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J. Biol. Chem., Vol. 281, Issue 26, 17929-17940, June 30, 2006

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Amino Acid Starvation Induces the SNAT2 Neutral Amino Acid Transporter by a Mechanism That Involves Eukaryotic Initiation Factor 2 Phosphorylation and cap-independent Translation^*

Francesca Gaccioliy, Charlie C. Huang, Chuanping Wang, Elena Bevilacqua, Renata Franchi-Gazzola, Gian Carlo Gazzola, Ovidio Bussolati, Martin D. Snider^¶, and Maria Hatzoglou¹

From the Departments of Nutrition and ^¶Biochemistry, Case Western Reserve University School of Medicine, Cleveland, Ohio 44106 and Unit of General and Clinical Pathology, Department of Experimental Medicine, University of Parma, 43100 Parma, Italy

Received for publication, January 12, 2006 , and in revised form, March 17, 2006.

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Nutritional stress caused by amino acid starvation involves a coordinated cellular response that includes the global decrease of protein synthesis and the increased production of cell defense proteins. Part of this response is the induction of transport system A for neutral amino acids that leads to the recovery of cell volume and amino acid levels once extracellular amino acid availability is restored. Hypertonic stress also increases system A activity as a mechanism to promote a rapid recovery of cell volume. Both a starvation-dependent and a hypertonic increase of system A transport activity are due to the induction of SNAT2, the ubiquitous member of SLC38 family. The molecular mechanisms underlying SNAT2 induction were investigated in tissue culture cells. We show that the increase in system A transport activity and SNAT2 mRNA levels upon amino acid starvation were blunted in cells with a mutant eIF2 that cannot be phosphorylated. In contrast, the induction of system A activity and SNAT2 mRNA levels by hypertonic stress were independent of eIF2 phosphorylation. The translational control of the SNAT2 mRNA during amino acid starvation was also investigated. It is shown that the 5'-untranslated region contains an internal ribosome entry site that is constitutively active in amino acid-fed and -deficient cells and in a cell-free system. We also show that amino acid starvation caused a 2.5-fold increase in mRNA and protein expression from a reporter construct containing both the SNAT2 intronic amino acid response element and the SNAT2-untranslated region. We conclude that the adaptive response of system A activity to amino acid starvation requires eukaryotic initiation factor 2 phosphorylation, increased gene transcription, and internal ribosome entry site-mediated translation. In contrast, the response to hypertonic stress does not involve eukaryotic initiation factor 2 phosphorylation, suggesting that SNAT2 expression can be modulated by specific signaling pathways in response to different stresses.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
The severe nutritional stress caused by amino acid starvation triggers several adaptive changes. One of these is the stimulation of transport system A for neutral amino acids. Adaptive regulation of system A has been described in most amino acid-starved animal cells (1–3). Work from several laboratories (4–6) has demonstrated that this regulatory mechanism is associated with an increase in the mRNA for SNAT2, the ubiquitously expressed member of the sodium-coupled neutral amino acid transporter family (7). The induction of SNAT2 transcription leads to the increased synthesis of SNAT2 carriers, which are found in greater amounts on the membranes of starved cells (5, 8). Recently, an amino acid-responsive element has been identified in the first intron of the mouse and human SNAT2 genes (9), supporting the hypothesis that transcriptional activation contributes to the adaptive regulation of system A.

Unlike transcriptional activation, the translation of SNAT2 during amino acid starvation has received little attention thus far. However, it is known that amino acid deprivation profoundly affects overall protein synthesis. Indeed, in amino acid-starved cells uncharged transfer RNAs activate the GCN2 pathway, a master regulator of the cellular response to nutritional stress from yeast to mammals (10), leading to the phosphorylation of the subunit of the eIF2² translation initiation factor (eIF2) on Ser-51. eIF2 phosphorylation causes reduced levels of ternary complexes (11), thus resulting in the inefficient translation of the majority of cellular mRNAs (12). In contrast, the translation of mRNAs that encode proteins that are essential for the cellular stress response is promoted (13, 14). Among these proteins are the transcription factors activating transcription factor 4 (ATF4) and CCAAT/enhancer-binding protein (C/EBP), which are important in stress-induced gene expression (15–18). Moreover, amino acid starvation causes the dephosphorylation of 4E-BP1 and eIF4E, thus lowering the activity of eIF4F (20). Because the vast majority of eukaryotic mRNAs are translated via the scanning mechanism, which requires the recognition of the 5'-end of the mRNA and its m-7G-cap by eIF4F (19), the dephosphorylation of 4E-BP1 and eIF4E is associated with a decreased translation efficiency of most mRNAs in amino acid-depleted cells (20). However, a selected pool of mRNAs, which encode either cell-defense proteins or proteins involved in apoptosis, are endowed with internal ribosome entry sites (IRES) and, thus, are efficiently translated via a cap-independent mechanism during amino acid starvation (21). This is the case for the mRNA that encodes the cationic amino acid transporter cat-1 (SLC7A1), which has an IRES in its 5'-UTR that mediates efficient translation of the cat-1 mRNA upon amino acid starvation (22). Interestingly, the preferential translation of cat-1 mRNA in amino acid-starved cells requires eIF2 phosphorylation (23). No information is yet available about the presence of IRES sequences in SNAT2 mRNA or the relationships between SNAT2 induction and eIF2 phosphorylation.

