1 MRC Centre for Developmental Neurobiology, New Hunts House, Kings College London, Guys Campus, London SE1 9RT, UK
2 Imperial Cancer Research Fund, 44 Lincolns Inn Fields, London WC2A 3PX, UK
* Present address: Albert Einstein College of Medicine, Jack and Pearl Resnick Campus, 1300 Morris Park Avenue, Bronx, NY 10641, USA
Author for correspondence (e-mail: ivor.mason{at}kcl.ac.uk)
Accepted 6 February 2002
![]() |
SUMMARY |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
fgf3 is co-expressed with fgf8 in the hindbrain prior to otic induction and, strikingly, when Fgf3 morpholinos were co-injected together with Fgf8 morpholinos, a significant number of embryos failed to form otocysts. These effects were made manifest at early stages of otic development by an absence of early placode markers (pax2.1 and dlx3) but were not accompanied by effects on cell division or death. The temporal requirement for Fgf signalling was established as being between 60% epiboly and tailbud stages using the Fgf receptor inhibitor SU5402. However, the earliest molecular event in induction of the otic territory, pax8 expression, did not require Fgf signalling, indicating an inductive event upstream of signalling by Fgf3 and Fgf8. We propose that Fgf3 and Fgf8 are required together for formation of the otic placode and act during the earliest stages of its induction.
Key words: Fgf, Otocyst, Placode, Embryo, Induction, Zebrafish
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Experimental studies of the tissue interactions involved in induction and development of the otic placode span much of the last century and include contributions from such luminaries as Yntema (Yntema, 1933), Harrison (Harrison, 1935
), Waddington (Waddington, 1937
) and Zwilling (Zwilling, 1941
) working on amphibian and avian embryos. These and the many subsequent studies have implicated two tissues either acting alone or in combination in the induction of the otic placode: the underlying mesoderm and the adjacent hindbrain. The most generally accepted model is that the surface ectoderm receives an inductive signal from the underlying head mesoderm that renders it competent to form an otic placode. A second signal from the posterior hindbrain is then believed to induce the otic placode and determine its location (for reviews, see Fritsch et al., 1998
; Torres and Giraldez, 1998
). However, the experimental data upon which this hypothesis is based are inconclusive.
A search for the molecular players that regulate development of the otic placode has strongly implicated the fibroblast growth factors (Fgfs). For example, Fgf3 was first detected in rhombomeres (r) 5 and 6 of the mouse hindbrain, adjacent to the developing otic placode (Wilkinson et al., 1988). These expression studies were extended by Mahmood et al. (Mahmood et al., 1995a
; Mahmood et al., 1996
) who reported expression additionally in r4 of the mouse and in r4, 5 and 6 in the chick embryo. However, various attempts to determine Fgf3 function in otic development of these embryos have provided conflicting information. Targeted disruption of the Fgf3 gene in transgenic mice results in a relatively mild otic phenotype, defective formation of the endolymphatic duct, and then only with incomplete penetrance and expressivity (Mansour et al., 1992
). By contrast, application of antisense oligonucleotides to chick embryos resulted in an invagination defect (Represa et al., 1991
) while ectopic expression of Fgf3 in cranial ectoderm using a viral vector resulted in the formation of ectopic vesicles expressing some otic markers (Vendrell et al., 2000
).
Several years ago, we reported the cloning of zebrafish fgf3 and also determined the biological properties of its protein product including its receptor specificity (Kiefer et al., 1996a; Kiefer et al., 1996b
). However, we were unable to determine its developmental role(s) in zebrafish, because of the lack of a means of inhibiting its function. Recently, chemically modified oligonucleotides called morpholinos have been used to specifically inhibit gene function in amphibian and zebrafish embryos (Heasman et al., 2000
; Nasevicius and Ekker, 2000
) and this approach potentially allows targeted knockdown of multiple genes in a single embryo. Morpholinos function by binding to and inhibiting translation of mRNA and are resistant to degradation. This development has allowed us to assess Fgf3 function in zebrafish otic development. We show that embryos with reduced levels of Fgf3 have smaller otic placodes and vesicles, a similar phenotype to that reported in the ace zebrafish which is mutated in the fgf8 gene (Reifers et al., 1998
). Moreover, when we co-inject morpholinos targeted against both fgf3 and fgf8, a significant proportion of embryos fail to develop otic placodes.
![]() |
MATERIALS AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Oligonucleotide sequences were as follows (bold letters indicate nucleotide substitutions in control sequences):
Fgf3 morpholino, 5'-CATTGTGGCATGGCGGGATGTCGGC-3';
Fgf3 control morpholino, 5'-CATTATGTCATGGCGGGAGGTGGGC-3';
Fgf8 morpholino, 5'-GAGTCTCATGTTTATAGCCTCAGTA-3'; and
Fgf8 control morpholino, 5'-GAGTATCAGGTTTATAGACTAAGTA-3'.
After injection, embryos were collected in aquarium water containing methylene blue (Westerfield, 1995) and grown at 28°C in Petri dishes to the desired developmental stages.
