The Fragile X Mental Retardation Protein FMRP Binds Elongation Factor 1A mRNA and Negatively Regulates Its Translation in Vivo*

Ying Ju SungDagger , Natalia Dolzhanskaya§, Sarah L. Nolin, Ted Brown, Julia R. Currie||, and Robert B. Denman§**

From the Dagger  Department of Anatomy and Cell Biology, Columbia University, New York, New York 10032, the § Biochemical Molecular Neurobiology Laboratory, Department of Molecular Biology, and the  Molecular Genetics Laboratory and || Bioinformatics Resource, Department of Human Genetics, New York State Institute for Basic Research in Developmental Disabilities, Staten Island, New York 10314

Received for publication, October 30, 2002, and in revised form, February 4, 2003

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Loss of the RNA-binding protein FMRP (fragile X mental retardation protein) leads to fragile X syndrome, the most common form of inherited mental retardation. Although some of the messenger RNA targets of this protein, including FMR1, have been ascertained, many have yet to be identified. We have found that Xenopus elongation factor 1A (EF-1A) mRNA binds tightly to recombinant human FMRP in vitro. Binding depended on protein determinants located primarily in the C-terminal end of hFMRP, but the hnRNP K homology domain influenced binding as well. When hFMRP was expressed in cultured cells, it dramatically reduced endogenous EF-1A protein expression but had no effect on EF-1A mRNA levels. In contrast, the translation of several other mRNAs, including those coding for dynamin and constitutive heat shock 70 protein, was not affected by the hFMRP expression. Most importantly, EF-1A mRNA and hFMR1 mRNA were coimmunoprecipitated with hFMRP. Finally, in fragile X lymphoblastoid cells in which hFMRP is absent, human EF-1A protein but not its corresponding mRNA is elevated compared with normal lymphoblastoid cells. These data suggest that hFMRP binds to EF-1A mRNA and also strongly argue that FMRP negatively regulates EF-1A expression in vivo.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The loss of a normal cellular protein, FMRP,1 causes fragile X syndrome, one of the most common forms of mental retardation (MR). FMRP is a RNA-binding protein that contains two hnRNP K-homology (KH) binding domains and an arginine-glycine-rich region that resembles an RGG box (1, 2). Several studies indicate that both the KH2 domain and the arginine-glycine-rich region likely play a role in RNA binding (1, 3-6), the latter interaction being mediated by a G quartet (7). FMRP associates with polyribosomes via a mRNP particle (8, 9), and it has been proposed to regulate gene expression post-transcriptionally (5, 10-14). Mammalian FMRPs inhibit mRNA translation in vitro at nanomolar concentrations in both rabbit reticulocyte lysates (15) and in microinjected Xenopus oocytes (16). These data suggest that translational repression may be an in vivo function of FMRP. Indeed, the Drosophila homolog of FMRP, dFMR1, was found to bind and negatively regulate futsch mRNA (17).

Recent studies have begun to delineate the mRNAs that mammalian FMRPs interact with in vivo. These studies have taken one of two forms. On the one hand, potential FMRP target mRNAs have been identified solely on the basis of their ability to bind to purified recombinant FMRP (15, 16) or cell-free produced FMRP (1, 3). Notwithstanding, it has not been determined whether any of these mRNAs bind to FMRP in vivo. On the other hand, mRNAs, including FMR1 mRNA, which associate with FMRP-containing mRNPs have also been isolated from cultured cells (10, 18). However, although these messages require FMRP in the mRNP for their association, it has not been demonstrated that they bind solely to it. Using the former methodology, we isolated a subset of mRNAs derived from normal adult brain that bind human FMRP (hFMRP) in vitro (3). During the course of this investigation we also tested a number of other mRNAs for their ability to interact with hFMRP. One of these mRNAs was Xenopus elongation factor 1A (xEF-1A). In the present paper we demonstrate that xEF-1A mRNA binds to recombinant and cell-free produced hFMRP in vitro. Furthermore, we show that hFMRP inhibits EF-1A mRNA translation in cultured PC12 and COS-7 cells and that the loss of hFMRP in fragile X lymphoblastoid cells derepresses human EF-1A (hEF-1A) mRNA translation.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Antibodies-- FMRP mAb 2160 and normal mouse serum were purchased from Chemicon. FXR1 (Y-19) mAb and FXR2 (S-16) mAb were obtained from Santa Cruz. Dynamin mAb and EF-1A mAb were purchased from Upstate Biotechnology. Hsp70cP mAb (HSP-820) was obtained from StressGen. Horseradish peroxidase-conjugated secondary antibodies were purchased from KPL and Santa Cruz.

Buffers-- RNA binding buffer 1 contained 50 mM Tris-HCl, pH 7.0, 2 mM MgCl2, and 150 mM NaCl. Buffer 2 contained 20 mM Hepes, pH 7.9, 2 mM MgCl2, 70 mM NH4Cl, 0.2% IGEPAL CA630, and 50 mg/ml yeast tRNA. FMRP purification buffer, buffer 3, contained 10 mM Hepes, pH 7.9, 300 mM NaCl, 1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, 5 mM beta -mercaptoethanol, and 20 mM imidazole. TAE buffer contained 40 mM Tris acetate and 1 mM EDTA. TMK buffer contained 50 mM Tris-HCl, pH 7.6, 10 mM MgCl2, and 25 mM KCl.

Plasmid Clones-- pET21A-hFMRP and pET21A-I304N, encoding hFMRP and the corresponding I304N point mutant, were gifts from Dr. Bernhard Laggerbauer, Max Planck Institute for Biochemistry, Germany. Each vector generates full-length FMRP with an N-terminal His tag. pTRI-XEF, encoding Xenopus EF-1A, was obtained from Ambion Laboratories. pAPP-695 and pT7-Control, encoding beta APP695 and a 1.4-kb lambda -HindIII/EcoRI RNA, respectively, have been described previously (3). pSF2-hFMRP, encoding human FMRP, was a gift from Dr. Ben Oostra, Erasmus University, Rotterdam, The Netherlands. pHA-hFXR1P, encoding human FXR1P, was a gift from Dr. Gideon Dreyfuss, University of Pennsylvania.

hFMRP Production for RNA Binding Studies-- Full-length and truncated 35S-hFMRPs were prepared by coupled in vitro transcription translation (3).

