A New 34-Kilodalton Isoform of Human Fibroblast Growth Factor 2 Is Cap Dependently Synthesized by Using a Non-AUG Start Codon and Behaves as a Survival Factor

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Molecular and Cellular Biology, January 1999, p. 505-514, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

A New 34-Kilodalton Isoform of Human Fibroblast Growth Factor 2 Is Cap Dependently Synthesized by Using a Non-AUG Start Codon and Behaves as a Survival Factor

Emmanuelle Arnaud, Christian Touriol, Christel Boutonnet, Marie-Claire Gensac, Stéphan Vagner, Hervé Prats, and Anne-Catherine Prats^*

INSERM U397, Endocrinologie et Communication Cellulaire, Institut Louis Bugnard, C.H.U. Rangueil, 31403 Toulouse Cedex 04, France

Received 30 July 1998/Returned for modification 28 September 1998/Accepted 15 October 1998

	ABSTRACT

Top Abstract Introduction Materials and methods Results Discussion References

Four isoforms of human fibroblast growth factor 2 (FGF-2) result from alternative initiations of translation at three CUGstart codons and one AUG start codon. Here we characterize a new34-kDa FGF-2 isoform whose expression is initiated at a fifthinitiation codon. This 34-kDa FGF-2 was identified in HeLa cellsby using an N-terminal directed antibody. Its initiation codonwas identified by site-directed mutagenesis as being a CUG codonlocated at 86 nucleotides (nt) from the FGF-2 mRNA 5' end. Bothin vitro translation and COS-7 cell transfection using bicistronicRNAs demonstrated that the 34-kDa FGF-2 was exclusively expressedin a cap-dependent manner. This contrasted with the expressionof the other FGF-2 isoforms of 18, 22, 22.5, and 24 kDa, whichis controlled by an internal ribosome entry site (IRES). Strikingly,expression of the other FGF-2 isoforms became partly cap dependentin vitro in the presence of the 5,823-nt-long 3' untranslatedregion of FGF-2 mRNA. Thus, the FGF-2 mRNA can be translated bothby cap-dependent and IRES-driven mechanisms, the balance betweenthese two mechanisms modulating the ratio of the different FGF-2isoforms. The function of the new FGF-2 was also investigated.We found that the 34-kDa FGF-2, in contrast to the other isoforms,permitted NIH 3T3 cell survival in low-serum conditions. A newarginine-rich nuclear localization sequence (NLS) in the N-terminalregion of the 34-kDa FGF-2 was characterized and found to be similarto the NLS of human immunodeficiency virus type 1 Rev protein.These data suggest that the function of the 34-kDa FGF-2 is mediatedby nucleartargets.

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

Fibroblast growth factor 2 (FGF-2) is a prototype of the FGF family of 17 genes coding for either mitogenic proteins, differentiatingfactors, or oncogenic proteins (22, 32, 35, 45, 52).FGF-2 is produced in many cell types and tissues, and its biologicalroles are pleiotropic. It is involved in embryogenesis and morphogenesis,especially in the nervous system and bone formation (11, 50).FGF-2 is a major angiogenic factor and thus a molecule of biologicalinterest in cardiovascular disease therapeutics. However, thisangiogenic effect also activates tumor neovascularization (25).In addition, the mitogenic and differentiating effects of FGF-2confer on it oncogenic potential (13, 42). FGF-2 has alsobeen described as playing a crucial role in wound healing (53).

The pleiotropic roles of FGF-2 can partly be explained by the different modes of action of this factor. On the one hand, itacts in a paracrine and autocrine manner, after being secretedby the producer cell. This mode of action is mediated by the recognitionby FGF-2 of specific receptors, whose activation induces signaltransduction cascades (54). This paracrine and autocrine effectmay also be the result of nucleolar translocation of exogenousFGF-2 (2). On the other hand, FGF-2 also exhibits intracrineaction, thereby allowing a direct effect on intracellular targetsin the absence of secretion (6, 14).

The different modes of action of FGF-2 are in fact the direct consequence of a process of alternative initiation of translationon the FGF-2 mRNA. Four in-frame initiation codons, includingthree CUGs and one AUG, give rise to four FGF-2 isoforms withdistinct features (15, 41). The CUG-initiated forms of 22,22.5, and 24 kDa (HMW [high-molecular-weight] FGF-2) are localizedin the nucleus, whereas the AUG-initiated form of 18 kDa is mostlycytosolic (9, 10). Constitutive expression of the 18-kDaform leads to transformation of adult bovine aortic endothelialcells, whereas expression of the HMW FGF-2 leads to immortalizationof the same cells (13). The 18-kDa FGF-2 is also able to stimulatecell migration and to down-regulate its own receptor, which isnot the case for the HMW FGF-2 (6, 33). These different featuresof the FGF-2 isoforms are correlated to their distinct modes ofaction: the 18-kDa isoform, secreted despite the absence of asignal sequence, is responsible for the paracrine and autocrineeffects. In contrast, the nuclear HMW isoforms are not releasedfrom the cell and are responsible for the intracrine effect ofFGF-2 (6, 14, 34).

We have known for a few years that FGF-2 expression is controlled at the translational level (40). Ninety percent of the6,774-nucleotide (nt)-long human FGF-2 mRNA is composed of nontranslatedregions, with a GC-rich leader of several hundred nucleotidesand an AU-rich 3' untranslated region (UTR) measuring almost 6,000nt (41). Five regulatory elements have been identified in theleader region of the messenger, either in the 5' UTR or in thealternatively translated region (40). One of these elementshas been identified as an internal ribosome entry site (IRES)which enables the FGF-2 mRNA to be translated independently ofthe classical cap-dependent scanning mechanism (29, 47). Afew cellular mRNAs have been shown to possess an IRES (5, 16,30, 36, 46). This feature allows such mRNAs to be expressedin conditions of cap-dependent translation arrest, such as understress (23).

A study of FGF-2 isoform expression in different human cell types has shown that the HMW isoforms are produced in variousimmortalized and transformed cell lines, while primary cells almostexclusively synthesize the 18-kDa form at confluence (48). Furthermore,the HMW isoforms are induced when normal cells are subjected toheat shock and oxidative stress, suggesting that the IRES, locatedjust upstream from the CUG start codons, is activated by stressstimuli. In both transformed and stressed cells, CUG codon expressionis correlated to the binding of specific factors to the FGF-2mRNA leader (48).

In this study, we demonstrate the existence of a new FGF-2 isoform that is generated through an additional process of alternativeinitiation of translation in human FGF-2 mRNA. This fifth FGF-2,with a molecular mass of 34 kDa, is the result of a translationinitiation at a CUG codon located 86 nt downstream from the mRNA5' end. The 34-kDa FGF-2, in contrast to the other FGF-2 isoforms,is exclusively synthesized by a cap-dependent, IRES-independentinitiation mechanism. We also show that the 34-kDa FGF-2, in contrastto the other FGF-2 isoforms, permits NIH 3T3 cell survival inlow-serum conditions. Furthermore, we have identified a new nuclearlocalization signal (NLS) sequence in the N-terminal region specificto this FGF-2isoform.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Plasmid construction. The construct WT5'-FGF (plasmid pSCT-12V) contains the first 1,179 nt of FGF-2 cDNA (with a short 3' UTR) cloned into theXbaI-SacI restriction sites of vector pSCT, under the controlof T7 and cytomegalovirus promoters (40). The construct $Delta$ 1-257(plasmid pSCT-27) corresponds to a deletion of nt 1 to 257 (SmaIsite) of the FGF-2 cDNA in the above-mentioned vector pSCT-12V(40). To obtain the construct WT5'CAT, a PCR fragment containingnt 1 to 312 of the FGF-2 cDNA was synthesized, using oligonucleotideFGF5', described previously (40), and oligonucleotide FLC, complementaryto nt 293 to 312 of FGF-2 cDNA with an ApaI site (Table 1). Thisfragment was introduced between the XbaI and ApaI sites of plasmidpFC2 described previously (47), giving a fusion of nt 1 to 312of the FGF-2 cDNA with the chloramphenicol acetyltransferase (CAT)coding sequence devoid of an AUG.

