Journal of Virology, December 1998, p. 9656-9667, Vol. 72, No. 12
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Neutralizing Antibodies from the Sera of Human Immunodeficiency
Virus Type 1-Infected Individuals Bind to Monomeric gp120 and
Oligomeric gp140
Nicholas M.
Stamatos,1,
John R.
Mascola,1,3
Vaniambadi S.
Kalyanaraman,4
Mark K.
Louder,2
Lynn M.
Frampton,2
Deborah L.
Birx,1 and
Thomas
C.
VanCott2,*
Division of Retrovirology, Walter Reed Army
Institute of Research,1 and
Henry M. Jackson Foundation,2 Rockville, Maryland
20850;
Department of Infectious Diseases, Naval Medical
Research Institute, Bethesda, Maryland
208893; and
Advanced BioScience
Laboratories, Kensington, Maryland 208954
Received 1 July 1998/Accepted 9 September 1998
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ABSTRACT |
Antibodies that neutralize primary isolates of human
immunodeficiency virus type 1 (HIV-1) appear during HIV-1 infection but are difficult to elicit by immunization with current vaccine products comprised of monomeric forms of HIV-1 envelope glycoprotein gp120. The
limited neutralizing antibody response generated by gp120 vaccine
products could be due to the absence or inaccessibility of the relevant
epitopes. To determine whether neutralizing antibodies from
HIV-1-infected patients bind to epitopes accessible on monomeric gp120
and/or oligomeric gp140 (ogp140), purified total immunoglobulin from
the sera of two HIV-1-infected patients as well as pooled HIV immune
globulin were selectively depleted of antibodies which bound to
immobilized gp120 or ogp140. After passage of each immunoglobulin preparation through the respective columns, antibody titers against gp120 and ogp140 were specifically reduced at least 128-fold. The
gp120- and gp140-depleted antibody fraction from each serum displayed
reduced neutralization activity against three primary and two T-cell
line-adapted (TCLA) HIV-1 isolates. Significant residual neutralizing
activity, however, persisted in the depleted sera, indicating
additional neutralizing antibody specificities. gp120- and
ogp140-specific antibodies eluted from each column neutralized both
primary and TCLA viruses. These data demonstrate the presence and
accessibility of epitopes on both monomeric gp120 and ogp140 that are
specific for antibodies that are capable of neutralizing primary
isolates of HIV-1. Thus, the difficulties associated with eliciting
neutralizing antibodies by using current monomeric gp120 subunit
vaccines may be related less to improper protein structure and more to
ineffective immunogen formulation and/or presentation.
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INTRODUCTION |
Neutralizing antibodies (NAbs) are
an important component of protective immunity against numerous viruses
(7, 12, 23, 27-29, 64, 68), and most effective vaccines
elicit pathogen-specific NAbs (reviewed in references
11 and 56). Since protection of
humans against human immunodeficiency virus type 1 (HIV-1) infection
has not been achieved, the role of NAbs in protective immunity against
HIV-1 is not known. However, based on the experience with other
viruses, it is reasonable to assume that NAbs play a role in protection
against infection by HIV-1. Abs capable of neutralizing HIV-1 in vitro
develop naturally, over several years, in HIV-infected patients
(10, 31, 41, 44, 57, 60, 77, 78). However, immunization with
monomeric forms of the HIV-1 envelope glycoprotein gp120 results in
production of Abs which neutralize T-cell line-adapted
(TCLA) viruses (4, 62, 65) but have only marginal
activity against primary isolates of HIV-1 (41, 42, 66, 79).
Possible explanations for this weak neutralizing activity against
primary viral isolates, in contrast to the potent NAbs that can develop
during natural infection, include the inaccessibility or absence of
relevant epitopes on the immunogen. Monoclonal Abs (MAbs) which
potently neutralize primary isolates can bind to gp120, but
it has been suggested that the neutralizing capacity of these
Abs correlates more closely with the efficiency of binding to epitopes
exposed on the oligomeric form of gp120 (22, 45, 49, 59), as
the oligomeric protein may more closely resemble the native structure
of HIV-1 gp120/gp41 (21, 51, 61, 70). In support of these
studies, recent work in our laboratory has shown that immunization of
rabbits with oligomeric gp140 (ogp140) can elicit moderate levels of
NAbs against some primary isolates (74).
Several experimental approaches have been used to identify the epitope
specificity of NAbs from the sera of HIV-infected patients (3, 6,
37, 43, 53, 67, 75). In antibody depletion studies, Abs which
bound to both linear and conformation-dependent epitopes of gp120 or to
the V3 loop peptide of gp120 were found to have a role in the
neutralization of TCLA viruses (3, 37, 43, 53, 67, 75). Work
from our laboratory extended these results to show that V3-specific Abs
had a marginal role in neutralizing primary viral isolates
(75). In this study, we depleted sera of Abs which bind to
monomeric gp120 or to ogp140 and evaluated their role in the
neutralization of three primary isolates and two TCLA strains of HIV-1.
We show that HIV-1 serum Abs directed to either monomeric gp120 or
ogp140 can neutralize primary isolates of HIV-1. These data suggest
that the epitopes important in mediating HIV-1 serum neutralization of
primary isolates are present on subunit HIV-1 envelope (Env)
glycoproteins and that further optimization of the presentation of
these epitopes on vaccine products could improve their immunogenicity.