Recombinant hFMRPs were expressed in Escherichia coli BL21 from pET21A-FMRP and pET21A-I304N (16, 19). Briefly, transformed E. coli BL21 were grown at 37 °C to 1.0 A560 in LB-Amp100 medium. 1 mM isopropyl-1-thio-beta -D-galactopyranoside was added, and the cells were grown at 30 °C overnight. Proteins were extracted from cell pellets using B-PerTM supplemented with 300 mM NaCl, 20 mM imidazole, 5 mM beta -mercaptoethanol, 1 mM phenylmethylsulfonyl fluoride, and 1 × CompleteTM protease inhibitors and purified on nickel-nitrilotriacetic acid resin, preequilibrated with buffer 3. Bound protein was eluted with buffer 3 plus 230 mM imidazole. hFMRP production (68-70 kDa) was confirmed by Western blotting, and its purity was determined by Coomassie Blue staining. The micro-BCA assay was used to determine protein concentration (20).

In Vitro RNA Target Production-- RNAs were produced from linearized plasmids by in vitro transcription. The transcripts were purified on QuickSpinTM columns and quantified by UV-visible spectrophotometry at 260 and 280 nm (3).

Agarose Gel Electrophoretic Shift Assay (AGESA)-- Purified recombinant hFMRP was bound to RNA at room temperature. Briefly, the recombinant protein was preincubated for 10 min in buffer 1 supplemented with 0.25 mg/ml tRNA and 0.25 mg/ml ultrapure bovine serum albumin. Subsequently, RNA was added and incubated for an additional 20 min. hFMRP·RNA complexes were then resolved on 1% TAE agarose gels (50-60 V, 50 mA for 1-2 h) and visualized by ethidium bromide staining. Kd values were determined from titrations of recombinant proteins with fixed amounts of in vitro transcribed target RNAs. The percent complex formation was measured from scanned images of the AGESAs using IPLab Gel software (Signal Analytics Corp.) and plotted versus the amount of recombinant protein input into the reaction. A molecular mass of 69,000 Da was used to calculate the molar amount of hFMRP (12). The data were fit using a nonlinear curve-fitting program Kaleidograph software (Synergy Software) (21).

To verify specific complex formation, bands from different regions of a gel shift experiment were excised and boiled for 5 min in SDS buffer (22). The resulting extracts were blotted and probed with FMRP mAb 2160.

Affinity Capture and Homoribopolymer Binding Assays-- 35S-Labeled hFMRP, hFMRPDelta RGG, hFMRPDelta KH2, and hFMRPDelta RNB binding to biotinylated xEF-1A RNA was measured by affinity capture using SoftLinkTM resin in buffer 2 (3). Nonspecific binding, determined by comparison with reactions without in vitro transcribed RNA or nonbiotinylated xEF-1A RNA, was negligible. RNA binding was quantified using IPLab Gel software. The percent binding was calculated as shown in Equation 1.


<UP>% binding = bound<SUB>intensity</SUB>/</UP>(<UP>bound<SUB>intensity</SUB></UP> (Eq. 1)

<UP> + </UP>(<UP>4 × unbound<SUB>intensity</SUB></UP>))<UP> × 100</UP>
This corrects for load differences between the bound and unbound fractions. For the studies presented in Fig. 2, B and C, in which both full-length and incomplete proteins were produced, only the full-length protein was quantified. The -fold decrease in biotinylated xEF-1A RNA binding between full-length wild-type and full-length truncated hFMRPs was calculated as shown in Equation 2.
<UP>fold decrease = % binding<SUB>full-length hFMRP</SUB>/% binding<SUB>truncated hFMRP</SUB></UP> (Eq. 2)

xEF-1 RNA competition with homoribopolymer resins (poly(rG), and poly(rU)) was carried out with a 10-fold molar excess of xEF-1A RNA over poly(rN), a 2-fold molar excess of soluble poly(rG), or a 2-fold molar excess of soluble poly(rU). Briefly, 35S-hFMRP was incubated in buffer 2 containing 3 µg of poly(rN) resin and either xEF-1A RNA or soluble poly(rN) (1 h, 4 °C). Unbound 35S-hFMRP was removed; the resins were then washed with 40 column volumes of buffer 2. Bound 35S-hFMRP was eluted by boiling in SDS buffer. Biotinylated xEF-1A RNA competition with nonbiotinylated target mRNAs was carried out using the SoftLinkTM affinity capture protocol described above. A 5-fold molar excess of nonbiotinylated target mRNA over biotinylated xEF-1A mRNA was added to the reaction before adding 35S-hFMRP. Competition was expressed as the ratio of the percentage of biotinylated xEF-1A mRNA bound to hFMRP in the presence of competitor mRNA to the percentage of biotinylated xEF-1A mRNA bound to hFMRP in the absence of competitor mRNA.

Cell Culture-- Undifferentiated PC12 cells were grown at 37 °C in 5% CO2 and maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum. COS-7 cells were cultured in RPMI supplemented with 5% fetal calf serum and 2 mM glutamine. Cells (3 × 105/35-mm dish) were transfected with 1 µg of pSF2-hFMRP or with 1 µg of control DNAs (pET21A-hFMRP, pHA-hFXR1P). 24, 48, 72, or 96 h later the cells were harvested and used to prepare total RNA or total proteins (3, 23). The transfection efficiency for each experiment varied between 20 and 60%, but within a particular experiment the efficiency was uniform. Fragile X and normal lymphoblastoid cell lines were cultured in RPMI supplemented with 10% fetal bovine serum.

Gene Expression in Cultured Cells-- Northern blotting was carried out as described previously (23). Probes were prepared by amplifying the first 871 bases of human FMR1 cDNA from pSF2-hFMRP DNA and the entire xEF-1A coding sequence from pTRI-XEF DNA (86.7% identity to rat EF-1A mRNA). cDNAs were random prime labeled with [alpha -32P]dCTP and desalted on G-50 QuickSpinTM columns before hybridization.