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TABLE 1. Sequences of oligonucleotides used for mutagenesis

The wild-type FGF-CAT used for Fig. 5 corresponds to the previously described plasmid pFC1 (47); it contains the 539 5'nt of the FGF-2 cDNA fused to the CAT sequence in the vector pSCT.Site-directed mutagenesis of CTG-86 and ACG-122 was obtained intwo steps. The first step was the creation of new restrictionsites. XbaI and BglII sites were introduced at positions 110 and107 of FGF-2 cDNA by PCR mutagenesis using Pwo DNA polymerase(Boehringer) as follows. A PCR fragment was amplified from thetemplate pFC1, using oligonucleotide FGF-5' (see above) as the5' primer and oligonucleotide AUGm, containing the new BglII andXbaI restriction sites and the HgaI site at position 121, as the3' primer (Table 1; see Fig. 4A). The PCR fragment was clonedinto the vector pBluescript KS+ EcoRV site. It was then subclonedfrom pBluescript, using enzymes HindIII and HgaI, into the vectorpFC1; the new plasmid was called pFC1-XB. An SfiI site was introducedat position 152 by insertion of double-stranded oligonucleotideSfi-S/Sfi-AS into plasmid pFC1, between positions 125 (SacII site)and 192 (PstI site) of the FGF-2 cDNA (Table 1); the new plasmidwas called pFC1-Sfi. Both plasmids pFC1-XB and pFC1-Sfi gave thesame FGF-2 isoform expression profile as pFC1 (notshown).

The second step of mutagenesis involved use of the double-stranded oligonucleotide insertion strategy, starting either fromplasmid pFC1-XB or from plasmid pFC1-Sfi. Plasmid pFC1-m1 (CTG-86mutated to ATG) resulted from insertion of the double-strandedoligonucleotide ATG86-S/ATG86-AS into plasmid pFC1-XB betweenpositions 50 (BssHII site) and 110 (XbaI site) (Table 1). Themutation introduced an AgeI site just downstream from the ATG-86codon. Plasmid pFC1-m2 (CTG-86 mutated to CCC) resulted from insertioninto plasmid pFC1-m1 of the double-stranded oligonucleotide CCC86-S/CCC86-ASbetween positions 1 (BamHI site in the polylinker) and 89 (AgeIsite) of the FGF-2 leader sequence (Table 1). Plasmid pFC1-m3(insertion of TAA downstream from CTG-86) was obtained in thesame way as pFC1-m2, but using the double-stranded oligonucleotideTAA89-S/TAA89-AS (Table 1). Both constructs contained a deletionof the 5' region (nt 1 to 76). Plasmid pFC1-m4 (ACG-122 mutatedto GCG) was obtained by insertion of the double-stranded oligonucleotideGCG122-S/GCG122-AS into plasmid pFC1-XB between the BglII site(position 107) and the HgaI site (position 121) (Table 1). PlasmidpFC1-m24 (double mutant of CTG to CCC and of ACG to AAG) was obtainedby ligation of a XbaI-SacI fragment from plasmid pFC1-m4 (containingthe FGF-2 leader region downstream from position 107 and the CATsequence) with an XbaI-SacI fragment from the plasmid pFC1-m2(containing the vector sequence and the FGF-2 leader region in5' from position107).

Plasmids p5'CAT-A0, p5'CAT-A1, and p5'CAT-A7 were derived from the plasmid pKSCAT-pA. pKSCAT-pA had been constructed by insertionof a 70-nt poly(A) fragment (5a) downstream from the CAT sequence,between the SpeI and BamHI sites of plasmid pKSCAT (containingthe CAT sequence subcloned between the HindIII and BamHI sitesof pBlueScript KS+, downstream from the T3 promoter). Plasmidp5'CAT-A0 resulted from introduction of a fragment of plasmidpFC1 (treated with BamHI, Klenow enzyme, and BspEI), containingthe leader region of the FGF-2 cDNA, into plasmid pKSCAT-pA (digestedby HincII and BspEI) upstream from the CAT sequence. To constructp5'CAT-A1, a fragment containing the CAT sequence and the shortestFGF-2 3' UTR (90 nt long) was obtained by PCR from the templatepSCT-DOG (this plasmid had been constructed by insertion of thecomplete FGF-2 3' UTR downstream from the CAT sequence into thevector pSCT-CAT (42a), using oligonucleotides CAT3'-S and UTR3'A1-AS(Table 1) as 5' and 3' primers, respectively. This PCR fragment(digested by BstEI) was introduced into the BspEI and SmaI sitesof p5'CAT-A0, giving rise to plasmid p5'CAT-A1, which has the5' end of FGF-2 fused to CAT, with a 90-nt FGF-2 3' UTR and apoly(A) site. To construct plasmid p5'CAT-A7, a DNA fragment frompSCT-DOG treated with XbaI, Klenow enzyme, and BspEI, and containingthe CAT and FGF-2 5,823-nt-long 3' UTR sequences, was introducedinto the BspEI and SmaI sites of p5'CAT-A0.

Plasmids used for transient transfection, pF18CAT and pF24CAT, expressing chimeric CAT proteins with the N-terminal partsof the 18- and 24-kDa FGF-2 isoforms, respectively, have beendescribed in a previous report (40), as has plasmid pSCT-CAT.Plasmid pSV-CAT was obtained by introducing into the vector pSCTHindIII and SacI sites a PCR fragment, obtained with oligonucleotidesSVNLS-5' and CAT-rev (Table 1), containing the nucleotide sequenceencoding the simian virus 40 (SV40) large-T-antigen NLS precededby an ATG initiation codon, in frame with the CAT open readingframe (ORF). Plasmid pF34CAT was obtained by amplifying a PCRfragment with the 5' primer bigATG-S (corresponding to nt 78 to103 of FGF-2 cDNA but introducing an ATG start codon and precededby a 5' XbaI site) and the 3' primer FGF5'-AS (complementary tont 293 to 323 including the XhoI site [Table 1]). This 245-nt-longfragment was introduced between the XbaI and XhoI sites of plasmidpFC1 (see above). Plasmid pF34 $Delta$ X was obtained by introducing thedouble-stranded oligonucleotide DELNLS-5'/DELNLS-3' between PstIand XmaI sites (positions 192 and 256, respectively); this resultedin deletion of nt 212 to234.

All plasmids used for stable transfection except the plasmid expressing the 34-kDa FGF-2 from an ATG codon (pF34EN) have beendescribed previously (31, 37). Each of these plasmids expressesdistinct (or no, in the case of pEN) FGF-2 isoforms from the firstcistron and the neomycin resistance gene (neo) from the secondcistron controlled by the encephalomyocarditis virus (EMCV) IRES.pF34EN was obtained by introduction of the PCR fragment describedin the previous paragraph between XbaI and XhoI sites of plasmidpFEN, which contains the wild-type FGF-2 cDNA (nt 1 to 1179) upstreamfrom EMCV and neo; in addition, the start codon ATG-485 was changedto TTA by insertion of a PCR fragment in order to prevent expressionof the 18-kDa FGF-2 from plasmid pF34EN (it was not necessaryto mutate the CTGs, as they were extinguished by the upstreamATG start codon [see Fig. 8A]).

Anti-N23 antibody preparation. The synthetic peptide NH2-VNPRSRAAGSPRTRGRRTEERPS-COOH, deduced from the nucleotide sequence of FGF-2 cDNA from positions242 to 310 (41), was provided by Neosystem S.A. This peptidewas coupled to keyhole limpet hemocyanin by using glutaraldehydeand carbodiimide, and the coupled product was used for rabbitimmunization (20). Polyclonal antibodies were purified fromrabbit serum by using an N23 peptide-coupled Affigel 10 column(Bio-Rad).

