This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Copyright Permission Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Smith, P. J. Articles by Chew, S. L. Search for Related Content PubMed PubMed Citation Articles by Smith, P. J. Articles by Chew, S. L. Pubmed/NCBI databases OMIM Substance via MeSH

An Exonic Splicing Enhancer in Human IGF-I Pre-mRNA Mediates Recognition of Alternative Exon 5 by the Serine-Arginine Protein Splicing Factor-2/ Alternative Splicing Factor

Department of Endocrinology (P.J.S., E.L.S., R.J.M.R., S.L.C.), and Department of Anaesthesia and Intensive Care (J.C., C.J.H.), St. Bartholomew’s Hospital, Queen Mary, University of London, London EC1A 7BE, United Kingdom; and Cold Spring Harbor Laboratory (A.R.K.), Cold Spring Harbor, New York 11724

Address all correspondence and requests for reprints to: Shern L. Chew, Department of Endocrinology, St. Bartholomew’s Hospital, London EC1A 7BE, United Kingdom. E-mail: s.l.chew{at}mds.qmw.ac.uk

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
The human IGF-I gene has six exons, four of which are alternatively spliced. Variations in splicing involving exon 5 may occur, depending on the tissue type and hormonal environment. To study the regulation of splicing to IGF-I exon 5, we established an in vitro splicing assay, using a model pre-mRNA containing IGF-I exons 4 and 5 and part of the intervening intron. Using a series of deletion mutants, we identified an 18-nucleotide purine-rich splicing enhancer in exon 5 that increases the splicing efficiency of the upstream intron from 6 to 35%. We show that the serine-arginine protein splicing factor-2/alternative splicing factor specifically promotes splicing in cultured cells and in vitro and is recruited to the spliceosome in an enhancer-specific manner. Our findings are consistent with a role for splicing factor-2/alternative splicing factor in the regulation of splicing of IGF-I alternative exon 5 via a purine-rich exonic splicing enhancer.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
MOST HUMAN GENES contain introns, which must be excised, and the exons spliced together, to allow gene expression. A substantial number of genes make transcripts that undergo alternative splicing, generating a great number of protein isoforms (1). The regulation of alternative splicing has been studied in some cases, and involves the serine-arginine (SR) family of splicing proteins and several heterogeneous nuclear RNA protein (hnRNPs) (2, 3, 4). Human IGF-I is a 70-residue peptide with growth-promoting and metabolic actions. It is derived from a gene with six exons, four of which are subject to alternative splicing (Fig. 1A). The alternative splices generate different precursor peptides, although they do not alter the structure of the mature peptide. Exons 1 and 2 are alternative leader exons derived from different transcription start sites, and encode part of the signal peptide (5, 6). Exons 3 and 4 are constant. Exons 5 and 6 are subject to a complex alternative splicing pattern. Exon 4 usually splices to exon 6 (5), but sometimes it splices to exon 5, representing 1–10% of IGF-I transcripts (7). A minor isoform results from splicing of exons 4 and 5, and from an alternative 5' splice site in exon 5 to exon 6 (8).

The production of IGF-I isoforms in several species is regulated at transcriptional (9, 10, 11), posttranscriptional (8, 12, 13, 14, 15, 16, 17, 18, 19) and translational (20, 21) levels. Once translated, the variant N-terminal domains encoded by IGF-I exons 1 or 2 are processed by canine microsomes, suggesting both are functional signal peptides (21). Alternative exons 5 and 6 encode different E domains. Part of the E domain encoded by exon 5 contains an amidated growth-promoting peptide (22), but there are few other functional data (23). Despite the lack of experimental data on the functional significance of the isoforms, there is species conservation of the genomic architecture of the exons, the splicing patterns producing alternative isoforms (6), and the peptide sequences (Cook, A., and S. L. Chew, manuscript in preparation). Because alternative splicing of exon 5 may vary depending on tissue type (13, 24, 25) or hormonal environment (8, 12, 13, 14, 17, 26), we examined the mechanisms controlling splicing of this exon.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Construction of pre-mRNA templates
A model in vitro splicing system was established to examine splicing between IGF-I exons 4 and 5 (Fig. 1). The entire exon 4 is 182 nucleotides (nt), the intron is 1505 nt, and exon 5 is 218 nt (up to the most upstream of several polyadenylation/cleavage sites). The experimental system involved incubation of radiolabeled IGF-I pre-mRNA substrates in HeLa nuclear extracts, followed by an assay of splicing. A major constraint of this approach is that RNA substrates splice less efficiently and are prone to degradation if they are too long. Therefore, for in vitro splicing experiments, we used only the downstream 93 nt of exon 4 and deleted a substantial part of the intron between exon 4 and exon 5 (Fig. 2A). This template, called SP6-IGF4–5, was made by overlap-extension PCR with Pfu Turbo (Stratagene, La Jolla, CA) and contains the SP6 RNA polymerase promoter to allow in vitro transcription of the IGF4–5 pre-mRNA. Derivatives were made from SP6-IGF4–5 with deletions of exon 5: pre-mRNAs A, B, and C (Fig. 2A) and E, F, and G (Fig. 3A). The derivatives were also made by PCR with Pfu Turbo. For making the SP6-IGF4–5 template, primers SP6-E4-493S (5'-ATTTAGGTGACACTATAGGGCTGGAGATGTATTGCGCA) and IGF-INT4-1599A (5'-CCACCCACATGCACAAGAGAGAGA) were used to make a fragment containing 93 bp of exon 4 and 63 bp of the upstream intron. Primers OL-IGF-INT4-2809S (5'-TGCATGTGGGTGGCTCTTCCCAGGTGACCCA) and E5-557A (5'-CCTTGCCTCTGTCTGTTTAAT) were used to make a fragment containing 221 bp of the 3' end of the downstream intron and 218 bp of exon 5. A third PCR, using SP6-E4-493S and E5-557A, in the presence of both amplified fragments, assembled the template. The product was cloned into pCR-blunt (Invitrogen, Carlsbad, CA) and verified by sequencing. Templates for in vitro transcription were made by further PCRs using a primer to the SP6 promoter and the following downstream primers: E5-630A (5'-TCCTTCTCTGAGACTTCG) for pre-mRNA A; E5-699A (5'-CTCTGATCTGCAGACTTGCT) for pre-mRNA B; E5-543A (5'-GTTTAATCCTCCTGTCCTTCA) for pre-mRNA C; E5-557A for pre-mRNA D; E5-648A (5'-GTGTCTTTGGCCAACCTT) for pre-mRNA E; E5-666A (5'-TCTGTTCCCCTCCTGGAT) for pre-mRNA F; and E5-684A (5'-TTGCTTCTGTCCCCTCCT) for pre-mRNA G. All labeled pre-mRNAs were made with SP6 RNA polymerase using [-³²P]-GTP and gel-purified. The Hß6 template has been described (27).