Western blotting was performed as described previously (24). FMRP mAb 2160 was used at a 1:10,000 dilution; under these conditions the antibody preferentially detects hFMRP, therefore it is not possible to ascertain whether transient transfection results in FMRP overexpression. HSP-820, EF-1A, and dynamin mAbs were used at a 1:5,000 dilution. Blots were blocked for 1 h at room temperature in phosphate-buffered saline supplemented with 3% non-fat dry milk and probed overnight in fresh buffer with the corresponding primary antibody at 4 °C. Blots were developed using LumiGlo. Horseradish peroxidase-conjugated goat anti-mouse secondary antibody was used at a 1:5,000 dilution. FXR1 (Y-19) antibody and FXR2 (S-16) antibodies were used at a 1:100 dilution. Blots were blocked and probed as above and then developed using the manufacturer's washing procedure (www.scbt.com; Research Applications). Horseradish peroxidase-conjugated bovine anti-goat secondary antibody was used at a 1:2,000 dilution. Blots were probed simultaneously with two different antibodies, an internal control antibody such as dynamin or HSP-820 and an antibody directed to the protein of interest. Blots were quantified from scanned images; the ratio of protein to Hsp70cP was used to normalize all data.

Immunoprecipitation Analysis-- PC12 cells were transfected with pSF2-hFMRP or pET21A-hFMRP. 48 h post-transfection the cells were scraped in 1.0 ml of diethyl pyrocarbonate-treated 1 × phosphate-buffered saline and pelleted by centrifugation. The pellet was washed twice with ice-cold diethyl pyrocarbonate-treated 1 × phosphate-buffered saline. All subsequent steps were carried out at 4 °C. Pellets were lysed with 100 µl of buffer 1 supplemented with 1% IGEPAL CA630. The lysates (50 µl) were precleared for 3.5 h with 30 µl of protein A/G that was pretreated with 30 µl of normal mouse serum, 10 µl of RNAsin, 20 µl of 50 × Complete protease inhibitors, and 500 µl of buffer 1. The precleared lysates were immunoprecipitated overnight with 30 µl of FMRP mAb 2160-coupled protein A/G beads. After a 10-min 3,000 × g spin, proteins or RNA was extracted from the supernatants and pellets. Supernatant proteins were prepared by adding 3 × SDS sample buffer to the supernatant (250:750 µl ratio). Immunoprecipitated proteins were prepared by adding 300 µl of 1 × SDS sample buffer to each pellet. Total RNA was extracted from the immunoprecipitant using 1 ml of TRI-ReagentTM. The final RNA pellet was dissolved in 25 µl of diethyl pyrocarbonate-treated H2O and used to prepared first strand cDNA. cDNAs were amplified using rat-specific EF-1A-specific primers (5'-ATATTATCCCTAACACCTGCC, 5'-GGTCTCAAAATTCTGTGACAG) that amplify a 259-bp fragment from bases 1464 to 1723 of rat EF-1A mRNA, accession no. X61043. FMR1-specific primers (set A: 5'-GGCTAGAAGCTTTCTGGA, 5'-GTGAATGGAGTACCCTAA) were used to amplify a 1,023-bp fragment from bases 945 to 1968 of mouse fmr1 mRNA, accession no. L23971; whereas set B (5'-GGCTAGAAGCTTTCTGGA, 5'-ACGTGGAGGAGGCTTCAAAGGAAA) amplifies a hFMR1-specific 833-bp fragment from bases 831 to 1,644 of human FMR1 mRNA, accession no. NM_002024.

Polyribosome Analysis-- Polyribosomes were prepared by pelleting PC12 lysates through 50% sucrose pads (25). Briefly, PC12 cells (5 × 107) were transfected with pSF2-hFMRP or pET21A-hFMRP. 24 h later the cells were scraped from the dishes in ice-cold TMK buffer and pelleted. The pellets were lysed in 200 µl of TMK buffer supplemented with 1% IGEPAL CA630. 50-µl aliquots were loaded on 50% sucrose pads containing 500 µl of TMK buffer and centrifuged at 50,000 rpm for 20 h. The resulting polyribosome pellets were washed with 200 µl of TMK buffer and then extracted with 50 µl of 1 × SDS sample buffer. In some cases, the lysates were treated for 5 min at 37 °C with 25 mM EDTA to disrupt the polyribosomes (8, 25-27).

RNA Motif Analysis-- A minimal sequence WGGN1-4 WGGN1-4 WGGN1-4 WGGN0-6 was used to assess EF-1A mRNA and individual FMRP-target mRNAs (1, 3) for the potential presence of G quartet structures. Candidates containing such sequences were then folded into secondary structure models using Mfold (//bioinfo.math.rpi.edu/) or RNABOB to determine whether a requisite hairpin stem-loop S6 NWGGN1-4 WGGN1-4 WGGN1-4 WGGN0-6NS6 formed (6).

    RESULTS
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ABSTRACT
INTRODUCTION
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FMRP Binds EF-1A in Vitro-- Several studies using FMR1 mRNA have been undertaken to define the RNA motif that FMRP recognizes (3, 7, 28). The results suggest that FMRP may bind to multiple regions of a mRNA (19); thus, in assessing FMRP target mRNA binding, an assay that measures interactions of large mRNAs with FMRP is necessary. To do this, we modified a nondenaturing AGESA (30) so that unlabeled in vitro transcribed mRNAs and mRNA·protein complexes could be visualized by ethidium bromide staining. Fig. 1A illustrates results obtained by incubating the 1.9-kb 3'-untranslated region of human FMR1 mRNA (FMR1 3'-UTR) or a 1.4-kb lambda RNA fragment (lambda -control RNA) in the presence or absence of purified recombinant human FMRP (hFMRP). As shown in lane 1, FMR1 3'-UTR mRNA migrated as two bands in the absence of hFMRP, indicating that the RNA resides in two conformational states (31). These two conformers coalesced into a uniquely migrating single band in the presence of hFMRP (lane 2). Although the shift was small, the bands were completely resolved. In contrast, the shift did not occur when the recombinant protein was added to lambda -control RNA (lanes 3 and 4). This was expected because FMR1 3'-UTR mRNA binds specifically to FMRP (1, 3, 7, 28), whereas the lambda -control RNA does not (1, 3).


