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Journal of Virology, September 2001, p. 8306-8316, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.8306-8316.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Noncytolytic Inhibition of X4 Virus by Bulk
CD8+ Cells from Human Immunodeficiency Virus Type 1 (HIV-1)-Infected Persons and HIV-1-Specific Cytotoxic T Lymphocytes
Is Not Mediated by 
-Chemokines
Ralf
Geiben-Lynn,
Mischo
Kursar,
Nancy V.
Brown,
Ethan L.
Kerr,
Andrew D.
Luster, and
Bruce D.
Walker*
Partners AIDS Research Center and Infectious
Disease Division, Massachusetts General Hospital and Harvard
Medical School, Boston, Massachusetts 02129
Received 14 December 2000/Accepted 1 June 2001
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ABSTRACT |
Human immunodeficiency virus (HIV)-specific cytotoxic T lymphocytes
(CTL) mediate immunologic selection pressure by both cytolytic and
noncytolytic mechanisms. Non cytolytic mechanisms include the release
of 
-chemokines blocking entry of R5 HIV-1 strains. In addition,
CD8+ cells inhibit X4 virus isolates via release of as yet
poorly characterized soluble factors. To further characterize these
factors, we performed detailed analysis of CTL as well as bulk
CD8+ T lymphocytes from six HIV-1-infected individuals and
from six HIV-1-seronegative individuals. Kinetic studies revealed that secreted suppressive activities of HIV-1-specific CTL and bulk CD8+ T lymphocytes from all HIV-1-infected persons are
significantly higher than that of supernatants from seronegative
controls. The suppressive activity could be blocked by monensin and
brefeldin A, was heat labile, and appeared in a pattern different from
that of secretion of chemokines (MDC, I-309, MIP-1
, MIP-1, and
RANTES), cytokines (gamma interferon, tumor necrosis factor alpha, and granulocyte-macrophage colony-stimulating factor), and interleukins (interleukin-13 and interleukin-16). This suppression activity was
characterized by molecular size exclusion centrifugation and involves a
suppressive activity of >50 kDa which could be bound to heparin and a
nonbinding inhibitory activity of <50 kDa. Our data provide a
functional link between CD8+ cells and CTL in the
noncytolytic inhibition of HIV-1 and suggest that suppression of X4
virus is mediated through proteins. The sizes of the proteins, their
affinity for heparin, and the pattern of release indicate that these
molecules are not chemokines.
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INTRODUCTION |
Cytotoxic T lymphocytes (CTL)
inhibit human immunodeficiency virus type 1 (HIV-1) replication by both
cytolytic and noncytolytic mechanisms (35, 37, 38).
Soluble inhibitory factors produced by CD8+ cells have been
shown to inhibit HIV-1 replication and may play a critical role in vivo
as an antiviral host defense (13, 32). These inhibitory
factors include -chemokines (3, 9, 14, 29), a subclass
of cytokines with chemotactic properties that act to block viral entry
through the coreceptor CCR5, which is utilized by R5 strains of virus
(13, 22, 31, 32), and less well characterized
X4-suppressive soluble factor(s) produced by CD8+ cells
(19, 23-25, 33, 35, 37, 38).
Whereas the role of -chemokines in inhibiting R5 strains of HIV-1
has been well established, soluble factors produced by CD8+
cells that inhibit X4 strains of virus are less well defined. Stromal-derived factor 1 (SDF-1), a ligand for the coreceptor CXCR4, at
high concentrations (1,000 ng/ml) can achieve significant inhibition
(3, 28, 36) which can be increased by N-terminal modification (36). However, the production of SDF-1 by
CD8+ cells has not been demonstrated (17), and
other ligands for CXCR4 have not been found. The chemokine I-309 is
another ligand able to block T-cell-tropic HIV-1 strains that can
utilize CCR8 as a coreceptor but has no influence in cell systems where
CXCR4 is used as the coreceptor (14). Another chemokine,
MDC, blocked macrophage- and T-cell-tropic viruses in some but not all
studies through an unknown mechanism (29) but also has not
been shown to be produced by HIV-1 antigen-specific CTL. Additionally,
interleukin-16 (IL-16) has been suggested to have antiviral activity
(1).
Another incompletely defined substance or group of substances produced
by CD8+ cells has been termed CD8+ cell
antiviral factors (CAF) (35). CAF inhibits replication of
X4 strains of HIV-1 at the level of viral transcription by suppressing
long terminal repeat-driven expression of viral proteins (6, 24,
33). However, its identity as well as the phenotype of cells
that produce it and the physiologic stimulus for its release still
elude characterization. The fact that it has been preferentially
observed in persons who are HIV-1 infected suggests that it may be an
antigen-specific response, and at least some reports indicate that a
factor with similar properties can be produced by HIV-1-specific CTL in
an antigen-specific manner (38). However, no studies have
reported a detailed comparison of CD8+ cells from both
seropositive and seronegative persons, as well as HIV-1-specific CTL.
In this study, we have performed a detailed characterization of the
cytokines and chemokines produced when HIV-specific CTL are triggered.
We report the release of MDC, I-309, and IL-16 by HIV-1-specific CTL as
well as CD8+ cells from HIV-1-seropositive persons. In
addition, we show that these factors along with the -chemokines do
not account for all of the noncytolytic inhibition mediated by
HIV-1-specific CTL.
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MATERIALS AND METHODS |
Subjects.
Peripheral blood mononuclear cells (PBMC) were
obtained from six HIV-1-infected subjects. All had plasma HIV-1 loads
of <400 RNA copies per ml and CD4+ cell counts of >500
per µl in the absence of therapy. Control blood samples were obtained
from six HIV-1-seronegative, healthy donors. HIV-specific CTL clones
were obtained from persons with established HIV-1 infections
(4).
