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Journal of Virology, June 1999, p. 4640-4650, Vol. 73, No. 6
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Cross-Subtype Neutralizing Antibodies Induced in
Baboons by a Subtype E gp120 Immunogen Based on an R5 Primary Human
Immunodeficiency Virus Type 1 Envelope
Thomas C.
VanCott,1,*
John R.
Mascola,2,3
Lawrence D.
Loomis-Price,1
Faruk
Sinangil,4
Naamah
Zitomersky,1
John
McNeil,2
Merlin L.
Robb,2
Deborah L.
Birx,2 and
Susan
Barnett4
Henry M. Jackson
Foundation1 and Division of
Retrovirology, Walter Reed Army Institute of
Research,2 Rockville, Maryland 20850;
Department of Infectious Diseases, Naval Medical Research
Institute, Bethesda, Maryland 208923; and
Chiron Corporation, Emeryville, California
946084
Received 28 December 1998/Accepted 1 March 1999
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ABSTRACT |
Global human immunodeficiency virus type 1 (HIV-1) diversity may
require engineering vaccines to express antigens representing strains
prevalent in the target population of vaccine testing. The majority
(90%) of incident infections in Thailand are genetic subtype E, with a small percentage of subtype B infections in the
intravenous drug user populations. We have evaluated and compared the binding and HIV-1 neutralizing properties of serum
antibodies induced in baboons by CHO cell-expressed monomeric gp120
derived from a CCR5-using (R5) subtype E primary
HIV-1CM235 or a CXCR4-using (X4) subtype B T-cell
line-adapted (TCLA) HIV-1SF2 isolate. In contrast
to the subtype-specific HIV-1 neutralizing antibodies induced with
recombinant HIV-1SF2 gp120
(rgp120SF2), rgp120CM235 immunization induced
antibodies capable of neutralizing both subtype E and subtype B TCLA
HIV-1 isolates. However, neither immunogen induced antibodies capable
of neutralizing primary HIV-1 isolates. Antibody induced by
rgp120CM235 preferentially bound natively folded gp120 and
retained strong cross-reactivity against multiple gp120 strains within
subtype E as well as subtype B. In contrast, antibody
responses to rgp120SF2 were directed predominantly to linear epitopes poorly exposed on native gp120 and had more limited cross-recognition of divergent gp120. Fine epitope mapping revealed differences in antibody specificities. While both
rgp120CM235 and rgp120SF2 induced antibodies to
regions within C1, V1/V2, V3, and C5, unique responses were induced by
rgp120CM235 to multiple epitopes within C2 and by
rgp120SF2 to multiple epitopes within C3, V4, and C4. These
data demonstrate that strain and/or phenotypic differences of HIV-1
subunit gp120 immunogens can substantially alter antibody binding
specificities and subsequent HIV-1 neutralizing capacity.
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INTRODUCTION |
Most human immunodeficiency virus
type 1 (HIV-1) subunit vaccine candidates are based on genes from
prototype T-cell line-adapted (TCLA) subtype B viruses. Examples are
gp120 and gp160 immunogens based on HIV-1 strain IIIB, MN, or SF2.
Since the HIV-1 epidemic in southeast Asia is largely caused by subtype
E viruses (35, 43, 56-58), it may be important to evaluate
vaccines expressing antigens from subtype E for use in this region.
Subtype E HIV-1 is antigenically distinct from subtype B; sera
(39, 40) and neutralizing monoclonal antibodies (MAbs)
(48, 78) derived from subtype B-infected donors
preferentially neutralize viruses from the same subtype, though other
studies have not identified such an association between HIV-1 serum
neutralization serotype and genetic subtype (29, 33). HIV-1
sera from subtype B- and E-infected individuals bind preferentially to
HIV-1 gp120 and gp160 from subtypes B and E, respectively (39,
80). However, while gp120 from subtype B and subtype E may
be distinct antigenically, it remains to be determined
whether as immunogens they are capable of inducing
cross-subtype functional immune responses. An example of discordance
between HIV-1 gp120 antigenic and immunogenic properties was
demonstrated by the ability of column-immobilized gp120 to remove
primary isolate-neutralizing antibody activity from HIV-1 serum and
its inability to elicit such antibodies in animals (70).
Previous subunit HIV-1 envelope vaccines using
monomeric forms of gp120 or gp160 are immunogenic in small
animals, primates, and humans, but the antibody responses, though
capable of neutralizing TCLA HIV-1 isolates, have limited
neutralizing activity against primary HIV-1 isolates (4, 25,
30, 41, 42, 67, 85); however, recent studies using a resting cell
assay obtained significant neutralization of several X4-using primary
HIV-1 isolates by sera from individuals immunized with
monomeric recombinant HIV-1SF2 gp120
(rgp120SF2) (10, 88). These results may be
attributable to the inefficiency of these monomeric gp120
vaccines to elicit antibodies specific for conserved, discontinuous
epitopes, since the majority of antibodies are focused primarily to
linear epitopes poorly accessible on cell surface expressed
gp120-gp41 (81). Monomeric gp120 or gp160 vaccines based on
TCLA isolates, therefore, may lack structural properties critical for
the ability to induce broadly reactive and neutralizing antibody. These
structural properties may be related to the adaptation of the HIV-1
envelope strain, since TCLA and primary isolates have been demonstrated
to have significant phenotypic differences with respect to
coreceptor usage (1, 14, 15, 18) and susceptibility to
antibody- or serum-mediated neutralization (2, 7, 13, 45,
63, 65). Immunization with monomeric gp120 from
strains MN and SF2 protected chimpanzees against homologous and
heterologous primary isolate HIV-1SF2 challenge
(5, 17), and a vaccine containing rgp120SF2
protected rhesus macaques against challenge with the closely
related SHIVSF13 (26). However, several
individuals enrolled in clinical trials of candidate
monomeric gp120 subunit vaccines became HIV-1
infected despite receiving the full vaccination regimen (12, 31,
44), indicating that these vaccines are less than 100% effective.