View larger version (11K): [in this window] [in a new window]   Figure 1. Alternative splicing of the human IGF-I pre-mRNA. Exons are shown as boxes, introns as lines, transcription start sites as arrows, splicing patterns as sloped lines, and polyadenylation signals as the letter A. The protein-coding potential of the exons is indicated underneath.

View larger version (38K): [in this window] [in a new window]   Figure 2. In vitro splicing of IGF-I minigene transcripts with progressive deletions of exon 5. A, Diagrams of the pre-mRNAs used in in vitro splicing experiments. The splicing substrate IGF4–5 is shown, exon 4 as an open box, the intron as a line and exon 5 as a black box. The deletion of 1221 nt from the intron is represented as double diagonal lines. The sizes in nucleotides (nt) are marked above the diagram. The deletion mutants, A, B, and C of exon 5 are shown underneath. The length of the 3' exon is given after each deletion. B, Splicing reactions using IGF4–5 pre-mRNAs. The radiolabeled pre-mRNA substrates represented in Fig. 2A (and as indicated by letters above the lanes) were incubated in HeLa nuclear extracts for 1 or 2 h (as shown above the lanes). The reactions were deproteinized, RNA extracted and run on denaturing polyacrylamide gels. The identity of the pre-mRNA, intron-lariat, and mRNA bands is indicated by symbols on the right of the autoradiograph, with the mRNAs also indicated by the square bracket.

View larger version (22K): [in this window] [in a new window]   Figure 3. Fine deletion mapping of the exon 5 enhancer by in vitro splicing. A, Diagram of finer deletions of IGF4–5, pre-mRNAs E, F, and G, is shown, with sizes of the 3' exons indicated in nucleotides at the end of the exon. B, Splicing reactions were performed by incubating the pre-mRNAs in nuclear extracts and products run on gels The pre-mRNAs used and times of incubation are shown above the lanes. The identity of the pre-mRNA and mRNA bands is indicated by the symbols on the right of the gel, with mRNAs also indicated by a square bracket. C, Quantification of splicing efficiencies. The y-axis shows the ratio of mRNA to pre-mRNA expressed as a percentage; the x-axis indicates the identity of the pre-mRNAs; error bars represent SE (n = 3).

Immunoprecipitations
The antibody to SF2/ASF, mAb96, and control antibody to maltose-binding protein, mAb105, have been described (30). The antibody to hTra2ß was kindly provided by Julian Venables and Ian Eperon (31). Immunoprecipitations were performed as described (32), with some changes. Briefly, splicing reactions were scaled up to 100 µl and incubated for 2 h, then diluted to 500 µl with IP150 buffer (50 mM Tris-HCl, pH 8.0; 150 mM NaCl; 0.05% NP40). Antibodies were pre-bound to protein A-Sepharose (Fast Flow, Amersham Pharmacia Biotech, Little Chalfont, Buckinghamshire, UK) in IP150 buffer and then added to splicing reactions and incubated at 4 C for 1 h, before three quick washes in IP150 buffer containing 0.5 mg/ml tRNA. The pellet was resuspended in 10 mM Tris-Cl pH 8.0 and 0.1 mM EDTA, and immunoprecipitated RNA recovered by phenol extraction and ethanol precipitation. The supernatant from the anti-MBP tubes was ethanol precipitated, and 10% of the resuspended material was loaded as a control.

Cotransfections and RNA analyses
An IGF-I minigene containing exons 4, 5, and 6 (pEGFP-IGF-F1) was made. A PCR fragment containing exon 4 (171 bp), intron 4 (1505 bp), exon 5 up to the first polyadenylation/cleavage site (218 bp) and the 5' end of intron 5 (198 bp) was made with primers EcoRI-MOD4-2244S (5'-GGAATTCCGGGTATGGCTCCAGCAGT) and NotI-MODINT3238A (5'-ATAAGAATGCGGCCGCACATATATTGACATAGGCAATTCT) using Expand High Fidelity polymerase (Roche Molecular Biochemicals, Mannheim, Germany) to amplify human genomic DNA. A second PCR fragment containing the 3' end of intron 5 (284 bp) and exon 6 (399 bp) was made with primers NotI-MODINT3367S (5'-ATAAGAATGCGGCCGCATAGAAGCAGATGAATCAACT) and SacII-MOD6A (5'-GCTGAGCCGCGGAGTGCAACTGGATCTATACAA). The fragments were assembled via the NotI sites and cloned into the EcoRI and SacII sites of pEGFP-C1 (CLONTECH Laboratories, Inc., Palo Alto, CA). The construction was verified by sequencing on both strands and was used as a reporter in cotransfection experiments (33) with plasmids pCG-SF2 (expressing SF2/ASF) or pCG-SC35 (expressing SC35). Briefly, 2 µg of pEGFP-IGF-F1, with or without 2 µg of pCG-SF2 or pCG-SC35, was transfected into approximately 75% confluent HeLa cells plated in 3-cm diameter wells using Fugene 6 (Roche Molecular Biochemicals), according to the manufacturer’s protocol. Total RNA was harvested 24 h later using the TRI reagent (Sigma, St. Louis, MO), and RT-PCR was performed as described (8). Splicing to exon 5 was assayed with primers EGFP-1323S (5'-GTACAAGTCCGGACTCAGAT) and E5-557A (5'-CCTTGCCTCTGTCTGTTTAAT). Splicing to exon 6 was assayed with primers EGFP-1323S and E6-669A (5'-CTGCGGTGGCATGTCACTCTT). Reaction products were resolved on 6% nondenaturing polyacrylamide gels, photographed and scanned with a Scanjet 5370C (Hewlett-Packard Co., Palo Alto, CA) and quantified through the IMAGE program. Muscle biopsies were obtained from patients after written informed consent or assent and approval of the study by the local research ethics committee and were subjected to RNA extraction, RT-PCR, Southern blotting and quantification, as described (8). Serum IGF-I was assayed by an in-house RIA (normal range 108–369 ng/ml; interassay and intraassay coefficient of variation <10%).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Splicing of IGF-I exon 5 in vitro
We first constructed an IGF-I splicing substrate consisting of exons 4 and 5 and the entire intervening intron. This pre-mRNA was very unstable under standard in vitro splicing conditions (data not shown). We therefore made another IGF-I pre-mRNA substrate with a 1221-bp deletion in the intron, IGF4–5 (Fig. 2A). The construct was made by overlap extension PCR. The size and position of the deletion was designed to allow sufficient intronic sequence so that disruption of the splice sites was unlikely, but not too much to make the pre-mRNA difficult to manipulate or subject to degradation. In particular, the branchsite of the intron has not been mapped, so a longer section at the 3' end of the intron was retained. This substrate spliced in vitro with little degradation (Fig. 2B, lane 9). We then generated a deletion series from the 3' end of exon 5 (Fig. 2A). The initial deletions were large and designed to examine regions of exon 5 for elements affecting splicing efficiency. An increase in splicing efficiency between pre-mRNAs A and B was observed (Fig. 2B, compare lanes 2 and 3 with lanes 4 and 5). Substrates C and D gave clear spliced products at 2 h (lanes 7 and 9), but the kinetics of mRNA appearance was slower than B at 1 h (compare lanes 6 and 8 to lane 4).

