxb1a is normally expressed inthe cranial mesoderm (Fig. 2D), while its expression in cdx1a/4morphant embryos was expanded posteriorly and reached the posteriorend (Fig. 2E). By contrast to ectopic hoxb1a expression in theneural tissue, however, we were unable to find any gap betweenthe anterior and posterior mesodermal expression, suggestingthat the anterior mesoderm expands instead of posterior mesoderm,rather than being ectopically induced at the posterior end.This is consistent with the posterior expansion of hoxb5a expressionin the mesoderm of Cdx1a/4-defective embryos (Davidson and Zon,2006). The data suggest that the ectopic induction of anteriortissues only took place in the neural tissue in the cdx1a/4morphant embryos.

In an attempt to reveal whether the cdx1a/4 morphant embryos containedectopic hindbrain neurons, we performed immunohistochemistrywith zn-5, which stains neurons such as hindbrain commissureneurons and secondary motoneurons (Trevarrow et al., 1990) (Fig. 3A-H). Wewere able to detect the hindbrain commissure neurons with theiraxons in the hindbrain of control embryos (Fig. 3A-C), and inthe hindbrain and the posteriormost neural tissue of the cdx1a/4morphant embryos (Fig. 3E-H). We further examined the formationof cranial motoneurons by injecting the cdx1a/4MOs into theislet1-GFP transgenic embryos (Higashijima et al., 2000). Here,we could detect GFP expression in the cranial motoneurons, including trigeminal,facial and vagal neurons in the control embryos (V, VII andX in Fig. 3I). In the cdx1a/4 morphant embryos, GFP expressionwas first detected in the hindbrain and the entire posteriorneural tissue at the pharyngula period. We also observed a clusterof GFP-positive neurons with their axons in the posteriormostneural tissue at 48 hpf (Fig. 3K, marked by arrowhead). Takentogether, the results suggest that inhibition of Cdx1a and Cdx4leads to posterior, mirror-image duplication of posterior hindbrainand anterior spinal cord.

We also observed the ectopic expression of krox20, in the embryos thatreceived cdx4MO alone (cdx4 morphant embryos, Fig. 2N). However,the ectopic transcripts were scattered in the middle trunk regionand were not detected in the posteriormost neural tissues (Fig. 2N).These data suggest that: (1) Cdx4 is required for repressing theposterior hindbrain fate at least partly non-redundantly; and(2) the ectopic formation of the posterior hindbrain dependson inductive signals that are affected differently in the cdx1a/4morphant and cdx4 morphant embryos.

As the inhibition of Cdx1a/4 also affects the development ofthe mesoderm (Davidson et al., 2003; Davidson and Zon, 2006; Shimizuet al., 2005), it was not clear whether cdx1a and cdx4 repressedthe formation of the posterior hindbrain and anterior spinalcord cell-autonomously or non-cell-autonomously. To addressthis issue, we transplanted wild-type or Cdx1a/4-deficient blastomeresinto wild-type host embryos (Fig. 4). Although cells from thewild-type donor embryos never expressed krox20 (n=0/18), ectopicexpression was occasionally detected in cells from the cdx1a/4morphant embryos, when the transplanted cells were incorporatedinto the neural tissue (n=20, 20% of the embryos; Fig. 4), indicatingthat Cdx1a and Cdx4 suppress the posterior hindbrain fate cell-autonomously.However, this ectopic expression was detected only when theCdx1a/4-deficient cells were located in the middle trunk regionof the neural tissue, and not in the anterior or the posteriormostspinal cord (Fig. 4B,C), further supporting the idea that inductivesignals for hindbrain gene expression were localized differentlyin the wild-type and cdx1a/4 morphant embryos.