Cell transfection, fractionation, and immunocytolocalization. COS-7 monkey cells were transfected with DNA (1 µg/ml) by the DEAE-dextran method (47). Cell lysates for Western blots wereprepared 48 h later. For immunocytolocalization experiments, cellswere seeded on lamella before transfection (Life Technologies);48 h later, cells were washed four times with phosphate-bufferedsaline (PBS) and fixed for 7 min with 3% paraformaldehyde. Cellswere washed again three times for 5 min each, once with PBS andtwice with PBS plus 50 mM NH₄Cl, permeabilized for 20 min at 37°Cin PBS plus 0.025% saponin, and then incubated for 20 min at 37°Cwith nonimmune antibody (1/100 in PBS-0.025% saponin-0.5% bovineserum albumin). Cells were then incubated with anti-CAT antibody(1/500; Santa Cruz Biotechnology) for 1.5 h at 37°C, washed againthree times as described above, incubated for 40 min at room temperaturewith fluorescein isothiocyanate-coupled anti-rabbit antibody (1/400;Tebu), and then washed again three times. Lamella were put onmicroscope slides in the presence of 8 µl of Citifluor (Pelco,Inc.).

SK-Hep-1 cells were transfected by using Lipofectin (Life Technologies). Cell fractionation to obtain cytosolic and nuclearextracts was performed as previously described (10, 37).

Stable NIH 3T3 clones were obtained by Lipofectin transfection with the different vectors of the pEN series (see above), andG418 at 1 mg/ml in Dulbecco modified Eagle medium (DMEM; LifeTechnologies) was added 72 h later. The cultures were maintainedfor 2 weeks in the presence of G418, and 10 to 12 clones fromeach transfection experiment were picked up and transferred into24-well plates before cultivation in largerdishes.

Analysis of cell proliferation. The proliferation curves were established with three stable clones from each transfection assay. Two procedures were usedinparallel.

(i) Classical cell counting. Six-well plates were seeded at 20,000 cells per well in DMEM plus 10% calf serum (CS). The next day, the complete medium wasreplaced by DMEM plus 1% CS. This medium was changed every 2 days.Cells were trypsinized every 3 days and counted in a Coulter counter(Coulter Electronics, Coultronics S.A., Andilly,France).

(ii) Crystal violet staining. The staining procedure allows measurement of cell proliferation without the step of cell trypsination. Ninety-six-well plateswere seeded with 750 cells/well in complete medium (DMEM plus10% CS). The next day, the medium was replaced by DMEM plus 1%CS; it was then changed every 2 days. For the proliferation analysis,cells were fixed with 10% glutaraldehyde for 15 min under agitation,then abundantly washed extensively with double-distilled water,and dried for 1 h at room temperature. After addition of 100 µlof 0.1% crystal violet to each well, the plates were incubatedfor 30 min at room temperature under agitation. Cells were thenwashed with water three times and dried for 1 h at room temperature;100 µl of 10% acetic acid (diluted in 200 mM formic acid [pH 6.7])was added, and plates were shaken for 15 min. Optical densitywas read at 540nm.

Western immunoblotting. Total proteins were prepared, quantified, and analyzed by Western immunoblotting (5 µg of proteins from each cell lysate)as previously described (47). FGF-2 and FGF-CAT proteins wereimmunodetected with rabbit polyclonal anti-FGF-2 (Santa Cruz)and anti-CAT (homemade) antibodies, respectively. FGF-2 enrichmentof an HeLa cell extract (from 10⁷ cells) on heparin-Sepharose beads (see Fig. 2) was performedas previously described (13).

CAT activity analysis. Cell pellets were resuspended in 100 mM Tris (pH 7.8)-2 mM MgCl₂ and sonicated four times for 5 s; 35 µl of the cell extractwas mixed with 5 µl of 1 M Tris (pH 7.8), 5 µl of butyryl coenzymeA at 5 mg/ml, and 5 µl of [¹⁴C]chloramphenicol and then incubated for 4 h at 37°C. Then 200µl of 2,6,10,14-tetramethylpentadecane-xylene (2:1) was added,and the samples were vortexed for 30 s. Centrifugation was achievedfor 3 min at 13,000 rpm, and 150 µl of the upper phase was countedin the presence of 3 ml of Ready Safe scintillating liquid ina scintillation counter (43).

In vitro transcription and translation. DNAs were linearized and transcription was performed with T7 or T3 RNA polymerase, using the transcription kits provided byAmbion. RNA transcripts were quantitated by absorbance at 260nm and ethidium bromide staining on agarose gels, and their integritywas verified. Translation was carried out in rabbit reticulocytelysate (RRL) provided by Promega (47). The translation productswere analyzed by electrophoresis on a 12.5% polyacrylamide gel(PAGE) followed by autoradiography and quantitation on a PhosphorImager(MolecularDynamics).

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

Identification of a 34-kDa isoform of FGF-2 resulting from an upstream initiation of translation. As we analyzed endogenous FGF-2 expression in different human cell types, it became apparent that a 34-kDa-migrating proteinwas recognized by anti-FGF-2 antibodies in various transformedcell lines (48). This protein was, for instance, clearly detectableby Western immunoblotting of HeLa and SK-Hep-1 cell extracts (Fig.1). HeLa cell extracts were then run through a heparin-Sepharosecolumn to see if this protein corresponded to FGF-2. As wouldbe expected for an FGF-2 isoform, the 34-kDa protein was retainedby heparin (Fig. 2B, lane 2).

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FIG. 1. Analysis of endogenous FGF-2 isoforms in HeLa and SK-Hep-1 cells. Aliquots (20 µg) of cell extracts from HeLa and SK-Hep-1 cells were analyzed by PAGE and transferred to nitrocellulose (see Materials and Methods). Immunoblotting was performed with anti-FGF-2 antibodies and chemiluminescence detection, immediately followed by autoradiography for 2 h. Positions of migration of size standards (right) and of the FGF-2 isoforms (left) are indicated.

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FIG. 2. Identification of the 34-kDa FGF-2 with anti-N-terminal antibodies. (A) Schema representing the FGF-2 mRNA and the FGF-2 coding sequence, showing positions of the peptides used to prepare the anti-N23 and anti-FGF-2 polyclonal antibodies (see Materials and Methods). (B) Heparin-Sepharose-purified HeLa extract was analyzed by Western immunoblotting with either anti-N23 ( $alpha$ N23) or anti-FGF-2 ( $alpha$ FGF-2) antibodies (see Materials and Methods). Migration of size standards is indicated on the left; migration of FGF-2 isoforms is indicated on the right. The 16-kDa-migrating band revealed in lane 1 by anti-N23 probably corresponds to a cleavage product.

The size of this potential new FGF-2 suggested that it could result from an additional initiation of translation at a codonlocated upstream from the known start codons. We tested this hypothesisby raising an antibody against a peptide (designated N23) deducedfrom the nucleic acid sequence of the FGF-2 cDNA upstream fromthe first CUG start codon (Fig. 2A). This antibody was used ina Western immunoblotting experiment with heparin-Sepharose-retainedHeLa cell proteins. As shown in Fig. 2B (lane 1), the 34-kDa proteinwas recognized by the anti-N23 antibody, in contrast to the otherFGF-2 isoforms. We also detected a 16-kDa-migrating band correspondingto a cleavage fragment of the 34-kDa protein (38).

To check that the 5' UTR of the FGF-2 cDNA was able to initiate translation of the 34-kDa protein, we then studied expressionof the FGF-2 cDNA either with the complete leader or with a deletionof the 5' 257 nt (Fig. 3A). FGF-2 isoform synthesis was analyzedeither by in vitro translation in rabbit reticulocyte lysate (Fig.3B, lanes 1 and 2) or by COS-7 cell transfection and Western immunoblottingwith an anti-FGF-2 antibody (Fig. 3B, lanes 3 and 4). In bothin vitro and in vivo experiments, an additional protein, sometimesmigrating as a doublet, was detected at 34 kDa (Fig. 3B, lanes1 and 3). This 34-kDa protein could not be detected with the 5'-deleted construct (Fig. 3B, lanes 2 and 4). Furthermore, an FGF-CATchimeric construct containing the 5' 312 nt of FGF-2 cDNA fusedto the CAT coding sequence (Fig. 3A) was able to express a fusionprotein, migrating at 33 kDa, which could be detected by bothanti-CAT and anti-N23 antibodies (Fig. 3B, lanes 5 and 6).