Amino acid starvation is not the sole stress that modifies SNAT2 transcription because the mRNA is also transiently induced by hypertonic treatment (24), leading to an enhanced expression of SNAT2 carriers (8). The resulting increase in the sodium-dependent transport of neutral amino acids is essential for the fast recovery of cell volume (25). The relationship between the response of system A activity to amino acid starvation and hypertonic stress has been widely debated and is not yet completely clarified (2, 26). Our previous results have demonstrated that amino acid starvation causes significant cell shrinkage and induces osmo-responsive genes, suggesting that this experimental condition is also associated with hypertonic stress (27). However, the transduction pathways involved in the response to amino acid starvation and hypertonic stress of system A transport activity appear to differ significantly (27–29).

In this study we report on the mechanism of SNAT2 induction during stress conditions. We demonstrate that eIF2 phosphorylation is required for the increase of SNAT2 expression and the maintenance of cell viability during amino acid starvation but not hypertonic stress. We also provide evidence that the 5'-UTR of the SNAT2 mRNA, which has the potential to form a stable secondary structure, contains an IRES that has similar activity in amino acid-fed and -depleted cells. Thus, the expression of the system A transporter SNAT2 during amino acid starvation is the result of both transcriptional activation and IRES-mediated translation, which allows the efficient production of new carriers under conditions where protein synthesis is inhibited.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Cells, Cell Culture, and Cell Viability—HeLa and C6 cells were cultured in high glucose Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum, 2 mM glutamine, 100 units/ml penicillin, and 100 µg/ml streptomycin. ATF4^–/–, eIF2-S/S (S/S), and eIF2-A/A (A/A) mouse embryonic fibroblasts were cultured in the same medium supplemented with both essential amino acid solution 50x, Sigma and nonessential amino acids (MEM nonessential amino acid solution 100x, Sigma). S/S and A/A cells, generous gifts from R. Kaufman (12), had been obtained from embryos expressing normal (S/S) or S51A (A/A) eIF2 at the homozygous state. The S51A mutation eliminates the phosphorylation site of eIF2.

Cells were starved for amino acids by culturing in Krebs-Ringer bicarbonate buffer with 10% dialyzed fetal bovine serum. Hypertonic treatment consisted of the incubation in high glucose Dulbecco's modified Eagle's medium (DMEM) supplemented with 100 mM sucrose for a final osmolality of 400 mosmol/kg (hypertonic DMEM).

Cell viability was assessed with resazurin (30). S/S and A/A cells were seeded in complete growth medium in 24-well plates at a density of 5 x 10⁴ cells/well and grown for 24 h before treatment. Growth medium was then substituted with Krebs-Ringer bicarbonate buffer, hypertonic DMEM, or complete medium with 1 mM dithiothreitol. After 24 h, the medium was replaced with fresh medium supplemented with 44 µM resazurin (Sigma) for 2 h, and fluorescence was measured as described.

Western Blot Analysis—Western blot analysis of eIF2 and phospho-eIF2 were carried out using a mouse monoclonal antibody (Quality Controlled Biochemicals, Inc.) and rabbit polyclonal antibody (BIOSOURCE), respectively. 4E-BP1 was detected using an anti-PHAS-1 peptide antibody (Zymed Laboratories Inc.), whereas anti-ATF4 antibody was from Santa Cruz Biotechnology Inc. -Tubulin antibody was from Sigma.

RNA Isolation and Analysis—SNAT2, asparagine synthase, and GAPDH mRNAs as well as 18 S ribosomal RNA were detected by Northern blotting using ³²P-labeled DNA hybridization probes as previously described (31). Total RNA was isolated by RNeasy Mini Kit (Qiagen) or CsCl centrifugation. One µg of total RNA was incubated with RNase-free DNase I (Promega) followed by Superscript III (Invitrogen) reverse transcriptase and gene-specific antisense primers (mSNAT1, 5'-GCTCCGAAGATCACCAGCTTCCCC-3'; mSNAT2, 5'-CACTTGAACCCAATTCCAACAG-3'; mSNAT4, 5'-CATTTCTCAGCACCCTGGGCTTCG-3'; GAPDH, 5'-TCATCATACTTGGCAGGTTTCTCC-3'; exogenous luciferase, 5'-GGGAGGTAGATGAGATGTGACG-3') at 55 °C for 1 h. The resulting cDNAs were amplified by PCR using Taq DNA polymerase. 5'-Forward primers were mSNAT1 (5'-GTGCCCGAAGATGACAACGTCAGC-3'), mSNAT2 (5'-GGTTCCTGAACTGAATTCTCAGCC-3'), mSNAT4 (5'-GCTCTGGATCACAACAACGGAAATCTGACG-3'), GAPDH (5'-ACTTTGGCATCGTGGAAGGG-3'), TET5 (5'-GAGACGCCATCCACGCTGTTTTGACC-3'), with the respective antisense primers described above. The TET5 primer was 10 nt downstream of the transcription start site and 60 nt upstream of the cloning site of the hairpin. Products were resolved by electrophoresis on 1% agarose gels and visualized by staining with ethidium bromide. The primers that were used for RT/PCR of bicistronic mRNAs have previously been described (32).

