Rapid Deadenylation and Poly(A)-Dependent Translational Repression Mediated by the Caenorhabditis elegans tra-2 3' Untranslated Region in Xenopus Embryos

doi:10.1128/MCB.20.6.2129-2137.2000

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Molecular and Cellular Biology, March 2000, p. 2129-2137, Vol. 20, No. 6
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Rapid Deadenylation and Poly(A)-Dependent Translational Repression Mediated by the Caenorhabditis elegans tra-2 3' Untranslated Region in Xenopus Embryos

Sunnie R. Thompson,¹^, Elizabeth B. Goodwin,² and Marvin Wickens¹^,^*

Department of Biochemistry, University of Wisconsin $---$ Madison, Madison, Wisconsin 53706-1569,¹ and Department of Cell and Molecular Biology and Lurie Cancer Center, Northwestern University Medical School, Chicago, Illinois²

Received 22 September 1999/Returned for modification 9 November 1999/Accepted 20 December 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The 3' untranslated region (3'UTR) of many eukaryotic mRNAs is essential for their control during early development. Negativetranslational control elements in 3'UTRs regulate pattern formation,cell fate, and sex determination in a variety of organisms. tra-2mRNA in Caenorhabditis elegans is required for female developmentbut must be repressed to permit spermatogenesis in hermaphrodites.Translational repression of tra-2 mRNA in C. elegans is mediatedby tandemly repeated elements in its 3'UTR; these elements arecalled TGEs (for tra-2 and GLI element). To examine the mechanismof TGE-mediated repression, we first demonstrate that TGE-mediatedtranslational repression occurs in Xenopus embryos and that Xenopusegg extracts contain a TGE-specific binding factor. Translationalrepression by the TGEs requires that the mRNA possess a poly(A)tail. We show that in C. elegans, the poly(A) tail of wild-typetra-2 mRNA is shorter than that of a mutant mRNA lacking the TGEs.To determine whether TGEs regulate poly(A) length directly, synthetictra-2 3'UTRs with and without the TGEs were injected into Xenopusembryos. We find that TGEs accelerate the rate of deadenylationand permit the last 15 adenosines to be removed from the RNA,resulting in the accumulation of fully deadenylated molecules.We conclude that TGE-mediated translational repression involveseither interference with poly(A)'s function in translation and/orregulateddeadenylation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Regulatory elements in the 3' untranslated region (3'UTR) can dramatically influence cell fate and early development by controllingmRNA stability, location, and translational activity (3, 4,8, 18, 31, 35, 43, 51, 61). Negative translationalcontrol elements in 3'UTRs have been identified genetically thatdisrupt pattern formation, cell-cell interactions, and cell fatedetermination in the early embryo (reviewed in references 8and 61). In many cases, repression by such negative controlelements is correlated with the presence of shorter poly(A) tails.Although the activity of 3'UTR control elements commonly requiresbinding to regulatory proteins, the mode of action of these RNA-proteincomplexes has not been elucidated indetail.

Caenorhabditis elegans is a self-fertilizing hermaphrodite worm, in which a single individual produces both oocytes and sperm.Hermaphrodites are somatic females that first produce sperm andthen switch and make oocytes. The tra-2 gene normally directsfemale development (19), and its repression is required forthe onset of hermaphrodite spermatogenesis. The tra-2 gene product,presumed to be a transmembrane protein, inhibits male determinantsand coordinates neighboring cells to adopt the same fate (29,37). tra-2 gain-of-function (gf) mutants are defective in acis-acting translational control element located in the tra-23'UTR (see Fig. 5A) (17). This element mediates translationalrepression of tra-2 RNA, as judged by polysome analysis and reporterexperiments in C. elegans (17). In tra-2 mRNA, the element istandemly repeated. Each individual element is called a TGE (fortra-2 and GLI elements). TGEs are not limited to the C. eleganstra-2 mRNA but have been identified in tra-2 from Caenorhabditisbriggsae, C. elegans tra-1, and the human oncogene GLI (23).

GLD-1 was identified using the Saccharomyces cerevisiae three-hybrid system as a protein that specifically binds to TGEs andrepresses translation of TGE-containing reporter RNAs in vivoand in vitro (22). GLD-1 is germ line specific and is requiredfor oogenesis as well as spermatogenesis (16, 24). GLD-1 isa member of the STAR protein family, consisting of a single KHRNA-binding domain with conserved QUA1 and QUA2 motifs (for areview, see reference 55). STAR proteins are found in a widerange of species, from invertebrates tomammals.

In several systems, regulated changes in poly(A) length are correlated with changes in translational activity. Increases inlength are correlated with increases in translation, and decreaseswith repression (reviewed in references 18 and 41). Changesin poly(A) length may be required for translational regulation.For example, in the Drosophila embryo, translation of bicoid mRNArequires a distinct length of poly(A) such that the mRNA mustundergo polyadenylation to become translationally active (44),while repression of hunchback mRNA apparently requires deadenylation(62). However, translational repression can also cause deadenylation(34), indicating that changes in poly(A) length can also bethe result, rather than the cause, of altered translational activity.In yeast and in somatic cells, poly(A) may facilitate translationby binding to poly(A) binding protein (PAB). The poly(A)-PAB complexinteracts with eIF-4G, a translation initiation factor, whichin turn binds to eIF-4E, the cytoplasmic cap binding protein (52,53, 59). This end-to-end linkage could play a role in theeffects of regulated changes in poly(A) length on translationalactivity in embryos and in the function of 3'UTR regulatory elements(reviewed in references 18 and 43).

Sequences that control poly(A) tail lengths commonly are located within the 3'UTR (reviewed in reference 41) and can functionacross species (56). In Xenopus embryos, the length of poly(A)present on an mRNA at any given time is determined by competingreactions that add and remove adenosines. Poly(A) tail lengtheningrequires a cytoplasmic polyadenylation element (CPE) and the nuclearpolyadenylation signal, AAUAAA. Poly(A) shortening occurs by twomechanisms: a rapid deadenylation caused by specific sequencesin the 3'UTR (e.g., references 1, 39, and 58) and a slowdeadenylation that acts on RNAs without either a CPE or AAUAAA,termed default deadenylation (15 54).