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FIG. 3. Analysis of the ability of the FGF-2 mRNA 5' UTR to promote translation initiation of the 34-kDa FGF-2. Expression of the 34-kDa FGF-2 was analyzed for three DNA constructs either by in vitro transcription and translation in RRL or by COS-7 cell transfection followed by Western immunoblotting (see Materials and Methods). (A) Schema of the mRNAs expressed from the different constructs (see Materials and Methods). WT5'-FGF corresponds to the FGF-2 mRNA with a complete 5' leader; $Delta$ 1-257 corresponds to a deletion of nt 1 to 257 in the FGF-2 mRNA 5' end; WT5'CAT corresponds to a fusion of FGF-2 cDNA nt 1 to 312 with the CAT sequence (devoid of an AUG start codon). (B) Analysis of mRNA expression either by in vitro translation (lanes 1 and 2) or by Western immunoblotting (lanes 3 to 6). Names of the antibodies ( $alpha$ FGF-2, $alpha$ CAT, and $alpha$ N23) are indicated at the bottom. Migration of size standards is indicated on the right; migration of FGF-2 isoforms is indicated on the left.

These results demonstrated the existence of a 34-kDa isoform of FGF-2 resulting from a process of alternative initiation oftranslation at a start codon located between nt 1 and 257 of FGF-2mRNA.

The 34-kDa FGF-2 is initiated at a CUG codon located 86 nt from the mRNA 5' end. To identify the start codon that gave rise to the 34-kDa FGF-2, we looked for potential in-frame start codons in the publishednucleotide sequence of the FGF-2 cDNA (41). The only potentialinitiation codon was an ACG at position 154 (Fig. 4A, line 1).However, examination of the published FGF-2 genomic DNA sequence(44) in this region revealed that a C was missing at position159, setting the ACG-154 out of frame (Fig. 4A, line 2). Introductionof the genomic DNA fragment (kindly provided by R. Z. Florkiewicz)corresponding to nt 1 to 312 into our FGF cDNA construct revealedan expression profile identical to that obtained with the cDNA(not shown), suggesting an error in one of the published nucleotidesequences.

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FIG. 4. Sequence of the FGF-2 mRNA leader. (A) The sequence of the FGF-2 cDNA 5' region was obtained by using a DNA analyzer (see Materials and Methods) and compared to the two published sequences. Under the schema of the FGF-2 cDNA indicating the two HgaI sites at positions 121 and 224 downstream from the 5' end are represented the three sequences of the region from 146 to 166. Lines 1 and 2 correspond to the published sequences of the cDNA and genomic DNA, respectively (41, 44). Line 3 is the sequence obtained in this study for both DNAs with the DNA analyzer. The new HgaI site is underlined (position 153). (B) The pFC1 plasmid with the 5' region of the FGF-2 cDNA, its homolog with the corresponding genomic sequence (kindly provided by R. Florkiewicz), and a pFC1-derived plasmid lacking the HgaI site at position 153 (point mutations change nt 153-GACGCGG to 153-GATGGC; published for its in-frame ATG-154 [47]) were BssHII digested. The 291-nt-long resulting fragments were dephosphorylated, kinase treated in the presence of [³²P]ATP, and then digested with enzyme HgaI. Each step was followed by a G50 column purification. The restriction fragments were fractionated on a 15% polyacrylamide-Tris-borate-EDTA gel, which was dried and autoradiographed. Sizes of the expected fragments are (i) 121, 85, 51, and 34 nt in the presence of the new HgaI site and (ii) 121 nt plus a doublet at 85 nt in its absence. The DNA origin (cDNA or genomic) is indicated at the top; control corresponds to the plasmid lacking the HgaI site at position 153. (C) Representation of the new reading frame given by the DNA sequence shown in A (line 3). The sequence between nt 80 and 163 is shown. The two potential initiation codons are shown in boldface; the HgaI site (positions 153 to 157) is underlined.

By sequencing this region of the FGF-2 cDNA with an automatic DNA sequencer (Applied Biosystems), we obtained the DNA sequence153-GACGCGGT downstream from position 153, which still differedfrom the published sequences of cDNA and genomic DNA, i.e., 153-GACGGCTand 153-GACGGT, respectively (Fig. 4A, line 3). According to thisnew sequence, an HgaI restriction site (GACGC) had to be presentat position 153 and two HgaI fragments of 34 and 51 nt shouldbe generated following HgaI enzymatic digestion. As shown in Fig.4B, such HgaI fragments were observed with both the cDNA and thegenomic DNA (lanes 1 and 2) but not with a control DNA in whicha point mutation removes the HgaI site (lane 3); this demonstratedthat the new sequence shown in Fig. 4A, line 3, corresponded tothe correct sequence effectively present in both the FGF-2 genomicDNA and cDNA. This sequence gave two possible in-frame start codons:a CTG codon at position 86 and an ACG codon at position 122 (Fig.4C).

To determine which of the CUG-86 and ACG-122 codons was used as the start codon, point mutations of each or of both togetherwere then introduced into a chimeric FGF-CAT construct in whichthe FGF-2 5' 539 nt was fused to CAT (Fig. 5A). The effect ofeach mutation on translation initiation was analyzed either invitro (in RRL [Fig. 5B]) or in vivo (in COS-7 cells [Fig. 5C]).Translation of the wild-type construct gave rise to a doubletat 42 and 40.5 kDa (consistent with the predicted size of theFGF-CAT protein derived from the 34-kDa FGF-2), the upper bandbeing the most abundant in RRL (Fig. 5B and C, lanes 2). Whereasmutation of CUG-86 to AUG resulted in overexpression of the upperband (Fig. 5B and C, lanes 3), its mutation to CCC or the additionof a UAA codon downstream from it resulted in disappearance ofthe upper band and an increase of the lower band (lanes 4 and5). In contrast, mutation of ACG-122 to GCG did not affect theupper band and resulted in strong decrease of the lower band (lane6). The double mutation of CUG-86 and ACG-122 was, however, followedby the extinction of both bands (lane 7). These data clearly showthat the FGF-2 34-kDa isoform was mostly initiated at CUG-86 (hereaftercalled CUG 0) in vitro and in vivo. The 40.5-kDa band of the doubletseemed to result in part from a secondary initiation at ACG-122(lane 7), while the remaining 40.5-kDa protein expressed fromthe ACG-122 mutant could be attributed to the putative GUG startcodon located just upstream from the ACG codon (Fig. 5A).

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FIG. 5. Identification of the start codon by site-directed mutagenesis. Several point mutations of CTG-86 or of ACG-122 were introduced into a chimeric FGF-CAT construct in which the first 539 nt of FGF-2 cDNA were fused to the CAT sequence (40) (see Materials and Methods). The mutant constructs were used either for in vitro transcription and translation in RRL or for COS-7 cell transfection followed by Western immunoblotting, as for Fig. 3. (A) Representation of nt 83 to 127 of the FGF-2 cDNA. CTG-86 and ACG-122 are represented in boldface; arrows indicate the mutations obtained. (B) Translation of the different in vitro-transcribed mRNAs in RRL. (C) Western immunoblotting of transfected COS-7 cell extracts with anti-CAT antibody. The names of the mutants are indicated above the lanes. WT corresponds to the wild-type FGF-CAT construct; the mutant m24 (lane 7) corresponds to a double mutant (m2 plus m4). Lane 1 corresponds to the control (C) assay without mRNA. Positions of migration of the size standards (left) and of FGF-CAT proteins (right) are indicated. The two bands corresponding to the largest FGF-CAT protein (42 and 40.5 kDa) are shown by arrows.