Opposite gradients of Fgf and RA signaling between hindbrain and posterior neural tissues
Since the normal formation and anteroposterior patterning ofthe hindbrain and anterior spinal cord is regulated by Fgf andRA signals, we considered the possibility that the ectopic expressionof the posterior hindbrain and anterior spinal cord markersmight also depend on these signals. In an effort to investigatethis possibility, we first examined the expression of the fgfgenes raldh2 and cyp26a1, which codes for an RA-degrading enzyme,in wild-type, cdx1a morphant, cdx4 morphant and cdx1a/4 morphantembryos, at the early segmentation stage (Fig. 5A-P), as the ectopicexpression is initiated at the early segmentation stages (Fig. 2R-W).We found that the expression of these genes did not significantlydiffer between wild-type and cdx1a morphant embryos (Fig. 5).The fgf3 and fgf8 expression domains in the anterior neuroectodermand r4 were not affected in the cdx4 and cdx1a/4 morphant embryos,and their expression in the posterior mesoderm was retainedat reduced levels (Fig. 5A-H). The expression of fgf8 in thesomitic mesoderm was relatively well maintained in the cdx4morphant but was strongly reduced in the cdx1a/4 morphant embryos(Fig. 5E,G,H). The expression domain of raldh2 in the trunkregion of the paraxial/lateral mesoderm shifted posteriorlyin the cdx4 morphant embryos. The raldh2 expression domain shiftedmore posteriorly and was located closer to the posterior endin the cdx1a/4 morphant embryos, than in the cdx4 morphant embryos (Fig. 5I-L).The expression of cyp26a1 in the posteriormost region was retainedin the cdx4 and cdx1a/4 morphant embryos but that in the anteriorspinal cord was strongly increased and shifted posteriorly inthe cdx1a/4 morphant embryos (Fig. 5M-P). The expression offgf8, raldh2 and cyp26a1in the posterior region was initiatedat the gastrula period and was affected in the cdx4 and cdx1a/4morphant embryos in a similar way to that observed at the earlysegmentation stage (see Fig. S1 in the supplementary material).Given that Fgf signaling activity was high in the posteriormost regionand RA signaling activity was high in the middle trunk regionin wild-type animals, the results from the cdx4 and cdx1a/4 morphantembryos indicate that the gradients of the Fgf and RA signalsin the ectopic posterior neural tissue were opposite to thosein the hindbrain and anterior spinal cord (Fig. 5R-T). Our resultsalso show that the region of high activity for Fgf and RA signalingoverlapped in the posteriormost region of the cdx1a/4 morphantembryos (Fig. 5T), but in the cdx4 morphant embryos these domains overlappedin the middle trunk region, where raldh2 and fgf8 are coexpressedin the somitic mesoderm (Fig. 5S). Considering these findings,we hypothesized that the overlapping Fgf and RA signaling recapitulatedthe signaling conditions for development of the posterior hindbrainand anterior spinal cord, thereby inducing their ectopic development inthe posteriormost neural tissue in the cdx1a/4 morphant embryos andin the posterior-trunk region in the cdx4 morphant embryos. Consistentwith this, we detected ectopic krox20 transcripts in the vicinityof the fgf8 expression domain in the somitic mesoderm of the cdx4morphant embryos (Fig. 5Q).

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Fig. 2. Ectopic formation of hindbrain in embryos lacking Cdx4 or Cdx1a/Cdx4. (A) Schematic presentation of genetic markers for the hindbrain and anterior spinal cord. Numbers indicate rhombomeres. (B-M) Expression of krox20 (B,C), hoxb1a (D,E), hoxa2b (F,G), valentino (val, H,I), hoxb4a and krox20 (J and K), krox20 and hoxb1a (L), or krox20 and valentino (M) in wild-type control (B,D,F,H,J) and cdx1a/4MO-injected embryos (C,E,G,I,K-M) at 22 hpf. (K-M) Higher magnification dorsal views of the posterior region are in the insets [bright-field images in K,L; bright-field (upper), fluorescent (middle) and superimposed (lower) images in M]. Ectopic expression of the hindbrain markers are indicated by arrowheads (C,E,G,I). In the posterior neural tissue of the cdx1a/4 morphant embryos, hoxb1a expression (r4, black arrowhead in L) was detected just posterior to the krox20 expression (r5, red arrowhead in L); valentino expression (r5, 6, black arrowhead in M) overlapped with krox20 expression (r5, red arrowhead in M) and extended anteriorly (krox20^-val⁺ domain corresponds to r6); the hoxb4a^- domain (r6, gray arrowhead in K) was anterior to the krox20 domain (r5, black arrowhead in K). (N) Expression of krox 20 in embryos that received 1 ng cdx4MO at 22 hpf. Higher magnification views in the inset. Ectopic expression domains are marked by arrowheads. (O-Q) Expression of krox 20, hoxb1a and valentino in embryos that received 1 ng cdx1aMO at 22 hpf. (R-W) Expression of krox20 at 13 hpf, of hoxb1a at 15 hpf and of valentino at 11 hpf in wild-type control (R,T,V) and cdx1a/4 morphant embryos (S,U,W). Ectopic expression domains are marked by arrowheads. Scale bar: 100 µm.

