Translational activation and repression by distinct elements within the 5'-UTR of ENaC alpha -subunit mRNA

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Translational activation and repression by distinct elements within the 5'-UTR of ENaC $alpha$ -subunit mRNA

Gail Otulakowski¹^,², Tanya Freywald², Yanxia Wen², and Hugh O'Brodovich¹^,²^,³

² Canadian Institutes of Health Research Group in Lung Development, Research Institute, Hospital for Sick Children, and Departments of ¹ Paediatrics and ³ Physiology, University of Toronto, Ontario M5G 1X8, Canada

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The rat amiloride-sensitive epithelial Na⁺ channel (rENaC), the rate-limiting step in epithelial Na⁺ transport, consists of three subunits, $alpha$ , $beta$ , and $gamma$ . We hypothesizedthat $alpha$ -rENaC translation is regulated via its 5'-untranslatedregion (UTR). Transient transfections of $alpha$ -rENaC promoter-reporterconstructs in representative epithelial cell lines demonstratedup to fivefold differences in activity among constructs containingdifferent amounts of the $alpha$ -rENaC 5'-UTR sequence. Differencesin reporter protein activity did not parallel differences in reportermRNA, demonstrating that 5'-UTR regulation must be at the levelof translation. Specifically, translation was enhanced by a regionextending from +53 to +211 bp downstream from the transcriptionstart site and repressed by the region between +367 and +499 bp.Examination of the 5'-UTR sequence revealed an out-of-frame initiationcodon within the repressive region, 43 bp upstream from the startof the $alpha$ -rENaC open reading frame. Mutational analysis of thisupstream start codon indicated that it plays, at most, a minorrole in impeding translation both in vitro and in vivo, suggestingthat additional mechanisms of translational regulation areoperative.

rat epithelial sodium channel; 5'-untranslated region; lung fluid; ion transport; translational regulation

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

THE AMILORIDE-SENSITIVE EPITHELIAL Na⁺ channel (ENaC) (reviewed in Refs. 12, 26, 53) is expressed in the apical membraneof salt-absorbing epithelia found in the kidney, colon, and lungwhere it constitutes the rate-limiting step in active Na⁺ and fluid absorption. It thus plays a major role in the regulationof salt homeostasis and blood pressure as indicated by the existenceof genetic hypertensive and hypotensive diseases associated withENaC gene mutations, such as Liddle's syndrome (45) and pseudohypoaldosteronismtype 1 (5). In the lung, ENaC is important in controlling theamount of liquid in the lung airspace. Targeted "knockout" ofthe gene for the $alpha$ -subunit of ENaC in mice gave rise to newbornsthat suffered respiratory distress, were unable to clear theirfetal lung liquid, and died within 2 days of birth despite havingmorphologically normal lungs (17).

ENaC, which consists of three homologous subunits, $alpha$ , $beta$ and $gamma$ , is part of a novel cation channel superfamily (12). ENaCsubunits have been cloned from many species including human andrat. In heterologous expression systems (Xenopus oocytes), amiloride-sensitiveNa⁺ currents can be measured in oocytes injected with rat $alpha$ -ENaC( $alpha$ -rENaC) mRNA; coexpression of all three subunits is requiredfor maximal activity (3). In the oocyte expression system,both a heterotetrameric structure containing two $alpha$ -, one $beta$ -, andone $gamma$ -subunit (11, 23) and a nonameric structure containingthree copies of each subunit (9, 47) have been proposed.Regardless of which model represents the correct protein subunitstoichiometry, no more than a twofold excess of the $alpha$ - over $beta$ -and $gamma$ -subunits is predicted. However, our laboratory has foundthat $alpha$ -ENaC mRNA is expressed at markedly greater levels than $beta$ - and $gamma$ -subunit mRNAs in respiratory tract epithelia; we observedmRNA ratios of 20:4:1 in human (31) and 50:1:5 in mouse (19)nasal turbinate by quantitative competitive reverse transcription-polymerasechain reaction (RT-PCR). This agrees with relative estimates byNorthern analysis and in situ hybridization (2, 10, 27,50) and suggests that $alpha$ -ENaC mRNA, under normal conditions,may be less efficiently translated than $beta$ - and $gamma$ -subunit mRNAs. $alpha$ -ENaC has been shown to be capable of expressing functional channelsin the absence of the $beta$ - and $gamma$ -subunits when this subunit is artificiallyexpressed alone (4, 21); however, the heteromultimer appearsto be the preferred form of assembly, unaltered even by injectionof a 100-fold excess quantity of message encoding a single subunit(11). Thus it is unlikely that formation of homomultimeric channelsaccounts for the excess $alpha$ -ENaC mRNAexpression.

Several observations suggest a possible role for the 5'-untranslated region (UTR) in the translational regulation of $alpha$ -ENaC.First, Smith et al. (46) have recently demonstrated that $alpha$ -ENaCmRNA expression is detectable during the earliest stages of fetallung development, at a time when the lung is a secretory and notan absorptive organ. Second, it has been shown that multiple $alpha$ -ENaCmRNAs differing in the 5'-UTR are expressed in human tissue (51).Both human and rat $alpha$ -ENaC 5'-UTRs are unusually long [up to 750nucleotides (nt); most 5'-UTRs are 50-100 nt] and contain GC-richregions, indicating a potential secondary structure (30). Finally,a study by Otulakowski et al. (30) revealed a decrease in reportergene activity in transfected A549 cells when $alpha$ -rENaC promoterconstructs were extended to include an additional 133 bp of the5'-UTR. These observations suggest the presence of a negativeregulatory element. Due to its location, such an element couldbe functionally active during either transcription or translation.Structural features in mRNA 5'-UTRs that may influence translationalefficiency are secondary structure, occurrence of upstream AUGstart codons, structural motifs recognized by specific bindingproteins, and internal ribosome entry sites (6, 16, 24,25, 32, 37, 49).

To study the translational regulation of $alpha$ -rENaC, we developed a quantitative competitive RT-PCR assay to assess reportermRNA levels in transiently transfected cells and examined theeffect of different regions of 5'-UTR on reporter gene mRNA andprotein expression. Mutational analysis was used to investigatethe potential influence of an upstream, out-of-frame initiationcodon in the $alpha$ -rENaC 5'-UTR.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Promoter-reporter constructs. Cloned genomic DNA fragments containing portions of the putative $alpha$ -rENaC promoter were inserted upstream of the secreted alkalinephosphatase (SEAP) gene in the promoterless expression vectorpSEAP2-basic (Clontech, Palo Alto, CA). A combination of naturallyoccurring restriction sites and fragments generated by exonucleasedigestion was used to assemble the reporter constructs. The sequenceATG at +473-475 bp was mutated to TTG by sequential PCR steps.The resulting PCR fragment was cloned into pBluescript II KS( $-$ );the sequence was confirmed and then substituted for the wild-typesequence in the "dSEAP2" construct series to generate the "dmOSEAP2"constructs.