The 34-kDa isoform of FGF-2 is translated in a cap-dependent manner, independently of the IRES. We have known for several years that the mechanism of synthesis of the FGF-2 isoforms is IRES driven (47). To find out whetherthe 34-kDa CUG 0-initiated isoform expression was cap dependent,in vitro translation experiments were performed with capped anduncapped mRNAs, using increasing concentrations of in vitro-synthesizedpolyadenylated FGF-2 mRNA with or without the 5,823-nt-long 3'UTR (Fig. 6). When mRNAs devoid of a 3' UTR or with a short (90-nt)3' UTR were used, expression of the isoforms initiated at CUG1, 2, or 3 or AUG was, as expected, unaffected by the cap (Fig.6A, lanes 2 to 11; Fig. 6B, left). In contrast, synthesis of the34-kDa FGF-2 was clearly cap dependent (Fig. 6A and B, CUG 0):its expression at the optimal mRNA concentration increased three-to fourfold in the presence of the cap (Fig. 6B, CUG 0, left).Furthermore, this cap dependence was even enhanced in the presenceof the 3' UTR, with a fivefold increase of expression in the presenceof the cap (Fig. 6B, CUG 0, right). Interestingly, the presenceof the 3' UTR also rendered the synthesis of the other isoformspartly cap dependent, with a twofold increase in the presenceof the cap (Fig. 6B, right). mRNA stability was measured to checkthat the mRNAs were not degraded during translation both in thepresence and in the absence of the 3' UTR (not shown).

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FIG. 6. Cap dependence of 34-kDa FGF-2 expression. Capped and uncapped FGF-CAT mRNAs, with or without the FGF-2 mRNA 3' UTR, were transcribed in vitro 2, and different dilutions of each mRNA were translated in RRL in the presence of [³⁵S]methionine and analyzed as for Fig. 5. (A) Autoradiography after PAGE analysis of FGF-CAT mRNA expression. The mRNA was transcribed in vitro from plasmid p5'CAT-A1, in which the first 539 nt of FGF-2 cDNA were fused to the CAT sequence and the shortest FGF-2 3' UTR (90 nt long). The results correspond to representative experiments that were repeated five times, either with a 90-nt-long 3' UTR (p5'CAT-A1) or with no 3' UTR (p5'CAT-A0). Migrations of the size standards and of FGF-CAT proteins are indicated (CUG 0 represents the largest isoform). C (lane 1) is the control without mRNA. FGF-CAT mRNA amounts used in each sample were 0.3, 0.9, 2.8, 8.3, and 25 µg/ml for lanes 2 to 6 (uncapped RNAs) and lanes 7 to 11 (capped RNAs), respectively. (B) FGF-CAT isoform expression using capped and uncapped mRNAs in which the 90-nt-long FGF-2 3' UTR ( $-$ 3' UTR, corresponding to panel A) or the 5,823-nt-long FGF-2 3' UTR (+3' UTR) was quantified by PhosphorImager analysis (ImageQuant software). Expression of each isoform from capped or uncapped mRNA is shown in a separate plot. The data are from representative experiments that were repeated at least five times. (C) Ratio of 34-kDa FGF-2 isoform versus total FGF-2 expression in the presence or absence of a 3' UTR, calculated for capped mRNAs from experiments shown in panel B (expressed as percentage of total FGF-2 expression).

The effect of the long FGF-2 3' UTR on cap dependence of the different FGF-CAT isoforms suggested an effect on the ratio ofthe CUG 0-initiated isoform versus total FGF-CAT expression. Thisratio was calculated for the capped RNA with or without the 3'UTR (Fig. 6C). Interestingly, this ratio increased as a functionof mRNA concentration. This increase was, however, much greaterin the absence of the 3' UTR, with the ratio of CUG 0 isoformversus total FGF-2 attaining 34.5% at the highest mRNA concentration.This ratio did not exceed 11% in the presence of the 3' UTR, suggestinga negative regulation by the long FGF-2 mRNA 3' UTR of the 34-kDaisoform in relation to the other FGF-2isoforms.

To confirm that the 34-kDa FGF-2 was exclusively expressed in a cap-dependent manner, we studied its expression in transfectedCOS-7 cells by using bicistronic vectors CAT-FGF, with or withouta 5' hairpin (Fig. 7A). These vectors enabled us to demonstratethe existence of the FGF-2 IRES in a previous report (47). Asexpected for IRES-driven translation, expression of the FGF-2isoforms initiated at CUGs 1, 2, and 3 and AUG, analyzed by Westernblotting, was not affected by the 5' hairpin (Fig. 7B, lanes 3and 4). In contrast, expression of the 34-kDa FGF-2 initiatedat CUG 0 was detected in the absence of the hairpin but disappearedin its presence (lanes 3 and 4) following cap-dependent CAT expression(Fig. 7B, lanes 1 and 2). This finding indicated that the synthesisof the 34-kDa FGF-2 observed in the absence of a hairpin resultedfrom a cap-dependent reinitiation process, although the distanceof 191 nt between the CAT stop codon and CUG-86 was longer thanthe optimal intercistronic length for reinitiation (28).

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FIG. 7. Expression of the 34-kDa FGF-2 from bicistronic vectors. Bicistronic vectors expressing CAT as first cistron (ORF1) and FGF-2 as second cistron (ORF2) were used to analyze the cap dependence of the 34-kDa FGF-2. (A) Representation of the two constructs with or without the presence of a 5' hairpin. (B) Transfection of COS-7 cells with the bicistronic constructs. CAT expression was analyzed by measuring CAT activity (lanes 1 and 2). FGF-2 expression was analyzed by Western immunoblotting with anti-FGF-2 antibodies (lanes 3 and 4). The presence or absence of a hairpin is indicated by + or $-$ , respectively. Migration of the different FGF-2 isoforms is shown on the right.

In conclusion, these results obtained for RRL and COS-7 transfected cells clearly showed that in contrast to the other isoforms,the new isoform of FGF-2 was exclusively synthesized accordingto a cap-dependentmechanism.

The 34-kDa FGF-2 permits NIH 3T3 cell survival in low-serum conditions. To investigate the function of the 34-kDa FGF-2 and compare it to functions of the other FGF-2 isoforms, NIH 3T3 fibroblastswere permanently transfected with bicistronic vectors expressingseparately the 24-kDa isoform, the 18-kDa isoform, or the 34-kDaisoform from the first cistron and the neomycin resistance genefrom the second cistron (Fig. 8A, pF24EN, pF18EN, and pF34EN,respectively). As a control, NIH 3T3 cells were also transfectedby the empty vector pEN. G418-resistant clones were derived fromthe different transfection experiments, and their FGF-2 productionwas checked by Western immunoblotting with anti-FGF-2 antibody(Fig. 8A).

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FIG. 8. Expression of the different FGF-2 isoforms in permanently transfected NIH 3T3 cells. NIH 3T3 cells were transfected with bicistronic vectors expressing the 24-kDa (pF24EN), the 18-kDa (pF18EN), or the 34-kDa (pF34EN) FGF-2 or no protein (pEN) from their first cistrons and the neomycin resistance gene from their second cistrons; 10 to 12 G418-resistant clones were kept for each transfection, and analyses were performed with at least three clones of each origin. Two clones expressing two different levels of 34-kDa FGF-2 (cl14 and cl19), and one clone expressing a medium level of FGF-2, chosen for 24- and 18-kDa FGF-2 expression, are shown as representative clones. (A) Western immunoblotting was performed with cell extracts of the different clones, using anti-FGF-2 antibody as for Fig. 1. Positions of size standards are represented on the right. (B) Phase-contrast microscopy examination (magnification, ×100) of the different cell clones after 14 days of cultivation in six-well plates in 1% CS (see Materials and Methods). The panels correspond to representative parts of the culture dishes. (C) Proliferation curves obtained by the crystal violet method for cells seeded in 96-well plates and cultivated for 17 days (see Materials and Methods). In this procedure, cell growth is measured by determining the optical density at 540 nm (OD 540). Experiments were done in quadruplicate; they were also reproduced several times in triplicate with the classical cell counting procedure, which always gave similar results (not shown).

