Replication of Avian Sarcoma Virus In Vivo Requires an Interaction between the Viral RNA and the T{psi}C Loop of the tRNATrp Primer

Reverse transcription in avian sarcoma virus (ASV) initiatesfrom the 3' end of a tRNA^Trp primer, which anneals near the5' end of the RNA genome. The region around the primer-bindingsite (PBS) forms an elaborate stem structure composed of theU5-inverted repeat (U5-IR) stem, the U5-leader stem, and theassociation of the tRNA primer with the PBS. There is evidencefor an additional interaction between the viral U5 RNA and theT ${psi}$ C loop of the tRNA^Trp (U5-T ${psi}$ C). We now demonstrate that thisU5-T ${psi}$ C interaction is necessary for efficient replication ofASV in culture. By randomizing specific biologically relevantregions of the viral RNA, thereby producing a library of mutantviruses, we are able to select, through multiple rounds of infection,those sequences imparting survival fitness to the virus. Randomizingthe U5-T ${psi}$ C interaction region of the viral RNA results in selectionof largely wild-type sequences after five rounds of infection.Also recovered are mutant viruses that maintain their abilityto base pair with the T ${psi}$ C loop of the tRNA^Trp. To prove thisinteraction is specific to the tRNA primer, we constructed asecond library, in which we altered the PBS to anneal to tRNA^Pro,while simultaneously randomizing the viral RNA U5-T ${psi}$ C region.After five rounds of infection, the consensus sequence 5'-GPuPuCPy-3'emerged, which is complementary to the 5'-GGTTC-3' sequencefound in the T ${psi}$ C loop of tRNA^Pro. These observations confirmthe importance of the U5-T ${psi}$ C interaction in vivo.

INTRODUCTION

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Introduction

Shortly after entering a susceptible host cell, the RNA genomeof avian sarcoma virus (ASV) is reverse transcribed into a double-strandedDNA, capable of undergoing integration and all subsequent stepsof the viral life cycle. Reverse transcription utilizes a hosttRNA^Trp annealed near the 5' end of the viral genome as theprimer. Regulation of this reverse transcription is largelyat the level of initiation and is related to the presence ofmultiple stem structures in the viral RNA surrounding the primer-bindingsite (Fig. 1). These structural elements have been preservedin a wide variety of retroviruses and transposable genetic elements(4, 6, 8, 10, 12; for a review, see reference 11). In ASV, severalof these structures have been extensively studied using viralinfectivity assays and in vitro reverse transcription analysis(1, 2, 6, 7, 13). One of the less understood interactions isthat of the viral U5 RNA with the T ${psi}$ C loop of the tRNA^Trp primer.It has been shown that base substitutions into this region ofthe U5 RNA that block interactions with the T ${psi}$ C loop of tRNATrpnegatively impact virus replication in culture as well as initiationof reverse transcription reconstituted in vitro (1). These studieshave shown that this region of the viral RNA is important forreplication, but they examined only a small number of specificmutations and therefore have not been able to confirm the mechanismfor these defects.

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FIG. 1. Secondary structure around the PBS of ASV RNA. (A) The nucleotide sequence of wild-type ASV, nucleotides 56 to 130 (boldface type), is shown annealed to the 3' end of tRNA^Trp (in gray type). The solid bars indicate ASV RNA sequences in either the PBS or the T ${psi}$ C interaction region that were randomized. (B) The nucleotides of ASV RNA, altered to be complementary to tRNA^Pro (stars), annealed to the tRNA^Pro are shown. N, randomized position in viral RNA.