Real-time PCR was performed with iCycler (Bio-Rad). Primers for the endogenous mSNAT2 and GAPDH were the same as primers used in RT-PCR; exogenous m/SNAT2-2 and m/SNAT2-2in were 5'-GTCGACGTATTTGACTGAGAGAAACCCACTG-3' (sense) at the 5'-end of the SNAT2 5'-UTR and 5'-GGGAGGTAGATGAGATGTGACG-3' (antisense) annealing 77 nt downstream of the LUC ATG. Each gene was assayed in triplicate with Sybr Green (Applied Biosystems); PCR reactions (25 µl) contained 1.4 µl of 1:60-diluted cDNA. GAPDH expression levels were used to normalize gene expression in each sample.

Amino Acid Transport Analysis—Cells were seeded in 24-well trays (Falcon) at a density of 5 x 10⁴ cells/cm² for S/S and A/A cells and cultured for 2 days. The activity of transport system A was evaluated by measuring the uptake of [¹⁴C]methylaminoisobutyric acid (MeAIB, 0.1 mM, 2 µCi/ml) for 1 min at 37 °C in 0.25 ml of Krebs-Ringer bicarbonate buffer. The incubation was terminated with two rapid washes in 3 ml of ice-cold 300 mM urea. Ethanol extracts of cells were added to 0.6 ml of scintillation fluid (Hisafe, PerkinElmer Life Sciences) and counted for radioactivity in a Wallac Microbeta Trilux counter (PerkinElmer). Cell monolayers were then dissolved with 0.5% sodium deoxycholate in 1 N NaOH, and protein content was determined using a modified Lowry procedure (27).

Expression Vectors—The 5'-end of the SNAT2 mRNA was amplified by polymerase chain reaction using 5'-SalI (5'-AAAGTCGACCGACGCCGCCGCCTTAGAACGCCT-3') and 3'-NcoI (5'-TTTCCATGGTAAGCACTGGGAGGAATCGGGTGCAG or 5'-TTTCCATGGCGGCCTTCTTCATGCTAAGCACTGGGAG) primers. Because the SNAT2 mRNA has two in-frame potential initiation ATGs with the second being in better consensus flanking sequences, we isolated both cDNAs and named them SNAT2-1 and SNAT2-2. These cDNAs were cloned into the SalI/NcoI site of the pSVCAT/BiP/LUC plasmid by replacing the IRES from the BiP mRNA. The resulting vectors were named b/SNAT2-1 and b/SNAT2-2, respectively. The plasmids b/hpSNAT2-1 and b/hpSNAT2-2 were constructed by replacing the BiP IRES within the pSVhpCAT/BiP/LUC vector at the NcoI/SalI sites. The pSVCAT/ICS/LUC (b/ICS) vector contains 400 nt of irrelevant sequence and was used as a negative control for IRES-mediated translation. The b/SNAT2-2mut contained the same sequence as b/SNAT2-2, with the upstream open reading frame (uORF) ATG changed to TTG using the polymerase chain reaction-based mutagenesis.

The m/SNAT2-1 and m/SNAT2-2 expression vectors were generated by cloning the chimeric LUC cDNAs into the pUHD10–3 expression vector (33) cleaved at the XbaI site 3' to the promoter region and the EcoRI site 5' to the polyadenylation signal. This vector contains a minimal cytomegalovirus promoter and the SV40 polyadenylation signal. SNAT2-1 (342 bp) and SNAT2-2 (360 bp) cDNAs were amplified by the polymerase chain reaction using 5'-EcoRI (5'-AAAGAATTCCGACGCCGCCGCCTTAGAACGCCT) and 3'-NcoI (5'-TTTCCATGGCGGCCTTCTTCATGCTAAGCACTGGGAG-3' and 5'-TTTCCATGGTAAGCACTGGGAGGAATCGGGTGCAG-3', respectively) primers and were cloned into the EcoRI/NcoI site of the pUHD10–3/LUC vector. We obtained the m/hpSNAT2-1 and m/hpSNAT2-2 vectors by inserting a hairpin in the SacII site. The SacII site is 70 nt downstream of the transcription start site. The hairpin was generated by annealing phosphorylated primers 5'-GGAAGCTTATCGATTTCGAACCCGGGGTACCG and 5'-AATTCGGTACCCCGGGTTCGAAATCGATAAGCTTCCGC. The m/SNAT2-2in vector was obtained by PCR amplification using adult human liver genomic DNA. The GC-rich PCR System (Roche Applied Science) with 1 M resolution solution was used. The PCR primers were EcoRI (5'-AAAGAATTCCGACGCCGCCGCCTTAGAACGCCT-3') and NcoI (5'-TTTCCATGGCGGCCTTCTTCATGCTAAGCACTGGGAG-3'). The PCR product was ligated into the m/SNAT2-2 vector at the EcoRI/NcoI site by replacing the SNAT2 5'-UTR. The final vector was sequenced to confirm the presence of the intronic sequence.

