(Received for publication, September 19, 1996, and in revised form, November 15, 1996)
From the Departments of Molecular Biology and
Pharmacology,
Pathology, and § Pediatrics, Washington
University School of Medicine, St. Louis, Missouri 63110 and the
** Division of Congenital Defects, Department of Pediatrics, University
of Washington School of Medicine, Seattle, Washington 98195
FGF-8 is a member of the family of fibroblast growth factors and is expressed during vertebrate embryo development. Eight potential FGF-8 isoforms are generated by alternative splicing in mice, several of which are expressed during embryogenesis in epithelial locations. The significance of the multiple isoforms is currently unknown. In this report, we investigate the expression patterns and the specificity of the FGF-8 isoforms for known fibroblast growth factor (FGF) receptors. RNAs for seven of the eight potential isoforms are present at multiple sites of embryonic Fgf8 expression. None of the FGF-8 isoforms exhibited activity when assayed with BaF3 cells expressing the "b" splice forms of FGF receptors 1-3, which are mostly expressed in epithelial tissues. Mesenchymally expressed "c" splice forms of FGF receptors 2 and 3 and FGF receptor 4 were activated by several FGF-8 isoforms. These findings are consistent with the hypothesis that the multiple FGF-8 isoforms are functionally redundant and function to signal in paracrine (epithelial to mesenchymal) contexts.
The mammalian fibroblast growth factor (FGF)1 family currently consists of structurally related polypeptides encoded by 10 genes (FGF-1-10) (reviewed in Ref. 1; see Refs. 2-4). Four distinct genes code for high affinity transmembrane receptor tyrosine kinases (FGFR1-4) that bind FGF ligands and display varying patterns of expression (reviewed in Ref. 5). Alternative mRNA splicing generates isoforms of receptors 1-3 that exhibit unique ligand binding characteristics (6-9). FGF receptor activation involves ligand binding and receptor dimerization, followed by transphosphorylation of the receptor and transduction of the signal into a biological response (5). FGF signal transduction has been implicated in development, wound healing, angiogenesis, and tumorigenesis (reviewed in Ref. 1). Germ line mutations of FGFs and FGFRs in mice (10-15) and humans (16-21) demonstrate the importance of FGF signaling in the process of development.
FGF-8 was first identified as an androgen-induced growth factor secreted by the mouse mammary tumor cell line SC-3 (2). Subsequently, Fgf8 was identified as a Wnt1-cooperating proto-oncogene in murine mammary tumorigenesis (22). Fgf8 expression has been detected during murine and chicken embryogenesis in regions of outgrowth and patterning, including the primitive epiblast, the apical ectodermal ridge of the limb bud, the primitive streak, the tail bud, the facial primordia, and the midbrain-hindbrain junction (22-29). The murine and human genes encoding FGF-8 have been localized to mouse chromosome 19 and human chromosome 10q24-26 (25, 26, 30, 31). The murine Fgf8 gene is unusual in the FGF family in that there are four exons (exons 1A-1D) equivalent to the usual exon 1 in other FGF genes (22, 25, 32). Alternative splicing of the four alternatively spliced exons results in potentially eight protein isoforms that differ at their amino termini and share a common carboxyl terminus encoded by exons 1D, 2, and 3 (22, 25, 32). Human FGF8 is similar to murine Fgf8 in structure; however, only four of the protein isoforms are encoded by FGF8 due to a blocked reading frame in the longer form of exon 1B (33).
The significance of the multiple FGF-8 protein isoforms is not clear. RNAs encoding several of these isoforms, or the protein isoforms, have been detected in the mouse embryo by ribonuclease protection and in situ hybridization assays (23, 32), demonstrating no significant difference in the expression patterns of the RNAs encoding the different FGF-8 isoforms. One exception is that RNA encoding FGF-8a was not seen in E10.5 tail bud (27). Also, multiple Fgf8 RNAs were detected by reverse transcription-polymerase chain reaction (RT-PCR) in the tail bud, limb bud, forebrain, and midbrain-hindbrain junction of E9.5 embryos, but RNA for FGF-8b was thought to be predominant (25). While there are discrepancies in the temporal and spatial expression of the various isoforms during development, there are some differences in their biological activity. FGF-8b potently transforms NIH 3T3 cells, while FGF-8a and FGF-8c do so weakly (34, 35). FGF-8b binds to and stimulates mitogenesis in cells containing FGFR3c > FGFR4 > FGFR2c, while FGF-8c interacts with FGFR3c > FGFR4 and does not interact with FGFR2c (32). Although FGF-8a had some activity in a limb bud assay (27), no activity for FGF-8a with any of the known FGFRs was demonstrated in vitro (32). FGF-8a, FGF-8b, and FGF-8c did not interact appreciably with FGFR1b, FGFR1c, FGFR2b, or FGFR3b, suggesting that epithelially produced FGF-8 isoforms interact with mesenchymally located receptors (32).