We have adopted a mutagenic technique that allows one to analyzein vivo, simultaneously, many possible mutations that can bemade within a small biologically important region of the viralgenome (5). This method involves placing randomized sequencesinto an infectious plasmid clone of ASV, transfecting the libraryinto turkey embryo fibroblasts (TEFs), and allowing the virusto replicate. Recovered viruses are serially passaged, and therange of biologically acceptable sequences and/or structuresis determined by direct sequencing methods. We have appliedthis method to examine the primer-binding site (PBS) and U5-T ${psi}$ Cregions of the ASV genome and the potential relationship betweenthe two. When randomizing the U5-T ${psi}$ C region of the viral RNA,sequences recovered after several rounds of infection includedboth wild-type as well as mutant sequences that maintain theability to base-pair to the T ${psi}$ C loop of the tRNA^Trp primer. Theseresults suggest that while the wild-type T ${psi}$ C-interacting sequencein the ASV genome is not absolutely required for virus replication,maintaining the ability to form this structure provides a growthadvantage to the virus. Furthermore, when the PBS sequence wasmodified to accept tRNA^Pro as the primer, and the randomizedU5-T ${psi}$ C region was subjected to selection, those bases selectedfrom the pool were predicted to maintain base pairing to theT ${psi}$ C loop tRNA^Pro instead of that to the wild-type tRNA^Trp. Thisshows conclusively that the selection of this region of theviral RNA is not directly for sequence but is for maintainingthe U5-T ${psi}$ C structure.

MATERIALS AND METHODS

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Materials and Methods

Reagents and cells. All enzymes were purchased from New England Biolabs. Deoxynucleotideswere purchased from Boehringer Mannheim. Oligodeoxynucleotideswere obtained from Genosys Biotechnologies, Inc., and from IntegratedDNA Technologies, Inc. Escherichia coli DH10B bacteria and Lipofectaminetransfection reagent were purchased from Gibco BRL. PrimaryTEFs, which do not contain endogenous retroviruses capable ofrecombining with ASV, were a generous gift from Rebecca Craven(Pennsylvania State Medical Center). The plasmids pDC101S andRCAS have been described previously (7, 9, 13). pDC101S.linkerwas created by removing a 206-bp SalI/SacI fragment encompassingnucleotides 52 to 259 of the ASV viral genome (including thePBS and surrounding stem structure) and replacing it with asmall linker fragment which preserves the SalI and SacI sitesand inserts a unique KpnI site to the vector. RCAS. ${Delta}$ .3'PBS wasderived from RCAS by removing an RsrII/EcoRV fragment immediatelydownstream of R in the 3' long terminal repeat (LTR), therebydeleting a second PBS found in the original RCAS vector. RCAS.linker ${Delta}$ .3'PBSwas created by removing a BsmI/SacI fragment, encompassing the5' LTR, from RCAS. ${Delta}$ .3'PBS, and replacing it with a small linkerfragment which preserves the BsmI and SacI sites and insertsa unique SpeI site to the vector.

Construction of randomized libraries. Wild-type pDC101S was amplified with mutagenic primers to createtwo distinct randomized PCR products, one with a randomizedPBS (rPBS) and one with a randomized U5-T ${psi}$ C interaction region(rU5-T ${psi}$ C). After amplification, the PCR products were purifiedby agarose gel electrophoresis using the QIAquick agarose gelextraction kit (Qiagen), digested with SacI and SalI, and treatedwith shrimp alkaline phosphatase to remove the 5' phosphategroups. PDC101S.linker was digested with SalI and SacI, andthe linker was removed using Microcon 50 spin columns (AmiconBioseparations). The mutant inserts were ligated to the digestedvector, using T4 DNA ligase and an insert/vector ratio of 4:1.After ligation, the reaction mixtures were heated to 65°Cfor 20 min to inactivate the T4 ligase, digested with KpnI tolinearize any residual pDC101S.linker (without insert), andelectroporated into E. coli DH10B. Each plasmid was preparedfrom bacterial cultures and sequenced to confirm the locationof the randomization. RCAS.linker ${Delta}$ .3'PBS and the randomized pDC101Splasmids were digested with BsmI and SacI. The linker fragmentwas removed from the RCAS.linker ${Delta}$ .3'PBS digestion reaction mixtureas described above. The BsmI/SacI inserts cleaved from the mutantpDC101S plasmids were gel purified, treated with shrimp alkalinephosphatase, and ligated to the digested RCAS vector as describedabove. After ligation, the plasmid DNA was digested with SpeIto linearize any residual RCAS.linker. ${Delta}$ 3'PBS. This product wasthen electroporated into E. coli DH10B. Plasmid DNA was preparedusing the Qiagen EndoFree Plasmid Maxi kit.

