A Novel Polymorphism at Codon 333 of Human Immunodeficiency Virus Type 1 Reverse Transcriptase Can Facilitate Dual Resistance to Zidovudine and L-2',3'-Dideoxy-3'-Thiacytidine

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J Virol, June 1998, p. 5093-5098, Vol. 72, No. 6
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

A Novel Polymorphism at Codon 333 of Human Immunodeficiency Virus Type 1 Reverse Transcriptase Can Facilitate Dual Resistance to Zidovudine and L-2',3'-Dideoxy-3'-Thiacytidine

Sharon D. Kemp,¹^, Chaofu Shi,² Stuart Bloor,¹^, P. Richard Harrigan,¹^, John W. Mellors,²^,³^,⁴ and Brendan A. Larder¹^,^*

Clinical Virology Research Unit, Medicines Research Centre, Glaxo Wellcome Research and Development, Stevenage, United Kingdom,¹ and Department of Infectious Diseases and Microbiology, Graduate School of Public Health,² and Department of Medicine, School of Medicine,³ University of Pittsburgh, and Veterans Affairs Medical Center,⁴ Pittsburgh, Pennsylvania

Received 8 September 1997/Accepted 3 March 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Recent clinical trials examining 3'-azido-3'-deoxythymidine (AZT, zidovudine, or Retrovir) combined with L-2',3'-dideoxy-3'-thiacytidine(3TC or lamivudine) have shown that combination therapy with thesenucleoside analogs affords significant virological and clinicalbenefits. The addition of 3TC to AZT delays AZT resistance intherapy-naive patients and can restore viral AZT susceptibilityin patients who previously received AZT alone. In some AZT-experiencedpatients, the virological response to AZT-3TC therapy is not sustainedand virus resistant to both drugs can be identified. To gain insightinto the possible mechanism of dual resistance, we studied a recentlydescribed variant resistant to both AZT and 3TC and obtained bysimultaneous passage of an AZT-resistant clinical isolate in cellculture with AZT and 3TC. Genetic mapping and site-directed mutagenesisexperiments demonstrated that a polymorphism at codon 333 (Glyto Glu) of human immunodeficiency virus type 1 reverse transcriptase(RT) was critical in facilitating dual resistance in a complexbackground of AZT and 3TC resistance mutations. To assess thepotential clinical relevance of RT codon 333 changes, we studieddually resistant viruses from patients taking AZT and 3TC. Geneticmapping of RT molecular clones derived from patients' plasma samplesdemonstrated that in some cases polymorphism at codon 333 wasresponsible for facilitating dual resistance.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Zidovudine (3'-azido-3'-doexythymidine, AZT, or Retrovir) is commonly used in combination with other antiretroviral agentsfor the treatment of human immunodeficiency virus type 1 (HIV-1)infection. AZT therapy delays the development of AIDS and increasesthe survival of patients with AIDS (6, 12, 39). Long-termtreatment with AZT monotherapy results in the eventual developmentof resistance to AZT (22, 26, 33), which ultimately leadsto treatment failure (4, 32). Site-directed mutagenesis experimentshave demonstrated that at least five amino acid changes in reversetranscriptase (RT) of HIV-1 (at codons 41, 67, 70, 215, and 219)are responsible for AZT resistance (16, 20; for reviews, see references19 and 31). The first mutation to arise after several monthsof AZT monotherapy is typically at codon 70, which results inan approximate eightfold increase in the 50% inhibitory concentration(IC₅₀). More resistant viruses, usually having combinations ofmutations that include changes at codons 41 and 215, subsequentlybecome dominant in the resistant virus population (3, 17).Highly AZT-resistant variants (with IC₅₀s increased more than100-fold) require the accumulation of four to six mutations inRT, frequently including a recently recognized mutation at codon210 of RT (10, 11).

In contrast to AZT resistance, high-level resistance to the nucleoside analog L-2',3'-dideoxy-3'-thiacytidine (3TC or lamivudine)is conferred by a single mutation in HIV-1 RT at codon 184 (Met-184to Val or occasionally Ile) (2, 7, 34, 38). The appearanceof this mutation during 3TC therapy is associated with an increasein plasma HIV-1 levels and treatment failure (35). Of note isthat the 184 Val mutation causes a concomitant increase in AZTsensitivity in genotypically AZT-resistant backgrounds (2,24, 38). Furthermore, AZT-3TC combination therapy in drug-naivepatients leads to a delay in the appearance of AZT resistancemutations even though 3TC resistance occurs rapidly (18, 24).These observations have prompted speculation that dual resistanceto both drugs may not develop easily, as phenotypic AZT resistancein the presence of the 184 Val mutation may be rare.