There are several potently neutralizing MAbs which map to regions
accessible on monomeric gp120 or gp41 (8, 11, 21, 23,
52, 53, 60, 75, 77, 78). The neutralizing epitopes, present
on monomeric gp120, are not currently immunogenic when presented in the context of a vaccine. The majority of the broadly anti-gp120 neutralizing MAbs are directed to conformational
epitopes that have been particularly difficult to elicit with
monomeric HIV-1 subunit vaccines. Studies designed to
correlate antibody binding and neutralizing capacity have shown poor
correlation with binding to monomeric gp120 and superior
correlation with binding to oligomeric forms of HIV-1 envelope
(19, 45, 64), though this correlation is not complete for
all antibodies (20). This attribute is likely due to highly
antigenic, but not functional, epitopes that are more accessible on
gp120 and less accessible in the context of membrane-expressed
oligomeric gp120-gp41 (19, 45, 50, 64, 69, 72). Presentation
of gp120 as part of an uncleaved oligomeric gp140 protein resulted in
the induction of antibodies capable of neutralizing divergent TCLA
isolates as well as some susceptible primary HIV-1 isolates
(83).
In this study, we compared the binding and neutralizing properties of
serum antibodies induced in baboons immunized with rgp120 from either a
subtype B X4 TCLA (HIV-1SF2) or a subtype E R5 primary (HIV-1CM235) HIV-1 isolate. Sera collected after a
series of immunizations were evaluated for antibody binding and
neutralization properties. The two immunogens induced antibody
responses that were readily distinguished. The X4 TCLA gp120 induced
antibodies specific for multiple linear epitopes within gp120 that
are poorly exposed on native gp120 and neutralized only subtype B TCLA
HIV-1 isolates. In contrast, the R5 primary gp120CM235
induced antibodies preferentially reactive with native gp120, bound to
multiple subtype B and E gp120 strains, and neutralized both subtype B
and subtype E TCLA isolates. These data demonstrate that HIV-1
envelope glycoprotein structural and antigenic properties, associated
with HIV-1 strain and/or phenotype, have substantial impact on
vaccine immunogenicity in nonhuman primates.
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MATERIALS AND METHODS |
Materials.
The rgp120SF2 subunit protein was
produced in CHO cells and has been previously described
(24); rgp120CM235 was prepared by similar
methods. Both proteins are correctly glycosylated and bind CD4, and
preparations are >90% pure. HIV-1SF2 is a TCLA
isolate that uses the X4 coreceptor. HIV-1CM235 is a
primary isolate that uses the R5 coreceptor and was originally isolated
by cocultivation in peripheral blood mononuclear cells (PBMC) from a
subtype E HIV-1-infected individual living in Chiang Mai, Thailand
(43). MF-59, a squalene-water emulsion containing 5%
squalene, 0.5% Tween 80, and 0.5% Span 85 (79), was used
as the adjuvant for both rgp120SF2 and
rgp120CM235. Denaturation of gp120SF2 and
gp120CM235 was performed by reduction and
carboxymethylation as described elsewhere (37). Briefly, the
proteins were chemically denatured with 6 M guanidine, reduced in 10 mM
dithiothreitrol under N2, carboxymethylated with 50 mM
iodoacetamide, and dialyzed back into phosphate-buffered saline (PBS)
before use. Peptides from the third hypervariable (V3) region of gp120
(V3SF2 and V3CM242) were synthesized by GenoSys
(The Woodlands, Tex.) to >80% purity as assessed by amino acid
analysis, high-pressure liquid chromatography, and mass spectrometry.
The subtype E strain CM235 was selected based on its similarity with
consensus subtype E throughout gp120 with the exception of the V3 loop
region. The V3 peptide sequence for strain CM242 was used in the
construction of rgp120CM235 since the V3 loop corresponding
to CM242 was more representative of the Thai E V3 consensus sequence at
the time of isolation. The native CM235 and CM242 sequences differ in
two amino acids within the V3 loop (43).
Baboon immunizations.
Five baboons were immunized
intramuscularly (i.m.) at 0, 1, 2, and 6 months with 50 µg of
rgp120SF2 (Chiron Corporation, Emeryville, Calif.)
formulated in MF-59 adjuvant (Chiron). Additionally, 10 baboons were
immunized i.m. at 0, 1, and 6 months with 50 µg of rgp120CM235 (Chiron) formulated in MF-59 adjuvant. All
baboon immunizations were performed at the primate center at the
Southwest Foundation for Biomedical Research (San Antonio, Tex.). Sera
were collected 2 weeks after the 6-month rgp120SF2 or
rgp120CM235 immunization for analysis. Sera collected 2 weeks after the third rgp120SF2 immunization (month 2) were
also evaluated for neutralizing and binding antibody properties. No
significant differences in binding or neutralizing antibody were
detected in sera collected after the third or fourth immunization.
Therefore, all data reported are from sera collected after the 6-month
(fourth) rgp120SF2 immunization. Table
1 summarizes the vaccine formulation,
dose, schedule, and antibody titer for each baboon in the two groups.
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TABLE 1.
Immunization schedule, dose, and antibody endpoint
binding titers against homologous and cross-subtype
monomeric rgp120 and V3 peptides
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Measurement of serum antibody binding titers by EIA.