Construction of rPBS and rU5-T ${psi}$ C randomized libraries in the context of tRNA^Pro as primer. Mutagenic primers and the SacI/SalI sites of pDC101S were usedto create pDC101S.PBS-Pro, a plasmid where the PBS has beenmodified to be complementary to tRNA^Pro. pDC101S.T ${psi}$ C-Pro, a plasmidin which the U5-T ${psi}$ C interaction region has been modified to becomplementary to tRNA^Pro, was created in the same fashion. Themutant libraries with either a randomized PBS or U5-T ${psi}$ C interactionregion in the context of a tRNA^Pro primer were created as describedabove except that pDC101S.PBS-Pro and pDC101S.T ${psi}$ C-Pro were usedas the base plasmids from which the mutagenic inserts were amplified.

Transfection and infection of cells. TEFs were transfected with the mutant RCAS.linker. ${Delta}$ 3'PBS plasmidsusing the Lipofectamine PLUS reagent according to manufacturer'sinstructions. Cells (2 x 10⁶) in a 100-mm-diameter dish weretransfected with 8 µg of DNA. One to two days postlipofection,the medium on the cells was changed in preparation for a 24-to 48-h virus collection period. Three days postlipofection,mutant virus was harvested from the medium by centrifugationthrough 20% sucrose gradients in the presence of STE (0.1 MNaCl, 10 mM Tris-HCl [pH 8.0], 1 mM EDTA) at 4°C for 90min at 26,000 rpm in a Spinco SW27 rotor. Virus pellets weresuspended in STE, and aliquots were assayed for reverse transcriptase(RT) activity as described previously (7). Mock-transfectedcontrol cells were treated in an identical fashion. Equal quantitiesof virus (as measured by RT activity) in 1 ml of serum-freeDulbecco's modified Eagle medium were used to infect Polybrene-treated(5 µg/ml) TEFs for 1 h (2 x 10⁶ cells in 100-mm-diameterdishes). At three days postinfection, virus was harvested fromthe medium, as was done following lipofection. Serial passageinto uninfected TEFs was performed after each harvest and continuedthrough five rounds of infection, or until the library revertedto wild type.

Analysis of selected viral sequences. Infected TEFs were trypsinized, washed with phosphate-bufferedsaline, suspended in 200 µl of phosphate-buffered saline,and frozen at -20°C. Cellular DNA was purified from thesecell samples using the QIAamp tissue kit from Qiagen. The regionof viral DNA surrounding the randomized region was PCR amplifiedfrom the cellular DNA. The PCR products, which represent thepool of sequences still present within the library, were purifiedfrom a 1% agarose gel using the QIAquick agarose gel extractionkit and sequenced using the Thermo Sequenase radiolabeled terminatorcycle sequencing kit from U.S. Biochemical Corporation. Equivalentmolar amounts of each PCR product were used in each sequencingreaction mixture so that direct comparisons could be made betweensamples. Additionally, the purified PCR products were digestedwith SacI and ligated into pUC19 linearized with SacI. Ligationproducts were electroporated into E. coli DH10B, and the transformedbacteria were plated onto ampicillin selection medium. Individualcolonies were picked, suspended in 10 µl of distilledwater, heated to 95°C for 5 min, and cooled on ice for 5min, and debris was removed by centrifugation for 3 min. DNAfrom each of these colony preparations was individually sequenced.

