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Journal of Virology, March 2001, p. 2142-2153, Vol. 75, No. 5
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.5.2142-2153.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Mature Dendritic Cells Infected with Canarypox
Virus Elicit Strong Anti-Human Immunodeficiency Virus CD8+
and CD4+ T-Cell Responses from Chronically Infected
Individuals
Jose
Engelmayer,1
Marie
Larsson,1
Andrew
Lee,1
Marina
Lee,1
William I.
Cox,2
Ralph M.
Steinman,1 and
Nina
Bhardwaj1,*
Laboratory of Cellular Physiology and
Immunology, The Rockefeller University, New
York,1 and Virogenetics Corporation,
Troy,2 New York
Received 31 July 2000/Accepted 29 November 2000
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ABSTRACT |
Recombinant canarypox virus vectors containing human
immunodeficiency virus type 1 (HIV-1) sequences are promising vaccine candidates, as they replicate poorly in human cells. However, when
delivered intramuscularly the vaccines have induced inconsistent and in
some cases transient antigen-specific cytotoxic T-cell (CTL) responses
in seronegative volunteers. An attractive way to enhance these
responses would be to target canarypox virus to professional
antigen-presenting cells such as dendritic cells (DCs). We studied (i)
the interaction between canarypox virus and DCs and (ii) the T-cell
responses induced by DCs infected with canarypox virus vectors
containing HIV-1 genes. Mature and not immature DCs resisted the
cytopathic effects of canarypox virus and elicited strong effector
CD8+ T-cell responses from chronically infected
HIV+ individuals, e.g., cytolysis, and secretion of gamma
interferon (IFN-
) and 
-chemokines. Furthermore, canarypox
virus-infected DCs were >30-fold more efficient than monocytes and
induced responses that were comparable to those induced by vaccinia
virus vectors or peptides. Addition of exogenous cytokines was not
necessary to elicit CD8+ effector cells, although the
presence of CD4+ T cells was required for their expansion
and maintenance. Most strikingly, canarypox virus-infected DCs were
directly able to stimulate HIV-specific, IFN--secreting CD4 helper
responses from bulk as well as purified CD4+ T cells.
Therefore, these results suggest that targeting canarypox virus vectors
to mature DCs could potentially elicit both anti-HIV CD8+
and CD4+ helper responses in vivo.
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INTRODUCTION |
Current antiviral treatments
consisting of highly active antiretroviral therapy (HAART) have made a
major impact on reducing mortality due to human immunodeficiency virus
(HIV) infection (39). However, HAART does not reduce viral
loads in all patients (43), and even in patients with no
detectable plasma viremia, latent reservoirs of HIV persist for
prolonged periods (10, 23, 24, 25, 28, 59, 61). Recent
studies estimate that more than 60 years of HAART would be required to
eradicate the virus in the latent reservoirs (9). As
antiviral drugs are too expensive to be widely used in developing
countries, the development of anti-HIV vaccines is of great urgency.
There is strong evidence supporting a role of cytotoxic T lymphocytes
(CTLs) in the containment of HIV replication. In early HIV infection,
the appearance of CTLs correlates with control of viremia and reduction
of symptoms (34). In chronic infection, major
histocompatibility complex (MHC) tetramer studies show an inverse
correlation between CTL effectors and low viral loads (40). In late infection, the loss of anti-HIV CTL
responses correlates with higher viral loads and progression of disease (32). Individuals with multiple exposures to HIV but who
remain uninfected show anti-HIV CTL responses in some cases
(47). Finally, CD8+ CTLs have been shown to be
critically involved in the control of simian immunodeficiency virus in
macaques, the best model of HIV infection in humans (29,
49).
HIV-specific CD4+ T cells also contribute to immune
resistance toward HIV. Individuals who maintain a very low viral load
and do not progress to disease have vigorous HIV-specific
CD4+ T-cell responses (44, 46), along with
strong and broad anti-HIV CTL responses (31). Further
studies have supported an association between robust HIV type 1 (HIV-1)-specific CTLs and strong helper cell responses (30,
58). A drop in HIV-specific CD4+ T cells leads to a
decline in anti-HIV CTL levels and more rapid disease progression
(31, 44, 46). Presumably, effective anti-HIV vaccines will
need to elicit CD4+ helper as well as CD8+ CTL
responses in order to maintain effective CTL function.
Several approaches are being taken to elicit anti-HIV CTL responses
using vaccine formulations (reviewed in reference 37). A
promising approach entails canarypox virus vectors. Canarypox virus
undergoes abortive replication in mammalian cells (42, 55). Recombinant genes are controlled by early promoters in canarypox virus and expressed before the block in replication (42, 55). Canarypox vaccines have an excellent safety
profile in phase 1 trials, and their effectiveness against a variety of infectious agents has been demonstrated in both animals and humans (42, 54). Canarypox virus vectors containing HIV-1 genes
(can-HIV vectors) have been reported to elicit specific CTL responses
in uninfected volunteers when administered intramuscularly (5, 11, 17, 19, 21, 22). However, the responses have been intermittent and inconsistent, sometimes requiring the addition of
cytokines in vitro for detection (26). To increase the
magnitude and durability of these responses, it may be critical to
target these vectors to potent antigen-presenting cells (APCs), namely, dendritic cells (DCs) (4, 51).
In this study, we characterized the interaction between canarypox virus
and DCs at different stages of their development. We found that mature
DCs infected with can-HIV stimulated IFN-- and
-chemokine-producing and cytolytic CD8+ effector cells
in vitro from chronically infected individuals. These responses, which
are induced only by DCs and not other APCs, were readily detectable in
the absence of repetitive stimulation or exogenous cytokines.