In this report we investigate the molecular mechanism by which TGEs regulate translation. In the Xenopus embryo, TGEs represstranslation and do so through a mechanism that requires a poly(A)tail. TGEs promote rapid, regulated deadenylation in the Xenopusembryo and cause shorter poly(A) tails in C. elegans. Since TGEsfunction across species and in multiple developmental stages,their poly(A)-dependent mechanism of repression may bewidespread.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Oligonucleotides. The sequences and nomenclature of oligonucleotides are provided in Table 1.

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TABLE 1. Oligonucleotides used in this study

RNA sequences and transcription templates. (i) mRNAs containing HA-tagged luciferase followed by TGE or $Delta$ TGE tra-2 3'UTRs. The SalI/BglII fragments containing the tra-2 3'UTR sequences (see pBtra-2 [wild type] and pBtra-2 [ $Delta$ TGE]) were subclonedinto pLuc/polylinker. pLuc/polylinker was constructed by insertingannealed oligonucleotides 9408.01 and 9408.02 into the BglII siteof pLuc/cyclin B1 (49); J. Collar and M. Wickens, unpublisheddata). A StyI fragment from pXlpap-HA containing a hemagglutinin(HA) tag (2) was placed in frame upstream of the luciferasecoding region by insertion at the StyI site in the pLuc/wild-typeand pLuc/ $Delta$ TGE plasmids. An A₆₅ sequence was introduced by insertingthe XbaI/ScaI fragment from pAFB102 (A. Barkoff and M. Wickens,unpublished data) into the SpeI/ScaI site of the pHA-Luc/wild-typeand pHA-Luc/ $Delta$ TGE plasmids to generate pHA-Luc/wild-type-pA andpHA-Luc/ $Delta$ TGE-pA, respectively. To prepare HA-Luc/TGE tra-2 andHA-Luc/ $Delta$ TGE tra-2 RNAs, pHA-Luc/wild-type and pHA-Luc/ $Delta$ TGE plasmidswere linearized with SpeI and transcribed with T7 RNA polymerase(Stratagene). To prepare HA-Luc/TGE-pA tra-2 and HA-Luc/ $Delta$ TGE-pAtra-2 RNAs, pHA-Luc/wild-type-pA and pLuc/ $Delta$ TGE-pA plasmids werelinearized with BglII and transcribed with T7 RNA polymerase(Stratagene).

(ii) 3'UTR RNAs with or without TGE that lack AAUAAA. To construct pBtra-2pA (wild type) and pBtra-2pA ( $Delta$ TGE plus insert), a PCR product was generated using primers EBG-20 andEBG-21b to amplify the tra-2 3'UTRs from genomic DNA isolatedfrom either tra-2 (wild-type) or tra-2(gf) animals. The 3' primercontains a U-to-G mismatch to generate the AAgAAA mutant polyadenylationsignal. The PCR products were digested with SalI and BglII andcloned into the SalI and BamHI sites of pBluescript II KS(+),creating pBtra-2 (wild type) and pBtra-2 ( $Delta$ TGE). The A₆₅ poly(A)tail was added by digesting these constructs with XbaI and ScaI,replacing this fragment with the XbaI/ScaI fragment containinga A₆₅ poly(A) tract from pABF102 (Barkoff and Wickens, unpublished).To generate a $Delta$ TGE tra-2 transcript with a length equivalent tothat of the TGE tra-2 RNA, a 108-nucleotide insert was generatedby amplifying pBluescript II KS (+) with a 5' insert primer and3' insert primer using Pfu polymerase (Stratagene). This productwas ligated into the HincII (Promega) site of pBtra-2pA ( $Delta$ TGE)to generate pBtra-2pA ( $Delta$ TGE plus insert). The resulting insertdid not create an open reading frame or an AUG in a favorablecontext for use as a start codon based on Kozak consensus sequences(25, 26). Identical results were obtained with a $Delta$ TGE tra-2RNA lacking the 108-nucleotide insert at the 5' end of the RNA(data not shown). TGE and $Delta$ TGE tra-2 RNAs were transcribed withT3 RNA from BglII-digested pBtra-2pA (wild type) and pBtra-2pA( $Delta$ TGE plus insert). To prepare RNAs without the A₆₅ poly(A) tail,the DNA was linearized before the poly(A) tract with SpeI andtranscribed with T3 RNApolymerase.

(iii) 3'UTR RNAs with or without TGE that contain AAUAAA. The templates for these RNAs were constructed as above except that the EBG-21b primer was replaced with the EBG-21a primerthat encodes a wild-type nuclear polyadenylation signal, AAUAAA.The pBtra-2pA (wild-type) and pBtra-2pA ( $Delta$ TGE plus insert) withAAUAAA constructs were further manipulated to reduce the distancebetween AAUAAA and the beginning of the poly(A) tail by digestingwith XbaI and SpeI (Promega) followed by mung bean nuclease treatmentas described by the manufacturer (Promega). These ends were religated,resulting in an 11-nucleotide deletion and generating pBtra-2pA(wild-type) XS and pBtra-2pA ( $Delta$ TGE plus insert) XS. To prepareTGE and $Delta$ TGE tra-2 RNAs with AAUAAA, BglII-digested DNA was transcribedwith T3 RNApolymerase.

(iv) RNAs containing zero or four TGEs (see Fig. 3). A SpeI site was introduced into pL1+ CPE/3Zf+ (56) by site-directed mutagenesis (28) using the SpeI L1 oligonucleotide.The resulting plasmid, pSpeI L1+CPE/3Zf+, was linearized withSpeI (Promega), and the annealed oligonucleotides, TGE1 and TGE2(consisting of two TGEs), were inserted. A clone containing twoinserts was isolated (4TGE/3Zf+). To prepare RNAs containing zeroor four TGEs, pL1 + CPE/3Zf+ and 4TGE/3Zf+, respectively, werelinearized with Hsp92I, upstream of the CPE and AAUAAAsequences.

(v) RNAs that contain the 3'UTR of C. briggsae tra-2. RNAs were prepared from Cb-tra-2(+) 3'UTR and Cb-tra-2 ( $-$ 38) 3'UTR as described in reference 23.

(vi) HA-C100 RNA. Transcripts were produced by linearizing pHA-C100 (9) with HpaI and transcribing with SP6 polymerase(Promega).