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Fig. 1.   Resolution of hFMRP·RNA complexes by AGESA. A, specific hFMRP·RNA complexes form in the presence of 50 ng of purified recombinant hFMRP and 0.1 µg of hFMR1 3'-UTR RNA (lane 2) which are resolved from unbound hFMR1 3'-UTR RNA (lane 1). These complexes (marked by an asterisk) form in the presence of excess tRNA; a nonbinding RNA of similar length (3) does not form complexes under identical conditions (lanes 3 and 4). B, 0.1 µg of xEF-1A mRNA binds to 50 ng of hFMRP in vitro. Specific hFMRP·xEF-1A mRNA complexes (lane 3) and hFMRP-I304N·xEF-1A complexes (lane 4) are observed under the same conditions as A. The complexes are fully resolved from xEF-1A mRNA alone (lane 1) or xEF-1A with 2.5 µg of bovine serum albumin and 2.5 µg of tRNA (lane 2). Complex formation is disrupted by increasing the ionic strength of the binding buffer to 0.5 M (lanes 5 and 6) or by prior denaturation of hFMRP or hFMRP-I304N (lanes 7 and 8). Recombinant proteins do not contain residual RNA (lanes 9 and 10). The effect of added salt (lanes 13-15) on binding is shown in lanes 3 and 12. C, binding 0-50 ng of hFMRP to 0.1 µg of xEF-1A mRNA is saturable, and quantitative differences are observed between wild-type and I304N mutant hFMRP. The mean values for two independent experiments are plotted. D, 10 ng of hFMRP is specifically isolated from 0.5 µg of the xEF-1A mRNA-shifted bands. Bands 1-5 (left panel) were excised and proteins extracted. The extracts 1-5 (right panel) were probed with FMRP mAb 2160 on Western blots.

Although these data are consistent with the formation of an hFMRP·FMR1 3'-UTR complex, several control experiments were performed to confirm this observation. To our surprise, another RNA, EF-1A from Xenopus (xEF-1A mRNA, 1.6 kb), displayed the same feature as FMR1 3'-UTR mRNA in AGESA. As shown in Fig. 1B, the two xEF-1A mRNA conformers (lane 1) coalesced into a uniquely migrating single band in the presence of hFMRP (lane 3). This result was recapitulated when we used hFMRP-I304N, containing the KH2 RNA binding domain mutation I304N (lane 4). This mutant was of particular interest because it is associated with exceptionally severe mental retardation (32). Because NaCl concentrations above 0.25 M decrease the FMRP affinity for RNA we also examined the effect 0.5 M NaCl had on xEF-1A mRNA binding to hFMRP and hFMRP-I304N. Fig. 1B, lanes 5 and 6, shows that the band shift seen in lanes 3 and 4 was completely abrogated; lesser decreases were observed at lower salt concentrations (lanes 11-15). The RNA mobility shift was also lost when the recombinant proteins were heat denatured at 65 °C for 5 min before adding xEF-1A mRNA (lanes 7 and 8). These data indicate that more than the mere presence of the recombinant hFMRPs is required for the shift. In addition, the fact that 2.5 µg of recombinant bovine serum albumin failed to produce a shift (compare lanes 1 and 2) indicates that the response was not due simply to added native protein. Finally, lanes 9 and 10 demonstrate that neither recombinant protein preparation contained large molecular mass nucleic acid, indicating that the shifted bands contained xEF-1A mRNA.

We then used AGESA to define further the binding properties of hFMRP and xEF-1A mRNA. Fig. 1C shows that xEF-1A mRNA binding was saturable with increasing concentrations of hFMRP or hFMRP-I304N. The apparent Kd values for these complexes were 3.0 and 6.1 nM, respectively. These data corroborate the data in Fig. 1B, suggesting that hFMRP and hFMRP-I304N binding to xEF-1A mRNA is specific.

To demonstrate further that the shifted band was an xEF-1A mRNA·hFMRP complex, hFMRP was specifically and uniquely recovered from the putative complex. Here, xEF-1A mRNA was incubated alone or with subsaturating amounts of purified recombinant hFMRP and subsequently resolved by AGESA. Fig. 1D shows that adding hFMRP resulted in either the loss or decrease in the upper xEF-1A conformers and a concurrent broadening of the lower conformer (compare lanes 1 and 2). Five regions of this gel were then excised and probed for the presence of hFMRP. The right panel of Fig. 1D shows that only the xEF-1A mRNA-shifted band contained hFMRP (lane 2). Thus, these data demonstrate that recombinant hFMRP and xEF-1A mRNA associate in vitro.

xEF-1A mRNA Binding Requires the C-terminal Arginine-Glycine-rich Region-- FMRP has three RNA binding domains, and there is no a priori basis for knowing whether one or any combination of them interacts with a particular RNA. We have previously used 35S-FMRP truncation mutants in affinity capture assays to show that hFMR1 mRNA binding requires determinants in its KH2 domain (1, 3). Therefore, we employed this strategy to determine the domains required for binding xEF-1A mRNA. Four different hFMRP forms were assessed: 1) full-length hFMRP, 2) hFMRPDelta RGG in which the last 334 amino acids including the arginine-glycine-rich region are deleted, 3) hFMRPDelta KH2 in which the arginine-glycine-rich region and the KH2 domain are deleted, and 4) hFMRPDelta RNB in which all three RNA binding domains are deleted (Fig. 2A). Fig. 2B shows that xEF-1A mRNA bound 35S-hFMRP, recapitulating the results of Fig. 1. 35S-hFMRPDelta RGG also bound to xEF-1A mRNA, albeit with a 6.5-fold decrease in affinity compared with full-length hFMRP. Removing the KH2 domain (35S-hFMRPDelta KH2) reduced the binding further, whereas 35S-hFMRPDelta RNB binding was not detectable under the conditions of the assay. Therefore, the C-terminal 334 amino acids of hFMRP play a major role (either direct or indirect) in binding xEF-1A mRNA; however, the KH2 domain also influences the binding as well.