Bulk CD8+ cells and HIV-1-specific CTL clones.
Polyclonal CD8+ cells that were 90 to 99% CD3+
and CD8+ positive were generated by fluorescence-activated
cell sorting (FACS) from the six seronegative and the six
HIV-1-seropositive persons by positive selection with anti-CD8
antibody-coated immunomagnetic beads (PerSeptive Biosystems,
Framingham, Mass.) as described elsewhere (7).
HIV-1-specific CTL clones were obtained by cloning of stimulated PBMC
at limiting dilution and characterized for epitope specificity and HLA
restriction as previously described (15, 16, 34). The
HIV-1-specific CTL clones included 115N2 (designated p24/HLA-Cw8),
specific for a Cw8-restricted HIV-1 p24 epitope (amino acids [aa] 305 to 313; RAEQASQEV), 15160-XH66 (designated Gag/HLA-B14),
specific for a B14-restricted Gag epitope (aa 298 to 306;
DRFYKTLRA), 15160-CX74 (designated Nef/HLA-Cw8), specific
for a Cw8-restricted Nef epitope (aa 82 to 91; KAAVDLSHFL), 15160-D75 (designated gp41/HLA-B14), specific for a
B14-restricted gp41 epitope (aa 589 to 597 ERYLKDQQL), and 53B14
(designated Env/HLA-B7), specific for a B7-restricted Env epitope (aa
848 to 856; IPRRIRGL). Bulk CD8+ cell lines from
seropositive and seronegative persons were established by incubating
purified CD8+ cells (2 × 106) with 2 × 107 irradiated allogeneic feeder cells (PBMC) and 0.25 µg of phytohemagglutinin (PHA; Murex, Dartford, United Kingdom) per
ml for 3 days. Cells were maintained in RPMI 1640 (Sigma, St. Louis,
Mo.) supplemented with 10% heat-inactivated fetal calf serum (Sigma),
10 mM HEPES, 2 mM glutamine, 100 U penicillin per ml, 10 µg of
streptomycin per ml, and 50 U of IL-2 per ml (R10-50). After 2 weeks,
0.5 × 106 cells/ml were stimulated by using CD3-
cross-linking in a 1:4 ratio of cells to goat anti-mouse
antibody-coated beads (PerSeptive Biosystems) saturated with a mouse
anti-human 12F6 CD3 antibody (38) (2 µg of
antibody/106 cells). The supernatant fluid was harvested at
the designated time points by centrifugation at 3,000 × g for 10 min.
Assay for inhibition of HIV-IIIIB replication.
H9 cells (HLA A1, B6, Bw62, Cw3) were acutely infected with
HIV-1IIIB at a multiplicity of infection of
10
2 50% tissue culture infective dose per ml and
resuspended in R20. The cells were then plated in 2 ml R20 at 5 × 105 cells/ml in a 24-well plate. CD8+ cell
supernatants were tested at a final dilution of 1:2. H9 cell
supernatant (1 ml) was removed every 3 days and replaced with medium
supplemented with CD8+ cell supernatant or cytokines. After
9 days, the concentration of p24 was measured with an HIV-1 p24
enzyme-linked immunosorbent assay (ELISA) kit (NEM Life Science,
Boston, Mass.), and the percentage inhibition was calculated against
the medium control.
Flow cytometric analysis.
FACS analysis was performed after
2 weeks of propagation for CD8+ cells, at the time cells
were used in the CD3 cross-linking assays. Cells were stained using
directly conjugated dye-labelled antibodies as follows:
CD28/CD3/CD8/CD38, CD45-RA/CD8/HLA-DR/CD45-RO, CD62-L/CD3/CD8, CD25/CD3/CD8, and CD44/CD3/CD8, using antibodies purchased from PharMingen (San Diego, Calif.). Isotype-matched controls
(immunoglobulin G1 [IgG1]-fluorescein isothiocyanate [FITC],
IgG1-phycoerythrin, IgG1-peridinin chlorophyll protein, and
IgG1-allophycocyanin) were also obtained from PharMingen. CXCR4
expression on H9 cells was determined using CXCR4-FITC-conjugated
antibodies and an IgG2a-FITC control from PharMingen.
Characterization of soluble factors.