RESULTS

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Results

Creating randomized libraries and maintaining a representative sample of each randomized pool. To investigate the role of the PBS and the U5 RNA-T ${psi}$ C interactionregion in virus replication, we introduced random sequencesinto these RNA elements and allowed the virus to select fromthe random libraries those sequences that supported replication.Random libraries were assembled by a PCR-based mutagenesis techniqueusing PCR primers with specifically randomized sequences, awild-type pDC101S template (7), and an acceptor pDC101S.linkerplasmid with a unique KpnI site introduced into a SalI/SacIfragment (see Materials and Methods). After ligation of therandomized PCR product inserts into the pDC101S.linker acceptorplasmid, each sample of ligated DNA was digested with KpnI sothat only circular ligation products with a randomized insertwere propagated in bacteria. Because a pDC101S-based vectorcannot produce infectious virus, the randomized sequences wereshuttled into RCAS (a virus vector) (7, 9). We created an RCAS.linkervector in which we removed the second copy of the PBS (downstreamof the 3' LTR) as well as the U5 sequences of the 3' LTR andinserted a unique SpeI site into a BsmI-SacI linker fragment(see Materials and Methods). Removal of these sequences is crucial,because we found that in the presence of the second PBS, recombinationevents that recover wild-type sequence from the 3' LTR, ratherthan by selecting it from the library, are possible. A poolof BsmI-SacI fragment derived from the pDC101S library was treatedwith phosphatase and ligated to RCAS cut with BsmI and SacI.The ligation products were then digested with SpeI prior totransformation of bacteria again to ensure that only circularproducts with the randomized inserts were propagated. Even ifrecircularized linker plasmids somehow escape linearizationwith KpnI (pDC101S-based ligations) or SpeI (RCAS-based digestions)and make it into the final RCAS pools, they would be replicationincompetent, because important regions of the 5' LTR were missing.This cloning strategy ensures that when wild-type ASV sequencesare recovered in viable viruses, they were derived from thelibrary and not from a contaminant.

Our largest randomized region encompasses 9 nucleotides, whichresults in a library of over 10⁶ possible sequence variations.Therefore, for the selection experiments to produce a completedata set, we must adequately sample well over 10⁶ possibilitiesat every step in the experimental process. This includes duringcloning, when each vector library is ligated and propagatedin bacteria; during transfection of TEFs with the vector libraries;and during infection of TEFs with the virus libraries. Withrespect to cloning of the libraries, each ligation reactionmixture contained a significant excess of both vector and insert,so that at least 10⁸ molecules of each was represented. Afterthe ligation products were electroporated into bacteria, thenumber of individual colonies in each electroporated bacterialculture was estimated by plating a fraction of the culture andcounting the colonies. The number of colonies in the vector-plus-insertculture was compared to the number of colonies produced fromthe culture of negative control vector alone (ligation reactionmixtures in which no insert was included). This method estimatedthe number of individual colonies, and presumably individualsequences, in each bacterial pool and verified that each possiblesequence combination was represented in the vector library harvestedfrom the bacteria.

To ensure adequate library sampling during the transfectionstep during which the RCAS-based vector libraries were introducedinto TEFs using a highly efficient lipofection technique, anestimate of transfection efficiency was made using a ß-galactosidaseexpression vector in which the ASV LTR drove ß-galactosidaseexpression. In parallel with the RCAS-based vector libraries,TEFs were transfected with the ß-galactosidase vector.The cells were then stained for ß-galactosidase expressionso that the transfection efficiency was estimated. This allowedus to verify that an adequate number of cells was transfectedto have a representative sampling of each library.

Several days posttransfection or postinfection, the virus librarieswere harvested and used to infect a fresh plate of previouslyuninfected TEFs. At the same time, wild-type virus was harvestedfrom our virus producer QT6 quail cell lines and used as a positivecontrol to monitor the course of infection and estimate themultiplicity of infection (MOI). Experiments using wild-typevirus and TEFs provided an estimate of the ratio of RT activityto 50% tissue culture infective dose (a measure of infectiousvirus). Calculation of the MOI in this manner verified thatadequate sampling of each library was achieved during the infectionprocess. In addition, by using a low MOI (0.1) and choosingtissue culture lines (QT6 and TEF) that do not contain endogenousvirus sequences related to ASV, we significantly reduce thepossibility of recombination between the mutant viral librariesand exogenous or endogenous viral sequences.

Randomization of the PBS. In ASV, the 18 nucleotides of the PBS are complementary to tRNA^Trp.If we randomized all 18 nucleotides of the PBS in a single library,there would be too many sequence possibilities to adequatelyscreen the library. We therefore targeted the 5' half of thePBS, which is complementary to the 3' end of the primer (Fig.1). As such, there should be a very strong selection for sequencesin the viral RNA that maintain the proper positioning of the3' hydroxyl end of the primer used to initiate minus strandsynthesis. In fact, the selection is strong enough that wild-typesequence dominated the library after only a single round ofinfection (Fig. 2). The presence of wild type was confirmedby sequencing several individual clones isolated from threereplicates of selected sequences. Thus, there was no tolerancefor mismatch base pairing between the 5' half of the PBS andthe 3' end of the tRNA^Trp. The results from this library alsodemonstrated that this in vivo mutagenesis procedure is capableof rapidly returning wild-type sequences when they are requiredby the virus.

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FIG. 2. Sequences recovered from the pool of viruses derived from a library in which the 5' half of the primer binding site was randomized. The PBS sequences randomized in the viral RNA are presented in Fig. 1A. "LIPO" refers to the randomized library transfected into cells. "1st INF" and refers to the pool recovered after the first round of infection derived from the transfected plate. Viral DNA was recovered from cells and sequencing as described in Materials and Methods.

Randomization of the U5-T ${psi}$ C interaction region. We have previously shown that block mutations within the U5-T ${psi}$ Cregion of ASV RNA (nucleotides 71 to 77) results in a defectin growth and initiation of reverse transcription (1). In thepresent study, random sequences were introduced into the U5-T ${psi}$ C-interactingregion (Fig. 3A) in order to examine the range of sequencescapable of supporting virus growth in vivo. In contrast to theresults observed with targeting the PBS, a significant amountof sequence variation is tolerated at these RNA nucleotide positions,even after five rounds of infection (Fig. 3A); however, analysisof the pool of sequences derived from the fifth round of replication,indicates a preference for wild-type bases at some positions(i.e., 72G, 73A, 74G, and 77C). Nineteen individual clones wereisolated from the pool and sequenced (Table 1). Five of nineteenclones returned wild-type bases at all seven positions. Twoadditional clones were able to maintain the base pairing atall seven positions. When examining the selected mutant sequencesmore carefully, it was found that several additional clonescould base pair to the T ${psi}$ C loop if the base pairing used nucleotidesthat were directly adjacent to and including bases in the U5RNA T ${psi}$ C interaction region. The range of the base pairing onthe viral RNA is indicated for each clone (Table 1). In thewild type, positions 71 to 77 are involved in this interaction,whereas the most extreme shifting resulted in the interactionwith positions 69 to 75 or 73 to 79. Thus, in 80% of the clonesthat were sequenced, the potential for base pairing betweenthe U5 RNA and the T ${psi}$ C arm of the tRNA is maintained. The factthat there are four clones with minimal potential to base pairargues that this interaction provides a growth advantage butis not absolutely required for initiation of reverse transcription.

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FIG. 3. Sequences recovered from the pool of viruses derived from a library in which the U5-T ${psi}$ C interaction region was randomized. The sequences of the ASV U5 T ${psi}$ C-interaction region that were randomized are as described in the legend to Fig. 1. All notations are as described in legend to Fig. 2. Designations such as 1st INF and 2nd INF refer to the pool recovered after the respective round of infection. (A) The U5-T ${psi}$ C randomization is done in a wild-type background. (B) The U5-T ${psi}$ C randomization is done in virus which has been altered to accept a tRNA^Pro as the priming tRNA. In the top panel the sequence of the PBS is shown for each round of infection, demonstrating that use of the alternate tRNA is maintained.