We now show that at multiple sites of Fgf8 expression during murine embryogenesis, RNAs encoding seven of the eight potential FGF-8 protein isoforms are present, suggesting that there is little, if any, temporal or spatial regulation of FGF-8 isoforms during development. We further demonstrate that there are three classes of FGF-8 isoforms with respect to their interactions with FGFRs: FGF-8b, and FGF-8f, which interact with FGFR2c, FGFR3c, and FGFR4; FGF-8c, FGF-8d, FGF-8e, and FGF-8g, which interact with FGFR3c and FGFR4; and FGF-8a, which does not interact with any of the known FGFRs (32), These results suggest that the different FGF-8 isoforms are redundant.
Swiss Webster mouse embryos were obtained from timed matings (B&K Universal, Edmonds, WA). Noon on the day the copulation plug was found was considered to be 0.5 days post-coitum (E0.5). Individual embryos were staged at the time of harvest according to Ref. 36. Microdissection of the embryo parts was performed, and total RNA was prepared from the embryo tissues (Ultraspec RNA isolation system, Biotecx Laboratories, Houston, TX).
First-strand cDNA was synthesized from 4 µg of total RNA in
33-µl reactions using random hexamer primers as described in the first-strand cDNA synthesis kit (Pharmacia Biotech Inc). The entire first-strand reaction was amplified by PCR in 100-µl reactions using
2.5 units of Taq DNA polymerase (Life Technologies, Inc.) and the following Fgf8 primers at a final concentration of
0.1 µM each: forward, 5-TCCGCACCTTCGGCTTGTCC-3
; and
reverse, 5
-CGAGCTCCCGCTGGATTCCT-3
. Thermal cycling (PTC-100, MJ
Research, Inc.) parameters were as follows: 95 °C for 2.5 min,
61 °C for 50 s, and 72 °C for 1 min for the initial cycle,
followed by 34 cycles of 95 °C for 50 s, 61 °C for 50 s, and 72 °C for 1 min, and then a 7-min extension at 72 °C and a
4 °C hold. PCR products were analyzed on 3% agarose (NuSieve) gels
and 8% polyacrylamide gels in Tris borate/EDTA buffer.
The observed PCR fragments were gel-purified and cloned into Bluescript
KS plasmids (Stratagene) by TA cloning (37). The inserts
were sequenced by thermal cycle sequencing with
32P-end-labeled primers (T3, T7, and
Fgf8-specific) and the fmolTM kit
(Promega). The resulting sequences were analyzed with MacVector version
5.0 software (Kodak Scientific Imaging Systems).
Full-length
cDNAs for FGF-8d, FGF-8e, FGF-8f, and FGF-8g isoforms were
generously provided by Philip H. Crossley and Gail R. Martin and
correspond to variants 3, 7, 6, and 5, respectively (25). cDNAs
encoding the mature FGF-8 isoforms (i.e. lacking the signal
peptide sequence and the stop codon) were obtained by PCR methods as
described previously for preparation of isoforms FGF-8a, FGF-8b, and
FGF-8c (32). The following forward primers were used: for FGF-8d and
FGF-8g, 5-AAAGGATCCCAGGTAAGGAGCGCTGCG-3
; and for FGF-8e and FGF-8f,
5
-AAAGGATCCCAGGAAGGCCCGGGCGGGCCT-3
. The following reverse primer was
used for all of the isoforms: 5
-AAAGATCTTCGGGGCTCCGGGGCCC-3
. PCR was
performed under the following conditions: 30 cycles at 95 °C for 1 min, 59 °C for 1 min, and 75 °C for 1 min, followed by a 10-min
extension at the end of cycling at 75 °C. Recombinant Pfu
DNA polymerase (Stratagene) was used with 1 × Pfu
buffer, (2 mM MgCl2), 0.2 mM dNTPs,
1 µM concentrations of each primer, and 10 ng of target
cDNA. The amplified products were electrophoresed, purified from
agarose gels, digested with BamHI and BglII, and
ligated into the vector pQE16 (QIAGEN Inc.).