The different clones were plated at low cell density and grown in the presence of 1% CS to analyze their ability to proliferateindependently of serum. The cells were counted (by the crystalviolet method; see Materials and Methods) during 17 days of growth,and their phenotypes were compared (Fig. 8B and C). Results showedthat cells expressing either the empty vector pEN, the 24-kDaFGF-2, or the 18-kDa isoform were able to proliferate only duringthe first 9 days; thereafter all of them started to die, as shownby the drastic decrease in cell number in the dishes (Fig. 8C,pEN, pF24EN, and pF18EN). In contrast, the two clones expressingthe 34-kDa FGF-2 did not stop growing and did not exhibit anycell death on day 17 (Fig. 8C, pF34EN-cl14 and -cl19). The proliferationrate of clone 19 was better than that of clone 14, in correlationwith the different levels of 34-kDa FGF-2 production. The phenotypeanalysis performed also showed that the two cell clones expressingthe 34-kDa FGF-2 were still growing in the end of the proliferationexperiment and exhibited a fibroblast aspect, whereas the otherthree were sparse and had a very poor aspect (Fig. 8B).

These results led us to conclude that endogenous expression of 34 kDa FGF-2 permitted NIH 3T3 cell survival in conditionswhere expression of the other FGF-2 isoforms was unable to preventcelldeath.

The 34-kDa FGF-2 contains a Rev-like NLS. The survival role of the 34-kDa FGF-2 distinguished it from the other isoforms and thus raised the question of its mode ofaction. Our first attempt was to determine the intracellular localizationof this new FGF-2.

The 78-amino-acid-long sequence of the 34-kDa FGF-2 N-terminal region was examined and revealed an arginine-rich box, PRRRPRR,reminiscent of the NLS of the human immunodeficiency virus type1 (HIV-1) Rev protein (Fig. 9A and reference 21). This N-terminalregion, either wild type or with the putative NLS deleted, wasfused to CAT protein (Fig. 9B, F34CAT or F34 $Delta$ NCAT). Plasmids expressingthese two CAT fusions, as well as plasmids expressing either CATalone or CAT fused to the SV40 NLS or to the 24-kDa or the 18-kDaFGF-2 N-terminal part (SV-, F24-, or F18CAT, respectively), wereused for cell transient transfection (Fig. 9B). In the first experiment,COS-7 cell transfection was followed by CAT immunodetection insitu, using anti-CAT antibody (Fig. 9B, fluorescent staining).In a second experiment, SK-Hep-1 cell transfection by the differentconstructs was followed by cell fractionation and measurementof CAT activity in the cytoplasmic and nuclear fractions (Fig.9B, histograms). As expected, the CAT and F18CAT controls werecytosolic with both procedures, while the SVCAT and F24CAT constructswere nuclear (Fig. 9B and references 10 and 24). The resultsobtained with the F34CAT fusion clearly indicated a nuclear localization,whereas F34 $Delta$ N-CAT was strictly cytosolic (Fig. 9B). These datashow that the N-terminal portion of the 34-kDa FGF-2 containsan arginine-rich NLS involving the PRRRPRR box and suggest thatthe survival role of this protein is probably mediated by nucleartargets.

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FIG. 9. Characterization of an NLS in the N-terminal domain of the 34-kDa FGF-2. (A) Amino acid sequence of the NH2-terminal domain of the 34-kDa FGF-2 (78 amino acid residues). The boldface boxed characters represent the amino acids that were deleted in construct F34 $Delta$ NCAT. (B) Subcellular distribution of different chimeric CAT proteins was analyzed either by immunocytolocalization in transfected COS-7 cells (fluorescent staining micrographs in the middle) or by fractionation of transfected SK-Hep-1 cells into nuclear and cytosolic extracts (histograms on the right), as described in Materials and Methods. SVCAT fusion contains the minimal SV40 large-T antigen NLS (PKKKRKV [24]). F18- and F24CAT chimeras have N-terminal parts corresponding to the 20 and 75 N-terminal amino acid residues of 18- and 24-kDa FGF-2, respectively. The latter includes the 24-kDa FGF-2 NLS described previously (1). The F34CAT chimera contains the 78-amino-acid N-terminal domain of the 34-kDa FGF-2 shown in panel A. F34 $Delta$ NCAT has a deletion of the arginine-rich box shown in panel A, corresponding to residues 43 to 49. Results from immunocytolocalization and cell fractionation are presented at the right for each chimeric protein and the control (CAT). The subcellular distribution between nucleus and cytosol is represented as a percentage of the total CAT activity measured.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

This work has revealed the existence of a new isoform of FGF-2 whose synthesis is initiated at a fifth alternative initiationcodon, a CUG at position 86 downstream from the mRNA 5' end. Expressionof the 34-kDa FGF-2 was shown to be exclusively cap dependent,in contrast to the IRES-dependent expression of the other FGF-2isoforms of 18, 22, 22.5, and 24 kDa. Furthermore, the long 3'UTR of the FGF-2 mRNA seemed to influence the ratio of the CUG0-initiated isoform versus total FGF-CAT expression in vitro.We have also demonstrated that the 34-kDa FGF-2 isoform, nuclearizedby a novel arginine-rich NLS, has a specific survivalfunction.

This makes the FGF-2 mRNA the most complex system of translational regulation described up to now. As schematized in Fig.10, FGF-2 mRNA can be translated by two alternative mechanisms,depending on the activity of the cap binding protein eIF-4E. Whentranslation occurs according to a cap-dependent mechanism, expressionof the 34-kDa FGF-2 is favored. In contrast, the other isoformsare produced according to an IRES-driven mechanism, although theirsynthesis may also occur according to the cap-dependent mechanismin certain conditions (15a). The balance between these two mechanismscontrols the use of the different initiation codons. This balanceseems to be influenced, at least in vitro, by the long 3' UTRof the FGF-2 mRNA (Fig. 6). The activities of the different regulatorycis elements are presumably controlled by trans-acting factorsbound to the FGF-2 mRNA, whose identification is currently underinvestigation (48).

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FIG. 10. Model of translational regulation of FGF-2 expression. The FGF-2 mRNA can be translated by two alternative mechanisms (see the text): either a cap-dependent mechanism dependent on eIF-4E activity or an IRES-dependent mechanism that is independent of eIF-4E activity. The initiation factors 4A and 4G, forming with eIF-4E the complex eIF-4F, are represented. The 43S corresponds to the 40S ribosome subunit associated with eIF2 and with the initiator tRNA. The two putative IRESes and the 3' UTR are schematized. The start codons of the FGF-2 isoforms are indicated.

From a mechanistic point of view, one could be surprised by the strong polar effect generated by introduction of an AUG inplace of CUG 0, which completely extinguished expression of thoseisoforms initiated at CUGs 1, 2, and 3 (positions 320, 347, and362) in vitro and in vivo (Fig. 5B and C, lanes 3). This interferenceof the AUG at position 86 with the downstream IRES can be explainedby IRES masking and/or destruction due to the presence of theelongation machinery. Such a polar effect is not, however, observedwith an AUG at position 156, which is in a different surroundingcontext and at a longer distance from the mRNA 5' end (47).This IRES extinction observed in the case of an upstream efficientcap-dependent initiation favors the idea that the cap-dependentand IRES-driven mechanisms are exclusive and do not occur simultaneouslyon the same RNAmolecule.

