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Journal of Virology, December 2000, p. 11173-11180, Vol. 74, No. 23
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
DNA Vaccines Encoding Interleukin-8 and RANTES
Enhance Antigen-Specific Th1-Type CD4+ T-Cell-Mediated
Protective Immunity against Herpes Simplex Virus Type 2 In
Vivo
Jeong-Im
Sin,1
Jong J.
Kim,1
Catherine
Pachuk,2
C.
Satishchandran,2 and
David B.
Weiner1,*
Department of Pathology and Laboratory
Medicine, University of Pennsylvania, Philadelphia, Pennsylvania
19104,1 and WLP, Malvern, Pennsylvania
193552
Received 3 January 2000/Accepted 8 September 2000
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ABSTRACT |
Chemokines are inflammatory molecules that act primarily as
chemoattractants and as activators of leukocytes. Their role in antigen-specific immune responses is of importance, but their role in
disease protection is unknown. Recently it has been suggested that
chemokines modulate immunity along more classical Th1 and Th2
phenotypes. However, no data currently exist in an infectious challenge
model system. We analyzed the modulatory effects of selected chemokines
(interleukin-8 [IL-8], gamma interferon-inducible protein 10 [IP-10], RANTES, monocyte chemotactic protein 1 [MCP-1], and
macrophage inflammatory protein 1
[MIP-1]) on immune phenotype and protection against lethal challenge with herpes simplex virus type
2 (HSV-2). We observed that coinjection with IL-8 and RANTES plasmid
DNAs dramatically enhanced antigen-specific Th1 type cellular immune
responses and protection from lethal HSV-2 challenge. This enhanced
protection appears to be mediated by CD4+ T cells, as
determined by in vitro and in vivo T-cell subset deletion. Thus, IL-8
and RANTES cDNAs used as DNA vaccine adjuvants drive antigen-specific
Th1 type CD4+ T-cell responses, which result in reduced
HSV-2-derived morbidity, as well as reduced mortality. However,
coinjection with DNAs expressing MCP-1, IP-10, and MIP-1 increased
mortality in the challenged mice. Chemokine DNA coinjection also
modulated its own production as well as the production of cytokines.
These studies demonstrate that chemokines can dominate and drive
immune responses with defined phenotypes, playing an important role in
the generation of protective antigen-specific immunity.
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INTRODUCTION |
The initiation of immune or
inflammatory reactions is a complex process involving the coordinated
expression of costimulatory molecules, adhesion molecules,
cytokines, and chemokines. In particular, chemokines are
important in the molecular regulation of trafficking of immune
cells to the peripheral sites of host defenses. The chemokine
superfamily consists of two subfamilies based upon the presence ( family) or absence (
family) of a single amino acid sequence
separating two cysteine residues (1, 2, 30, 36, 47). These
chemokines have been shown to induce direct migration of various immune
cell types, including neutrophils, eosinophils, basophils,
and monocytes (1, 2, 30, 36, 47). Recently, the
-chemokine family (CXC type), interleukin-8 (IL-8) and gamma interferon (IFN-
)-inducible protein 10 (IP-10), and the
-chemokine family (CC type), RANTES (regulated on activation, normal
T-cell expressed and secreted), monocyte chemotactic protein 1 (MCP-1), and macrophage inflammatory protein 1 (MIP-1), have been shown to
chemoattract T lymphocytes and alter cytokine production from T cells
(4, 12, 17, 19, 48). In particular, RANTES chemoattracts
unstimulated CD4+/CD45RO+ memory T cells and
stimulated CD4+ and CD8+ T cells (24, 27,
37, 46). MIP-1 and MCP-1 also stimulate Th1 or Th2 type
cytokine production from T cells (13, 46). Recent studies
support the notions that chemokine receptors mark T-cell subsets and
that chemokines may be involved in the generation of
antigen-specific immune responses (14, 35).