The LUC-P98 expression vector was obtained from M. W. Hentze (34). Monocistronic and bicistronic DNA vectors for in vitro transcription were generated by introducing the appropriate fragments into the corresponding sites of Bluescript KS–(Stratagene) and ligating it to LUC P98, which was obtained from the LUC-P98 vector. The LUC-P98 vector contains 98 A residues cloned at the 3'-end of the LUC ORF and upstream of a NotI site that was used to linearize the plasmids and generate RNA transcripts.

Cell Transfections and Analytical Procedures—Cells were seeded in 6-well plates (Falcon) at a density of 20 x 10⁴ cells/plate for HeLa, 50 x 10⁴ cells/plate for mouse embryonic fibroblast cells (MEFs), and 100 x 10⁴ cells/plate for C6 cells. The following day cells were transfected with 500 ng/well of bicistronic vectors or cotransfected with 100 ng/well each of monocistronic vectors and -galactosidase expression vector. Cells were subjected to treatment and/or collected for enzymatic assays 48 h after transfection. LUC, chloramphenicol acetyltransferase (CAT), and -galactosidase activities were measured as described previously (22). The activities were normalized to the protein content of the cell extracts, which was measured using the Bio-Rad D_C assay.

Cell-free Translation Assays—DNAs were linearized by digesting with NotI, and capped RNAs were synthesized using the mMessage mMachine T3 kit (Ambion). The purity and integrity of the RNA molecules was checked on urea-polyacrylamide gels. In vitro translations were performed using the Promega nuclease-treated rabbit reticulocyte lysate (RRL) cell-free system, and the LUC and CAT enzymatic activities were determined. HeLa (S3) cell extracts were prepared as previously described (34). HeLa cell extracts were treated with 0.01 unit of micrococcal nuclease for 6 min just before the translation reactions. EGTA was added to a final concentration of 2 mM, and after a brief centrifugation at 14,000 x g, the supernatant was used immediately for in vitro translation. Each in vitro translation reaction contained 6–8 µg/µl extract, and the reaction was as previously described (34). Translation reactions in the presence of [³⁵S]Met (15 mCi/ml) and analysis of the products on SDS-PAGE gels were as described previously (35).

View larger version (55K): [in this window] [in a new window]   FIGURE 1. Analysis of SNAT2 mRNA levels in S/S, A/A, AT4–/–, and HeLa cells during amino acid starvation and hypertonic stress. S/S, A/A, ATF4–/– MEF, and HeLa cells were maintained in culture medium until they were 70% confluent. Cells were changed to either amino acid depleted (A and B) or hypertonic (C) media and incubated for the indicated times. RNA was isolated and analyzed by Northern blotting using hybridization probes for SNAT2, AS, GAPDH, and 18 S ribosomal RNA.

	RESULTS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

SNAT2 synthesis is also induced during hypertonic stress to promote recovery of cell volume by increasing the sodium-dependent transport of neutral amino acids (8, 24). In contrast to what was observed for amino acid starvation, hypertonic stress caused a comparable induction of SNAT2 mRNA levels in S/S and A/A cells (Fig. 1C), suggesting that eIF2 phosphorylation is not required for this regulation. Hypertonic stress had no effect on AS mRNA levels (Fig. 1C). As a control for the two stress conditions, we tested induction of SNAT2 mRNA levels in HeLa cells, which showed the expected induction by both amino acid starvation and hypertonic stress (Fig. 1, A and C).

View larger version (37K): [in this window] [in a new window]   FIGURE 2. eIF2 phosphorylation contributes to induction of system A transport activity during amino acid starvation but not during hypertonic stress. A–B, 1-min influx of MeAIB (0.1 mM, 2 µCi/ml) was measured after cells had been incubated for the indicated times in either amino acid (aa)-depleted (A) or hypertonic medium (B). Points are the means ± S.D. of three independent determinations. C, Western blot analysis of total cell extracts (15µg of protein) from S/S and A/A cells incubated in control or hypertonic medium for the times indicated using antibodies for eIF2, phospho-eIF2, 4E-BP1, ATF4, and tubulin. The ratio eIF2-P/eIF2 is indicated. D, S/S and A/A cells were incubated for 24 h in control medium (C), amino acid-depleted medium (St), hypertonic medium (Hy) and in control medium supplemented with 1 mM dithiothreitol (ER). After treatment, cell viability was evaluated using resazurin. The bars represent the average ± S.D. of three independent experiments. **, p 0.001.

To understand the reasons for the differences in system A amino acid transport upon hypertonic and starvation stresses, we tested if hypertonic stress induces eIF2 phosphorylation in MEF cells. The results (Fig. 2C) indicate that, as expected, amino acid starvation caused an increase in eIF2 phosphorylation and promoted the expression of the eIF2 target, ATF4, in S/S but not in A/A cells. In contrast, hypertonic stress did not increase eIF2 phosphorylation in S/S cells. These data are, therefore, consistent with the conclusion that eIF2 phosphorylation is not required for the induction of SNAT2 mRNA by this stress. We also examined the phosphorylation of 4E-BP1 by the amino acid-sensitive mammalian target of rapamycin (mTOR) kinase, a mechanism which inhibits the binding of this protein to eIF4E, thereby stimulating translation (37). Amino acid starvation caused the increase of under-phosphorylated forms of 4E-BP1 only in S/S cells (note the transient increase in the lower under-phosphorylated bands). On the contrary, A/A cells depleted of amino acids did not show a dephosphorylation of 4E-BP1, suggesting a potential link of eIF2 phosphorylation and the mTOR pathway. A similar observation was previously reported in yeast (38). Hypertonic treatment caused a transient decrease in 4E-BP1 phosphorylation in both S/S and A/A cells, indicating that osmotic stress decreased mTOR activity (Fig. 2C), as described previously (39).

