A Highly Conserved Sequence in the 3'-Untranslated Region of the Drosophila Adh Gene Plays a Functional Role in Adh Expression

A Highly Conserved Sequence in the 3'-Untranslated Region of the Drosophila Adh Gene Plays a Functional Role in Adh Expression

John Parsch^1,a,b, Wolfgang Stephan^1,b, and Soichi Tanda^b
^a Molecular and Cell Biology Program, University of Maryland, College Park, Maryland 20742
^b Department of Biology, University of Maryland, College Park, Maryland 20742

Corresponding author: John Parsch, Department of Biology, University of Rochester, Rochester, NY 14627-0211., jnph{at}troi.cc.rochester.edu (E-mail)

Communicating editor: A. G. CLARK

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Phylogenetic analysis identified a highly conserved eight-basesequence (AAGGCTGA) within the 3'-untranslated region (UTR)of the Drosophila alcohol dehydrogenase gene, Adh. To examinethe functional significance of this conserved motif, we performedin vitro deletion mutagenesis on the D. melanogaster Adh genefollowed by P-element-mediated germline transformation. Deletionof all or part of the eight-base sequence leads to a twofoldincrease in in vivo ADH enzymatic activity. The increase inactivity is temporally and spatially general and is the resultof an underlying increase in Adh transcript. These results indicatethat the conserved 3'-UTR motif plays a functional role in thenegative regulation of Adh gene expression. The evolutionarysignificance of our results may be understood in the contextof the amino acid change that produces the ADH-F allele andalso leads to a twofold increase in ADH activity. While thereis compelling evidence that the amino acid replacement has beena target of positive selection, the conservation of the 3'-UTRsequence suggests that it is under strong purifying selection.The selective difference between these two sequence changes,which have similar effects on ADH activity, may be explainedby different metabolic costs associated with the increase inactivity.

THE Drosophila alcohol dehydrogenase enzyme (ADH; EC 1.1.1.1)and the gene that encodes it, Adh, have been used as a modelsystem for many studies of population genetics, molecular evolution,and molecular biology. ADH is responsible for the detoxificationof environmental alcohols (DAVID et al. 1976 ), and flies lackingADH activity cannot survive in environments containing moderatelevels of alcohol (GIBSON and OAKESHOTT 1982 ; VAN DELDEN 1982). ADH also plays an important role in the metabolism of ethanolinto energy-storage lipids, particularly at the larval stage(GEER et al. 1986 , GEER et al. 1991 ). In D. melanogaster,Adh produces two developmentally regulated transcripts thatdiffer in their 5'-untranslated leaders but are identical intheir protein-encoding regions and 3'-untranslated regions (UTRs)(BENYAJATI et al. 1983 ). Transcripts from a distal promoterare found predominantly in adult tissues, while those from aproximal promoter are found predominantly in larval tissues(BENYAJATI et al. 1983 ; SAVAKIS et al. 1986 ). Experimentsusing P-element-mediated germline transformation have shownthat all cis-acting sequence elements required for proper Adhexpression are contained within an 8.6-kb SacI-ClaI fragment,which contains the entire Adh mRNA-encoding region and ~5 kbof 5' flanking sequence (upstream from the distal promoter)and 1 kb of 3' flanking sequence (GOLDBERG et al. 1983 ; LAURIE-AHLBERGand STAM 1987 ).

Two forms of the ADH protein, designated as Fast (ADH-F) andSlow (ADH-S), which differ by a single amino acid (FLETCHERet al. 1978 ), have been found at high frequency in worldwidepopulations of D. melanogaster (OAKESHOTT et al. 1982 ). Inaddition, numerous polymorphisms have been detected at silentand noncoding sites within the Adh gene (KREITMAN 1983 ; LAURIEet al. 1991 ). ADH-F homozygotes have, on average, two- to threefoldhigher levels of enzymatic activity than ADH-S homozygotes.This difference is due to two factors, an increase in catalyticefficiency of the ADH enzyme and an increase in the total amountof enzyme in ADH-F flies (CHOUDHARY and LAURIE 1991 ). Experimentsusing site-directed mutagenesis and P-element-mediated germlinetransformation have shown that the Fast/Slow polymorphic siteis responsible for the difference in ADH catalytic activitybetween ADH-F and ADH-S flies (CHOUDHARY and LAURIE 1991 ).This site, however, has no effect on in vivo concentration ofADH protein, which suggests that other, nonreplacement sitesmust also play an important role in determining Adh expressionlevels. For example, a complex nucleotide substitution withinthe first (adult) Adh intron has been shown to have a significanteffect on ADH activity levels (LAURIE and STAM 1994 ). Interestingly,this intronic sequence has no effect on the concentration ofAdh mRNA, suggesting that there may be an interaction betweenthis region of the first intron and other regions of the pre-mRNAduring polyadenylation or other processing events that resultsin a change in the translational efficiency of the mature mRNA(LAURIE and STAM 1994 ). Other nonreplacement sites that affectlevels of Adh expression have been mapped to the protein-encodingregion and the 3'-UTR, but have not yet been tested by mutationalanalysis (STAM and LAURIE 1996 ).