For incubation with the Fgfr inhibitor, SU5402 (Calbiochem), embryos were dechorionated by incubation in 1 mg/ml pronase (Sigma) in aquarium water for 7 minutes. Chorions were removed by gently swirling the embryos in several changes of aquarium water, which also served to remove the pronse by serial dilution. Embryos were allowed to develop in petri dishes with a layer of 1% agarose on their base in aquarium water containing methylene blue. Upon reaching the desired stage, they were incubated in 60 µM SU5402 diluted in aquarium water from a 500x stock solution dissolved in DMSO. Control embryos had an equivalent volume of DMSO added to the aquarium water. Following incubation, embryos were washed gently in several changes of aquarium water and then grown to the desired developmental stages.
In situ hybridisation
Embryos were dechorionated as above. In situ hybridisation using NBT/BCIP and Fast Red substrates was performed as described (Shamim et al., 1999; Irving and Mason, 2001
). For colour reactions using p-iodonitrotetrazolium violet (Sigma) as the second substrate embryos were incubated in 0.188 mg/ml 5-bromo-4-chloro-3-indolyl-phosphate and 0.2 mg/ml p-iodonitrotetrazolium violet (Liang et al., 2000
).
Zebrafish Fgf3 protein, anti-Fgf3 serum and western blots
Production of zebrafish Fgf3 protein and the monoclonal antibody, MSD-1, against Fgf3 have been described previously (Mathieu et al., 1995a; Mathieu et al., 1995b
; Kiefer et al., 1996b
). SDS PAGE and immunoblotting techniques were modified from those of Jackson and Dickson (Jackson and Dickson, 1999
). Dechorionated embryos were extracted in sample buffer (4% w/v SDS, 10% v/v 2-mercaptoethanol, 20% v/v glycerol, 0.125M Tris.HCl pH 6.8, Bromophenol Blue) using at least 5 µl per embryo. Extracts were immediately heated at 100°C for 5 minutes, centrifuged and stored at 80°C. Proteins were separated on 12% Laemmli SDS-PAGE gels at 150 V alongside molecular weight markers (BioRad). Gels were briefly equilibrated in 25 mM Tris, 190 mM glycine, 20% v/v methanol prior to electroblotting onto Immobilon P (Millipore) membranes at 110 V for 1.5-2 hours with cooling. Membranes were briefly dried at room temperature, rewet in TBS, 1% Tween-20 for 30 minutes, washed once in TBS, 0.1% Tween-20 and nonspecific binding sites were blocked in TBS, 0.1% Tween-20, 5% w/v non-fat dried milk (Marvel) for 2 hours at room temperature or at 4°C overnight. Filters were washed twice each for 5 minutes in TBS, 0.05% Tween-20 before incubation in MSD-1 diluted 1/1000 in TBS, 1% w/v milk for 2 hours at room temperature on a rocking platform. Filters were washed three times in TBS, 0.05% Tween-20 and incubated for 1 hour in 1/20,000 dilution of goat anti-mouse IgG coupled to horseradish peroxidase in TBS, 1% milk with rocking. Blots were then washed three times in TBS, 0.05% Tween-20 and excess wash buffer drained onto paper towels after the final wash. Filters were placed protein side uppermost on Saranwrap and 0.1 ml/cm2 of lumigen solution (ECL kit, Amersham-Pharmacia) applied for 5 minutes. Excess lumigen solution was drained from the filters, which were wrapped in Saranwrap and exposed to x-ray film (X-Omat-AR, Kodak).
Detection of cell death and proliferation
Dividing cells were detected using an anti-phosphorylated histone H3 (Ser 128) antiserum (Calbiochem) according to the method of Saka and Smith (Saka and Smith, 2001). Embryos were dechorionated as above and fixed overnight in 4% (w/v) paraformaldehyde at 4°C. They were transferred to 100% methanol and stored at 20°C. Embryos were rehydrated through a graded series (75%, 50% and 25%) of methanol in PBS and then washed twice in PBS before being bleached for 1 hour in 1% v/v H2O2, 5% v/v formamide, 0.5xSSC for 30 minutes. They were rinsed with PBS and then with PBSBT [0.2% BSA (fraction V, Sigma), 0.1% v/v Triton X-100 in PBS] and incubated in 10% v/v goat serum in PBSBT for 1 hour. Embryos were then incubated in 1/1000 dilution of anti-phosphorylated histone H3 antiserum overnight at 4°C. They were washed briefly in 10% serum in PBSBT, washed four times each for 1 hour in PBSBT, and then for an hour in 10% goat serum in PBSBT before incubation in 1/250 dilution of anti-rabbit IgG conjugated to horseradish peroxidase (Amersham-Pharmacia) overnight at 4°C. After a brief wash in 10% serum in PBSBT and four washes each for 1 hour in PBSBT, embryos were equilibrated in 0.3 mg/ml DAB in PBS for 10 minutes and then H2O2 was added to 0.03% v/v final. Colour reaction was allowed to develop for 15-30 minutes before being stopped by several rinses with water, then in PBS. Embryos were cleared in 90% glycerol, PBS.