Cell culture. Madin-Darby canine kidney (MDCK) epithelial cells were maintained in Dulbecco's modified Eagle's medium (DMEM) with 10% fetalbovine serum (FBS). Mouse kidney cortical collecting duct epithelialcells (M1) were maintained in DMEM plus Ham's F-12 medium (1:1)with 5% FBS and 5 µM dexamethasone. Human lung epithelial cells(NCI-H441) were maintained in RPMI 1640 medium with 10% FBS. Mousedistal lung epithelial cells (MLE-15) were maintained in HITESmedium with 2% FBS. HITES medium consisted of RPMI 1640 mediumsupplemented with 5 µg/ml of insulin, 10 µg/ml of transferrin,30 nM sodium selenite, 10 nM hydrocortisone, 10 nM $beta$ -estradiol,10 mM HEPES, and 2 mM L-glutamine. MLE-15 cells were a gift fromDr. J. Whitsett (Children's Hospital Medical Center, Cincinnati,OH); all other cell lines were obtained from the American TypeCulture Collection (Manassas, VA). All lines were maintained inthe presence of 100 U/ml of penicillin G and 100 µg/ml of streptomycinsulfate.

DNA sequencing. Manual sequencing was carried out with the Pharmacia T7 sequencing kit (Amersham Pharmacia Biotech, Baie d'Urfé, PQ) and³⁵S-dATP. Automated sequencing reactions were performed with a ThermoSequenase fluorescent-labeled primer cycle sequencing kit with7-deaza-dGTP (Amersham) and analyzed on a LICOR DNA sequencermodel 4000L equipped with Base ImagIR software (LI-COR, Lincoln,NE).

Transfections. Cells were plated in six-well tissue culture dishes at 2.5 × 10⁵ cells/well for MDCK cells, 4 × 10⁵ cells/well for M1 cells, and 8 × 10⁵ cells/well for MLE-15 and H441 cells 18 h before transfection.Cells were cotransfected with pSEAP2 constructs and a Rous sarcomavirus (RSV)-driven $beta$ -galactosidase ( $beta$ gal)-expressing plasmid (RSV $beta$ gal)as an internal control for transfection efficiency. Transfectionswere carried out with LipofectAMINE reagent or LipofectAMINE Plusfor H441 cells (Life Technologies) according to the manufacturer'srecommendations. Medium was collected 48 h posttransfection foranalysis of SEAP activity with a Phospha-Light chemiluminescencekit (PerkinElmer Applied Biosystems Division, Mississauga, ON). $beta$ -Galactosidase activity was determined via a colorimetric assaywith o-nitrophenyl- $alpha$ -D-galactopyranoside as described previously(13) on cell extracts prepared by lysis of cultured cells in1% Triton X-100-0.25 M Tris · HCl, pH 7.8.

Quantitative RT-PCR. A competitive internal control, RSV $Delta$ SEAP, for quantitative RT (QRT)-PCR in transiently transfected cells was created by deletinga 218-bp NarI fragment from the SEAP coding region of an RSV promoter-drivenpSEAP construct. ENaC promoter-driven SEAP2 constructs were cotransfectedwith RSV $Delta$ SEAP at a ratio of 100:1 as described in Transfections.All transfections were carried out in triplicate. Forty-eighthours posttransfection, the cells were harvested by direct additionof lysis buffer (RLT buffer, QIAGEN, Santa Clarita, CA), and totalRNA was purified with the RNeasy Mini Kit (QIAGEN). The resultingRNA was treated with RNase-free DNase and again purified on anRNeasy column. RNA was quantitated by ultravioletspectrophotometry.

The primers for QRT-PCR were 5'-TTGAGCCTGGAGACATGAAATAC-3' for SEAP1 and 5'-TAACCCGGGTGCGCGGCGTCGGT-3' for SEAP2. SEAP1 andSEAP2 flank the deletion site in RSV $Delta$ SEAP such that ENaC promoter-drivenSEAP constructs give rise to a 663-bp product and RSV $Delta$ SEAP givesrise to a 446-bp product. Two-step QRT-PCR was carried out with1 µg of RNA from transfected cells. Each RT reaction contained1× first-strand synthesis buffer (Life Technologies), 10 mM dithiothreitol,0.5 mM deoxynucleotide triphosphates, 1 U/µl of RNAguard (PharmaciaBiotech), 0.25 µM primer SEAP2, and 50 U of SuperScript II reversetranscriptase (Life Technologies) in a final volume of 20 µl.RT was carried out for 45 min at 50°C. PCRs contained 1× Thermopolreaction buffer (New England Biolabs, Mississauga, ON), 0.1 mMdeoxynucleotide triphosphates, 0.1 µM primers SEAP1 and SEAP2,5 µl of RT reaction products, 5% (vol/vol) DMSO, and 0.5 U ofVent(exo-) polymerase (New England Biolabs). Amplification wascarried out for 31 cycles consisting of 30 s at 94°C, 30 s at55°C, and 1 min at 72°C in a PerkinElmer 9600 thermocycler. PCRproducts were analyzed by electrophoresis on an 8% nondenaturingpolyacrylamide gel followed by ethidium bromide (5 µg/ml) staining.Intensity of the fluorescent bands was quantitated with the NIHImage program (developed at the National Institutes of Healthand available on the Internet at http://rsb.info.nih.gov/nih-image/).

In vitro transcription and translation. Templates for in vitro transcription were constructed in pBluescript II KS( $-$ ). Template $alpha$ L contains the $alpha$ -rENaC cDNA sequencefrom +53 nt through the poly(A)⁺ tail; $alpha$ S contains the $alpha$ -rENaC full-length cDNA sequences from+420 nt through the poly(A)⁺ tail [ $alpha$ -rENaC open reading frame (ORF) initiates at +517 nt]. $alpha$ SM and $alpha$ LM contain the corresponding sequences, with mutationof the upstream ATG at +473-475 nt to TTG as described for thepromoter-reporter constructs. Templates were linearized 3' tothe poly(A)⁺ tail with XhoI. Capped mRNAs were generated with T7 RNA polymerasewith mMESSAGE mMACHINE (Ambion) and quantitated by ultravioletspectrophotometry. Aliquots were examined by electrophoresis onformaldehyde-containing agarose gels to verify length and confirmthat mRNA was not degraded. We used 0.8 pmol of each capped mRNAto prime in vitro translation reactions containing [³⁵S]methionine ( $>=$ 1,000 Ci/mmol; ICN, Cosa Mesa, CA) with a ReticLysateIVT kit (Ambion). The resulting proteins were analyzed on LaemmliSDS-polyacrylamide gels, subjected to fluorography with Amplify(Amersham Pharmacia Biotech), and exposed to Kodak X-OMAT film.For quantitation of synthesized protein, the dried gels were imagedwith a Molecular Dynamics STORM 840 phosphorimager equipped withImageQuant Software (Amersham PharmaciaBiotech).

Statistical analysis. All data are presented as means ± SE, and significances were calculated with one-way ANOVA. P < 0.05 was considered to besignificant. Statistical analysis was carried out with GraphPadInStat version 3.01 (GraphPad Software, San DiegoCA).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

$alpha$ -rENaC promoter activity in lung and kidney epithelial cell lines. In the present study, we created a series of promoter-reporter constructs (Fig. 1) extending up to 4,539 bp upstream and 499bp downstream of the $alpha$ -rENaC +1 transcription start site. We characterizedthe basal and steroid hormone-stimulated activity of these constructsin representative kidney (MDCK and M1) and lung (MLE-15 and H441)epithelial cell lines (Fig. 2).