Phylogenetic analysis has been used to identify noncoding regionsof the Adh gene that may play a functional role in Adh expression. KIRBY et al. 1995 used the phylogenetic-comparative methodto predict secondary structures of the Adh pre-mRNA and suggestthat the patterns of linkage disequilibrium found within theAdh gene of D. pseudoobscura (SCHAEFFER and MILLER 1993 ) arethe result of epistatic selection maintaining RNA pairing stemswithin intron sequences. Phylogenetic analysis has also identifiedseveral short-range RNA pairing stems within the Adh exon 2,as well as two long-range pairings between exon 2 and a highlyconserved region of the 3'-UTR (PARSCH et al. 1997 ). The functionalsignificance of one of these long-range pairings was testedby mutational analysis in D. melanogaster (PARSCH et al. 1997). A site-directed mutation at a silent third-codon positionof exon 2, which disrupted a Watson-Crick base pair in the proposedlong-range pairing, resulted in a significant reduction in adultADH activity level. ADH activity was restored to wild-type levelsby a second, "compensatory" mutation in the 3'-UTR. The 3'-UTRmutation by itself, however, had no measurable effect on ADHactivity levels. Thus, these observations do not fit a simplemodel of compensatory evolution (PARSCH et al. 1997 ).

To explore the possible cause of this discrepancy and furtherexamine the role of phylogenetically conserved sequence elementson Adh expression, we investigated a highly conserved sequencelocated just downstream of the nucleotide site where the single3'-UTR mutation was made. The high level of conservation withinthis region suggests that it may have a function that is distinctfrom that of the proposed RNA secondary structure. To test thishypothesis, in vitro deletion mutagenesis and P-element-mediatedgermline transformation were used to examine the effects ofspecific deletions within the conserved 3'-UTR sequence on ADHactivity and Adh mRNA levels in D. melanogaster. The resultsindicate that deletion of the conserved 3'-UTR motif leads toa significant increase in in vivo ADH activity. Since the ADHprotein-encoding sequence was not altered during mutagenesis,the observed increase in enzymatic activity must be the resultof an increase in Adh gene expression. Thus, the conserved 3'-UTRsequence plays a functional role in the negative regulationof Adh expression.

MATERIALS AND METHODS

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Plasmid construction and mutagenesis:
Basic molecular techniques were carried out following the methodsof SAMBROOK et al. 1989 . All Adh constructs were derived froman 8.6-kb SacI-ClaI fragment of the D. melanogaster Wa-f allele[originally described by KREITMAN 1983 ]. A pUC18 plasmid containingthe entire Adh mRNA-encoding region within a 3.2-kb SalI-ClaIfragment (PARSCH et al. 1997 ) was used for mutagenesis followingthe QuikChange (Stratagene, La Jolla, CA) procedure. Followingmutagenesis, a BamHI-ClaI restriction fragment containing eachmutant 3'-UTR was used to replace the corresponding fragmentin the original 8.6-kb SacI-ClaI clone. At this point, the entireBamHI-ClaI region subjected to mutagenesis was sequenced usinga cycle sequencing method (Life Technologies) to ensure thatthe desired mutation (and no other changes) was present.

P-element-mediated germline transformation:
The entire 8.6-kb Adh SacI-ClaI fragment of each mutant constructwas inserted into the polycloning region of the YES transformationvector, which contains the D. melanogaster yellow (y) gene asa selectable marker (PATTON et al. 1992 ). Germline transformationof an ADH-null D. melanogaster y w; Adh^fn6 ${Delta}$ 2-3,Sb/TM6 stock wasachieved by embryo microinjection (RUBIN and SPRADLING 1982; SPRADLING and RUBIN 1982 ). At least four independent insertionlines were generated through embryo microinjection for eachmutant construct. Additional transformed lines were then generatedby mobilization of the YES vector constructs within the originallines through genetic crosses, using the ${Delta}$ 2-3 P element as asource of transposase (ROBERTSON et al. 1988 ; PARSCH et al.1997 ). Transformants containing the wild-type 8.6-kb Adh Wa-fgenomic fragment were used as a control (PARSCH et al. 1997).

Previous experiments indicated that expression levels of Adhinsertions on the X chromosome may be increased due to dosagecompensation mechanisms in Drosophila (LAURIE-AHLBERG and STAM1987 ; PARSCH et al. 1997 ). For this reason, only autosomalinsertion lines were used for analysis. X chromosome insertionlines were identified as those that produced only y⁺ female(and only y^- male) offspring when transformant males were matedto females of a y w, Adh^fn6 stock. Furthermore, to ensure thatthe transformed lines contained only a single Adh insertion,a Southern blot was performed on genomic DNA prepared from eachtransformed line. The genomic DNA was digested with three six-cutterrestriction enzymes (BglII, SalI, and StuI) and hybridized witha probe derived from the Adh 5' flanking region (PARSCH et al.1997 ). The probe hybridizes to a fragment of constant sizefor the genomic Adh gene and a fragment of unique size for eachAdh insertion. A total of 30 independent, autosomal single-insertlines were used for ADH assays, consisting of the wild-type(10), ${Delta}$ 1762–1765 (9), ${Delta}$ 1766–1769 (4), and ${Delta}$ 1762–1769(7) transformant classes.

ADH assays:
ADH enzymatic activity was measured following the procedureof MARONI 1978 , using isopropanol as the substrate. For analysisof adult ADH activity, five 6- to 8-day-old males heterozygouswith respect to the Adh insertion were used (PARSCH et al. 1997). Units of ADH activity were measured as micromoles of NADreduced per minute per milligram of total protein. Total proteinwas estimated using the method of LOWRY et al. 1951 . Differencesin ADH activity between mutant and wild-type transformants weretested by analysis of variance (ANOVA) using a model that accountsfor position effects within each transformant class (LAURIE-AHLBERGand STAM 1987 ).