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Fig. 2.   Interaction of xEF-1A mRNA with hFMRP protein domains. A, RNA binding domains of full-length hFMRP, hFMRPDelta RGG, hFMRPDelta KH2, and hFMRPDelta RNB. KH domain numbering was based on sequence assignments of Lewis et al. (29). B, biotinylated xEF-1A mRNA binding to 35S-hFMRP, 35S-hFMRPDelta RGG, 35S-hFMRPDelta KH2, or 35S-hFMRPDelta RNB. Bound material was captured on SoftLinkTM avidin resin. The unbound (U) and the bound (B) fractions were assessed by autoradiography. Arrows mark full-length hFMRP or the corresponding truncation mutant. The asterisk (*) marks incomplete or breakdown products formed during in vitro translation (19). C, xEF-1A mRNA, target mRNAs hFMR1 CDS and hFMR1 3'-UTR but not lambda -control RNA, compete with biotinylated xEF-1A mRNA in binding to 35S-hFMRP. The values for two independent experiments are plotted. D, xEF-1A mRNA does not compete with poly(rG) in binding to 35S-hFMRP; binding was assessed as in B. The arrow marks full-length hFMRP forms. The asterisk (*) marks the major incomplete or breakdown product formed in the in vitro translation reaction.

hFMRP appears to use unique sets of residues in binding various parts of FMR1 mRNA. To determine whether these residues were similar or identical to those interacting with xEF-1A mRNA we performed affinity capture competition assays in which 35S-hFMRP binding to biotinylated xEF-1A RNA was competed with nonbiotinylated RNA cognates (xEF-1A, hFMR1 CDS, hFMR1 3'-UTR, or lambda -control). Fig. 2C shows the effect of a 5-fold molar excess of nonbiotinylated RNA. Here, FMR1 CDS RNA and FMR1 3'-UTR RNA reduced the amount of 35S-hFMRP bound to biotinylated xEF-1A mRNA by 28.6 and 44.4%, respectively. In contrast, lambda -control RNA had no effect. However, xEF-1A mRNA was the best competitor with a 66.7% reduction compared with binding in the absence of competitor RNA. These data suggest that the hFMRP residues that bind xEF-1A are similar but not identical to those that bind FMR1 CDS RNA or FMR1 3'-UTR RNA.

Poly(rG) and poly(rU) RNA mimetics bind primarily to incompletely overlapping residues in the last 300 amino acids of hFMRP. Therefore, we performed a similar competition study with them. We found that a 2-fold molar excess of poly(rG) completely blocked hFMRP binding to poly(rG) resin. In contrast, a 10-fold molar excess of xEF-1A mRNA had no effect on the ability of hFMRP to bind to poly(rG) (Fig. 2D) or poly(rU) (not shown) resins. This suggests that the determinants within the C-terminal region which bind to poly(rG) and poly(rU) differ from xEF-1A mRNA, or xEF-1A mRNA binds much more weakly to hFMRP than either homoribopolymer.

Recent studies have shown that a nucleic acid tertiary structure element called a G quartet, whose formation is enhanced in the presence of potassium cations, is present in several mRNAs that may interact with FMRP (6, 7, 17, 18). Using the criteria of Darnell et al. (6), we showed that xEF-1A mRNA lacked a perfect G quartet motif (Table I). We then experimentally confirmed that the hFMRP interaction with xEF-1A mRNA was not enhanced in buffers in which we substituted 0.15 M K+ for 0.15 M Na+ (not shown). These data, then, are consistent with the hypothesis that the interaction between hFMRP and xEF-1A mRNA does not depend on the formation of a G quartet structure.


                              
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Table I
G quartet analysis of FMRP target mRNAs

FMRP Inhibits EF-1A Expression in Vivo-- EF-1A mRNA is translationally repressed by a factor that can be salt-washed from mRNPs (33). Previous studies have also demonstrated that recombinant hFMRP inhibits the expression of certain mRNAs (15, 16, 34). To determine whether FMRP affects EF-1A mRNA translation, PC12 cells were transfected with plasmids that produce human FMRP (pSF2-hFMRP) or a nonexpressing control (pET21A-hFMRP). hFMRP and endogenous rat EF-1A (rEF-1A) protein expression patterns were then examined. First, transfected cell extracts were probed with antibodies to FMRP, EF-1A, and control proteins dynamin and Hsp70cP (Fig. 3A). Intense hFMRP-specific staining was observed in pSF2-hFMRP-transfected cell extracts, whereas comparatively weaker endogenous rFMRP staining was found in pET21A-hFMRP-transfected cell extracts. More importantly, rEF-1A levels were significantly lower in pSF2-hFMRP extracts than in pET21A-hFMRP extracts. This is not a pleiotrophic effect because dynamin and Hsp70cP levels were nearly equivalent in both sets of transfected cells.


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Fig. 3.   Effects of transiently expressing hFMRP in undifferentiated PC12 cells and COS-7 cells. A, PC12 cells were transfected with pET21A-hFMRP (lane 1) or pSF2-hFMRP (lane 2) and harvested 24 h after transfection. Total transfected cell proteins were blotted and probed sequentially with FMRP mAb and dynamin mAb, followed by Hsp70cP mAb and EF-1A mAb. B, Northern blots from an identical set of pET21A-hFMRP- (lane 1) or pSF2-hFMRP- (lane 2) transfected PC12 cells harvested 24 h post-transfection. Blots were probed with an FMR1-specific cDNA or an EF-1A-specific cDNA, as indicated. Total RNA is shown as a load control. C, COS-7 cells were transfected with pSF2-hFMRP (lane 1), pET21A-hFMRP (lane 2), or pHA-FXR1P (lane 3) and harvested 24 h post-transfection. Total proteins were blotted as in A; one blot was probed sequentially with FMRP mAb and dynamin mAb followed by Hsp70cP mAb and EF-1A mAb; a duplicate blot was probed with dynamin mAb and FXR1P mAb. The transfection efficiency, determined by immunostaining for hFMRP and hFXR1P, was equivalent.

To know whether the rEF-1A protein reduction in hFMRP-expressing cells resulted from transcriptional or translational regulation, we performed Northern blotting experiments using probes that specifically recognized human FMR1 mRNA or that detected endogenous rat EF-1A mRNA (rEF-1A mRNA). As shown in Fig. 3B, hFMR1 mRNA was expressed abundantly in pSF2-hFMRP-transfected cells but not in pET21A-hFMRP-transfected cells. However, there was no detectable reduction in rEF-1A mRNA, indicating that the decrease in rEF-1A protein levels in pSF2-hFMRP-transfected cells was not caused by hFMRP-mediated rEF-1A mRNA instability. These data are consistent with the hypothesis that hFMRP negatively regulates endogenous rat EF-1A mRNA translation in vivo.