Apoptotic cells were detected using the DeadEndTM colourimetric detection kit (Promega). Embryos were dechorionated and fixed overnight in 4% w/v paraformaldehyde in PBS. They were then incubated in methanol for 30 minutes and rehydrated through a graded series of methanol (75%, 50%, 25%) in PBST (PBS, 0.1% Tween-20), washed twice in PBST and twice in PBS. They were incubated in proteinase K (5 µg/ml in PBS) for exactly 5 minutes, washed in PBS and post-fixed in 4% w/v paraformaldhyde in PBS for 20 minutes. The embryos were then washed three times in PBS and three times in acetone, being stored at 20°C for 10 minutes in the final acetone wash. They were rinsed three times in PBS before being incubated for 10 minutes with equilibration buffer (DeadEnd kit). The equilibration buffer was removed and replaced with the terminal transferase reaction mix containing biotinylated UTP (DeadEnd kit) and the reaction was incubated at 37°C for 3 hours. Embryos were washed in 2xSSC for 30 minutes, three times in PBST and three times in PBS before being incubated in streptavidin-HRP 1/500 in PBS for 1 hour. After three washes in PBS, the colour reaction was performed using the DAB substrate and reaction mix provided with the kit. The reaction was stopped with several washes in distilled water, then in PBS and embryos were cleared in 90% glycerol, PBS.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
As is the case in avian embryos (Groves and Bronner-Fraser, 2000), the morphological manifestation of the zebrafish otic placode is presaged by the expression of transcripts of a number of genes. dlx3, which is initially expressed at the neurectoderm-ectoderm interface of the cranial neural plate, becomes upregulated in the prospective otic territory by bud stages (10 hours) and then becomes restricted to the otic placode (Ellies et al., 1997
; Mendonsa and Riley, 1999
). pax8 is expressed in ectoderm in the region of the prospective otic placode from bud stages (10 hours) and expression is confined to the otic placode when the latter becomes visible morphologically. Two other members of the Pax family, pax2.1 and pax2.2, are expressed in a similar manner in the prospective otic territory from two somites and three somites, respectively (Pfeffer et al., 1998
). Thereafter, the placode can be distinguished using Normarski optics from 9 somites, invaginates to form a vesicle by 19 somites and otoliths are visible from 25 hours (prim 7) (Kimmel et al., 1995
). Thus, our study indicates that the onset of fgf3 expression precedes that of the first molecular markers of prospective otic ectoderm.
We have compared the spatial relationship of fgf3 transcripts with three of these markers, dlx3, pax2.1 and pax8, at early stages of otic placode development. dlx3 expression is detected adjacent to the r4 fgf3 expression domain and extends approximately two rhombomere lengths posterior to r4 (Fig. 1J,K). The pax2.1 and pax8 domains also lie adjacent to r4 but extends both anteriorly, adjacent to r3, and posteriorly, adjacent to r5 and r6 (Fig. 1L,M), and thus may define a region of otic competence rather than the presumptive placode itself.
Transcripts of a second member of the Fgf family, fgf8 which signals from the isthmus to pattern midbrain and anterior hindbrain (Reifers et al., 1998), was also found to be expressed in the presumptive r4 territory at 90% epiboly prior to its expression in the isthmus (midbrain-hindbrain junction; Fig. 1N) (Phillips et al., 2001
) (J. W., H. M. and I. M., unpublished). Thus, at least two Fgfs are expressed in the hindbrain adjacent to the presumptive otic territory before the first molecular markers of the specification of the latter.
Inhibition of Fgf3 and Fgf8 together results in absence of the otic vesicle
To investigate Fgf3 function in the zebrafish embryo, we used morpholino oligonucleotides (Nasevicius and Ekker, 2000) injected into one- to eight-cell stage embryos to inhibit translation of Fgf3 protein. Zebrafish Fgf3 is a protein with an Mr of about 28,000 when detected on immunoblots (Fig. 2A). Fgf3 protein in blots of total protein extracts from individual embryos that had been injected with Fgf3 morpholino (Fgf3mo) was either greatly reduced or undetectable when compared with either wild-type fish or fish injected with a control morpholino which differed by only four nucleotides from the Fgf3mo (Fig. 2B) (J. W., H. M. and I. M. submitted and data not shown). The level of repression of translation varied between different Fgf3mo-injected embryos and thus it was expected that a hypomorphic series would be generated as previously reported by others (Nasevicius and Ekker, 2000
). In addition, using a morpholino against fgf8 (Fgf8mo), we were also able to phenocopy the homozygous ace zebrafish mutant which is mutated in the fgf8 gene. Defects observed in these embryos included loss of cerebellar tissue (Fig. 2C,D), somite defects (data not shown) and reduction in otocyst size. All of these defects were previously reported in homozygous ace fish (Reifers et al., 1998
).