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TABLE 1. Sequences of individual clones from the randomized U5 RNA T ${Psi}$ C interaction region library

Randomization of the U5-T ${psi}$ C interaction region in virus clones that utilize tRNA^Pro. Selection of non-wild-type nucleotides, which maintain the abilityto base pair to the T ${psi}$ C arm of the tRNA^Trp, strongly suggeststhat there is a selective pressure to maintain this interaction.To prove that this is the case, we have engineered a libraryin which the PBS was mutated to accept tRNA^Pro as the primer(Fig. 1B), and we simultaneously randomized the U5-T ${psi}$ C regionof the viral RNA. As seen in Fig. 3B, there is again a significantvariation in the sequences recovered after five rounds of infection.The PBS sequences remain stable and complementary to tRNA^Prothroughout all five rounds of infections (Fig. 3B, top panel).By comparing the data in Fig. 3A and B, subtle differences canbe seen between the pools recovered from the two libraries.For example, a preference towards A and G is seen at position75 from the PBS-Pro rT ${psi}$ C library, whereas a stronger C preferenceis seen at that position in the rT ${psi}$ C library; however, the realdifferences between these libraries become obvious only afterexamining individual clones. The sequences recovered from thePBS^Pro rT ${psi}$ C library are shown in Table 2. These differ considerablyfrom the sequences selected with the wild-type PBS shown inTable 1. Aligning the sequences reveals that a consensus sequenceof G-Pu-Pu-C-Py was maintained in 20 of 24 sequenced clones.This consensus sequence has the potential to base pair to theG-G-G-U-U-C-A sequence found in the T ${psi}$ C loop of tRNA^Pro and notthe G-U-G-U-U-C-G sequence found in tRNA^Trp. Again, as seenwith the tRNA^Trp experiments, maintenance of base pairing betweenthe viral five-base consensus sequence and tRNA^Pro required,in many cases, the shifting of the relative position of annealingup or down the viral RNA by a few nucleotides. These shiftsare indicated in Table 2. The most extreme shifts utilize viralnucleotides 71 to 76 or nucleotides 76 to 79, as opposed tothe wild-type region of nucleotides 71 to 77, so again theseshifts are small and not expected to greatly distort the overallstructure of the RNA complex. In all 24 clones, at least fournucleotides were able to base pair with the T ${psi}$ C loop.

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TABLE 2. Sequences of individual clones from the PBS-Pro rT ${Psi}$ C library^b

To complement the results described above, we have created anadditional library, in which the viral RNA U5-T ${psi}$ C region wasmutated to be complementary to the T ${psi}$ C loop of tRNA^Pro, and the5' end of the PBS was simultaneously randomized. In contrastto the results shown in Fig. 2, selection of exclusively thewild type was delayed to the second round of infection (Fig.4). This indicates that even selection of the critical PBS sequencesis affected by the nucleotides present within the U5-T ${psi}$ C region.

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FIG. 4. Sequences recovered from the pool of viruses derived from a library where the primer binding site was randomized in an RNA containing U5 sequences complementary to the T ${psi}$ C loop of tRNA^Pro. All notations are as indicated in the legend to Fig. 3.