To explore further the inverse correlation between hFMRP and rEF-1A protein expression we examined the effect hFXR1P, a homolog of hFMRP, had on EF-1A expression. Specifically, COS-7 cells were transfected with pSF2-hFMRP, pET21A-hFMRP, or pHA-FXR1P. Extracts from the transfected cells were then probed with antibodies to FMRP, EF-1A, dynamin, Hsp70cP, and hFXR1P (Fig. 3C). As expected, hFMRP was readily detected in pSF2-hFMRP-transfected cells, whereas the other two transfected cell lines displayed weaker staining of endogenous monkey FMRP. Similarly, FXR1P expression was detected preferentially in pHA-FXR1P-transfected cells. As was the case in PC12 cells, no discernible differences were observed in dynamin or Hsp70cP. In contrast, EF-1A levels were much lower in pSF2-hFMRP-transfected cells than in cells transfected with either pET21A-hFMRP or pHA-hFXR1P. Again, EF-1A mRNA levels were unchanged in the three different transfected cell lines (not shown). These data corroborate those from PC12 cells, demonstrating that the hFMRP effect on EF-1A expression does not depend on cell type.

If hFMRP suppresses EF-1A mRNA translation, then decreased hFMRP expression should increase EF-1A protein expression. Therefore, we transiently expressed hFMRP in PC12 cells and examined its effect on rEF-1A, Hsp70cP, and beta APP, a hFMRP-nonbinding mRNA (3), over an extended period of time post-transfection. Fig. 4A shows an example of one such experiment. Here, hFMRP reached its highest expression 24-48 h after transfection and subsequently decreased to 31% of its peak value 96 h later. In contrast, Hsp70cP levels were not markedly affected. Fig. 4B shows that as hFMRP levels decrease, a corresponding increase in relative rEF-1A protein expression occurs, whereas relative beta APP levels were not significantly affected. In contrast, in control extracts where endogenous rFMRP levels did not vary, both relative rEF-1A levels and relative beta APP levels were unchanged.


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Fig. 4.   rEF-1A expression correlates inversely with hFMRP expression in PC12 cells. PC12 cells were transfected with pSF2-hFMRP or pET21A-hFMRP. 24, 48, 72, and 96 h post-transfection the cells were harvested; extracted proteins were blotted as in Fig. 3. A, hFMRP expression in pSF2-hFMRP-transfected cells decreases over time. Corresponding changes were not observed for Hsp70cP. B, rEF-1A levels increase coordinately in pSF2-hFMRP-transfected cells but are relatively constant in pET21A-hFMRP-transfected cells. beta APP expression is unchanged in pSF2-hFMRP-transfected cells and pET21A-hFMRP-transfected cells. Western blots were probed simultaneously with antibodies to Hsp70cP and FMRP, or Hsp70cP and EF-1A, or Hsp70cP and beta APP; the FMRP:Hsp70cP, EF-1A:Hsp70cP, and beta APP:Hsp70cP ratios for two independent experiments are plotted. The amount of Hsp70cP over the period examined did not vary by more than 12%.

To demonstrate that the relationship between hFMRP expression and rEF-1A expression observed in Figs. 3 and 4 occurred by direct interaction of hFMRP and rEF-1A mRNA, we immunoprecipitated hFMRP from pSF2-hFMRP-transfected PC12 cells. We then isolated the mRNAs from the immunocomplex and determined whether rEF-1A mRNA was incorporated. As controls we immunoprecipitated pET21A-hFMRP-transfected cells and processed pSF2-hFMRP-transfected cells in the same manner without the precipitating antibody. Fig. 5A shows that hFMRP was present in the pSF2-hFMRP-transfected cell supernatant and immunoprecipitate; in contrast, hFMRP was only found in the supernatant in the absence of FMRP mAb 2160. Finally, FMRP was not detected in either the supernatant or the immunoprecipitate of pET21A-hFMRP-transfected cells under the same conditions. As shown in Fig. 3, A and C, FMRP mAb 2160 recognizes endogenous rFMRP with much less sensitivity than hFMRP. Thus, these results were not surprising.


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Fig. 5.   EF-1A mRNA specifically associates with hFMRP in transiently transfected PC12 cells. PC12 cells were transfected with pSF2-hFMRP or pET21A-hFMRP. 24 h post-transfection the cells were harvested and lysed. FMRP was immunoprecipitated (IP) from the lysates using FMRP mAb 2160. An identical pSF2-hFMRP transfection was processed similarly except that FMRP mAb 2160 was omitted. Half of the sample was used to extract proteins; half was used to extract mRNA. A, Western blot (WB) analysis of the FMRP distribution in immunoprecipitate (P) and supernatant (S) fractions. 1×S and 4×P correspond to the protein loads. B, FXR1P and FXR2P are found in pSF2-hFMRP-transfected cell immunoprecipitates and supernatants. C, EF-1A mRNA and FMR1 mRNA are amplified from RNA associated with the pSF2-hFMRP immunoprecipitate. Mouse FMRP plasmid DNA (10 ng) (lane 1) and cDNA from total PC12 lysates, the pET21A-hFMRP immunoprecipitate, and the pSF2-hFMRP immunoprecipitate (lanes 2-4, respectively) were amplified with primers for rat EF-1A mRNA (rEF-1A), rat and human FMR1 mRNA (r/hFMR1), or human FMR1 mRNA (hFMR1), as indicated. D, FMRP distribution in polyribosomes. PC12 cells were transfected with pSF2-hFMRP or pET21A-hFMRP. 24 h post-transfection the cells were harvested and lysed. Cell lysates were treated or not treated with EDTA and polyribosomal pellets isolated. Pelleted proteins were blotted and probed with FMRP mAb 2160 (top panels) or assessed for protein by Coomassie Blue staining (bottom panels).

Next, we demonstrated that the pSF2-hFMRP-transfected PC12 cell hFMRP immunocomplex contained known FMRP-associated proteins (10, 35-38). Western blots of the supernatant and immunoprecipitate fractions were probed with either FXR1P- or FXR2P-specific antibodies; both proteins were associated with the pSF2-hFMRP immunoprecipitate (Fig. 5B), indicating that the transiently expressed hFMRP associates with mRNPs that contain proteins that complex with endogenous rFMRP.