|
|
|
Cell death and division are unaffected by inhibition of Fgf3 and Fgf8
The effects of Fgf3 and Fgf8 morpholinos on otic development might be due to influences on cell death or proliferation in the otic territory. We examined injected embryos for effects on apoptosis using the TUNEL procedure at the time of morphological appearance of the otic vesicle. Apoptotic cells were only infrequently detected in embryos injected with control morpholinos (Fig. 4A,B; n=28), Fgf3 morpholinos (Fig. 4C,D; n=33) or Fgf8 morpholinos (Fig. 4E,F; n=23). By contrast, many more apoptotic cells were detected in embryos injected with Fgf3 and Fgf8 morpholinos in combination (Fig. 4G,H; n=46). However these dying cells were localised primarily to the dorsal neural tube region throughout its length (Fig. 4G) and the prospective otic ectoderm adjacent to the hindbrain showed no increase in numbers of apoptotic cells (Fig. 4H). We also examined embryos at the 8-somite stage, prior to appearance of the otic placode but when molecular markers suggest that the otic ectoderm has been specified. We found very few apoptotic cells either in control embryos or those that had been injected with morpholinos (Fig. 4I-L)
|
Early defects in otic development of Fgf3 and Fgf8 knockdown zebrafish
The early onset of fgf3 and fgf8 expression adjacent to the presumptive otic territory, together with the lack of obvious effects on cell death after morpholino injections, suggested that the absence or reduced size of otic vesicles might be due to defects in induction of the otic ectoderm. To determine whether or not Fgf3 and Fgf8 are required at the earliest stages of otic placode development, we examined expression of two early placode markers, dlx3 and pax2.1, in embryos injected with Fgf3mo and Fgf8mo singly and in combination. We found that neither Fgf3 or Fgf8 morpholinos injected alone prevented early or late expression of otic dlx3 and pax2.1 (Fig. 5B,C,F,G,J,K,N,O). However, expression was both weaker and less extensive along the anteroposterior axis than observed in control embryos (compare with Fig. 5A,E,I,M; Table 1). Other sites of expression were also affected, for example isthmic pax2.1 is lost in Fgf8mo-injected fish as expected from previous studies (Reifers et al., 1998).
|
Inhibition of Fgf signalling confirms its requirement during early otic development
To confirm our findings and to investigate the temporal requirement for Fgf signalling further, we incubated embryos, denuded of their chorions, in SU5402, a widely used inhibitor of Fgf receptor (Fgfr) activation. Predictions based upon structures of co-crystals of Fgf receptor tyrosine kinase domain and SU5402 suggest that it should block kinase activity and therefore signalling by all Fgf receptors (Mohammadi et al., 1997). Embryos were incubated in inhibitor for 5 hours starting at 30% epiboly, 60% epiboly and 5-somite stages, reaching tailbud, 2- to 3-somite and 16-somite stages, respectively, at the end of the incubation period. To demonstrate the effectiveness of the treatment, a subset of the embryos were fixed immediately and processed for in situ hybridisation for transcripts of the Ets family transcription factor, erm. Erm is a member of a subfamily of Ets proteins that are transcriptionally activated by activated Erk1 and Erk2 (MAP kinases), which themselves are activated following Fgfr activation. Distribution of activated Erk protein is identical to erm mRNA distribution during early zebrafish development (J. W. and I. M., unpublished) and closely parallels distribution of fgf3 and fgf8 transcripts. Moreover, treatment with SU5402 abrogates erm expression (Raible and Brand, 2001
; Roehl and Nusslein-Volhard, 2001
).
erm transcripts were either absent or barely detectable in the otic region and hindbrain of all embryos at the end of incubation with SU5402 (Fig. 6D-F), whereas mRNA was detected in the hindbrain and adjacent presumptive otic territory of control embryos at all stages (Fig. 6A-C). Thus, bathing embryos in the inhibitor was sufficient to inhibit Fgfr activity. Other embryos from the same experiment were allowed to develop to the 16-somite stage and then analysed for expression of pax2.1.
|
|
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Comparison of the relationship of the fgf3 expression domain in the hindbrain with those of pax2.1, pax8 or dlx3 in adjacent ectoderm showed that Pax genes were expressed in a region adjacent to rhombomeres 3 to 6. However, dlx3 was only detected adjacent to rhombomeres 4 to 6. This more extensive Pax-positive region has been reported by others in avian embryos (Groves and Bronner-Fraser, 2000) and may represent a region of competence to form otic placode, while the smaller dlx3 domain may reflect a response to a signal that specifies the otic primordium proper. Data on expression of erm, which can be considered to be a direct indicator of cells receiving an Fgf signal, indicates that cells throughout the Pax-positive ectoderm are directly responding to Fgf (Raible and Brand, 2001
).
Inhibition of Fgf3 in zebrafish embryos using morpholinos produced a hypomorphic series as evinced by the variable extent of Fgf protein loss and variability in severity of effects on otic development. The most severely affected embryos showed a reduction in otocyst size of about 30% and this correlated with reductions in level and spatial extent of early molecular markers of the otic placode. The reduction of expression of early otic markers being indicative of an early requirement for Fgf3 in otic placode development.