Each plasmid containing the appropriate FGF-8 coding region was used to transform XL-1 Blue bacteria (Stratagene), followed by sequencing of the plasmid DNA to confirm that there were no mutations. Mutation-free plasmids containing FGF-8 regions were then transfected into the M15 or SG13009 strain of Escherichia coli (QIAGEN Inc.), and the carboxyl-terminal histidine-tagged recombinant FGF-8 (rFGF-8) isoforms were purified using the QIAGEN denaturing protocol (6 M guanidinium chloride, 100 mM sodium phosphate, and 10 mM Tris-Cl, pH 8.0) and nickel-nitrilotriacetic acid-agarose chromatography. Elution of the purified rFGF-8 isoforms was performed with 8 M urea, 100 mM sodium phosphate, and 10 mM Tris-Cl. Renaturation of the rFGF-8 isoforms was achieved by successive dialysis against 1 M urea, 100 mM sodium phosphate, 10 mM Tris-Cl, and 5 mM reduced glutathione, pH 8.0, and then against phosphate-buffered saline with 5 mM reduced glutathione. The rFGF-8 isoforms were then lyophilized to a powder and quantitated using amino acid analysis. Recombinant proteins were analyzed by 12% SDS-polyacrylamide gel electrophoresis and stained by Coomassie Blue (38).
Mitogenic AssaysFull-length cDNAs encoding the three immunoglobulin-like forms of FGFR1b, FGFR1c, FGFR2b, and FGFR2c were cloned into the expression vector pMIRB as described (8, 35). The receptors used were of mouse origin, with the exception of FGFR2b, which was of human origin (9). FGFR3 cDNAs were modified to enhance signaling in BaF3 cells by constructing chimeric cDNAs consisting of the extracellular ligand-binding region of FGFR3 fused to the tyrosine kinase domain of FGFR1 (8). FGFR31b (FGFR3b in the figures) has the extracellular and transmembrane domains from FGFR3b and the tyrosine kinase domain from FGFR1, whereas FGFR31c (FGFR3c in the figures) has the extracellular domain of FGFR3c and the transmembrane and tyrosine kinase domains of FGFR1. These recombinant cDNAs were also cloned into the pMIRB vector.
pMIRB-FGFR plasmids were transfected into BaF3 cells and selected in
the presence of 600 µg/ml G418 (Life Technologies, Inc.) and WEHI-3
conditioned medium as described (8, 9). For mitogenic assays, BaF3
cells expressing each specific FGFR were washed and resuspended in RPMI
1640 medium (Life Technologies, Inc.), 10% neonatal bovine serum,
L-glutamine, and
penicillin-streptomycin/-mercaptoethanol with heparin (2 µg/ml).
22,500 cells in suspension were plated in each well of a 96-well plate.
FGF-8 isoforms d, e, f, and g, as well as FGF-1, were diluted in the
medium described above and added to appropriate wells to give a total
volume of 200 µl/well. The cells were then allowed to incubate at
37 °C for 36-40 h. After incubation, 1 µCi of
[3H]thymidine in 50 µl of medium was added to each
well. Cells were harvested after 4-5 h by filtration through
glass-fiber paper. Incorporated [3H]thymidine was then
quantitated using a Wallac
-plate scintillation counter.
Fgf8 encodes eight potential protein
isoforms, seven of which have been identified (25) by alternative
splicing of exons 1A-1D (Fig. 1). The presence of
multiple FGF-8 isoforms encoded by a single gene raises the question of
whether the isoforms might have unique temporal or spatial expression
patterns or unique abilities to interact with FGFRs. Prior attempts to
analyze the temporal and spatial expression patterns of the different
FGF-8 isoforms have generated conflicting results (23, 25, 26, 32).
Since in situ hybridization and immunohistochemical
approaches are limited by the availability of unique reagents, we chose
to analyze by RT-PCR dissected embryo tissues from several gestational stages for the presence of RNAs that encode FGF-8 isoforms. E7.5 mid-streak embryo; E8.5 forebrain and midbrain; E9.5 prosencephalon and
tail bud; and E10.5 maxillary arch, nasal placode, isthmus, and fore
limb buds all contained eight bands when analyzed on ethidium
bromide-stained polyacrylamide gels (Fig. 2). The bands were further identified as cDNAs encoding FGF-8 isoforms by cloning and sequencing of the observed PCR bands (data not shown). The lower
seven bands corresponded to the prior identified FGF-8a-g isoforms
(25). The upper eighth band corresponded to a partially spliced RNA
that has the intron between the longer form of exon 1B and exon 1C in
the RNA that would otherwise encode FGF-8f (Fig. 1). This upper band
would result in a translation reading frameshift that would not encode
a FGF-8 isoform. This RT-PCR is not "quantitative," but the results
indicate that RNAs for seven of the eight possible FGF-8 proteins are
produced when Fgf8 is expressed during mouse development.