PAT assay. tra-2 mRNA was isolated from wild-type and gain-of-function (e2020) worms using the method of Chomczynski and Sacchi (7).Endogenous mRNA poly(A) tail lengths were measured by the poly(A)test (PAT) analysis (45) essentially as previously described(23). RACE-1 oligonucleotide was used for the reverse transcriptionreactions. A PCR was performed as previously described (23),using primers CAH-1 (which hybridizes to the coding region oftra-2) and RACE-1 [which anneals to the poly(A) tail]. Then anested PCR was performed using the RACE-2 oligonucleotide andspecific oligonucleotides for the wild-type tra-2, for CAH-3,or for the gain-of-function, CAH-4. The products of this PCR wereanalyzed on a 2% agarose gel and visualized by ethidium bromide(Sigma).

In vitro transcription. Capped RNAs of specific radioactivity of 1 × 10³ to 20 × 10³ cpm/fmol (injection of 3'UTRs), 2 × 10² cpm/fmol (injected translational reporter mRNAs), or unlabeled(HA-C100 RNA) were prepared by in vitro transcription of linearizedplasmid templates using either bacteriophage T3 (Gibco BRL), T7(Promega or Stratagene), or SP6 (Promega) RNA polymerase. Transcriptionreactions were carried out essentially as described by the manufacturers,using m⁷GpppG (cap analog) (New England Biolabs) and, if radiolabeled,40 to 100 µCi of [ $alpha$ -³²P]UTP (DuPont). RNAs consisting of 3'UTR sequences were gel isolatedfrom a denaturing gel containing 6% polyacrylamide. RNAs wereeluted from a gel slice by incubating overnight at 25°C in a solutionof 0.1% sodium dodecyl sulfate (SDS), 1 mM EDTA, and 0.5 M ammoniumacetate. Reporter mRNAs were treated with DNase I, and free nucleotideswere removed with a G-50 Sephadex column (Boehringer Mannheim).All RNAs were extracted three times with a 5:1 mixture of phenol-chloroform(pH 4.7) (Amresco). Transcripts were precipitated three timeswith ethanol. The pellet was washed with 70% ethanol after eachprecipitation. RNA was resuspended in diethylpyrocarbonate (DEPC)-treatedwater.

Embryo injections. (i) RNA injections. Eggs were obtained, fertilized, and dejellied essentially as described previously (36). To obtain eggs for fertilization,adult females were injected with 50 U of pregnant mare serum (Calbiochem)2 to 5 days prior to oviposition. Females were induced to layeggs by injection with 500 U of human chorionic gonadotropin hormone(Sigma). Eggs were collected in 1× MMR (1× MMR is 100 mM NaCl,2 mM CaCl₂, 1 mM MgCl₂, and 5 mM HEPES-KOH [pH 7.4]) at 18°C.The eggs were drained of any buffer and smeared with maceratedtestes. Water was added to activate the sperm. Fertilized eggswere identified by contraction of the animal hemisphere and corticalrotation. Approximately 30 min after fertilization, the eggs weretreated with 2% cysteine (Sigma) in 1× MMR, neutralized to pH7.8. The dejellied eggs were rinsed several times with 1× MMRand placed in 5% Ficoll₄₀₀ (Sigma) in 1× MMR. Injection of theembryo was performed essentially as previously described (57).RNA (2 fmol) (10 nl) was injected into the embryo before the firstcleavage. Single embryos were collected by freezing on dry ice.The embryos were moved to 0.1× MMR between the 8-cell and 16-cellstage.

(ii) [³⁵S]methionine-cysteine injections. Embryos which previously had been injected with reporter RNAs were subsequently injected with 0.1 µCi (10 nl) of Tran³⁵S-label (ICN) or [³⁵S]methionine (Amersham) at the 64-cell stage. Incubation of theembryos was continued for 60 min (approximately two cleavage events)following injection with label. Embryos were collected in setsof 10 and frozen on dryice.

Extraction and analysis of RNA. Each individual embryo was analyzed separately. RNAs were isolated from single embryos by homogenization in 400 µl of a solutioncontaining 50 mM Tris (pH 7.9), 5 mM EDTA, 2% SDS, and 300 mMNaCl, followed by extraction with phenol-chloroform (5:1) (pH4.7) (Amresco) and ethanol precipitation of the aqueous phase.The RNA was resuspended in 8 µl of DEPC-treated water and 4 µlof loading buffer (46). The equivalent of 0.5 to 1 embryo wasanalyzed on a single lane of a 6% polyacrylamide gel containing7 M urea (47). Electrophoresis was performed for 2.5 h at 1,200V. Autoradiographic exposures of dried gels were generally for12 to 36 h with an intensifying screen at $-$ 70°C.

Molecular size standards. MspI fragments of pBR322 were labeled using the Klenow fragment of DNA polymerase I (Promega) and [ $alpha$ -³²P]dCTP (Amersham). Protein molecular size standards were SDS-polyacrylamidegel electrophoresis (PAGE) low range standards (Bio-Rad) or BenchMarkprestained protein standards (Gibco BRL). DNA standards were a100-bp ladder (GibcoBRL).

RNase H-oligo(dT) digestion. RNA was extracted from a single embryo as described previously (see above) except the RNA pellet was washed with 70% ethanol.Half of the RNA isolated from a single embryo was incubated in1× RNase H buffer (20 mM HEPES-KOH [pH 7.5], 10 mM MgCl₂, 50 mMKCl, and 1 mM dithiothreitol) with 5 µg of oligo(dT)_12-18(Pharmacia) at 65°C for 5 min and slowly cooled to 37°C, at whichpoint 0.5 to 2 U of RNase H (Promega) was added to the reactionmixture. The RNase H reaction mixture was incubated for 30 minat 37°C. The other half of the RNA sample from the embryo wastreated identically except that no oligo(dT) or RNase H enzymewas added. Then the reaction mixture was diluted to 200 µl withDEPC-treated water containing 100 mM NaCl, and proteins were extractedwith phenol-chloroform 5:1 (pH 4.7) (Amresco); the aqueous phasewas then mixed with ethanol. The precipitated RNA was resuspendedin DEPC-treated water and loading buffer and analyzed on a 6%denaturing polyacrylamide gel as describedpreviously.

Analysis of formation of complexes. Capped, labeled RNA (2 fmol) and Xenopus egg extract (5 µg) (prepared as described previously [13]) were incubated as previouslydescribed (17). Loading buffer III (46) was added to the RNAand egg extract, and the mixture was loaded on a 2× TBE (46)7% nondenaturing polyacrylamide gel (ratio of acrylamide to bisacrylamidewas 19:1) (gel dimensions were 25 cm long and 1.5 mm thick), whichhad been preequilibrated to 4°C. The gel was run in 2× TBE runningbuffer at 4°C for 1.5 to 3 h at 10W.