DISCUSSION

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Discussion

The primary interaction between the tRNA^Trp and the viral RNAis the 18 bases of the primer binding site. Mutations in theprimer-binding site that disrupted this interaction are lethalto virus growth. In the genetic analysis presented here, randomizationof the 5' half of the PBS, which is complementary to the 3'end of the tRNA primer, resulted in immediate selection of wild-typeclones from the virus library. This was expected since viralclones that are unable to initiate reverse transcription wouldbe eliminated from the library before completion of even a singleround of infection. This does not appear to be the case whenthe interaction between the primer tRNA T ${psi}$ C loop and the U5 viralRNA is disrupted. Previously, it had been shown that base substitutionsthat disrupt this base pairing caused a partial defect to viralreplication in vivo (1). The virus grew but at lower rates.The defect could be reproduced using a reconstituted initiationof reverse transcription system (1). The lack of an absoluterequirement for the maintenance of the U5-T ${psi}$ C interaction suggestedthat it is perhaps not part of the stable stem structure requiredat the initiation site. Instead, we theorized that this interactioncould be directing the tRNA^Trp onto the correct primer bindingsite in the 5' LTR, rather than several other regions withinthe viral RNA, which are similar enough in sequence to the PBSto base pair with tRNA^Trp. Since only properly annealed tRNAscan initiate reverse transcription, additional signals directingthe tRNA to the proper site should increase the efficiency ofassembly. An interaction such as the U5-T ${psi}$ C therefore may simplyincrease the efficiency of proper assembly, which would notbe absolutely required for virus replication, but which wouldprovide a growth advantage for viruses maintaining this interaction.

We have found that randomization of the U5-T ${psi}$ C interaction regionallows for considerable sequence diversity even after five roundsof infection. Although wild-type sequence was selected in approximately20% of the U5-T ${psi}$ C clones, they did not dominate the library aswas seen when mutating the PBS. In order to understand thisphenomenon, we examined the non-wild-type bases after five roundsof infection. In most of these mutant viruses, base pairingto the T ${psi}$ C loop of the primer was maintained, although in somecases this resulted from shifting the primer interaction a fewbases up or down the U5 RNA. This suggests that small changesin the positioning of the T ${psi}$ C loop interaction with the U5 portionof the ASV RNA can be tolerated. Larger shifts in the T ${psi}$ C interactionwould likely be prevented by the close proximity of the U5 leaderstem and the U5-inverted repeat (U5-IR) stem.

To confirm that selection of the U5 sequences of the U5-T ${psi}$ C interactionis based on the requirement for base pairing to the T ${psi}$ C loopof the primer tRNA, we engineered a virus clone which coulduse tRNA^Pro to prime reverse transcription. tRNA^Pro was chosenfor these experiments because it is present in an enriched concentrationwithin the virus particle, thereby removing primer availabilityas a limiting factor for reverse transcription initiation witha non-wild-type tRNA. Within the context of the tRNA^Pro clone,we randomized the U5-T ${psi}$ C region. As in the T ${psi}$ C library, we foundthat a great deal of degeneracy was tolerated in the selectedsequences after five rounds of infection. Again, we examinedthe mutant sequences and found that many of these clones couldbase pair to the T ${psi}$ C loop of tRNA^Pro with selection of interactionswith as many as 6 or 7-base pairs. These clones, for the mostpart, lost the ability to base pair to the T ${psi}$ C loop of tRNA^Trp.Therefore, selection of the U5-T ${psi}$ C region was dependent on thesequence of the T ${psi}$ C loop, and the ability to base pair to thisregion of the tRNA was preserved regardless of which tRNA primerwas used to initiate reverse transcription. In all of theseclones, the mutant PBS was maintained through five rounds ofinfection (Fig. 3B, top panel). As an additional control, weinfected TEFs with a mutant virus containing tRNA^Pro PBS witha wild-type T ${psi}$ C interaction region. These viruses also maintainedthe alternate tRNA usage through five rounds of infection (datanot shown). This is consistent with the work of Whitcomb etal. (16), who have shown that tRNA^Pro can function for up to15 rounds of infection in chicken embryo fibroblasts beforereversion to use of the wild-type tRNA. It is likely with theadded changes in the T ${psi}$ C interaction domain that usage of thealternate tRNA could persist for much longer. Also adding tothe stability of the alternate tRNA usage in this study is thelack of ASV-related endogenous retroviral sequences in TEFs(see Materials and Methods).