To further test the role of eIF2 phosphorylation in the response to different stress conditions, we tested the viability of S/S and A/A cells subjected to hypertonic stress, amino acid depletion, or endoplasmic reticulum (ER) stress. ER stress was induced by incubation with dithiothreitol, which also promotes eIF2 phosphorylation (40). The viability of S/S cells was not affected by any of these treatments, whereas only 50% of the A/A cells survived amino acid starvation or ER stress (Fig. 2D), indicating the importance of eIF2 phosphorylation in the response to both stresses. In contrast, the viability of A/A cells was not affected by hypertonic stress, consistent with our finding that eIF2 is not involved in the cellular response to this condition.

View larger version (43K): [in this window] [in a new window]   FIGURE 3. Expression of SNAT isoforms in S/S and A/A cells during amino acid starvation or hypertonic stress. A, diagram of primers used to amplify the mouse SNAT isoforms; expected fragment sizes are indicated. B, S/S and A/A cells were incubated in amino acid-depleted or hypertonic medium for the indicated times. Total mRNA (1 µg) was subjected to RT-PCR analysis with the corresponding SNAT primers. The concentration of GAPDH mRNA was determined using GAPDH-specific primers.

The SNAT2 5'-UTR Contains an Internal Ribosome Entry Site—The human SNAT2 5'-UTR has two in-frame ATGs separated by 15 nt that could be used as initiator codons. Use of these two codons will result in mRNAs with 5'-UTRs of 342 and 357 nt. These will be referred to as SNAT2-1 and SNAT2-2, respectively, in the studies that follow. Folding the 5'-UTR RNA using the Mfold program (42) predicts a very stable structure (G =–90 kcal/mol), suggesting that cap-dependent translation via the scanning mechanism will be inefficient. We, therefore, hypothesized that the SNAT2 5'-UTR may contain an IRES that can be used efficiently under conditions of amino acid starvation.

To test this hypothesis we constructed expression vectors that express monocistronic chimeric mRNAs containing the SNAT2 5'-UTR and a LUC reporter from a cytomegalovirus minimal promoter (Fig. 4A, m/SNAT2-1 and m/SNAT2-2). To distinguish between scanning-dependent and -independent translation initiation, constructs were generated with a stable RNA hairpin upstream of the SNAT2 UTRs (Fig. 4A, m/hpSNAT2-1 and m/hpSNAT2-2). These vectors were transfected into cells derived from three species: HeLa (human), wild type MEF S/S (mouse), and C6 (rat). LUC activity was expressed from the constructs containing the SNAT2 UTR in all three cell lines (Fig. 4B). Moreover, the presence of the RNA hairpin upstream of the LUC open reading frame did not affect expression, suggesting that these RNAs are translated via an IRES. To support this conclusion, we analyzed constructs that contained a UTR of 100 nt of irrelevant sequence from the vector between the cytomegalovirus transcription start site and the cloning site (Fig. 4A, m/CON and m/hpCON). In this case, LUC expression was largely inhibited by the hairpin (Fig. 4B), which is the expected result for cap-dependent translation initiation.

Although these results strongly suggest that the SNAT2 5'-UTR contains an IRES element, there are alternative explanations. To rule out the possibility that a cryptic promoter within the UTR allows the expression of an mRNA that does not contain the hairpin, we tested LUC expression from derivatives of the m/SNAT2-1 and m/SNAT2-2 vectors that had deletions of the promoter. In all three cell lines there was little expression from constructs with the deleted promoters (Fig. 4C), demonstrating that the SNAT2 5'-UTR does not contain a cryptic promoter. To rule out the possibility that there is unexpected splicing or differences in stability that account for the observed LUC expression in Fig. 4B, the integrity of mRNAs from m/SNAT2-2 and m/hpSNAT2-2 was tested in stably transfected wild-type MEF cells. Northern blot analysis shows that the mRNAs from the two vectors have similar sizes (Fig. 4D). LUC activities in these cells were 25 units/µg of protein (for m/hpSNAT2-2) and 55 units/µg of protein (for m/SNAT2-2), which is in agreement with the 2-fold difference in mRNA levels (Fig. 4D, lanes 2 and 3). The integrity of the constructs was confirmed by RT/PCR using primers within the 5'-end of the RNA transcript and the LUC cistron (Fig. 4E, lanes 3 and 4). We next determined if the RNA that is generated from the m/hpSNAT2-2 vector contains the hairpin. To determine this, we digested the cDNAs amplified from m/SNAT2-2- and m/hpSNAT2-2-expressing cells (Fig. 4E, lanes 3 and 4) with KpnI, which cleaves the cDNA within the hairpin. It is shown that only the cDNA from m/hpSNAT2-2 was cleaved by KpnI, producing two fragments of the expected sizes (Fig. 4E, compare lanes 7 and 8). These findings rule out alternative explanations for the similar LUC activity expressed from SNAT2 constructs with or without hairpin and support the existence of an IRES in the SNAT2 5'-UTR.