To define elements within the 69-nt segment between A and B, this region was subdivided into three segments (E, F, and G; Fig. 3A). A significant improvement in splicing efficiency was seen between E and F pre-mRNAs (compare lanes 4 and 6; Fig. 3B), but not between A and E pre-mRNAs (compare lanes 2 and 4, Fig. 3B). In three independent experiments, the mean ratio of mRNA to pre-mRNA after 1 and 2 h of splicing increased from 3% (SE 0.5%) and 6% (SE 1%) for pre-mRNAs A and E to 35% (SE 5%) for pre-mRNA F (Fig. 3C) (P = 0.02, Kruskal-Wallis test). The sequence between pre-mRNA E and F is 18-nt long and purine-rich (ATCCAGGAGGGGAACAGA) and begins 64 nt downstream of the 3' splice site of exon 5 and 15 nt downstream of the alternative 5' splice site in exon 5. Further enhancement of splicing was not achieved by sequences downstream of this element, and some delay in the kinetics of the reactions was seen with pre-mRNAs C, D, and G, suggesting the presence of silencer elements.

SF2/ASF promotes splicing of IGF-I exon 5
Several SR proteins in mammalian (34) and Drosophila (35) nuclear extracts bind purine-rich exonic elements to promote splicing. S100 cytosolic extracts were used to identify trans-acting factors required for promotion of splicing to exon 5. These extracts are not competent for splicing because they lack SR proteins (36). We complemented S100 extracts with either of two recombinant SR proteins: SF2/ASF and SC35. Both SF2/ASF and SC35 were able to restore splicing of a ß-globin pre-mRNA in an S100 extract (Fig. 4, lanes 3 and 4). We exploited this system to study the specificity of action of SR proteins on IGF pre-mRNA in vitro splicing. We incubated pre-mRNAs A, E, and F in nuclear and S100 extracts. As before, pre-mRNAs A and E showed only traces of splicing in nuclear extract (lanes 5 and 9), whereas pre-mRNA F was efficiently spliced (lane 13). None of the pre-mRNAs spliced in the S100 extract alone (lanes 2, 10, and 14; nonspecific degradation of the pre-mRNA is seen in lane 6). However, pre-mRNA F spliced efficiently in an S100 extract complemented with SF2/ASF (lane 15), but not in an S100 extract complemented with SC35 (lane 16). This indicated a specific requirement for SF2/ASF and the purine-rich enhancer for in vitro splicing to IGF-I exon 5 and ruled out a nonspecific effect of exon length on splicing of the pre-mRNAs. SF2/ASF was unable to promote splicing of the IGF4–5 pre-mRNA in the absence of this enhancer (lane 11). This experiment was independently performed twice with similar results.

View larger version (74K): [in this window] [in a new window]   Figure 4. S100-complementation reactions with IGF4–5 substrates. Pre-mRNAs A, E, and F were incubated for 2 h in either nuclear extract (NE), or S100 extract (S100). Some S100 reactions were complemented with SR proteins SF2/ASF (SF2) or SC35. The extracts and SR proteins used in each reaction are indicated by + signs above the lanes. ß-globin pre-mRNA (Hß6) was used as a control in lanes 1–4. The pre-mRNAs used are indicated above the lanes. The identity of the IGF pre-mRNA, lariat- intermediate, lariat-product and mRNA bands are given on the right of the autoradiograph, with the mRNA bands also shown as a square bracket. The identity of the ß-globin pre-mRNA, mRNA and 5' exon intermediate bands is given on the left of the autoradiograph.

View larger version (49K): [in this window] [in a new window]   Figure 5. Immunoprecipitation of labeled IGF-I transcripts from splicing reactions. Pre-mRNAs without (E) or with (F) the exon 5 enhancer element were incubated under splicing conditions. Prespliceosomal and spliceosomal complexes were immunoprecipitated with the indicated antibodies, and the labeled RNAs extracted from the precipitates. The lanes labeled SUP were loaded with 1/10 of the RNA recovered from the supernatant of the control anti-MBP immunoprecipitations. The pre-mRNAs and antibodies used are indicated above the lanes. The identity of the pre-mRNA and mRNA bands is shown by symbols on the right of the gel.