To
measure binding to the immunogen, an enzyme immunoassay (EIA) was used
as described previously (83). Briefly, rgp120SF2 (0.63 µg/ml), rgp120CM235 (0.63 µg/ml), or V3 peptide
V3SF2 (subtype B) or V3CM242 (subtype E) (1 µg/ml) in PBS (pH 7.4; with 0.01% thimerosal) was coated overnight
at 4°C onto Immulon 2 microtiter plates. Plates were washed twice
with wash buffer (PBS with 0.1% Tween 20 [pH 7.4]) prior to
incubation with twofold dilutions of baboon sera (diluted in wash
buffer with 5% skim milk [pH 7.4]) for 1 h at 37°C. Plates
were washed three times with wash buffer and incubated with horseradish
peroxidase-conjugated goat anti-human immunoglobulin G (diluted 1:4,000
in wash buffer with 5% skim milk, pH 7.4); Southern Biotechnologies,
Birmingham, Ala.). After a 1-h incubation at 37°C, plates were washed
three times, after which the substrate ABTS
[2,2'-azinobis(3-ethylbenzthiazolinesulfonic acid); Kirkegaard & Perry, Gaithersburg, Md.] was added. The reaction was stopped with
0.5% sodium dodecyl sulfate after 30 min at 37°C. Serum endpoint
titers were determined as the highest serum dilution with enzyme-linked
immunosorbent assay (ELISA) optical density (OD) signals greater than
twice the mean plus two times the standard deviations of the individual
preimmune baboon sera (typically >0.10 OD).
Native/denatured gp120 binding ratios determined by SPR.
To
determine the native/denatured gp120 binding ratio, surface plasmon
resonance (SPR) (BIAcore 2000; BIAcore Inc., Piscataway, N.J.) was used
as described previously (81-83). Immobilizations of
proteins (rgp120SF2, rgp120CM235, reduced,
carboxymethylated [rcm] gp120SF2, and
rcmgp120CM235) to the BIAcore biosensor dextran matrix were
performed with 100 mM N-hydroxysuccinimide and 400 mM
N-ethyl-N'-(3-diethylaminopropyl) carbodiimide
hydrochloride (EDC) chemical activation and coupling through free amine
groups on the proteins. Unreacted EDC-esters were deactivated by
reacting with an injection of 1 M ethanolamine. Immobilized rgp120
retains binding to CD4 and antibodies mapping to conformation
epitopes, demonstrating minimal loss in protein structure upon
covalent coupling to the biosensor matrix (82). Pre- and
postimmune baboon sera and HIV-1 sera (1:100) were diluted in HBS
running buffer (10 mM HEPES, 150 mM NaCl, 3.4 mM EDTA, 0.05% BIAcore
surfactant P20 [pH 7.4]), and 30-µl aliquots were injected through
the immobilized protein matrices at a flow rate of 5 µl/min. The net
difference in baseline signal (in response units [RU]) and signal
after completion of antibody injection was taken to represent the
binding value of a particular sample. Regeneration was performed with
two 5-µl pulses of 60 mM H3PO4 for both the
SF2 and CM235 rgp120 and rcmgp120 matrices. Binding of the individual
preimmune sera was subtracted from that of each of the postimmune sera
to yield the corrected serum binding value. Binding of preimmune sera
to each protein was <20 RU. Corrected serum binding values to both
rgp120 and rcmgp120 were then divided to yield the native/denatured
gp120 binding ratio.
Linear epitope mapping.
The entire sequences of both
immunizing proteins, rgp120SF2 and rgp120CM235,
excluding the signal sequences, were modeled with 12-mer peptides
overlapping by eight amino acids, 118 peptides each. Peptides were
synthesized on the heads of synthetic pins with cleavable
diketopiperazine linkages (Chiron Mimotopes, San Diego, Calif.) by
using 9-fluorenylmethoxycarbonyl chemistry and cleaved from the pins as
previously described (38). Peptides were covalently linked
to biotin at the N terminus by a short peptide linker (Ser-Gly-Ser-Gly)
and are denoted by the N-terminal amino acid. Peptides (typically
80% purity) were used without further purification as antigens in an
ELISA. Briefly, plates were coated with streptavidin (0.25 µg/well)
overnight and then peptides (0.1 µg/well) for 1 h. Pre- and
postimmune sera were diluted 1:1,000 in 5% nonfat dry milk in PBS and
incubated with peptides for 2 h at room temperature. After
washing, anti-human secondary antibody was added at 1:1,000 for 1 h. Appropriate substrate was added, and plates were read kinetically.
All assays were carried out in at least duplicate. Median serum
reactivity against 20 background peptides bound to streptavidin was
subtracted from all readings. Readings above 3 OD/min and absent in the
preimmune sera were considered significant.
Monomeric gp120 capture assay.
Culture supernatants of TCLA
viruses from subtype B (IIIB and SF2) and subtype E (NPO3, 9466, 9461, and 42368) were harvested from acutely infected H9 cells. Primary
HIV-1 (92/US/660, SF13, 92/US/717, and 9031) and subtype E (9466, CM235, CMU06, and 8868) isolates were isolated from PBMC of subjects
infected with subtype B and E viruses, respectively. At peak p24
antigen production, supernatants were harvested and lysed with Empigen
BB (1.0%) for 1 h at room temperature. Lysates were diluted in PBS
with 5% skim milk and 0.1% Tween 20 and captured by sheep antibodies
(D7324) to the C terminus of gp120 (49) adsorbed to wells of
Immulon 2 microtiter plates (2.5 µg/ml in sodium bicarbonate buffer
[pH 9.6] overnight). Test sera were diluted in PBS with 5% skim
milk, 0.1% Tween 20 and 5% normal goat serum, titrated down the plate (twofold), and detected with appropriate horseradish peroxidase-labeled secondary antibody as described above (83). HIV-1 serum
pools from 25 subtype B-infected and 25 subtype E-infected individuals were used as positive controls and to control for the amount of gp120
captured from each viral stock. Pooled normal human serum was used as a
negative control for the HIV-1 serum pools, and preimmune baboon
sera were used as negative controls for the baboon immune sera.