In this study, we reasoned that we could utilize the DNA vaccine model
to investigate whether chemokines could modulate immune responses and
then impact protection from herpes simplex virus type 2 (HSV-2)
challenge in a defined mouse model system. To investigate the
modulation of immune responses and protective immunity, we codelivered
a DNA expression construct encoding HSV-2 gD protein with plasmids
encoding selected chemokines, specific-receptor-responsive chemokines (IL-8 and IP-10) and shared-receptor-responsive chemokines (RANTES, MCP-1, and MIP-1). We then analyzed their
modulatory effects on antigen-specific immune induction and protection
from challenge. We observed that coinjection with IL-8 and
RANTES enhanced antigen-specific Th1 type CD4+
T-cell immune responses and protection from HSV challenge. On the other
hand, coinjection with IP-10, MCP-1, and MIP-1 had overall
detrimental effects on protection status. These studies support the
idea that chemokines can modulate important immune responses and
disease progression in a manner reminiscent of cytokines. Significant
immune modulation could be achieved through the use of codelivered
chemokine cDNAs, impacting not just an immune response but also
protection from disease. Furthermore, use of chemokine gene-delivered
adjuvants, in particular IL-8 and RANTES, could be important
in crafting more efficacious vaccines as immune therapies or
contributors to immune therapies for HSV.
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MATERIALS AND METHODS |
Mice.
Female 4- to 6-week-old BALB/c mice were purchased
from Harlan Sprague-Dawley (Indianapolis, Ind.). They were cared for
according to the guidelines of the National Institutes of Health
(Bethesda, Md.) and the University of Pennsylvania IACUC (Philadelphia).
Reagents.
HSV-2 strain 186 (a kind gift from P. Schaffer,
University of Pennsylvania, Philadelphia) was propagated in the Vero
cell line. The DNA vaccine encoding HSV-2 gD protein, pAPL-gD2 (pgD), was previously described (31). The expression vectors
pCDNA3-IL-8, pCDNA3-IP-10, pCDNA3-RANTES, pCDNA3-MCP-1, and
pCDNA3-MIP-1 were previously constructed in our laboratory
(14). Plasmid DNA was produced in bacteria and purified by
double-banded CsCl preparations. Recombinant HSV-2 gD proteins, a
generous gift from G. H. Cohen and R. J. Eisenberg,
University of Pennsylvania, were used as recombinant antigens in these studies.
DNA inoculation of mice.
The quadriceps muscles of BALB/c
mice were injected with gD DNA constructs formulated in 100 µl of
phosphate-buffered saline and 0.25% bupivacaine-HCl (Sigma, St. Louis,
Mo.) via a 28-gauge needle (Becton Dickinson, Franklin Lakes, N.J.).
Samples of various chemokine and cytokine gene expression cassettes
were mixed with pgD plasmid solution prior to injection.
ELISA.
An enzyme-linked immunosorbent assay (ELISA) was
performed as previously described (40, 43). In particular,
for the determination of relative levels of gD-specific immunoglobulin
G (IgG) subclasses, anti-murine IgG1 and IgG2a conjugated with
horseradish peroxidase (HRP) (Zymed, San Francisco, Calif.) were
substituted for anti-murine IgG-HRP. To determine ELISA titers, pools
comprising equal numbers of serum samples for each group were twofold
serially diluted from 1:100 and reacted with gD protein. The titers
were determined as the reciprocals of the highest serum dilutions
showing optical density (OD) values twice as high as that of the
negative control.
Th cell proliferation assay.
The T helper (Th) cell
proliferation assay was performed as previously described (40,
41).
In vitro depletion of CD4+ and CD8+ T
cells.
Splenocytes were reacted with anti-CD4 or anti-CD8
antibodies for 1 h at 4°C, followed by incubation with rabbit
complements for 1 h at 37°C. Cell viability postdepletion was
determined by trypan blue dye exclusion. Two cycles of antibodies plus
complements resulted in depletion of more than 98% of each specific
T-cell subpopulation as determined by fluorescence-activated cell
sorter (FACS) analysis.
In vivo depletion of CD4+ T cells.
One hundred
microliters of anti-CD4 (clone GK1.5) ascites fluid (a kind gift from
N. Chirmule of the University of Pennsylvania) was administered
intraperitoneally (i.p.) as previously described (41).
Antibody treatment resulted in more than 98% depletion of specific
CD4+ T-cell subsets of representative animals over a 3-week
period. Depleted mice were subsequently challenged with virus on day 0.
Th1 and Th2 type cytokines and chemokines.
A 1-ml aliquot
containing 6 × 106 splenocytes was added to the wells
of 24-well plates. Then 1 µg of HSV-2 gD protein/ml was added to each
well. After 2 days of incubation at 37°C in 5% CO2, cell
supernatants were secured and then used for detecting levels of IL-2,
IL-4, IFN-, RANTES, and MCP-1 with commercial cytokine and
chemokine kits (Biosource, Intl., Camarillo, Calif.; R&D Systems, Minneapolis, Minn.) by adding the extracellular fluids to the cytokine-
or chemokine-specific ELISA plates.
i.vag. HSV-2 challenge.
Mice were challenged as previously
described with some modifications (23, 26). Before
inoculation with the virus, the intravaginal (i.vag.) area was swabbed
with a cotton-tipped applicator (Hardwood Products Company, Guilford,
Maine) soaked with 0.1 M NaOH solution and then cleaned with dry cotton
applicators. Mice were then examined daily to evaluate pathological
conditions and survival rates.
Statistical analysis.
Statistical analysis was done with the
paired Student's t test or analysis of variance (ANOVA).
Values for different immunization groups were compared. P
values of <0.05 were considered significant.
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RESULTS |
Selection of chemokines.
Chemokines have been reported to bind
to their own specific receptors for immune cell functions (1,
33). In particular, both CXCR1 and CXCR2 recognize IL-8,
whereas CXCR3 interacts with IP-10. In contrast, four different
chemokine receptors, CCR1, CCR3, CCR4, and CCR5, respond to
RANTES. Similarly, CCR1, CCR4, and CCR5 recognize
MIP-1, while both CCR2 and CCR4 recognize MCP-1. In an effort to
compare differential effects of these specific- or
shared-receptor-responsive chemokines on the induction of
antigen-specific immune responses as well as protective immunity, we
selected the nonshared receptor-specific chemokines IL-8 and IP-10 as
well as the shared-receptor-specific chemokines RANTES,
MIP-1 and MCP-1.
Coadministration of chemokine plasmids influences systemic IgG
production.
We first investigated the in vivo effects of selected
chemokines on the induction of antigen-specific antibody responses. As
shown in Fig. 1A, coinjection with IL-8
and MIP-1 cDNAs resulted in a slight increase in gD-specific
IgG production compared to that with gD plus pCDNA3.
However, coinjection with IP-10, RANTES, and MCP-1 showed
gD-specific IgG production similar to that of gD plus pCDNA3.
Granulocyte-macrophage colony-stimulating factor (GM-CSF)
coinjection used as a control enhanced gD-specific antibody production
significantly more than gD DNA vaccine alone. Figure 1B shows that
ELISA titers of equally pooled sera collected 2 weeks after the
second immunization were determined as 3,200 (for IL-8), 1,600 (for
IP-10), 1,600 (for RANTES), 1,600 (for MCP-1), 3,200 (for
MIP-1), 6,400 (for GM-CSF), and 1,600 (for the gD DNA vaccine
alone).
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FIG. 1.
(A) Levels of systemic gD-specific IgG in mice
coimmunized with chemokine cDNAs. Each group of mice (n = 10) was immunized with gD DNA vaccines (60 µg per mouse) plus
chemokine genes (40 µg per mouse) or GM-CSF genes (40 µg per mouse)
at 0 and 2 weeks. Mice were bled 2 weeks after each immunization, and
each group's serum pool was diluted to 1:100 for reaction with gD. OD
was measured at 405 nm. Values represent means (n = 10); error bars, standard deviations. Stippled bars, 2-week sera;
solid bars, 4-week sera. (B) ELISA titers of 4-week sera. Equally
pooled sera obtained 2 weeks following the second immunization were
serially diluted from 1:100 for reaction with gD. The titers were
determined as the reciprocal of the highest serum dilution showing an
OD twice as high as that of negative controls. Asterisks indicate
values that are statistically significant at a P value of
<0.05 by Student's t test compared to that with pgD plus
pCDNA3.
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Coimmunization with chemokine plasmids shifts IgG subclasses to Th1
or Th2 isotypes.
IgG subclasses give an indication of the
Th1 versus Th2 nature of the induced immune responses. It has been
known that IgG1 and IgE are Th2-associated antibodies, whereas
IgG2a is a Th1-associated isotype antibody (44). We analyzed
the IgG subclasses induced by the coinjections. As shown in Fig.
2, IP-10 and MIP-1 coinjection enhanced IgG1 isotype production significantly over that with the gD
DNA vaccine alone. In contrast, RANTES coinjection inhibited IgG1 isotype production significantly relative to that with the gD DNA
vaccine alone. However, IL-8 and MCP-1 coinjection showed IgG1 isotype
production similar to that with the gD DNA vaccine alone. In the case
of IgG2a isotype production, IL-8 coinjection enhanced IgG2a production
significantly over that with the gD DNA vaccine alone, whereas IP-10
and MIP-1 coinjection inhibited IgG2a production significantly
relative to that with the gD DNA vaccine alone. In contrast,
RANTES and MCP-1 coinjection showed minimal changes in
IgG2a production compared to that with the gD DNA vaccine alone. The
IgG2a/IgG1 ratios were calculated as 0.71 (gD DNA vaccine alone), 0.8 (IL-8 coinjection), 0.35 (IP-10 coinjection), 0.91 (RANTES
coinjection), 0.69 (MCP-1 coinjection), and 0.53 (MIP-1).
Similar IgG2a/IgG1 ratios were obtained in three separate animal
studies (data not shown). This analysis suggests that IL-8 and
RANTES drive humoral immune responses towards a Th1 phenotype
in vivo.
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FIG. 2.
IgG1 versus IgG2a subclass levels in mice coimmunized
with chemokine cDNAs. Each group of mice (n = 10) was
immunized with gD DNA vaccines (60 µg per mouse) plus chemokine genes
(40 µg per mouse) at 0 and 2 weeks. The mice were bled 2 weeks after
the last immunization, and sera in each group were equally pooled and
diluted to 1:100 for reaction with gD. Samples were assayed in
triplicate. Values and error bars represent means (n = 3) and standard deviations, respectively. The IgG2a/IgG1 ratio was
then calculated by dividing the mean OD of IgG2a by that of IgG1.
Asterisks mark values that are statistically significant at a
P value of <0.05 by Student's t test compared
to that with the gD DNA vaccine alone.
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IL-8 and RANTES coinjections enhance Th cell
proliferative responses.
Th cell proliferation is a standard
parameter used to evaluate the potency of cell-mediated immunity. We
measured Th cell proliferation responses following coimmunization with
cytokine genes by stimulating splenocytes from immunized animals in
vitro with gD proteins. As shown in Fig.
3, gD DNA vaccination alone resulted in gD-specific Th cell proliferative responses. We also observed the significant enhancement of Th cell
proliferative responses over that with gD DNA vaccine alone by
coinjection with IL-8 and RANTES cDNAs. In contrast,
coimmunization with IP-10, MCP-1, and MIP-1 genes appeared to have
minimal effects on the levels of Th cell proliferative responses.
However, the coinjections showed no effects on phytohemagglutinin
(PHA)-induced nonspecific Th cell proliferative responses (the
stimulation index [SI] ranged from was 40 to 50). This finding
supports a direct effect on memory T cells, not nonspecific immune
induction. A lack of cytotoxic T-lymphocyte (CTL) responses against gD
in BALB/c mice has been observed previously (6,
22). Furthermore, gD plasmid vaccination does not result in
CTL responses in the BALB/c background (5, 6, 41).
Therefore, to evaluate cellular effects in more detail, we next
examined cytokine production profiles from chemokine-adjuvanted vaccines.
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FIG. 3.
Th cell proliferation levels of splenocytes after in
vitro gD stimulation in mice coimmunized with -chemokine cDNAs (A)
and -chemokine cDNAs (B). Each group of mice (n = 2)
was immunized with gD DNA vaccines (60 µg per mouse) plus chemokine
genes (40 µg per mouse) at 0 and 2 weeks. Two weeks after the last
DNA injection, two mice were sacrificed and spleen cells were pooled
for the proliferation assay. Splenocytes were stimulated with 1 and 5 µg of gD-2 proteins per ml and 5 µg of PHA per ml as a positive
control. After 3 days of stimulation, the cells were harvested and the
counts per minute were determined. The PHA control sample showed a
stimulation index of 40 to 50. Samples were assayed in triplicate.
Values are means; error bars, standard deviations. Asterisks indicate
values that are statistically significant at a P value of
<0.05 by Student's t test compared to that with the gD DNA
vaccine alone. The experiments were repeated 2 more times with similar
results.
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Chemokine coinjections influence production of Th1 type
cytokines.