Molecular weights for
the suppressive activities of harvested cell supernatants were
determined after heparin binding (5-ml HiTrap heparin-Sepharose column,
Amersham Pharmacia, Piscataway, N.J.) by Centricon centrifugation. The
heparin-nonbound fraction was obtained by washing the column with
phosphate-buffered saline (PBS), after which the heparin-bound fraction
was eluted with 2 M NaCl in PBS. Heparin-bound or unbound fractions
were then filtered through 20-ml Centricon membranes, (Millipore,
Bedford, Mass.) with molecular exclusion sizes of 100, 50, 8, and 3 kDa sequentially, concentrated to 100 µl, and washed twice with a 200-fold volume of PBS. An equimolar to 350 mM NaCl suppressive heparin-bound fraction was obtained by loading 20 to 80 ml of supernatant onto the heparin column, washing with 20 ml of PBS, and
running a 20-min PBS-1 M NaCl-PBS gradient at a flow rate of 500 µl/min. A 40-kDa heparin-bound Superdex suppressive fraction was
obtained by concentrating the 350 mM heparin-bound fraction on a 50-kDa
cutoff Centricon membrane and fractionating 200 µg of this
concentrate on a Superdex-200 column (3.2 by 300 mm; Pharmacia) at a
flow rate of 40 µl/min in PBS. Molecular mass of the heparin-bound Superdex fraction with the highest HIV-1 suppression was calibrated using the following calibration proteins (Sigma): thymus globulin (669 kDa), ferritin (440 kDa), catalase (232 kDa), aldolase (158 kDa),
albumin (67 kDa), ovalbumin (45 kDa), and chymotrypsin (25 kDa). ELISAs
were performed according to the manufacturer's instructions, using
paired antibodies from R&D Systems, Inc. (Minneapolis, Minn.) and
horseradish peroxidase-avidin D (Vector, Burlingame, Calif.). For the
MDC ELISA, a monoclonal capture antibody (R&D) was used, whereas for
the second antibody a polyclonal donkey anti-MDC antibody (ICOS,
Bothell, Wash.) was used. The peroxidase enzyme function was coupled
here with a chicken anti-donkey antibody (ICOS). The detection limit
for all ELISAs was below 15 pg/ml except for SDF-1, where the detection
limit was 2 ng/ml. Neutralizing antibodies for MDC, IL-16, I-309, and
polyclonal control antibody (PeproTech, Rocky Hill, N.J.) were used
alone or combined with a 4°C overnight preincubation of supernatant
before use in the inhibition test. The neutralizing antibodies were
used at a concentration of 5 µg/ml, where according the manufacturer
they were able to neutralize approximately 50% of chemokine (100 ng/ml). Protein concentration was determined by the bicinchoninic acid
method (Pierce, Rockford, Ill.). Proteinase treatment using proteinase
K immobilized on beads (Sigma) was performed with 1 U/ml for
supernatants at 37°C for 12 h, after which the solution was
filtered. Heat treatment was performed at 60°C for 30 min. To block
protein secretion, cells were treated with 2 µM monensin and 3.5 µM
brefeldin A (both from Sigma) for 4 h during anti-CD3
cross-linking activation. To block protein synthesis, cycloheximide
(Sigma) at 8.8 µM was used for 2 h at 37°C. Cells were then
washed twice and stimulated with anti-CD3 for 4 h at 37°C.
Supernatants of monensin-, brefeldin A-, and cycloheximide-treated
cells were then used in inhibition tests. Cytokines used were from
PeproTech Inc.; MDC(
2) is a modified form of MDC missing 2 aa at its
N terminus. Protein purity and molecular weight were estimated by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)
and silver staining (11) with a 15% slab gel, using a
low-range protein molecular weight marker (Bio-Rad, Hercules, Calif.).
The samples were treated with 2.5% 2-mercaptoethanol. For Western blot
analysis, protein samples were treated with 2.5% 2-mercaptoethanol and
separated by SDS-PAGE with a 15% slab gel. Immediately following
separation by SDS-PAGE, the gel was treated with transfer buffer and
blotted onto nitrocellulose paper (11). After blocking
with 5% bovine serum albumin in PBS and 0.05% Tween 20 (Fisher
Scientific, Springfield, N.Y.), the nitrocellulose paper was incubated
with a 1/1,000 dilution of anti-MDC, anti-IL-16, and anti-I-309 rabbit
antibodies (PeproTech) alone or combined for 16 h at 4°C in PBS,
0.05% Tween 20, and 0.1% bovine serum albumin. The nitrocellulose
paper was washed and treated with 1/10,000-diluted anti-rabbit
antibodies labeled with horseradish peroxidase (Vector). The membrane
was washed in PBS, and Western blot chemiluminescence reagent (NEM) was
added. The emitted light from the oxidative degradation of luminol was captured on Kodak X-Omat autoradiography film (Kodak, Rochester, N.Y.).
For the Western blots we used a prestained broad-range protein
molecular weight marker (Bio-Rad).
Ca2+ flux in leukocytes.
Ca2+ flux
experiments were performed as described previously (12) 1 week after stimulation with 0.25 µg of PHA per ml, using positively
selected CD4+ cells obtained using anti-CD4 antibody coated
on immunomagnetic beads (PerSeptive Biosystems) or log-phase-growing H9
cells. Purified cells were loaded with 5.0 µM fura-2 acetoxymethyl
ester (Molecular Probes, Eugene, Oreg.) for 60 min at 37°C in the
dark at 107 cells/ml in Dulbecco modified Eagle medium
supplemented with 1% heat-inactivated fetal bovine serum. Loaded cells
were washed twice and resuspended in a buffer containing 145 mM NaCl, 4 mM KCl, 1 mM NaHPO4, 0.8 mM MgCl2, 1.8 mM
CaCl2, 25 mM HEPES, and 22 mM glucose. Two milliliters of
cells (106 cells/ml) was placed in a continuously stirred
cuvette at 37°C in a dual-wavelength excitation source fluorimeter
(Photon Technology Inc., South Brunswick, N.J.). Changes in cytosolic
free calcium were determined after addition of the equimolar to 350 mM
NaCl heparin-bound fraction, the 40-kDa heparin-bound Superdex
fraction, and SDF-1 (Peprotech) by monitoring the excitation
fluorescence intensity emitted at 510 nm in response to sequential
excitation at 340 and 380 nm. The data are presented as the relative
ratio of fluorescence at 340 and 380 nm.
Statistical analysis.
Fisher's exact test was used to
determine significance. Standard error is shown as error bars.
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RESULTS |
Release of suppressive soluble factor(s) by HIV-1-specific CTL, as
well as bulk CD8+ cells of HIV-1 seropositive and
seronegative individuals.
CD8+ cells produce soluble
factors that inhibit X4 virus replication (6, 19, 23-25, 33, 35,
37, 38), but no kinetic studies have been reported as to when
the suppressive activity is produced or whether it is derived from
HIV-1-specific CTL. HIV-1-specific CTL clones as well as bulk
CD8+ cells, from HIV-1-seropositive and seronegative
individuals, that had been expanded in vitro in the presence of IL-2
were stimulated by anti-CD3 cross-linking for 1 to 16 h (Fig.