Endpoint titers were determined as described above. Binding ratios were
determined by dividing the endpoint titer of each subtype B or subtype
E baboon serum by the endpoint titer of the B or E HIV-1 serum
pool, respectively.
HIV-1 neutralization assay.
Neutralization assays, using
H9 target cells for TCLA viruses or stimulated PBMC targets for primary
isolates, were performed as previously described (39, 41).
Briefly, test sera and virus inoculum (100 50 tissue culture infective
doses) were preincubated for 30 min prior to addition of target cells.
After overnight incubation, cells were washed and resuspended in
appropriate culture media. Virus growth was monitored by ELISA
measurement of p24 antigen in culture supernatants, and neutralization
was determined during the early virus growth phase (days 4 to 6). Pre-
and postimmune baboon sera were directly compared in all assays at a
dilution of 1:10 in the presence of virus and a final dilution of 1:20 after the addition to target cells. Data represented as fold reduction were derived by the ratio of p24 antigen in preimmune sera to that in
postimmune sera. Thus, a 10-fold reduction in p24 antigen indicates
90% neutralization. Human sera from subjects infected with subtype E
and B HIV-1 were used as positive controls. All sera were
complement depleted by heat inactivation at 56°C for 40 min prior to
use. Subtype B TCLA viruses MN, IIIB, SF2, and RF were obtained from
the NIH AIDS Research and Reference Reagent Program. The subtype E TCLA
viruses were adapted to chronic growth in H9 cells and verified to be
neutralization sensitive to soluble CD4 and a subtype E-derived anti-V3
MAb (22). The corresponding primary subtype E isolate
HIV-9461 was a gift from Jay Levy (University of California, San
Francisco), and HIV-NP03 and 42368 were provided by researchers at the
Armed Forces Research Institute of the Medical Sciences in Bangkok,
Thailand. The primary isolate CM235 (homologous to the vaccine strain)
is a CCR5-using isolate that could not be adapted to growth in H9 cells.
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RESULTS |
Immunogenicity of SF2 and CM235 in baboons.
Five baboons (B54
to B58) were immunized i.m. at 0, 1, 2, and 6 months with 50 µg of
rgp120SF2, and 10 baboons (B62 to B71) were immunized i.m.
at 0, 1, and 6 months with rgp120CM235. Both SF2 and CM235
gp120 were formulated with MF-59 adjuvant, and sera collected after the
6-month immunization were studied for binding to homologous and
heterologous CHO monomeric gp120 and V3 peptides by ELISA
(Table 1). Sera from all baboons bound to both SF2 and CM235 rgp120 but
preferentially bound to gp120 from the strain homologous to the
immunizing protein. SF2-immunized baboon ELISA titers to
rgp120SF2 were up to eightfold higher than those to rgp120CM235. CM235-immunized baboon sera bound 2- to
16-fold more strongly to rgp120CM235 than to
rgp120SF2. All baboons seroconverted to their homologous
V3, but the binding was more type specific. In contrast to reactivity
against heterologous gp120, no cross-reactivity to the heterologous V3
peptide was observed, with the exception of weak binding to V3 of SF2
by sera B66 and B68. These data suggest antibody cross-recognition of
gp120 in regions outside of the V3 region.
Binding of baboon immune sera to rgp120
SF2 and
rgp120
CM235 was directly compared to binding of
subtype B and E HIV-1 serum
pools by SPR (Table
2). Direct comparisons were possible
since
SPR measurements, unlike those by ELISA, do not require secondary
antibodies for antibody detection and eliminate potential differential
binding efficiencies of conjugated secondary antibodies to human
and
baboon immunoglobulin. Pooled HIV-1 sera from individuals
infected
with subtype E (
n = 25) or subtype B (
n = 25) HIV-1 were
used for comparison. The US B HIV-1 serum
pool binding (692 RU)
was similar to the mean of the
rgp120
SF2-immunized baboon sera
(715 RU), with two of the
baboon sera (B55 and B57) showing higher
antibody reactivity.
The Thai E pool was >2-fold more reactive
than the mean of the
gp120
CM235-immunized baboons, with no single
baboon sera
reaching antibody reactivity levels comparable to
the pool. These data
demonstrate that while antibody levels elicited
by immunization by
rgp120
SF2 were comparable to those for subtype
B HIV-1
infection, antibody levels elicited by immunization with
rgp120
CM235 were weaker than the average titers induced
during
subtype E HIV-1 infection.
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TABLE 2.
Binding of sera from SF2 and CM235 gp120-immunized
baboons and of HIV-1 serum pools to rgp120 from clades B and E
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Binding to native and denatured gp120.
Sera from SF2 and CM235
gp120-immunized baboons were screened by SPR for reactivity against
native and denatured forms of HIV-1 gp120 (81-83).