Immunoprecipitation. Ten embryos were homogenized in 1 ml of radioimmunoprecipitation assay (RIPA) plus protease inhibitors (150 mM NaCl, 1% NonidetP-40, 0.5% sodium deoxycholic acid, 0.1% SDS, 50 mM Tris-Cl [pH8], 10 µg of leupeptin per ml, 1 µg of pepstatin per ml, 1 µgof chymostatin per ml, 10 µg of aprotinin per ml, and 17.4 µgof phenylmethylsulfonyl fluoride per ml). Homogenates were centrifugedfor 2 min at 16,000 × g at 4°C. The cleared lysate was collectedand incubated with 30 µg of anti-HA mouse monoclonal antibodyclone 12CA5 (Berkeley Antibody Company), rocking gently for 1h at 4°C. Protein A-Sepharose beads CL4B (Sigma) (5 µg) were added,and the incubation was continued for 1 h at 4°C with gentle rocking.Beads were collected by centrifuging for 5 min at 2,000 × g andwashed three times with RIPA plus protease inhibitors. Beads wereresuspended in protein loading buffer and boiled for 3 min. Proteinswere analyzed on an SDS-7.5% polyacrylamide gel. The protein gelwas stained (0.25% Coomassie blue, 50% methanol, 10% acetic acid)and destained (40% methanol and 10% acetic acid) followed by a30-min incubation in Amplify (Amersham). The protein gel was driedand exposed to a preflashed film using a Sensitize preflash unitRPN 2051 (Amersham) for quantitative analysis. Quantitations wereperformed using NIH image 1.60.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

TGEs repress translation in Xenopus embryos. To determine whether TGE-dependent translational repression occurs in Xenopus embryos, we injected reporter mRNAs with orwithout TGEs into fertilized Xenopus eggs. These reporter RNAscontained an N-terminal HA tag linked to a luciferase coding regionfollowed by either the wild-type C. elegans tra-2 3'UTR or a tra-23'UTR without TGEs. These mRNAs both contain a wild-type nuclearpolyadenylation signal (AAUAAA) and a 65-nucleotide poly(A) tail.The in vitro-transcribed RNAs were coinjected into 1-cell embryos,together with a control RNA (HA-C100) whose expression is constantthroughout early development (9). To measure translation ofthe injected mRNAs, we injected [³⁵S]methionine and [³⁵S]cysteine at the 64-cell stage, continued the incubation for1 h, and then immunoprecipitated the proteins using an anti-HAantibody. Newly synthesized proteins were analyzed by SDS-PAGEand autoradiography. For each mRNA, three separate groups of embryosare shown in Fig. 1. The injected RNAs were equally stable, asjudged by electrophoresis and autoradiography (data not shown).

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FIG. 1. TGE-regulated translational repression is conserved in Xenopus embryos. HA-tagged luciferase reporter mRNAs carrying the tra-2 3'UTR were prepared and injected into embryos. The 3'UTRs either contained the TGEs (lanes 1 to 3) or lacked the TGEs ( $Delta$ TGE) (lanes 4 to 6); both mRNAs contained a wild-type (AAUAAA) polyadenylation signal and an A₆₅ poly(A) tail. mRNAs were coinjected with HA-C100 mRNA (a control) into 1-cell embryos. The embryos were reinjected at the 64-cell stage with [³⁵S]methionine-cysteine, and incubated for 1 h before collecting embryos and immunoprecipitating HA-tagged proteins. Immunoprecipitated proteins were analyzed by SDS-PAGE and autoradiography.

Translation of the mRNA carrying the wild-type 3'UTR (TGE) was repressed compared to that of an mRNA from which the TGEs hadbeen deleted ( $Delta$ TGE) (Figure 1, compare lanes 1 to 3 to lanes 4to 6). The magnitude of repression was comparable to that observedin C. elegans (two- to threefold; E. Jan and B. Goodwin, personalcommunication). We conclude that TGEs cause translational repressionin Xenopusembryos.

Repression requires a poly(A) tail. To elucidate whether TGE-mediated repression required a poly(A) tail, we prepared reporter mRNAs identical to those in Fig.1, except that they lacked a poly(A) tail and carried a pointmutation in AAUAAA, converting it to AAgAAA (point mutation shownin lowercase). This mutation blocks poly(A) elongation in embryos(50). Thus, these mRNAs enabled us to assess the effects ofTGEs on translation in the absence of poly(A) or poly(A) metabolism.Translation was monitored by the same protocol as that used toprepare Fig. 1.

The level of translation of the reporter was unaffected by the presence of the TGEs (Fig. 2). To confirm that there is nodifference in translation dependent on the TGEs for RNAs thatlack a poly(A) tail, we performed luciferase assays. Luciferaseactivity was assayed at the 64-cell stage: the mRNAs with andwithout TGEs yielded equivalent luciferase activity (110,000 ±10,000 U versus 125,000 ± 20,000 U, with and without TGEs, respectively).The mRNA lacking TGEs was translated less well than was its counterpartwith a poly(A) tail and AAUAAA (compare Fig. 2, lanes 4 to 6,with Fig. 1, lanes 4 to 6), consistent with the stimulatory effectof poly(A) tails in Xenopus embryos (49, 50). The two mRNAswere comparably stable in embryos (not shown). We conclude thata poly(A) tail must be present for the TGEs to regulate translationof the injected reporters.

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FIG. 2. TGE-mediated translational repression requires a poly(A) tail. HA-tagged luciferase reporter mRNAs either contained the TGEs (lanes 1 to 3) or lacked the TGEs ( $Delta$ TGE) (lanes 4 to 6). Both mRNAs contained a mutant (AAgAAA) polyadenylation signal and no poly(A) tail. mRNAs were coinjected with HA-C100 (a control) into 1-cell embryos. The embryos were reinjected at the 64-cell stage with [³⁵S]methionine-cysteine and incubated 1 hour before collecting and immunoprecipitating HA-tagged proteins. Immunoprecipitated proteins were analyzed by SDS-PAGE and autoradiography.