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Fig. 3. Ectopic formation of hindbrain neurons in embryos lacking Cdx1a and Cdx4. (A-H) Detection of hindbrain commissure neurons by immunostaining with monoclonal antibody zn-5 of wild-type control (A-D) and cdx1a/4 morphant embryos (E-H) at 3 days post fertilization (dpf). (B,E) Bright field images. Lateral views (A,B,E,F) and high-magnification dorsal views of hindbrain (C,G) and tail regions (D,H) with anterior to the left. zn-5-positive commissure neurons can be recognized by their axonal structures in the hindbrain regions (arrowheads) and ectopically in the posteriormost neural tissue (arrows). (I-L) Detection of cranial motoneurons in control Tg(isl1:GFP) embryos and Tg(isl1:GFP) embryos that received cdx1aMO and cdx4MO at 48 hpf. Bright field images (J,L). The position of trigeminal (V), facial (VII) and vagal (X) motor nuclei was indicated. A cluster of the GFP+ neurons with their axons were detected in the posteriormost region of cdx1a/4 morphant embryos (arrowhead, K). Scale bars: 500 µm in A,B,E,F; 100 µm in C,D,G,H,I,K.

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Fig. 4. Cell-autonomous role of Cdx1a/4 in suppressing posterior hindbrain identity. (A-C) Transplantation of Cdx1a/4-defective cells into wild-type embryos. Blastomere cells were isolated from embryos that received cdx1a/4MOs and FITC-dextran at the sphere stage and transplanted into sibling wild-type embryos. The embryos were fixed at 22 hpf and stained with a krox20 riboprobe (purple) and an anti-FITC antibody (red). High-magnification bright field (B) and fluorescent images (C) of the posterior neural tissues (encircled by a square in A). krox20-expressing and non-expressing transplanted cells are marked with black and red arrowheads, respectively, in B, or with white and red arrowheads in C. Scale bars: 100 µm in A; 500 µm in B.

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Fig. 5. Gradients of Fgf and RA signals. (A-P) Expression of fgf3 (A-D), fgf8 (E-H), raldh2 (I-L) and cyp26a1 (M-P) in wild-type control (A,E,I,M), cdx1a morphant (B,F,J,N), cdx4 morphant (C,G,K,O) and cdx1a/4 morphant (D,H,L,P) embryos at 13 hpf. The posterior end of the embryos are marked by arrowheads (I-L). (Q) Expression of fgf8 (red) and krox20 (purple) in the trunk region of cdx4 morphant embryos at 22 hpf. The ectopic krox20 in neural tissue and fgf8 in somitic mesoderm are marked by a black arrowhead and red arrows, respectively. (R-T) Schematic presentation of the Fgf and RA signaling gradients in wild-type (R), cdx4 morphant (S) and cdx1a/4 morphant (T) embryos. The expression domains of the fgfs and raldh2 are indicated in red and green, respectively, in the body of each schematic. The gradients of the Fgf and RA signals in the neuroectoderm are also indicated in red and green, respectively, and shown to the right of each schematic. The solid red bars on the right in R and S indicate stripes of Fgf signaling (see Q). Scale bars: 100 µm.

Fgf and RA signaling are required for the ectopic formation of the posterior hindbrain
To test our hypothesis, we conducted experiments inhibitingFgf and/or RA signaling in the cdx1a/4 morphant embryos (Figs 6, 7;see Fig. S4 in the supplementary material). We inhibited Fgfsignaling by treating the embryos with 300 µmol/l SU5402,a specific inhibitor of the FGF receptor (Mohammadi et al.,1997

) or by co-injecting fgf3MO and fgf8MO (Wiellette and Sive,2004

). We inhibited RA signaling by treating the embryos with50 µmol/l 4-(Diethylamino)-benzaldehyde (DEAB), a potentretinaldehyde dehydrogenase inhibitor (Russo, 1997