Strikingly, canarypox virus-infected DCs also expanded HIV-specific
CD4+ T cells in culture. These CD4+ T-cell
responses were essential for the development of anti-HIV CD8+ CTLs. Our results reveal for the first time that
canarypox virus has the potential to stimulate both CD4+
and CD8+ arms of the anti-HIV immune response. They support
the use of canarypox virus as a vaccine vector which has the potential
to elicit virus-specific CD4+ T-cell help for the induction
and maintenance of CTL responses to HIV-1.
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MATERIALS AND METHODS |
Culture medium.
RPMI 1640 medium with 10 mM HEPES, 5 mM
L-glutamine, 20 µg of gentamicin per ml, and 1% human
plasma, 5% heat-inactivated human serum, or 10% fetal calf serum was used.
Human subjects.
Patients, recruited through the Rockefeller
University clinical research center, signed informed consents approved
by the Institutional Review Board. All nine individuals were 37- to
47-year-old males chronically infected with HIV-1 (duration of
infection ranged from 4 to 9 years) who had CD4 counts ranging from 75 to 633/µl and plasma viremia levels which ranged from undetectable to
192 × 103/ml by the Roche Ultrasensitive PCR kit. Six
of the nine individuals were on HAART, and two were on therapy
intermittently due to noncompliance. Seronegative individuals served as
controls. Three patients expressed HLA A*0201.
APCs.
Buffy coats from uninfected individuals or 60 to 80 ml
of blood from HIV-1+ patients were sources of peripheral
blood mononuclear cells (PBMCs). Mononuclear cells, enriched or
depleted of T cells, were obtained by rosetting PBMCs with
neuraminidase-treated sheep erythrocytes (6). Immature DCs
were generated from the T-cell-depleted fractions after supplementation
with recombinant human interleukin-4 (IL-4 1,000 U/ml; Schering Plough
Corporation, Kenilworth, N.J.) and recombinant human
granulocyte-macrophage colony-stimulating factor (GM-CSF; 100 IU/ml;
Immunex Corporation, Seattle, Wash.) every other day. To generate
mature DCs, nonadherent immature DCs were transferred to new plates on
day 6 and incubated for 2 days in monocyte conditioned medium (MCM;
50%, vol/vol) prepared as previously described (7).
HIV-negative donors were used as a source of monocytes for preparing
the MCM.
Virus stocks.
The recombinant WR vaccinia viruses used were
vP1170 WR-eco gpt (parental), vP1287 gag(IIIB), vP1288 pol(IIIB),
vP1218 nef(MN), and vP1286 env gp120 TM(MN), containing HIV-1 clade B
gag, pol, nef, and env genes. Canarypox virus
vectors were ALVAC (parental) and vCP300 encoding HIV-1 gp120(MN) and
transmembrane anchor regions of gp41(LAI), Gag(LAI), and protease(LAI);
Pol(LAI) CTL domains (residues 172 to 219, 325 to 383, and 461 to 519);
and Nef(BRU) CTL domains (residues 66 to 147 and 182 to 206). Canarypox
virus (5 to 10 PFU/cell or vaccinia virus (1 to 2 PFU/cell) was used to
infect APCs. James Tartaglia and William I. Cox (Virogenetics Corporation, Troy, N.J.) provided the titered doses of virus stocks.
Fluorescence-activated cell sorting (FACS) analysis.
Monoclonal antibody (MAb) 183, directed to HIV p24 protein, was kindly
provided by Melissa Pope. Phycoerythrin (PE)-conjugated HLA DR, CD14,
CD25, and isotype-matched controls (Becton Dickinson, Montainview,
Calif.), CD86 (PharMingen, San Diego, Calif.), CD83 (Immunotech,
Coulter Corporation, Hialeah, Fla.), and PE-conjugated goat anti-mouse
immunoglobulin G (IgG; TAGO, Burlingame, Calif.) were used for
phenotyping. For surface staining, cells were phenotyped with the above
panel of MAbs using a FACScan. For intracellular staining, cells were
fixed with 4% paraformaldehyde and permeabilized with 1% saponin
(6). Antibody to HIV p24 protein was added for 30 min,
cells were washed, and secondary PE-conjugated goat-anti mouse IgG was
added for 30 min prior to FACScan analysis.
Viability.
In addition to trypan blue exclusion, apoptosis
and necrosis were assessed by staining with fluorescein isothiocyanate
(FITC)-annexin V and propidium iodide, using an Early Apoptosis
detection kit (Kayima Biomedical Company, Seattle, Wash.).
IFN- ELISPOT assays.
PBMCs, monocytes, or DCs were
infected with poxviruses, and IFN- enzyme-linked immunospot
(ELISPOT) assays were carried out as described elsewhere
(35). In brief, poxvirus-infected or uninfected cells were
added together with T cells (1 × 105 to 2 × 105/well) to 96-well plates precoated with IFN- antibody
(Mabtech, Stockholm, Sweden) for 16 to 24 h. After washing, a
second biotinylated anti-IFN- antibody (Mabtech) was added followed
by avidin-bound biotinylated horseradish peroxidase H (Vector
Laboratories, Burlingame, Calif.) to develop the spots. ELISPOT assays
were also used to assess the expansion of antigen-specific T cells over
time. T cells were cocultured for 7 days with DCs infected with
canarypox virus control (can-ctl) or can-HIV. ELISPOTs were then
elicited in responding T cells by restimulation with antigen-pulsed
APCs. The latter consisted of monocytes infected with vaccinia virus or
canarypox virus vectors or pulsed with 5 µg of either HIV p24 or
control protein (Protein Science, Meriden, Conn.) per ml. T cells and
monocytes were used at a ratio of 1:1. Cells stimulated with
phytohemagglutinin were used as a positive control, and T cells, DCs,
or monocytes alone were negative controls. Responses were counted as
positive if a minimum of 10 spot-forming cells (SFC) per 2 × 105 cells were detected after the control was subtracted,
and if the numbers of spots were at least twice those in the negative control wells.