A Xenopus TGE-binding factor. C. elegans extracts contain a factor that associates specifically with the tra-2 TGE (17). To determine whether such a factorwas present in Xenopus eggs, we incubated radiolabeled tra-2 3'UTRRNAs in Xenopus egg extracts and analyzed RNA-protein complexesby native gel electrophoresis and autoradiography. These RNAscontain only the 3'UTR and adjacent polylinker sequences. Wild-typetra-2 RNA formed a specific complex that was not detected withan RNA lacking the TGEs (Fig. 3A). To examine further the bindingspecificity of this Xenopus factor, we tested the C. briggsaetra-2 3'UTR, which contains only a single TGE and forms a TGE-dependentcomplex in both C. elegans and C. briggsae extracts (23). Again,the wild-type tra-2 3'UTR from C. briggsae had a lower mobilityin the presence of Xenopus egg extract (Fig. 3B, lanes 1 and 2);a mutant RNA that lacked the TGE did not form the complex efficiently(Fig. 3B, lanes 3 and 4). Taken together, these results demonstratethat a factor in the Xenopus extract binds the TGE with a sequencespecificity similar to that of the TGE-binding factor in C. elegans.

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FIG. 3. A TGE-specific binding factor in Xenopus egg extract. (A) Labeled RNAs carrying the C. elegans tra-2 3'UTR either with the TGEs (lanes 1 and 2) or lacking the TGEs ( $Delta$ TGE) (lanes 3 and 4) were incubated in the presence (+) or absence ( $-$ ) of Xenopus egg extract. (B) Labeled RNAs carrying the C. briggsae tra-2 3'UTR either with the TGE (lanes 1 and 2) or lacking the TGE ( $Delta$ TGE) (lanes 3 and 4) were incubated in the presence (+) or absence ( $-$ ) of Xenopus egg extract. (C) RNAs containing four C. elegans TGEs alone (in the absence of the rest of the tra-2 3'UTR) (lanes 1 and 2) or no TGEs (lanes 3 and 4) were incubated in the presence (+) or absence ( $-$ ) of Xenopus egg extract. RNA complexes were analyzed by gel electrophoresis and autoradiography.

To determine whether TGEs are not only necessary but also sufficient for binding to the Xenopus factor, we prepared RNAs containingonly the TGE sequences from C. elegans tra-2 (plus vector sequences).These RNAs contain either four tandemly duplicated TGEs or, asa control, lacked TGEs entirely (Fig. 3C). Complexes were detectedreadily on the RNA possessing four TGEs (Fig. 3C, lanes 1 and2) and were not detected in the absence of the TGEs (Fig. 3C,lanes 3 and 4). Complexes formed less efficiently with the RNApossessing only four TGEs than with the entire 3'UTR, suggestingthat other 3'UTR sequences can influence binding. We concludethat Xenopus egg extracts contain a TGE-specific binding factor,consistent with the presence of a TGE-dependent repression mechanismin the Xenopusembryo.

TGEs regulate poly(A) tail lengths in C. elegans. The finding that TGE-mediated repression requires the presence of a poly(A) tail (Fig. 1 and 2) suggests that TGEs might influencepoly(A) tail length in C. elegans. To test this possibility, weanalyzed endogenous tra-2 mRNAs isolated from wild-type wormsand from mutant (gain-of-function) worms carrying a deletion inthe tra-2 3'UTR that spans the TGEs ( $Delta$ TGE). Poly(A) lengths wereassayed using the reverse transcriptase PCR (RT-PCR)-based assaydiagrammed in Fig. 4A (45). Primers for RT-PCR were designedto detect differences in poly(A) tail lengths. To compensate forthe 108-nucleotide deletion in the 3'UTR of the gain-of-functionallele, specific primers located at equal distances upstream ofthe 3' ends were used for the wild-type or gain-of-function mRNAs.The primers were designed such that a tra-2 mRNA with no poly(A)tail, derived from either the wild-type or deletion mutant allele,would result in a product of 400 nucleotides.

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FIG. 4. C. elegans endogenous wild-type tra-2 mRNA has a shorter poly(A) tail than gain-of-function mRNA. (A) Diagram of the PAT assay used to measure endogenous poly(A) tail lengths. Primers were designed to result in products of equal sizes if poly(A) lengths are equivalent. A tra-2 mRNA having a poly(A) tail of A₀ would result in a final product of 400 bp. (B) Ethidium bromide-stained agarose gel containing the products of the PAT assay performed on either wild-type (lane 1) or gain-of-function ( $Delta$ TGE) (lane 2) worms. It is important to note that any length over 400 bp is contributed by the poly(A) tail. The length of the PCR product generated by a nonadenylated mRNA would be 400 bp. Lane 3 (M) contains a 100-bp ladder.

The presence of the TGEs in tra-2 mRNA reduced its poly(A) length in C. elegans (Fig. 4B). The RT-PCR products obtained fromwild-type mRNA were approximately 50 to 100 nucleotides shorterthan those derived from the gain-of-function mRNAs that lack theTGEs. The length of PCR products above 400 nucleotides correspondsapproximately to the actual length of poly(A) on the mRNA (45).Thus, any differences in length correspond to differences in poly(A)tail lengths between the mRNAs. These data demonstrate that TGE-mediatedtranslational repression is correlated with a reduction in poly(A)tail length of endogenous tra-2 mRNA in C. elegans.

tra-2 TGEs promote rapid deadenylation in Xenopus embryos. To test whether TGEs control deadenylation in vivo, capped and polyadenylated tra-2 3'UTR RNAs with or without TGEs were injectedinto Xenopus 1-cell embryos. These RNAs comprise the 3'UTR oftra-2 mRNA, plus a 65-nucleotide poly(A) tail (Fig. 5A). A 108-nucleotidepolylinker sequence was inserted into the RNA from which the TGEshad been deleted, to compensate in length for the removal of theTGEs. To eliminate any possible effects of cytoplasmic polyadenylation,both RNAs carried a point mutation in the AAUAAA that abolishesthe poly(A) addition reaction in oocytes and embryos (14, 33,50). Synthetic RNAs were injected into fertilized 1-cell embryos.At various stages of development following injection, RNA wasisolated and analyzed by gel electrophoresis and autoradiography.