Ligand-Receptor Interactions of the FGF-8 Isoforms
The RNA localization studies (Fig. 2) and prior work (23, 25, 26, 32) indicate that multiple FGF-8 isoforms are produced when Fgf8 is expressed. The apparent absence of different expression patterns raises the possibility that the different FGF-8 isoforms may bind to and activate different FGFRs. We have developed a mitogenic assay for FGF activity in BaF3 cells expressing a single splice form of FGFR1-3 or FGFR4 (8, 9, 39-41). These assays detect the ability of a FGF preparation to activate a known splice version of FGFR and to induce a mitogenic response in BaF3 cells transfected with a construct that expresses the FGFR (measured by [3H]thymidine incorporation into DNA), and they are sensitive to as little as 20 pM FGF-1. Differences in the ability of FGF-8a, FGF-8b, and FGF-8c to activate FGFRs in the mitogenic assay and differences in the ability of FGF-8 isoforms to compete with FGF-1 for binding to various FGFRs suggest that the isoforms may have different functions (32). We therefore examined the ability of the other FGF-8 isoforms to induce mitogenesis in BaF3 cells expressing a single defined FGFR.
We prepared recombinant FGF-8 isoforms (FGF-8d-g) with a
carboxyl-terminal six-histidine tag in the same fashion as was done for
FGF-8a-c (32). The histidine tag was placed at the carboxyl-terminal end because this site was the same for all isoforms and would be
unlikely to affect one isoform selectively. We have shown that for the
FGF-8b isoform, the carboxyl-terminal tag and the absence of
glycosylation in the recombinant isoform do not affect receptor specificity when compared with the native isoform (32). The recombinant
FGF-8 isoforms were of the correct predicted size as assessed by
SDS-polyacrylamide gel electrophoresis (Fig. 3). Additionally, the cDNA constructs were sequenced to confirm that there were no mutations. These recombinant FGF-8 isoforms were used in
the BaF3 mitogenic assay. None of the FGF-8 isoforms was able to induce
a mitogenic response in BaF3 cells expressing FGFR1b, FGFR1c, FGFR2b,
or FGFR3b; however, these BaF3 cell lines all exhibited a good
mitogenic response when incubated with FGF-1 (Fig. 4,
A-C and E). BaF3 cell lines
expressing FGFR2c and FGFR3c responded to some of the FGF-8 isoforms
and to FGF-1 (Fig. 4, D and F). FGFR2c-expressing
cells responded well to FGF-8f and weakly to FGF-8d, but did not
respond to FGF-8e and FGF-8g (Fig. 4D). FGF-8d, FGF-8f, and
FGF-8g all activated FGFR3c-expressing BaF3 cells to a similar extent,
whereas FGF-8e also showed activity, but was only slightly more than
half that of the other three isoforms (Fig. 4F). All four
FGF-8 isoforms as well as FGF-1 were able to induce a mitogenic
response in BaF3 cells expressing FGFR4 (Fig. 4G)
Recombinant FGF-8 isoforms induce mitogenesis
in BaF3 cells expressing FGFR2c, FGFR3c, or FGFR4. BaF3 cells,
stably transfected with and expressing FGFR1b (A), FGFR1c
(B), FGFR2b (C), FGFR2c (D), FGFR3b
(E), FGFR3c (F), or FGFR4 (G), were
treated with rFGF-1 (
), rFGF-8d (
), rFGF-8e (
), rFGF-8f (×), or
rFGF-8g (
) in the presence of 2 µg/ml heparin. The cells were
incubated in the presence of [3H]thymidine, and
3H incorporation into DNA was measured (counts/minute) and
is plotted versus concentration of rFGF. The data points are
the mean of two determinations, and the standard deviation is indicated
by error bars.
FGF-1 induces mitogenesis in all BaF3 cell lines (Fig. 4) (8, 9, 32,
39). To compare the potency of the various FGF-8 isoforms with the
different splice forms of the receptors, we normalized the FGF-8 data
of Fig. 4 to that of FGF-1. Relative mitogenic activity was calculated
at two points on each curve, and the two values were averaged and
plotted in Fig. 5. Data for FGF-8a, FGF-8b, and FGF-8c
are from earlier work (32). There are three classes of FGF-8 isoforms
with respect to their abilities to activate FGFRs: Class 1, containing
FGF-8c, FGF-8d, FGF-8e, and FGF-8g, which induce mitogenesis in cell
lines expressing FGFR3c and FGFR4; Class 2, containing FGF-8b, and
FGF-8f, which induce mitogenesis with FGFR2c, FGFR3c, and FGFR4; and
Class 3, containing FGF-8a, which has no activity in this assay (Fig.