Previous studies have shown that serum antibodies from human vaccinees
receiving IIIB strains of HIV-1 gp120 or gp160 preferentially bound
denatured gp120 independent of the CD4-binding competency of the
immunogen (81), in contrast to the predominant
antibody response to native gp120 elicited during natural HIV-1 infection (46, 81). Native/denatured
gp120 antibody binding ratios to rgp120SF2 and
rgp120CM235 for baboon sera and HIV-1 serum pools
are shown in Fig. 1. Individual sera from
25 subtype B and 25 subtype E HIV-1-infected individuals were
included as comparisons and bound preferentially to natively folded
gp120 (2- to 30-fold) from both strains SF2 and CM235. The
native/denatured binding ratios for both subtype B and E HIV-1 sera
to the cross-subtype gp120 were higher than to the homologous
subtype gp120. HIV-1 sera (subtype E) had mean ratios of 4.5 ± 1.8 against CM235 and 9.5 ± 3.9 against SF2, while HIV-1
sera (subtype B) had mean ratios of 3.4 ± 2.0 against SF2 and
14.2 ± 8.7 against CM235. This finding suggests a relative
enrichment of binding specific for conformational epitopes within
the cross-subtype-reactive antibody population. In contrast, sera
from SF2-immunized baboons preferentially bound denatured
gp120 from both the homologous SF2 gp120 (0.54 ± 0.06) and
CM235 gp120 (0.64 ± 0.09), with comparable ratios against the two
proteins. Sera from CM235-immunized baboons, however, preferentially bound natively folded gp120 from both SF2 and
CM235, and the ratio increased from 2.9 ± 1.5 against the
homologous CM235 to 6.6 ± 4.6 against the cross-subtype SF2
gp120, also suggesting that the cross-reactive epitopes are
predominantly directed toward conformational epitopes. These ratios
are within twofold of those obtained with the subtype E HIV-1 sera.
These data demonstrate qualitative differences in the
specificities elicited by these two immunogens with the CM235 capable
of eliciting a greater fraction of antibodies specific for gp120
conformational epitopes.
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FIG. 1.
Sera from baboons immunized with rgp120CM235
or rgp120SF2 were collected 2 weeks after the 6-month
immunization for evaluation. Sera from individuals infected with
subtype E (n = 25) or subtype B (n = 25) HIV-1 isolates were included as comparisons. The sera
evaluated are listed along the x axis. Sera were evaluated
for binding to native and denatured forms of rgp120SF2 (A)
and rgp120CM235 (B). Data are plotted for individual sera
as the ratio of native/denatured gp120 binding as determined by SPR.
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Peptide epitope mapping.
Sera from SF2- and
CM235-immunized baboons were screened against linear peptides (12-mers)
encompassing the entire gp120 sequence from SF2 and CM235 gp120.
Peptide-specific binding by the SF2 and CM235 baboon sera to the
homologous as well as the cross-subtype set of peptides is summarized
in Table 3. Sera from the
SF2-immunized baboons responded strongly to epitopes throughout
all conserved regions within gp120 (C1 to C5) as well as V2 to V5. The
CM235-immunized baboons also responded strongly to several
epitopes, but these were fewer in number and located within C1,
V2, C2, V3, and C5. Regions immunogenic on both the CM235 and SF2 gp120
included C1, V2, C2, V3, and C5. The most striking differences in
peptide specificities were within the C3, V4, and C4 regions. Sera from
the SF2-immunized baboons recognized multiple peptides within C3, V4,
and C4 (n = 14), while sera from the CM235-immunized
baboons were minimally reactivity in this region. Sera from
CM235-immunized baboons recognized multiple peptides within C2; in
particular, peptide 234 was very reactive with CM235 baboon sera but
not with the SF2 baboon sera. A summary of total homologous and
cross-subtype peptide reactivities is shown in Table 3 for the CM235-
and SF2-immunized baboons. The SF2-immunized baboons recognized a
total of 38 homologous peptides, while the CM235-immunized baboons
recognized a total of 17 homologous peptides. The total numbers of
cross-subtype peptides recognized by both the CM235 and SF2 gp120 sera
decreased to 8 and 14, respectively. The presence of several reactive
cross-subtype peptides was consistent with the cross-subtype gp120
reactivity observed by ELISA (Table 1). For both immunogens, most of
the cross-subtype peptide recognition was within C1, C5, and a peptide spanning the tip of the V3 loop (peptide 306). These data indicate that
sera from SF2-immunized baboons reacted with a larger number of gp120 peptides, and this increased linear epitope
recognition can be related to preferential serum recognition of
denatured gp120 (Fig. 1). In contrast, sera from CM235-immunized
baboons recognized fewer gp120 peptides and preferentially bound
conformational epitopes within gp120.
Binding of sera to heterologous and cross-subtype strains of
gp120.
The ability of sera from SF2- and CM235-immunized baboons
to bind to gp120 from divergent HIV-1 isolates was evaluated.
Monomeric gp120 was captured from the supernatant of detergent-treated
acutely infected cells of TCLA isolates from subtype B SF2 (Fig.
2A) and subtype E 9466 (Fig. 2B) as well as primary
isolates from subtype B SF13 (Fig. 2C) and subtype E CM235 (Fig. 2D),
using antibodies specific for the C terminus of gp120. The serum
binding from SF2- and CM235-immunized baboons to divergent intra- and
intersubtype gp120 was compared to that of subtype B and E HIV-1
serum pools. The levels of binding of the B and E HIV-1 serum pools
to the captured gp120 were controls for the amount of gp120 captured and the degree of cross-reactive antibodies within HIV-1 serum. Binding of sera from SF2-immunized baboons is comparable to, or better
than, that of the US B pool against the homologous TCLA SF2 (Fig. 2A),
but binding to primary HIV-1 (SF13) and to TCLA E (9466) and
primary E (CM235) is approximately 4- to 16-fold lower than that of the
US B pool. In contrast, CM235 baboon sera bound comparably to the Thai
E pool for all gp120s studied.