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FIG. 5. tra-2 TGEs promote rapid deadenylation in Xenopus embryos. (A) Diagram of the 3'UTR RNAs used in this experiment for injections into Xenopus embryos. A box represents the coding region, and lines represent the 5'UTR and 3'UTR. The TGEs are represented by large arrows. The TGE RNA substrate consists of the entire 3'UTR of tra-2. The $Delta$ TGE RNA contains a 108-nucleotide deletion ( $Delta$ 108 nts) and lacks the TGEs and flanking sequences. To compensate for size differences, it has an insert of 108 nucleotides of vector sequences 5' to the tra-2 sequences (represented by a wavy line). Both RNAs contain a point mutation in AAUAAA (AAgAAA) and a 65-nucleotide poly(A) tail. (B) TGE RNA (lanes 1 through 11) or $Delta$ TGE RNA (lanes 12 through 22) containing AAgAAA and a A₆₅ poly(A) tail were injected into one-cell Xenopus embryos. Embryos were collected at various stages of development ranging from 1-cell to 1,000-cell stage. The position of a fully deadenylated RNA is indicated by an asterisk. (C) RNase H-oligo(dT) treatment of injected RNAs. RNA was extracted from 1,000-cell embryos injected with TGE RNA (lanes 1 and 2) or $Delta$ TGE RNA (lanes 3 and 4). Extracted RNAs were treated with RNase H-oligo(dT) (odd-number lanes) or not (even-number lanes) and then analyzed by gel electrophoresis and autoradiography. As a control for the effectiveness of the RNase H-oligo(dT) digestion, an uninjected RNA containing a poly(A) tail of A₆₅ was treated (lane 5) with RNase H-oligo(dT) or untreated (lane 6). The migration position relative to those of molecular weight standards is consistent with complete removal of the poly(A) tail.

The RNA that contained TGEs underwent rapid deadenylation (Fig. 5B, lanes 1 to 11). Fully deadenylated RNAs first appearedin the 4- to 8-cell embryo, after approximately 2.5 to 3 h (Fig.5B, lanes 3 and 4); most RNAs were deadenylated by the 32-cellto 128-cell stages (Fig. 5B, lanes 6 through 8). In contrast,the majority of the RNAs lacking the TGEs ( $Delta$ TGE) were not fullydeadenylated at any stage (Fig. 5B, lanes 12 through 22). Slowdeadenylation that occurs in the absence of specific sequenceshas been observed in both oocytes and embryos (15, 30, 38,54).

These data reveal that the TGEs affect deadenylation in at least tworespects.

(i) Kinetics and distribution of products. Shortly after injection, a minority of molecules carrying TGEs were fully deadenylated (Fig. 5A, lanes 2 through 4). In contrast,without the TGEs ( $Delta$ TGE), the entire population of RNA slowly andrelatively synchronously underwent poly(A) shortening. One simpleexplanation of these data is that deadenylation of some or allof the wild-type RNA is processive, while that of the mutant isdistributive. This possibility has not been tested rigorously,however.

(ii) Final lengths following deadenylation. The majority of the RNA molecules carrying TGEs ultimately were completely deadenylated, while the RNA lacking TGEs ( $Delta$ TGE)retained a short poly(A) tail even at very long times after fertilization(Fig. 5B). To confirm these differences, RNAs isolated from 1,000-cellembryos were incubated with oligo(dT) and RNase H (Fig. 5C). Themajority of the RNA that contained TGEs comigrated with an RNAlacking any adenosines, suggesting that it had been fully deadenylatedor nearly so in vivo (Fig. 5C, lanes 1 and 2); in contrast, theoligo(dT)-RNase H-treated RNA that lacked TGEs ( $Delta$ TGE) migratedmore slowly and possessed a poly(A) tail of approximately 15 to40 adenosines (Fig. 5C, lanes 3 and 4). The efficiency of theoligo(dT)-RNase H treatment was confirmed using a synthetic RNAwith a 65-nucleotide poly(A) tail (Fig. 5C, lanes 5 and6).

Deadenylation in frog oocytes and embryos is impeded by the presence of a non-A tract after the poly(A) tail (15, 54).To test whether the TGEs could overcome such an impediment, weprepared RNAs identical to those in Fig. 5, but carrying a 30-nucleotidetract of polylinker sequence after the 65-nucleotide poly(A) tail(Fig. 6). These RNAs were injected into 1-cell Xenopus embryos,embryos were collected at various cell stages, and RNA was extractedand analyzed on a polyacrylamide gel. With RNAs that contain TGEs,fully and partially deadenylated products appeared by the 8- to16-cell stage and accumulated thereafter (Fig. 6, lanes 1 to 11).In contrast, with the RNA lacking TGEs, deadenylation was veryinefficient, and no fully deadenylated products were detectedeven at the 1,000-cell stage (Fig. 6, lanes 12 to 22). The fractionof RNA molecules that were susceptible to the deadenylation pathwaywas only slightly reduced for the TGE RNA (compared to Fig. 5);in contrast, the $Delta$ TGE RNA was much less susceptible to deadenylation,leaving a greater fraction of the molecules full length. Thus,TGE-mediated deadenylation is not significantly impeded by thepresence of nonadenylate nucleotides following the poly(A) tail.We cannot distinguish whether the activity responsible is an exonucleaseor an endonuclease.

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FIG. 6. TGEs promote rapid deadenylation of an internal poly(A) tail. The sequence of the TGE (lanes 1 through 11) and $Delta$ TGE (lanes 12 through 22) tra-2 RNAs used here are identical to those in Fig. 5A, except that they contain an additional 30 nucleotides of vector sequence following the poly(A) tail. RNAs were injected into 1-cell Xenopus embryos. Embryos were collected at various cell stages indicated. RNA was isolated and analyzed by gel electrophoresis and autoradiography. The position of a fully deadenylated RNA is indicated by an asterisk.

We conclude that the TGEs regulate poly(A) length by affecting deadenylation. The presence of the TGEs accelerated deadenylation,caused the rapid appearance of fully deadenylated molecules, andpermitted the last 15 adenosines to be removed, resulting in theaccumulation of fully deadenylated products. Furthermore, theenhancement of deadenylation by TGEs enabled removal of even aninternal poly(A)segment.

TGE-dependent deadenylation competes with cytoplasmic polyadenylation. To determine whether TGEs promote rapid deadenylation in the presence of polyadenylation signals (AAUAAA), as would be foundin the natural mRNA, wild-type and $Delta$ TGE RNAs containing AAUAAAand a 65-nucleotide poly(A) tail were injected into 1-cell Xenopusembryos (Fig. 7A). The TGE tra-2 RNA underwent rapid and apparentlyprocessive deadenylation (Fig. 7A, lanes 1 through 11), whilethe $Delta$ TGE tra-2 RNA did not (Fig. 7A, lanes 12 through 22). Thepattern of reaction products containing AAUAAA or AAgAAA are similar(compare Fig. 5B to Fig. 7A). However, the final lengths of productswith AAUAAA are longer by approximately 20 nucleotides, suggestingcytoplasmic polyadenylation.