) or by injectingraldh2MO (Begemann et al., 2001

). Marker expression in embryostreated only with an inhibitor of Fgf or RA signaling is shownin Fig. S2 in the supplementary material (marker expressionin wild-type untreated embryos is shown in Fig. 2). Inhibitionof either the Fgf or RA signal did not perturb the other signalinggradient in the cdx1a/4 morphant embryos (Fig. S3 in the supplementary material). Inhibitionof the Fgf signal in the cdx1a/4 morphant embryos by the fgf3/8MOsabolished the ectopic expression of hoxb1a (r4, n=26/34), krox20(r5, n=36/36) and valentino (r5, 6, n=29/34) and reduced thenormal expression of krox20 in r5, but did not inhibit the expressionof hoxb4a (r7-) and hoxb5a (s1-) (Fig. 6A,E,I,M,Q; Fig. 7C).Inhibition of the Fgf signal by SU5402 abolished the ectopicexpression of hoxb1a (n=14/14) and the ectopic and normal expressionof krox20 (n=14/14) and valentino (n=14/14) but retained the hoxb4aand hoxb5a expression (Fig. 6B,F,J,N,R; Fig. 7D). The weakerphenotypes with the fgf3/8MOs are probably due to incompleteinhibition of the Fgf3 and Fgf8 function under our experimentalconditions, as the MOs did not disrupt the normal formationof r5 and r6 (Maves et al., 2002

; Walshe et al., 2002

; Wielletteand Sive, 2004

). The results suggest that the Fgf signal isrequired for the ectopic expression of the hindbrain r4-r6 markers,but dispensable for both normal and ectopic expression of ther7 and the anterior spinal cord markers. The inhibition of Raldh2by its MO in the cdx1a/4 morphant embryos repressed the expressionof hoxb5a (s1-, n=26/26), but did not suppress the normal orectopic expression of krox20 (r5), hoxb1a (r4), valentino (r5,6) or hoxb4a (r7-) (Fig. 7E; see Fig. S4 in the supplementary material).Strong inhibition of RA signaling by DEAB in the cdx1a/4 morphantembryos completely abolished the expression of hoxb4a (r7-;n=15/15) and hoxb5a (s1-, n=11/11) and strongly inhibited theexpression of valentino (r5, 6), but did not significantly inhibitthe expression of hoxb1a (r4) (Fig. 5C,G,K,O,S; Fig. 7F). Thesedata indicate that high RA signaling activity is required forthe normal and ectopic expression of the anterior spinal cordmarkers, and lower RA signaling activity is required for bothnormal and ectopic expression of the posteriormost hindbrainmarkers (r7 and probably r6).

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Fig. 6. RA and Fgf signals are involved in the formation of the duplicated neural structure in embryos lacking Cdx1a/4. (A-U) Expression of krox20 (A-D,U), hoxb1a (E-H), valentino (I-L), hoxb4a (M-P) or hoxb5a (Q-T) in embryos that received an injection of cdx1a/4MOs and 2 ng each of the fgf3MO and fgf8MOs (A,E,I,M,Q) or injection of cdx1a/4MOs and 2 ng each of wnt3aMO and wnt8MOs (U); cdx1a/4 morphant embryos that were treated with 300 µmol/l SU5402 (B,F,J,N,R); cdx1a/4 morphant embryos that were treated with 50 µmol/l DEAB (C,G,K,O,S); cdx1a/4 morphant embryos that were treated with 300 µmol/l SU5402 and 50 µmol/l DEAB (D,H,L,P,T) at 22 hpf. (V-X) Expression of krox20 (V), hoxb1a (W) and valentino (X) in cdx1a/4 morphant embryos that were treated with 100 µg/ml recombinant mouse FGF8b. The ectopic expression is marked by arrowheads. Scale bar: 100 µm.