View larger version (40K): [in this window] [in a new window]   Figure 6. Effect of transient overexpression of SF2/ASF or SC35 on alternative splicing of a cotransfected IGF-I minigene. A, The left panel shows total RNA from each well, as a control for recovery and loading. M, lambda/BstEII markers. The right panel shows representative data from an RT-PCR experiment. The exon amplified by each PCR reaction is indicated above the lanes. The + symbol above each lane indicates the plasmids used in transfections. M, pBR322/MspI markers. B, Summary of data from three experiments showing the fold change of the ratio of exon 5 to exon 6 expression compared with the IGF-I minigene alone. Error bars represent SD.

In the group of patients with GH deficiency, GH-treated patients had increased relative IGF-I exon 5 levels (for representative data, see Fig. 7A, compare lane 1 with lane 2 and lane 3 with lane 4). Placebo-treated patients showed less marked changes in IGF-I exon 5 levels (lanes 6–11). As a group, GH-treated patients had a significant 10.0-fold increase (SE 2.9-fold) in relative inclusion of IGF-I exon 5 compared with baseline, compared with a 2.5-fold increase in the placebo-treated patients (SE 1.1-fold) (Fig. 7B, solid bars; P = 0.032; two-tailed t test). Note that one patient in the GH-treated group, who showed no response by any criteria (including the serum IGF-I level, which failed to rise into the normal range) and who had a drop in muscle IGF-I exon 5 levels, was excluded from all analyses because we question the compliance of the patient with GH treatment. At baseline, there was no difference in age or body mass index between the GH-treated and the placebo-treated group (mean age 45 compared with 43.6 yr; mean body mass index 30 compared with 30.6 kg/m²). The GH-treated group were all male, whereas two of the five placebo-treated group were male. The increase in serum IGF-I levels after 6 months was significantly greater in the GH-treated compared with the placebo-treated group (mean rise in serum IGF-I of 441 vs. 45.4 ng/ml; P = 0.0003; two-tailed t test).

View larger version (32K): [in this window] [in a new window]   Figure 7. A, IGF-I exon 5 inclusion in muscle biopsies from GH-deficient patients. Representative semiquantitative RT-PCR data for IGF-I exon 5 inclusion in muscle biopsies from GH-treated vs. placebo-treated patients are shown in the top panel. GAPDH RT-PCR products were measured as an internal control, bottom panel. B, Relative level of IGF-I RT-PCR products from GH-deficient and ICU patients in follow-up muscle biopsies compared with baseline. The data are corrected for GAPDH expression and expressed as fold change from the baseline biopsy level. Solid bars show exon 5-containing products; open bars show exon 6-containing products; error bars are SE; GH, GH-treated; no GH, placebo-treated; ICU2, second biopsy from intensive-care patients; ICU3, third biopsy from intensive-care patients.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
A purine-rich exonic splicing enhancer in IGF-I exon 5 was identified by in vitro splicing assays with pre-mRNAs harboring systematic deletions in exon 5. This enhancer functioned specifically with SF2/ASF, and overexpression of SF2/ASF in cultured HeLa cells promoted splicing via exon 5 inclusion. Splicing enhancer sequences have been identified in several regulated and constitutive exons, and may be classified into purine rich (40) and nonpurine rich (41). Enhancers interact with SR proteins, including SF2/ASF (35, 42, 43, 44, 45, 46, 47, 48). SF2/ASF has high binding affinity for certain purine-rich sequences in vitro (49) and, under splicing conditions, SF2/ASF and SC35 function through distinct and degenerate consensus sequences (50, 51, 52). We analyzed IGF-I exon 5 using matrices for predicting sequences through which SF2/ASF and SC35 function (50, 52). The 18-nt extension between pre-mRNAs E and F significantly increases splicing to exon 5. The extended sequence in the F pre-mRNA completes an SF2/ASF high-score heptamer motif (beginning at nt 60; Fig. 8) and adds yet another (beginning at nt 69). For SC35, the extension does not affect the number of high-score motifs present. The matrices show two high-score motifs for SF2/ASF (beginning at nt 25 and 37) and two for SC35 (beginning at nt 5 and 53) in the part of exon 5 included in pre-mRNA A. However, a score above threshold may not be sufficient for exonic splicing enhancer function, because of the surrounding context, e.g. a juxtaposed silencer, which we are currently unable to predict (52). Our data are compatible with IGF-I exon 5 being a substrate for SF2/ASF via a short enhancer element, and thus, this mechanism may underlie the control of splicing to this exon.

View larger version (15K): [in this window] [in a new window]   Figure 8. High-score matches to SF2/ASF and SC35 consensus motifs in IGF-I exon 5. The nucleotides of exon 5 are given on the x-axis and the score is on the y-axis. SF2/ASF scores are in black bars and SC35 in gray bars. The sequence extension in pre-mRNA F is shown in bold. Only motifs with scores above the previously defined thresholds of 1.956 for SF2/ASF and 2.383 for SC35 are shown (77 ).

We attempted to understand the regulation of IGF-I alternative splicing by examining human muscle biopsies taken during studies in patients with GH deficiency. There was a significant increase in the ratio of exon 5-containing mRNAs in patients after treatment with GH, but not in those treated with placebo. The consequence of changes in splicing to exon 5 or 6 involves the E domain of the IGF-I precursor. The physiological roles of the E domains are unknown, although they are not present in insulin. The E domain encoded by exon 5 has been shown to harbor a mitogenic peptide fragment (22). Our preliminary experiments suggest the E domains may target the IGF-I precursor peptide to different cellular fates (unpublished data).

We also examined muscle biopsies from a heterogeneous group of intensive care patients, either with electrophysiological and histological evidence of myopathy, or with falls of serum IGF-I levels to below the normal range. GH resistance has been observed in such patients (53). In the intensive care patients, there was no trend evident in the ratios of muscle IGF-I mRNA isoforms. Our data make it less likely that changes in muscle IGF-I production play a role in ICU myopathy or in the falling IGF-I levels seen in these patients (53). It is possible that the fall in serum IGF-I in our patients was due to reduced liver production, as has been shown in rodent models (see references cited in 53) and by liver- specific IGF-I deletions in mice (54).