Embryos in which both Fgf3 and Fgf8 are inhibited lack otic vesicles
The effects of Fgf3 knockdown on otocyst size were remarkably similar to those observed in fgf8 mutant zebrafish (Reifers et al., 1998) and the latter were reproduced by injection of fgf8 morpholinos in this study. Taken together with observations that fgf3 and fgf8 were co-expressed in the presumptive r4 territory of the hindbrain adjacent to the region in which the otic placode arises, this suggested that they might function together during otic development. This was confirmed in experiments in which morpholinos against both were co-injected, resulting in complete loss of the otocyst in a significant proportion of embryos and more severe reduction of otocyst size in others compared with experiments using single morpholinos. We interpret this range of phenotypes as reflecting the generation of a hypomorphic series after morpholino injections as has been reported by others (Nasevicius and Ekker, 2000
) and consistent with variation between complete and partial loss of Fgf3 protein in individual embryos. While this manuscript was in revision, similar findings were reported by others after injection of Fgf3 morpholinos into ace mutant zebrafish embryos (Phillips et al., 2001
). However, Phillips et al. did not investigate specificity of the Fgf3 morpholinos and did not demonstrate knockdown of Fgf3 protein, the latter being important in interpreting variability between injected embryos. In support of redundancy in signalling to induce the otic vesicles, it is noteworthy that mutant fish, which lacked otic vesicles, were not isolated from mutagenesis screens (Whitfield et al., 1996
).
Fgf3 and Fgf8 are required early during induction of the otic placode
Loss of the otocyst in such embryos was presaged by absence of early markers of otic placode; both pax2.1 and dlx3 were not expressed in embryos injected with morpholinos against both Fgfs. Injections of individual morpholinos resulted in considerable reductions in both the spatial extent and relative abundance of transcripts for both of these genes. This effect correlates well with the reduced sizes of otic vesicles observed in older embryos after such treatments and indicates that the extent of the otic primordium may be determined by the level of Fgf signal from the hindbrain.
We examined both cell death and division in the ectoderm at early stages of otic development in such embryos but found no differences when compared with control embryos or those injected with individual morpholinos. Taken together, our data suggest that Fgf3 and Fgf8 are required at the earliest stages of otic placode development. To confirm the requirement for Fgf signalling and provide further data concerning when it is required, we treated embryos at a range of developmental stages with SU5402, a potent inhibitor of Fgfr activity. Embryos treated between 30% epiboly and tailbud and between 60% epiboly and 2-3 somites showed absence of pax2.1 expression, whereas older embryos were unaffected. This suggests that Fgf signalling is required only between 60% epiboly and tailbud stages, correlating well with the onset of fgf3 and fgf8 expression in the hindbrain.
Fgf3 and Fgf8 act directly on presumptive otic ectoderm
A key question concerns whether or not these Fgfs act directly upon presumptive otic ectoderm or indirectly via effects mediated within the developing hindbrain. Certainly, loss of Fgf3 and Fgf8 function has dramatic effects on the patterning of the hindbrain, for example transcripts for valentino/kreisler/mafb are not detected in such embryos (J. W., H. M. and I. M., unpublished). However, evidence suggests that they also act directly on adjacent ectoderm. First, absence of dlx3 transcripts occurs at tailbud stages, simultaneous with absence of the earliest affected marker of hindbrain patterning, valentino (Moens et al., 1996) (J. W., H. M. and I. M., unpublished). More importantly, expression of erm correlates exactly with cells in which Erk1 and Erk2 have been activated by Fgf signalling (Raible and Brand, 2001
; Roehl and Nusslein-Volhard, 2001
). erm transcripts occupy a broad domain within the zebrafish hindbrain at the time of fgf3 and fgf8 signalling (Fig. 5A,B) (Raible and Brand, 2001
; Roehl and Nusslein-Volhard, 2001
) but importantly this also includes the pax2.1-positive ectoderm territory (Raible and Brand, 2001
). Taken together, these data indicate a direct action of hindbrain Fgfs on presumptive otic ectoderm.
The dramatic effects of inhibition of both Fgf3 and Fgf8 together when compared with inhibition of either alone suggest that they might perform redundant functions during otic development. We have determined the receptor specificity of mouse, Xenopus and zebrafish Fgf3 proteins, and in all cases (Kiefer et al., 1993; Mathieu et al., 1995a
; Mathieu et al., 1995b
; Kiefer et al., 1996b
) Fgf3 binds and activates IIIb splice variants of Fgf receptors, particularly of Fgfr2, whereas Fgf8 preferentially activates IIIc isoforms (Ornitz et al., 1996
). Such considerations suggest that each may signal through a different Fgfr isoform and that redundancy may be at the level of activation of intracellular signalling pathways.
Fgf signalling and otic development in other vertebrate classes
Inhibition of Fgf3 function or its ectopic expression in chick or mouse embryos has provided conflicting data concerning its function(s) during otic development. Homozygous Fgf3 null mice exhibit defects in endolymphatic duct formation but with incomplete penetrance and expressivity (Mansour et al., 1992). In addition, kreisler mouse mutants lack hindbrain Fgf3 expression but again have relatively mild otic defects (McKay et al., 1996
). Attempts to inhibit Fgf3 function in chick embryos using antisense oligonucleotides affected otocyst invagination but not placode induction (Represa et al., 1991
), while ectopic Fgf3 expression in cranial ectoderm resulted in formation of small vesicular structures expressing some otic markers (Vendrell et al., 2000
). The relatively mild phenotypes associated with Fgf3 inhibition are consistent with our finding that Fgf8 must be inhibited with Fgf3 to prevent otic placode formation.