The results of several clinical trials examining the safety and efficacy of AZT-3TC combination therapy have recently beenpublished (1, 5, 14, 37). Collectively, these studiesshowed substantial effects on virological markers and significantclinical benefit in either therapy-naive or AZT-experienced patients.One plausible explanation for the duration of this benefit intherapy-naive patients is the observed delay in the developmentof AZT resistance, as discussed above. In AZT-experienced patients,more complex patterns of virological response and resistance havebeen observed, ranging from restoration of AZT susceptibilityto the development of AZT-3TC dual resistance (13, 27, 28).

An HIV-1 variant that was selected in cell culture and that became simultaneously highly resistant to AZT and 3TC was recentlydescribed (8). This mutant was obtained by cell culture passagein both AZT and 3TC of a preexisting highly AZT-resistant clinicalisolate (1373). To increase our understanding of how HIV-1 canbecome resistant to both AZT and 3TC, we describe a mapping andsite-directed mutagenesis study designed to define the geneticbasis of dual resistance of this cell culture-selected variant.A novel polymorphism at RT codon 333 was shown to be responsiblefor facilitating dual resistance in the context of AZT and 3TCresistance mutations. To determine the relevance of this codon333 polymorphism in AZT- and 3TC-treated patients, we studiedHIV-1 clinical isolates by genetic mapping of RT molecular clones.In some cases, polymorphism at codon 333 was responsible for facilitatingdual resistance.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Cloning and sequencing of the HIV-1 RT gene from virus resistant to AZT and 3TC. The RT coding region (1.7 kb) of the AZT- and 3TC-resistant virus was amplified by PCR from infected-cell DNA and cloned intothe M13 vector mptac18.1 as described previously (20). Single-strandedDNAs from this clone (mpAZT^r3TC^r) and the 3TC-susceptible, AZT-resistant parental clone (mpAZT^r1373) were sequenced with a PRISM Sequenase terminator single-strandedDNA sequencing kit (Applied Biosystems) and resolved on an ABI373 DNA sequencer (25). Recombinant clones containing a 1.7-kbfragment were assessed for the ability to express active RT byinduction of M13-infected Escherichia coli (strain 5KCPolA^tsF') with isopropyl-D-thiogalactopyranoside and measurement ofRT activity in E. coli lysates as described previously (20).

Construction of HIV-1 variants with recombinant RT genes. The EcoRI-EcoRV fragment encoding the equivalent of RT codons 1 to 143 was purified from mpAZT^r3TC^r and mpRTMQ+184V, a mutant construct that was described previouslyand that carries 41Leu, 67Asn, 70Arg, 184Met, and 215Tyr in theHIV-1_HXB2-D background (24). The fragments were then ligatedwith EcoRI-EcoRV-digested mpRTMQ+184V and mpAZT^r3TC^r, respectively, to form recombinant clones. The KpnI fragmentencoding the equivalent of RT codons 428 to 535 (i.e., most ofthe RNase H domain) was purified from M13 clone HIV-1_XHB2 andligated with KpnI-digested mpAZT^r3TC^r. The entire RT coding region from each of these recombinant cloneswas linearized by digestion with EcoRI and HindIII and subsequentlytransferred into the otherwise wild-type HIV-1_HXB2-D backgroundby homologous recombination. The T-cell line MT-2 (9) was cotransfectedby electroporation with a mixture of the RT-deleted proviral clonepHIVRTBstEII and the EcoRI- and HindIII-digested DNA describedabove (15). A PCR fragment (codons 7 to 243) derived from mpAZT^r3TC^r with the oligonucleotide primer pair comb2 and comb3 (24) wasalso used in recombination experiments with the pHIVBst11071 clone,which contains a 578-bp deletion in RT from codons 40 to 231 (24).

Site-directed mutagenesis of RT and construction of HIV-1 recombinants. Mutations in the RT gene were created by site-directed mutagenesis of the M13 clones mpAZT^r3TC^r and mpRTMQ+184V as described previously (23). Variants wereconstructed to convert mutant RT codon 333 (Glu) to wild-typeGly in mpAZT^r3TC^r and to convert wild-type RT codon 333 (Gly) in mpRTMQ+184V tomutant Glu. Mutations were verified by DNA sequence analysis asdescribed above. M13 replicative-form DNA was prepared, and thealtered RT coding regions were transferred into the HIV-1_HXB2-Dgenetic background by homologous recombination with pHIVRTBstEIIas described above.

