Regional Clustering of Shared Neutralization Determinants on Primary Isolates of Clade C Human Immunodeficiency Virus Type 1 from South Africa

Clade C is one of the most prevalent genetic subtypes of humanimmunodeficiency virus type 1 (HIV-1) in the world today andone of the least studied with respect to neutralizing antibodies.Most information on HIV-1 serology as it relates to neutralizationis derived from clade B. Clade C primary isolates of HIV-1 fromSouth Africa and Malawi were shown here to resemble clade Bisolates in their resistance to inhibition by soluble CD4 andtheir sensitivity to neutralization by human monoclonal antibodyimmunoglobulin G1b12 and, to a lesser extent, 2F5. Unlike cladeB isolates, however, all 16 clade C isolates examined resistedneutralization by 2G12. Infection with clade C HIV-1 in a cohortof female sex workers in South Africa generated antibodies thatneutralized the autologous clade C isolate and T-cell-line-adapted(TCLA) strains of clade B. Neutralization of clade B TCLA strainswas much more sensitive to the presence of autologous gp120V3 loop peptides compared to the neutralization of clade C isolatesin most cases. Thus, the native structure of gp120 on primaryisolates of clade C will likely pose a challenge for neutralizingantibody induction by candidate HIV-1 vaccines much the sameas it has for clade B. The autologous neutralizing antibodyresponse following primary infection with clade C HIV-1 in SouthAfrica matured slowly, requiring at least 4 to 5 months to becomedetectable. Once detectable, extensive cross-neutralizationof heterologous clade C isolates from South Africa was observed,suggesting an unusual degree of shared neutralization determinantsat a regional level. This high frequency of cross-neutralizationdiffered significantly from the ability of South African cladeC serum samples to neutralize clade B isolates but did not differsignificantly from results of other combinations of clade Band C reagents tested in checkerboard assays. Notably, two cladeC serum samples obtained after less than 2 years of infectionneutralized a broad spectrum of clade B and C isolates. Otherindividual serum samples showed a significant clade preferencein their neutralizing activity. Our results suggest that cladesB and C are each comprised of multiple neutralization serotypes,some of which are more clade specific than others. The clusteringof shared neutralization determinants on clade C primary HIV-1isolates from South Africa suggests that neutralizing antibodiesinduced by vaccines will have less epitope diversity to overcomeat a regional level.

INTRODUCTION

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Introduction

An important goal in the development of an effective human immunodeficiencyvirus type 1 (HIV-1) vaccine is to overcome the extensive geneticheterogeneity of the virus. Nucleotide sequence comparisonshave been used to define three groups of the virus known asgroup M (main), group O (outlier), and group N (non-M, non-O)(50, 69). Group M is further divided into 10 phylogenicallyrelated genetic subtypes (clades A, B, C, D, F1, F2, G, H, J,and K) that, together with a growing number of circulating intersubtyperecombinant forms, comprise the majority of HIV-1 variants inthe world today. Clade C is emerging as most prevalent, beingcommon in India (15, 16, 31, 41) and the southern African countriesof Botswana, Zimbabwe, Malawi, Mozambique, and South Africa(7, 8, 25, 26, 60, 64, 79, 81). Clade B is dominant in NorthAmerica and Western Europe and has been a major focus for vaccinedevelopment (27). It is uncertain whether vaccines that areultimately effective against clade B will be capable of targetingother genetic subtypes of the virus.

The uncertain relevance of genetic subtype to HIV-1 vaccinesis owed in part to a poor understanding of the immunotype diversityof the virus as it relates both to cellular and humoral immunity.The fact that genetic subtypes tend to cluster geographicallyraises the possibility that distinct immunotypes of the virushave evolved along similar lines and, although a growing bodyof evidence suggests that this may not be true in a strict sense(4, 12, 29, 38, 56, 61, 82), additional studies seem warranted.For example, with respect to humoral immunity, the sporadicneutralizing activity of sera from HIV-1-infected individualsappears to be independent of genetic subtype (38, 56, 61, 82).That observation has led to a general notion that genetic subtypedoes not predict the neutralization serotype of the virus. Anexception has been noted for clades B and E (E is now knownas recombinant subtype A/E [32]), which appear to consist ofdifferent neutralization serotypes relative to each other. Thatconclusion was based on results of checkerboard assessmentsmade with four serum samples and virus isolates from each clade(47) and when serum pools from both clades, selected for highneutralizing antibody titers, were tested with a larger panelof clade B and E isolates (45).

The concept of HIV-1 immunotypes may be particularly relevantto neutralizing antibodies. Neutralizing antibodies target thesurface gp120 and transmembrane gp41 envelope glycoproteinsof the virus (62, 65) and could be a valuable antiviral immuneresponse to generate with vaccines (44, 49, 52). These glycoproteinsexist as a trimolecular complex of gp120-gp41 heterodimers (17,24, 43, 83) and are essential for virus entry. Antibody-mediatedneutralization of HIV-1 may take place either by blocking gp120from binding its cellular receptor (CD4) or coreceptor (CCR5and CXCR4) or by preventing gp41 from mediating fusion withthe target cell membrane (2, 18, 21, 22, 28, 30, 39, 40, 74,84). Both glycoproteins display an unusual degree of sequencevariation that gives rise to complex epitopes. One manifestationof this variation during infection is the evolution of neutralizationescape variants. For example, serum from individuals infectedwith clade B HIV-1 often fails to neutralize contemporaneousand later virus isolates but neutralizes earlier isolates fromthe respective individuals quite potently (1, 3, 6). Epitopesresponsible for primary isolate neutralization by serum samplesfrom HIV-1-infected individuals remain largely unknown.