This is the first study which clearly shows that in vivo, therole of specific ASV sequences upstream of the PBS is to basepair to the T ${psi}$ C loop of the primer. The fact that shifting ofthe interaction up or down the viral RNA does not cause a defectin initiation was somewhat unexpected, because previous studiesshowed that contorting the stem structure would cause a defectin viral growth (2). However, if the interaction was transientor weak, as suggested by previous nuclease mapping experiments(14), and only required for initial placement of the tRNA ontothe correct PBS sequence, then shifting of the T ${psi}$ C interactionwould not affect the overall stem structure. This type of biologicalrole for the U5-T ${psi}$ C interaction region would explain previousdata from in vitro reverse transcription initiation experiments,where the T ${psi}$ C interaction was found to be much less importantwhen using very short RNA templates compared to longer templates.This was presumably because it was easier for the tRNA to findthe correct priming location on a shorter RNA (unpublished observations).In addition, if the primary role of the U5-T ${psi}$ C interaction regionwas to increase the efficiency of proper tRNA placement on theviral RNA, then the lack of this interaction would not preventvirus replication, but simply decrease the efficiency of replication,as shown by previous in vivo data.

Another factor that may drive the selection of clones with ashifted interaction is that in the PBS^Pro-T ${psi}$ C library, many ofthe clones with a +3-shifted interaction use two nonmutatedflanking nucleotides in the 5-bp interaction they maintain.This means that the virus needs only to select appropriate nucleotidesat three positions (two of which need only to select a purine)so that 1 in 16 of the clones from the input library would meetthe criteria for this interaction. The fact that these clonesdid not immediately dominate the library suggests that theyare likely at least partially defective, but are still ableto replicate well enough to persist through five rounds of infection.

The relative importances of the PBS and U5-T ${psi}$ C interaction inreverse transcription initiation and viral replication are reflectedin how quickly certain sequences were selected in vivo afterrandomization of each region. The PBS is absolutely requiredfor replication, a situation reflected in the fact that predominantlywild-type sequences were selected from the randomized PBS viruslibraries after only one round of infection. In contrast, theU5-T ${psi}$ C interaction region, which we believe plays a role primarilyduring tRNA placement, and therefore is not absolutely requiredfor replication, did not show definitive sequence selectionuntil multiple rounds of selection were complete. This modelof ASV reverse transcription initiation is supported by studiesin HIV-1, which have found that secondary interactions betweenthe tRNA primer and U5 sequences enhance proper placement ofthe tRNA and stabilize its interaction with the viral RNA (3).In the case of HIV-1, two interactions between the primer andthe viral RNA are required for virus growth. There is a primaryinteraction between the primer and the PBS and a secondary interaction between anti codon loop of the primerand the loop region of the U5-IR stem (7). When both the PBSand the U5-IR stem-loop are altered to be complementary to tRNA^His,the virus grows and stably maintains the use of the new tRNAduring successive rounds of viral replication. If only the PBSis changed, the virus reverts to using the wild-type to replicate (15). Recently, it has been proposedthat an additional interaction between the T ${psi}$ C loop of the primerRNA and a portion of the HIV-1 leader stem is involved in activationof reverse transcription (4). Both the primary and secondaryinteractions between the viral RNA and tRNA are similar in theavian and HIV model systems. In both cases the T ${psi}$ C interactionseems to be related to the very early stages of initiation,either by proper positioning of the tRNA or by signaling forinitiation. While HIV maintains the additional interaction withthe anticodon loop that is absent in the avian virus, the similaritiesobserved with the T ${psi}$ C interaction demonstrate some level of conservedmechanism between different families of retroviruses.

ACKNOWLEDGMENTS

This work was supported in part by United States Public Healthgrants CA38046 and CA52047 (to J.L.) and CA43600 (to E.S.).S.M. is supported by grant GM07250 from the National Institutesof Health. M.J. is supported by Carcinogenesis Training Programgrant CA09560 from the National Institutes of Health.

We thank Rebecca Craven for the generous gift of primary turkeyembyro fibroblasts.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, Northwestern University School of Medicine, 303 E. Chicago Ave., Chicago, IL 60611. Phone: (312) 503-0338. Fax: (312) 503-2790. E-mail: j-leis{at}northwestern.edu.

REFERENCES

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