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MATERIALS AND METHODS |
Cells and viruses.
Peripheral blood mononuclear cells
(PBMCs) were isolated by leukophoresis of blood from HIV-1- and
hepatitis B virus-seronegative donors and then subjected to
centrifugation over lymphocyte separation medium. PBMCs were stored
in liquid nitrogen at 3 × 107 cells/ml in RPMI 1640 medium (Quality Biological Inc., Gaithersburg, Md.) containing 20%
heat-inactivated fetal calf serum (FCS; PAA Laboratories Inc., Newport
Beach, Calif.) and 10% dimethyl sulfoxide. For treatment with
phytohemagglutinin (PHA; Difco Laboratories, Detroit, Mich.), cells
were thawed and cultured for 24 h at 106 cells/ml in
RPMI 1640 medium containing 15% FCS and 20 U of recombinant human
interleukin-2 (IL-2; Boehringer, Mannheim, Germany) per ml (complete
medium) in the presence of PHA at 1 µg/ml. Cells were washed free of
the PHA-containing medium after 24 h and were incubated for an
additional 48 to 72 h in complete medium. TCLA HIV-1IIIB and HIV-1MN and the primary isolate
HIV-1US056 were obtained from the AIDS Research and
Reference Reagent Program, National Institute of Allergy and Infectious
Diseases, National Institutes of Health. HIV-1US1 and
HIV-1CM237 are primary clade B isolates obtained from
infected subjects from the National Naval Medical Center, Bethesda,
Md., and Chiang Mai, Thailand, respectively. Virus titers were
determined in PHA/IL-2-stimulated PBMCs.
Ab and protein reagents.
Sera from patients US20 and US22,
selected based on their broad and strong neutralization of primary
HIV-1 isolates, were obtained with informed consent from clade B
HIV-infected subjects. All HIV-1 sera and normal human sera (NHS; Sigma
Chemical Co., St. Louis, Mo.) were heat inactivated at 56°C for 30 min prior to use. The purified polyclonal immunoglobulin (purified Ig)
fraction was purified from sera US20 and US22 by using an EZ-SEP kit
(Pharmacia Biotech, Piscataway, N.J.) prior to affinity column
depletion and purification. To ensure that equivalent amounts of
purified Ig and serum were used in subsequent binding and virus
neutralization assays, the volume of purified Ig was adjusted to return
the titers of Abs to gp120, ogp140, and p24 to the levels of
unfractionated HIV-1 sera. Samples were concentrated in Centricon 30 spin concentrators (Amicon, Danvers, Mass.) with multiple spins at
5,000 × g for 25 min. HIV-1 immune globulin (HIVIG; 50 mg/ml) is a preparation of purified polyclonal Ig derived from the
plasma of multiple HIV-infected donors and was kindly provided by Chris
Saban (NABI, Boca Raton, Fla.). The donors contributing to HIVIG were
clinically asymptomatic and had CD4 lymphocyte counts greater than or
equal to 400 cells/ml, high anti-p24 antibody titers, and undetectable p24 antigen (16). MAb T4 was kindly provided by Pat Earl
(National Institutes of Health) (20). Monomeric
gp120451 and ogp140451 were affinity purified
from the culture medium of a cell line (6D5) chronically infected with
HIV-1451 as described previously (35, 36, 76).
The ogp140451 preparation is comprised mostly of
trimers/tetramers and dimers, with some monomers (76), and is a truncated version of full-length gp160, with the truncation occurring just prior to the transmembrane domain. Recombinant p24 was
obtained from MicroGeneSys Inc. (Meriden, Conn.); V3MN peptide (YNKRKRIHIGPGRAFYTTKNIIGC), corresponding to the V3
region of gp120, and gp41 peptide gp41582
(QARILAVERYLKDQQLLGIWGCSGKLIC), corresponding to the
immunodominant domain of gp41 and contained within
ogp140451, were synthesized by Synthecell (Gaithersburg, Md.). Reduced, carboxymethylated gp120MN was generously
provided by Genentech Inc. (South San Francisco, Calif.).
Column depletion.
gp120451 and
ogp140451 were coupled to separate CNBr-activated Sepharose
4B beads as described by the manufacturer (Pharmacia Biotech). Prior to
incubation with purified Ig derived from sera of HIV-1-infected
patients or with NHS, 0.4 ml of packed gp120 or ogp140-coupled
Sepharose 4B beads was treated in a 2-ml polystyrene column (Pierce,
Rockford, Ill.) with 0.4 ml of NHS to reduce nonspecific binding of
Abs. The beads were then washed with 0.8 ml of phosphate-buffered saline (PBS) and incubated with 0.2 ml of purified Ig and 0.4 ml of PBS
in a 1.5-ml tube for 4 h at room temperature on a rotating wheel.
The mixture was transferred to a polystyrene column, and the eluate
(depleted fraction) was collected. The beads in the column were washed
twice with 0.4 ml of PBS, and each wash was added to the main eluate.