1). Cell-free supernatants were obtained
by 10-min 3,000 × g centrifugation, diluted 1:2, and
added to freshly HIV-1IIIB-infected H9 cells, and p24
production was monitored over a 9-day period. Virus production was weak
at day 3 but readily apparent by day 6 and maximal at day 9, with levels of infection in the controls showing p24 levels of >100 ng/ml.
Figure 1 compares relative levels of p24 HIV antigen suppression in
assays using inhibition assay supernatant fluid harvested on day 9. Maximal inhibition of p24 was detected in CD8+ cell
supernatants harvested 4 h after anti-CD3 stimulation (Fig. 1),
averaging 44% (range, 35 to 66%) for seronegative CD8+
cells, with 76% (range, 50 to 95%) for HIV-seropositive
CD8+ cells and 70% (range, 59 to 92%) for HIV-1-specific
CTL. The range of inhibition at 4 h was similar at 16 h.
Whereas the supernatants of the bulk CD8+ T cells from
seronegative individuals showed a significantly lower level of
inhibition starting at 4 h compared to CTL clones (P = 0.039) and bulk CD8+ cells from seropositive
individuals (P = 0.001), no significant differences in
the release of the suppressive soluble factor(s) were found between the
CTL clones and the bulk CD8+ T cells from seropositive
individuals at any of the six time points analyzed. The level of
inhibition over the time points tested for the seronegative bulk
CD8+ cells ranged from 30 to 60% of that produced by
CD8+ cells and CTL from seropositive persons. Inhibition
was not due to an antiproliferative effect on the H9 cells used in the
inhibition assay as measured by total cell counts in the log phase of
cell growth at days 3 to 6 in a control experiment without virus (data not shown). The maximal inhibition (95%) by the supernatants was found
when 4-h supernatants of bulk CD8+ cells of seropositive
individuals were analyzed at day 9 in the infection assay used to
quantitate level of inhibition, compared to 15 and 81% suppression at
days 3 and 6, respectively (Fig. 2).
These results indicate that CD8+ cells from HIV-1-infected
persons have an enhanced ability to suppress X4 strains of HIV-1
compared to cells from seronegative persons and that this activity is
similar in magnitude and kinetics to that produced by stimulation of
HIV-1-specific CTL.
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FIG. 1.
Differential suppressive activity of CD8+ T
cells of HIV-1-seronegative individuals (squares), CTL clones
(diamonds), and asymptomatic HIV-1-seropositive individuals (circles).
Supernatants of CD3-stimulated CD8+ T cells were collected
after 2, 4, 8, and 16 h, diluted 1:2 in R20, and added to H9 cells
acutely infected by HIVIIIB; 1 ml of H9 supernatant was
removed when 1 ml of 1:2-diluted supernatants was added at days 3 and
6. The supernatant of the inhibition test was collected and tested for
p24 production after 9 days in culture. Percentage of inhibition was
calculated against an untreated control. The asterisks indicate a
statistically significant difference of cells from HIV-1-seronegative
individuals (n = 6) against both cells from
HIV-1-seropositive individuals (n = 6) and CTL
(n = 5) (*, P < 0.05; **,
P < 0.01: Fisher's exact test). Error bars of at
least five independent experiments are shown.
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FIG. 2.
Levels of HIV-1 p24 antigen after an inhibition test
with supernatants from CD8+ cells of an HIV-1-infected
long-term nonprogressor. The CD8+ cells were stimulated for
a different period of time (0 to 16 h); supernatants were
collected, and acutely infected H9 cells were incubated for 3, 6, or 9 days (3d, 6d, or 9d; see Materials and Methods). Percentage shows the
highest inhibition of p24 antigen suppression against the medium
control found at day 9. Time zero denotes 4-h supernatant without CD3
activation.
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Phenotypic characterization of CD8+ cells from
HIV-1-seropositive and seronegative persons.
In response to viral
infection, unprimed naive CD8+ T cells clonally respond and
differentiate into memory- and effector-type virus-specific T cells
that are phenotypically distinct (2, 18, 21, 27, 39). To
determine if phenotypes among the sources of CD8+ cells
used are associated with the observed differences in release of the
suppressive factor(s), we examined the prevalence of surface makers
expressed at the time the cells were used for the anti-CD3 activation.
For these studies, fresh CD8+ cells were obtained from
HIV-1-seropositive and seronegative persons by positive selection with
an anti-CD8 monoclonal antibody coated on immunomagnetic beads. These
CD8+ cells and HIV-1-specific CTL clones were simulated
with PHA and irradiated allogeneic feeder cells, propagated for 2 weeks, and stained for FACS analysis. The bulk CD8+ cells
of seronegative individuals showed a significantly higher percentage of
CD62-L cells than either the cells derived from seropositive
individuals (P = 0.011) or CTL (P = 0.0004). The percentage of naive cells in seronegative persons as
measured by the CD45-RA antibody was also higher but not significantly different from that for either cells from seropositive individuals (P = 0.165) or CTL (P = 0.096). The
CD8+ cells from seronegative individuals are in the same
state of activation as CD8+ cells from seropositive
individuals and CTL, as measured by CD38 and CD44 activation (Table
1). No other significant differences between CTL and CD8+ cells could be found. Our data suggest
that the decreased suppression mediated by CD8+ cell
supernatants from seronegative persons is associated with a higher
percentage of naive cells.
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TABLE 1.
Cells stained by surface marker and significance of
difference of bulk CD8+ cells of seronegative individuals
compared to each bulk CD8+ cells of seropositive
individuals and HIV-1-specific CTL
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Release of cytokines and chemokines by bulk CD8+
lymphocytes of HIV-1-seropositive and seronegative individuals and by
HIV-1-specific CTL.
Having demonstrated that X4 virus-inhibitory
factors are produced in greater amounts by CD8+ cells and
CTL from HIV-seropositive persons, we next compared the magnitude and
kinetics of inhibition to that of other CD8+ cell factors
known to inhibit either R5 or X4 viruses. The supernatants of
HIV-1-specific CTL clones, bulk CD8+ cells from HIV-1
seropositive persons, and bulk CD8+ cells from seronegative
individuals were assayed for their secretion of cytokines after 0, 4, and 16 h of anti-CD3 stimulation (Fig. 3).
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FIG. 3.
Secretion of -chemokines (A) and other cytokines (B)
of CD8+ T cells of HIV-1-seronegative individuals (open
squares), asymptomatic HIV-1-seropositive individuals (gray squares),
and CTL clones (black squares). Supernatants of CD3-stimulated
CD8+ T cells were collected after 0, 4, and 16 h; time
zero denotes supernatant of 4-h incubation without anti-CD3
stimulation. Supernatants were tested for cytokine concentrations by
ELISA (see Materials and Methods). The asterisks indicate a
statistically significant difference of cells from seronegative
individuals against both cells from seropositive individuals and CTL
clones (P < 0.05; Fisher's exact test). All error
bars for at least five independent experiments are calculated, but some
are too small to show.
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The time course and magnitude of release of cytokines after CD3
cross-linking demonstrated significant differences when bulk
CD8
+ cells of seronegative individuals were compared to CTL
and bulk
CD8
+ cells of seropositive individuals. No
significant differences
for MIP-1
, MDC, I-309, IL-13, or IL-16 were
found (Fig.
3). Conversely,
cells from seropositive individuals
compared to seronegative persons
produced, after 4 h of
activation, more MIP-1
(
P = 0.021), RANTES
(
P = 0.034), gamma interferon (IFN-
) (
P = 0.028), tumor necrosis
factor alpha (TNF-
) (
P = 0.017), and granulocyte-macrophage colony-stimulating
factor
(GM-CSF) (
P = 0.034). CTL supernatants also produced
significantly
higher levels after 4 h for MIP-1
(
P = 0.036), RANTES (
P = 0.006),
IFN-
(
P = 0.0001), TNF-
(
P = 0.0001), and GM-CSF
(
P = 0.001)
compared to the levels produced by
seronegative bulk CD8
+ cells. None of the individual
factors assayed displayed a pattern
of release similar to that seen for
the X4 virus-suppressive factor(s),
which was characterized by
significant differences at 4 and 16
h of stimulation in
seropositive compared to seronegative persons.
As for differences
between CTL clones and bulk CD8
+ cells of seropositive
individuals, CTL clones released three
to five times more MDC, I-309,
and GM-CSF than bulk CD8
+ cells of seropositive
individuals, whereas for bulk CD8
+ cells of seropositive
individuals, a four fold greater release
of IL-13 was seen. This
suggests that the factors affecting X4
virus replication have a pattern
of release different from that
of the chemokines MIP-1
, MIP-1
,
RANTES, IL-13 (
9,
26),
MDC, I-309, and IL-16 (
1,
14,
29). Additionally, the mechanism
of action seems to be
independent from the cytokines TNF-
and
IFN-
, known to influence
HIV replication (
10), based on the
finding that the levels
of these cytokines are similar in all
groups at 16 h following
stimulation, yet suppression is observed
only in supernatants derived
from cells of HIV-1-seropositive
persons.
The conclusion that the X4 virus-suppressive factor is distinct from
known cytokines, chemokines, and interleukins was also
supported by
direct inhibition assays using recombinant forms
of these compounds.
The amounts of chemokines released (I-309,
MDC, and IL-16) were too low
to be responsible for the observed
inhibition. Even when used in
amounts 45 to 25,000 times higher
than measured, significant (greater
than 50%) inhibition could
never be achieved (Fig.
4). To further exclude the possibility
that these proteins are responsible for the suppression tested,
we used
neutralizing antibodies against I-309, MDC, and IL-16
at a
concentration of 5 µg/ml. None of the neutralizing antibodies
alone
or in combination inhibited the suppressive activity in
the
supernatants used (Fig.
5), excluding
these factors as responsible
for the suppressive activity measured. The
only factor tested
that showed significant inhibition was SDF-1
starting at a concentration
of 0.5 µg/ml and 50% inhibitory dose
(ID
50) of 81 nM (0.63 µg/ml).
However, no detectable
SDF-1 was present in the stimulated CD8
+ cell and CTL
supernatants by ELISA, consistent with the findings
of others
(
17).
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FIG. 4.
Inhibition of p24 antigen after addition of cytokines
(SDF-1 [1, 0.5, 0.25, and 0.1 µg/ml], I-309 [1 µg/ml], MDC [1
µg/ml], MDC(2) [1 µg/ml], and IL-16 [1 µg/ml]),
cycloheximide, proteinase K, and heat treatment. At days 3 and 6, 1 ml
of the 2-ml H9 cell supernatant was removed and replaced with 1 ml of
fresh R20 with new chemokines or with supernatants. At day 9, p24
antigen was measured. Here error bars for at least three independent
experiments are shown. The asterisks indicate a statistically
significant difference from the control (*, P < 0.05; **, P < 0.01; Fisher's exact test).
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FIG. 5.
Neutralization studies with antibodies against MDC,
I-309, and IL-16. Supernatants after 4 h of stimulation were
preincubated overnight at 4°C with anti-MDC, anti-I-309, and
anti-IL-16 antibodies (5 µg/ml) alone or combined. The supernatants
were diluted 1:2 when added to the inhibition test (see Materials and
Methods). At day 9, p24 antigen of the supernatant fluids of the
inhibition assays was measured. The experiment represents the average
of three independent experiments. The controls include the isotype
antibodies.
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Characterization of suppressive activity.
Having shown that
the suppressive activity released is different from cytokines,
chemokines, and interleukins, we next evaluated the stability of this
activity. The suppressive activity was 100% degradable with proteinase
K and heat treatment (Fig. 4). Additionally, cells were treated with
cycloheximide to determine if the inhibitory substance is preformed
within cells. The bulk CD8+ cells of the seropositive
individuals and CTL clones both demonstrated that the inhibitory
activity was preformed, in that it was not inhibited with
cycloheximide. In contrast, CD8+ cells from seronegative
persons no longer produced inhibitory factors after cycloheximide
treatment (Fig. 4). To analyze the exocytotic pathway, we incubated the
cells with monensin and brefeldin A and found that the suppressive
activity was blocked by >90% with these compounds. At the same time,
treatment with monensin and brefeldin A resulted in greater than 70%
inhibition of secretion of MIP-1, MIP-1, TNF-, and IFN-
(Table 2). These results indicate that
the suppressive activity is secreted in a manner similar to these
proteins.
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|
TABLE 2.
Decrease of production of RANTES, MIP-1, MIP-1,
TNF-, and IFN- and of HIV-1IIIB suppression after
treatment of CTL with monensin and brefeldin Aa
|
|
Using supernatants derived 4 h following stimulation with anti-CD3
of bulk CD8
+ cells from seropositive individuals or
HIV-1-specific CTL, active
fractions were obtained and used for further
purifications. The
protein amount necessary to block 50% of the virus
(ID
50) was
found to be 5 mg/ml using these supernatants
(1:2 dilution) derived
4 h after stimulation with anti-CD3 of bulk
CD8
+ cells of seropositive individuals or HIV-1-specific
CTL.
We next further characterized the binding properties and size of the
suppressive activity. Supernatants were separated into
heparin binding
and nonbinding fractions. The nonbinding fraction
was collected after
washing of the heparin-Sepharose column with
PBS. The binding fraction
then was eluted with 2 M NaCl in PBS.
Both eluates where then filtered
sequentially through Centricon
membrane with different exclusion sizes
(100, 50, 8, and 3 kDa).
Approximately half of the suppressive activity
of the 4-h supernatants
isolated by Centricon centrifugation is found
in the <50-kDa heparin-unbound
fraction, with an ID
50 of
770 µg/ml (1:30 dilution), which is
seven times lower than that of
the starting material. The remaining
suppressive activity is due to
proteins of >50 kDa by Centricon
centrifugation which bound to heparin
(Fig.
6), with a 15-fold
lower
ID
50 than the initial supernatant at 330 µg/ml (1:30
dilution)
(Table
3). In a Western blot
analysis with the heparin-bound
fraction, MDC, IL-16, and I-309 were
not detectable (Fig.
7C),
demonstrating
that these molecules did not contribute to the measured
inhibition.
Using the 350 mM heparin-bound fraction of 4-h supernatants
of bulk
CD8
+ cells of seropositive individuals or HIV-1-specific
CTL, we could
increase the purification factor to 215 with an
ID
50 of 23.5 µg/ml
at a 1:30 dilution; using the 40-kDa
heparin-bound Superdex fraction,
we found at a 1:75 dilution an
ID
50 of 5.5 µg/ml and a purification
factor of 909 (Table
3). The strength of inhibition of the 40-kDa
heparin-bound Superdex
fraction was associated with the prevalence
of a 43-kDa main protein as
measured by SDS-PAGE (Fig.
8). In
a
Western blot analysis with the 40-kDa Superdex eluate, MDC,
IL-16, and
I-309 were not detectable (Fig.
8C) in assays using
half of the total
protein amount used for the 9-day inhibition
test, where the fractions
were 75 times diluted again indicating
that these molecules are not
responsible for the measured inhibition.
Our data thus suggest that
there are either two suppressive activities
or one that is in two
different configurations after CD3 activation.
These can be
differentiated by heparin binding and size. We then
assessed for
down-regulation of the CXCR4 receptor and for Ca
2+ flux,
characteristics seen for activities of chemokines, which
can bind to
heparin. We found no chemokine-like activity: using
either the 350 mM
heparin-bound fraction or the 40-kDa heparin-bound
Superdex fraction,
no down-regulation of the CXCR4 receptor (Fig.
9) or Ca
2+-flux (Fig.
10) was observed.
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|
FIG. 6.
Differential suppressive activity of fractions after
HiTrap heparan sulfate chromatography of supernatant of 4-h
anti-CD3-stimulated HIV-1-specific CTL clone 15160-D75. A 5-ml heparin
column (Pharmacia) was loaded with 10 ml of supernatant and washed with
20 ml of PBS. The heparin-unbound fraction was filtered and
concentrated to 100 µl sequentially through Centricon membranes with
exclusion sizes of 100, 50, 8, and 3 kDa. The heparin-bound fraction
was then obtained by washing the heparin column with 20 ml of 2 M NaCl
in PBS, followed by the above-described size exclusion centrifugation
steps. The supernatants on top of the Centricon membranes were
concentrated to 100 µl, washed twice with a 200-fold times volume of
PBS, and tested for activity. The controls include the buffer
conditions.
|
|
View this table:
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|
TABLE 3.
ID50 and purification factors for each
purification step, using 4-h supernatant of anti-CD3-stimulated bulk
CD8+ cells of seropositive individuals or HIV-1-specific
CTL
|
|
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FIG. 7.
HIV-1-suppressive activity of the heparin-bound eluates
(A), silver-stained SDS-polyacrylamide gel of peak active suppressive
fraction (B), and Western blot of peak active suppressive fraction,
using a combination of antibodies against IL-16, MDC, and I-309 (C).
(A) Heparin-bound eluates were diluted 1:30 in the inhibition test (see
Materials and Methods). At day 9, HIV-1 p24 antigen was measured and
compared against a buffer-treated control. (B) Lane 1, 20 µl of
fraction with peak suppression was subjected to SDS-PAGE and silver
stained. (C) Lane 1, Western blot of 20 µl of fraction with peak
suppression (1/5 of total amount used for the 9-day inhibition test)
incubated with the combined antibodies; lane 2, Western blot of the
IL-16 protein (100 ng) incubated with combined antibodies; lane 3, Western blot of MDC protein (100 ng) incubated with combined
antibodies; lane 4, Western blot of the I-309 protein (100 ng)
incubated with combined antibodies. In control experiments, the Western
blots were incubated alone with antibodies against IL-16, MDC, and
I-309. AU, arbitrary units.
|
|
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FIG. 8.
HIV-1-suppressive activity of the heparin-bound Superdex
eluates (A) silver-stained SDS-polyacrylamide gel of peak active
suppressive fraction (B), and Western blot of peak active suppressive
fraction, using a combination of antibodies against IL-16, MDC, and
I-309 (C). (A) Superdex eluates were diluted 1:75 in the inhibition
test (see Materials and Methods). At day 9, HIV-1 p24 antigen was
measured and compared against a buffer-treated control. (B) Lane 1, 20 µl of fraction with peak suppression was subjected to SDS-PAGE and
silver stained. (C) Lane 1, Western blot of 20 µl of fraction with
peak suppression (1/2 of total protein amount used for the 9-day
inhibition test) incubated with the combined antibodies; lane 2, Western blot of the IL-16 protein (100 ng) incubated with combined
antibodies; lane 3, Western blot of MDC protein (100 ng) incubated with
combined antibodies; lane 4, Western blot of the I-309 protein (100 ng)
incubated with combined antibodies. In control experiments, the Western
blots were incubated alone with antibodies against IL-16, MDC, and
I-309. AU, arbitrary units.
|
|
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FIG. 9.
CXCR4 down-regulation by the heparin-bound suppressive
fraction. CD4+ cells (106/ml) were incubated
either with R10-50 (Ctrl), 15 to 30 µg of the 350 mM heparin-bound
fraction [(1)], or SDF-1 (250 ng/ml), incubated for 45 min at
37°C, and then stained with monoclonal CXCR4-FITC antibody or control
antibody (IgG2a). Staining was measured by FACS analysis. The data are
representative of three or more experiments for primary
CD4+ cells and H9 cells, using the 350 mM heparin-bound or
the 40-kDa heparin-bound Superdex fraction (0.5 to 6 µg of
protein).
|
|
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FIG. 10.
Ca2+ flux induced by heparin-bound fraction
versus SDF-1. Ca2+ flux was monitored by the ratio of
fluorescence of fura-2-loaded primary CD4+ cells. Arrows
indicate the time (at 50 s) of adding 15 to 30 µg of the 350 mM
heparin-bound fraction which was concentrated on a 50-kDa-cutoff
Centricon membrane to 100 µl and washed twice with a 200-fold volume
of PBS. SDF-1 (50 ng/ml) was added at 130 s to CD4+
cells (106/ml). The data are representative of three or
more experiments for primary CD4+ cells and H9 cells, using
the 350 mM heparin-bound or the 40-kDa heparin-bound Superdex fraction
(0.5 to 6 µg of protein).
|
|
| |
DISCUSSION |
HIV-1-specific CTL exert potent antiviral effects that are
mediated by distinct cytotoxic and noncytotoxic mechanisms. Whereas the
role of -chemokines in inhibiting R5 strains of HIV-1 is well
established, soluble factors produced by CD8+ cells that
inhibit X4 strains of virus are less well defined. In addition, there
are few studies that address the relationship between these two
effector mechanisms in the inhibition of X4 strains of the virus. Here
we show that the noncytolytic, X4 virus-specific antiviral properties
of HIV-1-specific CTL and CD8+ cells from seropositive
persons have similar characteristics. Both exist in a preformed state
within the cells, and both have similar initial kinetics of release
following stimulation of cells. In addition, antiviral suppression
mediated by both appears to be due to a secreted protein, since it can
be inhibited by proteinase K treatment and is heat labile. The fact
that the magnitude and kinetics of suppression are significantly
different from those observed with CD8+ cells from
uninfected persons underscores that this noncytolytic suppression is
induced by HIV infection.
Our data indicate that the lower amounts of naive CD8+
cells are responsible for the detected higher release of X4-suppressive factors of HIV-1-seropositive individuals and HIV-specific CTL compared
to CD8+ cells of seronegative individuals (Fig. 1; Table 1)
and that the suppressive factor(s) suppresses HIV-1 replication in
highly infected CD4+ cells (Fig. 2). Additionally, our data
directly examine the properties of the inhibitory activity and indicate
that the suppressive factor(s) is not likely a cytokine, for a number
of reasons. The kinetics of release of the antiviral activity is
distinct from the pattern of secretion of cytokines, chemokines, and
interleukins. In our in vitro system we found that none of the known
X4-suppressive factors (IL-16, MDC, I-309, and SDF-1) (1, 3, 14,
28, 29) displayed a pattern of release similar to that of the
X4-suppressive factor(s) here described. Significant differences in
release were observed at both 4 and 16 h after stimulation,
comparing CD8+ cells of seronegative individuals with
CD8+ cells of seropositive individuals and HIV-1-specific
CTL clones (Fig. 3). We also tested for cytokines (IFN-, TNF-,
and GM-CSF), interleukins (IL-13 and IL-16), and suppressive chemokines
(MIP-1, MIP-1, and RANTES) known to inhibit R5 viruses
(9), and we found that none of these factors showed a
pattern of secretion similar to that of these suppressive factors.