Several studies have investigated alternative splicing in the context of skeletal muscle differentiation, and in most cases this regulated expression involves exons that undergo skeletal muscle-specific inclusion or exclusion (e.g. in tropomyosin or troponin pre-mRNAs). Some of the factors regulating such exons are CUG-binding protein (55), SF2/ASF (56), and hnRNP H (57). The main difference between the skeletal muscle differentiation alternative splicing systems and our experiments is that muscle biopsies from the patients presumably represent fully differentiated tissue. Fully differentiated tissue may have a more limited capacity for changing splicing compared with that occurring during muscle differentiation. Also, both IGF-I isoforms are expressed, albeit with varying relative abundance. Thus, the effect of GH in changing IGF-I pre-mRNA splicing in differentiated adult skeletal muscle is quantitative. How the spliceosome is adapted to give qualitative changes in exon selection during muscle differentiation as well as quantitative changes seen in fully differentiated muscle is unclear.

SF2/ASF binding promotes assembly of the splicing machinery (34) and later stages of the splicing reaction (58, 59, 60, 61). In a well characterized system of alternative splicing, SF2/ASF binds to the Drosophila doublesex purine-rich enhancer in a cooperative manner with Tra2 (35). hTra2ß is one of two human homologs of Tra2 (37, 38) and promotes splicing in a sequence-specific manner (39). hTra2ß binds a natural exonic splicing enhancer in a human s tropomyosin alternative exon (Eperon, I. C., personal communication). In our experiments, hTra2ß was present in the IGF-I spliceosome, but not in an enhancer-dependent manner. By contrast, SF2/ASF associated with the spliceosome in an enhancer-dependent manner. This observation argues against simultaneous cooperative binding by SF2/ASF and hTra2ß in the context of the IGF-I exon 5 enhancer but does not exclude the possibility that pre-bound hTra2ß facilitates the recruitment of SF2/ASF, or that SF2/ASF binds cooperatively with other SR proteins or other RNA-binding proteins.

The activity of SF2/ASF may be regulated by several mechanisms (34, 62), including phosphorylation by kinases (63), cellular localization (64), and varying tissue concentrations (30). Some studies implicate SR proteins in signaling-mediated changes in alternative splicing. Insulin signaling changes splicing involving rat fibronectin exon EIIIB and is associated with increased levels of HRS, the rat homolog of SRp40 (48). The alternative splicing response to serum stimulation or withdrawal in the mouse SRp20 pre-mRNA involves SF2/ASF and SRp20 (65, 66). Alternative splicing of CD44 and CD45 pre-mRNAs occurs during cytokine- induced T-cell differentiation, via PKC and Ras pathways (67, 68, 69). SC35, SF2/ASF and other SR proteins alter CD44 and CD45 splicing (70, 71, 72).

It is possible that SF2/ASF and the purine-rich enhancer are involved in pathways that control the relative levels of expression of IGF-I isoforms in different tissues (13, 24, 25) and in response to GH in animal or cell culture models (8, 12, 13, 14, 17, 26), with some exceptions (73, 74). In vitro models for regulated splicing systems are difficult to develop (75), and hence it has not been possible to test whether SF2/ASF and the enhancer function in hormonally regulated or tissue-dependent alternative splicing of IGF-I. However, there are examples of enhancers in other exons with dual function in promoting splicing both in constitutive and regulated contexts (69, 76). Our working hypothesis, derived from the present work in HeLa cells, is that alterations in the localization, phosphorylation or level of SF2/ASF by cellular signals, such as GH-stimulated pathways, may control IGF-I exon 5 inclusion via interaction with the purine-rich exonic element.

	Acknowledgments

 
We are grateful to R. Xu and H.-X. Liu for SC35, A. Mayeda and L. Manche for help preparing SF2/ASF, J. Venables and I. Eperon for the anti-hTra2ß antibody, J. Rodriguez-Arnao, G. Yarwood, C. Botfield, and G. M. Besser for the muscle biopsies, I. Eperon for helpful discussions and comments on the manuscript.

	Footnotes

 
S.L.C. was partly supported by the Wellcome Trust (045401), and A.R.K. was supported in part by NIH Grant GM-42699.

Abbreviations: GAPDH, Glyceraldehyde phosphate dehydrogenase; hnRNP, heterogeneous nuclear RNA protein; ICU, intensive care unit; nt, nucleotides; SF2/ASF, splicing factor-2/alternative splicing factor; SR, serine-arginine.

Received July 17, 2001.

