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Glioblastoma Cell-specific Expression of Fibroblast Growth Factor Receptor-1ß Requires an Intronic Repressor of RNA Splicing¹

Section of Endocrine Neoplasia and Hormonal Disorders, Department of Medical Specialties, The University of Texas, M. D. Anderson Cancer Center, Houston, Texas 77030

	ABSTRACT

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The fibroblast growth factor receptor-1 (FGFR-1) primary transcript is alternatively processed to produce receptors that vary in their ligand affinity and specificity. A high affinity form of this receptor—FGFR-1ß—that lacks the exon is observed on the neoplastic transformation of glial cells. In this study, we have identified a 62-bp sequence located 97 bp downstream from the exon that is required for the exclusion of this exon in a human glioblastoma cell line. Deletion or mutation of this sequence is sufficient to allow enhanced inclusion of the exon or a heterologous exon in glioblastoma cells. Therefore, it would appear that this sequence element plays a key role in the glioblastoma-specific splicing to form FGFR-1ß mRNA.

	Introduction

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The FGFR-1³ is part of a family of tyrosine kinase receptors known to play key roles in the growth and differentiation of the several cell types. Alternative RNA processing of the FGFR-1 primary transcript creates functional diversity for this receptor by altering ligand specificity and affinity, subcellular localization, and activity of the tyrosine kinase (1 , 2) . Therefore, dysregulation of FGFR-1 alternative splicing has the potential to alter several processes involving normal cellular growth. In normal human glial cells, the predominantly expressed form of FGFR-1 (FGFR-1) has three extracellular immunoglobulin-like domains involved in ligand binding. However, in glial cell tumors there is a switch to a form having two immunoglobulin-like domains (FGFR-1ß; Ref. 3 ). The absence of the third domain has been shown to give FGFR-1ß an affinity for acidic and basic FGFs 10-fold greater than that of the FGFR-1 (4 , 5) . Expression of this form of FGFR-1 in glial cells is believed to provide a cell-growth advantage and possibly to contribute to glial cell malignancy. The production of FGFR-1ß results from skipping a single exon ( exon); therefore, alternative RNA processing plays a central role in glial cell malignancy. Using an RNA splicing cell culture model, we have previously identified an exon sequence that is required for exon inclusion (6) . In the present study, we have now identified a sequence located in the downstream intron that is required for exon exclusion in the glioblastoma cell line SNB-19.

	Materials and Methods

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Cell Culture.
The human astrocytoma cell line SNB-19 and the human choriocarcinoma cell line JEG-3 were maintained as described previously (6 , 7) .

Plasmid Constructs.
The plasmid constructs pFGFR-17, pFGFR-19, and pFGFR-20 have been described previously (7) . All of the additional constructs used are derived from pFGFR-17 and maintain the same promoter (Rous sarcoma virus), flanking exons (hMT 2A gene), and vector backbone (pGEM 4; Fig. 1A ). Deletion constructs were created using a strategy in which two EcoRV sites were created by mutagenesis, followed by EcoRV digestion and self-ligation. All of the mutations were introduced using the QuikChange site-directed mutagenesis kit (Stratagene). For some reactions the protocol was modified to employ three primers instead of two primers as described previously (6) . The EcoRV sites were introduced into seven separate locations using primers FP34, FP63, FP64, FP65, FP99, FP100, or FP101. For pFGFR-61, an insert encoding FGFR-1 exon 4 and flanking intron was derived by PCR amplification of a genomic P1 clone with primers FP11 and FP12. The PCR fragment was inserted into pFGFR-49, which was created from pFGFR-17 by the introduction of a HindIII site 97 bp upstream and an EcoRV site 8 bp downstream from the exon by mutagenesis. Mutations were introduced into construct FGFR-17 using primers FP133 through FP138 to create plasmids pFGFR-90, pFGFR-91, pFGFR-92, pFGFR-93, pFGFR-94, and pFGFR-95. Detailed information on the creation of specific plasmids will be provided upon request. All of the mutations and deletions were confirmed by sequencing analysis.