Inhibition of both the Fgf and RA signals by SU5402 and DEABin the cdx1a/4 morphant embryos suppressed the ectopic hoxb1a expression(r4, n=15/15) and the normal and ectopic expression of krox20(r5, n=18/18), valentino (r5, 6, n=9/9), hoxb4a (r7-, n=10/10)and hoxb5a (s1-, n=10/10) (Fig. 6D,H,L,P,T; Fig. 7G). This inhibitionalso elicited a slight expansion of the hoxb1a-expressing domain(Fig. 6H; Fig. 7G), suggesting that these embryos lost the duplicatedposterior hindbrain and anterior spinal cord, but instead showedan expanded r4 domain. Although Wnt signaling is reported tobe involved in patterning and neurogenesis in the hindbrain(Amoyel et al., 2005

; Riley et al., 2004

), inhibition of Wnt3aand Wnt8, which disrupt the posterior body formation in wild-typeembryos (Shimizu et al., 2005

; Thorpe et al., 2005

), did notinhibit the formation of the ectopic neural tissue (Fig. 6U).Our results indicate that the ectopic formation of r4-6 requireshigh Fgf signaling, whereas that of anterior spinal cord andthe posteriormost hindbrain requires high RA signaling, in asimilar manner to the normal formation of these tissues.

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Fig. 7. Schematic presentation of the neural structures of cdx1a/4 morphant, and Fgf and/or RA signal-defected cdx1a/4 morphant embryos. (A) Wild type (wt). (B) cdx1a/4 morphants. (C) cdx1a/4 morphants that received co-injected fgf3/8MOs. (D) cdx1a/4 morphants treated with 300 µmol/l SU5402. (E) cdx1a/4 morphant embryos expressing the raldh2MO (see Fig. S4 in the supplementary material). (F) cdx1a/4 morphant embryos treated with 50 µmol/l DEAB. (G) cdx1a/4 morphant embryos treated with SU5402 and DEAB.

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Fig. 8. Posterior Hox proteins function as transcriptional activators leading to the Cdx-mediated inhibition of hindbrain formation. Expression of krox20 in wild-type control embryos (A) and embryos that received an injection of 25 pg of hoxa9a RNA (B), 25 pg of hoxb9a RNA (C), cdx1a/4MOs and hoxa9a RNA (D), cdx1a/4MOs and hoxb9a RNA (E), cdx1a/4MOs and 25 pg of En-hoxa9a RNA (F), cdx1a/4MOs and 25 pg of En-hoxb9a RNA (G), cdx1a/4MOs and 25 pg of VP-hoxa9a RNA (H) or cdx1a/4MOs and 25 pg of VP-hoxb9a RNA (I). Overexpression of hoxa9a, hoxb9a, VP-hoxa9a or VP-hoxb9a suppresses the expression of krox20 in its normal and ectopic positions. Overexpression of En-hoxa9a or En-hoxb9a did not suppress the ectopic krox20 expression (marked by arrowheads). Scale bar: 100 µm.

To gain better insight into this issue, we investigated whetherFgf and RA were sufficient to induce the posterior hindbrainin the absence of Cdx1a and Cdx4. We treated the cdx1a/4 morphantembryos with mouse FGF8. Compared with untreated cdx1a/4 morphantembryos (Fig. 2), the FGF8-treated cdx1a/4 morphant embryosshowed anterior expansion of the ectopic expression domainsof krox20 and valentino, but not of hoxb1a (Fig. 6V,W,X). Asthe posterior mesoderm expresses raldh2 in the cdx1a/4 morphantembryos (Fig. 5L), our results suggest that Fgf and RA signalsinduced the posterior hindbrain fate in posterior neural tissuelacking Cdx1a/4.

Posterior Hox proteins mediate the repression by Cdx of the posterior hindbrain identity
Cdx proteins are known to regulate the expression of the posterior hoxgenes (Charite et al., 1998; Gaunt et al., 2004; Isaacs et al., 1998;Pownall et al., 1996; Subramanian et al., 1995), and the expressionof posterior hox genes, such as hoxb7a and hoxa9a, is absentfrom the neural tissues of cdx1a/4 morphant embryos (Shimizu etal., 2005) (Fig. 1F,H), suggesting that the posterior Hox proteinsfunction downstream of Cdx1a/4 to repress the fate of the posteriorhindbrain. To address this issue, we injected RNAs for hoxb7a,hoxa9a or another posterior hox gene, hoxb9a, with or withoutthe cdx1a/cdx4MOs. The misexpression of these posterior hox genesin wild-type embryos suppressed the expression of krox20 (n=15/15for hoxa9a, n=19/19 for hoxb9a and n=11/15 for hoxb7a) (Fig. 8A-C,and data not shown for hoxb7a). The ectopic expression of krox20,which was observed in the cdx1a/4 morphant embryos (Fig. 2C),was abolished in these embryos (n=14/15 for hoxa9a, n=15/17for hoxb9a and n=15/17 for hoxb7a) (Fig. 8D,E, and data notshown for hoxb7a), indicating that these posterior hox genes compensatedfor the loss of Cdx1a and Cdx4 in repressing the posterior hindbrainfate. Misexpression of the anterior hox genes hoxb1a or hoxb1bdid not suppress the ectopic krox20 expression in the cdx1a/4morphant embryos (data not shown). These findings suggest thatthe posterior hox genes function downstream of Cdx1a and Cdx4to repress the posterior hindbrain fate.