We then extracted mRNA associated with the FMRP immunoprecipitates and amplified it with rat EF-1A-specific primers. Fig. 5C shows that rEF-1A mRNA was amplified from cDNA generated from untransfected PC12 cell RNA and from the pSF2-hFMRP immunoprecipitate, but not the pET21A-hFMRP immunoprecipitate. Because FMR1 mRNA binds to FMRP, we also examined whether the immunoprecipitate-associated mRNA contained FMR1 mRNA. Two sets of primers were used; set A amplified a conserved 1,023-bp fragment from different species of FMR1, and set B amplified a 833-bp human FMR1-specific fragment. As expected, the set A primers amplified Fmr1 from as a plasmid containing full-length mouse FMRP as well as cDNAs derived from PC12 cell total RNA and from the pSF2-hFMRP immunoprecipitate, but not from the pET21A-hFMRP immunoprecipitate. In contrast, set B primers exclusively amplified hFMR1 from the pSF2-hFMRP immunoprecipitate. These results demonstrate that rEF-1A mRNA as well as r/hFMR1 mRNA and hFMR1 mRNA associate with hFMRP in PC12 cells.

Finally, to rule out that the decreased rEF-1A expression in pSF2-hFMRP-transfected cells occurred because heterologous hFMRP sequestered rEF-1A mRNA in inactive mRNPs, we ascertained whether recombinant hFMRP was incorporated into PC12 cell polyribosomes. Western blots of pET21A-hFMRP-transfected cell polyribosomal pellets contain a band corresponding to endogenous rFMRP that was dissociated by EDTA (Fig. 5D). In pSF2-hFMRP-transfected cells, a much stronger band corresponding to recombinant hFMRP and endogenous rat FMRP was found in the polyribosome pellet in the absence of EDTA. Again, EDTA treatment released most of the associated FMRP. Thus, the data in Fig. 5, C and D, demonstrate that rEF-1A mRNA associates with hFMRP in a multiprotein mRNP complex and that hFMRP-containing mRNPs associate with polyribosomes.

EF-1A Protein Levels Increase in Fragile X Lymphocytes-- Fragile X syndrome results from the loss of hFMRP, and it has been hypothesized that this loss should produce changes in the expression of the mRNAs it interacts with (3, 39, 40). The data obtained from transiently expressing hFMRP in PC12 and COS-7 cells suggest that hFMRP negatively regulates EF-1A expression. If true, human EF-1A (hEF-1A) expression should be greater in fragile X patients than in normal individuals. To test this, full-mutation fragile X male and normal male control lymphoblastoid cell lines were probed for EF-1A and Hsp70cP expression. Fig. 6A shows that hEF-1A was 2.1-fold greater in fragile X cell lines than in control cell lines (p > 0.003, analysis of variance). In contrast, hEF-1A mRNA levels were not significantly different between the two groups (Fig. 6B). Thus, hFMRP appears to regulate hEF-1A mRNA translation in vivo negatively.


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Fig. 6.   A, EF-1A protein levels are elevated in fragile X lymphoblastoid cells compared with control lymphoblastoid cells. Total lymphoblastoid cell line proteins from six full-mutation fragile X males with moderate to profound mental retardation and four normal male controls were probed simultaneously for Hsp70cP and EF-1A expression by Western blotting. The EF-1A:Hsp70cP ratio (relative EF-1A) for two experiments is plotted. B, EF-1A mRNA levels are not altered in fragile X lymphoblastoid cells. Total RNA from control lymphoblastoid cell lines (C1-C3) and fragile X lymphoblastoid cell lines (F1-F5) was blotted and probed with 32P-labeled EF-1A cDNA. The rRNA load for each sample is shown below.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Our data show that hFMRP binds xEF-1A mRNA in vitro. Binding was detected both as a minimal mRNP composed of recombinant hFMRP and xEF-1A mRNA and also as a larger mRNP (1) using in vitro translated hFMRP. This serendipitous finding led us to perform several experiments to confirm the observation and then to generalize the interaction to an in vivo setting by isolating EF-1A mRNA from hFMRP-containing immunoprecipitates. To our knowledge this is the first demonstration that a mRNA that binds to solely to FMRP in vitro has altered expression when FMRP levels are modulated in vivo. Other reports, (1, 3, 12, 15, 16) have failed to demonstrate that specific in vitro bound mRNAs bind FMRP in cells or that mRNAs associated with FMRP-containing mRNPs bind directly to it (10, 17, 18, 35).

Using two in vitro binding assays and several different binding conditions we found that hFMRP formed a specific complex with xEF-1A mRNA. From agarose gel shift assays conducted under conditions used to demonstrate specific binding of the RNA binding protein HuD (30), we observed small reproducible shifts in the migration of a rather large xEF-1A mRNA transcript. These shifts occurred only in the presence of native hFMRPs and were disrupted by high salt concentrations. We also determined that the Kd of xEF-1A mRNA and recombinant hFMRP was ~3 nM. This value is similar to Kd values calculated for FMR1 mRNA (12) using an affinity capture assay, EMSA results for a 426-base RNA encoding part of the FMR1 CDS (7), as well nitrocellulose filter binding experiments with 96-base SELEX-derived RNAs (6). Thus, AGESA complements these other assays and demonstrates that specific interactions occur between recombinant hFMRP and mRNA in vitro.

Studies with truncated hFMRPs showed that the arginine-glycine-rich C-terminal end was required for efficient xEF-1A mRNA binding in vitro. Currently, we cannot differentiate whether this region interacts directly with xEF-1A mRNA or whether it merely stabilizes the domain that xEF-1A mRNA binds to. The results of Fig. 2B suggest that the KH2 domain plays at least a small role in binding, and this is corroborated by the results in Fig. 1C showing that the hFMRP-I304N Kd is slightly weaker than hFMRP. Furthermore, the protein determinants used to bind xEF-1A mRNA do not appear to overlap completely those of FMR CDS RNA, FMR1 3'-UTR RNA (Fig. 2C), or poly(rG) (Fig. 2D), or poly(rU). Although studies using other FMRP truncations and point mutants are needed to address this question fully our data are consistent with the view that full-length mRNAs bind to multiple FMRP RNA binding domains.