Accepted for publication September 24, 2001.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Black DL 2000 Protein diversity from alternative splicing: a challenge for bioinformatics and post-genome biology. Cell 103:367–370[CrossRef][Medline]
2. Chabot B 1996 Directing alternative splicing: cast and scenarios. Trends Genet 12:472–478[CrossRef][Medline]
3. Wang Y-C, Selvakumar M, Helfman DM 1997 Alternative pre-mRNA splicing. In: Krainer AR, ed. Eukaryotic mRNA processing. Oxford, UK: IRL Press; 242–279
4. Smith CW, Valcárcel J 2000 Alternative pre-mRNA splicing: the logic of combinatorial control. Trends Biochem Sci 25:381–388[CrossRef][Medline]
5. Jansen M, van Schaik FMA, Ricker AT, Bullock B, Woods DE, Gabbay KH, Nussbaum AL, Sussenbach JS, Van den Brande JL 1983 Sequence of cDNA encoding human insulin-like growth factor I precursor. Nature 306:609–611[CrossRef][Medline]
6. Tobin G, Yee D, Brunner N, Rotwein P 1990 A novel human insulin-like growth factor I messenger RNA is expressed in normal and tumor cells. Mol Endocrinol 4:1914–1920[CrossRef][Medline]
7. Rotwein P 1986 Two insulin-like growth factor I messenger RNAs are expressed in human liver. Proc Natl Acad Sci USA 83:77–81[Abstract/Free Full Text]
8. Chew SL, Lavender P, Clark AJL, Ross RJM 1995 An alternatively spliced human IGF-I transcript (IGF-IEc) with hepatic tissue expression that diverts away from the mitogenic IBE1 peptide. Endocrinology 136:1939–1944[Abstract]
9. Adamo ML, Ben-Hur H, Roberts CT, LeRoith D 1991 Regulation of start site usage in the leader exons of the rat insulin-like growth factor-I gene by development, fasting, and diabetes. Mol Endocrinol 5:1677–1686[CrossRef][Medline]
10. Pell JM, Saunders JC, Gilmour RS 1993 Differential regulation of transcription initiation from insulin-like growth factor-I (IGF-I) leader exons and of tissue IGF-I expression in response to changed growth hormone and nutritional status in sheep. Endocrinology 132:1797–1807[Abstract]
11. Shemer J, Adamo ML, Roberts CT, LeRoith D 1992 Tissue-specific transcription start site usage in leader exons of the rat insulin-like growth factor-I gene: evidence for differential regulation in the developing kidney. Endocrinology 131:2793–2799[Abstract]
12. Roberts CTJ, Lasky SR, Lowe WLJ, Seaman WT, LeRoith D 1987 Molecular cloning of rat insulin-like growth factor I complementary deoxyribonucleic acids: differential messenger ribonucleic acid processing and regulation by growth hormone in extrahepatic tissues. Mol Endocrinol 1:243–248[CrossRef][Medline]
13. Lowe Jr WL, Lasky SR, LeRoith D, Roberts Jr CT 1988 Distribution and regulation of rat insulin-like growth factor I messenger ribonucleic acids encoding alternative carboxyterminal E-peptides: evidence for differential processing and regulation in liver. Mol Endocrinol 2:528–535[CrossRef][Medline]
14. Lowe Jr WL, Adamo ML, LeRoith D, Roberts Jr CT 1989 Expression and stability of insulin-like growth factor-I (IGF-I) mRNA splicing variants in the GH3 rat pituitary cell line. Biochem Biophys Res Commun 162:1174–1179[CrossRef][Medline]
15. Hepler JE, Van Wyk JJ, Lund PK 1990 Different half-lives of insulin-like growth factor mRNAs that differ in length of 3' untranslated sequence. Endocrinology 127:1550–1552[Abstract]
16. Duguay SJ, Swanson P, Dickhoff WW 1994 Differential expression and hormonal regulation of alternatively spliced IGF-I mRNA transcripts in salmon. J Mol Endocrinol 12:25–37[Abstract/Free Full Text]
17. Yang S, Alnaqeeb M, Simpson H, Goldspink G 1996 Cloning and characterization of an IGF-1 isoform expressed in skeletal muscle subjected to stretch. J Muscle Res Cell Motil 17:487–495[CrossRef][Medline]
18. Zhang J, Whitehead REJ, Underwood LE 1997 Effect of fasting on insulin-like growth factor (IGF)-IA and IGF-IB messenger ribonucleic acids and prehormones in rat liver. Endocrinology 138:3112–3118[Abstract/Free Full Text]
19. Zhang J, Chrysis D, Underwood LE 1998 Reduction of hepatic insulin-like growth factor I (IGF-I) messenger ribonucleic acid (mRNA) during fasting is associated with diminished splicing of IGF-I pre-mRNA and decreased stability of cytoplasmic IGF-I mRNA. Endocrinology 139:4523–4530[Abstract/Free Full Text]
20. Foyt HL, LeRoith D, Roberts Jr CT 1991 Effect of growth hormone on levels of differentially processed insulin-like growth factor I mRNA in total and polysomal mRNA populations. J Biol Chem 266:7300–7305[Abstract/Free Full Text]
21. Yang H, Adamo ML, Koval AP, McGuinness MC, Ben-Hur H, Yang Y, LeRoith D, Roberts Jr CT 1995 Alternative leader sequences in insulin-like growth factor I mRNAs modulate translational efficiency and encode multiple signal peptides. Mol Endocrinol 9:1380–1395[Abstract]
22. Siegfried JM, Kasprzyk PG, Treston AM, Mulshine JL, Quinn KA, Cuttitta F 1992 A mitogenic peptide amide encoded within the E peptide domain of the insulin-like growth factor IB prohormone. Proc Natl Acad Sci USA 89:8107–8111[Abstract/Free Full Text]
23. Lund PK, Hepler JE, Hoyt EC, Simmons JG 1991 Physiological relevance of IGF-I heterogeneity. In: Spencer EM, ed. Modern concepts of insulin-like growth factors. New York: Elsevier Science Publishing Co.;111–120
24. Hoyt EC, Van Wyk JJ, Lund PK 1988 Tissue and development specific regulation of a complex family of rat insulin-like growth factor I messenger ribonucleic acids. Mol Endocrinol 2:1077–1086[CrossRef][Medline]
25. Nagaoka I, Someya A, Iwabuchi K, Yamashita T 1991 Expression of insulin-like growth factor-IA and factor-IB mRNA in human liver, hepatoma cells, macrophage-like cells and fibroblasts. FEBS Lett 280:79–83[CrossRef][Medline]
26. Lin WW, Murray JD, Oberbauer AM 1998 Overexpression of growth hormone affects alternatively spliced IGF-I mRNA expression in oMt1a-oGH transgenic mice. Transgenic Res 7:295–302[CrossRef][Medline]
27. Krainer AR, Maniatis T, Ruskin B, Green MR 1984 Normal and mutant human ß-globulin pre-mRNAs are faithfully and efficiently spliced in vitro. Cell 36:993–1005[CrossRef][Medline]
28. Mayeda A, Krainer AR 1998 Preparation of HeLa cell nuclear and cytosolic S100 extracts for in vitro splicing. Methods Mol Biol 118:309–314
29. Krainer AR, Mayeda A, Kozak D, Binns G 1991 Functional expression of cloned human splicing factor SF2: homology to RNA-binding proteins, U1 70K, and Drosophila splicing regulators. Cell 66:383–394[CrossRef][Medline]
30. Hanamura A, Cáceres JF, Mayeda A, Franza Jr BR, Krainer AR 1998 Regulated tissue-specific expression of antagonistic pre-mRNA splicing factors. RNA 4:430–444[Abstract]
31. Venables JP, Elliott DJ, Makarova OV, Makarov EM, Cooke HJ, Eperon IC 2000 RBMY, a probable human spermatogenesis factor, and other hnRNP G proteins interact with Tra2ß and affect splicing. Hum Mol Genet 9:685–694[Abstract/Free Full Text]
32. Blencowe BJ, Nickerson JA, Issner R, Penman S, Sharp PA 1994 Association of nuclear matrix antigens with exon-containing splicing complexes. J Cell Biol 127:593–607[Abstract/Free Full Text]
33. Cáceres JF, Stamm S, Helfman DM, Krainer A 1994 Regulation of alternative splicing in vivo by overexpression of antagonistic splicing factors. Science 265:1706–1709[Abstract/Free Full Text]
34. Graveley BR 2000 Sorting out the complexity of SR protein functions. RNA 6:1197–1211[CrossRef][Medline]
35. Lynch KW, Maniatis T 1996 Assembly of specific SR protein complexes on the distinct regulatory elements of the Drosophila doublesex splicing enhancer. Genes Dev 10:2089–2101[Abstract/Free Full Text]
36. Krainer A, Conway GC, Kozak D 1990 Purification and characterization of pre-mRNA splicing factor SF2 from HeLa cells. Genes Dev 4:1158–1171[Abstract/Free Full Text]