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FIG. 2.
Examples of a single subtype B-immunized baboon and a
subtype E-immunized baboon along with the pooled subtype B HIV-1 sera
and subtype E HIV-1 sera binding to gp120 from TCLA SF2, subtype B (A),
TCLA 9466, subtype E (B) primary SF13, subtype B (C), and primary
CM235, subtype E (D). Sera were run at eight twofold dilutions, and the
OD at each dilution is plotted. Preimmune baboon sera and normal human
sera negative controls were <0.10 OD at all dilutions.
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Baboon serum binding endpoint titers to homologous, heterologous,
and cross-subtype gp120 are summarized in Fig.
3. Serum
titers for the SF2-immunized
baboons binding to rgp120
SF2 are
comparable to the
serum titers for the CM235-immunized baboons
binding to
rgp120
CM235 (Fig.
3A). Reactivities against the subtype
B
gp120s are within two to threefold for the SF2 and CM235 baboon
sera
with the exception of SF2 gp120, where the SF2-immunized
baboons had
fivefold-stronger reactivity. The CM235 baboon sera,
however,
consistently bound 3- to 12-fold more strongly than the
SF2 baboon sera
to all subtype E gp120s. These data are plotted
as ratios in Fig.
3B,
normalized for the reactivity of the US
B and Thai E HIV-1 serum
pools. For each captured gp120, the SF2
and CM235 baboon serum endpoint
titers were divided by the endpoint
titers of the US B and Thai E serum
pools, respectively. The SF2-immunized
baboons had the highest ratio
against the SF2 gp120 (0.75), with
decreased ratios (0.02 to 0.32) for
the other gp120s. The CM235-immunized
baboons had a ratio of
approximately 0.4 against the homologous
CM235 gp120, with ratios
ranging between 0.17 and 0.72 for all
other gp120s. These data
demonstrate the presence of measurable
amounts of cross-reactive
antibodies in both the CM235 and SF2
baboon sera. However, the CM235
serum cross-recognition pattern
was comparable to the Thai E HIV-1
serum pool, while the SF2 baboon
serum recognition profile was more
restricted and type specific
for homologous SF2 gp120.
View larger version (37K):
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|
FIG. 3.
Binding to gp120 from divergent HIV-1 isolates by
sera from rgp120SF2- and rgp120CM235-immunized
baboons. Monomeric gp120 was captured from the supernatant of
detergent-treated acutely infected cells. TCLA isolates from subtypes B
(IIIB and SF2) and E (NPO3, 9466, 9461, and 42368) and primary isolates
from subtypes B (US/660, SF13, US/717, and 9013) and E (9466, CM235,
CMU06, and 8868) were evaluated. Data are presented as serum endpoint
titer (determined by EIA) against each gp120 (A) and ratio of baboon
serum binding to the HIV-1 serum pool from the same subtype (B).
The endpoint titers and binding ratios are means of the 5 rgp120SF2 and 10 rgp120CM235 immune sera. Mean
endpoint titers for individual preimmune baboon sera binding to each of
the gp120 were <1:100 in panel A.
|
|
HIV-1 neutralizing antibody.
To determine if the
differences in serum antibody specificities have an impact on
functional neutralizing antibody, sera from SF2- and CM235-immunized
baboons were evaluated for the ability to neutralize TCLA HIV-1
isolates from both subtype B (Fig. 4) and
E subtype (Fig. 4). Sera collected before and after the 6-month immunization with gp120 were evaluated, and neutralization was defined
as a 10-fold or greater reduction in p24 antigen by immune sera, using
the individual paired preimmune sera as the reference. Sera from all
five SF2-immunized baboons neutralized the homologous HIV-1SF2, with a mean fold reduction of 48.8. SF2
baboon sera neutralized heterologous TCLA HIV-1: MN, five of five
(mean, 91.1); IIIB, four of five (mean, 15.9); and RF, three of five
(mean, 14.4). In contrast, none of the SF2 baboon sera
neutralized subtype E TCLA NPO3, 9461, or 42368 (Fig. 4B). Sera
from CM235-immunized baboons neutralized subtype E TCLA viruses:
NPO3, 10 of 10 (mean, 113.0); 42368, 6 of 10 (mean, 37.6); and
9461, 2 of 10 (mean, 5.9). The subtype E-immunized baboons displayed
neutralizing activity versus subtype B TCLA isolates: SF2, 9 of 10 (mean, 24.4); MN, 8 of 10 (mean 59.6); IIIB, 7 of 10 (mean, 33.7); and
RF, 6 of 10 (mean, 178.5). The lack of cross-subtype neutralization by SF2-immunized baboons is probably not due to relative resistance of the
subtype E TCLA to serum neutralization, since the NPO3 and 42368 isolates appear susceptible to neutralization by subtype E sera.
Neutralization data are summarized in Table
4. Both rgp120SF2 and
rgp120CM235 immunization of baboons induced antibodies
capable of neutralizing TCLA HIV-1 within the same subtype.
However, only rgp120CM235 immunization resulted in
substantial intersubtype neutralization. These data represent the first
example of an immunogen inducing cross-subtype neutralizing antibody
responses. When sera were also evaluated for neutralization of the
primary HIV-1CM235, no significant neutralization was
observed (data not shown).
View larger version (15K):
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|
FIG. 4.