Hox proteins are reported to function as transcriptional activatorsor repressors (Asahara et al., 1999; Lu et al., 2003; Salehet al., 2000; Tour et al., 2005). We investigated whether theposterior Hox proteins function as transcriptional repressorsof the posterior hindbrain genes or as transcriptional activatorsthat indirectly repress the transcription of these genes. Toapproach this issue, we constructed activator and repressorversions of Hoxa9a and Hoxb9a, by constructing fusion proteinswith either the transcriptional repressor domain of DrosophilaEngrailed (En-Hoxa9a and En-Hoxb9a) or the activation domainof the Herpes Simplex Virus transcriptional activator VP16 (VP-Hoxa9aand VP-Hoxb9a), respectively. Although the expression of En-hoxa9aor En-hoxb9a led to a reduction of posterior structures andan expansion of the anterior structure in wild-type (data notshown) and cdx1a/4 morphant embryos (Fig. 8F,G), neither ofthese fusion proteins inhibited the ectopic expression of krox20 (n=17/17for En-hoxa9a and n=25/27 for En-hoxb9a) (Fig. 8F,G). By contrast,the expression of VP-hoxa9a or VP-hoxb9a suppressed the expressionof krox20 in its normal and ectopic positions (n=10/15 for VP-hoxa9aand n=11/15 for VP-hoxb9a) (Fig. 8H,I), as did the wild-typeRNA. Our data show that the posterior Hox proteins functionas transcriptional activators that indirectly repress the formationof the posterior hindbrain.

DISCUSSION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Role of the Cdx-Hox code in formation of the hindbrain
In this study, we unexpectedly found that the loss of Cdx1aand Cdx4 functions led to ectopic expression of the hindbraingenes and ectopic formation of the hindbrain neurons (Figs 2, 3).Mutations in, or the inhibition of, caudal-related genes isreported to affect the development of the posterior body structurein invertebrate and vertebrate species (Chawengsaksophak etal., 2004; Macdonald and Struhl, 1986; Shinmyo et al., 2005;van den Akker et al., 2002; van Nes et al., 2006), but no rolehas been reported for them in inhibiting the ectopic formationof an anterior structure in the posterior body. Our data reveala previously unrecognized role for the caudal-related genesin body patterning.

Our data show that expression of the posterior hox genes inhibits theectopic formation of the posterior hindbrain in cdx1a/4 morphant embryos,suggesting that the posterior hox genes mediate the activity ofCdx. The possibility remains that Cdx proteins by themselvesor downstream genes other than the posterior hox genes suppressthe formation of the posterior hindbrain and anterior spinalcord. To address this issue, loss-of-function experiments forall the posterior Hox proteins must be performed. This is notpossible currently, because there are too many posterior hoxgenes to be knocked down by MOs. Our findings, however, showthat the posterior Hox proteins play at least some part in the Cdx-mediatedinhibition of posterior hindbrain formation.

The Hox proteins interact directly - or indirectly through Pbxproteins - with transcriptional co-repressors and histone deacetylases,and they function as transcriptional repressors (Asahara et al.,1999; Saleh et al., 2000), which implies that the posteriorHox proteins might directly repress the expression of the posteriorhindbrain genes. Our data show, however, that the posteriorHox proteins function as transcriptional activators to repressthe posterior hindbrain genes. Therefore, the Hox proteins mayactivate the expression of transcriptional repressors that inhibitthe expression of the posterior hindbrain genes. Alternatively, posteriorHox proteins might repress the function of transcriptional activatorsthat induce the expression of the posterior hindbrain genes, througha protein-protein interaction or competition for the bindingsites. In any case, the posterior Hox proteins indirectly repressthe expression of the posterior hindbrain genes.

