Inactivation of Human Immunodeficiency Virus Type 1 Infectivity with Preservation of Conformational and Functional Integrity of Virion Surface Proteins

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Journal of Virology, October 1998, p. 7992-8001, Vol. 72, No. 10
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Inactivation of Human Immunodeficiency Virus Type 1 Infectivity with Preservation of Conformational and Functional Integrity of Virion Surface Proteins

J. L. Rossio,¹ M. T. Esser,¹ K. Suryanarayana,¹ D. K. Schneider,¹ J. W. Bess Jr.,² G. M. Vasquez,¹ T. A. Wiltrout,¹ E. Chertova,³ M. K. Grimes,² Q. Sattentau,⁴ L. O. Arthur,² L. E. Henderson,³ and J. D. Lifson¹^,^*

Retroviral Pathogenesis Laboratory,¹ Biological Products Laboratory,² and Protein Chemistry Laboratory,³ AIDS Vaccine Program, SAIC Frederick, National Cancer Institute $---$ Frederick Cancer Research and Development Center, Frederick, Maryland 21702, and Centre d'Immunologie de Marseille-Luminy, Marseilles, France⁴

Received 12 March 1998/Accepted 22 June 1998

	ABSTRACT

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Whole inactivated viral particles have been successfully used as vaccines for some viruses, but procedures historically usedfor inactivation can denature virion proteins. Results have beeninconsistent, with enhancement of disease rather than protectionseen in some notable instances following vaccination. We usedthe compound 2,2'-dithiodipyridine (aldrithiol-2; AT-2) to covalentlymodify the essential zinc fingers in the nucleocapsid (NC) proteinof human immunodeficiency virus type 1 (HIV-1) or simian immunodeficiencyvirus (SIV) virions, thereby inactivating infectivity. The inactivatedvirus was not detectably infectious in vitro (up to 5 log unitsof inactivation). However, in contrast to virions inactivatedby conventional methods such as heat or formalin treatment, viraland host cell-derived proteins on virion surfaces retained conformationaland functional integrity. Thus, immunoprecipitation of AT-2-treatedvirions was comparable to precipitation of matched untreated virus,even when using antibodies to conformational determinants on gp120.AT-2 inactivated virions bound to CD4⁺ target cells and mediated virus-induced, CD4-dependent "fusionfrom without" comparably to native virions. However, viral entryassays demonstrated that the viral life cycle of AT-2-treatedvirions was arrested before initiation of reverse transcription.The major histocompatibility complex (MHC) class II moleculeson the surface of AT-2-treated virions produced from MHC classII-expressing cells retained the ability to support class II-dependent,superantigen-triggered proliferative responses by resting T lymphocytes.These findings indicate that inactivation via this method resultsin elimination of infectivity with preservation of conformationaland functional integrity of virion surface proteins, includingboth virally encoded determinants and proteins derived from thehost cells in which the virus was produced. Such inactivated virionsshould provide a promising candidate vaccine antigen and a usefulreagent for experimentally probing the postulated involvementof virion surface proteins in indirect mechanisms of HIV-1 pathogenesis.

	INTRODUCTION

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The nucleocapsid (NC) proteins of all lentiviruses and oncornaviruses contain zinc finger motifs, which are among the mosthighly conserved elements in retroviral sequences (6, 27).Accumulating results from site-directed mutagenesis studies withseveral different retroviral systems implicate the NC proteinin multiple distinct but essential aspects of the viral life cycle.Mutations that disrupt the capacity of the NC protein zinc fingersto coordinate zinc result in a phenotype characterized by profoundimpairment in packaging of viral genomic RNA into virions (11,26, 50). More subtle mutations, in which the zinc-coordinatingcapacity of the NC protein is preserved but the sequence is altered,package viral genomic RNA at levels comparable to those in wild-typevirus, but the resulting virions are incapable of productive infection,with the defect in infectivity mapping to critical preintegrationsteps of the viral life cycle (26a).

The key role of the NC protein at multiple essential steps in the viral life cycle and the highly conserved nature of theretroviral zinc finger motifs in the NC protein make it an attractivetarget for development of antiretroviral drugs (48, 50, 51).Indeed, a number of compounds have been identified that act viaa variety of different mechanisms to covalently modify the NCzinc fingers, resulting in ejection of the coordinated zinc andloss of infectivity (38, 48, 51, 63, 64). Despite differencesbetween detailed mechanisms of action for these compounds, thecommon mechanistic feature involves a preferential chemical attackon the zinc-coordinating cysteine sulfurs in the residues thatmake up the NC protein zinc fingers (38). According to thismechanism, it should be possible to identify compounds that caneject zinc from the zinc fingers yet should not affect proteinsin which cysteine residues are already involved in disulfide linkages(e.g., viral envelope glycoproteins).

Such a mode of inactivation might provide certain advantages, since the conformational integrity of proteins on the virionsurface would be preserved. This would be of interest from thedual perspectives of developing a potentially improved inactivatedwhole-particle vaccine immunogen and studying the functional andimmunopathogenic properties of conformationally intact but noninfectiousvirons.