Construction of infectious clones containing RT derived from plasma HIV-1 RNA. To produce HIV-1 infectious clones from plasma viral RNA, we used a recently described system based on the novel cloning vectorxxLAI-np (36). HIV-1 RNA was extracted from 1.0 ml of patientplasma with RNAzol B (Biotecx Laboratories, Inc., Houston, Tex.).RNA from the equivalent of 100 to 500 µl of plasma and 10 pmolof downstream PCR primer were used for cDNA synthesis with SuperScriptIIRNaseH RT (Gibco-BRL, Long Island, N.Y.). A nested PCR strategy wasused to amplify the 1,460-bp RT fragment (codons 15 to 440) fromthe cDNA as described previously (36). The PCR products werecolumn purified (Promega Corporation, Madison, Wis.), digestedwith XmaI and XbaI, and repurified by ethanol precipitation (thisproduct is referred to as xxRT). The vector backbone was preparedby digesting xxLAI-np with XmaI and XbaI. Approximately 0.02 µgof xxRT was ligated with 0.02 µg of gel-purified xxLAI-np backboneby use of T4 DNA ligase (Promega), and the entire ligation mixturewas used to transform competent E. coli JM109. The proviral librarieswere expanded by overnight growth in Luria-Bertani broth containingampicillin. Individual proviral clones were isolated by spreadingthe transformed cells onto Luria-Bertani agar plates containingampicillin. Proviral DNA was purified (Qiagen Inc., Chatsworth,Calif.) and screened for the 1,460-bp xxRT insert by digestionwith XmaI and XbaI. Recombinant viruses were produced by electroporating5 µg of recombinant DNA into MT-2 cells as described above. Supernatantscontaining virus were harvested at the peak of cytopathic effect,which occurred 5 to 7 days after transfection.

Fragment exchange and site-directed mutagenesis in the xxLAI-np vector. The 1,460-bp XmaI-XbaI fragment was cut from single coresistant proviral clones, separated by agarose gel electrophoresis,and purified with a GeneClean II kit (Bio 101, Inc., La Jolla,Calif.). The fragment was then digested with BstYI, PflmI, andBsp1286I to generate XmaI-BstYI, XmaI-PflmI, and XmaI-Bsp1286Ifragments corresponding to codons 14 to 190, 14 to 315, and 14to 359 of RT, respectively. Similarly, BstYI-XbaI, Pflm1-XbaI,and Bsp1286I-XbaI fragments were isolated from wild-type xxLAI.The fragments were gel purified and ligated with the xxLAI-npbackbone to generate proviruses with RT amino acid residues 14to 190, 14 to 315, and 14 to 359 derived from coresistant clones.Site-directed mutagenesis of the XmaI-XbaI RT fragment was carriedout with an Altered Sites in vitro mutagenesis system (Promega).XmaI-XbaI fragments from individual viral clones were ligatedinto the pALTER-1 mutagenesis vector, and single-stranded DNAwas prepared and used as a template in mutagenesis reactions.Mutant colonies were screened by direct sequencing of the plasmidDNA. XmaI-XbaI fragments containing the desired mutations werethen cloned into xxLAI-np for the production of infectious virusby electroporation of MT-2 cells as described above.

AZT and 3TC susceptibility assays. The AZT and 3TC susceptibilities of HIV-1 variants with recombinant RT genes and site-directed mutant viruses were determinedby a plaque reduction assay with the HeLa-CD4⁺ cell line HT4LacZ-1 by infection of cell monolayers as describedpreviously (21, 36). The resulting syncytia were counted followingstaining with either methyl violet (21) or 5-bromo-4-chloro-3-indolyl- $beta$ -D-galactopyranoside(36). The IC₅₀s were determined by linear regression analysisof the log₁₀ inhibitor concentration versus percent inhibitionof syncytium formation.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Analysis of an AZT- and 3TC-resistant laboratory strain. We first confirmed by a plaque reduction assay with HeLa-CD4⁺ cells the previously reported drug susceptibility of the 1373virus before and after passage in AZT and 3TC (8). As anticipated,the initial isolate was AZT resistant and 3TC sensitive (respectiveIC₅₀s, 1.98 and 3.89 µM). In contrast, the passaged virus remainedAZT resistant but was also 3TC resistant (respective IC₅₀s, 0.86and >200 µM). We next sequenced the entire RT coding regions fromthe AZT- and 3TC-resistant variant AZT^r3TC^r as well as the parental virus. Both viruses had the followingAZT resistance mutations: Met41Leu, Asp67Asn, Lys70Arg, Leu210Trp,and Thr215Tyr. In addition, we found six differences between theseviruses in the deduced amino acid sequence of RT (i.e., Arg20Lys,Thr39Lys, Met184Val, Asp192Glu, His480Gln, and Lys558Arg). Theonly recognizable drug resistance mutation induced during thepassage experiment was the 3TC resistance mutation Met184Val.