Genetic variation also affects the higher-order structure ofthe native envelope glycoprotein complex, having a profoundeffect on antigenicity. For example, certain N-glycans and tertiaryfolds in the gp120 core can render primary HIV-1 isolates resistantto neutralization by soluble CD4 (sCD4) and many antibody specificitiescompared to T-cell-line-adapted (TCLA) strains of the virus(20, 68, 72, 85). This is very common for epitopes in the thirdvariable cysteine-cysteine loop (V3 loop) of gp120 (5, 73, 77).Antibodies in sera from infected individuals and vaccinatedvolunteers may have potent neutralizing activity against thematched (autologous) HIV-1 variant but those antibodies havelimited neutralizing activity against heterologous variants(14, 34, 55, 58, 63). This is especially true in the case ofvaccine-elicited antibodies (9, 48). Some exceptions includea small number of human monoclonal antibodies (e.g., 2G12, immunoglobulinG1b12 [IgG1b12], and 2F5) and sera from a subset of HIV-1-infectedlong-term nonprogressors, in which cases a broad spectrum ofHIV-1 isolates are neutralized (10).

Immunotype diversity could adversely impact the ability to developa single HIV-1 vaccine that is broadly effective on a globalscale. Alternatively, it may be possible to tailor vaccinesto match the virus variant(s) circulating in specific regionstargeted for vaccination. In either case, the ability to identifyand predict the relevant immunotypes of the virus would hastenvaccine efforts. With respect to neutralizing antibodies, veryfew virus isolates and serum samples belonging to clade C havebeen characterized, and in fact, very little is known aboutthe neutralization properties of clade C isolates and serumsamples from South Africa. The present studies were conductedto define the neutralization properties of these virologic andserologic reagents in preparation for future vaccine clinicaltrials in South Africa and other areas where clade C is common.Our results identify important similarities and differencesbetween clades B and C of HIV-1. Moreover, we provide evidencethat neutralization serotypes of HIV-1 may cluster geographicallywithin a clade. The implications of these findings for vaccinedevelopment are discussed.

MATERIALS AND METHODS

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Materials and Methods

Viruses, cells, and serum samples. Eight clade B and 17 clade C primary HIV-1 isolates were usedin these studies. All clade B isolates possessed an R5 phenotypeand were obtained during early seroconversion from subjectsin the United States, Trinidad, and Italy (9). Nine clade Cisolates (which begin with the prefix Du) were isolated in 1998from female sex workers recruited from four truck stops alongthe major trucking route between Durban and Johannesburg, SouthAfrica. These women were participating in a multicenter clinicaltrial of a potential vaginal microbicide (78). Details of therecruitment procedures are documented elsewhere (67). The womenwere screened monthly for sexually transmitted infections includingHIV. HIV-1 seroconversion was assessed by enzyme-linked immunosorbentassay (ELISA) (Abbott, Chicago, Ill.) and confirmed by usingthe Vironostika HIV Uniform II micro-ELISA 4 system (Omnimed,Madison, Wis.). All HIV-1-positive tests were further confirmedby the Institute of Tropical Medicine, Antwerp, Belgium--thecentral laboratory for the multicenter trial. At each visit,women were given pre- and posttest HIV-1 counseling and wereprovided with intensive condom counseling. Sexually transmitteddiseases were treated according to the South African syndromicmanagement guidelines. Virus was isolated within 4 months ofinitial seroconversion from five of these sex workers (Du123,3 months; Du151, 1.5 months; Du156, 1 month; Du172, 1 month;Du422, 4 months) and at later time points from four additionalsex workers (Du174, 19.5 months; Du179, 21 months; Du204, 12months; Du368, 7.5 months). Sequence analysis of gag, pol, andenv confirmed that all South African isolates were clade C andlacked intersubtype recombination (Williamson et al., submittedfor publication).

Eight additional clade C isolates (which begin with the prefixS) were obtained from individuals attending the sexually transmitteddisease clinic of the Lilongwe Central Hospital in Malawi (64).These isolates were shown to be clade C by serologic and sequenceanalysis of the V3 loop of gp120 (64). All clade C isolatesfrom Africa had an R5 phenotype except for Du179, which wasR5X4 and induced syncytium formation in MT-2 cells. Coreceptorusage of clade C isolates from South Africa was assessed inU87.CD4 cells transfected to express either CCR5 or CXCR4 asdescribed (57). The coreceptor usage of the remaining isolateswas reported previously (9, 64).