RANTES detection.
DCs were infected with either can-ctl or
can-HIV and cocultured with autologous T cells at a DC-to-T cell (DC:T)
ratio of 1:30. After 6 to 7 days, the supernatants of cultures with
HIV-specific CTLs were tested for RANTES using an enzyme-linked
immunosorbent assay (ELISA) kit (R & D Systems, Minneapolis, Minn.).
CTL induction.
Monocytes and mature DCs (107
cells/ml) were infected with can-ctl (ALVAC) or can-HIV (vCP300) at a
multiplicity of infection (MOI) of 10, or infected with vaccinia virus
at MOIs of 1 to 2.5, for 1 h at 37°C. The cells were washed
twice and added to enriched T cells. Where indicated, DCs were pulsed
with the HLA A*0201-restricted Pol peptide ILKEPVHGV (10 µg/ml) for
2 h at room temperature. The T-cell-enriched fraction was obtained
from sheep erythrocyte rosetted cells by depletion of NK cells with
anti-CD56 (PharMingen) and sheep anti-mouse magnetic beads (Dynal, Lake
Success, N.Y.). In some experiments, T cells were further purified into
CD8+ and CD4+ T-cell fractions using magnetic
beads (Miltenyi Biotech, Auburn, Calif.); 2 × 106
T-cells were cultured with APCs at a ratio of 10:1 (unless otherwise indicated) in 24-well plates for 7 days.
Chromium release assay.
After 7 days, effector cells in the
DC-T cell cocultures were harvested, counted, and plated in graded
doses in 96-well plates. B-lymphoblastoid cell lines (BLCLs) generated
from each patient served as targets. The BLCLs were infected with
recombinant vaccinia virus vectors as described above and incubated
with 4 µCi of Na51CrO4 for 1 h.
Alternatively, T2, an HLA A*0201+ class II
and transporter-associated protein (TAP)-deficient cell line, was used
as a target. T2 cells were pulsed with the HLA A*0201-restricted influenza virus matrix peptide GILGFVFTL (negative control peptide) or
HLA A*0201-restricted HIV-1 Gag SLYNTVATL and Pol ILKEPVHGV peptides
at 10 µg/ml for 1 h and then labeled with
Na51CrO4 as described above. Target cells were
added to effector cells at effector-to-target cell (E:T) ratios of 30:1
to 10:1. After 5 to 6.5 h, the assay mixtures were harvested. Two
steps were taken to calculate HIV-1 antigen-specific lysis. We first
calculated the percent specific lysis for each stimulating APC
population (e.g., can-ctl- or can-HIV-infected DCs) using the formula
(ER 
SR)/(TR SR), where ER represents the release in the
experimental sample, SR is spontaneous release, and TR is total
release. We then deducted any nonspecific lysis obtained with DCs
pulsed with control vectors or peptides from that obtained by DCs
pulsed with HIV-1 antigen-expressing vectors or peptides. This value is
referred to as HIV antigen-specific lysis.
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RESULTS |
Interactions of canarypox virus vectors and DCs.
In previous
studies we found that poxvirus vectors profoundly affected DC function
(18). For example, vaccinia virus induces extensive
apoptosis of immature DCs, inhibits their maturation, and diminishes
their T-cell-stimulating capacity. In contrast, mature DCs are
relatively resistant to these adverse outcomes. Therefore, we
investigated the consequences of canarypox virus infection on DCs in
terms of cytopathicity, maturation effects, and extent and durability
of HIV protein expression.
We first compared the effects of canarypox virus infection on DC
viability at two distinct stages of development. Immature DCs, akin to
tissue resident DCs, can be derived in vitro from monocytes following
culture in GM-CSF and IL-4. These APCs are highly efficient at antigen
capture but far less able to activate T cells (4). Mature
DCs are generated from immature DCs after the addition of maturation
stimuli such as a MCM, lipopolysaccharide or CD40 ligand (CD40L).
Following maturation, DCs downregulate antigen capture, upregulate MHC
and costimulatory molecules, express the maturation-associated markers
CD83 (62) and DC-LAMP (14), and acquire
potent T-cell-stimulating capacity (4). We infected either
immature or mature DCs with can-HIV or can-ctl. In the former case, the
immature DCs were exposed to MCM immediately after infection to induce
maturation. If the DCs were immature at the time of infection, there
was a rapid and significant decrease in viability as assessed by trypan
blue exclusion. The effect was more rapid than with vaccinia virus,
apparent after only 1 day postinfection (Fig.
1A).
Mature DCs resisted the cytopathic effect to a great extent, as in the case of vaccinia virus
(18). To analyze the mechanism of cytopathicity, DCs were
stained with FITC-annexin V, a marker of early apoptosis (33,
56), and propidium iodide. Up to 60% of infected immature DCs
were already apoptotic or dead at 1 day postinfection, compared to only
15 to 20% infected mature DCs, when one discounts uninfected control values (Fig. 1B). The apoptotic effect was clearly induced by canarypox
virus and not HIV genes, as we used the parental vector for these
experiments. Furthermore, similar results were obtained with can-HIV.
Unlike vaccinia virus, canarypox virus did not inhibit DC maturation
when MCM was added to canarypox virus-infected immature DCs (data not
shown).
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FIG. 1.
Interaction of recombinant poxvirus with DCs. (A)
Immature and mature DCs were uninfected or infected with vac-gag (MOI
of 2) or can-HIV (MOI of 10). The immature DCs were exposed to MCM
immediately following infection. The percentage of live cells, as
determined by trypan blue exclusion, is shown in immature DCs plus MCM
(left) and mature DCs (right) at different time points after infection.
The mean and standard error of three experiments are shown. (B)
Immature DCs were uninfected or infected with canarypox virus, after
which MCM was added. Mature DCs were infected or uninfected in like
manner. At multiple time points after infection, the extent of
apoptosis and necrosis was determined by staining the cells with
FITC-annexin V (An.V) and propidium iodide (PI). Results shown are
representative of three experiments. (C) Immature and mature DCs were
uninfected or infected with vac-gag (MOI of 2) or can-HIV (MOI of 10)
as for panel A; 24 h later, the cells were permeabilized and
stained with a MAb against HIV-1 p24 protein. Anti-IgG1 antibody was
the isotype control used to set the horizontal limit of background
staining. The gates were set to exclude dead cells. One representative
experiment of eight is shown. In panels B and C, the y axis
is set on a logarithmic scale and the percentages of cells are
indicated in the corresponding gates.
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We next compared the levels of HIV-1 protein expression in DCs
following infection with can-HIV and a vaccinia virus construct
containing the
gag gene (vac-gag). As above, we infected
either
immature or mature DCs, and in the former case, the immature DCs
were exposed to MCM immediately after infection to induce maturation.
The cells were stained to detect p24 expressed by the
gag
gene
as a measure of the degree of infection (Fig.
1C; Table
1). Vaccinia
virus vectors encoding
Gag induced higher frequencies of p24
+ cells in
immature DCs (67% ± 21%) and mature DCs (44% ± 20%)
compared to
can-HIV (15% ± 11% in immature DCs and 7% ± 6% in
mature DCs).
Maturation reduced the frequency of p24-expressing
DCs, consistent with
our previous observations that mature DCs
are generally more resistant
to poxvirus infection. Nevertheless,
p24 expression in mature DCs was
sustained over 3 days in culture
(data not shown). We found MOIs of 5 to 10 to be optimal for canarypox
virus-induced recombinant protein
expression. Lower doses (MOIs
of 1 to 2) resulted in even lower levels
of p24 expression, whereas
higher doses did not increase the levels
significantly but compromised
viability (not shown). These data are
consistent with our recent
studies of vaccinia viruses
(
18).
Although only low frequencies of mature DCs were infected with
canarypox virus, their resistance to the virus's cytopathic
effects,
sustained protein expression, and potency as stimulators
of T-cell
responses prompted us to use them for all subsequent
experiments.
Mature DCs, but not monocytes, induce strong HIV-1-specific
CD8+ responses following infection with canarypox
virus.
To ascertain whether canarypox virus-infected mature DCs
could present HIV antigens to CD8+ T cells, we took
advantage of a cohort of nine chronically infected HIV-1 individuals
who had been previously characterized in our laboratory (see Materials
and Methods). Patients were screened for HIV-specific CD8+
T-cell responses in fresh PBMCs by ELISPOT assay using vaccinia virus
vectors encoding HIV genes (35). All individuals had
responses to antigens derived from Pol, four had responses to both Pol
and Gag antigens, and one had responses to antigens derived from Gag, Pol, Env, and Nef. The number of HIV-specific CD8+ T cells
ranged from 20 to 225 in 200,000 PBMCs, i.e., an HIV-1 antigen-specific
frequency of 1 in 600 to 10,000 PBMCs. We prepared DCs and monocytes
from each of these individuals, infected them with can-HIV or can-ctl,
and cocultured them with autologous T cells. The development of
HIV-specific CD8+ T-cell responses was assessed by (i)
cytolysis by chromium release assay, (ii) RANTES secretion by ELISA,
and (iii) IFN- production by ELISPOT assay.
Induction of CTL.
We first evaluated CTL responses in an HLA
A*0201+ patient (HVR) with known specificity to the
pol-encoded epitope ILKEPVHGV (35). Mature DCs
from this individual were either untreated or infected with can-ctl or
can-HIV and then added to freshly isolated T cells for 7 days, during
which no exogenous cytokines were added. The responses were compared to
those elicited by DCs pulsed with specific peptide or vaccinia virus
vectors. Effector CTLs were assessed by their cytolytic activity on
51Cr-labeled autologous BLCLs or T2 targets. These were
infected with vaccinia virus vectors or pulsed with HLA
A*0201-restricted peptides, respectively. DCs infected with can-HIV
stimulated peptide-specific responses that were comparable to those
stimulated by DCs pulsed with peptide (28 versus 42% HIV-specific
lysis, respectively, at an E:T ratio of 30:1 [Fig.
2A, top
half). In both cases, the CTLs recognized endogenously presented
antigens, as they lysed BLCL targets infected with vaccinia virus
vectors encoding Pol antigens (26 versus 35% HIV-specific lysis for
peptide versus can-HIV-pulsed DCs, respectively, at an E:T ratio of
30:1 [Fig. 2A, bottom half]). Surprisingly, the responses elicited by
can-HIV-infected DCs were similar in magnitude to those induced by
vac-pol-infected DCs, at least at the higher E:T ratio of 30:1 (Fig.
2B). The vac-pol vector was expected to be superior to canarypox virus
as it infects >40% of DCs and contains the entire pol
gene, while can-HIV contains only specific domains of pol
(see Materials and Methods). In two additional individuals tested,
can-HIV-infected DCs elicited CTL responses that were comparable to
those induced by DCs infected with vaccinia virus vectors (data not
shown).
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FIG. 2.
DCs infected with can-HIV antigens induce CTL
responses. (A) DCs generated from an HLA A*0201+
individual (HVR) were either uninfected, pulsed with the HLA
A*0201-restricted Pol peptide (ILKEPVHGV), or infected with can-ctl
or can-HIV. DCs were coincubated with autologous T cells for 7 days at
DC:T ratios of 10:1, after which effectors were tested for cytolytic
activity. Targets were T2 cells pulsed with an irrelevant influenza
virus matrix peptide (T2 matrix peptide) or with the Pol peptide (T2
Pol peptide), and autologous BLCLs were infected with vac-ctl (BLCL
vac-ctl) or vac-pol (BLCL vac-pol). E:T ratios of 30:1, 10:1 and 3:1,
were tested. (B) DCs from the same individual were infected with
vac-ctl or vac-pol at a MOI of 2 and cocultured with T cells. Cytolytic
activity was measured after 7 days at E:T ratios of 30:1 to 7:1.
Targets were autologous BLCLs infected with vac-ctl or vac-pol.
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Using can-HIV-infected DCs, it was possible to detect significant
HIV-specific CTL responses in five of seven patients tested
by this
assay, and in a reproducible fashion (Table
2). In these
five patients, cytolytic
activity was directed against one or
more HIV antigens. In two patients
(HVJ and HVW) who had demonstrable
HIV-directed responses by ELISPOT
assay, specific CTL activity
was not detected, possibly due to high
background responses to
can-ctl. Notably, HIV-1-specific responses were
not seen in seronegative
volunteers (data not shown).
We next compared the immunostimulatory effect of DCs with a
T-cell-depleted fraction of PBMCs consisting primarily of monocytes.
DCs stimulated strong HIV-specific responses in individual HVR
(62%
specific lysis at an E:T ratio of 30:1 [Fig.
3, top]). These
responses were
maintained even at E:T ratios as low as 3:1 (data
not shown).
Furthermore, significant CTL responses could be elicited
with even few
DCs. For example, at DC:T ratios of 1:100, up to
56% specific lysis
for Pol-derived antigens was obtained (Fig.
3, upper right). In
contrast, monocytes were capable of inducing
HIV-specific CTL responses
only at an APC:T ratio of 1:10 and
only at E:T ratios of 30:1 or
greater (Fig.
3, bottom). Similar
results were obtained with two
additional subjects. Overall, these
results show that DCs are
substantially more potent than monocyte-enriched
populations for the
stimulation of anti-HIV-1 CTLs.
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FIG. 3.
DCs are more potent than monocytes in inducing
anti-HIV-CTLs. DCs or monocytes from individual HVR were infected with
can-ctl or can-HIV and cocultured with autologous T cells at various
APC:T ratios. Cytolytic activity was measured on day 7 using autologous
BLCLs infected with vac-ctl or vac-pol as targets at E:T ratios of 30:1
and 10:1.
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RANTES secretion.
The -chemokines RANTES, MIP-1
, and
MIP-1 are the principal anti-HIV molecules secreted by
CD8+ T cells. These chemokines may inhibit viral entry into
CD4+ cells by binding to CCR5, the coreceptor of
macrophagetropic HIV-1 (12, 57, 60). We measured the
concentration of RANTES in supernatants from 7-day cocultures of T
cells and can-HIV-infected DCs by ELISA. The results shown are from
patient HVC, who was tested on two different occasions (Fig.
4). CD8+ T cells stimulated
with can-HIV-infected DCs produced significant levels of RANTES and
also lysed vac-gag-infected BLCLs (Table 2). In contrast,
can-ctl-infected DCs failed to induce significant levels of RANTES or
HIV-specific CTL activity. Similar data were obtained with two other
patients (not shown). These data suggest that -chemokine secretion
correlates with the induction of HIV-specific CD8+ T-cell
responses by canarypox virus-infected mature DCs.
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FIG. 4.
Can-HIV-infected DCs elicit RANTES secretion. DCs from
individual HVC were infected with can-ctl or can-HIV and cocultured
with autologous T cells at an APC:T ratio of 1:30. After 6 to 7 days,
HIV-specific cytolytic responses were obtained (Table 2), and the
supernatants of such cultures were tested for the presence of the
-chemokine RANTES using an ELISA kit (R&D).
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IFN- production.
IFN- is a key antiviral cytokine
produced by CD8+ effector cells. We determined whether
can-HIV-infected DCs could elicit IFN--producing CD8+ T
cells from freshly isolated T cells of chronically infected individuals. In all of five subjects tested by ELISPOT assay, DCs
induced significant levels of HIV-specific, IFN--producing SFC
within 24 h (range, 190 to 1,210 SFC/106 T cells at a
DC:T ratio of 1:10 [Fig. 5A]). The
responses were up to sixfold greater in magnitude than those induced by
can-HIV-infected PBMCs, where primarily monocytes comprise the APCs (up
to 30% of the PBMC fraction [35]).
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FIG. 5.
Can-HIV-infected DCs elicit and expand IFN--secreting
cells. (A) Mature DCs from four HIV-1+ individuals were
infected with can-ctl or can-HIV and added to freshly sampled
autologous T cells at DC:T of 10:1. IFN- SFC were enumerated after
24 h by ELISPOT assay. (B) Cocultures of T cells and canarypox
virus-infected DCs or monocytes from individual HVR were allowed to
expand for 7 days. IFN- was then induced in the responding T cells
by exposure to autologous monocytes uninfected or infected with can-ctl
or can-HIV. uninf, uninfected. (C) T cells and canarypox virus-infected
DCs from individual HVJ were cultured for 7 days. IFN- was then
induced in the responding T cells by exposure to autologous monocytes
uninfected or infected with can-ctl, can-HIV, vac-ctl, or vac-pol. In
panels B and C, monocytes or T cells alone were additional controls,
and these values were subtracted from experimental values.
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Importantly, can-HIV-infected DCs also successfully expanded
HIV-specific IFN-
-producing T cells over several days of culture
without the addition of exogenous cytokines. A representative
example
of seven experiments is shown in Fig.