View larger version (32K): [in this window] [in a new window]   FIGURE 4. The SNAT2 5'-UTR contains an IRES. A, monocistronic constructs used in this study. hp refers to the hairpin present upstream of the 5'-UTRs. B–C, HeLa, S/S and C6 cells were independently transfected with the indicated constructs along with a -galactosidase expression vector. LUC and -galactosidase activities were measured in cell extracts 48 h after transfection. The bars represent the average ± S.D. of three independent experiments. D, Northern blot analysis of total RNA (10 µg) from S/S cells that were stably transfected with the indicated constructs using a LUC hybridization probe. E, RT-PCR analysis using RNA from S/S cells stably transfected with m/SNAT2-2 or m/hpSNAT2-2 using TET5 (forward) and LUC (reverse) primers. TET5 lies 5' of the hairpin. In lanes 6 and 8 the PCR products were digested with KpnI, which cleaves the DNA within the sequence of the hairpin. RT (-) indicates PCR amplification of RNA in the absence of RT. This shows that amplification occurred from the RNA and not from contaminating plasmid DNA. M, mass markers; Kb, kilobases.

View larger version (28K): [in this window] [in a new window]   FIGURE 5. The SNAT2 5'-UTR functions as an IRES in a bicistronic vector. A, bicistronic constructs used in this study. b/BiP has the BiP 5'-UTR inserted between the CAT and LUC cistrons and is used as a positive control. b/ICS has an irrelevant sequence between the CAT and LUC cistrons and is used as a negative control. The hairpin (hp) inserted upstream of the CAT cistron is the same sequence that was used in the monocistronic vectors (Fig. 4). B–E, HeLa (B and E), S/S (C), and C6 (D) cells were independently transfected with the indicated vectors. LUC and CAT activities were measured 48 h after transfection. The data are presented as the LUC and CAT activities and as the LUC/CAT ratio. The bars represent the average ± S.D. of three independent experiments. F, RT-PCR analysis performed on RNA extracted from HeLa cells transfected with b/SNAT2-1 or b/SNAT2-2 using primers spanning a portion of the LUC and CAT cistrons (32). Note that the transcripts are of the correct molecular mass. No smaller PCR fragments were observed, indicating that no aberrant splicing occurred. RT (-), an RT-PCR amplification of RNA without reverse transcriptase in the RT reaction.

View larger version (15K): [in this window] [in a new window]   FIGURE 6. The SNAT2 5'-UTR supports translation initiation during amino acid starvation. S/S cells were independently transfected with pGL3/AS (AS), m/CON, m/SNAT2-2, m/hpSNAT2-2, and m/SNAT2-2in vectors. A -galactosidase-expressing vector was cotransfected with all constructs. After transfection (48 h) cells were incubated in amino acid-fed or -depleted media for the indicated times, and cell lysates were used to measure LUC and-galactosidase activities. The data are presented as the LUC/-galactosidase ratio, and the bars represent the average ± S.D. of three independent experiments, **, p 0.001.

View larger version (26K): [in this window] [in a new window]   FIGURE 7. The SNAT2 UTR inhibits cap-dependent translation in cell-free systems. A, capped monocistronic and bicistronic RNAs used for in vitro translation with RRL and HeLa extracts. The capped m/CAT/PA36 RNA, which contains the CAT coding sequence, was used as a control for translation efficiency (not shown). B, different amounts of m/SNAT2-1/PA98 were translated in vitro using RRL and the LUC enzymatic activities were determined. C, the indicated capped monocistronic RNAs were cotranslated in vitro with m/CAT/PA36 RNA using RRL or HeLa extracts as described under "Experimental Procedures." LUC, CAT, and LUC/CAT activities are indicated. The bars represent the average ± S.D. of three independent experiments.

View larger version (25K): [in this window] [in a new window]   FIGURE 8. The SNAT2 5'-UTR functions as an IRES in a cell-free system. A and B, the indicated capped bicistronic RNAs (10 ng/µl) were translated in vitro using RRL (A and B) or HeLa extracts (A). LUC and CAT activities were measured, and the data are presented as the LUC/CAT ratio. Bars represent the average ± S.D. of three independent experiments. C, the indicated RNAs were translated in RRL in the presence of [35S]Met, and labeled products were analyzed on an SDS-PAGE gel. The positions of the LUC and CAT proteins are shown.

To determine whether the SNAT2 UTR can function as an IRES in a cell-free system, we translated bicistronic SNAT2 RNAs in RRL and HeLa extracts. The LUC activities (Fig. 8A) demonstrated that both SNAT2 UTRs function as IRESs in a cell-free system. Moreover, the 5' half of the SNAT2 UTR is important in IRES activity because truncations of this region caused a 50% reduction in LUC activity (Fig. 8B). However, the construct that contains residues –50 to +16 retained IRES activity, suggesting that this sequence may be able to recruit ribosomes.