Viruses were isolated by peripheral blood mononuclear cell (PBMC)coculture as described (53, 57). All primary isolates were ofa low passage number (three passages or fewer) in PBMC exclusively.Stocks of the TCLA strains, HIV-1_IIIB, HIV-1_MN, and HIV-1_SF-2,were generated in H9 cells (54). All virus stocks were madecell free by filtration (filter pore size, 0.45-µm) andstored in aliquots at -80°C until use. Two additional celllines used in neutralization assays, MT-2 and CEMx174, havebeen described previously (35, 70). PBMC were maintained inRPMI 1640 containing 20% heat-inactivated fetal bovine serumand supplemented with gentamicin (50 µg/ml) and humaninterleukin-2 (4%). Growth medium for the H9, MT-2, and CEMx174cells consisted of RPMI 1640 containing 12% heat-inactivatedfetal bovine serum supplemented with gentamicin (50 µg/ml).

Serum samples presumed to be clade B were obtained from HIV-1-infectedindividuals attending the Duke University Medical Center InfectiousDiseases Clinic in Durham, N.C. The individuals had been infectedwith HIV-1 for $>=$ 2 years and donated serum between 1998 and 2000.A previous study assessed these serum samples for neutralizingactivity against the eight clade B primary isolates used here(9). Additional serum samples were collected at multiple timepoints from each of the nine sex workers in South Africa. Dueto personal preference, participation in a structured treatment-interruptionprotocol, or nonavailability, no subjects were on antiretroviraltherapy at the time of serum collection; this was done to avoidpossible in vitro antiviral activity of the drugs that mightbe misinterpreted as neutralizing antibody activity at low serumdilutions. All sera were heat inactivated at 56°C for 45min.

Monoclonal antibodies and sCD4. IgG1b12, 2G12, and 2F5 are human monoclonal antibodies thatbind conserved epitopes and cross-neutralize a variety of TCLAstrains and primary isolates (11, 23, 36, 66, 75, 76). The epitopefor IgG1b12 is located in the CD4-binding domain of gp120 andis sensitive to mutations in V2 and C3 (51). 2G12 recognizesan epitope in the C2-V4 region of gp120 that involves sitesof N glycosylation (76). 2F5 recognizes a linear epitope inthe ectodomain of gp41 having the amino acid sequence ELDKWA(59). sCD4 comprising the full-length extracellular domain ofhuman CD4 and produced in Chinese hamster ovary cells was obtainedfrom Progenics Pharmaceuticals, Inc. (Tarrytown, N.Y.).

DNA sequencing. The DNA sequence of the V3 loop of gp120 was determined by directsequencing of amplified products generated by RT-PCR. PCR primers,with the reverse outer primer used as the reverse transcriptaseprimer in the cDNA synthesis step, were o-env, 6201 to 6227and 9067 to 9095; i-env, 6815 to 6838 and 7322 to 7349 (numberedusing the HIV-1 HXBr sequence, Los Alamos HIV sequence database).Amplified DNA fragments were purified using the QIAQUICK PCRPurification Kit (Qiagen, Valencia, Calif.). Sequencing wasdone using the Sanger dideoxyterminator strategy with fluorescencedyes attached to the dideoxynucleotides, and the sequence determinationwas made by electrophoresis using an ABI 377 sequencer. A portionof the gag (939 bases), pol (834 bases), and gp120-gp41 junction(340 bases) was also sequenced and shown to be clade C withno evidence of recombination (Williamson et al., submitted).

gp120-V3 peptides. Peptides corresponding to amino acid sequences in the V3 loopof clade C isolates were synthesized, purified, and analyzedby SynPep Corporation (Dublin, Calif.). The HIV-1_IIIB V3 peptidewas purchased from Sigma (Saint Louis, Mo.), whereas the HIV-1_MNV3 peptide was purchased from American BioTechnologies, Inc.(Cambridge, Mass.). All peptides were >90% pure as judgedby high-pressure liquid chromatography and mass spectrometry.

Neutralizing antibody assays. Neutralization of primary isolates was measured in PBMC by usinga reduction in p24 Gag antigen synthesis as described previously(9). Briefly, 500 50% tissue culture infective doses of viruswere incubated with various dilutions of test samples (serum,monoclonal antibodies, and sCD4) in triplicate for 1 h at 37°Cin 96-well U-bottom culture plates. PHA-PBMC were added andincubated for one day. The cells were then washed three timeswith growth medium and resuspended in 200 µl of freshgrowth medium. Culture supernatants (25 µl) were collectedtwice daily thereafter and mixed with 225 µl of 0.5% TritonX-100. The 25 µl of culture fluid removed each day wasreplaced with an equal volume of fresh growth medium. Concentrationsof p24 Gag antigen in Triton X-100 lysates were measured inan antigen capture ELISA as described by the supplier (DuPont/NENLife Sciences, Boston, Mass.). Concentrations of p24 in viruscontrol wells (virus plus cells but no test serum) were determinedfor each harvest day. Concentrations in all remaining wellswere determined for a harvest day that corresponded to a timewhen p24 production in virus control wells was in an early linearphase of increase that exceeded 3 ng/ml, which is when optimumsensitivity is achieved in this assay (87). The limit of detectionin the p24 ELISA was 0.1 ng of p24/ml. Neutralization titersare given as the reciprocal of the minimum serum dilution (calculatedprior to the addition of cells) that reduced p24 synthesis by80% relative to a negative control serum sample from a healthy,HIV-1-negative individual.