ADH activity levels were measured for different developmentalstages and parts of the body using the above method, with thefollowing modifications: For embryonic and larval assays, transformantshomozygous for the appropriate Adh insertion were crossed toa y w; Adh^fn6 stock to produce offspring heterozygous with respectto Adh insertion. Freshly laid eggs were collected ~1 hr afteroviposition and incubated for an additional 19 hr at room temperature.A total of 40 20-hr heterozygous embryos were used for eachADH assay. Larval assays were performed on preparations of 20heterozygous larvae collected at each instar stage. For bodypart assays, 20 6- to 8-day-old heterozygous males were dissectedand preparations from head, legs, thorax, and abdomen were usedfor separate ADH assays.

Analysis of Adh mRNA levels:
Individual wild-type and ${Delta}$ 1762–1765 transformed lines exhibitingADH activities typical of their respective transformant classwere subjected to quantitative Northern blot analysis. TotalRNA was prepared from 10, 6- to 8-day-old males heterozygousfor the Adh insertion using TRIzol reagent (Life Technologies)and following the manufacturer's protocol. Northern blottingwas performed as descibed in SAMBROOK et al. 1989 , with ~0.5µg of RNA loaded into each lane of the gel. The Adh probewas prepared from a PCR product spanning bases 739–1924of the Wa-f allele (KREITMAN 1983 ) and was labeled with [³²P]dATPusing the RadPrime DNA labeling system (Life Technologies).As a control for equal sample loading, the blot was simultaneouslyhybridized with a probe prepared from a genomic clone of theD. melanogaster Dras2 gene (BISHOP and CORCES 1988 ). The Adhprobe detects a transcript of 1.1 kb, while the Dras2 probedetects a transcript of 1.6 kb. Relative estimates of Adh mRNAlevels were obtained by scanning densitometry using the AlphaImager 2000 (Alpha Innotech Corporation). Because of the highconcentration of Adh mRNA relative to Dras2 mRNA, two separateexposures of the same filter were used for mRNA quantitation.A short exposure (20 min) was used for Adh, while a longer (2-hr)exposure was used for Dras2. All exposures were carried outat -80° using BioMax (Eastman Kodak, Rochester, NY) filmwith the manufacturer's intensifying screen.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

3'-UTR sequence organization:
Previous phylogenetic analysis has identified a completely conservedsequence within the 3'-UTR of Adh sequences from 10 differentDrosophila species spanning three subgenera (PARSCH et al. 1997). The sequence consists of 8 bases (AAGGCTGA). Of the 8 bases(AAGTCTGA), 7 are conserved in the Adh-2 sequence of the Mediterraneanfruit fly, Ceratitis capitata. In all cases, the highly conservedsequence is located between the stop codon and the polyadenylationsignal. The length of sequence separating these landmarks, however,varies among species. Species from the subgenus Sophophora,as well as D. hydei and D. mulleri from the subgenus Drosophila,show a similar sequence organization (Figure 1). In these species,the highly conserved 8-base sequence is located 74–115bases downstream of the stop codon and 24–45 bases upstreamof the polyadenylation signal. The two Hawaiian species fromthe subgenus Drosophila (D. affinidisjuncta and D. silvestris)have a very different organization of their 3'-UTRs. In thesetwo species, the conserved 8-base motif is located much fartherfrom the stop codon (236–240 bases) and much closer tothe polyadenylation signal (6–7 bases). The D. lebanonensis3'-UTR is similar to that of the Sophophora species, thoughthe distance between the conserved 8-base sequence and the polyadenylationsite is greater (82 bases). The medfly sequence resembles theSophophora sequences in its distance between the stop codonand the conserved 8-base sequence (101 bases), but the distancebetween the conserved sequence and the polyadenylation signalis much shorter (4 bases) and is more similar to that foundin the Hawaiian species.

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Figure 1. Organization of the Adh 3'-UTR. The region depicted begins with the stop codon (leftmost solid box) and ends at the polyadenylation site. The highly conserved eight-base motif is shown as a hatched box and the polyadenylation signal is shown as a solid box. The separating sequences are shown as open boxes, drawn approximately to scale. mel, D. melanogaster; tei, D. teisseri; ere, D. erecta; psu, D. pseudoobscura; amb, D. ambigua; hyd, D. hydei; mul, D. mulleri; aff, D. affinidisjuncta; sil, D. silvestris; leb, D. lebanonensis; med, Ceratitis capitata.