5).
The alternative splicing of Fgf8, resulting in multiple protein isoforms, is unique in the FGF family, and the role of the different isoforms is unclear. One possibility is that the different FGF-8 isoforms are expressed in different temporal and/or spatial contexts. A second possibility is that different FGF-8 isoforms bind to and activate different FGFRs. A third possibility is that the different FGF-8 isoforms are redundant and serve no unique roles. If this latter possibility is true, any regulation of FGF-8 signaling would be at the level of receptor expression. Our results (Fig. 2) and those in the literature (25, 32) indicate that at multiple sites of Fgf8 expression, RNAs encoding all known FGF-8 isoforms are present. It is possible that subtle quantitative differences in the steady-state levels of RNA encoding FGF-8 isoforms exist (25, 27), but the significance of potential differences remains to be determined. Although some regulation of alternative splicing may exist, the regulation is not absolute, and there is no discernible temporal or spatial regulation of FGF-8 isoform expression.
Given the apparent lack of temporal or spatial differences in FGF-8 isoform location, we examined the different FGF-8 isoforms for mitogenic activity in cells expressing defined FGFRs. FGF-8b and FGF-8f are similar in their activation of FGFRs, stimulating mitogenesis with FGFR2c, FGFR3c, and FGFR4 (Figs. 4 and 5). FGF-8c, FGF-8e, and FGF-8g activate FGFR3c and FGFR4, but not FGFR2c (Figs. 4 and 5). FGF-8d is similar to FGF-8b and FGF-8f, but it only weakly activates FGFR2c (Figs. 4 and 5). These results indicate that rather than activating distinct receptors, the FGF-8 isoforms are very similar in activity. None of the isoforms activate the "b" splice forms of FGFR1-3 (Figs. 4 and 5), demonstrating that one role of Fgf8 in development is to signal in a paracrine fashion from epithelial (site of Fgf8 expression) to mesenchymal (location of "c" splice forms of FGFR2 and FGFR3) regions (32).
From a structure-function view, it appears that the 11 amino acids
encoded by the 5-region of the longer form of exon 1D (Fig. 1) are
responsible for the ability of FGF-8 isoforms to activate FGFR2c. The
isoforms that contain these 11 amino acids (FGF-8b, FGF-8d, and FGF-8f)
(Fig. 1) are the only isoforms that activate FGFR2c (Figs. 4 and 5). We
hypothesize that if FGF-8h exists, it would also have some activity for
FGFR2c.
These assays were performed at nanomolar concentrations of FGF-8 (Fig. 4). It is not clear what the physiologically relevant concentration of FGF-8 isoforms is during development. However, we (32) and others (34) have shown some activity of FGF-8 isoforms on FGFR1c when the concentration of FGF-8 is in the micromolar range. The importance of this weaker interaction for normal development remains to be determined.
FGF-8b has recently been shown to induce, initiate, and maintain the development of the chick limb (28) and has been shown to induce an ectopic midbrain when placed in the caudal forebrain of the chick embryo (29). As Fgf8 is expressed normally at these locations in the chick (28, 29) and mouse (23-25, 27), it is likely that one or more of the FGF-8 isoforms normally perform these functions during vertebrate development. Given that FGF-8b can perform these functions (28, 29) and that it is highly conserved evolutionarily (mouse and human, 100% identical; chicken, 82% identical) (28, 33), it seems likely that it is an important FGF-8 isoform. FGF-8f has very similar activity to FGF-8b in our mitogenic assays and is nearly as well conserved evolutionarily as FGF-8b (mouse and human, 97% identical) (33). The role of the other FGF-8 isoforms is less clear. FGF-8c, FGF-8d, FGF-8g, and FGF-8h are not encoded by human FGF8 (33). FGF-8a and FGF-8e are the least potent isoforms in our assays, but they may have roles in non-mitogenic contexts or with as yet undiscovered FGFRs. The possibility of heterodimerization of FGF-8 ligands and their effects on FGFR signaling remain to be determined.
We thank Philip C. Crossley and Gail R. Martin for the generous gift of phages containing cDNA inserts
for FGF-8d, FGF-8e, FGF-8f, and FGF-8g.