As a final test of the relative translation efficiencies of monocistronic and bicistronic mRNAs containing the SNAT2 UTR, we measured incorporation of [³⁵S]Met in the LUC and CAT proteins in RRL (Fig. 8C). LUC protein levels were higher with the m/CON than the m/SNAT2 mRNAs (Fig. 8C), in agreement with the results in Fig. 7C. Interestingly, LUC was translated from the monocistronic and bicistronic mRNAs at similar levels (Fig. 8C). These data confirm the conclusion that the SNAT2 UTR functions as an IRES during in vitro translation.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Marked stimulation of system A transport activity is observed upon either amino acid starvation or hypertonic stress. Because cell shrinkage occurs under both stress conditions, system A stimulation may be viewed as an adaptive response aimed at restoring cell volume. However, although the biochemical characteristics of system A transport have been extensively studied in a variety of cell types, the molecular mechanisms underlying transport stimulation have not been fully characterized. It was previously shown that the induction of system A amino acid transport by both stresses is associated to the increased abundance of SNAT2 mRNA, the system A transporter encoded by the SLC38A2 gene (4, 9). The increased abundance of SNAT2 mRNA would lead to the enhanced synthesis of SNAT2 carriers, the amount of which has been found markedly augmented on the plasma membrane of starved cells (5, 8). It was also found that an enhancer element in the first intron of the gene (9) causes transcriptional activation during amino acid starvation. This suggests that expression of the SNAT2 gene is also regulated at the level of transcription during this stress.

In this study we have extended our understanding of the regulation of SNAT2 expression by cellular stress with the following novel findings. (i) The induction of the SNAT2 mRNA and system A amino acid transport by amino acid starvation involves signaling via the phosphorylation of eIF2, which is the master regulator of this stress response (13, 16). In contrast, the induction of SNAT2 mRNA levels by hypertonic stress does not involve eIF2 phosphorylation. (ii) Translation of the SNAT2 mRNA is mediated via an IRES that is located within the 5'-UTR of the SNAT2 mRNA. (iii) The SNAT2 IRES is constitutively active in fed and fasted cells. Therefore, the IRES supports translation of the SNAT2 mRNA during fasted conditions when cap-dependent translation decreases. (iv) The SNAT2 IRES can function in a cell-free system, and maximum activity requires sequences at the 5'-end of the leader. As a consequence, the increased expression of SNAT2 protein, observed in amino acid-starved cells (5, 8), should be considered the result of both the transcriptional activation of SLC38A2 and the cap-independent translation of the mRNA, allowed by the IRES in the 5'-UTR.

The signaling pathway induced by eIF2 phosphorylation is essential for cell survival during amino acid deprivation (Fig. 2) as well as in other stress conditions (13). Interestingly, hypertonic stress did not induce eIF2 phosphorylation, and cell survival was independent of eIF2 phosphorylation under this condition. The differential response to the two stresses may indicate that eIF2 phosphorylation is associated with conditions that lead to cell death rapidly. On the other hand, hypertonic stress activates signaling pathways that, through the inhibition of mTOR, transiently adjust protein synthesis rates until recovery occurs. Our data are consistent with the idea that two distinct signaling pathways promote system A up-regulation upon osmotic cell shrinkage and amino acid limitation and that maximal stimulation is achieved when both pathways are activated. This hypothesis may explain the 5-fold increase in SNAT2 mRNA levels in amino acid-depleted cells (associated with both nutritional and osmotic stress) and the 3-fold increase caused by hypertonicity alone (associated with osmotic stress only).

In this regard, regulation of SNAT2 mRNA levels by amino acid starvation is clearly different from regulation of expression of other amino acid sensitive genes. Increased levels of mRNAs encoding AS, CHOP (C/EBP homologous protein), and cat-1 are induced by limitation of any single essential amino acid (44, 46), which stimulates eIF2 phosphorylation (47). Therefore, transcription of these three genes can be stimulated by the eIF2 phosphorylation signaling pathway. In contrast, SNAT2 mRNA levels are not increased by amino acid limitation if any of its substrate amino acids are present at high concentrations (4). This is consistent with the complex regulation of SNAT2 gene expression observed in our study; eIF2 phosphorylation is only partially required for SNAT2 mRNA accumulation during amino acid starvation and is not required during hypertonic stress. On the contrary, AS induction is completely suppressed in the absence of eIF2 phosphorylation. This is consistent with the observation that AS and SNAT2 transcription also exhibit different dependence on ATF4, whose expression is increased by eIF2 phosphorylation. Indeed, although ATF4–/– cells are not competent for AS induction upon amino acid starvation, they still exhibit a significant stimulation of SNAT2 expression under the same conditions (Fig. 1B).

We have previously shown that amino acid starvation induces SNAT2 mRNA levels via a mechanism that involves activation of the extracellular signal-regulated protein kinase (ERK) 1/2 pathway (48). It is possible that ERK 1/2 activation causes a post-translational modification of a transcription factor. In fact, C/EBP is a substrate of ERK 1/2 and is activated by this phosphorylation (49). Given the partial dependence of SNAT2 induction on eIF2 phosphorylation, these data suggest that there might be cross-talk between eIF2 phosphorylation and the ERK 1/2 signaling. eIF2 phosphorylation causes increased expression of several transcription factors, including ATF4 and C/EBP (15, 17, 18), which in turn increases transcription of target genes (16). It is, therefore, possible that eIF2 phosphorylation induces expression of transcription factors that are further activated when they are phosphorylated by ERK 1/2. Moreover, induction of other transcription factors has been described under both stress conditions, such as TonEBP/NFAT5 (27, 50). Future studies will determine the role of cross-talk between these signaling pathways in activation of SNAT2 gene transcription.