Deletion analysis of the highly conserved 3'-UTR sequence:
To test the functional significance of the highly conserved3'-UTR sequence, in vitro deletion mutagenesis was performedon the wild-type D. melanogaster Adh gene. Three separate deletionswere made within the conserved eight-base sequence: ${Delta}$ 1762–1765,which deleted the first four bases of the eight-base motif; ${Delta}$ 1766–1769, which deleted the last four bases; and ${Delta}$ 1762–1769,which deleted the entire eight-base sequence. The mutant constructswere introduced into the D. melanogaster genome through P-element-mediatedgermline transformation, and the ADH activity of the transgenicflies was measured spectrophotometrically as micromoles of NADreduced per minute per milligram of total protein (multipliedby 100). For all three deletion constructs, there was a greaterthan twofold increase in ADH activity relative to transformedlines containing the wild-type Adh gene (Figure 2). The averageADH activity of wild-type transformants was 103.2 units. Theaverage activities of ${Delta}$ 1762–1765, ${Delta}$ 1766–1769, and ${Delta}$ 1762–1769transformants were 226.9, 219.1, and 220.3 units, respectively.The difference in ADH activity level was highly significant(P < 0.001) for comparisons of all deletion lines with wildtype. There were, however, no significant differences in activitylevels among transformants containing the three deletion constructs.Thus, deletion of all or part of the highly conserved eight-basesequence has the same effect in increasing ADH activity. Underthe assumption that the three deletions are functionally equivalent,we chose to focus on one of the deletions ( ${Delta}$ 1762–1765, forwhich we had the greatest number of transformed lines) and selecteda line that showed an average level of ADH activity for itstransformant class for further characterization (see below).

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Figure 2. Average ADH activity of wild-type, ${Delta}$ 1762–1765, ${Delta}$ 1766–1769, and ${Delta}$ 1762–1769 transformed lines. Activity is given in units of micromoles of NAD reduced per minute per milligram of total protein (multiplied by 100). Error bars represent the least significant difference at the 5% level. Least significant differences were calculated for individual comparisons, with the activity of each mutant line being compared to wild type.

Developmental stage and body-part ADH activity:
Deletion of the highly conserved 3'-UTR sequence clearly leadsto a significant increase in adult ADH activity (Figure 2).To determine whether or not this increase is present at differentdevelopmental stages, we performed additional ADH assays oneggs, larvae, and adults of wild-type and ${Delta}$ 1762–1765 transformants.The results are shown in Figure 3 and clearly indicate thatthere is an increase in ADH activity at all larval and adultstages. ADH activity could not be distinguished from backgroundduring the embryonic stage of either wild-type or ${Delta}$ 1762–1765lines (Figure 3). The overall developmental pattern of ADH expressionappears to be similar in both wild-type and ${Delta}$ 1762–1765 flies,with relatively low levels of ADH activity in larvae (slightlyincreased during second and third instar stages) and much higherlevels in adults. Although the ADH activity of ${Delta}$ 1762–1765transformants is greater than that of wild-type transformantsat all adult stages, the difference in activity level is notconstant throughout adult development (Figure 3). Within thefirst 3 days, both wild-type and ${Delta}$ 1762–1765 flies show thehighest levels of ADH activity. The difference between wild-typeand ${Delta}$ 1762–1765 activity is ~1.3-fold at these early adultstages. After day 3, the activity of both wild-type and ${Delta}$ 1762–1765transformants appears to level off and the difference in ADHactivity is approximately 2-fold (Figure 3). Such a developmentalpattern in activity level may be indicative of a negative regulatorymechanism in which one or more components are not fully expresseduntil later in development (after day 2).

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Figure 3. Average ADH activity of wild-type (hatched boxes) and ${Delta}$ 1762–1765 (solid boxes) transformants at different developmental stages. Activity was measured for eggs (E), first instar larvae (1L), second instar larvae (2L), third instar larvae (3L), and adults of various days of age (0–1, 1–2, 2–3, 4, 6, 8). Units of ADH activity are the same as in Figure 2. Error bars represent the range of activities observed at each developmental stage.

The ADH activity of various parts of the body was also examinedin order to determine whether deletion of the highly conserved3'-UTR sequence affected the spatial distribution of Adh expressionin adult flies. Activity was measured for preparations of head,legs, thorax, and abdomen from both wild-type and ${Delta}$ 1762–1765transformants (Figure 4). The results indicate that there isan increase in ADH activity in all ${Delta}$ 1762–1765 body partpreparations relative to wild type (Figure 4). This differencein activity level is roughly twofold for all preparations andis thus similar to the difference measured in whole adult flies(Figure 2).

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Figure 4. Average ADH activity of various body part preparations of wild-type (hatched boxes) and ${Delta}$ 1762–1765 (solid boxes) transformants. Adult flies (6–8 days of age) from each line were dissected and activity was measured separately for preparations from head, legs, thorax, and abdomen. Units of ADH activity are the same as in Figure 2. Activity is scaled by the total amount of soluble protein isolated from each preparation. Error bars represent the range of activities observed for each preparation.

Comparison of wild-type and mutant mRNA levels:
Northern blot analysis was used to estimate the levels of AdhmRNA in wild-type and ${Delta}$ 1762–1765 transformants. Figure5 shows the results of a Northern blot of two separate preparationsof total RNA from adult flies of each transformant class. Theblot was hybridized with an Adh probe, as well as a Dras2 probe,which served as a control for equal sample loading. Each probedetected only a single band corresponding to the mature transcriptof the appropriate size. The relative amount of Adh mRNA ineach lane was determined from band density (standardized bythe density of the Dras2 band in the same lane). Figure 5 indicatesthat there is a clear increase in Adh mRNA levels in ${Delta}$ 1762–1765transformants relative to wild type. The difference in Adh mRNAconcentration was estimated to be 2.4-fold; thus the increasein ADH activity in the 3'-UTR deletion lines (Figure 2) canbe accounted for by an underlying increase in Adh mRNA.