37. Dauwalder B, Amaya-Manzanares F, Mattox W 1996 A human homologue of the Drosophila sex determination factor transformer-2 has conserved splicing regulatory functions. Proc Natl Acad Sci USA 93:9004–9009[Abstract/Free Full Text]
38. Beil B, Screaton G, Stamm S 1997 Molecular cloning of htra2-ß-1 and htra2-ß-2, two human homologs of tra-2 generated by alternative splicing. DNA Cell Biol 16:679–690[Medline]
39. Tacke R, Tohyama M, Ogawa S, Manley JL 1998 Human Tra2 proteins are sequence-specific activators of pre-mRNA splicing. Cell 93:139–148[CrossRef][Medline]
40. Tian H, Kole R 1995 Selection of novel exon recognition elements from a pool of random sequences. Mol Cell Biol 15:6291–6298[Abstract]
41. Coulter LR, Landree MA, Cooper TA 1997 Identification of a new class of exonic splicing enhancers by in vivo selection. Mol Cell Biol 17:2143–2150[Abstract]
42. Hedley ML, Maniatis T 1991 Sex-specific splicing and polyadenylation of dsx pre-mRNA requires a sequence that binds specifically to tra-2 protein in vitro. Cell 65:579–586[CrossRef][Medline]
43. Sun Q, Mayeda A, Hampson RK, Krainer A, Rottman FM 1993 General splicing factor SF2/ASF promotes alternative splicing by binding to an exonic splicing enhancer. Genes Dev 7:2598–2608[Abstract/Free Full Text]
44. Lavigueur A, La Branche H, Kornblihtt AR, Chabot B 1993 A splicing enhancer in the human fibronectin alternate ED1 exon interacts with SR proteins and stimulates U2 snRNP binding. Genes Dev 7:2405–2417[Abstract/Free Full Text]
45. Ramchatesingh J, Zahler AM, Neugebauer KM, Roth MB, Cooper TA 1995 A subset of SR proteins activates splicing of the cardiac Troponin T alternative exon by direct interactions with an exonic enhancer. Mol Cell Biol 15:4898–4907[Abstract]
46. Gontarek RR, Derse D 1996 Interactions among SR proteins, an exonic splicing enhancer, and a lentivirus rev protein regulate alternative splicing. Mol Cell Biol 16:2325–2331[Abstract]
47. Yeakley JM, Morfin J-P, Rosenfeld MG, Fu X-D 1996 A complex of nuclear proteins mediates SR protein binding to a purine-rich splicing enhancer. Proc Natl Acad Sci USA 93:7582–7587[Abstract/Free Full Text]
48. Du K, Peng Y, Greenbaum LE, Haber BA, Taub R 1997 HRS/SRp40-mediated inclusion of the fibronectin EIIIB exon, a possible cause of increased EIIIB expression in proliferating liver. Mol Cell Biol 17:4096–4104[Abstract]
49. Tacke R, Manley JL 1995 The human splicing factors ASF/SF2 and SC35 possess distinct, functionally significant RNA binding specificities. EMBO J 14:3540–3551[Medline]
50. Liu H-X, Zhang M, Krainer AR 1998 Identification of functional exonic splicing enhancer motifs recognized by individual SR proteins. Genes Dev 12:1998–2012[Abstract/Free Full Text]
51. Schaal TD, Maniatis T 1999 Identification of functional exonic splicing enhancer motifs recognized by individual SR proteins. Mol Cell Biol 19:1705–1719[Abstract/Free Full Text]
52. Liu H-X, Chew SL, Cartegni L, Zhang MQ, Krainer AR 2000 Exonic splicing enhancer motif recognized by human SC35 under splicing conditions. Mol Cell Biol 20:1063–1071[Abstract/Free Full Text]
53. Ross RJM, Chew SL 1995 Acquired growth hormone resistance. Eur J Endocrinol 132:655–660[Abstract/Free Full Text]
54. Butler AA, LeRoith D 2001 Minireview: Tissue-specific versus generalized gene targeting of the igf1 and igf1r genes and their roles in insulin-like growth factor physiology. Endocrinology 142:1685–1688[Abstract/Free Full Text]
55. Philips AV, Timchenko LT, Cooper TA 1998 Disruption of splicing regulated by a CUG-binding protein in myotonic dystrophy. Science 280:737–740[Abstract/Free Full Text]
56. Gallego ME, Gattoni R, Stévenin J, Marie J, Expert-Bezançon A 1997 The SR splicing factors ASF/SF2 and SC35 have antagonistic effects on intronic enhancer-dependent splicing of the ß-tropomyosin alternative exon 6A. EMBO J 16:1772–1784[CrossRef][Medline]
57. Chen CD, Kobayashi R, Helfman DM 1999 Binding of hnRNP H to an exonic splicing silencer is involved in the regulation of alternative splicing of the rat ß-tropomyosin gene. Genes Dev 13:593–606[Abstract/Free Full Text]
58. Tarn WY, Steitz JA 1995 Modulation of 5' splice site choice in pre-messenger RNA by two distinct steps. Proc Natl Acad Sci USA 92:2504–2508[Abstract/Free Full Text]
59. Roscigno RF, Garcia-Blanco MA 1995 SR proteins escort the U4/U6.U5 tri-snRNP to the spliceosome. RNA 1:692–706[Abstract]
60. Chew SL, Liu H-X, Mayeda A, Krainer AR 1999 Evidence for the function of an exonic splicing enhancer after the first catalytic step of pre-mRNA splicing. Proc Natl Acad Sci USA 96:10655–10660[Abstract/Free Full Text]
61. Zheng ZM, Quintero J, Reid ES, Gocke C, Baker CC 2000 Optimization of a weak 3' splice site counteracts the function of a bovine papillomavirus type 1 exonic splicing suppressor in vitro and in vivo. J Virol 74:5902–5910[Abstract/Free Full Text]
62. Manley JL, Tacke R 1996 SR proteins and splicing control. Genes Dev 10:1569–1579[Free Full Text]
63. Misteli T 1999 RNA splicing: what has phosphorylation got to do with it? Curr Biol 9:R198–R200
64. Misteli T, Cáceres JF, Clement JQ, Krainer AR, Wilkinson MF, Spector DL 1998 Serine phosphorylation of SR proteins is required for their recruitment to sites of transcription in vivo. J Cell Biol 143:297–307[Abstract/Free Full Text]
65. Jumaa H, Guenet J-L, Nielsen PJ 1997 Regulated expression and RNA processing of transcripts from the SRp20 splicing factor gene during the cell cycle. Mol Cell Biol 17:3116–3124[Abstract]
66. Jumaa H, Nielsen PJ 1997 The splicing factor SRp20 modifies splicing of its own mRNA and ASF/SF2 antagonizes this regulation. EMBO J 16:5077–5085[CrossRef][Medline]
67. Screaton GR, Cáceres JF, Mayeda A, Bell MV, Plebanski M, Jackson DG, Bell JI, Krainer AR 1995 Identification and characterisation of three members of the human SR family of pre-mRNA splicing factors. EMBO J 14:4336–4349[Medline]
68. Konig H, Ponta H, Herrlich P 1998 Coupling of signal transduction to alternative pre-mRNA splicing by a composite splice regulator. EMBO J 17:2904–2913[CrossRef][Medline]
69. Lynch KW, Weiss A 2000 A model system for activation-induced alternative splicing of CD45 pre-mRNA in T cells implicates protein kinase C and Ras. Mol Cell Biol 20:70–80[Abstract/Free Full Text]
70. Lemaire R, Winne A, Sarkissian M, Lafyatis R 1999 SF2 and SRp55 regulation of CD45 exon 4 skipping during T cell activation. Eur J Immunol 29:823–837[CrossRef][Medline]
71. ten Dam GB, Zilch CF, Wallace D, Wieringa B, Beverley PC, Poels LG, Screaton GR 2000 Regulation of alternative splicing of CD45 by antagonistic effects of SR protein splicing factors. J Immunol 164:5287–5295[Abstract/Free Full Text]
72. Wang HY, Xu X, Ding JH, Bermingham JR, Fu XD 2001 SC35 plays a role in T cell development and alternative splicing of CD45. Mol Cell 7:331–342[CrossRef][Medline]
73. Bichell DP, Kikuchi K, Rotwein P 1992 Growth hormone rapidly activates insulin-like growth factor I gene transcription in vivo. Mol Endocrinol 6:1899–1908[Abstract]
74. Stahlbom AK, Sara VR, Hoeben P 1999 Insulin-like growth factor mRNA in Barramundi (Lates calcarifer): alternative splicing and nonresponsiveness to growth hormone. Biochem Genet 37:69–93[CrossRef][Medline]
75. Chew SL 1997 Alternative splicing of mRNA as a mode of endocrine regulation. Trends Endocrinol Metab 8:405–413
76. Tian M, Maniatis T 1994 A splicing enhancer exhibits both constitutive and regulated activities. Genes Dev 8:1703–1712[Abstract/Free Full Text]
77. Liu H-X, Cartegni L, Zhang MQ, Krainer AR 2001 A mechanism for exon skipping caused by nonsense or missense mutations in BRCA1 and other genes. Nat Genet 27:55–58[Medline]