It is shown here that the SNAT2 mRNA is translated via an IRES element in the 5'-UTR. Amino acid starvation causes a decrease in cap-dependent translation initiation, which affects the translation of most mRNAs (51). However, translation initiation of mRNAs that contain IRESs occurs independently of the 5'-cap. Prediction of the structure of the SNAT2 mRNA 5'-UTR (42) suggests that it forms a very stable RNA structure that would inhibit cap-dependent translation initiation. In agreement with this prediction, we show that mRNAs with the human SNAT2 UTR were translated much less efficiently than the control mRNA in vitro (Fig. 7). We found that the SNAT2 5'-UTR contains an IRES that supports cap-independent translation initiation both in cultured cells and in cell-free systems. This conclusion is based on the finding that similar levels of expression were observed from the m/SNAT2-2, m/hpSNAT2-2, and b/SNAT2-2 constructs (Fig. 4D). The LUC activities were very similar when they were normalized to the mRNA levels (data not shown). Interestingly, translation mediated by this IRES is nearly as efficient as cap-dependent translation from control mRNAs (Fig. 4B), suggesting that the SNAT2 IRES competes well with the cellular mRNAs.

The activity of the SNAT2 IRES did not increase during amino acid starvation, suggesting that it is not regulated by this condition. The BiP mRNA also contains a constitutive IRES (22). For both genes cellular stress increases mRNA expression, and the IRES allows mRNA translation and protein expression when cap-dependent translation initiation is inhibited. In contrast, the activity of other cellular IRESs is regulated, whereas viral IRESs are constitutive (for review, see Ref. 21). The fact that the SNAT2 IRES is active in both normal and stressed conditions emphasizes the importance in this protein for normal metabolism and survival during stress.

This study did not determine the RNA structure in the 5'-UTR that forms the SNAT2 IRES. However, in vitro translation of deletion mutants demonstrated that the 5'-end of the UTR is an important component of the IRES (Fig. 8). We also do not know the protein factors required for initiation from the SNAT2 IRES. Our current knowledge of IRES structure and function suggests that internal ribosome binding involves factors required for cap-dependent translation and novel proteins (21). All these factors work together to form an RNA structure that recruits the initiation codon of the mRNA to the P site of the ribosome (19). A mammalian mRNA that uses the prokaryotic-type mode of ribosome recruitment has also been described (52). The Gtx homeodomain mRNA contains a 9-nucleotide element that is believed to facilitate translation initiation by base pairing with the 18 S ribosomal RNA. The 5'-end of the SNAT2 UTR contributes to its activity, suggesting that recruitment of the ribosome could require a structural component.

Although the induction of system A and SNAT2 in response to various stress conditions has been discussed in several reviews (1, 2, 26, 44), the physiological significance of this regulation is not yet fully understood. The results presented here suggest that the increase in system A activity is an integral part of the cell adaptation to amino acid starvation. This stress condition, encountered in severe ischemia as well as upon disruption of placental function, elicits complex adaptation mechanisms that also involve autophagy and proteasomal activity (53, 54). Interestingly, low system A activity was associated with reduced fetal growth when placental function is insufficient (55). Therefore, the dissection of the molecular mechanisms involved in the adaptation to nutritional stress may constitute an important step for the understanding of conditions in which these responses are dysregulated.

	FOOTNOTES

 
^* This work was supported by National Institutes of Health Grants RO1-DK60596 and RO1-DK53307 (to M. H.) and by Local Interest Fund-University of Parma (to R. F.-G.) and O. B. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ To whom correspondence should be addressed: Dept. of Nutrition, Case Western Reserve University, 10900 Euclid Ave., Cleveland, OH 44106-4906. Tel.: 216-368-3012; Fax: 216-368-6644; E-mail: mxh8{at}po.cwru.edu.

² The abbreviations used are: eIF, eukaryotic initiation factor; ATF4, activating transcription factor 4; AS, asparagine synthetase; IRES, internal ribosome entry site; LUC, luciferase; MeAIB, 2-methylaminoisobutyric acid; MEF, mouse embryonic fibroblasts; C/EBP, CCAAT/enhancer-binding protein ; RT, reverse transcriptase; UTR, untranslated region; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; uORF, upstream open reading frame; RRL, rabbit reticulocyte lysate; ER, endoplasmic reticulum; nt, nucleotides; CAT, chloramphenicol acetyltransferase.

	ACKNOWLEDGMENTS

 
We thank Drs. R. Kaufman for the S/S and A/A cells, R. Wek for ATF4–/– cells, and P. Sarnow for the pSVCAT/BIP/LUC and pSVCAT/ICS/LUC vectors. We also thank Haiyan Liu and Dr. Ibrahim Yaman for assisting with the experiments.

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