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Figure 5. Adh mRNA levels in wild-type (WT) and ${Delta}$ 1762–1765 ( ${Delta}$ ) transformants. Two separate preparations of total RNA from adult flies (6–8 days of age) of each transformant class were used for quantitative Northern blot analysis. The blot was hybridized with an Adh probe that detects a mature transcript of 1.1 kb. As a control, the blot was simultaneously hybridized with a Dras2 probe that detects a transcript of 1.6 kb. Relative amounts of Adh mRNA were estimated based on band density (corrected by the amount of total RNA in each lane). Because of the high concentration of Adh mRNA relative to Dras2 mRNA, two separate exposures of the same filter were used for mRNA quantitation (see MATERIALS AND METHODS). The ratio of Adh mRNA in ${Delta}$ 1762–1765 to wild-type transformants is 2.4:1.

DISCUSSION

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Noncoding regions of genes, such as introns and UTRs, typicallyshow much higher levels of sequence divergence than do protein-encodingregions (LI and GRAUR 1991 ). Such a pattern is found for theDrosophila Adh gene. The Adh protein-encoding region is sufficientlyconserved to allow for an unambiguous alignment of sequencesfrom within the genus Drosophila (SULLIVAN et al. 1990 ; PARSCHet al. 1997 ). The Adh noncoding regions, however, show toomuch divergence for unambiguous alignment across the entiregenus (SULLIVAN et al. 1990 ; PARSCH et al. 1997 ). In additionto the many nucleotide substitutions that have occurred withinthe 3'-UTR, there have also been numerous insertion/deletionevents. The result is that the overall 3'-UTR length variesfrom 152 to 293 bases within the genus.

Given the high level of DNA sequence divergence within the 3'-UTR,it is remarkable that a perfectly conserved eight-base sequencecan be found between the stop codon and the polyadenylationsignal in every Drosophila species analyzed (Figure 1). Themost distantly related Drosophila species are estimated to havediverged from a common ancestor 60 million years ago (AYALAet al. 1996 ; KWIATOWSKI et al. 1997 ). The sequence is alsoconserved (though not perfectly) in the Adh-2 sequence of theMediterranean fruit fly, which is estimated to have divergedfrom the Drosophila lineage 100 mya (AYALA et al. 1996 ; KWIATOWSKIet al. 1997 ). This high level of conservation suggests thatthe 3'-UTR sequence may be of functional significance, a hypothesisthat was tested experimentally using the techniques of in vitrodeletion mutagenesis and P-element-mediated germline transformation.

Deletion of the first four bases, the last four bases, or theentire eight-base sequence led to a significant increase inadult ADH activity relative to that of wild-type flies (Figure2), indicating that this sequence does play a functional rolein Adh gene expression. The activity increase was approximatelytwofold for each deletion construct and there was no significantdifference in ADH activity among transformants containing differentdeletion constructs (Figure 2). These results, along with thehigh level of sequence conservation, suggest that the entireeight-base motif must be intact for the sequence to functionproperly. It is possible, however, that certain substitutionswithin the eight-base consensus sequence do not disrupt function.This idea is supported by the observation that the eight-basemotif is not perfectly conserved in the medfly, though its effecton Adh expression in the medfly is unknown.

What molecular mechanism lies behind the twofold increase inADH activity caused by deletion of the conserved 3'-UTR sequence?Because deletion of the UTR sequence has no effect on the aminoacid sequence of the ADH protein, the difference in activitymust be the result of an increase in the amount of ADH protein.One possibility is that the 3'-UTR deletion mutations lead toa disruption of the Adh mRNA secondary structure. A portionof the conserved eight-base motif (bases 1762–1764) isinvolved in a phylogenetically predicted long-range pairingwith bases 810–812 of exon 2 (PARSCH et al. 1997 ). The810–812/1762–1764 pairing, however, appears to bequite weak in D. melanogaster, consisting of two AU base pairsand one GU wobble pair. Disruption by a mutation at site 819of a stronger long-range pairing (three GC pairs) between bases817 and 819/1756 and 1758 resulted in a 15% reduction in Adhexpression (PARSCH et al. 1997 ). It thus seems unlikely thatthe disruption of the weaker pairing stem would result in theobserved 100% increase in Adh expression. Furthermore, the ${Delta}$ 1766–1769mutation does not disrupt the 810–812/1762–1764 pairing,yet results in a 100% increase in Adh expression (Figure 2).This suggests that, though it may be involved in a long-rangeRNA-RNA pairing, the eight-base 3'-UTR motif also has a functionin Adh regulation that is unrelated to RNA secondary structure.The regulatory function may explain why we did not observe areduction in ADH activity in our previous experiment in whichwe made a site-directed mutation at position 1756 (PARSCH etal. 1997 ). It may be that this single nucleotide change adjacentto the conserved motif also leads to an increase in Adh expressionthat masks any reduction in expression caused by the disruptionof the 817–819/1756–1758 pairing. In fact, our previousresults indicate that there is a slight increase in ADH activityin transformed lines with the 1756 mutation, though this increaseis not significant (PARSCH et al. 1997 ).