View larger version (46K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Enhancement of -exon inclusion in SNB-19 cells by intron deletion. A, schematic representation of the pFGFR-17 construct and the RNA splicing pathways demonstrating cell-specific -exon recognition. Thin lines and bracket, the FGFR-1 genomic sequence.; thick lines, the sequence derived from the hMT 2A gene that has been fused to the Rous sarcoma virus enhancer/promoter. The numbers (bp) indicate the length of the exons or introns. The relative position of the oligonucleotide primers and the size of RT-PCR products are indicated. Note that the exon is excluded from all RT-PCR observed. Deletion of the FGFR-1 intron sequence was performed on pFGFR-17. B, examination of -exon inclusion in RNA isolated from cells transfected with indicated constructs. Deletions are depicted schematically showing the portion of the FGFR-1 intron remaining downstream from the exon and the size of the deletion provided in parentheses (the complete intron contains an additional 130 nucleotides of the hMT 2A gene sequence). RT-PCRs were performed 72 h after transfection using a 32P-end-labeled primer. Reaction products were separated by PAGE. A representative autoradiograph is shown in the right panels; arrows, RT-PCR products, which include (I) or skip (S) the -exon. Numbers below each lane, quantification of exon inclusion as determined by Molecular Imager analysis. The percentage of -exon inclusion is derived from phosphor counts for the inclusion band divided by the counts for the inclusion and exclusion bands after the subtraction of background counts. The values presented are for three independent transfections + SD.

Oligonucleotide Primers.
The oligonucleotide primers used were as follows: (a) FP11: 5'-GGGGAAGCTTGCAAGACACCTCCAGGT-3'; (b) FP12: 5'-GGGGAGTACTACACGTACCTTGTAGCC-3'; (c) FP34: 5'-GAGGAGGTTCACCGATATCTGAAACTGGCAGAG-3'; (d) FP44: 5'-CCCGCATCACAGGGGAGGAG-3'; (e) FP63: 5'-CAGAGAGGTGACTAGATA-TCGTGGGCCCCAGG-3'; (f) FP64: 5'-GAGATCTGGGCAAGATATCG-TGGAAAAAAATCACAGGG-3'; (g) FP65: 5'-GGAGAGGAACCCAGG-ATATCCGCAAGGGAGCTG-3'; (h) FP99: 5'-CTCCTCCCCCTCCGA-TATCTGCCCCCACTCTGC-3'; (i) FP100: 5'-CAGGGAGCAATGTGATA-TCGCAGCAGTTTCTG-3'; (j) FP101: 5'-CCTCTCTGAGAGCCAGATAT-CGCGGCAGGCAGGG-3'; (k) FP133: 5'-CCCCCTCCGTGATCAAACC-CCACTCAAATTCAGAAACTGCTGC-3'; (l) FP134: 5'-CACTCTGCTT-CAGAAACAAAAAACCACTAACATTGCTCCC-3'; (m) FP135: 5'-CTG-CCCACTAACATAAATCCCTGCCTGCCGC-3'; (n) FP136: 5'-CCAC-TAACATTGCTCCCAAAAAAAAGCGTGGCTTGGCTCTC-3'; (o) FP137: 5'-CCCCCTCCGTGATCAAACCCCACTCAAATTCAGAAACAAAAAA-C-3'; and (p) FP138: 5'-CCACTAACATAAATCCCAAAAAAAA-GC-3'.

	Results and Discussion

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A failure to recognize the exon during RNA processing of the FGFR-1 primary transcript has been correlated with glial cell malignancy (3) . Sequence analysis of a region encompassing the exon has failed to find splice site mutations in glioblastoma cell DNA, which suggests that the aberrant RNA results from changes in trans-acting factors. To begin to identify these regulatory factors, we previously developed an RNA splicing reporter/transfection cell culture model system that mimics the pathways observed in normal brain glial cells and glioblastoma (7) . The reporter construct (pFGFR-17) contains a 3.8-kb fragment of the FGFR-1 genomic sequence inserted into hMT 2A gene intron 1 (Fig. 1A) . RNA transcripts derived from this reporter construct demonstrate cell-specific recognition of the exon; the exon is included predominantly in JEG-3 cells (86%) and excluded in the glioblastoma cell line SNB-19 (27%; Fig. 1B ). Previous studies identified a sequence within the exon that was required for exon inclusion in JEG-3 cells but had little effect on splicing in SNB-19 cells (6) . To identify regulatory sequences involved in the glioblastoma cell-specific splicing event, we have continued our analysis, focusing on the region located downstream from the exon.