View larger version (20K):
[in this window]
[in a new window]

Fig. 1. Rat epithelial Na⁺ channel $alpha$ -subunit ( $alpha$ -rENaC) promoter-reporter constructs. Top line, structural organization of the $alpha$ -rENaC promoter (not to scale). Note the presence of a glucocorticoid responsive element (GRE) between XhoI and HindIII (30). Labels at right, promoter-secreted alkaline phosphatase (SEAP) 2 constructs representing genomic DNA fragments corresponding to the region of the $alpha$ -rENaC promoter directly above; nos. at right, 3'-end of the fragment; nos. at left, nucleotide number of the 5'-end of the fragment based on +1 being the exon 1A transcriptional start site identified in a previous publication by Otulakowski et al. (30). All constructs terminate upstream of the authentic $alpha$ -rENaC open reading frame. $star$ , Mutation of upstream ATG to TTG as described in MATERIALS AND METHODS.

View larger version (48K):
[in this window]
[in a new window]

Fig. 2. Activity of $alpha$ -rENaC promoter-reporter constructs in kidney and lung cell lines. $alpha$ -rENaC promoter-SEAP2 constructs (see Fig. 1) were transiently transfected into Madin-Darby canine kidney (MDCK; A), M1 (B), MLE-15 (C), and H441 (D) cell lines. Standard medium for M1 cells contained 5 µM dexamethasone. Standard medium for MLE-15 cells contained 10 nM hydrocortisone and 10 nM $beta$ -estradiol. SEAP activity in each well was first normalized to $beta$ -galactosidase activity to correct for transfection efficiency and is expressed relative to the promoterless SEAP2-basic vector transfected in parallel wells. Data represent means of triplicate wells in a representative transient transfection experiment. All transient transfection experiments were carried out at least 3 times in each cell line. Differences between selected pairs of constructs were calculated with ANOVA followed by Bonferroni posttest. * P < 0.01 compared with SEAP2(+367) construct from same series. ^¶ P < 0.05 compared with PvuSEAP2(+211) construct from same series.

Otulakowski et al. (30) have reported results from a subset of these constructs (297-, 548-, 1051-, and 1474SEAP2) in COS-7and A549 cells in a previous publication; basal SEAP activitywas only two- to threefold relative to the promoterless pSEAP2reporter in the constructs. Basal expression from these $alpha$ -rENaCconstructs in the MDCK, M1, MLE-15, and H441 cell lines was atleast twice as high as they had obtained in COS-7 and A549 cells.Activity of the glucocorticoid-responsive element previously described(30), located between $-$ 552 and $-$ 1,054 nt, is evident in M1 andMLE-15 cells, which are cultured in medium containing steroidhormone (Fig. 2, B and C; note the log scale); relative activityof 1051SEAP2 in the presence of glucocorticoid stimulation reached61-fold in M1 cells and 47-fold in MLE-15, in contrast to themodest 5-fold activity previously reported by Otulakowski et al.(30) in COS-7 cells . When dexamethasone (M1 cells) or hydrocortisone(MLE-15 cells) is eliminated from the medium during the posttransfectionperiod, 1051-series constructs yield activities comparable tothe 548-series constructs (data notshown).

Otulakowski et al. (30) previously reported the presence of a negative regulatory element in the +367- to +499-nt region,significant in the lung carcinoma line A549 but not in the fibroblast-likekidney line COS-7. In all four of the kidney and lung epithelialcell lines tested in these studies, this element was active, reducingactivity by up to 70% (P < 0.01; Fig. 2, SEAP2 vs. dSEAP2). Thisrepressive effect is maintained even in the presence of steroidinduction; reporter activity of 1051-, 1474-, and 5000dSEAP2 constructsin M1 and MLE-15 cells (Fig. 2, B and C) was ~50% lower than thecorresponding 1051-, 1474-, and 5000SEAP2constructs.

We examined the role of sequences within the 5'-UTR further by generating additional constructs. The PvuSEAP2 constructs (Fig.2), which shortened the 5'-UTR to 211 bp, resulted in an increasein activity in three cell lines as would be expected on decreasingthe length of the 5'-UTR; however, this effect did not alwaysreach significance. Further truncation, to +53 nt ("-uSEAP2" constructs;Fig. 2), resulted in a decrease in activity in M1, MLE-15, andH441 cells to levels similar to constructs extending to +367 nt.This difference between uSEAP2 and PvuSEAP2 constructs was significantregardless of the length of the upstream promoter. Taken together,these experiments suggest a positive element located in the 53-to 211-bp region, operational in H441, MLE-15, and M1 cell lines.The enhancement of reporter gene expression ranged from 33 to86% depending on the cell line and promoter context. Althoughthis is a modest effect, we feel it is significant because increasingthe 5'-UTR length from 53 to 211 bp would normally decrease, ratherthan increase, proteinexpression.

Reporter mRNA levels in transiently transfected cells. Because the regulatory regions identified between +53 and +499 nt are located downstream from the transcriptional start site,it is impossible to tell from SEAP enzyme activity alone whetherthey are modifying transcription initiation, mRNA stability, ormRNA translational efficiency. To begin to clarify the processthrough which these elements act, we designed a control plasmidto allow quantitative RT-PCR analysis of reporter gene mRNA levelsin transfected cells. RSV $Delta$ SEAP contains a small deletion in theregion encoding the COOH terminus of SEAP protein; primers flankingthis sequence were designed such that RT-PCR amplification productsof full-length SEAP and $Delta$ SEAP mRNAs can be distinguished on thebasis of size. RSV $Delta$ SEAP was cotransfected with 548uSEAP2, 548PvuSEAP2,548SEAP2, and 548dSEAP2 such that it would serve both as a controlfor transfection efficiency and as an internal, competitive controlfor QRT-PCR.

There was no significant difference in SEAP mRNA levels in M1 cells transfected with the four different $alpha$ -rENaC promoter-drivenSEAP reporters (Fig. 3B) despite significant differences in SEAPenzyme activity (Fig. 3C). In the lung epithelial cell line MLE-15,the sequence between +211 and +367 nt did significantly decreasereporter gene mRNA expression in transiently transfected cells(Fig. 4B); however, the associated decrease in reporter gene activitywas not significant (Fig. 4C). Both cell types consistently showedthat extension of the promoter constructs from +53 to +211 nt(Fig. 4) induced a significant doubling of reporter gene enzymeactivity in the absence of any significant change in mRNA levels.In addition, SEAP enzyme activity was significantly decreasedby extension of the constructs from +367 to +499 nt (Fig. 4),again in the absence of any change in reporter gene mRNA levels.These data indicate that differences in SEAP enzyme activity resultfrom differences in the efficiency of translation of the SEAPmRNAs expressed from the different reporter constructs ratherthan from differences in transcription rate or mRNA stability.Specifically, they suggest the existence of a sequence elementenhancing translation located between +53 and +211 nt and an elementrepressing translation between +367 and +499 nt.

View larger version (22K):
[in this window]
[in a new window]

Fig. 3. Comparison of $alpha$ -rENaC-driven reporter gene mRNA and enzyme activity levels in M1 cells. A: M1 cells were transiently transfected with a series of fragments of the $alpha$ -rENaC promoter, extending 552 bp upstream from the transcription start site and terminating at various positions within the 5'-untranslated region (UTR). B: cells were cotransfected with ENaC promoter-driven SEAP and Rous sarcoma virus (RSV) $Delta$ SEAP. SEAP mRNA levels are expressed relative to $Delta$ SEAP mRNA and represent the average of triplicate wells in 2 independent transfections. C: cells were cotransfected with ENaC promoter-driven SEAP and RSV $beta$ -galactosidase ( $beta$ gal). SEAP enzyme activity was normalized to $beta$ -galactosidase activity to correct for transfection efficiency and is expressed relative to the promoterless SEAP2-basic vector transfected in parallel wells. Data represent means of triplicate wells. Differences between pairs of constructs were calculated with ANOVA followed by Tukey-Kramer posttest.

View larger version (18K):
[in this window]
[in a new window]

Fig. 4. Comparison of $alpha$ -rENaC-driven reporter gene mRNA and enzyme activity levels in MLE-15 cells. A: MLE-15 cells were transiently transfected with a series of fragments of the $alpha$ -rENaC promoter, extending 552 bp upstream from the transcription start site and terminating at various positions within the 5'-UTR. B: cells were cotransfected with ENaC promoter-driven SEAP and RSV $Delta$ SEAP. SEAP mRNA levels are expressed relative to $Delta$ SEAP mRNA and represent the average of triplicate wells in 2 independent transfections. C: cells were cotransfected with ENaC promoter-driven SEAP and RSV $beta$ gal. SEAP enzyme activity was normalized to $beta$ -galactosidase activity to correct for transfection efficiency and is expressed relative to the promoterless SEAP2-basic vector transfected in parallel wells. Data represent means of triplicate wells. Differences between pairs of constructs were calculated with ANOVA followed by Tukey-Kramer posttest.

Effect of the +367- to +499-nt region in the context of uSEAP2 reporters. The decrease in reporter gene expression seen when extending the $alpha$ -rENaC 5'-UTR from +367 to +499 nt may simply be due toincreasing the length of the 5'-UTR past a certain threshold.To investigate this, we deleted bases from +54 to +366 nt, effectivelymoving the +367- to +499-nt region directly adjacent to the 3'-endof the uSEAP2 constructs (Fig. 1, $Delta$ dSEAP2 constructs). As shownin Fig. 5, the $Delta$ dSEAP2 constructs exhibited decreased reportergene activity compared with their corresponding uSEAP2 reporters,although this inhibition was approximately half as great as thatseen with the full-length dSEAP2 constructs. The decrease failedto reach significance in the 1051-series constructs in the kidneycell lines MDCK and M1 and in the 5000-series constructs in thelung cell lines MLE-15 and H441. The effect did not appear tobe modified under conditions of steroid induction of the reportergene in M1 or MLE-15 cells (Fig. 5, B and C).

View larger version (40K):
[in this window]
[in a new window]

Fig. 5. Effect of +367- to +499-nucleotide (nt) region directly abutted to uSEAP2 promoter constructs. $alpha$ -rENaC promoter-SEAP2 constructs (see Fig. 1) were transiently transfected into MDCK (A), M1 (B), MLE-15 (C), and H441 (D) cell lines. Standard medium for M1 cells contained 5 µM dexamethasone. Standard medium for MLE-15 cells contained 10 nM hydrocortisone and 10 nM $beta$ -estradiol. SEAP activity in each well was first normalized to $beta$ -galactosidase activity to correct for transfection efficiency and is expressed relative to the promoterless SEAP2-basic vector transfected in parallel wells. Data are means ± SE of 6 wells. Differences between constructs were calculated with ANOVA followed by Tukey-Kramer posttest. Significantly different compared with uSEAP2 in same construct series: * P < 0.05; $dagger$ P < 0.01; $Dagger$ P < 0.001.

Effect of upstream ORF on mRNA translation. The sequence of the $alpha$ -rENaC 5'-UTR is indicated in Fig. 6. Adjacent AUG codons initiating the $alpha$ -rENaC ORF are underlined at+517 nt. Note the existence of an AUG codon upstream and out-of-frameinitiation codon with the $alpha$ -rENaC protein-coding region, initiatingan upstream ORF (uORF) at +473 nt. Such upstream initiation codonshave frequently been reported to exert negative effects on translationinitiation at the correct, downstream initiation codon (14).None of the AUG codons exist in an optimal Kozak consensus sequence(RCCAUGG, with R at $-$ 3 nt and G at +4 nt being most influential)(25). Thus we hypothesized that the initiation of protein synthesisat the upstream AUG was inhibiting translation of the SEAP reporter(with which it is also out of frame in our constructs) in "-dSEAP2"constructs. We therefore mutated the upstream ATG sequence inour SEAP reporter constructs to TTG, thus eliminating the initiationcodon of the uORF. The results of this mutation are shown in Fig.7 (dmOSEAP2 constructs). Surprisingly, removal of the uORF hadlittle effect, restoring activity convincingly only in kidney-derivedcell lines (Fig. 7, A and B) transfected with constructs containingminimal amounts of the upstream promoter (297dmOSEAP2 and 548dmOSEAP2).In lung-derived epithelial cell lines (Fig. 7, C and D), no significantincrease in reporter gene activity resulted from the uORF mutationexcept in MLE-15 cells transfected with 297dmOSEAP2, where a partialrestoration of activity was seen.

View larger version (35K):
[in this window]
[in a new window]

Fig. 6. Nucleotide sequence of the 5'-end of $alpha$ -rENaC mRNA. Vertical lines, end points of promoter-reporter constructs with nucleotide position above the sequence; underlined letters, methionine codons (AUG). Note the upstream open reading frame (uORF) that initiates at +473 nt and encodes a 23-amino acid peptide, overlapping the authentic $alpha$ -rENaC open reading frame that initiates at +517 nt.

View larger version (47K):
[in this window]
[in a new window]

Fig. 7. Effect on reporter gene enzyme activity with elimination of the $alpha$ -rENaC uORF by mutagenesis of ATG to TTG. $alpha$ -rENaC promoter-SEAP2 constructs (see Fig. 1) were transiently transfected into MDCK (A), M1 (B), MLE-15 (C), and H441 (D) cell lines. Standard medium for M1 cells contained 5 µM dexamethasone. Standard medium for MLE-15 cells contained 10 nM hydrocortisone and 10 nM $beta$ -estradiol. SEAP activity in each well was first normalized to $beta$ -galactosidase activity to correct for transfection efficiency and is expressed relative to the promoterless SEAP2-basic vector transfected in parallel wells. Data are means ± SE of triplicate wells. Significantly different compared with dSEAP2 in same construct series: * P < 0.01; $dagger$ P < 0.01; $Dagger$ P < 0.05.

Effects of $alpha$ -rENaC 5'-UTR on translational efficiency in vitro. To confirm the effects of the $alpha$ -rENaC 5'-UTR on translation efficiency in conjunction with the $alpha$ -rENaC protein-coding region,as opposed to heterologous reporter constructs, we created fourtemplates suitable for in vitro transcription and translationof $alpha$ -rENaC protein (Fig. 8A). Equimolar amounts of capped $alpha$ -rENaCtranscripts containing either 97 ( $alpha$ S and $alpha$ SM) or 464 ( $alpha$ L and $alpha$ LM)nt of the $alpha$ -rENaC 5'-UTR were used to direct protein synthesisin a reticulocyte lysate system. Radiolabeled protein productswere analyzed by SDS-PAGE as demonstrated in Fig. 8B. All fourtemplates gave rise to a specific protein product at 72 kDa, consistentwith the expected size of in vitro translated $alpha$ -rENaC. Considerablymore protein was produced from RNA transcripts containing thetruncated 5'-UTR (compare protein produced from $alpha$ S with $alpha$ L). Toconfirm these observations, $alpha$ -rENaC protein was quantitated fromthree independent transcription or translation experiments (Fig.8C). As in transient transfections, mutation of the upstream AUGresulted in only a small increase in translational efficiency,which was significant only in the context of the truncated UTR.

View larger version (26K):
[in this window]
[in a new window]

Fig. 8. In vitro transcription/translation of $alpha$ -rENaC. A: templates for in vitro transcription of $alpha$ -rENaC mRNAs were assembled in pBluescript KS( $-$ ) such that sense RNA could be synthesized with T7 RNA polymerase. Hatched box, open reading frame of $alpha$ -rENaC cDNA that initiates at +517 nt. $alpha$ S and $alpha$ SM contain 97 nt of $alpha$ -rENaC 5'-UTR; $alpha$ L and $alpha$ LM contain 464 nt of $alpha$ -rENaC 5'-UTR. ATG in $alpha$ S and $alpha$ L indicates upstream ATG. $star$ , ATG mutated to TTG in $alpha$ SM and $alpha$ LM. $alpha$ -rENaC cDNAs were inserted between SacII and XbaI such that all in vitro synthesized transcripts contained the same minimal (19 nt) amount of vector-derived sequence at the extreme 5'-end. B: representative SDS-PAGE analysis of [³⁵S]methionine-labeled protein products from in vitro translation of 0.8 pmol of $alpha$ -rENaC cRNA. In vitro translation reaction containing 1 of the 4 $alpha$ -rENaC cRNAs described in A was electrophoresed on a 7.5% SDS-polyacrylamide gel, dried, and exposed to X-ray film overnight. Major band at ~72 kDa corresponds to predicted size of unglycosylated $alpha$ -rENaC. Benchmark-prestained protein ladder (Life Technologies) was used to estimate protein size. C: relative amounts of $alpha$ -rENaC protein synthesized in vitro from equimolar amounts of cRNAs differing in the 5'-UTR region. [³⁵S]methionine incorporated into the 72-kDa $alpha$ -rENaC band was quantitated with a phosphorimager and is expressed relative to protein produced from $alpha$ L cRNA. Values are means ± SE of 3 independent in vitro transcription or translation experiments. Truncation of the UTR ( $alpha$ S) significantly increased translational efficiency. * P < 0.01 compared with $alpha$ L. Mutation of the upstream AUG ( $alpha$ SM) increased translational efficiency significantly in the context of the short UTR. ** P < 0.01 compared with $alpha$ S. In the context of the long UTR ( $alpha$ LM vs. $alpha$ L), the increase seen was reproducible but did not reach significance.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We have presented evidence that suggests that the 5'-UTR of $alpha$ -rENaC mRNA plays a role in regulating ENaC expression. The overallinhibitory effect of the long $alpha$ -rENaC 5'-UTR is clear in our invitro translation experiments. Transient transfection experimentsindicated the existence of specific positive and negative translationalregulatory elements within the 5'-UTR. Specifically, the regionlocated between +53 and +211 nt increased the expression of alinked reporter gene in a variety of cell lines without increasingthe amount of mRNA expressed. A second region of interest, locatedbetween +367 and +499 nt, severely inhibited translation of alinked reporter gene. In general, one would expect expressionto decrease with increasing length of the 5'-UTR. The inhibitoryeffect of the +367- to +499-nt region was tested in the contextof a shorter $alpha$ -rENaC 5'-UTR, i.e., in the $Delta$ dSEAP2 constructs (Fig.5). Interpretation of the data from the $Delta$ dSEAP2 constructs iscomplicated because they delete the putative positive regulatoryregion from +54 to +211 nt. However, it is clear from Fig. 2Athat the +54- to +211-nt region has no effect in MDCK cells. InFig. 2A, expression was not affected by increasing the amountof $alpha$ -rENaC 5'-UTR from 53 nt (uSEAP2) to 211 nt (PvuSEAP2) oreven further to 367 nt (SEAP2) in MDCK cells. Yet the $Delta$ dSEAP2constructs, with only 186 nt of $alpha$ -rENaC 5'-UTR, generated significantlyless reporter gene expression than the uSEAP2 constructs (Fig.5A). Similar results were seen in other cell lines (Fig. 5, B-D).The inhibition was only about half as much as was seen with theintact 499-nt UTR region (dSEAP2 constructs), suggesting thateither total length or possibly secondary structure interactionsbetween the +367- to +499-nt region and the deleted sequencesalso play a role. Overall, the data suggest that the decreasein translation efficiency seen when extending the 5'-UTR from+367 to +499 nt is not solely due to increasing the length ofthe 5'-UTR.

In a previous publication, Otulakowski et al. (30) reported the existence of an additional transcription start site in thisregion, at position +455, detectable by conventional 5'-rapidamplification of cDNA ends and primer extension. As seen in Figs.3 and 4, this region does not increase transcription (SEAP mRNAlevels) in transiently transfected M1 or MLE15 cells, and we havesubsequently been unable to demonstrate transcripts initiatingat this site with a RNase protection assay (Otulakowski and O'Brodovich,unpublished data). A GC-rich sequence immediately upstream of+455 nt may have impeded RT through this region in 5'-rapid amplificationof cDNA ends and primerextension.

The upstream, out-of-frame initiation codon in this region seems to mediate only a minor component of the translational repressionas demonstrated by the effects of point mutation of the upstreamstart codon in both transfected cells and in vitro translationsystems. Our data thus suggest that an additional level of translationalrepression is conferred by this region, which may be specificto lung, because point mutation of the upstream AUG restored reportergene activity to a lesser extent in MLE-15 or H441 cells thanin MDCK and M1 cells. We do not presently understand the mechanismby which mutation of the upstream AUG restored activity only inconstructs containing a "minimal" promoter, but the observationsuggests that translational inhibition mediated by the 5'-UTRmay be influenced by sequences in the 5'-flanking region and maybe subject to cell- or tissue-specific effects. As discussed above,Fig. 5 suggests the influence of the region between +367 and +499nt may also be dependent on promoter context and cell line intransienttransfections.

The importance of control of eukaryotic gene expression at the level of translation is now well recognized (see Refs. 14,40, 41 for recent reviews). Specific sequences within mRNAUTRs can modulate translational efficiency in a tissue- and developmentalstage-specific manner. Most translational effects are exertedat the level of protein chain initiation with a combination ofspecific sequence features in the 5'- or 3'-UTRs of mRNAs and/orphysiological regulation of initiation factoractivities.

Experimental studies with both in vivo and in vitro systems clearly demonstrate that mRNAs with a high potential to form astable secondary structure in the 5'-UTR tend to be translatedinefficiently (7, 24, 25, 36). Tissue-specific use ofalternative promoters to produce transcripts with different 5'-UTRshaving varying amounts of secondary structure has been reported,for example, for the human $alpha$ -folate receptor (49) and insulin-likegrowth factor II (29). Mechanisms permitting the regulated releaseof this translational repression in response to specific signalsare not completely understood. One possibility is the activationof general initiation factors involved in mRNA binding (e.g.,by phosphorylation) (1). Alternative use of a shorter, moreefficiently translated leader sequence may also occur in responseto some developmental (6, 35) or environmental (6, 54)cue. In this context, it is interesting to note that human $alpha$ -ENaCmRNAs differing in the 5'-UTR through use of alternative transcriptionalstart sites have been reported (30, 51).

The presence of upstream AUG codons in the 5'-UTR can also affect the efficiency of translation initiation of the main ORF.In >90% of mRNAs, the AUG initiating the main ORF is the firstAUG encountered when scanning from the 5'-end (25). Additionalupstream AUGs tend to severely decrease the efficiency of initiationat the correct AUG, but these effects can be tissue specific (18,20, 39).

Structural motifs in mRNA molecules can provide sites for the binding of specific proteins. In the case of the 5'-UTR, suchbinding can impede initiation by stabilizing an element of thesecondary structure not itself strong enough to be inhibitory(15, 16). Most recently, the identification of internal ribosomeentry sequence (IRES) elements in the 5'-UTR in a variety of cappedeukaryotic mRNAs has led to the discovery of an alternative mechanismof translation initiation that can function as an alternativeto "scanning" the 5'-UTR by the 43S preinitiation complex. Usageof IRES-mediated translational initiation can avoid the inhibitoryeffects of the secondary structure at the 5'-end of the mRNA andmay be physiologically regulated (32).

The observation that the mRNA encoding $alpha$ -ENaC in both humans and rats contains an unusually long 5'-UTR burdened with GC-richregions indicates immediately that this mRNA is probably inefficientlytranslated and may explain the relative abundance of $alpha$ -ENaC mRNAcompared with $beta$ - and $gamma$ -ENaC mRNAs in native tissue. Furthermore,the observation of tissue (51) and developmental (30) regulationof the expression of alternative 5'-UTRs suggests that translationalregulation may play a role in controlling ENaC synthesis. Ourdata now indicate that the $alpha$ -rENaC 5'-UTR contains sequence elementsexerting both positive and negative effects on translation ofthe downstream ORF. The mechanism by which these elements functionis not yet elucidated, and a number of possibilities exist basedon the examples given above. The positive element 53- to 211-bpregion may contain sequences that bind regulatory proteins, influencesecondary structure, or contain an IRES, allowing recruitmentof ribosomes downstream of secondary structure at the extreme5'-end of the mRNA. The negative effects of the 367- to 499-bpsequence appear to be only minimally mediated via the upstreamAUG, suggesting that secondary structure or specific regulatoryproteins may be involved in this region also. The translationalefficiency of mRNAs burdened with a secondary structure in the5'-UTR is susceptible to regulation via cell signaling cascadesthat modify assembly of the eukaryotic translation initiationcomplex eIF4F, which is responsible for unwinding the secondarystructure.

The number of functional ENaCs on the cell surface is small and tightly regulated. Previous studies (34, 48, 52) haveshown that most of the channel proteins remain in a core-glycosylatedform in pre-Golgi compartments and are subsequently degraded beforeever reaching the plasma membrane. This has led to the suggestionthat the limiting steps for the accumulation of functional channelsin the plasma membrane are the processes of assembly and maturationof the subunits in the endoplasmic reticulum (52). However,these studies have been carried out in heterologous expressionsystems (Xenopus oocytes and transfected mammalian cells) andused $alpha$ -ENaC cDNAs that lack the extended 5'-UTRs concurrentlyreported in both rats (30) and humans (51). Consequently,it is possible that much less $alpha$ -ENaC protein would be producedfrom the endogenous mRNAs than was seen in the heterologous systems,possibly eliminating the buildup of excess unassembled proteinin the endoplasmic reticulum. Little information is availableon the biosynthesis and trafficking of endogenous ENaC; however,May et al. (28) have examined the rate of synthesis of $alpha$ -, $beta$ -,and $gamma$ -ENaC subunit proteins in A6 cells. After aldosterone treatment,an increase in the rate of synthesis of $alpha$ -ENaC protein precededthe increase in $alpha$ -ENaC mRNA. This led the authors to suggest thatsynthesis of the $alpha$ -subunit was a limiting factor in channel assemblyand that aldosterone may selectively increase translation of existing $alpha$ -ENaCmRNAs.

More recently, the serum- and glucocorticoid-dependent kinase sgk has been identified as an early, aldosterone-induced genethat is a likely candidate to mediate the early increase in ENaCactivity in response to aldosterone. Although aldosterone inducesphosphorylation of the carboxy termini of $beta$ - and $gamma$ -ENaC subunitswhen the channel is expressed in MDCK cells (44), sgk appearsnot to phosphorylate ENaC directly (8) nor to affect its degradation(43). Although many scenarios by which a kinase signaling cascadecan lead to an increase in ENaC cell surface expression are possible,one hypothesis consistent with our observations and those of Mayet al. (28) would be a kinase-mediated increase in the translationinitiation of ENaC mRNAs. Specifically, the eukaryotic translationinitiation factor eIF4E, which has been suggested to be limitingfor translation in vivo, is serine phosphorylated in responseto growth factors, hormones, and mitogens (reviewed in Ref. 14).Phosphorylation of eIF4E enhances its activity, resulting in increaseddelivery of eIF4F (an RNA helicase) to the 5'-UTR, disruptingthe secondary structure. In fact, in mammalian cells, overexpressionof eIF4E results in a more efficient translation of reporter mRNAscontaining structured 5'-UTRs (22) and has been shown to enhancetranslation of a number of mRNAs such as cyclin D1 (38) andornithine decarboxylase with structure-rich 5'-UTRs (42). Thusit is plausible that aldosterone induces a rapid increase in ENaCprotein synthesis by specifically increasing the efficiency oftranslation initiation of $alpha$ -ENaC.

Understanding of mRNA cellular biology, such as regulation of splicing, subcellular trafficking, translation efficiency, andstability, has generally lagged behind our knowledge of functionalmechanisms involving DNA and proteins. However, the importantrole that UTRs of eukaryotic mRNAs play in gene expression isbecoming more widely recognized and has led to the recent creationof a specialized database of 5'- and 3'-UTR sequences and functionalelements (33). $alpha$ -ENaC mRNAs from both rats and humans are clearlyburdened with unusually long 5'-UTRs. Our study using recombinantDNA constructs indicates that the 5'-UTR contains regions capableof regulating ENaC expression at the translational level. An investigationof the translational efficiency of endogenous $alpha$ -rENaC mRNA viapolysome gradient analysis will be required to prove the physiologicalsignificance of these effects. Regulation at the translationallevel, probably in combination with ENaC assembly and trafficking,would enable ENaC-expressing tissues to respond more quickly toenvironmental signals than de novo transcription wouldpermit.

	ACKNOWLEDGEMENTS

This work was supported by a Canadian Institutes of Health Research Group Grant in LungDevelopment.

	FOOTNOTES

Address for reprint requests and other correspondence: G. Otulakowski, Programme in Lung Biology Research, Hospital for SickChildren Research Institute, 555 University Ave., Toronto, OntarioM5G 1X8, Canada (E-mail: gotulak{at}sickkids.on.ca).

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

Received 8 September 2000; accepted in final form 26 July 2001.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Brown, EJ, and Schreiber SL. A signaling pathway to translational control. Cell 86: 517-520, 1996[ISI][Medline].

2. Burch, LH, Talbot CR, Knowles MR, Canessa CM, Rossier BC, and Boucher RC. Relative expression of the human epithelial Na⁺ channel subunits in normal and cystic fibrosis airways. Am J Physiol Cell Physiol 269: C511-C518, 1995[Abstract/Free Full Text].

3. Canessa, CM, Horisberger JD, and Rossier BC. Functional cloning of the epithelial sodium channel: relation with genes involved in neurodegeneration. Nature 361: 467-470, 1993[Medline].

4. Canessa, CM, Schild L, Buell G, Thorens B, Gautschi I, Horisberger JD, and Rossier BC. Amiloride-sensitive epithelial Na+ channel is made of three homologous subunits. Nature 367: 463-467, 1994[Medline].

5. Chang, SS, Grunder S, Hanukoglu A, Rosler A, Mathew PM, Hanukoglu I, Schild L, Lu Y, Shimkets RA, Nelson-Williams C, Rossier BC, and Lifton RP. Mutations in subunits of the epithelial sodium channel cause salt wasting with hyperkalaemic acidosis, pseudohypoaldosteronism type 1. Nat Genet 12: 248-253, 1996[ISI][Medline].

6. Cianetti, L, Di Cristofaro A, Zappavigna V, Bottero L, Boccoli G, Testa U, Russo G, Boncinelli E, and Peschle C. Molecular mechanisms underlying the expression of the human HOX-5.1 gene. Nucleic Acids Res 18: 4361-4368, 1990[Abstract/Free Full Text].

7. Curnow, KM, Pascoe L, Davies E, White PC, Corvol P, and Clauser E. Alternatively spliced human type 1 angiotensin II receptor mRNAs are translated at different efficiencies and encode two receptor isoforms. Mol Endocrinol 9: 1250-1262, 1995[Abstract].

8. De la Rosa, DA, Zhang P, Naray-Fejes-Toth A, Fejes-Tóth G, and Canessa C. The serum and glucocorticoid kinase sgk increases the abundance of epithelial sodium channels in the plasma membrane of Xenopus oocytes. J Biol Chem 274: 37834-37839, 1999[Abstract/Free Full Text].

9. Eskandar, S, Snyder PM, Kreman M, Zampighi GA, Welsh MJ, and Wright EM. Number of subunits comprising the epithelial sodium channel. J Biol Chem 274: 27281-27286, 1999[Abstract/Free Full Text].

10. Farman, N, Talbot CR, Boucher R, Fay M, Canessa C, Rossier B, and Bonvalet JP. Noncoordinated expression of $alpha$ -, $beta$ -, and $gamma$ -subunit mRNAs of epithelial Na⁺ channel along rat respiratory tract. Am J Physiol Cell Physiol 272: C131-C141, 1997[Abstract/Free Full Text].

11. Firsov, D, Gautschi I, Merillat AM, Rossier BC, and Schild L. The heterotetrameric architecture of the epithelial sodium channel (ENaC). EMBO J 17: 344-352, 1998[ISI][Medline].

12. Garty, H, and Palmer LG. Epithelial sodium channels: function, structure, and regulation. Physiol Rev 77: 359-396, 1997[Abstract/Free Full Text].

13. Giguère, V, Shago M, Zirngibl R, Tate P, Rossant J, and Varmuza S. Identification of a novel isoform of the retinoic acid receptor gamma expressed in the mouse embryo. Mol Cell Biol 10: 2335-2340, 1990[Abstract/Free Full Text].

14. Gray, NK, and Wickens M. Control of translation initiation in animals. Annu Rev Cell Dev Biol 14: 399-458, 1998[ISI][Medline].

15. Gu, W, and Hecht NR. Translation of a testis-specific Cu/Zn superoxide dismutase (SOD-1) mRNA is regulated by a 65-kilodalton protein which binds to its 5' untranslated region. Mol Cell Biol 16: 4535-4543, 1996[Abstract].

16. Hentze, MW, and Kuhn LC. Molecular control of vertebrate iron metabolism: mRNA-based regulatory circuits operated by iron, nitric oxide, and oxidative stress. Proc Natl Acad Sci USA 93: 8175-8182, 1996[Abstract/Free Full Text].

17. Hummler, E, Barker P, Gatzy J, Beermann F, Verdumo C, Schmidt A, Boucher R, and Rossier BC. Early death due to defective neonatal lung liquid clearance in $alpha$ ENaC-deficient mice. Nat Genet 12: 325-328, 1996[ISI][Medline].

18. Iwaki, A, Iwaki T, Goldman JE, and Liem R. Multiple mRNAs of rat brain $alpha$ -crystallin B chain result from alternative transcriptional initiation. J Biol Chem 265: 22197-22203, 1990[Abstract/Free Full Text].

19. Kassovska-Bratinova, S, Vannam V, Freywald T, Otulakowski G, and O'Brodovich H. Absence of detectable amiloride-sensitive ion transport in murine tracheal epithelia may result from lack of $beta$ -ENaC mRNA expression (Abstract). Am J Respir Crit Care Med 161: A234, 2000.

20. Kilpatrick, DL, Zinn SA, Fitzgerald M, Higuchi H, Sabol SL, and Meyerhardt J. Transcription of the rat and mouse proenkephalin genes is initiated at distinct sites in spermatogenic and somatic cells. Mol Cell Biol 10: 3717-3726, 1990[Abstract/Free Full Text].

21. Kizer, N, Guo XL, and Hruska K. Reconstitution of stretch-activated cation channels by expression of the $alpha$ -subunit of the epithelial sodium channel cloned from osteoblasts. Proc Natl Acad Sci USA 94: 1013-1018, 1997[Abstract/Free Full Text].

22. Koromilas, AE, Lazaris-Karatzas A, and Sonenberg N. mRNAs containing extensive secondary structure in their 5' non-coding region translate efficiently in cells overexpressing initiation factor eIF-4E. EMBO J 11: 4153-4158, 1992[ISI][Medline].

23. Kosari, F, Sheng S, Li J, Mak DOD, Foskett JK, and Kleyman TR. Subunit stoichiometry of the epithelial sodium channel. J Biol Chem 273: 13469-13474, 1998[Abstract/Free Full Text].

24. Kozak, M. An analysis of vertebrate mRNA sequences: intimations of translational control. J Cell Biol 115: 887-903, 1991[Abstract/Free Full Text].

25. Kozak, M. Structural features in eukaryotic mRNAs that modulate the initiation of translation. J Biol Chem 266: 19867-19870, 1991[Free Full Text].

26. Matalon, S, and O'Brodovich H. Sodium channels in alveolar epithelial cells: molecular characterization, biophysical properties, and physiological significance. Annu Rev Physiol 61: 627-661, 1999[ISI][Medline].

27. Matsushita, K, McCray PB, Jr, Sigmund RD, Welsh MJ, and Stokes JB. Localization of epithelial sodium channel subunit mRNAs in adult rat lung by in situ hybridization. Am J Physiol Lung Cell Mol Physiol 271: L332-L339, 1996[Abstract/Free Full Text].

28. May, A, Puoti A, Gaeggeler HP, Horisberger JD, and Rossier BC. Early effect of aldosterone on the rate of synthesis of the epithelial sodium channel $alpha$ subunit in A6 renal cells. J Am Soc Nephrol 8: 1813-1822, 1997[Abstract].

29. Nielsen, FC, Gammeltoft S, and Christiansen J. Translational discrimination of mRNAs coding for human insulin-like growth factor II. J Biol Chem 265: 13431-13434, 1990[Abstract/Free Full Text].

30. Otulakowski, G, Rafii B, Bremner HR, and O'Brodovich H. Structure and hormone responsiveness of the gene encoding the $alpha$ -subunit of the rat amiloride-sensitive epithelial sodium channel. Am J Respir Cell Mol Biol 20: 1028-1040, 1999[Abstract/Free Full Text].

31. Otulakowski, G, Staub SF, Ellis L, Ramlall K, Staub O, Smith D, Durie P, and O'Brodovich H. Relation between $alpha$ , $beta$ , $gamma$ hENaC mRNA levels and nasal epithelial potential difference in healthy men. Am J Respir Crit Care Med 157: 1213-1220, 1998[Abstract/Free Full Text].

32. Pain, VM. Initiation of protein synthesis in eukaryotic cells. Eur J Biochem 236: 747-771, 1996[ISI][Medline].

33. Pesole, G, Liuni S, Grillo G, Licciulli F, Larizza A, Makalowski W, and Saccone C. UTRdb and UTRsite: specialized databases of sequences and functional elements of 5' and 3' untranslated regions of eukaryotic mRNAs. Nucleic Acids Res 28: 193-196, 2000[Abstract/Free Full Text].

34. Prince, LS, and Welsh MJ. Cell surface expression and biosynthesis of epithelial Na⁺ channels. Biochem J 336: 705-710, 1998.

35. Reynolds, PJ, Lesley J, Trotter J, Schulte R, Hyman R, and Sefton BM. Changes in the relative abundance of type I and type II lck mRNA transcripts suggest differential promoter usage during T-cell development. Mol Cell Biol 10: 4266-4270, 1990[Abstract/Free Full Text].

36. Roberts, SJ, Chung KN, Nachmanoff K, and Elwood PC. Tissue-specific promoters of the $alpha$ human folate receptor gene yield transcripts with divergent 5' leader sequences and different translational efficiencies. Biochem J 326: 439-447, 1997.

37. Rouault, TA, Klausner RC, and Harford JB. Translational control of ferritin. In: Translational Control, edited by Hershey JWB, Mathews MB, and Sonenberg N.. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory, 1996, p. 335-362.

38. Rousseau, D, Kaspar R, Rosenwald I, Gehrke L, and Sonenberg N. Translation initiation of ornithine decarboxylase and nucleocytoplasmic transport of cyclin D1 mRNA are increased in cells overexpressing eukaryotic initiation factor 4E. Proc Natl Acad Sci USA 93: 1065-1070, 1996[Abstract/Free Full Text].

39. Ruan, H, Shantz LM, Pegg AE, and Morris DR. The upstream open reading frame of the mRNA encoding S-adenosylmethionine decarboxylase is a polyamine-responsive translational control element. J Biol Chem 271: 29576-29582, 1996[Abstract/Free Full Text].

40. Sachs, AB. Cell cycle-dependent translation initiation: IRES elements prevail. Cell 101: 243-245, 2000[ISI][Medline].

41. Sachs, AB, Sarnow P, and Hentze MW. Starting at the beginning, middle, and end: translation initiation in eukaryotes. Cell 89: 831-838, 1997[ISI][Medline].

42. Shantz, LM, Hu RH, and Pegg AE. Regulation of ornithine decarboxylase in a transformed cell line that overexpresses translation initiation factor eIF-4E. Cancer Res 56: 3265-3269, 1996[Abstract/Free Full Text].

43. Shigaev, A, Asher C, Latter H, Garty H, and Reuveny E. Regulation of sgk by aldosterone and its effects on the epithelial Na⁺ channel. Am J Physiol Renal Physiol 278: F613-F619, 2000[Abstract/Free Full Text].

44. Shimkets, RA, Lifton R, and Canessa CM. In vivo phosphorylation of the epithelial sodium channel. Proc Natl Acad Sci USA 95: 3301-3305, 1998[Abstract/Free Full Text].

45. Shimkets, RA, Warnock DG, Bositis CM, Nelson-Williams C, Hansson JH, Schambelan M, Gill JRJ, Ulick S, Milora RV, Findling JW, Canessa CM, Rossier BC, and Lifton RP. Liddle's syndrome: heritable human hypertension caused by mutations in the beta subunit of the epithelial Na channel. Cell 79: 404-414, 1994.

46. Smith, DE, Otulakowski G, Yeger H, Post M, Cutz E, and O'Brodovich HM. Epithelial Na⁺ channel (ENaC) expression in the developing normal and abnormal human perinatal lung. Am J Respir Crit Care Med 161: 1322-1331, 2000[Abstract/Free Full Text].

47. Snyder, PM, Cheng C, Prince LS, Rogers JC, and Welsh MJ. Electrophysiological and biochemical evidence that DEG/ENaC cation channels are composed of nine subunits. J Biol Chem 273: 681-684, 1998[Abstract/Free Full Text].

48. Staub, O, Gautschi I, Ishikawa T, Breitschopf K, Ciechanover A, Schild L, and Rotin D. Regulation of stability and function of the epithelial Na⁺ channel (ENaC) by ubiquitination. EMBO J 16: 6325-6336, 1997[ISI][Medline].

49. Sun, XL, and Antony AC. Evidence that a specific interaction between an 18-base cis-element in the 5'-untranslated region of human folate receptor- $alpha$ mRNA and a 46-kDa cytosolic trans-factor is critical for translation. J Biol Chem 271: 25539-25547, 1996[Abstract/Free Full Text].

50. Talbot, CL, Bosworth DG, Briley EL, Fenstermacher DA, Boucher RC, Gabriel SE, and Barker PM. Quantitation and localization of ENaC subunit expression in fetal, newborn, and adult mouse lung. Am J Respir Cell Mol Biol 20: 398-406, 1999[Abstract/Free Full Text].

51. Thomas, CP, Auerbach S, Stokes JB, and Volk KA. 5' Heterogeneity in epithelial sodium channel $alpha$ -subunit mRNA leads to distinct NH₂-terminal variant proteins. Am J Physiol Cell Physiol 274: C1312-C1323, 1998[Abstract/Free Full Text].

52. Valentijn, JA, Fyfe GK, and Canessa CM. Biosynthesis and processing of epithelial sodium channels in Xenopus oocytes. J Biol Chem 273: 30344-30351, 1998[Abstract/Free Full Text].

53. Voilley, N, Galibert A, Bassilana F, Renard S, Lingueglia E, Coscoy S, Champigny G, Hofman P, Lazdunski M, and Barbry P. The amiloride-sensitive Na⁺ channel: from primary structure to function. Comp Biochem Physiol A Physiol 118: 193-200, 1997[Medline].

54. Waterhouse, P, Khokha R, and Denhardt DT. Modulation of translation by the 5' leader sequence of the mRNA encoding murine tissue inhibitor of metalloproteinases. J Biol Chem 265: 5585-5589, 1990[Abstract/Free Full Text].

This article has been cited by other articles:

Translational activation and repression by distinct elements within the 5'-UTR of ENaC -subunit mRNA

Translational activation and repression by distinct elements within the 5'-UTR of ENaC $alpha$ -subunit mRNA