The combined eluate was then reincubated with a fresh 0.4 ml of packed,
coupled Sepharose beads for an additional 4 h at room temperature
on a rotating wheel. This material was transferred to a new column, and
the eluate was collected. These beads were washed three times with 0.4 ml of PBS, and the washes were added to the main eluate. The eluate
combined with the three washes was considered the final depleted
fraction. gp120- or ogp140-depleted fractions were concentrated in
Centricon spin concentrators to a volume at which the enzyme-linked
immunosorbent assay (ELISA) titer of anti-p24 Abs was equal to that of
the undepleted Ig. In the case of depleted NHS, the sample was
concentrated to the original total IgG concentration.
The gp120- or ogp140-coupled Sepharose beads with bound serum Abs were
washed five times with 1 ml of PBS, followed by two washes with 1 ml of
500 mM NaCl to remove weakly or nonspecifically associated Abs. For
US20 and US22, Ab was eluted with 2.5 ml of 100 mM
Na2CO3, pH 11. For HIVIG, Ab was eluted with
100 mM Na2CO3 as described above, followed by
addition of 1.8 ml of 100 mM H3PO4, pH 2. The
efficiency of Ab recovery was improved twofold by this sequence of
high- and low-pH elution. The high- and low-pH solutions containing
eluted Abs were neutralized with 1 N HCl and 1 M NaPO4, respectively. All data for affinity-purified Abs from HIVIG refer to
Abs combined from the high- and low-pH elutions, except for the HIVIG
data shown in Table 2, which are for
Na2CO3-eluted Abs alone. Columns were prepared
for reuse by serial washes with 100 mM Na2CO3
and 100 mM H3PO4 followed by extensive washing
with PBS. Eluted Abs were concentrated to the original volume in
Centricon 30 spin concentrators as described above. Where indicated,
V3MN peptide was immobilized to Sepharose, and Ab depletion
and affinity purification were done as described above and previously
(76).
Ab binding levels in depleted and affinity-purified Ig
samples.
Unfractionated serum, purified Ig, and column-depleted
and affinity-purified Ab fractions were assayed for amount of Ab
reactive to specific HIV-1 peptides and to subunit HIV-1 Env
glycoproteins, or for the amount of total Ig, by ELISA as described
previously (1, 72, 74). Briefly, gp120451,
ogp140451, p24, or synthetic peptides V3MN and
gp41582 (1 µg/ml) in PBS (pH 7.4, with 0.01% thimerosal)
were coated overnight at 4°C onto Immulon 2 microtiter plates
(Dynatech, Chantilly, Va.). Plates were washed twice with wash buffer
(PBS with 0.1% Tween 20, pH 7.4) prior to incubation with twofold
dilutions of Ab-containing samples diluted in serum diluent (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 IgG (diluted 1:8,000 in serum
diluent) (Kirkegaard & Perry, Gaithersburg, Md.). After a 1-h
incubation at 37°C, plates were washed three times, after which
substrate [2,2'-azinobis(3-ethylbenzthiazolinesulfonic acid) (ABTS);
Kirkegaard & Perry] was added. The reaction was stopped with 0.5%
sodium dodecyl sulfate after 30 min at 37°C. Alternatively, total
serum IgG concentrations were determined by coating plates with
unlabeled anti-human IgG and detecting captured human IgG by using
horseradish peroxidase-conjugated goat anti-human IgG as described
elsewhere (1). Concentrations were determined by using a
human IgG standard (Sigma). Relative levels of Ab specific for
native and denatured forms of HIV-1 gp120 were determined by surface
plasmon resonance (SPR) as described previously (72-74).
Virus neutralization assays.
Virus neutralization assays
were performed with PHA/IL-2-stimulated PBMCs by methods similar to
those previously described (40, 41). Isolates of HIV-1 (100 50% tissue culture infective doses) were preincubated, in
quadruplicate wells, with 5 to 8 serial 2- to 10-fold dilutions of
HIV-1 sera, purified Ig, column-depleted Ab, or affinity-purified Ab in
0.05-ml 96-well culture plates (PGC, Frederick, Md.) for 45 min at
37°C. Controls included virus preincubated with NHS and PBS.
Dilutions were made in RPMI 1640 containing 15% FCS. HIV-1 sera,
purified Ig, and gp120- or ogp140-depleted Ab, previously normalized by
ELISA reactivity to p24 antigen as described above, were prepared at
the same initial sample dilutions. The initial dilutions of eluted
gp120451- and ogp140451-specific purified Abs
were adjusted so that the ELISA reactivity of each sample to gp120 or
ogp140 was equivalent to that of the undepleted purified Ig. Then
1.5 × 105 PHA-activated PBMCs in 0.05 ml were added
to the Ab-virus mixture. After incubation for 18 to 24 h at
37°C, the infected cells were washed five times with 0.45 ml of RPMI
1640 containing 15% FCS to remove unabsorbed virus and residual
antibody to p24 (39). Cells were resuspended in 0.25 ml of
complete medium, and 0.22 ml was distributed into wells of a 96-well
tissue culture plate (Costar, Cambridge, Mass.). Culture supernatants
from infected cells were tested on day 4, 5, or 6, depending on virus
growth kinetics (40), and viral growth was determined by
measuring p24 antigen in the culture medium by ELISA (Coulter, Miami,
Fla.). Virus neutralization was determined by measurement of the
fraction of remaining infectious virus after exposure to Ab. This value was obtained by dividing the amount of p24 antigen produced at each
dilution of HIV-1 Abs by the amount produced in the absence of
HIV-specific Abs. Fifty percent, 90%, and 99% neutralization titers
were determined by linear regression analysis.
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RESULTS |
Efficient depletion of monomeric gp120- and ogp140-binding Abs from
purified Ig of HIV-infected patients.
To determine the relative
importance of Abs specific for monomeric gp120 and ogp140 in
neutralization of primary and TCLA isolates of HIV-1, purified Ig from
three sources (US20, US22, and HIVIG) was selectively depleted of Abs
which bound to gp120451 or ogp140451. To test
the efficiency of the affinity column depletion and purification
procedures, the titers of Abs in the depleted and affinity-purified
fractions reactive with ogp140451, gp120451, p24, and two peptides, V3MN and gp41582, were
determined by ELISA. Screening against p24 antigen was included as a
control to test and correct for nonspecific loss of Ig during the
depletion procedure, thus permitting direct comparison of Ab titers in
the various fractions against ogp140451,
gp120451, V3MN, and gp41582.
Peptide gp41582, present only on ogp140451, was
included as an additional control for the specificity of the
gp120451 column. One of the samples, HIVIG, was also
depleted of V3MN-binding Abs by using a
V3MN-Sepharose column to confirm results of a previous
study (75) and to compare directly the roles of V3- versus
gp120- and ogp140-specific Abs in the neutralization of primary and
TCLA HIV-1 isolates.
ELISA titers of column-depleted and affinity-purified fractions against
various antigens are shown in Table 1 for
US20 and HIVIG. The data for US22 were similar and are not shown. As
mentioned previously, the volumes of the gp120- and ogp140-depleted
samples were adjusted such that the Ab responses against the control
antigen p24 were equivalent to those of the purified Ig samples, as
shown in Table 1. This required an approximately twofold concentration, indicating some nonspecific loss of antibody during the depletion procedure. While the p24-binding Ab titers for purified Ig and depleted samples were comparable, the gp120451-
and/or ogp140451-binding Ab titers were substantially
lower, indicating a selective depletion of HIV-1 envelope-specific Abs.
The gp120451-binding Ab titer of each purified Ig
preparation was reduced at least 128-fold (greater than 99% reduction)
after passage through the Sepharose-gp120451 column
(gp120-depleted fractions [Table 1]). Similarly, the
ogp140451 binding Ab titer of each purified Ig preparation
after passage through the Sepharose-ogp140451 column was
reduced at least 256-fold (ogp140451-depleted fractions
[Table 1]). Abs reactive with gp120451 were efficiently
removed after passage through either the gp120451 or
ogp140451 columns, while the majority of Abs reactive with ogp140451 were efficiently removed by immobilized
ogp140451 but not by gp120451, indicating the
presence of a substantial proportion of ogp140451-specific
Abs reactive with epitopes either within gp41 or within gp120 but
unique to its oligomeric configuration.
To characterize more precisely the accessibility of specific epitopes
on the column-immobilized gp120 and ogp140 used in these experiments,
the extent of depletion of V3MN- and
gp41582-specific Abs on each column was determined. The
gp120451-depleted fraction retained the full reactivity by
ELISA against the gp41 peptide (gp41582), while reactivity
was diminished in the gp140-depleted fraction. Interestingly, while
reactivity to gp41582 was reduced >16-fold in US20, only
an 8-fold reduction was obtained for HIVIG despite the 8,192-fold
reduction in reactivity against the entire ogp140451
protein. There was also only a modest four- to eightfold reduction in
Ab titer to V3MN in both the gp120- and gp140-depleted material from each purified Ig preparation, in contrast to the more
than 256-fold reduction in V3-specific Abs after HIVIG was passed
through the Sepharose V3MN column. Thus, depletion of Abs to the whole gp120451 or ogp140451 proteins by
using the gp120 or ogp140 affinity columns was more efficient than
depletion of Abs against specific immunodominant epitopes. However,
while some Abs specific for immunodominant linear epitopes were less
efficiently depleted, total gp120- and ogp140-specific Abs were reduced
>99%.
Affinity-purified gp120- and ogp140-specific Abs retain binding
capacity.
Abs which had bound column-immobilized
gp120451 or ogp140451 were eluted and evaluated
for efficiency of recovery and specificity of reactivity by ELISA
against the panel of proteins and peptides used in the assays described
above for the depleted fractions. As shown in Table 1, there was
minimal nonspecific binding of Abs to each column, as demonstrated by
the small amount of affinity-purified Abs reactive with p24
(representing <0.5% of the initial p24 reactivity). Elution of Abs
from either column and concentration of each fraction to its original
volume resulted in recovery of approximately 25% of the initial gp120-
or ogp140-specific binding activity (compare data for gp120 and ogp140
Abs with data for purified Ig). Similar percentages of
gp120451 reactivity were recovered from both the gp120451 and ogp140451 columns for all three
purified Ig preparations (data shown for only US20 and HIVIG in Table
1). In contrast, Abs recovered from the ogp140 column displayed greater
reactivity to ogp140 than did Abs recovered from the gp120 column,
probably because of the presence of Abs to gp41 in the ogp140-purified Abs. These data demonstrate that gp120- and ogp140-specific Abs were
selectively enriched by binding to the affinity columns and that the
eluted affinity-purified Abs retained binding capacity.