Sera from immunized baboons were tested for the ability
to neutralize subtype B (A) and subtype E (B) TCLA isolates. Subtype B
TCLA isolates included MN, IIIB, RF, and SF2; subtype E TCLA isolates
included NPO3, 9461, and 42368. Data are plotted as fold reduction in
p24 antigen for each HIV-1 isolate in the presence of pre- and
postimmune baboon sera. The horizontal bar indicates the geometric mean
of the rgp120SF2 or rgp120CM235 immune sera.
Sera were tested at a dilution of 1:10 in the presence of virus (1:20
in the presence of virus and cells).
|
|
View this table:
[in this window]
[in a new window]
|
TABLE 4.
Comparison of sera from SF2 and CM235 gp120-immunized
baboons to neutralize TCLA HIV-1 from clades B and E
|
|
| |
DISCUSSION |
Immunization of baboons with a monomeric rgp120 based
on a subtype E, R5 primary HIV-1 envelope induced antibodies
capable of neutralizing TCLA HIV-1 from homologous and heterologous
subtypes. This was in contrast to immunization obtained with an
rgp120 based on a subtype B, X4 TCLA isolate which induced
subtype-restricted TCLA HIV-1 neutralization. Cross-subtype
HIV-1 neutralization by rgp120CM235-specific immune
sera was associated with an antibody binding profile that included
preferential recognition of conformational epitopes within gp120
and strong cross-recognition of divergent strains of gp120. This
finding is consistent with a study demonstrating that HIV-1 serum
antibodies directed toward conformational epitopes within gp120
were responsible for heterologous TCLA HIV-1 neutralization (71). The data presented here may indicate that
strain-specific differences in antigenic structure can significantly
affect the immunogenicity of rgp120. However, since the current rgp120
immunogens differed with respect to both coreceptor usage and subtype,
the property responsible for these observed differences cannot be determined at this time. Despite the induction of antibodies specific for conserved, conformational epitopes and with neutralizing
activity against intra- and intersubtype TCLA HIV-1 by the
rgp120CM235 immunogen, no neutralization of the homologous
primary HIV-1CM235 was obtained. In comparison to sera
from subtype E HIV-1-infected individuals, antibody titers achieved
with rgp120CM235 immunization were lower. The impact of
higher antibody titer on primary HIV-1 isolate neutralization
capacity remains to be determined.
Serum antibodies from rgp120CM235-immunized baboons were
directed predominantly to conformational epitopes on the homologous rgp120CM235 as well as on the heterologous
rgp120SF2. This preferential recognition of conformational
gp120 epitopes is similar to profiles obtained in serum from
naturally HIV-1-infected individuals (46, 81). This was
in contrast to the responses to rgp120SF2 and to those
obtained in previous studies evaluating other HIV-1 subunit envelope vaccines based on TCLA HIV-1 isolates (81).
Lack of immune serum recognition of conformational epitopes in the
previous study correlated with poor binding to cell surface-expressed
HIV-1 envelope and poor neutralization of heterologous HIV-1
isolates (81). The ability of rgp120CM235 to
elicit a substantially higher relative amount of antibody capable
of recognizing conformational epitopes (5- to 10-fold) compared to
rgp120SF2 may be related to increased structural stability
of gp120 proteins from primary isolates compared to gp120 TCLA
isolates. It has been demonstrated that primary and TCLA
HIV-1 isolates have different antigenic properties with respect to
differential exposure of epitopes and susceptibility to
antibody-mediated neutralization (3, 6, 47, 55, 65, 72, 84, 85,
87). HIV-1 isolates adapted for growth in T-cell lines may
have adopted a structural configuration with enhanced exposure of
epitopes involved in CD4 or coreceptor interactions and resulting
in a gp120 molecule with greater structural flexibility
(83). Increased structural stability or rigidity of primary
gp120 envelope immunogens may allow increased immune recognition of
discontinuous epitopes such as the CD4 binding site. Preferential
recognition of conformational gp120 epitopes was also observed
previously with an oligomeric gp140IIIB immunogen, suggesting that gp140 oligomerization may more efficiently
present conformational gp120 epitopes, perhaps by enhancing
gp120 conformational stability. The HIV-1 envelope
glycoprotein gp160 is known to exist as a multimer (trimer or tetramer)
on the surface of a virion (16, 59, 66, 76). Immunization
with the soluble CD4-rgp120IIIB complex also was effective
at generating antibody responses to conformational epitopes in
mice, suggesting CD4-induced stabilization of gp120 conformational
structure (32). The data presented here suggest that
conformational determinants within R5 primary gp120 antigens may
be more efficiently presented for immune recognition in the absence of
gp120-gp41 oligomerization or binding to CD4 than the X4 TCLA SF2 rgp120.
Preferential binding to denatured gp120 by rgp120SF2 immune
sera was supported by linear epitope mapping studies. Immune sera from rgp120SF2-immunized baboons recognized twice as many
gp120 peptides as sera from the rgp120CM235-immunized
baboons. Regions immunogenic on both the CM235 and SF2 gp120
included C1, C2, V2, V3, V5, and C5. Sera from the SF2-immunized
baboons strongly recognized additional peptides within C3, V4, and C4,
while sera from the CM235-immunized baboons had minimal reactivity in
this region. Many epitopes within C3 and C4 are predicted not to be
exposed on native, monomeric gp120 and thereby inaccessible
to antibody binding (50). The strongest linear epitope
responses from the SF2 sera were directed to the V3 loop. This was also
evident by the ELISA data presented in Table 1. Lack of recognition of
the larger (30-amino-acid) cross-subtype V3 peptide by ELISA with recognition of the smaller (12-amino-acid) peptide (peptide 306) by
PEPscan suggests that the smaller peptide poorly mimics the tip of
the V3 loop in the context of the larger V3 peptide. The antibody
titers for V3SF2 were much higher relative to
rgp120SF2 than the corresponding relative
V3CM242 and rgp120CM235 titers for the
CM235-immunized baboons. This finding indicates increased accessibility
and immunogenicity of the V3 loop in the X4 rgp120SF2 compared to the R5 rgp120CM235. It is possible that
increased exposure and accessibility of the V3 region within the
rgp120SF2 protein block antibody recognition of some of the
immunogenic discontinuous epitopes. These data indicate many of the
antibodies induced by rgp120SF2 immunization are specific
for epitopes poorly accessible on the surface of native gp120,
consistent with studies demonstrating that many immunogenic
gp120 epitopes are poorly exposed on properly folded gp120
(50).