A second possibility is that the 3'-UTR motif is involved inan RNA processing event that affects the translation rate ofthe mature mRNA. LAURIE and STAM 1994 report that a noncodingsequence within the first Adh intron affects the amount of ADHprotein in adult flies without affecting levels of Adh mRNAand suggest that this sequence may function in polyadenylation.The highly conserved 3'-UTR sequence, though it is located justupstream of the polyadenylation signal in all species analyzed,does not appear to function through the same mechanism as theintronic sequence. Results of Northern blot analysis indicatethat there is a greater amount of Adh mRNA present in deletionlines than in wild-type lines (Figure 5). The difference inmRNA level appears to be equal to the difference in ADH activitybetween mutant and wild-type lines (Figure 2 and Figure 5),and thus it is likely that the increase in the amount of ADHprotein is the result of an underlying increase in mRNA levels.

The increased amount of Adh mRNA found in the deletion mutantscould be the result of an increase in either Adh transcriptionrate or Adh mRNA stability. While the results of this studydo not rule out the possibility of an increased level of Adhtranscription in the mutant lines, this explanation seems unlikelyfor several reasons. All known regulatory elements that affectAdh transcription have been mapped to the 5' flanking regionof the gene, including the enhancer sequences required for properlarval and adult Adh expression. While transcription enhancing/silencingsequences have been identified within the 3'-UTR of other genes(LE CAM and LEGRAVEREND 1995 ; MCDONOUGH and DENERIS 1997 ),such sequences appear to be exceedingly rare and so far havebeen reported only for highly regulated mammalian genes. Theshort length of the conserved sequence (eight bases) and thefact that its location appears to be constrained to a specificregion of the 3'-UTR upstream of the polyadenylation signalalso make it unlikely that it is involved in transcriptionalcontrol.

Two sequence motifs involved in post-transcriptional regulationof gene expression have been identified within the 3'-UTRs ofD. melanogaster genes involved in the Notch signaling pathway(LAI and POSAKONY 1997 ; LEVITEN et al. 1997 ). These sequences,designated as the Brd box (AGCTTTA) and the GY box (GTCTTCC),have been shown to mediate negative regulation of both transcriptand protein levels in vivo (LAI and POSAKONY 1997 ). The Brdbox and the GY box of the E(spl)m4 gene are both perfectly conservedbetween D. melanogaster and D. hydei and are located withina region of the 3'-UTR just upstream of the polyadenylationsignal (LAI and POSAKONY 1997 ). While the highly conservedAdh 3'-UTR sequence (AAGGCTGA) does not match either of theabove motifs, it is similar to the Brd box in its core sequenceof GCT and in having an A at the first and last position ofthe motif. The medfly Adh 3'-UTR motif (AAGTCTGA) does not sharethe core sequence of GCT found in the Brd box, but does sharefour consecutive bases with the GY box (GTCT). The similarityof the Adh 3'-UTR sequence to these other conserved motifs,along with its role in the negative regulation of mRNA and proteinlevels, suggests that it may function through a similar mechanism.Though genes containing Brd box and GY box motifs are expressedin cells of the peripheral nervous system during development,the regulatory function of the Brd box has been shown to beboth spatially and temporally general (LAI and POSAKONY 1997). This general effect on protein and transcript levels is thussimilar to that observed in the Adh 3'-UTR deletion experiments.The Brd box, however, differs from the Adh 3'-UTR sequence inthat the former is often found in multiple copies (LAI and POSAKONY1997 ), while the latter is found only as a single copy in allof the Adh sequences analyzed (Figure 1).

While the exact molecular mechanism responsible for the increasein Adh expression observed in the 3'-UTR deletion mutants remainsobscure, the overall phenotypic effect of the deletions is clearlya large increase in in vivo ADH activity. This implies thatthe eight-base 3'-UTR sequence plays a negative regulatory rolein Adh expression in wild-type flies. The finding that sucha negative regulatory element is highly conserved is unexpectedin light of previous population genetic and molecular evolutionarystudies of Adh. For example, the amino acid replacement thatdistinguishes the Fast and Slow ADH allozymes in D. melanogasterresults in an approximatly twofold increase in ADH activityin Fast homozygotes, yet there does not appear to be purifyingselection against this replacement. On the contrary, it appearsthat the Fast allele has risen to high frequency relativelyrecently and may be favored by selection, at least in some environments(OAKESHOTT et al. 1982 ; KREITMAN 1983 ; AQUADRO et al. 1986; MERCOT et al. 1994 ). Similarly, an intronic polymorphismthat is typically associated with Adh-f alleles has been shownto increase ADH activity levels and also appears to be a targetof positive selection (LAURIE et al. 1991 ; BERRY and KREITMAN1993 ; LAURIE and STAM 1994 ). These observations raise thequestion of why nucleotide changes within the highly conserved3'-UTR sequence are strongly selected against, while changesat other sites that have the same phenotypic effect on ADH activityappear to be selectively favorable.

A clear difference between the effect on ADH activity causedby deletion of the conserved 3'-UTR sequence and that causedby the Fast/Slow amino acid replacement is that the 3'-UTR deletionresults in an increase in mRNA levels, while the amino acidreplacement affects only the catalytic efficiency of the ADHenzyme, not the amount of Adh mRNA. Thus, even though thesetwo sequence changes may have nearly identical phenotypic effectswhen measured as in vivo ADH activity, the phenotypes may differgreatly (twofold) when measured as in vivo Adh mRNA levels.Similarly, other naturally occurring polymorphisms within theD. melanogaster Adh gene have been shown to affect the totalamount of ADH protein in adult flies, resulting in an increasein in vivo ADH activity, without affecting levels of Adh mRNA(LAURIE and STAM 1988 , LAURIE and STAM 1994 ; STAM and LAURIE1996 ). It is thus likely that any potential benefit of increasedADH activity caused by disruption of the 3'-UTR sequence isoutweighed by the cost of maintaining such high concentrationsof Adh mRNA. The translation of an amount of mRNA greater bytwofold may have a large energetic cost and may occupy a substantialfraction of the available ribosomes within the cytoplasm, leavingthem unavailable for the translation of other cellular proteins.ADH may be particularly sensitive to such effects because itis expressed at very high levels, accounting for an estimated1–2% of the total translational activity in wild-type adultflies (BENYAJATI et al. 1980 ).

FOOTNOTES

¹ Present address: Department of Biology, University of Rochester,Rochester, NY 14627.

ACKNOWLEDGMENTS

We thank John Braverman and Steve Mount for helpful discussionsand suggestions during the course of this research. We alsothank Darryn Potosky for technical assistance in the laboratory.Two anonymous reviewers provided valuable comments on the manuscript.This work was funded in part by National Institutes of Healthgrant GM-58405.

Manuscript received July 15, 1998; Accepted for publication October 19, 1998.

LITERATURE CITED

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

AQUADRO, C. F., S. F. DESSE, M. M. BLAND, C. H. LANGLEY, and C. C. LAURIE-AHLBERG, 1986 Molecular population genetics of the alcohol dehydrogenase gene region of Drosophila melanogaster.. Genetics 114:1165-1190[Abstract/Free Full Text].

AYALA, F. J., E. BARRIO, and J. KWIATOWSKI, 1996 Molecular clock or erratic evolution? A tale of two genes. Proc. Natl. Acad. Sci. USA 93:11729-11734[Abstract/Free Full Text].

BENYAJATI, C., N. WANG, A. REDDY, E. WEINBERG, and W. SOFER, 1980 Alcohol dehydrogenase in Drosophila: isolation and characterization of messenger RNA and cDNA clone. Nucleic Acids Res. 23:5649-5667.

BENYAJATI, C., N. SPOEREL, H. HAYMERLE, and M. ASHBURNER, 1983 The messenger RNA for alcohol dehydrogenase in Drosophila melanogaster differs in its 5' end in different developmental stages. Cell 22:125-133.

BERRY, A. and M. KREITMAN, 1993 Molecular analysis of an allozyme cline: alcohol dehydrogenase in Drosophila melanogaster on the east coast of North America. Genetics 134:869-893[Abstract].

BISHOP, J. G. and V. G. CORCES, 1988 Expression of an activated ras gene causes developmental abnormalities in transgenic Drosophila melanogaster.. Genes Dev. 2:567-577[Abstract/Free Full Text].

CHOUDHARY, M. and C. C. LAURIE, 1991 Use of in vitro mutagenesis to analyze the difference in Adh expression associated with the allozyme polymorphism in Drosophila melanogaster.. Genetics 129:481-488[Abstract].

DAVID, J. R., C. BOCQUET, M. ARENS, and P. FOUILLET, 1976 The role of alcohol dehydrogenase in the tolerance of Drosophila melanogaster to aliphatic alcohols: utilization of an ADH null mutant. Biochem. Genet. 14:989-997[Medline].

FLETCHER, T. S., F. J. AYALA, D. R. THATCHER, and G. K. CHAMBERS, 1978 Structural analysis of the ADHs electromorph of Drosophila melanogaster.. Proc. Natl. Acad. Sci. USA 75:5609-5612[Abstract/Free Full Text].

GEER, B. W., S. W. MCKECHNIE, and M. L. LANGEVIN, 1986 The effect of dietary ethanol on the composition of lipids of Drosophila melanogaster larvae. Biochem. Genet. 24:51-69[Medline].

GEER, B. W., S. W. MCKECHNIE, P. W. H. HEINSTRA, and M. J. PYKA, 1991 Heritable variation in ethanol tolerance and its association with biochemical traits in Drosophila melanogaster.. Evolution 45:1107-1119.

GIBSON, J. B., and J. G. OAKESHOTT, 1982 Tests of the adaptive significance of the alcohol dehydrogenase polymorphism in Drosophila melanogaster: paths, pitfalls, and prospects, pp. 291–306 in Ecological Genetics and Evolution, edited by J. S. F. BARKER and W. T. STARMER. Academic Press, Sydney, Australia.

GOLDBERG, D. A., J. W. POSAKONY, and T. MANIATIS, 1983 Correct developmental expression of a cloned alcohol dehydrogenase gene transduced into the Drosophila germ line. Cell 34:59-73[Medline].

KIRBY, D. A., S. V. MUSE, and W. STEPHAN, 1995 Maintenance of pre-mRNA secondary structure by epistatic selection. Proc. Natl. Acad. Sci. USA 92:9047-9051[Abstract/Free Full Text].

KREITMAN, M., 1983 Nucleotide polymorphism at the alcohol dehydrogenase locus of Drosophila melanogaster.. Nature 304:412-417[Medline].

KWIATOWSKI, J., M. KRAWCZYK, M. JAWORSKI, D. SKARECKY, and F. J. AYALA, 1997 Erratic evolution of glycerol-3-phosphate dehydrogenase in Drosophila chymomyza, and Ceratitis.. J. Mol. Evol. 44:9-22[Medline].