Mapping AZT and 3TC dual resistance mutations by marker transfer. In order to map the mutation(s) responsible for the AZT and 3TC dual resistance phenotype of the AZT^r3TC^r virus, experiments were performed in which RT DNA fragments weretransferred between the dually resistant virus and the laboratory-derivedmutant RTMQ+184V (carrying Met184Val and the AZT resistance mutationsMet41Leu, Asp67Asn, Lys70Arg, and Thr215Tyr in the HIV-1_HXB2-Dbackground). The source of DNA for these marker transfer experimentswas M13 clones containing mutant RT coding regions. As shown schematicallyin Fig. 1, the EcoRI-EcoRV fragment encompassing codons 1 to 143of the RT polymerase domain was exchanged between the M13 clonempAZT^r3TC^r described above and mpRTMQ+184V. The KpnI fragment carrying codons428 to 535 of RT (virtually all of the RNase H domain) was exchangedbetween the M13 clone HXB2 mpAZT^r3TC^r. Infectious viruses with recombinant RT genes were recoveredby recombination with the RT deletion proviral clone pHIVRTBstEII.A PCR fragment derived from mpAZT^r3TC^r with the oligonucleotide primer pair comb2 and comb3 was alsoused in the recombination experiments, but in this case, withthe partial RT deletion clone pHIVBst11071 (24). This procedureresulted in the transfer of a mutant RT fragment containing RTcodons 40 to 231.

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FIG. 1. Mapping AZT and 3TC dual resistance in HIV-1 strain AZT^r3TC^r. In order to map dual resistance in laboratory isolate AZT^r3TC^r, various RT fragments were exchanged between either mpAZT^r3TC^r and the wild-type virus (HIV-1_HXB2-D) or AZT^r3TC^r and RTMQ+184Val (RTMQ+184). RTMQ+184Val contains the following RT mutations in the HIV-1_HXB2-D background: Met41Leu, Asp67Asn, Lys70Arg, Met184Val, and Thr215Tyr. The open bars represent HIV-1_HXB2-D RT, the solid bars represent AZT^r3TC^r RT, and the hatched bars represent RTMQ+184Val RT. The numbers above the bars are the amino acid positions at which RT fragments were exchanged. In recombinant RRcomb2,3, residues 40 to 231 represent the size of the deletion in the deletion clone used to construct the virus; since this virus was constructed by recombination, the maximum possible size of the mutant fragment in the virus is the size of the deletion. Recombinant viruses were assessed for AZT susceptibility with the HeLa-CD4⁺ cell assay as described in Materials and Methods.

The sensitivity of these viruses to AZT and 3TC was assessed by a plaque reduction assay with the HeLa-CD4⁺ cell line HT4LacZ-1 (Fig. 1). The virus RR/Q184, constructedwith the RT fragment 5' of the EcoRV site from the dually resistantvirus and the RT fragment 3' of the EcoRV site from RTMQ+184V,was sensitive to AZT (IC₅₀, 0.07 µM) and resistant to 3TC (IC₅₀,>200 µM). Although this virus contained four of the known AZTresistance mutations (at codons 41, 67, 70, and 215), the codon184 mutation suppressed AZT resistance in this background (24).The recombinant Q184/RR, constructed conversely to that above,was resistant to both drugs (AZT IC₅₀, 2.13 µM; 3TC IC₅₀, >200µM). This fact indicated that the mutation(s) responsible fordual resistance mapped to the RT fragment 3' of the EcoRV site(codons 143 to 560). To address the role of the mutations betweencodons 143 and 231, a recombinant virus was constructed by cotransfectingthe comb2-comb3 PCR fragment (spanning RT codons 7 to 243) withthe RT deletion clone pHIVBst11071 (with a deletion of codons40 to 231). The resulting virus, RRcomb2,3, was AZT sensitive(IC₅₀, 0.09 µM) and 3TC resistant (IC₅₀, >200 µM). Finally, weassessed the drug sensitivity of recombinant RR/Kpn_HXB2-D, whichcontained virtually the whole RNase H domain from the wild-typevirus (codons 428 to 535) in the background of the dually resistantstrain. This virus retained AZT resistance (Fig. 1) and was alsoresistant to 3TC (IC₅₀, >200 µM). From these results, it was clearthat the mutation(s) responsible for dual resistance mapped tothe 3' end of RT between codons 231 and 428 or between codons536 and 560.