Recent studies show that hFMRP binds to a G quartet structure in hFMR1 CDS with high affinity (7), and an in vitro selected RNA (sc-1) with a G quartet binds to the arginine-glycine-rich-region of an alternatively spliced hFMRP variant (6). EF-1A mRNA, however, does not contain a perfect G quartet motif, and we determined experimentally that the G quartet-stabilizing cation, K+ (41), did not enhance xEF-1A mRNA binding to hFMRP. This suggests that there are different RNA-binding determinants in xEF-1A mRNA than FMR1 mRNA or sc-1 RNA. In fact, of the 10 RNAs we have demonstrated hFMRP binds in vitro (1, 3), 5 do not contain a G quartet structure (Table I). These data extend the recently published microarray studies (18) and imply that this structure may not be as involved in generating the fragile X phenotype as has been intimated (42).

The effects of altering hFMRP levels in vivo were examined in cultured cells that transiently express hFMRP and cultured lymphoblastoid cells derived from fragile X patients that lack FMRP. The former mimics, to a certain degree, FMRP expression during embryogenesis where the level of FMRP rises and then levels off or decreases in certain cells (43-46). In both cases EF-1A protein levels, but not mRNA levels, change in response to hFMRP expression. The effect is very specific because three other proteins, beta APP, dynamin, and Hsp70cP, remain unaltered in the transfected cells, and hFXR1P expression did not replicate the effect. These data suggest that hFMRP regulates EF-1A mRNA translation via direct interaction. To demonstrate this more convincingly, we immunoprecipitated hFMRP from transiently transfected PC12 cells and showed that rEF-1A mRNA was specifically found in the immunoprecipitate. We also established that the expressed recombinant hFMRP functioned normally in PC12 cells. Indeed, we showed that hFMRP was present in polyribosomal pellets and could be dissociated by conditions that keep the ribosomal subunits intact (8, 26, 27). Based on this, we believe our transient expression system validly models functional FMRP- mRNA interactions.

Although providing an important indicator, the transient transfection data alone did not conclusively demonstrate that FMRP negatively regulates EF-1A expression. For example, if hFMRP positively regulated rEF-1A mRNA translation, but the hFMR1 mRNA transcription rate exceeded its translation rate, the excess hFMR1 mRNA produced might sequester the entire endogenous rFMRP and recombinant hFMRP. Because the Kd values of hFMR1 and EF-1A mRNA are similar, this would lead to decreased rEF-1A when hFMRP is expressed. However, if the hFMR1 mRNA transcription rate is less than or equal to its translation rate, then hFMR1 mRNA should not alter FMRP levels enough to affect rEF-1A mRNA binding; in this case, decreased rEF-1A would imply a negative regulatory mechanism. To differentiate between these two possibilities, we compared EF-1A levels in fragile X lymphoblastoid cell lines, lacking FMRP, with their normal counterparts. We found that EF-1A protein levels were elevated in fragile X-derived cells compared with the normal controls, whereas EF-1A mRNA levels did not change. Both data sets are consistent with the hypothesis that FMRP negatively regulates EF-1A expression.

Our results show that in PC12 cells, COS-7 cells, and in fragile X lymphoblastoid cells EF-1A expression is altered as a function of hFMRP expression. However, this observation must be extended to the brain and testes, the major affected organs in fragile X syndrome. We are currently addressing this by comparing EF-1A expression profiles in fragile X knockout mouse and normal littermate controls; however, several factors may complicate this analysis. First, it has been noted previously that FMRP in vitro binding displays both species specificity and isoform specificity (19), and it is currently not known whether any mouse FMRP isoform binds mEF-1A mRNA. Second, FMRP knockout mice demonstrate region-specific deficits in several proteins including the receptor GluR1 (47), and their effect on EF-1A expression is also unknown. Third, in humans, rats, and mice two forms of EF-1A (EF-1A and EF-1A-2) are expressed in a tissue-specific manner. Unlike lymphocytes where EF-1A is singularly expressed, both forms are coexpressed in brain, and they appear to be regulated differentially (48-51). Although the amino acid homology of the two proteins is high in mice (92.4%), the nucleotide homology is less striking (79.8%), and it is not known whether EF-1A-2 mRNA binds to FMRP, or whether changes in the level of either protein may be compensated by the other.

What role might elevated EF-1A levels play in fragile X syndrome? In yeast (52) increased EF-1A protein levels correlate with increased nonsense suppression. In fact, a 2-fold EF-1A increase significantly increased suppression of a number of marker genes. Such an increase is about what we observed in fragile X lymphoblastoid cells. Whether suppression occurs in mammalian cells in response to FMRP-altered EF-1A expression is unknown; however, such a result might lead to increased mutant or truncated protein levels that could negatively affect normal cellular functions. As this would be a stochastic process this result could explain the observed variability in the fragile X phenotype (53). Alternatively, increased EF-1A expression might manifest itself in growth defects and changes in cellular morphology by altering cytoskeletal actin as has been observed in yeast (54). Actin-associated alterations in dendritic spine shape and stability are a well known feature of fragile X syndrome (55-57). Both questions are under active investigation. However, it is also possible that the altered EF-1A levels in fragile X patient lymphoblastoid cells have nothing to do with brain dysfunction or any of the other clinical features of the fragile X phenotype. Rather, it may simply be a silent by-product of the loss of FMRP. Further work will determine which of these scenarios is correct.

    ACKNOWLEDGEMENTS

We thank Drs. David L. Miller, Yu-Wen Hwang, and Carl Dobkin for comments on this manuscript and Dr. George Merz for expert technical assistance with the confocal microscopy studies.

    FOOTNOTES

* This work was supported in part by the FRAXA Foundation and the New York State Office of Mental Retardation and Developmental Disabilities.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

** To whom correspondence should be addressed: Biochemical Molecular Neurobiology Laboratory, Dept. of Molecular Biology New York State Institute for Basic Research in Developmental Disabilities, 1050 Forest Hill Rd., Staten Island, NY 10314. Tel.: 718-494-5199; Fax: 718-494-5905; E-mail: rbdenman@yahoo.com.

Published, JBC Papers in Press, February 19, 2003, DOI 10.1074/jbc.M211117200

    ABBREVIATIONS

The abbreviations used are: FMRP, fragile X mental retardation protein; AGESA, agarose gel electrophoretic shift assay; CDS, coding sequence; EF-1A, elongation factor 1A; FXR1P and FXR2P, fragile X related proteins 1 and 2, respectively; h, human species designation; Hsp70cP, constitutive heat shock 70 protein; KH2 domain, hnRNP K homology domain; m, mouse species designation; mAb, monoclonal antibody; r, rat species designation; UTR, untranslated region; x, Xenopus species designation.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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