Fgf8 expression has not been detected in the hindbrains of chick or mouse embryos despite several detailed studies having been undertaken (Heikinheimo et al., 1994; Ohuchi et al., 1994
; Crossley and Martin, 1995
; Mahmood et al., 1995b
) and otic defects have not been reported in a murine Fgf8 hypomorphic series (Meyers et al., 1998
). This raises the possibility that another Fgf acts alongside Fgf3 in these vertebrate classes, although low level expression of Fgf8 cannot be discounted. Interestingly, we have previously reported Fgf4 transcripts in hindbrain neurectoderm at open neural plate stages in the chick embryo (Shamim and Mason, 1999
), where it is co-expressed with Fgf3 (Mahmood et al., 1995a
). At similar stages, Fgf4 is also co-expressed with Fgf15/Fgf19 in mesoderm underlying the prospective otic placode territory (Shamim et al., 1999
; Ladher et al., 2000
). However, evaluation of the role(s) of both of these in vertebrate otic development awaits appropriate inhibition studies.
The initial stage of otic induction is Fgf-independent
pax8 is currently the earliest molecular marker of the presumptive otic territory (Pfeffer et al., 1998) and, in only one embryo was its expression absent after injections of Fgf3 and Fgf8 morpholinos. Both Fgf4 and Fgf15/Fgf19 are expressed in mesoderm underlying the prospective otic territory in avian embryos prior to the appearance of markers of otic induction. Recent studies have suggested that Fgf15/Fgf19 might be a mesodermal inducer for the otic placode (Ladher et al., 2000
), although its unique specificity for Fgfr4 (Xie et al., 1999
) and the lack of otic defects in Fgfr4-null mice (Weinstein et al., 1998
) indicate that it might not act alone. To further investigate the potential role of other Fgfs, including those that are mesodermally expressed, we examined embryos treated with SU5402 from 30% epiboly for expression of pax8 transcripts and failed to find any evidence of a requirement for Fgf signalling in its induction.
Ladher et al. (Ladher et al., 2000) also implicated Wnt8c, which is expressed in the developing hindbrain, as a component of the inductive cascade in avian embryos. However, inhibition of retinoic acid signalling in the chick embryo results in absence of Wnt8c but otic induction is unaffected (Dupe and Lumsden, 2001
), Thus, a different non-Fgf signal is most probably involved in initiation of otic induction. It is possible that this initiation signal is provided, at least in part, by the cranial mesendoderm, as pax8 expression is delayed in one-eyed pinhead zebrafish mutants, which lack that tissue (Mendonsa and Riley, 1999
; Phillips et al., 2001
), but is subsequently rescued possibly by neurectodermal Fgf signalling.
We conclude that a non-Fgf signal(s), possibly of mesendodermal origin, provides the first inductive cue in specification of the otic ectoderm. Shortly thereafter, signalling by Fgf3 and Fgf8 from the hindbrain induce the second phase of gene expression within the latter territory further elaborating its developmental programme. Inhibition of both Fgfs results in a failure to execute that programme beyond its earliest stages.
![]() |
ACKNOWLEDGMENTS |
---|
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Crossley, P. H. and Martin, G. R. (1995). The mouse Fgf8 gene encodes a family of polypeptides and is expressed in regions that direct outgrowth and patterning in the developing embryo. Development 121, 439-451.
Dupe, V. and Lumsden, A. (2001). Hindbrain patterning involves graded responses to retinoic acid signalling. Development 28, 2199-2208.
Ellies, D. L., Stock, D. W., Hatch, G., Giroux, G., Weiss, K. M. and Ekker, M. (1997). Relationship between the genomic organisation and the overlapping embryonic expression patterns of the zebrafish dlx genes. Genomics 45, 580-590.[Medline]
Fritsch, B., Barald, K. F. and Lomax, M. (1998). early embryology of the vertebrate ear. In Development of the Auditory System Vol. 9 (ed. E. W. Rubel, A. N. Popper and R. R. Fay). pp. 80-145. New York: Springer.
Groves, A. K. and Bronner-Fraser, M. (2000). Competence, specification and commitment in otic placode induction. Development 127, 3489-3499.
Harrison, R. G. (1935). Factors concerned in the development of the ear in Ambystoma punctatum. Anat. Rec. Suppl. 64, 38-39.