Construction of HIV-1 strains with codon 333 polymorphisms. Closer inspection of the 3' end of RT (from codons 231 to 428 and 536 to 560) revealed nine amino acid changes between HIV-1_HXB2-Dand AZT^r3TC^r (i.e., Gly333Glu, Gly359Ser, Ala371Val, Ile375Val, Thr376Ala,Lys390Arg, Glu404Asp, Phe416Tyr, and Lys558Arg). All of thesechanges were seen in the parental 1373 virus, except for codon558, which was Lys, as in HIV-1_HXB2-D. Of these residues thatcould have been responsible for the dual resistance phenotype,codon 333 was highly conserved among wild-type HIV-1 variants,whereas the other residues were less conserved. It should be noted,however, that the Gly333Glu polymorphism was not selected duringin vitro passage but was already present in the parental virus(AZT-resistant isolate 1373). Nevertheless, because amino acidconservation implies an important role in the function of theenzyme, we decided to construct variants by site-directed mutagenesisto assess the potential role of the Gly333Glu polymorphism inAZT and 3TC coresistance.

First, we converted codon 333Glu in the dually resistant variant to the wild-type residue, Gly. The resulting variant was3TC resistant but showed a marked increase in sensitivity to AZT(3TC IC₅₀, 200 µM; AZT IC₅₀, 0.06 µM) (Fig. 2). Next, we introducedthe Gly333Glu polymorphism into the AZT-sensitive, 3TC-resistant(IC₅₀, >200 µM) laboratory variant RTMQ+184V. This process renderedthe resulting virus resistant to both AZT (IC₅₀, 1.73 µM) and3TC (IC₅₀, >200 µM) (Fig. 2).

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FIG. 2. AZT susceptibility of recombinant HIV-1 variants with altered RT codon 333. Recombinant viruses were constructed by site-directed mutagenesis in order to alter RT codon 333. This codon was changed from Glu to Gly in the dually resistant strain AZT^r3TC^r (designated RR) to produce RR/333G. In addition, codon 333 was changed from Gly to Glu in the laboratory isolate RTMQ+184Val (designated RTMQ+184V) to produce Q184V+333E. RTMQ is an AZT-resistant strain based on HIV-1_HXB2-D and containing the following changes in RT; Met41Leu, Asp67Asn, Lys70Arg, and Thr215Tyr. Recombinant viruses were assessed for AZT susceptibility with the HeLa-CD4⁺ cell assay as described in Materials and Methods.

Genetic analysis of dually resistant HIV-1 from AZT- and 3TC-treated patients. Recombinant viruses containing RT sequences derived from plasma HIV-1 RNA were constructed with samples from five patientsreceiving AZT and 3TC and in whom treatment failure was suspectedfrom declining CD4⁺ T-cell counts (50% decrease from baseline) and/or a new onsetof HIV-1-related symptoms (27). Baseline (pretherapy) sampleswere not available for analysis. HIV-1 RT fragments (1,460 bp)were derived by RT-PCR of plasma viral RNA and were subsequentlyligated into the RT cassette cloning vector xxLAI-np in orderto obtain infectious HIV-1 molecular clones. Clonal mixtures andindividual subclones were used to generate infectious virus forAZT and 3TC susceptibility determinations. Recombinant virusesderived from the clonal mixtures (not shown) as well as the individualsubclones (Table 1) showed dual resistance to AZT and 3TC forall five patients. Recombinant viruses derived from four controlpatients who had stable CD4⁺ T-cell counts and no HIV-1-related symptoms on AZT and 3TC therapyshowed resistance to 3TC (IC₅₀, >30 µM) but not AZT (IC₅₀, <0.01µM) (data not shown).

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TABLE 1. AZT and 3TC susceptibilities of recombinant virus clones derived from plasma HIV-1 RNA from five patients

We next performed a series of fragment exchange experiments with dually resistant proviral clones in which mutant sequenceswere exchanged for wild-type sequences to derive a series of chimericrecombinant strains (containing fragments from dually resistantclones corresponding to RT amino acids 14 to 190, 14 to 315, and14 to 359). Dual resistance mapped to RT regions encoding aminoacids 190 to 315 in three of these clones and to amino acids 315to 359 in the remaining two clones (Table 2). The genotypes ofthese clones, shown in Table 3, revealed the presence of thecodon 333 polymorphism in the two clones (G2-2a and V213b) inwhich dual resistance mapped to regions encoding amino acids 315to 359. Sequencing of the original clonal mixtures from whichthe subclones were derived also demonstrated the polymorphismat codon 333, indicating that it was the predominant species inthe plasma samples (data not shown).

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TABLE 2. Mapping AZT and 3TC dual resistance in clones from clinical isolates

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TABLE 3. Genotypes of five AZT- and 3TC-resistant clones from patient samples

The relevance of the Gly333Glu-Asp polymorphisms for the dual resistance of these clones was determined by reversion of theGlu or Asp residues by site-directed mutagenesis to the wild-typeresidue, Gly. Drug susceptibility analysis showed that the AZTsusceptibility of the revertants had increased by six- to sevenfold(Table 4). Conversely, conversion of the natural Gly333 residueto Asp in the LAI background containing only 41Leu, 184Val, 210Trp,and 215Tyr resulted in a 7.7-fold decrease in AZT susceptibility(Table 4).