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FIG. 7. tra-2 TGEs promote rapid deadenylation in Xenopus embryos in the presence of both competing reactions, cytoplasmic polyadenylation and deadenylation. (A) The sequences of the TGE (lanes 1 through 11) and $Delta$ TGE (lanes 12 through 22) tra-2 RNAs used here are identical to those in Fig. 5A, except that they contain AAUAAA. RNAs were injected into 1-cell Xenopus embryos. The position of a fully deadenylated RNA is indicated by an asterisk. (B) tra-2 RNAs are substrates for polyadenylation. The RNAs used are identical to those in panel A, except that they lack a poly(A) tail as injected. TGE (lanes 1 through 11) and $Delta$ TGE (lanes 12 through 22) tra-2 RNAs were injected into 1-cell Xenopus embryos. Embryos were collected at various cell stages as indicated. RNA was isolated and analyzed by gel electrophoresis and autoradiography. The positions of RNAs with poly(A) tails of A₀ or A₆₀ are indicated. The position of the TGE RNA with an A₆₀ poly(A) tail is indicated by the < symbol.

To test directly whether the tra-2 RNAs were substrates for polyadenylation and whether TGEs could overcome poly(A) addition,we injected RNAs identical to those in Fig. 7A except that theylacked a poly(A) tail (Fig. 7B). Both the RNAs with and withoutTGEs received short poly(A) tails. The RNA that lacked TGEs ( $Delta$ TGE)continued to increase gradually in poly(A) tail length throughoutthe time course, while the wild-type tra-2 RNA maintained a shorterpoly(A) tail. We conclude that the tra-2 RNAs are substrates forcytoplasmic polyadenylation in Xenopus embryos and that theirfinal differences in poly(A) tail length are due to differencesin deadenylation rather thanpolyadenylation.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Mutations in the 3'UTR of tra-2 mRNA partially relieve translational repression of tra-2 mRNA in C. elegans and cause thehermaphrodite worm to switch to female (17). The work reportedhere permits three main conclusions. First, TGEs repress translationin Xenopus embryos but only if the mRNA carries a poly(A) tail.Second, a TGE-binding factor exists in Xenopus egg extracts. Third,TGEs promote rapid and complete deadenylation of tra-2 RNAs infrog embryos and cause tails to be shorter in C. elegans. We concludethat TGE-mediated translational repression requires either thepoly(A) tail or changes in its length and that TGE-mediated repressionand enhanced deadenylation is conserved between Xenopus and C.elegans.

TGEs and deadenylation. Several lines of evidence demonstrate that TGEs stimulate deadenylation in fertilized Xenopus embryos. In experiments usingsynthetic 3'UTRs, TGEs accelerate the rate of poly(A) removal,cause the accumulation of deadenylated molecules, and confer theability to remove an internal poly(A) segment. The effects ondeadenylation are not likely to be due to a secondary consequenceof inhibition of translation initiation or cap recognition, sinceno translational repression is observed in the absence ofpoly(A).

TGEs qualitatively alter the deadenylation reaction in a manner explicable by a shift from distributive and slow to processiveand rapid. By definition, a processive deadenylase would associatewith an RNA molecule and remove the entire poly(A) tail beforedisassociating, while a distributive deadenylase would associatewith an RNA molecule and remove only a few adenosines before disassociating.Elements in the 3'UTR of certain growth factor and lymphokinemRNAs accelerate deadenylation in somatic cells, apparently conferringeither processive or distributive characters to the reaction (6).In neither case have processive and distributive mechanisms beentested directly. A TGE-bound factor could confer processive characterto the deadenylation reaction by stably recruiting a deadenylaseor by inducing a TGE-dependent alteration in the RNP substratethat makes it more susceptible to complete and rapid deadenylation.Such an alteration might be removal of poly(A) binding protein.Alternatively, TGEs could cause endonucleolytic cleavage betweenthe poly(A) tail and the body of themRNA.

In addition to accelerating deadenylation, TGEs stabilize fully deadenylated molecules, such that they accumulate during earlycleavage stages (e.g., Fig. 5B): in their presence, synthetic3'UTR RNAs of equivalent lengths are stabilized three- to fourfoldin the embryo (data not shown). AU-rich elements (AREs), suchas those found in the 3'UTRs of c-myc and granulocyte-macrophagecolony-stimulating factor mRNAs, accelerate deadenylation andare thought to thereby destabilize the mRNA in mammalian cells(reviewed in references 6, 20, and 42). Similarly, AREsmay cause translational repression in embryos (27, 32) througheffects on deadenylation (58). Thus, both AREs and TGEs promotedeadenylation and cause repression. A protein of the ELAV family,HuR, stabilizes deadenylated molecules by interacting with AREsin a recently developed in vitro system from mammalian cells (12).Similarly, overexpression of Hel-N1 or HuR can stabilize ARE-containingmRNAs in vivo (11, 21, 40). Two different factors may beinvolved in accelerating deadenylation and stabilizing the deadenylatedspecies (12). The Xenopus embryo may contain analogous TGE-specificfactors that both accelerate deadenylation and stabilize the product(this work). AREs behave very similarly in Xenopus embryos (58).Thus, the behavior of TGEs in the embryo is similar to that ofAREs in embryos (58) and in the mammalian cell-free system (12).It is possible that common components participate in TGE- andARE-dependent regulation, though no such common RNA-binding factorshave yet been identified to ourknowledge.

Systems that promote deadenylation appear to be highly conserved. TGE-mediated translational repression is conserved betweenspecies including C. elegans, C. briggsae, Xenopus, and mammals(23; this work). Similarly, AREs from mammalian cells acceleratedeadenylation in amphibian embryos (58). Sequences in the Xenopusc-mos 3'UTR promote rapid deadenylation in embryos, as do 3'UTRelements in several other Xenopus maternal mRNAs (1, 5,30, 39). Although the sequences of AREs, TGEs, and the c-moselements are not obviously related, these diverse elements mayact through similar mechanisms. In each case, the elements acceleratepoly(A) loss in the Xenopus embryo and lead to reduced translationalactivity.