Nevertheless, we do show that HIV-1-specific CTL release IL-16, MDC,
and I-309, and this can occur in picogram to nanogram amounts (Fig.
3A). Additionally, these molecules used as recombinant proteins were not able to significantly suppress X4 HIV-1 even in high concentrations (Fig. 4). Here we show that of the chemokines tested, only SDF-1 was
able to suppress X4 HIV-1 (Fig. 4), but this molecule was not
detectable by ELISA. Additionally, SDF-1 RNA expression was not found
with an SDF-1-specific DNA probe (data not shown), which is consistent
with findings of others (17). Not only was the pattern of
secretion of the tested cytokines and chemokines different, but the
amounts produced for IL-16, MDC, and I-309 were not substantial enough
to explain the measured suppressive activity. To exclude biologically
active molecules of these chemokines not distinguished by the ELISA
used but possibly responsible for the inhibition measured, we performed
studies with neutralizing antibodies against IL-16, MDC, and I-309.
None of these antibodies alone or in combination decreased the
suppressive activity in the supernatants used, indicating that these
molecules are not responsible for the suppressive activity (Fig. 5).
Additionally, Western blots of the heparin-bound fraction and the
40-kDa heparin-bound Superdex fraction with anti-IL-16, anti-MDC, and
anti-I-309 antibodies showed no evidence of these chemokines (Fig. 7C
and Fig. 8C).
Although the above data suggest that the factor is not a known cytokine
or chemokine, a number of experiments support the conclusion that the
suppressive factor is a preformed secreted protein. The suppressive
activity was found to be 100% degradable by proteinase K and heat
(Fig. 4). In this respect, it appeared distinct from the 30 to 40-kDa
CD8+ CAF (6, 35; J. A. Levy, personal
communication), which has been reported to be heat stable.
Additionally, the secretion of the soluble factor(s) was not
significantly suppressed with cycloheximide in HIV-seropositive bulk
CD8+ cells (P = 0.062) and CTL clones
(P = 0.882), whereas it was totally abolished from
CD8+ cells of seronegative individuals (P = 0.010). Thus, de novo synthesis was necessary to
achieve measurable inhibition in supernatants from seronegative
CD8+ cells after 4 h of stimulation, but this was not
characteristic for seropositive persons (Fig. 4). Monensin and
brefeldin A treatment decreased the suppression activity, indicating
that factor release involves the exocytotic pathway. Additionally,
monensin and brefeldin A treatment showed that the suppressive activity
was not part of the RANTES-glycoaminoglycan complex (5)
because RANTES was not blocked by monensin and brefeldin A treatment
(Table 2).
Although we have not precisely identified the active fraction mediating
antiviral suppressive activity, our data should facilitate future
studies to further elucidate the contributing components. Our data
indicate that there is at least one factor with two distinct configurations which differ in size and heparin binding properties. Approximately half of the total suppressive activity is within a
heparin-bound fraction that contains proteins with molecular sizes of
>50 kDa as determined by Centricon centrifugation. Additionally, the
350 mM heparin-bound fraction could not down-regulate CXCR4 (Fig. 9).
This excludes a mechanism of inhibition for X4 viruses seen for the
chemokines (3, 29). Also, the 350 mM heparin-bound fraction and the 40-kDa heparin-bound Superdex fraction did not induce
a Ca2+ flux (Fig. 10). Additionally, the correlation
between inhibition seen from the Superdex eluates and the prevalence of
a 43-kDa main protein as measured by SDS-PAGE indicates that the
chemokines are not responsible for the inhibition. Chemokines are
typically much smaller (<10 kDa) and would be expected to bind to
heparin and to induce a Ca2+ flux (12). A
second fraction with suppressive activity did not bind to heparin and
had proteins smaller than 50 kDa but larger than 3 kDa, also as
determined by Centricon centrifugation (Fig. 6). Other studies of
CD8+ cell noncytotoxic suppression have not examined
the ability to bind to heparin, and so this finding cannot be
compared to other published studies. Additionally, the suppressive
factor(s) described here may be different from others described in the
literature because a different stimulation approach was used compared
to the conventional methods with anti-CD3/anti-CD28 and/or PHA and IL-2
stimulation and collection of supernatants 3 to 8 days later. Further
experiments will be required to fully define the factors described
here, determine their mechanism of inhibition, and establish at which
step in the viral life cycle the CD8+ cell factor(s) is
active (6, 25, 33). These data also need to be examined in
the context of other studies of non cytolytic inhibition where a
CD8+ CAF was reported to be released by baboon
CD8+ cells (23) or Epstein-Barr virus-specific
CD8+ cells (19).
In summary, our data provide a functional link between CTL and
CD8+ cell-derived virus-suppressive factors. We hypothesize
that the noncytotoxic activity may be particularly important at the
level of the local microenvironment, where it may serve an important function in inhibiting the spread of infectious virus.
| |
ACKNOWLEDGMENTS |
We thank David Chantry of ICOS Co. for the gift of polyclonal MDC antibodies.
This research was funded in parts by grants from the Defense
Advanced Research Projects Agency (MDA-972-97-1-00144), the
Deutsche Forschungsgemeinschaft, and the NIH (AI30914, AI28568, and AI46999).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Partners AIDS
Research Center, 149 13th St., Charlestown, MA 02129. Phone: (617)
724-8332. Fax: (617) 726-4691. E-mail:
bwalker{at}helix.mgh.harvard.edu.
| |
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Journal of Virology, September 2001, p. 8306-8316, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.8306-8316.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