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TABLE 4. AZT susceptibility of HIV-1 clones from clinical samples with a reversion at RT codon 333

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The initial aim of this study was to elucidate the genetic basis of AZT and 3TC dual resistance in a laboratory-derived HIV-1isolate. This topic was of interest for a number of reasons. First,early attempts to select such variants by cell culture passageexperiments were unsuccessful, presumably because of the effectof the 184Val mutation on AZT resistance (24). Second, it hasrecently become evident that in addition to the occurrence ofrestored phenotypic AZT susceptibility, AZT- and 3TC-resistantvariants may emerge during combination AZT-3TC therapy (13,27, 28). This finding appears more common in the context ofextensively AZT-experienced patients receiving AZT-3TC combinationtherapy and who already have AZT-resistant virus. Thus, we anticipatedthat a clearer understanding of the genetic nature of dual resistancein a laboratory variant would provide a broader understandingof this mechanism, particularly in clinical strains.

It was quite unexpected that our mapping and site-directed mutagenesis studies would reveal a polymorphism at codon 333 inRT as the change responsible for facilitating dual resistance.This finding was particularly intriguing because the Gly333Gluchange was not selected during passage of the virus in AZT and3TC but already existed in the initial AZT-resistant strain. Thisvariant was already highly AZT resistant and contained five ofthe six recognized AZT resistance mutations (at codons 41, 67,70, 210, and 215). Selection of the 184Val mutation by passagein AZT and 3TC subsequently conferred high-level 3TC resistance.However, in the context of the preexisting 333Glu polymorphism,it appeared that 184Val no longer exerted the expected AZT resistancereversal effect. This result was proven in two ways. First, conversionof 333Glu to Gly in the dually resistant variant caused a concomitantswitch to an AZT-susceptible phenotype. Second, mutation of thewild-type Gly333 residue to Glu in the AZT-susceptible laboratoryisolate RTMQ+184V resulted in an AZT resistance phenotype despitethe presence of 184Val. It should be noted that the 333Glu changealone is not responsible for conferring dual resistance but somehowinfluences AZT susceptibility in the context of AZT and 3TC resistancemutations.

The precise molecular mechanism by which 333Glu modulates AZT resistance in the presence of 184Val and AZT resistance mutationsis not obvious. The crystal structure of HIV-1 RT shows that residueGly333 in the p66 subunit is located far from the polymerase activesite (approximately 42 Å from the carbon of residue 333 to thatof residue 184), in the so-called connection domain of the enzyme(29, 36a). This domain lies between the palm region in thepolymerase domain and the RT carboxy terminus, which comprisesthe RNase H domain (29). Gly333 in the RT p66 subunit is alsopositioned close to the base of the thumb region, which is involvedin template-primer interactions. Thus, it is possible that changesat this position alter the positioning of the thumb region andsubsequently reposition the template-primer in the active siteof the polymerase domain. Recently, the crystal structure of HIV-1RT containing four AZT resistance mutations was solved. The structureshowed that AZT resistance mutations at codons 215 and 219 giverise to a conformational change in the RT polypeptide that extendsto the active-site Asp residues (30). Clearly, long-range effectsof these mutations can modulate the recognition of AZT triphosphatein the polymerase active site. Similarly, crystal structures ofmutant RT enzymes harboring the 333Glu change together with AZTand 3TC resistance mutations may reveal specific movements inthe enzyme active site and shed light on this molecular mechanismof dual resistance.

We conducted an investigation of the genetic basis of dual resistance in recombinant viruses containing RT sequences fromfive patients with clinical evidence of AZT and 3TC treatmentfailure. We used a novel RT cassette cloning system which enablesthe generation of infectious HIV-1 clones that can be used toproduce virus for a susceptibility analysis. We found that virusesfrom two of these individuals were dually resistant due to aminoacid polymorphisms in the RT region from residues 315 to 359.Sequence analysis revealed the previously recognized change atcodon 333 of Gly to Glu, in addition to a novel change of Glyto Asp. Reversion of Glu or Asp to Gly unequivocally demonstratedthat these polymorphisms were responsible for facilitating dualresistance in the context of the AZT and 3TC resistance mutations.Thus, it appears that this mechanism of dual resistance can occurin patients in a manner similar to that in the laboratory variantthat we analyzed. Final confirmation that the 333Asp residue influencesdual resistance came from the conversion of Gly to Asp in a clonallaboratory LAI strain that contained 184Val plus AZT resistancemutations. Therefore, it appears that the Asp substitution atcodon 333 causes a phenotypic effect similar to that of the Glusubstitution. We assume that, as in the situation with the 1373virus, the observed polymorphisms at codon 333 in isolates G2-2aand V213b were preexisting. Since we did not have pretherapy samples,we cannot rule out the possibility that these changes at codon333 appeared during therapy. However, sequence analysis of baselinesamples from about 100 AZT-experienced individuals who participatedin the AZT-3TC combination therapy trial NUCB3002 showed thatthe codon 333 polymorphisms preexisted in the viral populationat a frequency of 10% (unpublished observations).