Translational regulation by TGEs. TGEs repress translation in Xenopus through a mechanism that requires a poly(A) tail. This conclusion follows from the observationsthat reporter mRNAs that possess a poly(A) tail are repressed,while those that lack one are not (Fig. 1 and 2). Moreover, TGE-mediatedrepression does not require the tra-2 5'UTR, since it is observedin C. elegans and in Xenopus with mRNAs containing various 5'UTRs(17, 23; this report). The data are consistent with two mechanisticinterpretations. First, a TGE-bound factor might interfere witha communication between the poly(A) tail and the 5' end of themRNA and the m⁷GpppG cap in particular. Subsequently, the poly(A) tail shortens,perhaps enhancing the repressed state. Alternatively, a TGE-boundfactor might repress translation by promoting deadenylation, therebydecreasing the length of the poly(A) tail. Consistent with thishypothesis, injected mRNAs that acquire comparable length poly(A)tails, added in vivo, are not repressed (notshown).

Xenopus factors and natural substrates. Recently, a TGE-binding factor, GLD-1, was identified in C. elegans using a yeast three-hybrid screen, and has been shownto specifically bind to TGEs and inhibit translation (22). GLD-1is a member of the STAR family of RNA-binding proteins (reviewedin reference 55). The single known Xenopus STAR protein, identifiedas a homologue of mouse quaking, is expressed in embryonic neuraltissue (64). It appears not to be the TGE-binding factor detectedhere, since it is undetectable in eggs or cleavage stage embryosand first appears in early gastrulation (63).

In Xenopus, TGE-mediated repression and deadenylation are detected after fertilization but not before, demonstrating thatTGE function can be regulated in stage-specific fashion in vivo.The mode of regulation of TGE activity in C. elegans is unclear,but TGE-mediated repression is required to permit spermatogenesis(10, 48). In one simple model, TGE activity is controlledtemporally. Initially, in hermaphrodites, TGEs would be active,causing rapid deadenylation and translational repression; later,TGE activity would be shut off, resulting in extension of thetail and activation of the mRNA. This mode of control would beanalogous to the regulation of several mRNAs in vertebrate oocytesduring meiotic maturation, in which short poly(A) tails are elongatedto derepress the mRNA at specific times (reviewed in reference41). Alternatively, the regulation of TGE activity might besex specific, being active in XO males, but not in XX hermaphrodites.In this model, TGEs would reduce the level of tra-2 protein presentin males, and thereby permit spermatogenesis. These two modelsare not mutually exclusive, and TGEs may repress expressionconstitutively.

The identity of the Xenopus mRNAs that are subject to the mode of repression seen with TGEs is not yet known. Although specificendogenous mRNAs are rapidly deadenylated during early frog development,the sequences that mediate that control (5, 30, 39) arenot strikingly similar to those in the TGEs. The finding thatthe TGEs of mammalian GLI mRNAs can function in C. elegans (23)and that the TGEs of C. elegans tra-2 can function in Xenopusembryos (this report), strongly suggests that multiple mRNAs withdifferent biological functions are targets of this widespreadregulatorysystem.

	ACKNOWLEDGMENTS

We are grateful to members of the Wickens and Goodwin laboratories for scientific discussions and comments on the manuscript.We appreciate the help of the U.W. Biochemistry Media Lab in preparingfigures.

Work in the Goodwin and Wickens laboratories is supported by the NIH (GM51836 to E.G. and GM31892 to M.W.).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biochemistry, University of Wisconsin $---$ Madison, 433 Babcock Dr., Madison,WI 53706-1569. Phone: (608) 262-8007. Fax: (608) 265-2603. E-mail:wickens{at}biochem.wisc.edu.

Present address: Department of Microbiology and Immunology, Stanford University, Stanford, CA94305.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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54. Varnum, S. M., and W. M. Wormington. 1990. Deadenylation of maternal mRNAs during Xenopus oocyte maturation does not require specific cis-sequences: a default mechanism for translational control. Genes Dev. 4:2278-2286[Abstract/Free Full Text].

55. Vernet, C., and K. Artzt. 1997. STAR, a gene family involved in signal transduction and activation of RNA. Trends Genet. 13:479-484[CrossRef][Medline].

56. Verrotti, A. C., S. R. Thompson, C. Wreden, S. Strickland, and M. Wickens. 1996. Evolutionary conservation of sequence elements controlling cytoplasmic polyadenylylation. Proc. Natl. Acad. Sci. USA 93:9027-9032[Abstract/Free Full Text].

57. Vize, P. D., D. A. Melton, A. Hemmati-Brivanlou, and R. M. Harland. 1991. Assays for gene function in developing Xenopus embryos. Methods Cell Biol. 36:367-387[Medline].

58. Voeltz, G. K., and J. A. Steitz. 1998. AUUUA sequences direct mRNA deadenylation uncoupled from decay during Xenopus early development. Mol. Cell. Biol. 18:7537-7545[Abstract/Free Full Text].

59. Wells, S. E., P. E. Hillner, R. D. Vale, and A. B. Sachs. 1998. Circularization of mRNA by eukaryotic translation initiation factors. Mol. Cell 2:135-140[CrossRef][Medline].

60. Wharton, R. P., and G. Struhl. 1991. RNA regulatory elements mediate control of Drosophila body pattern by the posterior morphogen nanos. Cell 67:955-967[CrossRef][Medline].

61. Wickens, M., J. Kimble, and S. Strickland. 1996. Translational control of developmental decisions, p. 411-450. In J. W. B. Hershey, M. B. Mathews, and N. Sonenberg (ed.), Translational control. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

62. Wreden, C., A. C. Verrotti, J. A. Schisa, M. E. Lieberfarb, and S. Strickland. 1997. Nanos and pumilio establish embryonic polarity in Drosophila by promoting posterior deadenylation of hunchback mRNA. Development 124:3015-3023[Abstract].

63. Zorn, A. M., M. Grow, K. D. Patterson, T. A. Ebersole, Q. Chen, K. Artzt, and P. A. Krieg. 1997. Remarkable sequence conservation of transcripts encoding amphibian and mammalian homologues of quaking, a KH domain RNA-binding protein. Gene 188:199-206[CrossRef][Medline].

64. Zorn, A. M., and P. A. Krieg. 1997. The KH domain protein encoded by quaking functions as a dimer and is essential for notochord development in Xenopus embryos. Genes Dev. 11:2176-2190[Abstract/Free Full Text].

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