The Cdx-Hox code modifies tissue response to Fgf and RA
It is well known that the same signaling molecules are oftenused for different developmental processes. fgf3 and fgf8 controlthe anteroposterior patterning of the hindbrain and spinal cord (Maveset al., 2002; Walshe et al., 2002; Waskiewicz et al., 2002; Wielletteand Sive, 2004), the morphogenesis of the posterior body (Dubrulleet al., 2001; Sawada et al., 2001) and the development of telencephalon(Shinya et al., 2001; Walshe and Mason, 2003). The RA signalcontrols the anteroposterior patterning of the hindbrain/spinalcord (Begemann et al., 2001; Grandel et al., 2002; Maves etal., 2002; Waskiewicz et al., 2002) in the anterior region andregulates neurogenesis and segmentation in the posterior region(Diez del Corral et al., 2003). The biological activities ofthe Fgf and RA signals must therefore be controlled differentlyin the anterior and posterior regions, by other factors. Here,we were able to demonstrate that Cdx1a and Cdx4 function tocontrol the responsiveness of Fgf and RA signals. First, inhibitionof Cdx1a/4 led to ectopic expression of the posterior hindbrainand anterior spinal cord genes, and the ectopic expression was suppressedby inhibition of Fgf and/or RA signals (Figs 6, 7). The Fgfsignal is known to be required for the formation of posteriorbody (Griffin et al., 1998), and it is possible that the inhibitionof the Fgf signal might secondarily affect ectopic formationthrough the repression of inductive signals from the posteriorbody. The incubation of the cdx1a/4 morphant embryos with theFGF8 protein, however, led to expansion of the ectopic expressionbut did not significantly affect the posterior body structures (Fig. 6),suggesting that the Fgf signal acts directly on the neural tissueto induce the hindbrain genes, and Cdx1a and Cdx4 repress theFgf-dependent ectopic expression. This is consistent with theproposed direct role of Fgf and RA signals in the normal formationof the posterior hindbrain and anterior spinal cord. Our transplantationexperiment also showed that Cdx1a and Cdx4 function in repressingthe hindbrain genes cell-autonomously (Fig. 4). Viewed as awhole, Cdx1a and Cdx4 can be seen as controlling the formationof the posterior neural tissue by modifying the competence ofthese tissues to respond to the Fgf and RA signals.

It is unlikely, however, that Cdx1a and Cdx4 repress the ectopicformation of the hindbrain and anterior spinal cord throughinhibiting the Fgf and RA signaling pathways. Cdx1a requiresFgf signaling to induce the expression of the posterior hoxgenes (Shimizu et al., 2005), and RA signaling is known to beinvolved in neurogenesis of the spinal cord, where Cdx genesare expressed (Diez del Corral et al., 2003). Rather than inhibitingthe Fgf and RA signals then, Cdx1a and Cdx4 actually controlthe responsiveness to the Fgf and RA signaling. Although themolecular mechanism by which the Cdx proteins control the Fgfand RA responsiveness remains unclear, the posterior hox genesare suitable candidates to be involved in this mechanism.

Cdx proteins are involved in the special control of Fgf and RA signaling
In addition to the cell-autonomous role of Cdxs in repressinghindbrain gene expression in the neural tissue, Cdxs also controlthe sources of Fgf and RA signals in the mesodermal tissues.In our study we observed the raldh2 expression domain in theparaxial/lateral mesoderm to shift posteriorly in the cdx1a/4morphant embryos, resulting in overlapping regions of high Fgfand RA signaling in the posteriormost neural tissue (Fig. 5).This is involved in the ectopic formation of the posterior hindbrainand anterior spinal cord. In a previous study we had reportedthat cdx1a and cdx4 are required for the formation of the posteriormesoderm (Shimizu et al., 2005), suggesting that Cdx1a and Cdx4function to separate the regions of high Fgf and RA signalingthough regulating the posterior body formation, thereby preventingectopic formation in the posteriormost neural tissue. We also detectedupregulation of cyp26a1 expression in the anterior spinal cordof the cdx1a/4 morphant embryos (Fig. 5). This is probably due tohigh RA signaling activity, as cyp26a1 is strongly responsiveto RA signaling (Emoto et al., 2005). It is not yet clear, however,exactly how the RA signaling gradient is generated in the posteriorhindbrain in the presence of high Cyp26a1 activity in the cdx1a/4morphant embryos. As the RA signal is high in these embryos,it could be the case that some part of the RA may escape fromthe Cyp26a1-meidated degradation and be sufficient for the formationand patterning of the posterior hindbrain and anterior spinalcord. In the posteriormost neural tissue, the high RA activityprobably contributes to the mirror image duplication in thecdx1a/4 morphant embryos.