A recent report suggested that AZT and 3TC dual resistance in clinical isolates from four individuals was a function of theoverall number of amino acid changes in RT (28). In that study,changes in the C-terminal region of RT (between residues 261 and561) were not found to play a major role in dual resistance. However,only one of these isolates had a high level of AZT resistancesimilar to that of the laboratory and clinical isolates examinedin our study. Only this isolate is analogous to the clonal samplesG2-1b, G2-3g, and V178a analyzed here. The other three isolatesreported by Nijhuis et al. (28) displayed various degrees ofpartial resistance to AZT. Although sequence data were not shown,we anticipate that in these isolates the 333Glu-Asp polymorphismwas not present. Thus, the fact that these isolates were not highlyAZT resistant is consistent with the 184Val mutation still havinga suppressive effect.

Our findings regarding the influence of residue 333 on AZT resistance obviously have implications for the interpretation ofHIV-1 RT genotypic profiles from clinical samples. By focusingonly on the six recognized AZT resistance mutations plus codon184, it is clearly not possible to derive an accurate pictureof the viral phenotype. Under certain circumstances, a virus maybe phenotypically AZT susceptible because of the influence of184Val, even though significant numbers of AZT resistance mutationsare present. Conversely, a virus may be phenotypically AZT resistantwhen all of these mutations are present along with polymorphismat codon 333. Therefore, sequence information from the 3' regionof RT in addition to the 5' region is required to make more reliablepredictions about the likely phenotype. However, the situationregarding AZT and 3TC dual resistance is obviously quite complex.Additional polymorphisms in the 3' region of RT may also turnout to influence dual resistance, as may polymorphisms in the5' region (implied by the study of Nijhuis et al. [28] and alsoby three of the clonal clinical isolates in the present study).We are now focusing on understanding the genetic basis of AZTand 3TC dual resistance in a larger collection of clinical isolates.It is anticipated that this work will further help to define polymorphismsin RT that facilitate dual resistance. Such information is ofclear importance in situations in which only the viral genotypeis determined as a means of assessing drug resistance of virusfrom treated individuals.

	ACKNOWLEDGMENTS

We thank M. Goulden for supplying the HIV-1 1373 viral isolates. We thank V. Miller and S. Staszewski for patient plasma samplesG2-1b, G2-3g, V178a, G2-2a, and V213b.

This work was supported in part by research grants from the Medical Research Service of the Department of Veterans Affairs,from the Department of Defence, and from the National Institutesof Health (RO1A134301-01).

	FOOTNOTES

^* Corresponding author. Present address: Virco UK, 162A Cambridge Science Park, Milton Rd., Cambridge CB4 4GH, United Kingdom.Phone: 44 1 223 425 450. Fax: 44 1 223 423 456. E-mail: brendan.larder{at}viro.co.uk.

Present address: Virco UK, 162A Cambridge Science Park, Cambridge CB4 4GH, United Kingdom.

Present address: BC Center for Excellence in HIV/AIDS, Vancouver, British Columbia, Canada.

REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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2. Boucher, C. A., N. Cammack, P. Schipper, R. Schuurman, P. Rouse, M. A. Wainberg, and J. M. Cameron. 1993. High-level resistance to ( $-$ ) enantiomeric 2'-deoxy-3'-thiacytidine in vitro is due to one amino acid substitution in the catalytic site of human immunodeficiency virus type 1 reverse transcriptase. Antimicrob. Agents Chemother. 37:2231-2234[Abstract/Free Full Text].

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4. D'Aquila, R. T., V. A. Johnson, S. L. Welles, A. J. Japour, D. R. Kuritzkes, V. DeGruttola, P. S. Reichelderfer, R. W. Coombs, C. S. Crumpacker, J. O. Kahn, and D. D. Richman. 1995. Zidovudine resistance and HIV-1 disease progression during antiretroviral therapy. AIDS Clinical Trials Group Protocol 116B/117 Team and the Virology Committee Resistance Working Group. Ann. Intern. Med. 122:401-408[Abstract/Free Full Text].

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1.	Bartlett, J. A., S. L. Benoit, V. A. Johnson, J. B. Quinn, G. E. Sepulveda, W. C. Ehmann, C. T. Soukas, M. A. Fallon, P. L. Self, and M. Rubin. 1996. Lamivudine plus zidovudine compared with zalcitabine plus zidovudine in patients with HIV infection. Ann. Intern. Med. 125:161-172[Abstract/Free Full Text].
2.	Boucher, C. A., N. Cammack, P. Schipper, R. Schuurman, P. Rouse, M. A. Wainberg, and J. M. Cameron. 1993. High-level resistance to ( $-$ ) enantiomeric 2'-deoxy-3'-thiacytidine in vitro is due to one amino acid substitution in the catalytic site of human immunodeficiency virus type 1 reverse transcriptase. Antimicrob. Agents Chemother. 37:2231-2234[Abstract/Free Full Text].
3.	Boucher, C. A., E. O'Sullivan, J. W. Mulder, C. Ramautarsing, P. Kellam, G. Darby, J. M. Lange, J. Goudsmit, and B. A. Larder. 1992. Ordered appearance of zidovudine resistance mutations during treatment of 18 human immunodeficiency virus-positive subjects. J. Infect. Dis. 165:105-110[Medline].
4.	D'Aquila, R. T., V. A. Johnson, S. L. Welles, A. J. Japour, D. R. Kuritzkes, V. DeGruttola, P. S. Reichelderfer, R. W. Coombs, C. S. Crumpacker, J. O. Kahn, and D. D. Richman. 1995. Zidovudine resistance and HIV-1 disease progression during antiretroviral therapy. AIDS Clinical Trials Group Protocol 116B/117 Team and the Virology Committee Resistance Working Group. Ann. Intern. Med. 122:401-408[Abstract/Free Full Text].
5.	Eron, J. J., S. L. Benoit, J. Jemsek, R. D. MacArthur, J. Santana, J. B. Quinn, D. R. Kuritzkes, M. A. Fallon, M. Rubin, and the North American HIV Working Party. 1995. Treatment with lamivudine, zidovudine, or both in HIV-positive patients with 200 to 500 CD4+ cells per cubic millimeter. N. Engl. J. Med. 333:1662-1669[Abstract/Free Full Text].
6.	Fischl, M., D. D. Richman, M. Grieco, M. S. Gottlieb, P. A. Volberding, O. L. Laskin, J. M. Leedom, J. E. Groopman, D. Mildvan, R. T. Schooley, G. G. Jackson, D. T. Durack, D. King, and the AZT Collaborative Working Group. 1987. The efficacy of azidothymidine (AZT) in the treatment of patients with AIDS and AIDS related complex: a double-blind, placebo-controlled trial. N. Engl. J. Med. 317:185-191[Abstract].
7.	Gao, Q., Z. Gu, M. A. Parniak, L. Cameron, N. Cammack, C. Boucher, and M. A. Wainberg. 1993. The same mutation that encodes low-level human immunodeficiency virus resistance to 2',3'-dideoxyinosine and 2',3'-dideoxycytidine confers high-level resistance to the ( $-$ ) enantiomer of 2',3'-dideoxy-3'-thiacytidine. Antimicrob. Agents Chemother. 37:1390-1392[Abstract/Free Full Text].
8.	Goulden, M. G., N. Cammack, P. L. Hopewell, C. R. Penn, and J. M. Cameron. 1996. Selection in vitro of an HIV-1 variant resistant to both lamivudine (3TC) and zidovudine. AIDS 10:101-102[Medline].
9.	Harada, S., Y. Koyanagi, and N. Yamamoto. 1985. Infection of HTLV-III/LAV in HTLV-I carrying cells MT-2 and MT-4 and application in a plaque assay. Science 229:563-566[Abstract/Free Full Text].
10.	Harrigan, P. R., I. Kinghorn, S. Bloor, S. D. Kemp, I. Najera, A. Kohli, and B. A. Larder. 1996. Significance of amino acid variation at human immunodeficiency virus type 1 reverse transcriptase residue 210 for zidovudine susceptibility. J. Virol. 70:593-594.
11.	Hooker, D., G. Tachedjian, A. E. Soloman, A. D. Gurusinghe, S. Land, C. Birch, J. L. Anderson, B. M. Roy, E. Arnold, and N. J. Deacon. 1996. An in vivo mutation from leucine to tryptophan at position 210 in human immunodeficiency virus type 1 reverse transcriptase contributes to high-level resistance to 3'-azido-3'-deoxythymidine. J. Virol. 70:8010-8018[Abstract].
12.	Ioannidis, J. P., J. C. Cappelleri, J. Lau, P. R. Skolnik, B. Melville, T. C. Chalmers, and H. S. Sacks. 1995. Early or deferred zidovudine therapy in HIV-infected patients without an AIDS-defining illness. Ann. Intern. Med. 122:856-866[Abstract/Free Full Text].
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