Cross-subtype neutralization by rgp120CM235 immune sera may
be attributable to antibody specific for conserved, conformational epitopes. Antibodies directed toward V3 have been shown to potently neutralize TCLA HIV-1, though neutralization of primary HIV-1 is less efficient (11, 45, 84). Cross-subtype neutralization of subtype B TCLA by rgp120CM235 sera occurred, however, in
the absence of detectable V3SF2- and low-level
V3CM242-specific antibodies, indicating non-V3-mediated
neutralization. SPR studies show that recognition of subtype B gp120 by
CM235 baboon sera occurred predominantly by antibodies binding to
conformational epitopes. In contrast, epitope mapping studies
revealed that the cross-subtype gp120 peptide-specific responses of
rgp120SF2 immune sera were directed to epitopes within
C1 and C5 (data not shown). These regions are well exposed on
monomeric forms of rgp120, but based on data from the
crystal structure of HIV-1 gp120 (36, 86), mutagenesis analysis (27, 34), and antibody binding studies (50,
51), the C1 and C5 regions are involved in the gp120-gp41
noncovalent interaction and are expected to be poorly exposed on the
membrane-expressed oligomeric gp120-gp41 complex. Recent data, however,
have demonstrated the ability of V3- and C5-specific MAbs to bind free
HIV-1 in a virus capture EIA (54). The lack of
cross-subtype neutralization by the rgp120SF2 immune sera
is thus attributable to the absence of subtype E V3 binding antibody
together with the lack of antibodies specific for conserved,
conformational epitopes. The absence of detectable neutralizing
activity against primary HIV-1 isolates in rgp120CM235
immune sera indicates insufficient antibody specific for neutralizing
epitopes on primary isolates. The majority of the antibody
specificities may be directed toward neutralizing epitopes unique
to TCLA HIV-1 and not to epitopes such as the CD4 binding site
(8, 28, 60, 73) or gp120 epitopes exposed after CD4
binding known to be involved in binding interactions with coreceptor
(62, 74).
The use of a gp120 immunogen based on an R5, primary HIV-1 isolate
significantly altered the epitope specificities and conformational dependence of immune serum antibody compared to X4 TCLA
gp120SF2. Structural features associated with the primary
isolate gp120 may play a significant role in the immunogenicity of
these proteins. Alteration of gp120 structure has previously been shown
to affect resulting antigenicity and immunogenicity. Removal of the V1
and V2 domains altered the accessibility of a TCLA HIV-1 to
neutralization by some MAbs (9). Removal of the V2
region from a primary HIV-1 isolate while not affecting in
vitro replication greatly enhanced its susceptibility to HIV-1
serum-mediated neutralization (68). Finally, infection of
rhesus macaques with a simian immunodeficiency virus isolate that had
glycosylation sites within V1 removed induced serum antibodies to novel
epitopes previously blocked by glycosylation and which potently
neutralize the virus (61). HIV-1 subunit proteins based
on R5 rather than X4 strains may also differentially expose or block particular epitopes. Further optimizations of HIV-1 subunit proteins based on strain, phenotype, or
oligomerization may be required to induce potent primary isolate
neutralization responses.
Thus, both genetic subtype or virus phenotype (primary versus TCLA) may
influence the immunogenicity of soluble HIV-1 envelope proteins,
indicating the importance of determining correlates linking protein
structural elements, antigenicity, and immunogenicity. In this study,
subtype E rgp120CM235 was as efficient as subtype B
rgp120SF2 at inducing subtype B TCLA neutralizing antibody. This finding suggests the possibility of substituting a single subtype
E rgp120 vaccine to induce neutralizing antibody against both subtype B
and E in an area where both strains predominate, such as Thailand.
| |
ACKNOWLEDGMENTS |
We thank Susan Hegerich, Ann King, and Mark Louder (Henry M. Jackson Foundation) and Yide Sun and Keith Higgins (Chiron Corporation) for technical assistance; Kathy Brasky (Southwest Foundation for Biomedical Research, San Antonio, Tex.) for the care and immunizations of primates; Kathy Steimer for initiating studies with Thai E gp120 at
Chiron; and the nursing staff, Charles Oster, and the Military Medical
Consortium for Applied Retroviral Research for sera from
HIV-1-infected volunteers and for care of these individuals.
This work was supported in part by cooperative agreement no.
DAMD17-93-V-3004 between the U.S. Army Medical Research and Materiel Command and the Henry M. Jackson Foundation for the Advancement of
Military Medicine.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Henry M. Jackson
Foundation, 13 Taft Ct., Suite 200, Rockville, MD 20850. Phone: (301) 762-0089. Fax: (301) 762-4177. E-mail address:
tvancott{at}hiv.hjf.org.
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