The extinction of downstream-initiated isoform synthesis resulting from the presence of an AUG codon in place of CUG 0 (Fig.5) confers considerable significance on the presence of noncanonicalcodons as initiators in alternative translation initiation systems:if an AUG were naturally present at position 86, the 34-kDa FGF-2would be predominant. This could be harmful to the function ofFGF-2 in the cell as overexpression of the 34-kDa isoform resultsin maintenance of cell proliferation (Fig. 8). Consistent withthis inference, we have detected it only in transformed cell lines(Fig. 1 and reference 48). The presence of a weakly efficientCUG codon to initiate 34-kDa FGF-2 synthesis is a clever way ofmaintaining a correct ratio of the 34-kDa protein in relationto the other isoforms. The crucial role of non-AUG codons in alternativeinitiation systems is not limited to FGF-2. Examples in the literatureinclude the messengers of murine leukemia virus and of the proto-oncogenec-myc, both of which have an alternative CUG initiation codon(19, 39). In the first case, a cap-dependent CUG codon initiatesthe synthesis of a cell surface antigen important for viral disseminationwithin the animal, whereas an IRES-driven AUG codon controls synthesisof the viral capsid proteins; this allows the maintenance of asuitable ratio between the two synthesized proteins (4, 12,49). As regards c-myc mRNA, the CUG- and AUG-initiated proteinsc-Myc1 and c-Myc2, whose synthesis is also controlled by an IRES,have distinct targets as transcription factors and must also bepresent in a suitable ratio (18, 36).

This report suggests for the first time a role for the huge 3' UTR of the FGF-2 mRNA (Fig. 6). This 5,823-nt-long 3' UTR infact corresponds to the longest of several species of the FGF-2mRNA resulting from the use of alternative polyadenylation sites(3, 41, 51). The length of the 3' UTR is in fact regulatedaccording to cell density (7, 46a); this could result in amodulation of the ratio of 34-kDa FGF-2 to the other FGF-2isoforms.

We have demonstrated here that the 34-kDa human FGF-2 does effectively exist in cells (Fig. 2). This protein is detected invarious transformed cell types but not in primary cells (Fig.1 and reference 48). Such an observation is in good agreementwith previous reports that showed an up-regulation of eIF-4E incancer cells (26). As the 34-kDa FGF-2 synthesis is cap dependent,it could be expected to follow the level of eIF-4E activity. Thiswas supported in a study of translational enhancement of rat FGF-2by eIF-4 factors which showed that translation of a rat 31-kDaFGF-2 isoform was induced when the eIF-4E level increased (27).Although the existence of the rat FGF-2 isoform has not been confirmedby specific antibodies, it could correspond to human 34-kDa FGF-2.In that same study, the 22- and 21-kDa rat isoforms were not enhancedby eIF-4E, suggesting that they corresponded to the CUG 1-, 2-,or 3-initiated isoforms of human FGF-2 whose synthesis is IRESdriven. In conclusion, the complex mechanism of FGF-2 mRNA translation,with alternative initiations of translation regulated by the balancebetween cap-dependent and IRES-dependent initiation, seems tobe evolutionarilyconserved.

The important function of the 34-kDa FGF-2 evidenced in the present study could explain its conservation in evolution. Clearly,this FGF-2 isoform is involved in cell growth maintenance, bypreventing cell death in low-serum conditions. Previous reportshave shown that constitutive expression of the 24- or the 18-kDaFGF-2 leads to cell immortalization and/or transformation (13,42). However in our experiments, where cells were seeded atlow density, neither the 18-kDa nor the 24-kDa FGF-2 could preventcell death. This survival effect of endogenous FGF-2 seems tobe a specific function of the 34-kDaisoform.

As regards its mode of action, the presence of an NLS in the N-terminal part of the 34-kDa FGF-2 suggests that this proteinhas nuclear targets and that its effect may be intracrine, likethat of the nuclear 24-kDa isoform. An Arg-rich NLS is also anovel feature for a cellular NLS-containing protein. This NLSresembles the NLS recently described for HIV-1 Rev (RQARRNRRRRWR[21]). Its Arg-rich NLS allows Rev to enter the nucleus througha nonclassical pathway involving its direct interaction via itsNLS with the human nuclear import receptor, importin $beta$ (otherNLS-containing proteins bind to importin $alpha$ receptor, which itselfinteracts with importin $beta$ via an Arg-rich domain [17, 21]).Such an NLS is responsible in the case of HIV-1 Rev for regulationof importation, as the NLS overlaps with the RNA binding domainof the protein and is then masked when Rev bindsRNA.

The existence of two different (and atypical) NLSs in the 34-kDa FGF-2 versus the 21-, 22-, and 24-kDa (HMW) FGF-2 isoformsoffers the possibility of a differential nuclearization regulation.Furthermore, their different N-terminal domains may allow a differentialtargeting of FGF-2 isoforms within the nucleus. On the one hand,the HMW FGF-2 contains a glycine-arginine-rich domain (RGG), whichmight be involved in protein-protein interaction as shown forthe RGG domain of nucleolin (8). On the other hand, the 34-kDaFGF-2 contains an Arg-rich N-terminal domain (Fig. 9A) that rendersit more basic than the other isoforms, with a pI greater than12. This suggests that the N-terminal domain of the 34-kDa FGF-2,in addition to its NLS function, could mediate direct interactionsof the new FGF-2 with nucleicacids.

	ACKNOWLEDGMENTS

Emmanuelle Arnaud and Christian Touriol contributed equally to thiswork.

We thank F. Bayard, B. Bugler, and B. Galy for helpful discussions, D. Villa for pictures, D. Warwick for English proofreading,and C. Zanibellato for technical assistance. We thank R. Z. Florkiewiczfor the gift of the genomic DNA FGF-2 sequence. We also thankE. Bieth for the poly(A)-containing plasmid and A. Ramackers forplasmid pSCT-DOG.

This work was supported by grants from the Association pour la Recherche sur le Cancer, the Agence Nationale de Recherchessur le SIDA, the Ligue Nationale contre le Cancer, the ConseilRégional Midi-Pyrénées, and the European Community BiotechnologyProgram (subprogram Cell Factory, Actions de Recherches Concertées,contract 94/99-181). E. Arnaud received successive fellowshipsfrom the Association pour la Recherche sur le Cancer and fromthe Ligue Régionale contre le Cancer. C. Touriol received successivefellowships from the Ministère de l'Education Nationale et dela Recherche and from the Ligue Nationale contre leCancer.

	FOOTNOTES

^* Corresponding author. Mailing address: INSERM U397, Endocrinologie et Communication Cellulaire, Institut Louis Bugnard, C.H.U.Rangueil, Avenue Jean Poulhès, 31403 Toulouse Cedex 04, France.Phone: 33 (5) 61 32 21 42. Fax: 33 (5) 61 32 21 41. E-mail: pratsac{at}rangueil.inserm.fr.

Present address: Swiss Institute for Experimental Cancer Research, 1066 Epalinges,Switzerland.

REFERENCES

Top
Abstract
Introduction
Materials and methods
Results
Discussion
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33. Mignatti, P., T. Morimoto, and D. B. Rifkin. 1991. Basic fibroblast growth factor (bFGF) released by single isolated cells stimulates their migration in an autocrine manner. Proc. Natl. Acad. Sci. USA 88:11007-11011[Abstract/Free Full Text].

34. Mignatti, P., T. Morimoto, and D. B. Rifkin. 1992. Basic fibroblast growth factor, a protein devoid of secretory signal sequence, is released by cells via a pathway independent of the endoplasmic reticulum-Golgi complex. J. Cell. Physiol. 151:81-93[Medline].

35. Miyake, A., M. Konishi, F. Martin, N. Hernday, K. Ozaki, S. Yamamoto, T. Mikami, T. Arakawa, and N. Itoh. 1998. Structure and expression of a novel member, FGF-16, of the fibroblast growth factor family. Biochem. Biophys. Res. Commun. 243:148-152[Medline].

36. Nanbru, C., I. Lafon, S. Audigier, M. C. Gensac, S. Vagner, G. Huez, and A. C. Prats. 1997. Alternative translation of the proto-oncogene c-myc by an internal ribosome entry site (IRES). J. Biol. Chem. 272:32061-32066[Abstract/Free Full Text].