Neutralization assay for TCLA strains were performed in eitherMT-2 cells (HIV-1_IIIB and HIV-1_MN) or CEMx174 cells (HIV-1_SF2)by using neutral red to quantify the percentage of cells thatsurvived virus-induced killing (54). Briefly, 500 50% tissueculture infective doses of virus were incubated with multipledilutions of serum samples in triplicate for 1 h at 37°Cin 96-well flat-bottom culture plates. Cells were added andthe incubation continued until most but not all of the cellsin virus control wells (cells plus virus but no serum sample)were involved in syncytium formation (usually 4 to 6 days).Cell viability was quantified by neutral red uptake as described(54). Neutralization titers are defined as the reciprocal serumdilution (before the addition of cells) at which 50% of cellswere protected from virus-induced killing. A 50% reduction incell killing corresponds to an approximate 90% reduction inp24 Gag antigen synthesis in this assay (9). Each set of assaysincluded a positive control serum that had been assayed multipletimes and had a known average titer.

V3-specific neutralizing antibodies were assessed by incubatingdiluted serum samples (diluted with an equal volume of phosphate-bufferedsaline, pH 7.4) for 1 h at 37°C in the presence and absenceof V3 peptide (50 µg/ml). Titers of neutralizing antibodieswere then determined in either the PBMC assay (in the case ofprimary isolates) or the MT-2 cell assay (in the case of HIV-1_IIIBand HIV-1_MN) as described above.

ELISA. V3 peptide-specific binding antibodies were assessed by ELISAin Nunc (Roskilde, Denmark) Immuno plates (MaxiSorb F96) usingalkaline phosphatase-conjugated, goat anti-monkey IgG as described(19). Plasma samples were assayed in duplicate at a 1:50 dilution,and values are given as the average absorbance at a wavelengthof 405 nm.

Statistical analyses. Differences in positive response rates (i.e., positive neutralizationat any serum dilution) between genetic subtypes of the virusfor a given serum sample were tested for statistical significanceby using the two-sided Fisher's exact test. Differences in meanlog neutralizing antibody titers between genetic subtypes ofthe virus for a given serum sample were tested by using thetwo-sided Wilcoxon rank sum test. For overall differences ineither the positive response rates or mean log neutralizingantibody titers between genetic subtypes of the virus, pairwiseresults were pooled as a sample and tested for significanceby using the nonparametric Wilcoxon sign rank test. All differenceswere considered significant if P was $<=$ 0.05. Analyses of overalldifferences included only heterologous virus-serum pairs. Thiswas done to eliminate bias, since only the Du samples containedautologous pairs.

RESULTS

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Results

Neutralization of clade C primary HIV-1 isolates with sCD4 and monoclonal antibodies. Primary isolates from eight subjects in South Africa and eightsubjects in Malawi were characterized in neutralization assayswith sCD4 and three broadly neutralizing human monoclonal antibodies.These clade C isolates all exhibited a high level of resistanceto inhibition by sCD4 (Table 1). Of the three monoclonal antibodiestested, IgG1b12 was most effective, neutralizing five of eightisolates from South Africa and four of eight isolates from Malawiat doses in the range of <1.8 to 50 µg/ml. Monoclonalantibody 2F5 neutralized two isolates from Malawi but none fromSouth Africa. A third monoclonal antibody, 2G12, failed to neutralizeall 16 clade C isolates tested. The broad resistance of cladeC primary isolates to neutralization by 2G12 was in strikingcontrast to the ability of this same preparation of 2G12 toneutralize six of eight clade B isolates tested previously (9).Control assays performed with TCLA strains and primary isolatesbelonging to clade B confirmed no loss of activity of the sCD4and monoclonal antibodies used in these experiments (data notshown).

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TABLE 1. Neutralization sensitivity of HIV-1 clade C isolates as measured with sCD4 and human monoclonal antibodies

Neutralizing antibody response following infection with clade C HIV-1. Serum samples collected at multiple time points from nine SouthAfrican sex workers were assayed for neutralizing activity againstthe autologous virus isolate and three TCLA strains of cladeB HIV-1. All subjects developed a neutralizing antibody responseagainst their own virus (Fig. 1). The magnitude of this responsevaried between individuals and was relatively potent in mostcases (titers of >100 in seven of nine cases). Although thetiming of serum collection did not permit a refined assessmentof the temporal response, it is accurate to say that autologousneutralizing antibodies were undetectable for at least the first4 to 5 months of infection in three subjects (Du123, Du151,and Du422). Despite this delay, all three subjects eventuallymounted a potent autologous neutralizing antibody response.Autologous neutralizing antibodies were low or undetectableat early time points and later rose in magnitude for subjectsDu123, Du151, Du156, Du172, and Du422 as evidence that thesefive study subjects were in an early stage of seroconversionat the time of their enrollment. Autologous neutralizing antibodiesin these five subjects were assessed with virus that was obtainedshortly after infection. Autologous neutralizing antibodiesin the remaining cases were measured with virus that was obtainedeither before (Du368) or after (Du174, Du179, and Du204) thetime of first serum collection (an estimated 6 to 15 monthsfrom initial ELISA positivity). Of these latter cases, virusfrom subject Du368 was neutralized potently by all serum samplescollected 5.5 months later and thereafter. Virus isolated atmonth 21 from subject Du179 was neutralized weakly by serumsamples obtained at month 15 and was neutralized potently byserum samples obtained at month 25 and thereafter. Virus fromsubject Du174, isolated at month 19.5, was neutralized weaklyor not at all by serum collected at months 13, 18, 30, and 34.A second study subject, Du204, had a similar weak autologousneutralizing antibody response.

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FIG. 1. Neutralizing antibody response over time in infected individuals in South Africa. Neutralizing antibodies were measured in PBMC with the early autologous isolate and in either MT-2 or CEMx174 cells with the clade B TCLA strains IIIB (MT-2), MN (MT-2), and SF2 (CEMx174). Results that were negative (neutralization titers of <4 for autologous isolates and <20 for IIIB, MN, and SF2) were assigned a value of 1 for representation.

TCLA strains belonging to clade B HIV-1 were highly sensitiveto neutralization by the clade C serum samples. Overall neutralization-sensitivitywith clade C serum samples was HIV-1_MN ${cong}$ HIV-1_SF2 > HIV-1_IIIB(Fig. 1). Neutralizing antibodies were sometimes detected withclade B TCLA strains before being detected with the autologousclade C isolate. Moreover, the potency of neutralization detectedwith TCLA strains usually exceeded the potency detected withthe autologous isolate.

Two additional observations are worth noting. First, as mentionedabove, sera from 5 subjects were capable of neutralizing theautologous isolate obtained prior to serum collection (Du123,10.5 months; Du151, 8 months; Du156, 3 months; Du172, 8 months;Du422, 9 months). Autologous isolates in these cases were obtained1 to 3 months after initial seroconversion and, as such, couldclosely resemble the transmitted variant that drove the initialantibody response, leading to antibodies that neutralized theearly variant. Two subjects enrolled later in infection (Du179and Du368) had detectable autologous neutralizing antibodiesthat increased in magnitude over the observation period. Autologousisolates in these two cases were obtained 21 and 7.5 monthsafter infection and therefore could be variants that escapedan earlier neutralizing antibody response. In this event, theneutralizing antibodies we detected might have arisen as a denovo antibody response to escape epitopes. Although earlierisolates were not available to test this possibility, a laterisolate from subject Du179 (36.5 months) was sensitive to neutralization(titer >108) by serum samples collected at months 25, 30,and 32.5, suggesting that the neutralization determinants werenot evolving at a fast pace.

Antibody response to the V3 loop of gp120. V3-specific antibodies were assessed by ELISA and in competitiveneutralization assays with peptides from five different cladeC isolates from South Africa (Du123, Du151, Du172, Du179, andDu422), the clade C consensus sequence (37), and the clade BTCLA strains HIV-1_MN and HIV-1_IIIB. The amino acid sequenceof each V3 peptide is shown in Table 2. Sera from South Africansubjects reacted strongly with the autologous peptide and exhibitedbroad cross-reactivity with heterologous clade C peptides (Fig.2). Reactivity was somewhat diminished in the case of the consensusclade C peptide and more so in the case of the IIIB peptide.Reactivity to the HIV-1_MN peptide was variable, being relativelystrong for subjects Du151 and Du179 and low to moderate forsubjects Du123 and Du422.

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TABLE 2. Amino acid sequences of V3 peptides

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FIG. 2. ELISA reactivity to V3 peptides. Serum samples (1:50 dilution) were evaluated by ELISA for the presence of antibodies that could bind individual peptides derived from the V3 loop of the indicated virus strains. The amino acid sequence of each peptide is shown in Table 2. The dotted line represents the cutoff value for positive reactivity (twice the optical density [OD] of a control serum sample from a healthy, HIV-1-negative individual). The following serum samples were obtained after the estimated number of months of infection: Du123 (13.5 months), Du151 (11.3 months), Du172 (8 months), Du179 (25 months), Du422 (17 months). CC, clade C consensus sequence.

To determine whether these V3-specific antibodies had neutralizingactivity, serum samples were preincubated with V3 peptides andthen assayed for neutralizing activity against the autologousvirus and two TCLA strains (Fig. 3). A major fraction of autologousneutralizing activity in serum Du179 was blocked by the matchedDu179 V3 peptide, suggesting the presence of neutralizing antibodiesdirected against the V3 loop of this virus. As a control, theHIV-1_MN peptide had no effect on the autologous neutralizingactivity of this serum sample. Matched V3 peptides and the HIV-1_MNV3 peptide had no effect on the autologous neutralizing activityof four other clade C serum samples. By comparison, the HIV-1_MN-specificneutralizing activity of all five serum samples was dramaticallyreduced in the presence of matched V3 peptides and the HIV-1_MNV3 peptide but not the HIV-1_IIIB V3 peptide. In addition, theHIV-1_IIIB-specific neutralizing activity was reduced in thepresence of matching V3 peptide and the HIV-1_IIIB V3 peptidebut not the HIV-1_MN V3 peptide. We note that the reduction inHIV-1_IIIB-specific neutralization was minor in one of threecases examined (Du123). Due to sample availability and low neutralizationtiters against HIV-1_IIIB, the remaining two samples could notbe tested in these competition assays with HIV-1_IIIB.

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FIG. 3. Ability of V3 peptides to out-compete the neutralizing activity of clade C serum samples from South Africa. Serum samples shown in Fig. 1 were evaluated for neutralizing activity in the presence and absence of gp120 V3 peptides (50 µg/ml) as described in Materials and Methods. Autologous (Autol.) V3 peptide refers to a peptide bearing the amino acid sequence of the virus from the subject who was the source of serum listed on the x axis. The top panel shows autologous virus-serum combinations, the middle panel shows clade C serum samples assayed with the HIV-1_MN virus, and the bottom panel shows clade C serum samples assayed with the HIV-1_IIIB virus. ID₈₀, 80% inhibitory dose.

Analysis of intra- and interclade neutralization. A checkerboard analysis was performed with clade B and C virusisolates and serum samples. Clade C serum samples were selectedfrom the South African sex workers at a time when neutralizingactivity was detected with the autologous virus and TCLA strains.Clade B serum samples were obtained from individuals in NorthCarolina who had documented HIV-1 infection for $>=$ 2 years. Thesesame clade B serum samples were assayed recently against theclade B viruses in our panel (9), and therefore, those resultswere used in our comparative analyses. We caution that a potentialsource of error in our checkerboard assays is the lack of sequenceinformation to confirm the genetic subtype of virus from ourpresumed clade B serum donors from North Carolina. These subjectswere presumed to be infected with clade B based on the highincidence of clade B in North America. We also note that ourpartial genetic and serologic characterization of the cladeC isolates from Malawi does not entirely eliminate the possibilitythat these are recombinant viruses.

Cross-neutralization within and between genetic subtypes wasreadily apparent (Table 3). The clade C isolates appeared tobe more sensitive to neutralization overall compared to cladeB isolates. Specifically, the Du isolates were neutralized 70%of the time (excluding autologous virus-serum combinations)by Du serum samples, and 54% of the time by clade B serum samples.Moreover, the Malawi isolates were neutralized 48% of the timeby Du serum samples. By comparison, clade B isolates were neutralized25% of the time by Du serum samples (Table 3) and 27% of thetime by clade B serum samples (9). Overall trends were analyzedstatistically based on positive neutralization frequencies andmean neutralization titers. Only the positive response ratesbetween Du and clade B isolates tested with Du serum sampleswere found to be statistically significant (Table 4). We notethat no significant differences were identified based on meanneutralization titers (Table 4).

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TABLE 3. Checkerboard analysis of clade B and C neutralization

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TABLE 4. Statistical analysis of checkerboard results

A number of clade-specific reactivities were observed withinthe overall analysis: (i) isolate Du174 was neutralized preferentiallyby clade C sera (P < 0.01 based on response rate), (ii) serumDu151 exhibited a preferential neutralization of clade C isolatesfrom South Africa (P = 0.01 based on response rate; P = 0.02based on mean neutralization titer), (iii) serum NLS-02 exhibiteda preferential neutralization of clade C isolates from SouthAfrica (P = 0.01 by both criteria), and (iv) serum Du204 exhibiteda preferential neutralization of clade C isolated from SouthAfrica (P $<=$ 0.05 based on mean neutralization titer). Notably,one serum sample from the Du cohort (Du179) neutralized 16 of16 clade C isolates and six of eight clade B isolates (Table3).

A broader assessment of cross-neutralizing activity with 50heterologous primary HIV-1 isolates was performed on a smallsubset of serum samples for which an adequate supply of serumwas available. These particular serum samples had potent neutralizingactivity against the early autologous clade C isolate (titer> 100) and were able to neutralize TCLA strains belongingto clade B. They were assayed at a 1:20 dilution with the 50primary isolates to be selective for relatively potent heterologousneutralization specificities. The heterologous primary isolatesconsisted of the 8 clade B and 16 clade C isolates listed inTable 3 plus an additional 26 clade B isolates. The resultsare summarized in Table 5 and do not include autologous virus-serumcombinations. Serum Du151 neutralized 40% of the isolates asevidence that this serum sample contains broadly cross-reactiveneutralizing antibodies. Serum samples Du156 and Du368 weremuch less cross-reactive but nonetheless neutralized 7 to 17%of isolates. No clade-specific preferences were observed withthese two serum samples (P = 1.00).

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TABLE 5. Cross-neutralizing activity of serum samples from three subjects infected with clade C HIV-1

DISCUSSION

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Discussion

The neutralization properties of primary isolates and serumsamples from clade C HIV-1-infected individuals were characterizedand compared to clade B. Our goal was to develop standard virologicreagents and to acquire information that would benefit vaccinedesign. A major focus was placed on South Africa because ofthe high rates of HIV-1 transmission and the lack of informationon neutralizing antibodies in that country. A particular emphasiswas placed on a group of female sex workers located at multiplestops along a major trucking route between Durban and Johannesburg.These women were participating in HIV-1 prevention programsas part of a microbicide trial and were screened monthly forHIV-1 seroconversion. Virus isolates and serum samples wereavailable in some cases very soon after infection, which madeit possible to examine the autologous and heterologous neutralizingactivity of the earliest antibodies generated.

All but one clade C isolate possessed the R5 biologic phenotypethat is typical of transmitted variants. These isolates (eightfrom South Africa and eight from Malawi) resembled R5 cladeB isolates in their sensitivity to neutralization by some butnot all serologic reagents. Shared properties included a highlevel of resistance to inhibition by sCD4 and the frequent neutralizationby monoclonal antibody IgG1b12. Resistance to sCD4 is a generalproperty that distinguishes primary isolates from TCLA strains(20) and is thought to reflect the exposure of critical epitopesin and around the CD4 binding site of gp120 as affected by N-linkedglycans and tertiary folds in the native gp120 molecule (85).It may be presumed that we preserved the sCD4-resistant phenotypeof these clade C isolates by passing them a minimum number oftimes in PBMC exclusively (71). Many sCD4-resistant variantsof HIV-1 are difficult to neutralize with monoclonal antibodiesand sera from infected individuals. The IgG1b12 epitope, whichoverlaps the CD4 binding domain of gp120 (51), is an exceptionin that neutralization by this monoclonal antibody is not predictedby sCD4 sensitivity. For example, the 89.6 and 89.6P variantsof simian-human immunodeficiency virus are both moderately sensitiveto inhibition by sCD4 yet exhibit a striking dichotomy in theirsensitivity to neutralization by IgG1b12 (19). The ability ofIgG1b12 to neutralize many sCD4-resistant variants of cladeC HIV-1 is additional evidence that this antibody specificitywould be highly beneficial for broadly effective vaccination.

Another monoclonal antibody, 2F5, that is known to be effectiveagainst primary isolates was only able to neutralize 2 of 16clade C isolates here. Since this low frequency was no differentstatistically from the three of eight clade B isolates neutralizedby this same batch of 2F5 (9), the neutralizing activity of2F5, like that of IgG1b12, does not appear to distinguish cladeB from clade C. A much different outcome occurred with the 2G12monoclonal antibody in that it failed to neutralize all 16 cladeC isolates from South Africa and Malawi up to the highest dosetested (50 µg/ml). 2G12 has been shown to neutralize primaryHIV-1 isolates from multiple clades (9, 23, 46, 75, 76), butvery high doses were needed to neutralize the small number ofclade C isolates tested in those studies (75, 86). We concludethat 2G12 has very poor neutralizing activity against cladeC isolates relative to other clades. It seems unlikely thatthe neutralizing specificity of 2G12 will have an impact inregions where clade C is prevalent, except in cases where itis synergistic with other neutralizing antibody specificities(86).

Our analysis of sequential serum samples from a group of SouthAfrican sex workers infected with clade C HIV-1 showed a delayin autologous neutralizing antibody production following primaryinfection of at least 4 to 5 months. That delay was similarto clade B infection (55, 63) and could be due to either earlyimmunologic dysfunction, the poor immunogenicity of the envelopeglycoproteins, or a combination of these factors. Followingthe delay, a potent autologous neutralizing antibody responsewas detected in most cases (titers > 100) as evidence thatthe B-cell response to critical epitopes eventually matured.Despite potent neutralizing antibodies, one individual (Du151)never gained control of her viremia and progressed to AIDS rapidly.We do not know the status of this person's HIV-1-specific cellularimmune response, nor were we able to determine whether a neutralizationescape variant arose that might explain the rapid progression.

In addition to neutralizing the autologous isolate, clade Cserum samples from South Africa neutralized TCLA strains ofclade B HIV-1 with a level of potency similar to clade B serumsamples. This is evidence that the antibody specificities forTCLA HIV-1 neutralization are conserved between clades B andC. In support of this notion, antibodies in clade C serum samplesbound peptides corresponding to the V3 loop of clade B and Cgp120, which is a major target for the neutralization of cladeB TCLA strains (5, 73, 77). Although the amino acid sequenceof the V3 loop of clades B and C can be quite different (37,64), they appear to share antigenic features recognized by monoclonalantibodies (33). This may explain why the neutralizing activityof clade C serum samples against clade B TCLA strains was sensitiveto the presence of V3 loop peptides. The inability of V3 looppeptides to block autologous neutralization of clade C primaryisolates in four of five cases examined, this despite the presenceof antibodies to the autologous V3 peptide, suggests that certainepitopes in the V3 loop of clade C primary isolates are poorlyantigenic relative to TCLA strains. A similar phenomenon hasbeen described for clade B (5, 73, 77). This dichotomy in antigenicityis an indication that epitope exposure on the native envelopeglycoprotein complex of clade C primary isolates will pose achallenge for neutralizing antibody induction by candidate HIV-1vaccines much the same as it has for clade B (52, 85).

Primary isolates of clade B and C HIV-1 were further comparedin checkerboard neutralization assays that differed from thosein previous reports in several ways: (i) a large number of cladeC isolates and serum samples were included, (ii) virus isolateswere obtained early in infection, and (iii) the clade C serumsamples corresponded to an early stage of neutralizing antibodyproduction. In general, the earliest neutralizing antibodiesto be detected in an HIV-1-infected individual have a limitedrange of specificity (14, 55). It was therefore unexpected tofind 70% of heterologous clade C virus-serum combinations testingpositive from South Africa. This high frequency is unusual and,with the exception of sera from some long-term nonprogressors(13, 63), has not be documented previously.

The extensive cross-neutralization within the South Africanserum samples and virus isolates may be an indication of sharedneutralization determinants. This would be encouraging for vaccineefforts, as it suggests that neutralizing antibodies will haveless epitope diversity to overcome at a regional level. Thebroad implications of this concept depend in part on the geographicrange of the shared determinant that defines the correspondingneutralization serotypes. Less epitope diversity would be expectedif multiple subjects in our cohort were infected by the sameindividual. Shared determinants might also arise as a consequenceof serial transmission of selected isolates in these sex workers.Early evidence in South Africa suggested multiple introductionsof the virus into the country, with the diversity observed beinggreater than one would expect from founder-type effects suchas seen in Thailand (8, 79). Similarly, within this sex workercohort, the analysis of the relationships between gag, pol,and env sequences showed relatively high diversity, and littlephylogenetic clustering of sequences was detected (Williamsonet al., submitted). Single- donor and serial transmission ofselected isolates are therefore not obvious explanations forour results. However, full-length sequencing does show reliableclustering of two of the isolates (Du151 and Du422), suggestingthat at least for these two isolates there was a common sourcein the not-too-distant past (80). Moreover, we cannot be certainthat these female sex workers were not infected multiple timesto give rise to a cross-reactive polyvalent neutralizing antibodyresponse. Along this same line, it has been reported that initialvirus populations are more heterogeneous in women than in menimmediately following transmission (42). Additional studieswill be needed to clarify the events that gave rise to the cross-neutralizingantibody responses in the South African subjects and how thoseevents might impact vaccine development.

The 70% positive neutralization rate within the set of SouthAfrican clade C viruses and serum samples differed significantlyonly from the overall ability of these same serum samples toneutralize clade B isolates. This case of clade-specific neutralizationdid not extend to other combinations in our checkerboard assayswith clade B and C reagents, suggesting that clades B and Care comprised in part of overlapping neutralization serotypes.Evidence that the overlap was only partial comes from a numberof individual cases of clade-specific neutralization. One exampleis a clade C isolate (Du174) that was neutralized preferentiallyby clade C serum samples. In addition, two South African cladeC serum samples neutralized South African clade C isolates ina specific manner. Taken together with the selective neutralizingactivity of 2G12, these examples reflect subtle associationsbetween genetic subtype and neutralization serotype that havegone unnoticed in previous studies, owing in part to the complexityof the neutralization determinants on the virus and the limitednumber of clade C reagents used in the past. One unexpectedfinding was the preferential neutralization of clade C isolatesby a presumed clade B serum sample. Unfortunately, a lack ofsequence information on the virus from this individual makesit possible that infection was with a non-clade B virus. Nonetheless,this is an additional case of a serum that recognized a neutralizationserotype found in clade C that was rarely detected in cladeB. Our combined results are an indication that within each geneticsubtype are multiple neutralization serotypes, some of whichare more clade-specific than others.

During the course of our studies we discovered two individualsin South Africa (Du151 and Du179) whose serum after less than2 years of infection neutralized a large number of clade B andC primary isolates. This cross-neutralizing activity was notunlike that of sera from some HIV-1-infected long-term nonprogressors(13, 63) and appears to be relatively unique for recent seroconverters.The cross-reactive neutralizing activity could be due to hostfactors, viral factors, or a combination of the two. It alsoserves to confirm that clades B and C consist in part of overlappingneutralization serotypes. The viral envelope glycoproteins fromthese two individuals are interesting candidates for vaccinedevelopment.

It seems possible that some neutralization serotypes track morewith geography than with genetic subtype, as was suggested byour observations in a cohort of sex workers in South Africainfected with clade C HIV-1. If generally true, targeted immunogensmight prove beneficial for vaccines in this and other partsof the world. The selection of immunogens for such tailoredvaccines will require extensive surveys of virus isolates andserum samples. Alternatively, new approaches for cross-reactiveneutralizing antibody induction are under investigation thatmay make tailoring efforts unnecessary (52). With few exceptions(e.g., 2G12 epitope), an immunogen that generates antibodiescapable of neutralizing many clade B isolates may be expectedto neutralize many clade C isolates and vice versa. Until suchimmunogens become available, efforts to induce neutralizingantibodies with candidate HIV-1 vaccines might benefit the mostby including envelope glycoproteins from one or more strainsof the virus that predominate in the specific regions targetedfor vaccination. We add as a cautionary note that it is notclear at this time what level of neutralizing antibody inductionand clinical benefit will be achieved with those envelope glycoproteins.

ACKNOWLEDGMENTS

We thank Mary Phoswa and Melissa Kerkau for virus isolationand Tonie Cilliers for virus phenotyping. We also thank MyronS. Cohen for providing access to samples from Malawi, DennisBurton for IgG1b12, and Herman Katinger and John Mascola for2G12 and 2F5.

This work was supported by the U.S. National Institutes of Health(grants AI46705, P30-HD37260, and DK49381), the South AfricanAIDS Vaccine Initiative, the Poliomyelitis Foundation, and theNational Research Foundation of South Africa.

FOOTNOTES

* Corresponding author. Mailing address: Department of Surgery, Box 2926, Duke University Medical Center, Durham, NC 27710. Phone: (919) 684-5278. Fax: (919) 684-4288. E-mail: monte{at}duke.edu.

REFERENCES

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