Three constructs containing progressive deletions beginning at the 3' end of the FGFR-1 insert were examined for -exon inclusion in transfected SNB-19 and JEG-3 cells (Fig. 1B) . For two of these constructs, pFGFR-19 and pFGFR-20, there was no significant increase in the level of exon inclusion in either SNB-19 or JEG-3 cells. This is consistent with previous findings for these constructs in which intron size rather than the specific sequence was required to maintain exon exclusion in SNB-19 cells (7) . However, the removal of an additional 133 nucleotides of intron (pFGFR-80), resulted in a dramatic increase in exon inclusion in the SNB-19 cells. The inclusion level of the exon went from 38 to 87% in SNB-19 cells, whereas it increased only slightly in JEG-3 cells (Fig. 1B ; compare pFGFR-20 with pFGFR-80).

The data above localize a potential SNB-19 cell-specific inhibitor of -exon inclusion to an intron region between 71 and 204 nucleotides downstream from the exon. However, because these constructs contain large intron deletions, we cannot definitively assign an inhibitory element to this region. The downstream intron in pFGFR-80 is reduced to only 201 nucleotides. Because a small intron size is correlated with enhanced splicing efficiency, it is possible that the elevated inclusion of exon results solely from this reduction (8) . Therefore, we tested constructs containing smaller internal deletions targeted to this region (Fig. 2) . The pFGFR-81 construct contains a 115-bp internal deletion mapped to the region identified in Fig. 1. In transfected SNB-19 cells, the pFGFR-81 construct showed the same dramatic increase in -exon inclusion seen for deletion construct pFGFR-80 (from 27 to 72%; Fig. 2 ). Similarly sized deletions, one immediately downstream (pFGFR-82), and a deletion removing the exon (pFGFR-83) had no effect on the level of -exon inclusion in transfected SNB-19 cells (pFGFR-56 and pFGFR-58; Fig. 2 ). The level of -exon inclusion in transfected JEG-3 cells was not increased for any of the constructs compared with pFGFR-17, with a slight decrease in inclusion seen for pFGFR-82 and pFGFR-83 (Fig. 2) . These data support the findings of the previous deletion constructs and suggest a role for this intronic sequence, rather than intron size, as a cell-specific inhibitor of -exon inclusion.

View larger version (37K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Identification of a region that inhibits -exon inclusion in SNB-19 cells. Intron deletions were performed in pFGFR-17 without changes to the flanking sequence. Construct deletions are depicted schematically, showing the size (bp, in parentheses) and location of the deletions relative to the end of the exon. and dotted lines, a 62-bp region that was deleted from constructs displaying elevated -exon inclusion in SNB-19 cells. The values presented are for three independent transfections + SD.

View larger version (33K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Inhibition of heterologous exon recognition in SNB-19 cells by the FGFR-1 intron sequence. A, an intron deletion is schematically depicted showing the size (bp) and location of the deletion relative to the end of the exon. B, a schematic depicting the parent construct and the intronic region interest. The construct pFGFR-61 replaces exon and flanking sequence with FGFR-1 exon 4 and its flanking sequence (double lines). , engineered restriction enzyme sites. All of the sizes are given in bp. The values presented are for three independent transfections ± SD.