The functions of Th1 cytokines (IL-2 and IFN-) and
Th2 cytokines (IL-4, IL-5, and IL-10) have been a mainstay in our
understanding of the polarization of immune responses. Th1 immune
responses are thought to drive induction of cellular immunity, whereas
Th2 immune responses play an important role in humoral immunity. Based on the IgG phenotype results, we further evaluated the Th1-versus-Th2 issue by analyzing cytokine release directly. As shown in Fig. 4A, IL-2 production was dramatically
increased, almost sevenfold, by coinjection with IL-8 cDNA. IL-2 was
also induced by coinjection with the MIP-1 cassette. In particular,
production of IFN- was most significantly enhanced by codelivery of
RANTES (20-fold) and IL-8 (6-fold), further supporting the
isotyping results and demonstrating that IL-8 and RANTES
mediate Th1 type cellular immune responses in an antigen-dependent
fashion. However, IL-4 production was not affected by these chemokine
coinjections (data not shown). This illustrates that IL-8 and
RANTES drive memory T-cell responses predominantly in a Th1
type fashion.
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FIG. 4.
Cytokine (A) and chemokine (B) production levels of
splenocytes after in vitro gD stimulation in mice coimmunized with
chemokine cDNAs. Each group of mice (n = 2)
was immunized with gD DNA vaccines (60 µg per mouse) plus chemokine
genes (40 µg per mouse) at 0 and 2 weeks. Two weeks after the last
DNA injection, two mice were sacrificed and spleen cells were pooled.
Splenocytes were stimulated with 1 µg of gD proteins/ml for 2 days.
Samples were assayed in triplicate. Values are means of released
cytokine or chemokine concentrations; error bars, standard deviations.
Asterisks indicate values that are statistically significant at a
P value of <0.05 by Student's t test compared
to that with the gD DNA vaccine alone. The experiments were repeated
two more times with similar results.
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Chemokine coinjections influence production of -chemokines.
To determine if chemokine coinjection would induce -chemokine
production in an antigen-dependent manner, we coimmunized and then
analyzed release levels of -chemokines from splenocytes after in
vitro stimulation with recombinant gD antigen. As shown in Fig.
4B, IL-8 and RANTES cDNA coinjections enhanced
RANTES production significantly over that with the gD DNA
vaccine alone. In contrast, MCP-1 and MIP-1 cDNA coinjection showed
decreased production levels of RANTES compared to that with
the gD DNA vaccine alone or IP-10 cDNA coinjection. In the case of
MCP-1 production, IL-8 cDNA coinjection enhanced MCP-1 production over
that with the gD DNA vaccine alone. In contrast, RANTES and
MIP-1 cDNA coinjection decreased MCP-1 production compared to
that with the gD DNA vaccine alone. This suggests that chemokines
influence their own production through their effector T cells.
IL-8 and RANTES coinjection enhances survival of i.vag.
HSV-2 challenge.
It is important that antigen-specific immune
modulation influences a pathogen's replication. We analyzed the
protective efficacy of chemokine coinjection in the murine HSV
challenge model. The i.vag. challenge route was chosen because HSV-2
infects mucocutaneously (28). As shown in Fig.
5, mice were coimmunized intramuscularly (i.m.) with pgD (10 µg per mouse) and chemokine cDNAs (20 µg
per-mouse) and then challenged i.vag. with low lethal doses (4 50%
lethal doses [LD50]) of HSV-2. IL-8 and RANTES
coinjection resulted in enhanced survival of lethal HSV-2 challenge,
whereas the gD DNA vaccine alone showed a 70% survival rate. However,
IP-10, MCP-1, and MIP-1 coinjection showed survival rates of 50, 40, and 50%, respectively. A similar finding was also obtained when mice
were immunized twice with pgD (60 µg per mouse) plus chemokines
(40 µg per mouse) and then challenged i.vag. with a very high lethal dose (200 LD50) of HSV-2 (Fig.
6). This illustrated that chemokines IL-8
and RANTES as vaccine adjuvants enhanced protection from HSV-2 infection through antigen-specific immune modulation.
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FIG. 5.
Survival rates of mice immunized with gD DNA vaccines
plus chemokine cDNAs after a low-lethal-dose challenge. Each
group of mice (n = 10) was immunized with gD DNA
vaccines (10 µg per mouse) plus -chemokine (A) or -chemokine
(B) cDNAs (20 µg per mouse). Four weeks after the initial
immunization, mice were challenged i.vag. with 4 LD50 of
HSV-2 strain 186 (1.4 × 104 PFU). Asterisks indicate
results that are statistically significant at a P value of
<0.05 using ANOVA compared to those for mice coinjected with IP-10,
MCP-1, or MIP-1.
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FIG. 6.