Virion surface proteins include both virally encoded proteins and proteins derived nonrandomly through budding from the hostcells in which the virions were produced (2, 43). Viral proteinson the virion surface, such as the envelope glycoproteins, areessential for binding and entry into target cells and can alsoserve as a target for host immune responses (40, 55). Viralproteins have also been implicated in various immunopathogenicmechanisms, such as induction of anergy or apoptosis in humanimmunodeficiency virus type 1 (HIV-1) infection (1, 31, 58)as well as other viral infections (29). Host cell-derived proteinson the HIV-1 virion surface include major histocompatibility complex(MHC) class II molecules, notably HLA-DR (2, 43). These proteinshave been shown to be capable of inducing protective immunityagainst in vivo challenge with simian immunodeficiency virus (SIV)propagated in human cells (3, 12). As cell surface moleculesphysiologically involved in immunoregulatory cell-cell recognitionevents (21, 22, 25), MHC class II proteins may also havethe potential to mediate immunopathogenic effects when displayedon the surface of virions.

In this study, we examined HIV-1 virions whose infectivity was abrogated by using the prototypical NC zinc finger targetingcompound, 2,2'-dithiodipyridine (aldrithiol-2 [AT-2]). Our analysisfocused on assays intended to assess the conformational and functionalintegrity of virion surface proteins, comparing AT-2-inactivatedvirus to native virus and to virions inactivated by classicalmeans such as heat treatment or formaldehyde fixation. Our findingsindicate that the surface proteins of AT-2-treated virus are conformationallyand functionally intact, but the virions are not infectious, withthe block to infectivity occurring after virion binding and membranefusion but before reverse transcription.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Viruses. HIV-1_MN/H9 clone 4 and HIV-1_LAI/H9 were propagated in H9 cells, as described previously (44). SIVmne was obtained from supernatantsof the cloned E11S cell line, derived from a culture of HuT-78cells infected with SIVmne (5, 24). Where indicated, concentratedvirus preparations were produced by sucrose gradient banding ina continuous-flow centrifuge (7). Primary HIV-1 isolates 92US727and 91US054 were obtained from short-term cocultures of peripheralblood mononuclear cells (PBMC) from HIV-1-infected subjects withphytohemagglutinin (PHA)-activated (PHA-M [GIBCO, Grand Island,N.Y.]; 1:100 for 72 h), IL-2-supported (20 U/ml) PBMC from HIV-1-seronegativevolunteer donors. All virus stocks were stored at $-$ 70°C or invapor-phase liquid nitrogen until use. Microvesicles, used asa control reagent, were isolated from supernatants of uninfectedH9 cell cultures in a manner identical to that used for viruspreparation from infected cells (7).

Virus titer determinations. Virus titers were determined, essentially as described previously (39), with H9 cells, AA2 cells (10, 62), or PHA-stimulatedhuman PBMC blasts (72 h), as indicated, with or without the additionof Polybrene (Sigma, St. Louis, Mo.). Briefly, 2 × 10⁶ indicator cells in 1-ml volumes were inoculated with serial 10-folddilutions of each native or inactivated (see below) virus stockand incubated overnight (14 to 16 h). After being washed, inoculatedcells were seeded at 10⁵ cells in 250 µl in 96-well culture plates, using 16 replicatesper dilution or treatment. Cells were cultured in RPMI 1640 with10% heat-inactivated fetal bovine serum and 2 mM L-glutamine (completemedium); 100 µl of medium was replaced twice weekly. Culturesof PBMC blasts were also supplemented with 20 IU of interleukin-2per ml. On day 10 postinoculation, supernatants were harvestedand tested for p24^CA content as an index of productive infection by using a captureenzyme-linked immunosorbent assay (AIDS Vaccine Program, NationalCancer Institute $---$ Frederick Cancer Research and Development Center[NCI-FCRDC], Frederick, Md.). For SIV titer determinations, serialdilutions of virus in quadruplicate were inoculated onto AA2 clone5 cells and cultures were monitored for 21 days, with twice-weeklychanges of medium. Culture supernatants were monitored for p28^CA. Wells containing >100 pg of p24 per ml or 300 pg of p28^CA per ml were scored as positive, and the 50% tissue culture infectivedose (TCID₅₀) was calculated by the method of Reed and Muench(47).

Virus inactivation procedures. For all procedures, frozen virus stocks were quickly thawed at 37°C in a water bath. Heat inactivation was carried out at56°C in a water bath for 2 h with frequent mixing. Virus was thenkept on ice until used (within 2 h). Formaldehyde inactivationwas performed as described previously (46). Briefly, virus preparationswere treated with a 1:80 solution of buffered formalin (1:2,000formaldehyde; Sigma, St. Louis, Mo.) in phosphate-buffered saline(PBS) for 24 h at 37°C. Formalin was then neutralized with 2%sodium bisulfite in PBS. For inactivation with AT-2, a stock solutionof AT-2 (100 mM in dimethyl sulfoxide [Aldrich, Milwaukee, Wis.])was prepared and added directly to virus to produce the desiredAT-2 concentration. Virus preparations were treated for 1 h at37°C and then kept on ice until used (within 2 h). At the conclusionof the inactivating procedures, treatment agents were removedby ultrafiltration with a centrifugal filtration device with a500-kDa cutoff (Centriprep 500; Amicon, Beverly, Mass.). Filtrationswere done at 4°C and resulted in at least a 1:375 reduction inthe concentration of the chemical inactivating agents. Controlvirus preparations were sham treated and processed in parallelwith inactivated samples.