This article has been cited by other articles:

				S. A. Akker, S. Misra, S. Aslam, E. L. Morgan, P. J. Smith, B. Khoo, and S. L. Chew Pre-Spliceosomal Binding of U1 Small Nuclear Ribonucleoprotein (RNP) and Heterogenous Nuclear RNP E1 Is Associated with Suppression of a Growth Hormone Receptor Pseudoexon Mol. Endocrinol., October 1, 2007; 21(10): 2529 - 2540. [Abstract] [Full Text] [PDF]

				L. M. Morimoto, P. A. Newcomb, E. White, J. Bigler, and J. D. Potter Variation in Plasma Insulin-Like Growth Factor-1 and Insulin-Like Growth Factor Binding Protein-3: Genetic Factors Cancer Epidemiol. Biomarkers Prev., June 1, 2005; 14(6): 1394 - 1401. [Abstract] [Full Text] [PDF]

				N. A. Patel, H. S. Apostolatos, K. Mebert, C. E. Chalfant, J. E. Watson, T. S. Pillay, J. Sparks, and D. R. Cooper Insulin Regulates Protein Kinase C{beta}II Alternative Splicing in Multiple Target Tissues: Development of a Hormonally Responsive Heterologous Minigene Mol. Endocrinol., April 1, 2004; 18(4): 899 - 911. [Abstract] [Full Text] [PDF]

				N. Psilander, R. Damsgaard, and H. Pilegaard Resistance exercise alters MRF and IGF-I mRNA content in human skeletal muscle J Appl Physiol, September 1, 2003; 95(3): 1038 - 1044. [Abstract] [Full Text] [PDF]

				L. Cartegni, J. Wang, Z. Zhu, M. Q. Zhang, and A. R. Krainer ESEfinder: a web resource to identify exonic splicing enhancers Nucleic Acids Res., July 1, 2003; 31(13): 3568 - 3571. [Abstract] [Full Text] [PDF]

				V. van Heyningen and K. A. Williamson PAX6 in sensory development Hum. Mol. Genet., May 15, 2002; 11(10): 1161 - 1167. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted