Identification of an Intragenic Ribosome Binding Site That Affects Expression of the uncB Gene of the Escherichia coli Proton-Translocating ATPase (unc) Operon

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Journal of Bacteriology, August 1998, p. 3940-3945, Vol. 180, No. 15
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Identification of an Intragenic Ribosome Binding Site That Affects Expression of the uncB Gene of the Escherichia coli Proton-Translocating ATPase (unc) Operon

Sharlene R. Matten,¹^, Thomas D. Schneider,² Steven Ringquist,³^, and William S. A. Brusilow¹^,^*

Department of Biochemistry and Molecular Biology, Wayne State University School of Medicine, Detroit, Michigan 48201¹; Laboratory of Computational and Experimental Biology, National Cancer Institute, Frederick, Maryland 21702-1201²; and Department of Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder, Colorado 80309³

Received 7 August 1997/Accepted 1 June 1998

	ABSTRACT

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The uncB gene codes for the a subunit of the F_o proton channel sector of the Escherichia coli F₁ F_o ATPase. Control of expressionof uncB appears to be exerted at some step after translationalinitiation. Sequence analysis by the perceptron matrices (G. D.Stormo, T. D. Schneider, L. Gold, and A. Ehrenfeucht, NucleicAcids Res. 10:2997-3011, 1982) identified a potential ribosomebinding site within the uncB reading frame preceding a five-codonreading frame which is shifted one base relative to the uncB readingframe. Elimination of this binding site by mutagenesis resultedin a four- to fivefold increase in expression of an uncB'-'lacZfusion gene containing most of uncB. Primer extension inhibition(toeprint) analysis to measure ribosome binding demonstrated thatribosomes could form an initiation complex at this alternativestart site. Two fusions of lacZ to the alternative reading framedemonstrated that this site is recognized by ribosomes in vivo.The results suggest that expression of uncB is reduced by translationalframeshifting and/or a translational false start at this sitewithin the uncB reading frame.

	INTRODUCTION

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The Escherichia coli unc (also called atp) operon is comprised of nine genes which encode the subunits of the proton-translocatingF₁F_o ATPase. This enzyme couples an electrochemical gradient ofprotons to the synthesis of ATP from ADP and P_i. Under anaerobicconditions, the enzyme hydrolyzes ATP and pumps protons acrossthe cytoplasmic membrane to form a proton gradient which can beused in the uptake of essential nutrients such as sugars and aminoacids. The nine genes of the unc operon are transcribed in theorder uncIBEFHAGDC, corresponding to protein i, which has no knownfunction, and subunits a, c, b, $delta$ , $alpha$ , $gamma$ , $beta$ , and $varepsilon$ . These subunitsare integrated into two sectors, the F_o and the F₁. The F_o isthe proton-conducting integral membrane sector composed of thea, b, and c subunits. The F₁ is the peripheral sector carryingthe catalytic sites for ATP synthesis and hydrolysis (for reviews,see references 6, 18, and 23). Each gene exists in a singlecopy within the operon, and the operon is transcribed into a singlepolycistronic mRNA, yet the subunits encoded by these genes existin different numbers in the assembled complex. It has been shownthat differences in translational initiation result in differentialsynthesis of many of the subunits (15).

Particularly interesting is the stoichiometry of the a and c subunits of the F_o sector, encoded by uncB and uncE, respectively.The a/c ratio in the assembled complex has been determined tobe 1:10 (5), and it is clear that in a variety of experiments,the a and c subunits are synthesized in significantly differentamounts (2, 19). However, our previous studies on expressionof a series of uncB'-'lacZ fusion genes (25) demonstrated thattranslational initiation of uncB is apparently as efficient asinitiation of uncE (c subunit). Early fusions, containing 10 to15% of uncB fused to lacZ, produced as much $beta$ -galactosidase activityas an uncE'-'lacZ fusion. A late uncB'-'lacZ fusion, carryingabout 95% of uncB, however, was expressed 10 times less well thanthe early fusions. Also, Lang et al. (14) showed that even thoughthe a and c subunits were synthesized in vitro at significantlydifferent rates, ribosome binding to uncB appeared to be verysimilar to that of uncE, especially when the ratio of mRNA toribosomes was low. The uncB reading frame might therefore containsome posttranslational initiation signals which decrease synthesisof the a subunit. The present study analyzed the uncB readingframe for alternative ribosome recognition sites and tested thehypothesis that uncB expression is influenced by the presenceof such a site.

	MATERIALS AND METHODS

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Plasmids. Plasmids pDKWH103, pKS104, and pKS105 were described previously (25). Plasmid pSRM106 is identical to pKS104 except forthe T $right-arrow$ C mutation at position 285 of uncB, as shown below (seeFig. 2). The 617-bp BamHI fragment within uncB was cloned intoM13 and mutagenized to change the false start ATG codon to ACG,by using the mutagenic primer 5'-GCTTTTGCCGTGGTACATGTC-3'. Theentire fragment was sequenced to ensure that there were no additionalmutations. The mutagenized fragment was then used to constructpSRM106 just as the wild-type fragment had been used to constructpKS104 (25). Plasmid pSRM114 was constructed by mutagenizingthe 617-bp BamHI fragment so that the termination codon of thefalse start reading frame was eliminated, and the false startreading frame was fused in frame to the uncB reading frame. Themutagenic primer 5'-GGCCAGCGGAGCAATGCTTGCTTTTGCCATG-3' resultsin the deletion of the first two bases, TG, of the stop codonfor the false start reading frame. Plasmid pWSB52 consists oflacZ fused directly to the false start initiation codon. An NcoIsite was added to the lac fusion vector pMLB1034 (24) by digestingthe plasmid with EcoRI and ligating in the presence of an EcoRI-NcoIadaptor, 5'-AATTCCCATGGG-3'. The resultant plasmid, pWSB53, containedan NcoI site, the ATG for which is in frame with lacZ. The falsestart initiation codon was then cloned into this vector by digestingpKS104 with PstI and NcoI and cloning the resultant fragment intopWSB53 which had been digested with PstI and NcoI. The resultantplasmid, pWSB52, carries the unc promoter, uncI, and uncB up tothe false start initiation codon, the ATG for which is part ofthe NcoI site, and is in frame with the lacZ gene of pMLB1034.

Assays of $beta$ -galactosidase activity. As described by Solomon et al. (25), these fusions were constructed in plasmids and then recombined into $lambda$ and finally intothe $lambda$ att site to create single-copy fusions in the chromosomeof MC1000 $Delta$ (uncI-uncC), an E. coli strain deleted for both uncand lac (1). $beta$ -Galactosidase activities produced by each fusiongene in single-copy lysogens were assayed as described by Miller(17). The values for the $beta$ -galactosidase activities producedby single copies of the fusions in pDKWH103 and pKS105 are fromthe work of Solomon et al. (25).

Toeprint analysis. Primer extension inhibition (toeprint) analysis of the intragenic false start site within uncB was performed. The extent ofribosome binding in the initiation region of protein synthesiswas determined by primer extension inhibition. RNA was synthesizedin vitro from PCR-generated DNA. Primers containing the T7 polymerasepromoter sequence and DNA flanking the false start site were usedto mutagenize the sequence. T7 polymerase was then used to synthesizeRNA. The transcript was purified on a 6% acrylamide gel and annealedto a ³²P-end-labeled oligonucleotide primer (see Fig. 3); this was followedby RNA sequencing reactions and primer extension inhibition (toeprinting)reactions without and with 30S ribosomes and tRNA^fMet, as described by Hartz et al. (8), except that gel-purifiedRNA was used. Toeprinting reaction mixtures contained 100 nM 30Ssubunits and 500 nM tRNA^fMet. Preincubation was done for 10 min at 37°C; this was followedby primer extension for 15 min at 37°C with Moloney murine leukemiavirus reverse transcriptase (200 U/reaction mixture).

Immunoblots of fusion proteins. E. coli MC1000 $Delta$ (uncI-uncC) (1) carrying either pKS104, pSRM114, or pWSB52 was grown in LB-ampicillin medium to an opticaldensity at 600 nm of 0.4 to 0.7 and then chilled, pelleted bycentrifugation, resuspended in 3 ml of 10 mM MOPS (morpholinepropanesulfonicacid)-10 mM MgCl₂ (pH 7), and lysed in a French press at 16,000lb/in². The pKS104 culture was grown in 25 ml of medium; the other twowere grown in 250 ml. Unlysed cells were removed by centrifugation,and the supernatant fractions were loaded onto a sodium dodecylsulfate (SDS)-7% polyacrylamide gel. Electrophoresis and immunoblotting,with anti- $beta$ -galactosidase (Promega Corporation, Madison, Wis.),were carried out as described previously (3).

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Potential ribosome binding sites of the entire unc sequence, including uncB, were distinguished from other sites by usingthree perceptron weight matrices developed previously, w101, w71,and w51 (26). Each perceptron weight matrix represents a ribosomeas it scans the mRNA. Translational initiation occurs with somefixed probability at any site along the RNA message. This probabilityis related to the value given by the perceptron weight matrixwhen positioned at a given site. Regions with a proper initiationcodon and Shine-Dalgarno sequence are given positive values bythe perceptron weight matrices. A higher weight matrix score indicatesthat a particular sequence fitting within the bounds of the chosenmatrix is more likely to be a ribosome binding site. The resultsof this analysis of the unc operon are shown in Table 1. Allthree matrices identified ribosome binding sites (i.e., producedpositive values) at the initiation codons for uncB, -H, -A, -D,and -C. One matrix identified the initiation codon for uncE. Noneof the matrices identified ribosome binding sites preceding uncIor uncF. Other potential ribosome binding sites are indicatedby positive values in the table. All three matrices identifieda site within uncB (at base 1307) as being a potential ribosomebinding site. Figure 1 shows the location of this potential falsestart and how the resultant reading frame is five codons longand shifted one base compared to the uncB reading frame. Exceptfor this site and the true initiation codons for five of the ATPasegenes, no other site in the operon was given a positive scoreby all three matrices.

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TABLE 1. Perceptron analysis of the unc operon^a

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FIG. 1. Location of translation false start within uncB. All three perceptron weight matrices identified this region as a translation initiation region. The bases between positions 271 and 303 of the uncB reading frame are shown. The amino acids of the uncB product coded for by those bases are shown above them. The false start translation initiation site identified by the perceptron matrices, followed by a short reading frame, is indicated below the bases.

Effect of mutagenizing the false start ribosome binding site on expression of the late uncB'-'lacZ fusion gene. As discussed above, even though the differential expression of most of the ATPase genes appears to be controlled at the levelof translational initiation, past studies suggest that synthesisof the a subunit is controlled at some step after initiation.We tested the role of the alternative reading frame identifiedby perceptron analysis in decreasing the expression of the pKS104uncB'-'lacZ fusion gene, which contains most of the uncB gene(25) (Fig. 2). The CAU corresponding to histidine-95 (Fig. 1)was changed to a CAC (also histidine), creating plasmid pSRM106.This mutation converted the false-start AUG to ACG, thereby destroyingthe putative ribosome binding site. The score resulting from perceptronw101 analysis of this region changed from +61 to $-$ 69 as a resultof this single change. The scores resulting from analysis by theother matrices were even more negative. Eliminating this falsestart ribosome binding site resulted in a four- to fivefold increasein expression of the uncB'-'lacZ fusion gene from 10 to 12 U of $beta$ -galactosidase for the unmutated single-copy KS104 constructionto 45 to 50 U for the mutated single-copy SRM106 fusion gene.Mutation of the site identified by perceptron analysis increasesexpression of uncB (Fig. 2).

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FIG. 2. $beta$ -Galactosidase activities produced by in-frame uncB'-'lacZ fusions. Locations of the unc promoter (P_unc), uncI, uncB, and uncE are shown at the top of the figure. The amounts of unc DNA fused in frame to lacZ in plasmids pDKWH103, pKS104, and pKS105 are indicated by the horizontal lines. Plasmid pSRM106 is identical to pKS104 except for the T $right-arrow$ C mutation at position 285 of uncB, which is indicated by an asterisk. $beta$ -Galactosidase activities produced by each fusion gene in single-copy lysogens were assayed as described by Miller (17). The values for the $beta$ -galactosidase activities produced by single copies of the fusions in pDKWH103 and pKS105 are from the work of Solomon et al. (25).

Toeprint analysis of the false start ribosome binding site. To determine whether this false start region was actually capable of forming an initiation complex with ribosomes and initiatortRNA, we carried out primer extension inhibition experiments,also called toeprint analysis (8). In a toeprint experiment,reverse transcriptase is allowed to begin transcribing an mRNAfrom a primer downstream of a putative ribosome binding site.Without ribosomes in the reaction mixture, the reverse transcriptaseshould pass across the site. When ribosomes are included and allowedto bind, they block the transcriptase, and a distinct band forms15 bases downstream of the initiation codon. Such analysis hasbeen done previously for the ribosome binding sites of the genesof the unc operon (22).

In our initial studies on the mRNA produced by the pKS104 plasmid, which consists of the true unc promoter, uncI, and mostof uncB fused in frame to lacZ (Fig. 2), we detected no toeprintat the false start. Computer analysis of the mRNA around the falsestart suggested the existence of a strong secondary structure(Fig. 3) which, in the in vitro toeprint experiment, might preventor interfere with ribosome binding. A smaller stem-loop structureimmediately following the larger stem-loop might also interferewith the primer extension reaction used to create the toeprint(Fig. 3). Using mutagenic PCR primers, we replaced 21 bases ofone side of the stem-loop with 11 adenosine residues, and we madethree single base changes in the smaller stem-loop to minimizeits effect on the primer extension reactions (Fig. 3). Ribosomebinding to the resultant mRNA revealed a strong toeprint +15 basesfrom the false start initiation codon, precisely where the perceptronanalysis predicted it (Fig. 4). Therefore, this region is capableof forming an initiation complex with ribosomes once the mRNAsecondary structure is disrupted.

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FIG. 3. Putative mRNA secondary structure around translational false start. The sequence between bases 247 and 334 of uncB are shown folded into a secondary structure predicted by the MFOLD program, version 2.0 (10, 11, 30). The false-start AUG and the primer used for sequencing and for primer extension in the toeprint experiment are indicated. To obtain a toeprint of this site, the region indicated by the arrows was replaced by 11 adenosine residues, and a single-base deletion and two single-base mutations were constructed in the small loop, as indicated.

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FIG. 4. Primer extension inhibition (toeprint) analysis of the intragenic false start site within uncB. The extent of ribosome binding in the initiation region of protein synthesis was determined by primer extension inhibition as described in Materials and Methods. Sequencing lanes (G, A, T, and C) are indicated. Lanes labeled (+) and ( $-$ ) represent reactions run in the presence or absence of ribosomes, respectively. Next to lane (+), an arrow indicates the toeprint band which forms at +15 from the false start initiation codon. Below the autoradiogram is shown the location of the toeprint within the initiation domain of the false start, 15 nucleotides 3' of the first base of the initiation codon AUG (boxed). The Shine-Dalgarno sequence (SD) is underlined. The band seven bases above the toeprint could be a minor ribosome binding region predicted by the w51 matrix (see Results).

The RNA synthesized for the toeprint analysis was too short in sequence to be analyzed by any of the perceptron weight matrices.To evaluate how these mutations might affect the perceptron analysis,we assumed the presence of 100 adenosine residues on each endof the sequence, analyzed those sequences with the perceptronmatrices, and found that the changes which allowed us to observea toeprint were changes which raised the perceptron score resultingfrom analysis with the w51 matrix but lowered the scores resultingfrom analysis with the other two matrices. It is therefore unlikelythat these mutations were creating a new ribosome binding site.Interestingly, analysis of the mutated sequence by the w51 matrixgave a positive score to a site seven bases upstream of the falsestart site, and the primer extension inhibition analysis (Fig.4) revealed a minor toeprint at that site.

Translational initiation at the false start. We fused lacZ to the false start reading frame two ways (Fig. 5). First, we deleted the first two bases, TG, of the stop codonof the false start reading frame so that this reading frame, insteadof ending, was fused to the remainder of the uncB reading frame.The resultant plasmid, pSRM114, is therefore identical to pKS104except for a mutation which disrupts the true uncB reading frameat the stop codon for the false start reading frame. Second, wefused lacZ in frame directly to the false start initiation codonto create pWSB52. $beta$ -Galactosidase activity produced by eitherof these two constructions probably results either from translationinitiation at the false start or ribosomal frameshifting at thefalse start. We compared the $beta$ -galactosidase activities producedin unc-deleted cells carrying pKS104, pSRM114, or pWSB52. Thetrue uncB'-'lacZ fusion plasmid pKS104 produces between 200 and600 U of activity in cells grown on minimal medium containingantibiotic. (Measurements of activity produced by high-copy-numberplasmids produce a much wider range of activities than those producedby single-copy lysogens.) Cells carrying plasmid pSRM114 produce10 to 20 U, and cells carrying pWSB52 produce 50 to 60 U underthe same conditions. When the false start codon in pWSB52 wasmutagenized to an ACG, the $beta$ -galactosidase activity produced fromthe resultant multicopy plasmid dropped by an average of 70%.Although this decrease confirms that translation is initiatedat this site, the fact that activity was not completely abolishedindicates that additional factors contribute substantially toribosome frameshifting and/or reinitiation at this site.

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FIG. 5. Plasmid constructions which fuse lacZ to the false start reading frame. The top line shows the unmutagenized region of the false start in the uncB'-'lacZ fusion gene found in pKS104 (see Fig. 1 and 2 for more detail). In plasmid pSRM114, the termination codon of the false start reading frame is eliminated, and the false start reading frame is fused in frame to the uncB reading frame. Plasmid pWSB52 consists of lacZ fused directly to the false start initiation codon. The details of these constructions are given in Materials and Methods. Ribosomes initiating at the true uncB initiation codon terminate 31 codons downstream of the deletion in pSRM114 and 6 codons after the indicated sequence in pWSB52.

When the fusion in pWSB52 was moved into $lambda$ to create single-copy lysogens, it produced very low but non-zero activity in ournormal assay, approximately 5 to 10% of the activity producedby the $lambda$ pKS104 lysogen. The single-copy activity produced fromthe SRM114 construction was too low to measure.

As a further demonstration that ribosomes recognize the false start site in vivo, we analyzed whole-cell lysates of MC1000 $Delta$ (uncI-uncC) carrying the three fusion plasmids pKS104, pSRM114,and pWSB52 by immunoblotting with anti- $beta$ -galactosidase (Promega).The results are shown in Fig. 6. Lane 1 contains the productsof pKS104. The full-length uncB'-'lacZ product is clearly visibleas the highest-molecular-weight band. As is often observed with $beta$ -galactosidase fusion proteins, all three lysates contain a significantamount of the $beta$ -galactosidase moiety alone, which probably resultsfrom proteolysis at or near the fusion joint. Lane 2 containsthe products of pSRM114. The product visible as the top band,which is the same size as the fusion protein produced by pKS104,could be produced only by translational initiation at the trueuncB start codon and ribosomal frameshifting in the vicinity ofthe false start reading frame. Compared to pKS104, pSRM114 alsoproduces an additional fusion protein (lane 2). This additionalprotein is the correct size for a fusion protein that was initiatedat the false start initiation codon. Since this band is not visibleat all in the products of pKS104, it is unlikely to be a proteolysisproduct of the full-length fusion protein. The fusion proteinmade from pWSB52 (lane 3) would be the same size as the $beta$ -galactosidasemoiety produced by cleavage at the fusion joint of the other full-lengthfusion proteins, if translation were to initiate at the falsestart. The higher-molecular-weight protein produced by pWSB52(lane 3) is the correct size for the product of the true uncBtranslational start site frameshifted at the false start. Therelatively small difference in molecular weight between this frameshiftedprotein produced by pWSB52 and the protein initiating at the falsestart in pSRM114 would not be detectable on these gels (~5,500difference in proteins with a molecular weight of >125,000), especiallyconsidering that the a subunit is known to migrate anomalouslyin SDS gels. These results support the conclusion that ribosomescan recognize the false start site in vivo and that this siteprobably produces both ribosomal frameshifting and translationalinitiation.

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FIG. 6. Immunoblots of fusion proteins. Lysates were prepared from E. coli MC1000 $Delta$ (uncI-uncC) (1) carrying either pKS104, pSRM114, or pWSB52 as described in Materials and Methods. The pKS104 culture was grown in a 25-ml volume; the other two were grown in 250 ml. Unlysed cells were removed by centrifugation, and the supernatant fractions were loaded onto an SDS-7% polyacrylamide gel. Electrophoresis and immunoblotting, with anti- $beta$ -galactosidase (Promega), were carried out as described previously (3). The samples and amounts loaded were as follows: pKS104, 12 µg (lane 1); pSRM114, 250 µg (lane 2); pWSB52, 250 µg (lane 3). Lanes 2 and 3 therefore contained 20 times as much total protein as lane 1. The top band in lane 1 is the full-length fusion protein coded for by pKS104; it consists of most of the a subunit fused in frame to $beta$ -galactosidase. The top band in lane 2 is the same-size protein, which could result only from a frameshift at the false start of ribosomes which had initiated at the true uncB translation start site. The second band (arrow) in lane 2 represents a lac fusion protein initiated at the false start site. The top band (arrow) in lane 3 is the proper size for a protein initiated at the true uncB translational start site and fused to lacZ by frameshifting at the false start. The second bands in lanes 1 and 2 represent the $beta$ -galactosidase moiety (BG) derived from proteolysis of each fusion protein at the fusion joint. The equivalent band in lane 3 probably represents the fusion protein derived from translational initiation at the false start together with the $beta$ -galactosidase moiety derived from proteolysis of the higher-molecular-weight fusion protein at the fusion joint.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The uncB gene codes for the a subunit, which is present in 1 copy per ATPase complex. This subunit is the most complex transmembranesubunit in the F_o, and several residues are believed to be involvedin proton translocation across the membrane (23, 27). However,the a subunit alone has been demonstrated to be harmful to growingcells. Overexpression of uncB has been shown to have deleteriouseffects on cell growth (12, 28). Studies on expression ofthe first three genes of the operon have shown that the a subunitis synthesized more poorly than the c subunit, which is encodedby uncE, even though translation initiation levels of uncB anduncE appear to be comparable (14, 25). The relatively lowrate of expression of uncB is not well understood. Studies ofthe unc transcript have shown that the mRNA transcript withinthe uncB cistron is more sensitive to cleavage and degradationthan most of the genes in the operon (13, 16, 20, 21),so even though uncB is preceded by a relatively strong translationinitiation region, the presence of sites of endonucleolytic attack,leading to specific mRNA degradation, might be responsible forthe relatively low level of synthesis of the a subunit. Additionally,we have shown that the mysterious uncI gene also plays a posttranslationinitiation role in controlling expression of uncB (9). Thestudies described here suggest an additional or alternative controlmechanism to explain the relatively low level of synthesis ofthe a subunit despite its apparent high rate of translationalinitiation. Perceptron matrices were trained to analyze nucleotidesequences for potential ribosome binding sites. Analysis of theunc operon by these matrices identified a potential strong ribosomebinding site within uncB, frameshifted one base relative to theuncB reading frame. Elimination of the false start AUG at thisinternal ribosome binding site resulted in increased expressionof the late uncB'-'lacZ fusion gene, so this site clearly hasa significant effect on uncB expression, even though its eliminationdoes not increase expression of the KS104 fusion to the levelmeasured for the DKWH103 fusion. Both the CAC and CAU histidinecodons are present with equal frequencies in E. coli genes (29),so the effect probably does not result from altered codon usage.The experiments presented here demonstrate that this region iscapable of forming an initiation complex with ribosomes, althoughit was necessary to mutagenize the mRNA secondary structure aroundthis site before such an in vitro complex could be observed. Finally,fusing this alternative ribosome binding site to lacZ in frameproduced $beta$ -galactosidase activity in vivo from multicopy plasmids,and immunoblot analysis of the resultant fusion proteins showsthat both ribosomal frameshifting and translational initiationoccur at the false start.

This ribosome binding site obviously exerts some effect on the expression of uncB, and it appears to do so through recognitionby ribosomes. These studies do not address the mechanism of actionof this site, although we can speculate that ribosomes stall atthis site due to either the frameshifted ribosome binding site,the mRNA secondary structure, or both. No toeprint is observedon RNA carrying the wild type sequence, so it is unlikely thatunbound ribosomes initiate translation at this site. The low rateof expression of lac fusions to the false start ribosome bindingsite also indicates that ribosomes frameshift and initiate translationat this site poorly. The effect of this site on uncB expressionmay involve a relationship between translation and mRNA breakdown.The uncB mRNA has been shown to be more susceptible to degradationthan other cistrons in the operon (13, 16, 20, 21). Ithas been demonstrated by Chevrier-Miller et al. (4) that uncouplingof transcription and translation leads to differential mRNA half-livesof lacZ mRNA. These authors proposed that inefficient ribosomeloading might unwind the RNA without protecting it, making suchRNA less stable than untranslated RNA. In studies of RNaseE cleavageof mRNA, Gross (7) has speculated that RNase recognition ofmRNA requires some undefined interactions of mRNA with ribosomes,so that only translated mRNA is susceptible to degradation. Itis therefore possible that the translational false start identifiedin these experiments might affect either the number of ribosomesthat complete the translation of uncB, the sensitivity of theuncB message to endonucleolytic degradation, or both.

	ACKNOWLEDGMENTS

This research was supported by National Science Foundation grant DMB-9096159 and by American Heart Association grant-in-aid93007730. S.R.M. was supported by grant 7620010 from the AmericanHeart Association, Maryland Affiliate.

We thank Heven Sze of the Department of Botany and Tomas Kempe of the Protein and Nucleic Acid Synthesis Laboratory, bothat the University of Maryland. We also thank Larry Gold of theDepartment of Molecular, Cellular, and Developmental Biology atthe University of Colorado for the use of his laboratory for thetoeprinting and Robert Traut of the University of California,Davis, for generously providing purified 30S ribosomes.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biochemistry and Molecular Biology, Wayne State University School ofMedicine, Scott Hall, 540 E. Canfield Ave., Detroit, MI 48201.Phone: (313) 577-6659. Fax: (313) 577-2765. E-mail: wbrusilow{at}med.wayne.edu.

Present address: U.S. Environmental Protection Agency, Washington, DC 20460.

Present address: Sidney Kimmel Cancer Center, San Diego, CA 92121.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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12. Kanazawa, H., T. Kiyasu, T. Noumi, and M. Futai. 1984. Overproduction of subunit a of the F_o component of proton-translocating ATPase inhibits growth of Escherichia coli cells. J. Bacteriol. 158:300-306[Abstract/Free Full Text].

13. Lagoni, O. R., K. von Meyenberg, and O. Michelsen. 1993. Limited differential mRNA inactivation in the atp (unc) operon of Escherichia coli. J. Bacteriol. 175:5791-5797[Abstract/Free Full Text].

14. Lang, V., C. Gualerzi, and J. E. G. McCarthy. 1989. Ribosomal affinity and translational initiation in Escherichia coli. J. Mol. Biol. 210:659-663[Medline].

15. McCarthy, J. E. G., and C. Bokelman. 1988. Determinants of translational initiation efficiency in the atp operon of Escherichia coli. Mol. Microbiol. 2:455-465[Medline].

16. McCarthy, J. E. G., B. Gerstel, B. Surin, U. Wiedeman, and P. Ziemke. 1991. Differential gene expression from the Escherichia coli atp operon mediated by segmental differences in mRNA stability. Mol. Microbiol. 5:2447-2458[Medline].

17. Miller, J. H. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

18. Nakamoto, R. K. 1996. Mechanisms of active transport in the F_oF₁ ATP synthase. J. Membr. Biol. 151:101-111[Medline].

19. Nielsen, J., F. G. Hansen, J. Hoppe, P. Friedl, and K. von Meyenburg. 1981. The nucleotide sequence of the atp genes coding for the F_o subunits a, b, c, and the F₁ subunit $delta$ of the membrane bound ATP synthase of Escherichia coli. Mol. Gen. Genet. 184:33-39[Medline].

20. Patel, A., and S. D. Dunn. 1992. RNase E-dependent cleavages in the 5' and 3' regions of the Escherichia coli unc mRNA. J. Bacteriol. 174:3541-3548[Abstract/Free Full Text].

21. Patel, A., and S. D. Dunn. 1995. Degradation of the Escherichia coli uncB mRNA by multiple endonucleolytic cleavages. J. Bacteriol. 177:3917-3922[Abstract/Free Full Text].

22. Schaefer, E. M., D. Hartz, L. Gold, and R. D. Simoni. 1989. Ribosome-binding sites and RNA processing sites in the transcript of the Escherichia coli unc operon. J. Bacteriol. 171:3901-3908[Abstract/Free Full Text].

23. Senior, A. E. 1990. The proton-translocating ATPase of Escherichia coli. Annu. Rev. Biophys. Biophys. Chem. 19:7-41[Medline].

24. Silhavy, T. J., M. L. Berman, and L. W. Enquist. 1984. Experiments with gene fusions. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

25. Solomon, K. A., D. K. W. Hsu, and W. S. A. Brusilow. 1989. Use of lacZ fusions to measure in vivo expression of the first three genes of the Escherichia coli unc operon. J. Bacteriol. 171:3039-3045[Abstract/Free Full Text].

26. Stormo, G. D., T. D. Schneider, L. Gold, and A. Ehrenfeucht. 1982. Use of the `Perceptron' algorithm to distinguish translational initiation sites in E. coli. Nucleic Acids Res. 10:2997-3011[Abstract/Free Full Text].

27. Vik, S. B., and B. J. Antonio. 1994. A mechanism of proton translocation by F₁F_o ATP synthases suggested by double mutants of the a subunit. J. Biol. Chem. 269:30364-30369[Abstract/Free Full Text].

28. von Meyenburg, K., B. B. Jørgensen, O. Michelsen, L. Sørensen, and J. E. G. McCarthy. 1985. Proton conduction by subunit a of the membrane-bound ATP synthase of Escherichia coli revealed after induced overproduction. EMBO J. 4:2357-2363[Medline].

29. Wada, K., S. Aota, R. Tsuchiya, F. Ishibashi, T. Gojobori, and T. Ikemura. 1990. Codon usage tabulated from the GenBank genetic sequence data. Nucleic Acids Res. 18:2367-2368.

30. Zuker, M. 1989. On finding all suboptimal foldings of an RNA molecule. Science 244:48-52[Abstract/Free Full Text].

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Appl. Environ. Microbiol.	Infect. Immun.	Eukaryot. Cell
Mol. Cell. Biol.	J. Virol.	Microbiol. Mol. Biol. Rev.
	ALL ASM JOURNALS

1.	Angov, E., and W. S. A. Brusilow. 1988. Use of lac fusions to measure in vivo regulation of expression of Escherichia coli proton-translocating ATPase (unc) genes. J. Bacteriol. 170:459-462[Abstract/Free Full Text].
2.	Brusilow, W. S. A., D. J. Klionsky, and R. D. Simoni. 1982. Differential polypeptide synthesis of the proton-translocating ATPase of Escherichia coli. J. Bacteriol. 151:1363-1371[Abstract/Free Full Text].
3.	Brusilow, W. S. A. 1987. Proton leakiness caused by cloned genes for the F_o sector of the proton-translocating ATPase of Escherichia coli. J. Bacteriol. 169:4984-4990[Abstract/Free Full Text].
4.	Chevrier-Miller, M., N. Jacques, O. Raibaud, and M. Dreyfus. 1990. Transcription of single-copy hybrid lacZ genes by T7 RNA polymerase in Escherichia coli: mRNA synthesis and degradation can be uncoupled from translation. Nucleic Acids Res. 18:5787-5792[Abstract/Free Full Text].
5.	Foster, D. L., and R. H. Fillingame. 1982. Stoichiometry of subunits in the H⁺-ATPase complex of Escherichia coli. J. Biol. Chem. 257:2009-2015[Abstract/Free Full Text].
6.	Futai, M., T. Noumi, and M. Maeda. 1989. ATP synthase (H⁺-ATPase): results by combined biochemical and molecular biological approaches. Annu. Rev. Biochem. 58:111-136[Medline].
7.	Gross, G. 1991. RNaseE cleavage in the atpE leader region of atpE/interferon- $beta$ hybrid transcript in Escherichia coli causes enhanced rates of mRNA decay. J. Biol. Chem. 266:17880-17884[Abstract/Free Full Text].
8.	Hartz, D., D. S. McPheeters, and L. Gold. 1989. Selection of the initiator tRNA by Escherichia coli initiation factors. Genes Dev. 3:1899-1912[Abstract/Free Full Text].
9.	Hsu, D. K. W., and W. S. A. Brusilow. 1995. Effects of uncI on expression of uncB, the gene coding for the a subunit of the F₁F_o ATPase of Escherichia coli. FEBS Lett. 371:127-131[Medline].
10.	Jaeger, J. A., D. H. Turner, and M. Zucker. 1989. Improved predictions of secondary structures for RNA. Proc. Natl. Acad. Sci. USA 86:7706-7710[Abstract/Free Full Text].
11.	Jaeger, J. A., D. H. Turner, and M. Zucker. 1990. Predicting optimal and suboptimal secondary structures for RNA. Methods Enzymol. 183:281-306[Medline].
12.	Kanazawa, H., T. Kiyasu, T. Noumi, and M. Futai. 1984. Overproduction of subunit a of the F_o component of proton-translocating ATPase inhibits growth of Escherichia coli cells. J. Bacteriol. 158:300-306[Abstract/Free Full Text].
13.	Lagoni, O. R., K. von Meyenberg, and O. Michelsen. 1993. Limited differential mRNA inactivation in the atp (unc) operon of Escherichia coli. J. Bacteriol. 175:5791-5797[Abstract/Free Full Text].
14.	Lang, V., C. Gualerzi, and J. E. G. McCarthy. 1989. Ribosomal affinity and translational initiation in Escherichia coli. J. Mol. Biol. 210:659-663[Medline].
15.	McCarthy, J. E. G., and C. Bokelman. 1988. Determinants of translational initiation efficiency in the atp operon of Escherichia coli. Mol. Microbiol. 2:455-465[Medline].
16.	McCarthy, J. E. G., B. Gerstel, B. Surin, U. Wiedeman, and P. Ziemke. 1991. Differential gene expression from the Escherichia coli atp operon mediated by segmental differences in mRNA stability. Mol. Microbiol. 5:2447-2458[Medline].
17.	Miller, J. H. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
18.	Nakamoto, R. K. 1996. Mechanisms of active transport in the F_oF₁ ATP synthase. J. Membr. Biol. 151:101-111[Medline].
19.	Nielsen, J., F. G. Hansen, J. Hoppe, P. Friedl, and K. von Meyenburg. 1981. The nucleotide sequence of the atp genes coding for the F_o subunits a, b, c, and the F₁ subunit $delta$ of the membrane bound ATP synthase of Escherichia coli. Mol. Gen. Genet. 184:33-39[Medline].
20.	Patel, A., and S. D. Dunn. 1992. RNase E-dependent cleavages in the 5' and 3' regions of the Escherichia coli unc mRNA. J. Bacteriol. 174:3541-3548[Abstract/Free Full Text].
21.	Patel, A., and S. D. Dunn. 1995. Degradation of the Escherichia coli uncB mRNA by multiple endonucleolytic cleavages. J. Bacteriol. 177:3917-3922[Abstract/Free Full Text].
22.	Schaefer, E. M., D. Hartz, L. Gold, and R. D. Simoni. 1989. Ribosome-binding sites and RNA processing sites in the transcript of the Escherichia coli unc operon. J. Bacteriol. 171:3901-3908[Abstract/Free Full Text].
23.	Senior, A. E. 1990. The proton-translocating ATPase of Escherichia coli. Annu. Rev. Biophys. Biophys. Chem. 19:7-41[Medline].
24.	Silhavy, T. J., M. L. Berman, and L. W. Enquist. 1984. Experiments with gene fusions. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
25.	Solomon, K. A., D. K. W. Hsu, and W. S. A. Brusilow. 1989. Use of lacZ fusions to measure in vivo expression of the first three genes of the Escherichia coli unc operon. J. Bacteriol. 171:3039-3045[Abstract/Free Full Text].
26.	Stormo, G. D., T. D. Schneider, L. Gold, and A. Ehrenfeucht. 1982. Use of the `Perceptron' algorithm to distinguish translational initiation sites in E. coli. Nucleic Acids Res. 10:2997-3011[Abstract/Free Full Text].
27.	Vik, S. B., and B. J. Antonio. 1994. A mechanism of proton translocation by F₁F_o ATP synthases suggested by double mutants of the a subunit. J. Biol. Chem. 269:30364-30369[Abstract/Free Full Text].
28.	von Meyenburg, K., B. B. Jørgensen, O. Michelsen, L. Sørensen, and J. E. G. McCarthy. 1985. Proton conduction by subunit a of the membrane-bound ATP synthase of Escherichia coli revealed after induced overproduction. EMBO J. 4:2357-2363[Medline].
29.	Wada, K., S. Aota, R. Tsuchiya, F. Ishibashi, T. Gojobori, and T. Ikemura. 1990. Codon usage tabulated from the GenBank genetic sequence data. Nucleic Acids Res. 18:2367-2368.
30.	Zuker, M. 1989. On finding all suboptimal foldings of an RNA molecule. Science 244:48-52[Abstract/Free Full Text].