Western blot analysis. HIV-1_MN was treated with AT-2 or heat as described above. Samples were centrifuged for 1 h at 17,000 × g (4°C) to pellet thevirus. Samples for electrophoresis were run separately on sodiumdodecyl sulfate-polyacrylamide (4 to 20% gradient) gels (NOVEX,San Diego, Calif.) under reducing and nonreducing conditions.Proteins were transferred onto polyvinylidere difluoride membranes,stained with 0.5% (wt/vol) Ponceau S stain, and detected by immunoblotanalysis with monospecific polyvalent goat antiserum preparedagainst purified viral NC and enhanced chemilumenscence reagents(Amersham, Arlington, Ill.).

Cell lines. The H9, A3.01, and Sup-T1 cell lines were obtained from the National Institute of Allergy and Infectious Diseases AIDS Researchand Reference Reagent Program (Rockville, Md.). The AA2 cell line(62) was provided by R. Benveniste (NCI-FCRDC). All cell lineswere mycoplasma negative (PCR mycoplasma detection kit; AmericanType Culture Collection, Rockville, Md.) and were cultured incomplete medium (RPMI 1640, 10% heat-inactivated fetal bovineserum, 2 mM L-glutamine, 100 U of penicillin G per ml, 100 µgof streptomycin sulfate per ml).

Antibody reagents. The generation and characterization of polyclonal goat antibodies against human MHC class I and class II and a polyclonalgoat antibody raised against microvesicles prepared from culturesof H9 cells have been described previously (2, 7). The murinemonoclonal antibody 48d (also listed as 4.8D) (59) and the neutralizingmonoclonal antibody IgG1b12 (32, 60), both directed againstconformational determinants on gp120, were obtained from the AIDSResearch and Reference Reagent Program (Rockville, Md.).

Primary cells. PBMC were isolated by density centrifugation (Ficoll-Hypaque; Sigma) from leukopacks obtained from healthy, HIV-1 seronegativedonors at either the National Institutes of Health, Bethesda,Md. or NCI-FCRDC.

Whole-particle immunoprecipitation assay. A whole-particle immunoprecipitation assay was performed as described previously (2). Briefly, comparable input amountsof native or inactivated virus preparations were incubated withempirically optimized concentrations of each antibody preparation(or PBS) for 1 h at 37°C, then overnight at 4°C, with rocking.Formalin-fixed Staphylococcus aureus Cowan strain (GIBCO) wasthen added, and after incubation at 20°C for 30 min, virions withbound antibody were immunoprecipitated by centrifugation (2,000× g for 30 min). To calculate the percent clearance of viral particles,the residual virus content of the supernatant after immunoprecipitationwas determined by p24 capture immunoassay and compared to thep24 content of the same virus preparation after identical precipitationwith PBS instead of antibody. Clearance by a particular antibodyin this assay is indicative of the presence of intact antigenimmunoreactive with that antibody on the surface of the virions(2). For purposes of comparison, data were normalized by consideringthe maximal amount of clearance achieved by each antibody forprecipitation of native virus to be 100% relative clearance. Therelative percent clearance of inactivated virus preparations byeach antibody was determined by comparing the extent of clearanceto this 100% value. Maximal absolute clearance values for nativevirus ranged from 90% (anti-H9 antibody) to 35% (48d antibody).

Virus binding assay. An immunofluorescence flow cytometric whole-particle virion binding assay was performed by using modifications to a previouslyreported assay format (56, 65). The A3.01 cell line expressesCD4 and CXCR4 but does not express HLA-DR. Virus propagated inHLA-DR expressing cells incorporates host cell-derived HLA-DRinto the viral envelope (7). Thus, acquisition of HLA-DR reactivityby A3.01 cells following incubation with HLA-DR-containing virionscan be used as a criterion of virion binding.

Briefly, A3.01 cells (2 × 10⁵ per condition) were preincubated at 4°C for 30 min with either staining buffer (calcium- andmagnesium-free PBS with 1% [wt/vol] bovine serum albumin) or unlabeledanti-Leu 3a (5 µg/ml [Becton Dickinson Immunocytometry Systems,San Jose, Calif.]) and then washed once. The cells were then incubatedwith 100 µl of staining buffer or native or inactivated viruspreparation at 37°C for 30 min and washed twice. Immunofluorescentstaining was performed (4°C for 30 min) with fluorochrome-conjugatedmonoclonal antibodies to HLA-DR (phycoerythrin conjugated) andCD4 (anti-Leu 3a, fluorescein isothiocyanate conjugated) and OKT4(fluorescein isothiocyanate conjugated) with nonspecific antibodybinding measured by using isotype-matched monoclonal antibodiesof irrelevant specificity, conjugated to the appropriate fluorochromes(all antibodies from Becton-Dickinson Immunocytometry Systemsexcept for OKT4 [Ortho Diagnostics, Raritan, N.J.]). Followingantibody staining, the cells were washed three times and fixedin 1% paraformaldehyde for 30 min at 4°C before being analyzedon a FACScan flow cytometer with Cell Quest software (Becton DickinsonImmunocytometry Systems).

Fusion from without. To test the ability of AT-2-treated virus to mediate CD4-dependent, HIV-1 envelope glycoprotein-mediated "fusion from without"(15, 28), we incubated Sup T1 cells (10⁵ cells/well/50 µl in 96-well flat-bottom plates), which are highlysusceptible to HIV-1-induced cell fusion, at 37°C with matchedconcentrated preparations of HIV-1 or AT-2-inactivated HIV-1 (HIV-1_MN/H9clone 4; 50 µl/well). The presence of characteristic syncytiawas evaluated by inverted phase-contrast microscopy 1 to 3 h followingvirus addition. Syncytia present at this time are due to fusionfrom without (that is, due to the input virus inoculum), sincethis is insufficient time for infection to result in cell surfaceexpression of envelope glycoproteins and resulting syncytia (fusionfrom within). The CD4 dependence of fusion was determined by preincubatingtarget cells with anti-Leu 3a (25 µg/ml) for 30 min before theaddition of virus.

Viral entry assay. To determine the stage of the viral life cycle at which infectivity was arrested for inactivated virus preparations, we performeda viral entry assay in which reverse-transcribed viral DNA specieswere quantified by a real-time PCR assay. Briefly, PHA-activated,interleukin-2-supported PBMC from HIV-1-seronegative donors wereinoculated with native or inactivated virus (1,600 TCID₅₀, 9,000pg of HIV-1 p24 per 2.5 × 10⁶ cells). After being washed, the inoculated cells were culturedin complete medium and aliquots were harvested at 24 and 48 hpostinoculation. A parallel control culture was treated with zidovudine(AZT; 20 µM) and ddI (20 µM), with pretreatment of the targetcells for 2 h before inoculation; compounds were present for theduration of the cultures. After being harvested, the washed, drycell pellets were cryopreserved at $-$ 70°C until used for processingand analysis.

The pellets were lysed and total DNA was extracted with commercial reagents (PureGene kit; Gentra Systems, Minneapolis, Minn.)as recommended by the manufacture. HIV-1 strong-stop DNA, indicativeof initiation of reverse transcription, and HIV-1 gag DNA, indicativeof completion of first-strand DNA synthesis, were quantitatedby a real-time PCR assay on an ABI Prism 7700 sequence detectionsystem. The underlying principles and operation of this instrumentare reviewed in detail elsewhere (26c, 36, 57a). For the presentassays (57b), the following reagent sets were used: strong stop,forward primer, 5'-GGT CTC TCT GGT TAG ACC A-3' (455 to 473);reverse primer, 5'-CAC ACT GAC TAA AAG GGT CTG-3' (593 to 573);probe, 5'-(R)TAG TGT GTG CCC GTC TGT TGT GTG ACT(Q)-3' (554 to580); Gag, forward primer, 5'-GiC ATC AiG CAG CCA TGC AAA T-3'(1366 to 1387); reverse primer, 5'-CAT iCT ATT TGT TCi TGA AGGGTA CTA G-3' (1507 to 1480, where i indicates an inosine residueinserted to avoid bias in amplification based on sequence mismatchat positions where mismatches have been documented among sequencedHIV-1 isolates [45a]); probe, 5'-(R)TCA ATG AGG AAG CTG CAG AATGGG AT(Q)-3' (1402 to 1427) (based on the reference sequence forHIV-1 isolate HXB2 [GenBank accession no. K03455]), where Rindicates the reporter fluorochrome (6-carboxyfluorescein) andQ indicates the quencher dye 6-carboxytetramethylrhodamine conjugatedthough a linker arm nucleotide (LAN [36]). (Fluorescent probesfor HIV-1 gag and strong-stop DNA were obtained from DNA Sciences,Inc., San Diego, Calif.) In addition, each specimen was analyzedfor the copy number for a unique sequence from the coding regionfor porphobilinogen deaminase (PBGD) (14a, 26b) by using a fluorescentprobe purchased from the Applied Biosystems Division of Perkin-Elmer(Foster City, Calif.). Since this sequence is present at two copiesper diploid cell and there are no pseudogene sequences, quantitativeanalysis of this sequence in a given specimen provides an internalcontrol, allowing normalization of HIV sequences relative to thenumber of diploid genome equivalents of DNA present in the specimen.The average interassay coefficient of variation for the real-timePCR assays for HIV-1 gag and strong-stop and PBGD DNA was <15%,with a nominal threshold sensitivity of 3 DNA copy equivalentsper reaction.

MHC class II-dependent, superantigen-triggered proliferation of resting T lymphocytes. Superantigens trigger polyclonal proliferation of T lymphocytes through a mechanism that is dependent on the presentationof the superantigen to the T-cell receptor complex by MHC classII molecules (13, 35). We have shown previously that the MHCclass II molecules incorporated into HIV-1 virions produced fromMHC class II-expressing cells are capable of providing the necessaryMHC class II proteins to support this effect (53). We thereforeperformed a comparative evaluation of the ability of native virionsand matched virion preparations inactivated by different meansto support superantigen-triggered proliferation. PBMC were isolatedfrom leukopacks by density centrifugation. Monocytes were removedby two rounds of plastic adherence (37°C for 1 h and overnight)and recovered separately. Resting T lymphocytes were preparedby passage of nonadherent cells through T-cell enrichment columns(R & D Systems, Minneapolis, Minn.) as recommended by the manufacturer.To ensure that cells were not activated at the initiation of functionalassays, T lymphocytes recovered from the T-cell preparation columnswere cultured in complete medium with no activating agents for48 h before use.

To measure superantigen-triggered proliferative responses, resting T cells were seeded in 96-well culture plates at 5 × 10⁴ cells per well (triplicate wells for each condition), incubatedalone or with various additions to the cultures for 3 days, andpulsed with [³H]thymidine (1 µCi/well; specific activity, 6.8 Ci/mmol [NEN LifeSciences, Boston, Mass.]) during the final 8 h of culture. Thecells were harvested, and [³H]thymidine incorporation was measured as an index of proliferationby liquid scintillation counting (LKB Microbeta; LKB, Rockville,Md.). Culture conditions included T cells alone, T cells plusautologous adherent cells, T cells plus superantigen (staphylococcalenterotoxin A, 100 ng/ml [Sigma]), T cells plus autologous adherentcells plus superantigen, T cells plus native or inactivated virus,and T cells plus native or inactivated virus plus superantigen.

	RESULTS

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The effectiveness of inactivation of HIV-1 infectivity by treatment with AT-2 was evaluated, and the conformational and functionalpreservation of virion surface structures after inactivation wasassessed. AT-2 treatment eliminated the infectivity of HIV-1,as measured by the inability of treated virus to replicate inhighly permissive AA-2 cells, H9 cells, or PHA-treated human lymphoblastsin vitro. As shown in Table 1, the heat, formaldehyde, and AT-2treatments completely inactivated the viral stocks tested, providing3 to >4 log units of inactivation. In additional experiments,AT-2 treatment demonstrated in excess of 5 log units of inactivation,with treatment concentrations greater than 100 µM completely inactivatingall virus stocks tested in the studies summarized in Table 1,including multiple different HIV-1 viral isolates, as well asviruses produced from both T-cell lines and primary PBMC. SinceAT-2 targets a structure that is conserved across all lentiviruses,we were also able to evaluate AT-2 inactivation of SIV infectivity.Following AT-2 treatment, residual SIV infectivity was undetectable,even after purification and 1,000-fold concentration of the inactivatedvirus (Table 1). In separate dose-effect experiments with virusstocks of different infectivities, complete inactivation of HIV-1was achieved at AT-2 doses greater than 300 µM, with a 50% reductionat about 30 µM AT-2 (Table 2).

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TABLE 1. Inactivation of HIV-1 and SIV by AT-2, heat, or formalin treatment

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TABLE 2. Effect of AT-2 treatment concentration on HIV-1_MN^a

The mechanism of HIV-1 inactivation by AT-2 is proposed to be via covalent modification of the zinc fingers in the NC (p7)protein of HIV-1, with ejection of the coordinated Zn²⁺, resulting in disruption of multiple aspects of viral replication(38). The Western blot analysis in Fig. 1 shows that the p7^NC protein in AT-2-treated HIV-1 is modified so that it does notmigrate to the expected position on gel electrophoresis, withother studies demonstrating AT-2-mediated cross-linking of p7into high-molecular-weight aggregates (data not shown). Completechemical reduction of the virus extract with 3% 2-mercaptoethanolin sample buffer resulted in the reappearance of the p7^NC band at the correct molecular weight (Fig. 1). Heating HIV-1at 56°C for 2 h did not affect the migration of p7^NC, although the treated virus was not detectably infectious.

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FIG. 1. Western blot analysis of AT-2-treated HIV-1. HIV-1 preparations treated with AT-2 (lanes AT) or heat (56°C for 2 h) (lanes 56) and untreated controls (lanes C) were lysed and electrophoresed in 4 to 20% polyacrylamide gradient gels under nonreducing (left) or strongly reducing (right) conditions. The proteins were blotted, and developed with antiserum to p7^NC. The left panel shows that p7^NC does not migrate to its normal position in AT-2-treated virions. Upon complete chemical reduction of AT-2-treated virus (right panel), the p7NC band reappears.

To assess the integrity of viral and cellular proteins on the surface of noninfectious virions inactivated by AT-2 or othermeans, whole-particle immunoprecipitation was performed. The antibodiesused were directed against a variety of determinants on the virionsurface, including both linear and conformational determinants,and both viral and host cell-derived proteins. As shown in Fig.2A, immunoprecipitation of AT-2-inactivated virions was comparableto precipitation of native virions with all antibodies tested,including comparable immunoprecipitation with the monoclonal antibody48d, which recognizes a conformational determinant on gp120 (59).Figure 2B demonstrates comparable precipitation of native andAT-2-inactivated virions by using IgG1b12, a potently neutralizingmonoclonal antibody that reacts with a conformational determinant(32, 60). In marked contrast, immunoprecipitation of bothformaldehyde-inactivated virions and heat-inactivated virionswas greatly decreased compared to native virus, including minimalimmunoprecipitation by the 48d monoclonal antibody, demonstratingthe virtually complete denaturation or loss of conformationalantigenic determinants on virions following these modes of inactivation(Fig. 2A).

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FIG. 2. (A) Whole-particle immunoprecipitation of HIV-1. HIV-1_MN, either untreated or inactivated by different methods as described in the text, was precipitated with antisera to cellular proteins (HLA class I or class II) or viral proteins (gp120, 48d, which recognizes a conformationally sensitive epitope [59]) or H9, an antiserum raised against microvesicle preparations derived from H9 cells (7). All inactivated virus preparations used for these experiments were not detectably infectious. Results shown are the mean ± 1 standard error of the mean for triplicate determinations for each condition in two separate experiments. (B) Whole-particle immunoprecipitation of untreated or AT-2-inactivated HIV-1_MN by anti-H9 antiserum or monoclonal antibody IgG1b12, a potently neutralizing antibody to a conformational determinant on gp120 (32, 60). Results shown are the mean ±1 standard error of the mean for triplicate determinations in four separate experiments.

The results of the immunoprecipitation studies described above suggested that conformational determinants on AT-2-inactivatedvirus were preserved, including determinants on the envelope glycoproteingp120. To further investigate whether the envelope glycoproteinwas functionally intact on AT-2-inactivated virus, we performeda flow cytometry-based virion binding assay. Figure 3A shows thatthe A3.01 cell line expresses CD4, demonstrated by reactivitywith both anti-Leu 3a and OKT4 monoclonal antibodies, but doesnot express HLA-DR. After incubation of target cells with nativevirions produced from HLA-DR-positive H9 cells, the cells becamepositive for HLA-DR staining, with a concomitant decrease in anti-Leu3a staining but no change in OKT4 staining, consistent with bindingof virions to the target cells (Fig. 3B). The HLA-DR stainingreflects the MHC class II determinants on the surface of virionsbound to the target cells. Staining for the Leu 3a determinantis decreased, since this epitope is involved in interactions withHIV-1 gp120 (4) and since binding of virions blocks antibodyaccess. Staining with OKT4 is not decreased, since this epitopeon CD4 is sufficiently removed from the gp120 interaction site.The acquired HLA-DR staining is not attributable to target cellbinding of HLA-DR-containing microvesicles present in the viruspreparation (7), since incubation of target cells with highconcentrations of purified microvesicles derived from uninfectedcultures of the same cells used to produce the virus did not resultin acquisition of HLA-DR reactivity (data not shown). Preincubationof the target cells with unlabeled anti-Leu 3a before the additionof virions inhibited the acquisition of HLA-DR staining (Fig.3C). Not all binding was blockable by anti-Leu 3a pretreatment,perhaps reflecting CD4-independent binding (65). However, allinfectivity was blockable by anti-Leu 3a (data not shown). Similarstudies with AT-2-inactivated virus demonstrated CD4-dependentbinding comparable to that of native virions (Fig. 3D and E).In contrast, binding of virions inactivated by either heat orformaldehyde treatment was markedly decreased relative to thatof native virions (Fig. 3F).

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FIG. 3. Virion binding demonstrated by flow cytometry. For panels A to E, the solid line indicates Leu 3a staining, the dotted line indicates OKT4 staining, the dashed line indicates isotype-matched irrelevant-specificity control staining, and the shaded area indicates HLA-DR staining. Ten thousand cells were evaluated in each analysis. (A) In the absence of added HIV-1 virions, A3.01 cells are CD4⁺ (anti-Leu 3a and OKT4 staining) and HLA-DR. (B) Incubation of A3.01 cells with native HIV-1 produced from HLA-DR-expressing cells results in acquisition of HLA-DR staining and a decrease in anti-Leu 3a but not OKT4 staining, reflecting binding of virions. (C) Preincubation of A3.01 cells with unlabeled anti-Leu 3a prior to incubation with HIV-1 virions and subsequent staining blocks anti-Leu 3a staining and substantially reduces virion binding, reflected in decreased acquisition of HLA-DR staining. (D) Acquisition of HLA-DR reactivity and loss of anti-Leu 3a staining following incubation with AT-2-treated HIV-1 virions were comparable to those in native virions (compare to panel B). (E) Binding of AT-2-inactivated HIV-1 virions is authentic, as reflected by the ability of target cell preincubation with unlabeled anti-Leu 3a to inhibit acquisition of HLA-DR staining (compare to panel C). (F) Binding of AT-2-inactivated HIV-1 virions, as indicated by acquisition of HLA-DR staining, is comparable to that of native virions, while virions inactivated by formalin or heat treatment show virtually no anti-Leu 3a-inhibitable binding. The plot shows mean channel fluorescence for HLA-DR staining following incubation of target cells with comparable amounts (p24^CA content) of each virus preparation. Results are representative of four independent assays.

To evaluate whether bound AT-2-inactivated virus was capable of undergoing post-CD4 binding-induced conformational changesand resulting membrane fusion events, we tested the ability ofsuch virions to mediate fusion from without (15). As shown inFig. 4, inactivated virions rendered noninfectious by AT-2 treatmentwere nevertheless able to mediate CD4-dependent fusion from withoutcomparably to matched native virion preparations.

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FIG. 4. HIV-1 induced fusion from without of Sup T1 cells. (A) Sup T1 cells, highly susceptible to CD4-dependent, HIV-1 envelope glycoprotein-mediated cell fusion. (B) Following a 3-h incubation with concentrated native HIV-1, characteristic syncytia are seen, reflecting virion-mediated fusion from without. (C) Fusion mediated by native virions is inhibited by prior incubation of cells with anti-Leu 3a. (D) AT-2-inactivated virions mediate fusion from without comparable to native virus. (E) Fusion mediated by AT-2-inactivated virions is inhibited by anti-Leu 3a. Magnification, ×200.

Having confirmed that AT-2-inactivated virus was capable of binding to target cells and undergoing postbinding conformationalchanges and membrane fusion events comparably to native virions,we next used a viral entry assay to test whether viral entry (57),uncoating, and reverse transcription occurred normally. The viralentry assay used is based on quantitative real-time PCR analysisfor HIV reverse transcription intermediates, with normalizationof the results based on a single-copy genomic sequence. Quantitationof HIV-1 gag DNA copy equivalents per 100,000 diploid genome equivalentsshowed a time-dependent accumulation of defined reverse transcriptionintermediates in cultures inoculated with untreated virus (Fig.5). Treatment of target cells with the reverse transcriptase inhibitorsAZT and ddI completely blocked accumulation of gag DNA. AT-2 treatmentof virions that eliminated infectivity also prevented the synthesisof gag DNA. Quantitation of AZT- and ddI-inhibitable synthesisof HIV-1 strong-stop DNA sequences showed that initiation of reversetranscription was also blocked for AT-2-treated virions comparedto native virions, after accounting for the noninhibitable strong-stopDNA that may reflect intravirion endogenous reverse transcription(61, 66). As was observed for cells treated with AZT and ddIinoculated with native virions, no new strong-stop DNA was madein untreated cells inoculated with AT-2-treated virions (Fig.5), indicating that although such treated virions bind to targetcells comparably to native virions and can mediate the fusionof viral envelope and host cell membranes, further progressionof the viral life cycle is blocked before the initiation of reversetranscription.

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FIG. 5. Viral DNA in cells exposed to native and AT-2-inactivated HIV-1. Human 3-day PHA-induced lymphoblasts were exposed to HIV-1, and cell pellets were collected at 24 and 48 h. Total DNA from the cell pellets was prepared and tested by real-time PCR for reverse-transcribed HIV-1 gag and strong-stop DNA. Results were normalized based on copies of DNA coding for PBGD, as described in the text. Note the time-dependent accumulation of gag and strong-stop DNA in untreated controls and the absence of gag DNA in AZT- and ddI-treated cultures. AT-2 treatment of HIV-1 prevents the production of both gag and strong-stop DNA. Results shown are averages of duplicate determinations of the DNA copy number for each condition in one of three experiments with consistent results. In a separate experiment in which low levels of gag DNA were produced from virions treated with a suboptimal concentration of AT-2, no productive infection was observed (data not shown), suggesting that AT-2-treated virions may also be deficient in the ability to complete other post-reverse transcription, pre-integration steps of the viral life cycle in which p7^NC has been implicated (26a).

MHC class II-dependent, superantigen-triggered proliferation of resting T lymphocytes was measured as a reflection of thefunctional integrity of MHC class II determinants on inactivatedvirions. Neither cultures of resting T cells alone, resting Tcells plus macrophages, or resting T cells plus superantigen showedmeaningful proliferative responses (Fig. 6). HIV alone did notinduce T-cell proliferation under these conditions, either innative form (53) or after AT-2 treatment (data not shown). Asexpected, when resting T cells were cultured with superantigenin the presence of autologous monocytes/macrophages to providea source of MHC class II, a vigorous proliferative response wasobserved. The MHC class II present on native virions was sufficientto support superantigen-triggered proliferation by resting T cells,in the absence of other sources of class II. AT-2-inactivatedvirions supported superantigen-triggered proliferation comparablyto native virions, while virions inactivated by either heat orformaldehyde treatment were not capable of supporting the superantigentriggered proliferative response (Fig. 6).

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FIG. 6. Superantigen-induced T-cell proliferation. Resting human peripheral blood lymphoid cells alone, in the presence of autologous macrophages alone, or in the presence of SEA alone do not proliferate, as measured by [³H]-thymidine incorporation during the last 8 h of a 3-day incubation (bottom three bars). SEA exposure in the presence of MHC class II present on macrophages induces strong proliferation (top bar). HIV-1 produced from MHC class II-expressing cells was able to support the superantigen-triggered proliferative response when present as the only source of class II in the culture, and AT-2 inactivated virus was as active as untreated HIV-1. Formalin or heat treatment of HIV-1 rendered virions incapable of supporting superantigen-induced proliferative responses. Representative results from one of three experiments are shown; each bar represents the mean of triplicate cultures ±1 standard error of the mean.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Whole inactivated virions have been used successfully as vaccines for numerous viruses (16, 17, 41, 42, 46), buttraditional means of viral inactivation can denature virion surfaceproteins. Results have been inconsistent, with examples of botheffective protection and disease exacerbation associated withinactivated virus vaccines (9, 14, 33). Formalin treatmenthas been shown to be poor in preserving the antigenicity of SIV(18), consistent with our observations in this study. The uniquemechanism of retroviral inactivation mediated by compounds targetingthe NC protein zinc fingers suggested that this approach mightbe a means of inactivating infectivity while preserving the conformationalintegrity of virion surface proteins. We tested this hypothesisby inactivating HIV-1 stocks with the prototype zinc finger-modifyingcompound AT-2 and performing comparative testing of native virusand AT-2-inactivated virus, along with matched virus preparationsinactivated with heat or formaldehyde treatment. These inactivatedvirions were characterized by using a battery of assays to probethe conformational and functional integrity of both virally encodedand host cell-derived virion surface proteins.

Treatment with more than 100 µM AT-2 completely inactivated the detectable infectivity of all HIV-1 stocks tested (more than5 log units), including multiple different primary isolates propagatedin primary PBMC and isolates adapted for growth in T-cell lines(Table 1). Inactivation of SIV infectivity has also been observed(Table 1) (7a). However, in marked contrast to virus inactivatedby heat or formaledehyde treatment (18, 54), AT-2 treatmentpreserved the conformational and functional integrity of surfaceproteins on inactivated HIV-1 virions. Thus, AT-2-inactivatedvirions were immunoprecipitated comparably to native virions,even using monoclonal antibodies to conformational determinantson gp120 (Fig. 1 and 2). The conformational and functional integrityof host cell-derived proteins on the surface of AT-2-inactivatedvirions was also preserved, as reflected by the ability to supportMHC class II-dependent, superantigen-triggered proliferation byresting T lymphocytes (Fig. 6). AT-2-inactivated virions showedCD4-dependent binding to target cells comparable to native virions(Fig. 3). Treated virions were capable of mediating membrane fusion(Fig. 4), although infectivity was blocked before initiation ofreverse transcription (Fig. 5). In combination with biochemicaldata suggesting cross-linking of p7^NC in treated virions (37), these results are consistent witha blockade based on cross-linking of the NC protein in treatedvirions, preventing full uncoating and initiation of reverse transcriptionfollowing fusion of the virion envelope with the target cell plasmamembrane (57).

Maintenance of conformational and functional integrity by AT-2-inactivated virions suggests that such virions may be a usefulvaccine antigen. Oligomeric forms of HIV-1 envelope glycoproteinhave been shown to be more effective in inducing antibodies toconformational determinants important for broad neutralizing activitythan have monomeric forms of envelope glycoprotein (8, 19,20, 52). Noninfectious but conformationally intact whole virionsmay represent a further improvement in this regard. Such virionsmay be particularly useful as the boost component of "prime-boost"vaccination regimens involving live vectors such as attenuatedpoxviruses (45) or in vaccination schemes involving DNA immunization(34). The use of inactivated virions produced from mutant virusstrains engineered for improved immunogenicity, especially forinduction of neutralizing antibodies, may provide even greaterutility (49).

Another potential application of these observations is the inactivation of HIV-1 in patient blood samples used in hospitalor research laboratories, reducing the infectious hazards associatedwith the manipulation of such samples. The effects of AT-2 onserum chemistry analyses and cellular metabolism are under investigation.Since this mode of inactivation can be expected to be effectiveagainst all retroviruses that contain zinc finger motifs in theirnucleocapsid proteins, it may also be relevant to enhancing thesafety of biological products such as monoclonal antibodies producedfrom cell lines that may harbor endogenous retroviruses.

The virions produced by AT-2 inactivation, by virtue of the conformational and functional integrity of their surface proteins,may also provide a useful reagent for studies to evaluate thepotential role of virions and virion proteins in the immunopathogenesisof HIV-1 infection, independent of cytopathic or other consequencesof productive viral infection, including proposed "bystander"mechanisms of CD4 cell depletion (23, 30). The postulatedinvolvement of the HIV-1 envelope glycoprotein in inducing anergyor priming cells for subsequent apoptotic cell death may perhapsbe best explored by using conformationally authentic but noninfectiousvirions. Similarly, the possible contributions of host cell-derivedmolecules on the virion surface can also be investigated.

Analysis of retroviral NC proteins by site-directed mutagenesis is providing insight into the critical role of this proteinin several different stages of the viral life cycle (26). Theessential functions mediated by the NC protein make it an attractivetarget for antiretroviral drug development as well, with the identificationof compounds capable of inactivating the virus via p7^NC interactions providing good leads for drug development (51,63). The mechanism of action of inactivation by these compoundsalso results in virions that may be useful as a candidate vaccineand may also facilitate basic studies of retroviral pathogenesisin yet another applied aspect of investigation of this fascinating,yet still incompletely understood, viral protein.

	ACKNOWLEDGMENTS

We thank P. Grove for assistance with the preparation of the manuscript and B. Kane for electrophoresis.

This project has been funded with Federal funds from the National Cancer Institute, National Institutes of Health, under contractNO1-CO-56000.

	FOOTNOTES

^* Corresponding author. Mailing address: Retroviral Pathogenesis Laboratory, AIDS Vaccine Program, SAIC Frederick, NationalCancer Institute $---$ Frederick Cancer Research and Development Center,Building 535, Room 510, Frederick, MD 21702. Phone: (301) 846-5019.Fax: (301) 846-5588. E-mail: lifson{at}avpaxp1.ncifcrf.gov.

REFERENCES

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Abstract
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Materials & Methods
Results
Discussion
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