Heasman, J., Kofron, M. and Wylie, C. (2000). ß-catenin signalling activity dissected in the early Xenopus embryo: a novel antisense approach. Dev. Biol. 222, 124-134.[Medline]
Heikinheimo, M., Lawshe, A., Shackleford, G. M., Wilson, D. B. and MacArthur, C. A. (1994). Fgf-8 expression in the post-gastrulation mouse suggests roles in the development of the face, limbs and central nervous system. Mech. Dev. 48, 129-138.[Medline]
Holder, N. and Xu, Q. (1999). Microinjection of DNA, RNA and protein into the fertilized zebrafish egg for analysis of gene function. In Methods in Molecular Biology 97: Molecular Embryology (ed. P. Sharpe and I. Mason), pp. 462-487. Humana Press.
Irving, C. and Mason, I. (2002). In situ hybridisation and sectioning of whole embryos and tissues. In Microscopy and Histology for Molecular Biologists (ed. J. Kiernan and I. Mason). London: Portland Press (in press).
Jackson, D. I. and Dickson, C. (1999). Protein techniques. In Methods in Molecular Biology 97: Molecular Embryology (ed. P. Sharpe and I. Mason), pp. 699-708. Humana Press.
Kiefer, P., Mathieu, M., Close, M. J., Peters, G. and Dickson, C. (1993). FGF3 from Xenopus laevis. EMBO J. 12, 4159-4168.[Abstract]
Kiefer, P., Strahle, U. and Dickson, C. (1996a). The zebrafish Fgf-3 gene: cDNA sequence, transcript structure and genomic organization. Gene 168, 211-215.[Medline]
Kiefer, P., Mathieu, M., Mason, I. and Dickson, C. (1996b). Zebrafish FGF-3 has properties in between those of the mouse and Xenopus homologues. Oncogene 12, 1503-1511.[Medline]
Kimmel, C. B., Ballard, W. W., Kimmel, S. R., Ullmann, B. and Schilling, T. F. (1995). Stages of the embryonic development of the zebrafish. Dev. Dyn. 203, 253-310.[Medline]
Ladher, R. K., Anakwe, K. U., Gurney, A. L., Schoenwolf, G. C. and Francis-West, P. H. (2000). Identification of synergistic signals initiating inner ear development. Science 290, 1965-1967.
Liang, J. O., Etheridge, A., Hantsoo, L., Rubinstein, A. L., Nowak, S. J., Belmonte, J. C. I. and Halpern, M. E. (2000). Asymmetric Nodal signaling in the zebrafish diencephalon positions the pineal organ. Development 127, 5101-5112.
Lombardo, A., Isaacs, H. V. and Slack, J. M. (1998). Expression and functions of FGF-3 in Xenopus development. Int. J. Dev Biol. 42, 1101-1107.[Medline]
Mahmood, R., Kiefer, P., Guthrie, S., Dickson, C. and Mason, I. J. (1995a). Multiple roles for FGF-3 during cranial neural development of the chicken. Development 121, 1399-1410.
Mahmood, R., Bresnick, J., Hornbruch, A., Mahony, K., Morton, N., Colquhoun, K., Martin, P., Lumsden, A., Dickson, C. and Mason, I. (1995b). FGF-8 in the mouse embryo: a role in the initiation and maintenance of limb bud outgrowth Curr. Biol. 5, 797-806.[Medline]
Mahmood, R., Mason, I. J. and Morriss-Kay, G. M. (1996). Expression of Fgf-3 in relation to hindbrain segmentation, otic pit position and pharyngeal arch morphology in normal and retinoic acid-exposed mouse embryos. Anat. Embryol. 194, 13-22.[Medline]
Mansour, S. L., Goddard, J. M. and Capecchi, M. R. (1992). Mice homozygous for a targeted disruption of the proto-oncogene int-2 have developmental defects in the tail and inner ear. Development 117, 13-28.
Mathieu, M., Kiefer, P., Mason, I. and Dickson, C. (1995a). Fibroblast growth factor (FGF). 3 from Xenopus laevis (XFGF-3). binds with high affinity to FGF receptor 2. J. Biol. Chem. 270, 6779-6787.
Mathieu, M., Chatelain, E., Ornitz, D., Bresnick, J., Mason, I., Kiefer, P. and Dickson, C. (1995b). Receptor binding and mitogenic properties of mouse fibroblast growth factor 3 (FGF3); modulation of response by heparin. J. Biol. Chem. 270, 24197-24203.
McKay, I. J., Lewis, J. and Lumsden, A. (1996). The role of FGF-3 in early inner ear development: an analysis in normal and kreisler mutant mice. Dev. Biol. 174, 370-378.[Medline]
Mendonsa, E. S. and Riley, B. B. (1999). Genetic analysis of tissue interactions required for otic placode induction in the zebrafish. Development 206, 100-112.
Meyers, E. N., Lewandoski, M. and Martin, G. R. (1998). An Fgf8 mutant allelic series generated by Cre-and Flp-mediated recombination. Nat. Genet. 18, 136-141.[Medline]
Moens, C. B., Yan, Y. L., Appel, B., Force, A. G. and Kimmel, C. B. (1996). valentino: a zebrafish gene required for normal hindbrain segmentation. Development 122, 3981-3990.