Affinity-purified gp120- and ogp140-specific Abs bind
preferentially to native gp120.
To confirm that Sepharose-bound
gp120451 and ogp140451 were capable of binding
Abs specific for conformational epitopes within gp120, the
gp120451- and ogp140451-depleted and
affinity-purified Abs from HIVIG were analyzed by SPR for binding to
conformationally intact gp120 and denatured (reduced,
carboxymethylated) gp120. HIVIG bound preferentially to native gp120,
with a native/denatured gp120 binding ratio of 7.2 (Table
2), consistent with previous results for
sera from HIV-1 infected individuals (46, 72). Both
gp120451- and ogp140451-depleted fractions were
preferentially depleted of Abs to native gp120. In both cases, there
was a reduction in the native/denatured gp120 binding ratio from 7.2 (found in the unfractionated HIVIG) to 1.5 in the depleted samples.
This was calculated by dividing antibody binding (in RU) to native, monomeric gp120 (3,542 RU) by binding to denatured gp120 (492 RU). In
contrast, Abs to linear epitopes were selectively removed when HIVIG
was depleted by using the V3MN-coupled Sepharose beads. The
native/denatured gp120 binding ratio rose to 48.3, consistent with the
relative accessibility of the V3 region on native and denatured gp120.
These data also indicate that the majority of denatured gp120-specific
Abs within HIVIG are specific for V3. The affinity-purified
gp120451 and ogp140451 Abs had reactivities to
native and denatured gp120 similar to those of unfractionated HIVIG,
with ratios of 6.2 and 7.1, respectively. These results demonstrate
that both immobilized gp120451 and ogp140451
were able to bind Abs to conformational epitopes, suggesting that the tertiary structure of gp120 was retained in the column matrix. In
addition, the presence of oligomeric gp140-specific epitopes within the
immobilized gp140 column, but not the gp120 column, was demonstrated by
using an oligomer-specific MAb (T4 [20]) that bound
only to the former (data not shown). In summary, both gp120451 and ogp140451 columns depleted HIV-1
sera preferentially of Abs specific for conformational gp120 epitopes,
and affinity-purified Abs from both columns preferentially bound native
gp120.
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TABLE 2.
gp120 and ogp140 columns selectively deplete and affinity
purify Abs to conformational epitopes of gp120
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Purified Ig from HIV-1 sera retains neutralizing activity against
primary and TCLA HIV-1.
To confirm that the viral inhibitory
activities of the sera from HIV-infected patients US20 and US22 were Ig
mediated and not due to other factors such as chemokines
(13), the viral neutralization titers of purified Ig from
these two sera against three primary isolates and two TCLA viruses were
compared to the viral neutralization titers of the respective sera.
Samples from the third source of purified Ig, HIVIG, were assayed
similarly, but the original serum pool was not available for
comparison. Of the three purified Ig preparations, US20 had the lowest
titer of Abs to gp120451 and ogp140451, as
measured by ELISA, yet demonstrated the strongest neutralization of the
three HIV-1 primary isolates US1, CM237, and 056 (Table
3). The serum and purified Ig of US20 had
approximately equal neutralization titers (ID50 and
ID90) against these viruses. US22 serum and purified Ig
also had similar ID50 values against the primary isolates,
although the ID90 of the purified Ig was two- to threefold
less than that of the serum (Table 3). HIVIG had a high neutralization
titer against HIV-1CM237 but relatively low neutralization
titers against HIV-1US1 and HIV-1056. All three
purified Ig preparations had comparably strong neutralization activity
against TCLA HIV-1MN. Their neutralization titers against
HIV-1IIIB were lower and more comparable to those observed
against the primary isolates. These data demonstrate that the purified
Ig from US20 and US22 sera retained most of the ability of the sera to
neutralize primary and TCLA HIV-1. Neutralizing activity for these sera
did not correlate with the total amount of Abs to monomeric
gp120451 or ogp140451. This finding is
consistent with other studies showing no correlation between HIV-1
Env-specific MAb binding titers to gp120 and neutralization (22,
45, 50, 59).
Depletion of gp120- and ogp140-specific Abs from HIV-1 sera
diminishes neutralizing activity against TCLA and primary HIV-1.
To determine the importance of gp120- and ogp140-specific Abs from
individual sera in the neutralization of HIV-1, gp120451- and ogp140451-depleted fractions and affinity-purified Abs
from US20 and US22 were evaluated for neutralizing capacity against TCLA and primary HIV-1 isolates. After standardization of the depleted
fractions to the purified Ig by the amount of Abs to p24, the gp120-
and ogp140-depleted fractions from US20 and US22 had reduced
neutralizing activity against all viruses evaluated (Fig.