It is clear that the 62-nucleotide region functions as a cell-specific repressor of RNA splicing. A sequence comparison found that the region was also conserved in the rat gene with a higher degree of homology (87%) than the surrounding intron (data not shown). This suggests that the entire 62-nucleotide region may serve as a functional element. The region shares two features in common with other intronic regulatory elements; the sequence is pyrimidine-rich and contains multiple copies of a UGC motif (Fig. 4) . The UGC motif is repeated seven times within the 62-nucleotide region but found in only four additional places in the remaining 229 nucleotides of the downstream intron (data not shown). The UGC motif is reported to play a role in the regulated splicing of several genes (9, 10, 11, 12, 13, 14, 15, 16) . However, for most of these examples, the UGC motif serves as a part of an intronic activator of splicing. The exception is the -tropomyosin gene: the UGC motifs are found in two intron repressor elements that flank exon 3. They function to ensure the skipping of exon 3 in smooth muscle cell (15, 16, 17) . To test whether the UGC motifs play a similar role in glioblastoma cell-specific RNA splicing, we generated constructs containing mutations of the 62-bp region in pFGFR-17. Constructs pFGFR-90, pFGFR-91, pFGFR-92, and pFGFR-93 each contain mutations specifically targeting one or two UGC motifs in the 62-nucleotide region (Fig. 4) . Although a moderate increase in exon inclusion was seen for pFGFR-90 and pFGFR-91, none of the constructs obtained the level of exon inclusion observed for construct pFGFR-88 (Fig. 4) . This data suggested that either the UGC motif was not a critical component of the element, or that there was functional redundancy. To examine this further, we mutated all of the UGC motifs simultaneously (Fig. 4 , pFGFR-94). For this construct, the level of exon inclusion was clearly elevated in SNB-19 cells without altering RNA splicing in JEG-3 cells. Although this observation clearly implicates this region as an important regulator of exon splicing, the high number of nucleotides mutated makes it difficult to draw conclusions regarding the role of the UGC motif. The fact that constructs pFGFR-85 and pFGFR-86 both show elevated exon inclusion suggests that the functional element may comprise motifs mapping to both regions. In addition, the key UGC motifs involved in -tropomyosin gene splicing exist as direct repeats (15) . Therefore, we decided to mutate the two UGCUGC motifs simultaneously (Fig. 4 , pFGFR-95). When this construct was tested in both of the cell types, the level of exon inclusion was similar to that observed for pFGFR-88 and pFGFR-94 (Fig. 4) . Thus, it would appear that these two elements play a key role in the function of the splicing inhibitory element; however, we cannot rule out a role for additional nucleotides.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Mutation of a repeat sequence within the intronic splicing inhibitor results in enhanced -exon inclusion in SNB-19 cells. Intronic deletions and mutations were performed in pFGFR-17 (17) without changes to the flanking sequence (see Fig. 1 ). The schematic localizes and provides the specific sequence of the 62-nucleotide region required for -exon exclusion. Underlined, the UGC sequence motif. Arrow, the boundary for deletions in pFGFR-85 and pFGFR-86 (Fig. 2) . Below the pFGFR-17 sequence are the specific deletions (-) and mutations (uppercase letters) found in each construct’s RNA. Flanking each sequence: left, the pFGFR clone number; right, the quantification of -exon inclusion. The values presented are for three independent transfections ± SD.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ This work was supported by Public Health Service Grant CA-67946 (to G. J. C.) from the National Cancer Institute.

² To whom requests for reprints should be addressed, at M. D. Anderson Cancer Center, Section of Endocrinology, Box 15, 1515 Holcombe Boulevard, Houston, TX 77030. Phone: (713) 792-2840; Fax: (713) 794-4065; E-mail: gcote{at}mdanderson.org

³ The abbreviations used are: FGFR, FGF receptor; FGF, fibroblast growth factor; RT, reverse transcription; hMT, human metallothionein; PTB, polypyrimidine tract binding protein.

⁴ Unpublished observations.

Received 10/27/98. Accepted 11/30/98.

	REFERENCES

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5. Wang F., Kan M., Yan G., Xu J., McKeehan W. L. Alternately spliced NH₂-terminal immunoglobulin-like Loop I in the ectodomain of the fibroblast growth factor (FGF) receptor 1 lowers affinity for both heparin and FGF-1. J. Biol. Chem., 270: 10231-10235, 1995.[Abstract/Free Full Text]
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