5B. T cells from
individual HVR
were cocultured with can-HIV-infected DCs and tested
for specificity on
day 7 by ELISPOT assay. Specificity for HIV-1
antigens was assessed
by restimulating the T cells for 24 h with
autologous monocytes
infected with can-ctl or can-HIV. One-day
restimulation by
poxvirus-infected APCs induces IFN-
production
from CD8
+
T cells and not CD4
+ T cells (
35). At least a
two- to threefold increase in HIV-specific
SFC number was evident by
this recall assay (compare HVR data
in Fig.
5A and B). Although
can-ctl-infected DCs induced significant
numbers of SFCs compared to
uninfected DCs, no HIV-specific responses
were elicited by these cells.
In contrast to DCs, monocytes failed
to expand HIV-specific
IFN-
-producing CD8
+ T cells over 7 days (Fig.
5B).
We next applied the recall ELISPOT assay to identify HIV-specific
responses in individuals in whom CTL responses were not
detected. For
example, subject HVJ had a previously characterized
Pol-specific
CD8
+ T-cell response by overnight ELISPOT assay, but we
could not
elicit HIV-specific cytolytic activity when his T cells were
stimulated
with can-HIV-infected DCs (Table
2). However, when recall
ELISPOT
assays were used, we were easily able to visualize the
expansion
of HIV-specific CD8 effectors from this individual. The
responding
cells also included Pol-specific effectors since they could
be
stimulated with vac-pol-infected monocytes (Fig.
5C). Thus, this
assay allows one to detect specific responses that may be obscured
in
CTL assays. This disparity between different assays may be
due to high
cytolytic backgrounds from nonspecific NK cell responses.
Alternatively, this subject may have HIV-specific CD8
+ T
cells that produce antiviral cytokines but are impaired in
cytolytic
function (
2).
In summary, can-HIV-infected mature DCs have the capacity to elicit
strong anti-HIV CD8
+ effector cells which are characterized
by their production of
IFN-
,
chemokines, and cytolytic
activity.
Expansion of CD8+ effectors by canarypox virus requires
CD4+ T-cell help.
We next assessed whether
CD4+ T cells were required for expanding HIV-specific
CD8+ effector cells by canarypox virus. We chose to study
individual HVP, who was previously shown to have Gag-specific
CD4+ and CD8+ T cells (Table 2). Bulk or
CD4-depleted T cells were cocultured with canarypox virus-infected DCs
for 7 days. The expansion of Gag-specific CD8+ effector
cells was monitored by ELISPOT assay after restimulation with
vac-gag-infected monocytes (Fig. 6A) and
by cytolytic assay (Fig. 6B). As expected, bulk T cells developed into
IFN--secreting and cytotoxic cells. In contrast, CD4-depleted T
cells had substantially reduced HIV-specific CD8+ T-cell
responses (Fig. 6 A and B, middle). Adding exogenous cytokines in the
form of lymphocult to the CD8+ T cells did not restore the
HIV-specific expansion observed with the bulk T-cell populations. Taken
together, these results suggest that mature DCs infected with can-HIV
require the presence of CD4+ T cells to induce strong
HIV-specific CD8+ effector responses. The results are
representative of three subjects studied.
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 6.
CD4 helper cells are necessary to induce HIV-specific
CD8+ T-cell responses. Bulk and CD4-depleted T cells
(>98% pure CD8+ T cells by FACS analysis) from individual
HVP were cocultured with DCs infected with can-ctl or can-HIV.
Exogenous cytokines in the form of lymphocult was added to some of the
cocultures of CD8+ T cells and DCs. After 7 days,
IFN--producing cells were elicited by restimulation with vaccinia
virus-infected monocytes. T-cell cultures from panel A were also tested
for cytolytic activity on autologous BLCLs infected with vac-ctl or
vac-gag (B) or for p24 reactivity by reexposure to monocytes pulsed
with p24 or control protein (C).
|
|
Based on the above data, we surmised that can-HIV-infected DCs must
expand HIV-specific CD4
+ T cells in addition to
CD8
+ T cells. To test this possibility, bulk or
CD4-depleted T cells
from the Gag responder HVP were cocultured with
DCs infected with
either can-ctl or can-HIV for 7 days (Fig.
6C). The T
cells were
then restimulated for 24 h with autologous monocytes
that had
been pulsed with either recombinant p24 or control proteins.
By
using whole protein preparations in the place of poxvirus vectors,
we stimulated CD4
+ rather than CD8
+ T cells.
Responding IFN-
-producing T cells were enumerated by
ELISPOT assay.
Importantly, p24-specific T cells were detectable
only in bulk T-cell
populations. As expected, depletion of CD4
+ T cells before
stimulation with can-HIV-infected DCs abrogated
the response to p24
antigen. Addition of cytokines to the CD4-depleted
T-cell population
restored some, albeit low, p24-specific responses,
possibly by
expanding the few contaminating CD4
+ T cells. Altogether,
these results suggest that can-HIV has the
capacity to expand
antigen-specific CD4
+ T cells while it is simultaneously
expanding CD8
+ T cells, and that this expansion is
essential for the development
of the CD8 effector
response.
Canarypox virus-infected DCs directly stimulate and expand
HIV-specific CD4+ T cells.
To formally prove that
CD4+ T cells could be directly expanded by canarypox virus,
we purified CD4+ T cells from selected subjects
and cocultured them with can-HIV-infected DCs. Bulk and purified
CD8+ T cells were compared alongside. At day 0, we detected
significant responses in bulk and purified CD8+ T-cell
populations by ELISPOT assay (50 and 220 SFC/106
cells, respectively). In contrast, no significant responses were detected in the CD4+ T-cell population (10 SFC/106 T cells) (Fig. 7A).
This is because canarypox virus, like vaccinia virus, induces
IFN- production primarily from CD8+ T cells in the
first 24 h of T cell-APC cocultures (35).
View larger version (15K):
[in this window]
[in a new window]
|
FIG. 7.