1A; Table
4). The level of reduction in
neutralization was similar for the gp120451- and
ogp140451-depleted fractions. The increase in virus growth
in the presence of the gp120- and gp140-depleted fractions was most
striking against HIV-1IIIB, with a 2- to
3-log10 difference between the depleted and unfractionated material (Fig. 1A). In the presence of lower dilutions of depleted US20
fractions, a greater than 100-fold increase in virus growth of
HIV-1US1, HIV-1CM237, and HIV-1056
primary isolates was obtained (Fig. 1A). The corresponding
ID90 and ID99 (neutralizing titers) of the
depleted US20 material against the primary isolates of HIV-1 were
reduced 2- to 10-fold (Table 4). The more weakly neutralizing US22
serum had a 2- to 10-fold reduction in ID50 against these viruses (Table 4). Despite the reduction of neutralizing capacity against primary and TCLA HIV-1 isolates in both the gp120- and gp140-depleted US20 fractions, the remaining Abs in these depleted fractions retained a substantial (i.e., greater than 90%
neutralization at the higher Ig concentration) level of neutralizing
activity (Fig. 1A; Table 4).
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FIG. 1.
Preparation of purified Ig and depleted samples, design
of viral neutralization assays, and evaluation of p24 antigen were as
described in Materials and Methods. (A) Results for gp120- and
ogp140-depleted material from US20; (B) results for HIVIG. Each point
represents the average from triplicate wells from one experiment of
four that gave similar results. Depleted fractions were standardized to
the purified Ig and serum by equating reactivity to p24 such that
equivalent amounts of each were added. Diluted samples were evaluated
by ELISA for titers of Abs to p24 after the neutralization assay to
confirm that equivalent amounts were added. The amount of viral growth
in comparable dilutions of NHS was used as the standard for 100% virus
growth. Purified Ig and depleted fractions were assessed for
neutralizing capacity against primary (US1, CM237, and 056) and TCLA
(MN and IIIB) HIV-1 isolates. gp120-depleted and ogp140-depleted
fractions correspond to HIV-1 serum US20 or HIVIG depleted over the
gp120 or ogp140 affinity columns, respectively.
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Previous data showed that V3-specific Abs were important in mediating
neutralization of TCLA (37, 53, 75) but not primary (75) HIV-1 isolates. To confirm these previous studies using HIVIG and to provide a basis for comparison with gp120- and
ogp140-depleted samples, HIVIG was passed through a
V3MN-coupled Sepharose column, resulting in a >256-fold
reduction in V3MN-specific Abs (Table 1). In agreement with
previous findings, neutralization of TCLA HIV-1MN by
V3MN-depleted HIVIG was substantially reduced (
20-fold against MN), with minimal corresponding reduction in neutralizing capacity against the primary isolates US1, CM237, and 056 (Table 4;
Fig. 1B). In contrast, both gp120- and ogp140-depleted HIVIG had
reduced primary isolate neutralization capacity. For example, while
V3MN-specific depletion failed to achieve a twofold
reduction in ID50 and ID90 against primary
HIV-1 isolates, gp120- and ogp140-specific depletion reduced the
ID50 and ID90 approximately fourfold or more.
The reduction in neutralizing titer of gp120- and ogp140-depleted HIVIG
against TCLA isolate IIIB was comparable to the reduction against the
primary HIV-1 isolates (Table 4), while a greater reduction in MN
neutralizing titer was obtained. As obtained previously with US20,
despite the reduction in primary isolate neutralizing capacity, in the
case of CM237, significant neutralizing Abs remained in the gp120- and
ogp140-depleted HIVIG.
To confirm that the procedures for purified Ig purification and Ab
depletion, elution, and concentration did not introduce factors which
nonspecifically inhibited viral growth, each experiment included
negative controls in which the purified Ig from NHS was processed on
the gp120 and ogp140 columns identically to the HIV-1 samples. Neither
the purified Ig, the mock-depleted gp120 and ogp140 fractions, nor the
mock-purified Abs from NHS had detectable neutralization against the
viruses used in the study (data not shown). As an additional control,
all HIVIG samples evaluated above were subjected to an identical
experiment substituting a clade E HIV-1 isolate (9461 [74]), against which the clade B HIVIG had marginal
neutralizing activity. None of these samples inhibited or enhanced
viral growth of the clade E isolate.
gp120 and ogp140 affinity-purified antibodies neutralize both TCLA
and primary HIV-1 isolates.
US20, US22, and HIVIG
affinity-purified Abs from the gp120 and ogp140 columns were tested for
neutralizing activity against both TCLA and primary HIV-1 isolates.
Prior to evaluation for neutralization activity, the concentrations of
gp120- and ogp140-affinity purified Abs in the Ab fractions were
adjusted so that the ELISA titer against gp120 or ogp140 was equivalent
to that of unfractionated purified Ig. Abs recovered from both gp120
and ogp140 columns from US20 had substantial neutralization activity
against the two TCLA and three primary isolates of HIV-1 (Fig.
2A; Table 4). This
activity was quantitatively similar to that of the unfractionated purified Ig. Furthermore, to compare the potencies of the gp120 and
ogp140 Abs, the concentration of IgG in the initial dilution of each
sample from US20 was determined and found to be as follows: serum,
645.5 µg/ml; purified Ig, 648.7 µg/ml; gp120 Abs, 10.1 µg/ml; and
ogp140 Abs, 29.7 µg/ml. Based on IgG concentration, the 99%
inhibitory concentrations against HIV-1US1 of gp120- and ogp140-specific Abs were similar at 4 and 5 µg/ml, respectively (data
not shown), suggesting similar neutralizing potencies of the gp120 and
ogp140 affinity-purified Abs. gp120- and ogp140-specific Abs from US22
and HIVIG also neutralized both TCLA and primary HIV-1 isolates, but to
a more limited degree than US20 (data shown for HIVIG in Fig. 2B and
Table 4). Thus, both gp120- and ogp140-specific, affinity-purified Abs
from HIV-infected patients had potent neutralizing activity (90 to
99.9% at the lowest dilutions studied) against primary isolates and
TCLA HIV-1.