37. Patry, V., E. Arnaud, F. Amalric, and H. Prats. 1994. Involvement of basic fibroblast growth factor NH2 terminus in nuclear accumulation. Growth Factors 11:163-174[Medline].

38. Patry, V., B. Bugler, F. Amalric, J. C. Promé, and H. Prats. 1994. Purification and characterization of the 210-amino acid recombinant basic fibroblast growth factor form (FGF-2). FEBS Lett. 349:23-28[Medline].

39. Prats, A. C., G. De Billy, P. Wang, and J. L. Darlix. 1989. CUG initiation codon used for the synthesis of a cell surface antigen coded by the murine leukemia virus. J. Mol. Biol. 205:363-372[Medline].

40. Prats, A. C., S. Vagner, H. Prats, and F. Amalric. 1992. cis-acting elements involved in the alternative translation initiation process of human basic fibroblast growth factor. Mol. Cell. Biol. 12:4796-4805[Abstract/Free Full Text].

41. Prats, H., M. Kaghad, A. C. Prats, M. Klagsbrun, J. M. Lélias, P. Liauzun, P. Chalon, J. P. Tauber, F. Amalric, J. A. Smith, and D. Caput. 1989. High molecular mass forms of basic fibroblast growth factor are initiated by alternative CUG codons. Proc. Natl. Acad. Sci. USA 86:1836-1840[Abstract/Free Full Text].

42. Quarto, N., D. Talarico, R. Florkiewicz, and D. B. Rifkin. 1991. Selective expression of high molecular weight basic fibroblast growth factor confers a unique phenotype to NIH 3T3 cells. Cell Regul. 2:699-708[Medline].

42a. Ramackers, A. Unpublished results.

43. Seed, B., and J. Sheen. 1988. A simple phase-extraction assay for chloramphenicol acyltransferase activity. Gene 67:271-277[Medline].

44. Shibata, F., A. Baird, and R. Z. Florkiewicz. 1991. Functional characterization of the human basic fibroblast growth factor gene promoter. Growth Factors 4:277-287[Medline].

45. Smallwood, P. M., I. Munoz-Sanjuan, P. Tong, J. P. Macke, S. H. C. Hendry, D. J. Gilbert, N. G. Copeland, N. A. Jenkins, and J. Nathans. 1996. Fibroblast growth factor (FGF) homologous factors: new members of the FGF family in nervous system development. Proc. Natl. Acad. Sci. USA 93:9850-9857[Abstract/Free Full Text].

46. Teerink, H., H. O. Voorma, and A. A. Thomas. 1995. The human insulin-like growth factor II leader 1 contains an internal ribosomal entry site. Biochim. Biophys. Acta 1264:403-408[Medline].

46a. Touriol, C. Unpublished results.

47. Vagner, S., M. C. Gensac, A. Maret, F. Bayard, F. Amalric, H. Prats, and A. C. Prats. 1995. Alternative translation of human fibroblast growth factor 2 mRNA occurs by internal entry of ribosomes. Mol. Cell. Biol. 15:35-44[Abstract].

48. Vagner, S., C. Touriol, B. Galy, S. Audigier, M. C. Gensac, F. Amalric, F. Bayard, H. Prats, and A. C. Prats. 1996. Translation of CUG- but not AUG-initiated forms of human fibroblast growth factor 2 is activated in transformed and stressed cells. J. Cell Biol. 135:1391-1402[Abstract/Free Full Text].

49. Vagner, S., A. Waysbort, M. Marenda, M. C. Gensac, F. Amalric, and A. C. Prats. 1995. Alternative translation initiation of the Moloney murine leukemia virus mRNA controlled by internal ribosome entry involving the p57/PTB splicing factor. J. Biol. Chem. 270:20376-20383[Abstract/Free Full Text].

50. Wagner, J. A. 1991. The fibroblasts growth factors: an emerging family of neural growth factors. Curr. Top. Microbiol. Immunol. 165:95-118[Medline].

51. Weich, H. A., N. Iberg, M. Klagsbrun, and J. Folkman. 1990. Expression of acidic and basic fibroblast growth factors in human and bovine vascular smooth muscle cells. Growth Factors 2:313-320[Medline].

52. Yamaguchi, T. P., and J. Rossant. 1995. Fibroblast growth factors in mammalian development. Curr. Opin. Genet. Dev.

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34.	Mignatti, P., T. Morimoto, and D. B. Rifkin. 1992. Basic fibroblast growth factor, a protein devoid of secretory signal sequence, is released by cells via a pathway independent of the endoplasmic reticulum-Golgi complex. J. Cell. Physiol. 151:81-93[Medline].
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36.	Nanbru, C., I. Lafon, S. Audigier, M. C. Gensac, S. Vagner, G. Huez, and A. C. Prats. 1997. Alternative translation of the proto-oncogene c-myc by an internal ribosome entry site (IRES). J. Biol. Chem. 272:32061-32066[Abstract/Free Full Text].
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39.	Prats, A. C., G. De Billy, P. Wang, and J. L. Darlix. 1989. CUG initiation codon used for the synthesis of a cell surface antigen coded by the murine leukemia virus. J. Mol. Biol. 205:363-372[Medline].
40.	Prats, A. C., S. Vagner, H. Prats, and F. Amalric. 1992. cis-acting elements involved in the alternative translation initiation process of human basic fibroblast growth factor. Mol. Cell. Biol. 12:4796-4805[Abstract/Free Full Text].
41.	Prats, H., M. Kaghad, A. C. Prats, M. Klagsbrun, J. M. Lélias, P. Liauzun, P. Chalon, J. P. Tauber, F. Amalric, J. A. Smith, and D. Caput. 1989. High molecular mass forms of basic fibroblast growth factor are initiated by alternative CUG codons. Proc. Natl. Acad. Sci. USA 86:1836-1840[Abstract/Free Full Text].
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42a.	Ramackers, A. Unpublished results.
43.	Seed, B., and J. Sheen. 1988. A simple phase-extraction assay for chloramphenicol acyltransferase activity. Gene 67:271-277[Medline].
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46.	Teerink, H., H. O. Voorma, and A. A. Thomas. 1995. The human insulin-like growth factor II leader 1 contains an internal ribosomal entry site. Biochim. Biophys. Acta 1264:403-408[Medline].
46a.	Touriol, C. Unpublished results.
47.	Vagner, S., M. C. Gensac, A. Maret, F. Bayard, F. Amalric, H. Prats, and A. C. Prats. 1995. Alternative translation of human fibroblast growth factor 2 mRNA occurs by internal entry of ribosomes. Mol. Cell. Biol. 15:35-44[Abstract].
48.	Vagner, S., C. Touriol, B. Galy, S. Audigier, M. C. Gensac, F. Amalric, F. Bayard, H. Prats, and A. C. Prats. 1996. Translation of CUG- but not AUG-initiated forms of human fibroblast growth factor 2 is activated in transformed and stressed cells. J. Cell Biol. 135:1391-1402[Abstract/Free Full Text].
49.	Vagner, S., A. Waysbort, M. Marenda, M. C. Gensac, F. Amalric, and A. C. Prats. 1995. Alternative translation initiation of the Moloney murine leukemia virus mRNA controlled by internal ribosome entry involving the p57/PTB splicing factor. J. Biol. Chem. 270:20376-20383[Abstract/Free Full Text].
50.	Wagner, J. A. 1991. The fibroblasts growth factors: an emerging family of neural growth factors. Curr. Top. Microbiol. Immunol. 165:95-118[Medline].
51.	Weich, H. A., N. Iberg, M. Klagsbrun, and J. Folkman. 1990. Expression of acidic and basic fibroblast growth factors in human and bovine vascular smooth muscle cells. Growth Factors 2:313-320[Medline].
52.	Yamaguchi, T. P., and J. Rossant. 1995. Fibroblast growth factors in mammalian development. Curr. Opin. Genet. Dev.