Mohammadi, M., McMahon, G., Sun, L., Tang, C., Hirth, P., Yeh, B. K., Hubbard, S. R. and Schlessinger, J. (1997). Structures of the tyrosine kinase domain of fibroblast growth factor in complex with inhibitors. Science 276, 955-960.
Nasevicius, A. and Ekker, S. C. (2000). Effective targeted gene knockdown in zebrafish. Nat. Genet. 26, 216-220.[Medline]
Ohuchi, H., Yoshioka, H., Tanaka, A., Kawakami, Y., Nohno, T. and Noji, S. (1994). Involvement of androgen-induced growth factor (FGF-8). gene in mouse embryogenesis and morphogenesis. Biochem. Biophys. Res. Commun. 204, 882-888.[Medline]
Ornitz, D. M., Xu, J., Colvin, J. S., McEwen, D. G., MacArthur, C. A., Coulier, F., Gao, G. and Goldfarb, M. (1996). Receptor specificity of the fibroblast growth factor family. J. Biol. Chem. 271, 15292-15297.
Oxtoby, E. and Jowett, T. (1993). Cloning of the zebrafish krox-20 gene (krx-20). and its expression during hindbrain development. Nucleic Acids Res. 21, 1087-1095.[Abstract]
Phillips, B. T., Bolding, K. and Riley, B. B. (2001). Zebrafish fgf3 and fgf8 encode redundant functions required for otic placode induction. Dev. Biol. 235, 351-365.[Medline]
Pfeffer, P. L., Gerster, T., Lun, K., Brand, M. and Busslinger, M. (1998). Characterisation of three novel members of the zebrafish Px2/5/8 family: dependency of Pax5 and Pax8 on the Pax2.1(noi). function. Development 125, 3063-3074.
Reifers, F., Bohli, H., Walsh, E. C., Crossley, P. H., Stainier, D. Y. and Brand, M. (1998). Fgf8 is mutated in zebrafish acerebellar (ace). mutants and is required for maintenance of midbrain-hindbrain boundary development and somitogenesis. Development 125, 2381-2395.
Represa, J., Leon, Y., Miner, C. and Giraldez, F. (1991). The int-2 proto-oncogene is responsible for induction of the ear. Nature 353, 561-563.[Medline]
Raible, F. and Brand, M. (2001). Tight transcriptional control of the ETS domain factors Erm and Pea3 by FGF signalling during early zebrafish development. Mech. Dev. 107, 105-117.[Medline]
Roehl, H. and Nusslein-Volhard, C. (2001). Zebrafish pea3 and erm are general targets of FGF8 signaling. Curr. Biol. 11, 503-507.[Medline]
Saka, Y. and Smith, J. C. (2001). Spatial and temporal patterns of cell division during Xenopus embryogenesis. Dev. Biol. 229, 307-318.[Medline]
Shamim, H. and Mason, I. (1999). Expression of Fgf4 during early development of the chick embryo. Mech. Dev. 85, 189-192.[Medline]
Shamim, H., Mahmood, R. and Mason, I. (1999). In situ hybridisation to RNA in whole embryos. In Methods in Molecular Biology 97: Molecular Embryology (ed. P. Sharpe and I. Mason), pp 623-634. Humana Press.
Torres, M. and Giraldez, F. (1998). The development of the vertebrate inner ear. Mech. Dev. 71, 5-21.[Medline]
Vendrell, V., Carnicero, E., Giraldez, F., Alonso, M. T. and Schimmang, T. (2000). Induction of inner ear fate by FGF3. Development 127, 2011-2019.
Waddington, C. H. (1937). The determination of the auditory placode in the chick. J. Exp. Biol. 14, 232-239.
Weinstein, M., Xu, X., Ohyama, K. and Deng, C. X. (1998). FGFR-3 and FGFR-4 function cooperatively to direct alveogenesis in the murine lung. Development 25, 3615-3623.
Westerfield, M. (1995). The Zebrafish Book. 3rd edn. Eugene, OR: University of Oregon Press.
Wilkinson, D. G., Peters, G., Dickson, C. and McMahon, A. P. (1988). Expression of the FGF-related proto-oncogene Int-2 during gastrulation and neurulation in the mouse. EMBO J. 7, 691-695.[Abstract]
Whitfield, T. T., Granato, M., van Eeden, E. J. M., Schach, U., Brand, M., Furutani-Seiki, M., Hafter, P., Hammerschmidt, M., Heisenberg, C.-P., Jiang, C. P. et al. (1996). Mutations affecting development of the zebrafish inner-ear and lateral-line. Development 123, 241-254.
Xie, M. H., Holcomb, I., Deuel, B., Dowd, P., Huang, A., Vagts, A., Foster, J., Liang, J., Brush, J., Gu, Q. et al. (1999). FGF-19, a novel fibroblast growth factor with unique specificity for FGFR4. Cytokine 11, 729-735.[Medline]
Yntema, G. L. (1933). Experiments on determination of the ear ectoderm in the embryo of Ambystoma punctatum. J. Exp. Zool. 65, 317-357.
Zwilling, E. (1941). The determination of the otic vesicle in Rana pipiens. J. Exp. Zool. 86, 333-342.