DCs infected with canarypox virus expand
CD4+ T cells. Bulk, CD4+ and CD8+ T
cells from individual VHK were cocultured with DCs that were infected
with can-ctl or ctl-HIV. IFN--producing cells were enumerated after
16 h by ELISPOT assay (A) or 7 days after restimulation with monocytes
pulsed with p24 protein, control protein, can-ctl or can-HIV (B).
HIV-specific values were determined after deducting values for control
protein or control vectors.
|
|
However, after 7 days of stimulation with can-HIV-infected DCs, high
numbers of HIV-specific CD4
+ cells could be expanded from
both bulk and CD4
+ T-cell fractions (2,200 and 5,750 SFC/10
6 T cells). The expansion was measured by
restimulating the T cells
with p24-pulsed monocytes in an ELISPOT
assay; as expected, p24-pulsed
monocytes failed to stimulate IFN-
production from purified CD8
+ T cells (Fig.
7B).
Poxvirus-pulsed monocytes (either can-HIV
or vac-pol) induced responses
only from bulk cultures of T cells,
not purified CD4
+ and
CD8
+ T cells. This is consistent with the interpretation
that CD8
+ T cells require CD4
+ T cells to
expand and develop into effector cells. Data are representative
of
three
experiments.
In summary, our results confirm that canarypox virus directly
stimulates HIV-specific CD4
+ T cells in addition to CTL
precursors. To our knowledge, this
is the first illustration of this
vector's ability to stimulate
CD4
+ helper cell responses.
Our results also demonstrate that the
activation of antigen-specific
CD4
+ T cells, unlike that of CD8
+ T cells,
requires more than 24 h of exposure to canarypox virus-derived
antigens.
| |
DISCUSSION |
In this study we describe the interaction between DCs and
canarypox virus, and we evaluate the ability of canarypox
virus-infected DCs to elicit antigen-specific T-cell responses from
chronically infected HIV-1+ individuals with known
CD8+ T-cell reactivity to HIV-1 antigens. We chose to study
mature DCs rather than immature DCs, since they resisted the cytopathic outcome of infection, expressed HIV-1 antigens for sustained periods, and maintained their mature phenotype and function. In all of the
HIV-1+ individuals studied here, we successfully elicited
CD8+ effector responses using DCs infected with canarypox
virus encoding HIV antigens. These reproducible responses consisted of
IFN- production within 16 h of stimulation, release of
antiviral chemokines (RANTES), and/or cytotoxic activity against
targets expressing HIV antigens. There was a clear correlation between
(i) antigenic specificity between IFN- production by vaccinia
virus-infected PBMCs and (ii) cytokine secretion and cytolytic
activity of T cells stimulated by canarypox-infected DCs. For example,
patients HVR, HVP, and HVC showed strong responses to Pol, Gag, and
Nef, respectively, in all assays (Table 2; Fig. 2 and 4).
Despite the low frequency of canarypox virus infection, mature DCs
presented HIV antigens derived from can-HIV comparably to
HLA-restricted peptides and, where tested, even antigens derived from
vaccinia virus vectors. This ability of mature DCs to stimulate strong
CTL responses with small amounts of foreign protein has been observed
with heat-inactivated influenza virus and inactivated Epstein-Barr
virus (6, 53). Moreover, when DCs cross-present antigens
from apoptotic cells, as few as 1 to 10 apoptotic cells charge 100 DCs
efficiently (1). Mature DCs infected with canarypox virus
were up to 30 times more potent than monocyte-enriched cells in
stimulating anti-HIV CD8+ CTL responses, suggesting that
mature DCs are far superior APCs to be targeted in a vaccine
formulation. The low levels of stimulatory capacity seen with monocytes
may have been dependent on residual DCs in the monocyte preparations.
We have found that monocytes, when used at high APC:T ratios, have the
capacity to stimulate antigen-specific IFN- production from
CD8+ T cells in short-term ELISPOT assays using bulk T
cells. However, unlike mature DCs, they fail to induce the expansion
and full differentiation of CD8+ T cells into
cytokine-secreting and cytolytic effector cells (Fig. 3 and reference
36).
HIV-specific cytolytic responses were detected in five of seven
individuals studied by this assay. In the remaining two subjects, we
were unable to detect specific cytolysis. However, in recall ELISPOT
assays, can-HIV-infected DCs readily expanded antigen-specific CD8+ effector cells from these individuals. It is possible
that these individuals have HIV-specific CD8+ T cells which
lack cytolytic activity secondary to diminished perforin responses
(2). As all patients in the cohort were more than 30 years
old, they were likely to have been vaccinated against smallpox, and it
is known that responses to vaccinia virus are long lived even in
HIV-infected individuals (13). In prior canarypox vaccine
studies, control vectors were not used at the stimulation level to
monitor responses in vitro (5, 11, 17, 19, 21, 22, 48).
Our study emphasizes that it is critical to use control vectors to
establish the specificity of HIV-specific responses.
An important finding was the requirement for CD4 help to expand
antigen-specific CD8+ T cells in response to
can-HIV-infected DCs. As canarypox virus induces relatively low protein
expression in DCs, there may be insufficient quantities of processed
peptide antigens to directly expand CD8+ T cells. CD4 help,
in the form of CD40-CD40L interactions which prolong DC viability and
induce IL-12 production, would ensure activation of the antiviral CTL
response (3, 8, 27, 45, 50, 52). Additional help could
come from TRANCE-RANK interactions, which are known to be critical for
antiviral responses in animal models (3, 27). The source
of help was likely to be HIV-specific CD4+ T cells expanded
by canarypox virus-infected DCs, as the addition of nonspecific help in
the form of exogenous cytokines failed to restore anti-HIV responses in
purified CD8+ T cell populations.
The requirement for antigen-specific CD4+ T cells to expand
CD8+ T cells was verified by demonstrating that canarypox
virus-infected DCs directly activated p24-specific responses from
purified CD4+ T cells. This activation was not evident at
early time points in either bulk or CD4+ T-cell populations
(i.e., in 24-h ELISPOT assays) but could be detected with 7 days of
stimulation. As antigens from canarypox virus are endogenously derived,
early on following infection antigens may be more accessible to the MHC
class I than the class II pathway. We have previously shown that PBMCs
prepared from chronically infected HIV+ individuals produce
IFN- within 16 to 24 h following infection with canarypox
virus, and the response is almost entirely mediated by CD8+
T cells (35). Therefore, rapid effector function induced
by canarypox virus (as reflected by IFN- production) is likely to be
CD4 independent, but the expansion of cytokine-producing and cytotoxic
CD8+ T cells, perhaps from true memory T cells, is
critically dependent on antigen-specific CD4 helper cells. To our
knowledge these experiments provide the first evidence that avipox
virus vectors, when targeted to DCs, can simultaneously stimulate and
expand antigen-specific CD4+ and CD8+ T cells.
CD4+ T cells are critical for the maintenance of antiviral
CD8+ T-cell immunity, and data are now emerging to support
a correlation between strong helper cell and CD8+ T-cell
function in HIV-1-infected individuals (46). Therefore, our observations further validate the use of canarypox virus as a
vaccine vector for HIV-1 infection.
Two additional important observations were made in this study. We found
that mature DCs could induce IFN--producing CD8+ T cells
and recall CTL responses in the absence of repetitive stimulation or
cytokines, which are traditionally used to expand HIV-specific
CD8+ effector cells in vitro. Prior studies have shown that
canarypox virus-infected PBMCs can activate anti-HIV-1 cytolytic
effectors (21). However, the canarypox virus activation of
CTLs was strictly dependent on cytokines such as IL-2 and IL-7. We also
showed that peptide-pulsed DCs were directly able to elicit CTLs that
recognized endogenously processed HIV antigens. Mature DCs pulsed with
the influenza virus MP peptide can elicit influenza virus CTLs from bulk or purified CD8+ T-cell populations in vitro
(36) and can dramatically boost MP-specific effector
function when delivered in vivo to healthy volunteers
(16). These findings, while consistent with the concept that mature DCs can bypass antigen-specific CD4 help because of increased costimulation and enhanced viability and cytokine production, are harder to reconcile with the requirement for CD4 help by canarypox virus. Pulsing the mature DCs exogenously with a high concentration of
peptide may charge sufficient numbers of MHC class I molecules to
directly stimulate CD8+ CTL responses. Alternatively, help
in the form of nonspecific CD4-DC interactions in our cocultures may
have contributed to the development of peptide-specific
CD8+ effector cells. Notably, in the absence of MHC class
II, DCs are unable to prime CTLs to strong antigen in mice
(38). Further studies will be required to determine
whether activation of HIV-specific CD8+ T cells by
peptide-pulsed DCs requires CD4+ T cells.
Our results using poxviruses and DCs to stimulate CD8+
T-cell responses are in contrast to a previous study in which DCs were unable to stimulate CTL responses from T cells of patients with low CD4
counts (20). One possible explanation for this discrepancy is the use of immature preparations of DCs in that study.
Alternatively, since most of the individuals studied here were on
therapy and had low to undetectable levels of plasma viremia, CD4
function may have been relatively intact or partially restored. Indeed, many of our patients had demonstrable p24-specific responses by ELISPOT
assay. Our results suggest that mature DCs presenting antigen from a
canarypox virus vector will successfully expose anti-HIV CTL responses,
provided that some HIV-specific CD4+ T cells exist.
Recombinant canarypox viruses administered intramuscularly have an
excellent safety profile in humans, but their immunogenicity has been
disappointing. Seronegative individuals who have been vaccinated with
ALVAC constructs expressing HIV-1 genes demonstrate intermittent
responses of variable magnitude (48). This may be because
the vectors fail to be acquired by potent APCs such as DCs. Recently we
demonstrated that a subcutaneous injection of antigen-pulsed mature DCs
elicited in healthy volunteers broad T-cell immunity that was sustained
for several months (15). Therefore, mature DCs infected
with recombinant canarypox virus vectors expressing HIV genes could
constitute effective anti-HIV vaccines, given that they elicit both
CD4+ and CD8+ HIV-specific responses. They may
be of greatest therapeutic value if delivered to individuals initiated
on HAART. While acutely infected HIV-1 patients treated early with
HAART can regain HIV-specific CD4+ T-helper responses
(46), CD4+ and CD8+ T-cell
responses decline with prolonged treatment (41, 44). By
targeting canarypox virus vectors to DCs, one could prime or boost
immune responses against HIV which involve helper cells, cytolytic
responses, and release of antiviral factors.
| |
ACKNOWLEDGMENTS |
The first two authors contributed equally to this work.
We thank Judy Adams for graphics and Patrick Haslett for referring
individuals to this study.
This work was supported by grants from the Swedish Medical Research
Council (K98-99PK-12334-02 [M.L.]) and National Institutes of
Health (AI39516 and AI44628 [N.B.]; AI40874 [R.S.]), by a Burroughs Wellcome Fund Clinical Scientist Award (N.B.), and by General Clinical
Research Center grant MO1-RR00102 from the National Center for Research
Resources at the National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: The Rockefeller
University, 1230 York Ave., New York, NY 10021. Phone: (212) 327-8332. Fax: (212) 327-8875. E-mail:
bhardwn{at}rockvax.rockefeller.edu.
| |
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Journal of Virology, March 2001, p. 2142-2153, Vol. 75, No. 5
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.5.2142-2153.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