LAI, E. and J. POSAKONY, 1997 The Bearded box, a novel 3' UTR sequence motif, mediates negative post-transcriptional regulation of Bearded and Enhancer of split complex gene expression. Development 124:4847-4856[Abstract].

LAURIE, C. C. and L. F. STAM, 1988 Quantitative analysis of RNA produced by Slow and Fast alleles of Adh in Drosophila melanogaster.. Proc. Natl. Acad. Sci. USA 85:5161-5165[Abstract/Free Full Text].

LAURIE, C. C. and L. F. STAM, 1994 The effect of an intronic polymorphism on alcohol dehydrogenase expression in Drosophila melanogaster.. Genetics 138:379-385[Abstract].

LAURIE, C. C., J. T. BRIDGHAM, and M. CHOUDHARY, 1991 Associations between DNA sequence variation and variation in expression of the Adh gene in natural populations of Drosophila melanogaster.. Genetics 129:489-499[Abstract].

LAURIE-AHLBERG, C. C. and L. F. STAM, 1987 Use of P-element-mediated transformation to identify the molecular basis of naturally occurring variants affecting Adh expression in Drosophila melanogaster.. Genetics 115:129-140[Abstract/Free Full Text].

LE CAM, A. and C. LEGRAVEREND, 1995 Transcriptional repression, a novel function for 3' untranslated regions. Eur. J. Biochem. 231:620-627[Medline].

LEVITEN, M., E. LAI, and J. POSAKONY, 1997 The Drosophila gene Bearded encodes a novel small protein and shares 3' UTR sequence motifs with multiple Enhancer of split complex genes. Development 124:4039-4051[Abstract].

LI, W.-H., and D. GRAUR, 1991 Fundamentals of Molecular Evolution. Sinauer, Sunderland, MA.

LOWRY, O. H., N. J. ROSEBROUGH, A. L. FARR, and R. J. RANDALL, 1951 Protein measurements with the Folin phenol reagent. J. Biol. Chem. 193:265-275[Free Full Text].

MARONI, G., 1978 Genetic control of alcohol dehydrogenase levels in Drosophila.. Biochem. Genet. 16:509-523[Medline].

MCDONOUGH, J. and E. DENERIS, 1997 ß43': an enhancer displaying neural-restricted activity is located in the 3'-untranslated exon of the rat nicotinic acetylcholine receptor ß4 gene. J. Neurosci. 17:2273-2283[Abstract/Free Full Text].

MERCOT, H., D. DEFAYE, P. CAPY, E. PLA, and J. R. DAVID, 1994 Alcohol tolerance, ADH activity, and ecological niche of Drosophila species. Evolution 48:746-757.

OAKESHOTT, J. G., J. B. GIBSON, P. R. ANDERSON, W. R. KNIBB, and D. G. ANDERSON et al., 1982 Alcohol dehydrogenase and glycerol-3-phosphate dehydrogenase clines in Drosophila melanogaster on different continents. Evolution 36:86-96.

PARSCH, J., S. TANDA, and W. STEPHAN, 1997 Site-directed mutations reveal long-range compensatory interactions in the Adh gene of Drosophila melanogaster.. Proc. Natl. Acad. Sci. USA 94:928-933[Abstract/Free Full Text].

PATTON, J. S., X. V. GOMES, and P. K. GEYER, 1992 Position-independent germline transformation in Drosophila using a cuticle pigmentation gene as a selectable marker. Nucleic Acids. Res. 20:5859-5860[Free Full Text].

ROBERTSON, H. M., C. R. PRESTON, R. W. PHILLIS, D. M. JOHNSON-SCHLITZ, and W. K. BENZ et al., 1988 A stable genomic source of P element transposase in Drosophila melanogaster.. Genetics: 118:461-470[Abstract/Free Full Text].

RUBIN, G. M. and A. C. SPRADLING, 1982 Genetic transformation of Drosophila with transposable element vectors. Science 218:348-353[Abstract/Free Full Text].

SAMBROOK, J., E. F. FRITSCH and T. MANIATIS, 1989 Molecular Cloning: A Laboratory Manual, Ed. 2. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY.

SAVAKIS, C. M., M. ASHBURNER, and J. H. WILLIS, 1986 The expression of the gene coding for alcohol dehydrogenase during the development of Drosophila melanogaster.. Dev. Biol. 114:194-207.

SCHAEFFER, S. W. and E. L. MILLER, 1993 Estimates of linkage disequilibrium and the recombination parameter determined from segregating nucleotide sites in the alcohol dehydrogenase region of Drosophila pseudoobscura.. Genetics 135:541-552[Abstract].

SPRADLING, A. C. and G. M. RUBIN, 1982 Transposition of cloned P-elements into Drosophila germ line chromosomes. Science 218:341-347[Abstract/Free Full Text].

STAM, L. F. and C. C. LAURIE, 1996 Molecular dissection of a major gene effect on a quantitative trait: the level of alcohol dehydrogenase expression in Drosophila melanogaster.. Genetics 144:1559-1564[Abstract].

SULLIVAN, D. T., P. W. ATKINSON, and W. T. STARMER, 1990 Molecular evolution of the alcohol dehydrogenase genes in the genus Drosophila. Evol. Biol. 24:107-147.

VAN DELDEN, W., 1982 The alcohol dehydrogenase polymorphism in Drosophila melanogaster.. Evol. Biol. 15:187-222.

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