Anteroposterior patterning of neural tissue by Fgf, RA and the Cdx-Hox code
How are our present findings integrated with the current modelfor the anteroposterior patterning of neural tissue? The anteroposteriorpatterning of neural tissues is initially regulated by inductivesignals from the dorsal organizer and the non-axial mesendoderm,in which Wnt and Fgf signaling are believed to be involved.The subsequent regional specification is controlled by inductivesignals from the secondary organizing centers and the adjacent mesodermtissues, in which Fgf and RA signaling are involved (Moens andPrince, 2002). cdx1a and cdx4 are regulated by Wnt and Fgf signals (Shimizuet al., 2005), and they confer on the neural tissues differentcompetences for responding to the local Fgf and RA signals.The region in which cdx1a and cdx4 are not expressed takes onthe posterior hindbrain/anterior spinal cord fate in responseto the counter gradients of Fgf and RA signaling. In the posterior neuraltissue, where cdx1a and cdx4 are expressed, cdx1a and cdx4 notonly suppress the posterior hindbrain/anterior spinal cord fate,but also are required for the formation of normal posteriorneural tissue (Shimizu et al., 2005).

A previous study (Bel-Vialar et al., 2002) has reported that,in chick embryos, 3' HoxB genes - which correspond to anteriorhox genes in this study - are responsive to RA signaling, while5' Hox genes (posterior hox genes) are responsive to Fgf signaling.The CDX activity makes the posterior hox genes competent torespond to Fgf signaling. We previously reported that Fgf signalingis also required for the Cdx-mediated expression of hoxa9a andhoxb7a (Shimizu et al., 2005). These reports suggest that Cdxproteins cooperate with Fgf signaling in controlling the patterningand formation of the posterior spinal cord. Consistent with this,our preliminary data show that misexpression of cdx1a activates ectopicexpression of hoxb9a in the hindbrain region in an Fgf-dependentmanner (data not shown). From this perspective, cdx1a and cdx4are key genes for switching the tissue competence to respond toFgf signaling from the anterior to the posterior mode. As inchick embryos, the anterior hox gene hoxb1b is shown to be responsiveto the RA signaling at the gastrula period in zebrafish (Kudohet al., 2002). As paralog group1 (PG1) of the anterior hox geneshave been shown to be involved in the formation of posteriorhindbrain (r4-r6) in various species (Carpenter et al., 1993; Chisakaet al., 1992; Dolle et al., 1993; Gavalas et al., 1998; Lufkinet al., 1991; Mark et al., 1993; McClintock et al., 2001; Rosseland Capecchi, 1999; Studer et al., 1998), then this suggeststhat the anterior hox genes also cooperate with Fgf and RA signalingin the formation of the posterior hindbrain.

Our findings provide compelling evidence that a Cdx-Hox codecontrols the tissue competence to respond to the inductive signalsthat control the anteroposterior patterning of neural tissues.The roles of the Cdx-Hox code in neural patterning illuminateat least one mechanism by which a given inductive signal cancontrol different processes during embryogenesis.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/133/23/4709/DC1

ACKNOWLEDGMENTS

We thank H. Okamoto for Tg(isl1:GFP) line; A. Yamamoto for commentson the manuscript; M. Royle for editing the manuscript; H. Akiyama, Y.Wataoka, K. Bando, and A. Katsuyama for fish care and technicalassistance; and the members of the Hibi laboratory for helpfuldiscussions. This work was supported by a grant from the Ministryof Education, Science, Sports and Technology (17570185 to T.S.)and RIKEN (to M.H.).

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