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|
FIG. 2.
Affinity-purified antibodies from the
gp120451 and ogp140451 affinity columns for
US20 (A) and from HIVIG (B) were compared with the respective
unfractionated Ig for neutralization activity against primary (US1,
CM237, and 056) and TCLA (MN and IIIB) HIV-1 isolates. Abs affinity
purified from the monomeric gp120 column (gp120 Abs) or ogp140 column
(ogp140 Abs) were standardized to the unfractionated serum and/or
purified Ig by adding equivalent amounts of reactivity to gp120 or
ogp140, respectively. Dilutions were evaluated by ELISA for titers to
gp120 and/or ogp140 after the assay to confirm that equivalent amounts
of reactivity had been added.
|
|
| |
DISCUSSION |
We have demonstrated that HIV-1 serum Abs which neutralize primary
HIV-1 isolates bind to both soluble monomeric gp120451 and
ogp140451. Monomeric gp120 and ogp140 coupled to Sepharose beads efficiently removed >99% of serum Abs specific for the
homologous protein. Elution of bound Abs from both gp120 and ogp140
columns yielded gp120- and ogp140-specific Abs which were normalized to original anti-Env reactivity and evaluated for HIV-1 neutralizing activity. The affinity-purified antibodies specific for gp120 were
directed predominantly to epitopes exposed on native gp120. Less
efficient depletion by gp120 or ogp140 was obtained against specific
immunodominant epitopes such as V3 (V3MN) and the
immunodominant domain in gp41 (gp41582), suggesting either
reduced accessibility of these epitopes on immobilized gp120 or ogp140,
differences in amino acid sequence of the epitope in the protein used
to deplete (i.e., 451) and the peptide used for the antibody binding
assay (MN or LAI), or insufficient concentration of the epitope within the protein immobilized on the column. For example, column immobilized peptide V3MN was capable of complete depletion of HIV-1
serum V3 antibody, but the concentration of the V3 region in the V3 affinity column material was approximately 100-fold higher than the
concentration of V3 in the gp120 or ogp140 affinity columns. Therefore,
while the total gp120- and ogp140-binding Ab titers were reduced
100-fold, some epitope-specific Ab populations may have been less
efficiently depleted.
Removal of more than 99% of gp120- or ogp140-binding Abs from the sera
of HIV-infected patients resulted in a significant decrease in
neutralization titers against three primary and two TCLA isolates of
HIV-1. This was in contrast to V3-depletion of HIV-1 sera in this study
as well as in a previous study (74), where removal of V3
antibodies reduced neutralization against TCLA but not primary HIV-1
isolates. These data suggest the presence of antibodies with
specificities outside of linear V3 epitopes and present on both gp120
and ogp140 with neutralizing activity against multiple primary HIV-1
isolates. In addition, affinity-purified gp120451- and
ogp140451-specific Abs neutralized the infectivities of
both TCLA and primary HIV-1 isolates. The gp120-specific Abs purified
from both the gp120451 and ogp140451 affinity
columns were predominantly directed to epitopes present on native but not denatured gp120, consistent with observations that HIV-1 serum gp120-specific Abs are directed predominantly to native gp120 (46,
72) and that many broadly neutralizing MAbs are specific for
discontinuous epitopes within gp120 (9, 26, 52, 71). MAbs
specific for HIV-1 gp41 which potently neutralize HIV-1 have been
identified (14, 15, 47); however, the comparable
HIV-1-neutralizing activities of gp120 and ogp140
affinity-purified Abs from HIVIG, US20, and US22 suggest that a
significant portion of the primary HIV-1 isolate-neutralizing activity
of polyclonal serum Ig is present in Abs with gp120 epitope
specificities. For example, Abs from US20 recovered from the gp120 and
ogp140 columns had comparable neutralizing potencies against
HIV-1US1 as well as HIV-1CM237 and
HIV-1056. Therefore, the presence of gp41-specific antibodies in the ogp140 affinity-purified fraction did not contribute to enhanced neutralizing activity. It remains to be determined whether
fine epitope specificities of the gp120-specific Abs from the gp120 and
ogp140 affinity-purified sera are similar or whether the two fractions
have distinct antibody populations with comparable neutralizing activities.
The oligomeric protein used in this study is comprised of a truncated
gp160 (gp140) which is secreted from a chronically infected cell line
derived from HUT78 cells. Although it naturally assembles and is
secreted in culture media as monomers, dimers, and trimers/tetramers (76), the extent of resemblance, after being immobilized
onto Sepharose, to native gp120/gp41 expressed on the surface of
virions and infected cells is not clearly defined. This may help
explain why despite extensive depletion of Abs to conformational
epitopes on ogp140 (a 256-fold reduction in titer against
ogp140451), substantial neutralizing activity (greater than
90% of total neutralizing activity of US20 Ig) remained in the
depleted fraction. NAbs specific for the C terminus of gp41 (truncated
in ogp140) or to conformational epitopes of gp120/gp41 requiring proper
quaternary structure dependent on either membrane expression or the
presence of an entire intact gp41 may not have been absorbed from the
sera analyzed. The depletion studies, by selectively removing gp120
conformational antibody, demonstrated the presence of some properly
folded gp120 within the gp120- and gp140-coupled matrices. Binding of
MAb T4, which maps to an oligomer-specific epitope within gp41
(19, 20), indicated the presence of some oligomeric gp140
after coupling to the column.
Another explanation may be the presence of NAbs type specific for the
various primary isolates evaluated which were not efficiently depleted
with the 451 strain of gp120 and ogp140 used for this study. These data
indicate a significant proportion (up to 50%) of type-specific primary
isolate NAb. Additionally, critical gp160 epitopes may be absent on the
column-immobilized gp120 or ogp140, possibly secondary to immobilizing
the proteins onto the Sepharose beads. For example, gp120 has been
shown to undergo conformational changes after binding CD4 that result
in enhanced accessibility or exposure of previously cryptic epitopes
(17, 18, 24, 58, 69). Recent HIV-1 envelope structural data
have also identified conserved regions of gp120 involved with
interactions with CD4 and/or coreceptors which are hidden on the native
gp120 protein by glycosylation and the hypervariable loop domains
(38, 55, 80). Abs directed to these regions may be induced
during natural infection but would not be expected to be efficiently
depleted by using soluble gp120 and ogp140. Finally, NAbs directed
against nonenvelope (8, 32, 48, 63) or nonvirus-encoded
proteins (5, 25, 34, 54) which also would not have been
depleted by using the HIV-1 Env-specific reagents have been identified. It should be noted that the inability to remove completely serum neutralizing activity by binding to immobilized gp120, even when evaluated against the homologous TCLA virus (43, 67), has been observed previously.
The presence of epitopes accessible on both monomeric gp120 and ogp140
(antigenicity) capable of depleting HIV-1 serum neutralizing activity
against primary HIV-1 isolates as well as affinity purifying broadly
neutralizing Ab activity is inconsistent with their role as immunogens.
Monomeric forms of gp120 have proven effective in eliciting NAb against
TCLA HIV-1 isolates but with limited neutralizing activity against
primary HIV-1 isolates (2, 30, 33, 41, 42, 62, 78). ogp140
has been shown to elicit Abs capable of neutralizing some primary HIV-1
isolates, but these responses have been restricted to date to those
which are particularly susceptible to Ab-mediated neutralization
(74). Broadly neutralizing Ab responses against primary
isolates as observed with the gp120 and ogp140 affinity-purified sera
have not been achieved in vaccine studies. Therefore, there appears to
be a significant dislinkage between antigenicity and immunogenicity of
soluble HIV-1 subunit vaccines. This may be related to structural
instability of critical conformational epitopes within gp120 as
expressed in gp120 or ogp140 and a more stringent requirement for
eliciting an immune response. Potent NAbs may be capable of binding
with lower affinity to these soluble HIV-1 envelope preparations but
not effectively elicited by using these same proteins. Dose, route,
timing of immunizations, and adjuvant formulations have been shown to
qualitatively alter the quality of the Ab immune response in rabbits
after immunization with ogp140 (74). This finding raises the
possibility that further stabilization of immunogen, by oligomerization
or adjuvant selection, may preserve neutralizing epitopes.
Alternatively, in natural infection, potent NAbs against heterologous
primary viral isolates develop over several years, and therefore more
optimal maturation of the immune response may be required to elicit
NAbs by immunization.
Our laboratory is continuing to identify epitopes on gp120/gp41 which
are recognized by NAbs, with the goal of applying this knowledge toward
design of an immunogenic vaccine. Comparison of the epitope
specificities of gp120- and ogp140-specific Abs from a potently
neutralizing HIV-1 serum with similarly purified Abs from vaccinee sera
should help identify gaps in the latter. In addition, we are
determining whether the remaining neutralizing activity in the
gp120451- and ogp140451-depleted fractions,
similar to what was seen in other studies (43, 67), is
related to heterologous NAbs which did not bind to gp120451
and ogp140451 or to Abs with epitope specificities not
optimally presented by gp120 or ogp140. Finally, extensions of these
type of studies to non-clade B HIV-1 isolates will be important to
determine the relative contribution of various HIV-1 Env-specific
antibodies to HIV-1 isolates circulating in areas where vaccine
efficacy trials may be performed.
| |
ACKNOWLEDGMENTS |
We thank patients and staff of the Infectious Diseases Clinic at
the National Naval Medical Center, Bethesda, Md. for sera used in these
studies. We also thank I. Kalisz for technical assistance, C. Drew for graphic support, C. Sapan for HIVIG, P. Earl for MAbs, L. Loomis-Price for helpful discussions, and P. Gomatos for review of the manuscript.
This work was supported in part by cooperative agreement
DAMD17-93-V-3004, between the U.S. Army Medical Research and Material 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:
tvancott{at}hiv.hjf.org.
Present address: Institute of Human Virology and Department of
Medicine, University of Maryland, Baltimore, MD 21201-1192.
| |
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Abstract
Introduction