Survival rates of mice immunized with gD DNA vaccines
plus chemokine cDNAs after a high-lethal-dose challenge. Each
group of mice (n = 8) was immunized with gD DNA
vaccines (60 µg per mouse) plus -chemokine (A) or -chemokine
(B) cDNAs (40 µg per mouse) at 0 and 2 weeks. Three weeks
after the second immunization, the mice were challenged i.vag. with 200 LD50 of HSV-2 strain 186 (7 × 105 PFU).
Asterisks indicate results that are statistically significant at a
P value of <0.05 using ANOVA compared to those for mice
coinjected with IP-10 or MCP-1.
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IL-8 and RANTES coadministration reduces morbidity
following i.vag. HSV challenge.
Surviving mice challenged with 200 LD50 of HSV-2 were observed for herpetic lesions for 2 months postchallenge. The high LD50 was chosen to evaluate
the disease status of animals after i.vag. HSV-2 challenge. Naive mice
infected with HSV-2 started to show pathological signs, such as
lethargy, abnormal gaits, and ruffling of fur, 2 to 3 days after virus
infection. Naive mice started to die after 5 days of infection, and all
were dead by 8 days after infection. As shown in Table
1, the groups coinjected with IL-8 and
RANTES cDNAs had a lower number of mice exhibiting
herpetic lesions in the vaginal area than the group immunized with pgD plus pCDNA3. Rather dramatically, not only did the pgD-plus-IL-8- and the pgD-plus-RANTES-immunized group have the fewest mice
with herpetic lesions, but 100% of the mice recovered completely from the lesions at 42 and 60 days post-viral challenge, respectively. This
study demonstrates two distinct advantages of such a vaccination scheme: one with regard to survival and one with regard to actual disease pathogenesis.
CD4+ T cells mediate enhancement of antigen-specific
Th1 type cellular responses by IL-8 or RANTES coinjection in
vitro.
Next we sought to evaluate whether CD4+ or
CD8+ T cells are responsible for the enhanced cellular
responses induced by IL-8 or RANTES coinjection. Following
vaccination we depleted CD4+ or CD8+ T cells in
vitro from splenocytes of immunized mice and then tested the effects of
specific cell populations on IFN- production. As shown in Fig.
7, when CD4+ T cells were
depleted, IFN- production was decreased to a background level,
whereas CD8+ T cell depletion resulted in the same
enhancement of IFN- production as that seen in whole
splenocytes from animals coinjected with IL-8 or
RANTES. This supports the idea that CD4+ T cells
are responsible for enhanced Th1 type cellular responses through
coinjection of IL-8 or RANTES cDNAs.
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FIG. 7.
IFN- production levels after in vitro
CD4+ or CD8+ T-cell subset depletion in mice
coimmunized with IL-8 or RANTES cDNAs. Each group
of mice (n = 4) was immunized once with gD DNA vaccines
(30 µg per mouse) and IL-8 or RANTES cDNAs (20 µg of each per mouse). Three weeks after the initial DNA injection,
two mice were sacrificed and spleen cells were pooled. CD4+
or CD8+ T cells were depleted in vitro from splenocytes,
followed by 3 days of stimulation with 1 µg of gD protein/ml. Cell
supernatants were assayed in triplicate. Asterisks indicate results
that are statistically significant at a P value of <0.05
using Student's t test compared to that for the
CD4+ T-cell depletion group. The experiments were repeated
two more times with similar results.
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CD4+ T cells are involved in enhanced protection by
IL-8 or RANTES coinjection.
We next focused on possible
roles of CD4+ T cells in inducing IL-8- or
RANTES-enhanced protective immunity against viral infection. It has also been reported that Th1 type CD4+ T cells, but
not CD8+ T cells, are responsible for protecting animals
from HSV challenge (16, 20, 26). As shown in Fig.
8, all animals immunized with pgD plus
IL-8 or pgD plus RANTES survived lethal HSV challenge. However, coinjected animals treated with anti-CD4 antibodies, like
naïve control animals, failed to survive lethal challenge. In
particular, IL-8 or RANTES control plasmid-injected animals showed survival rates similar to those of naïve control mice. These data confirm that IL-8 or RANTES can enhance survival
through effects on CD4+ T cells in vivo.
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FIG. 8.
In vivo depletion of CD4+ T cells and
protective immunity against HSV challenge. Each group of inbred BALB/c
mice (n = 5) was immunized with 20 µg of IL-8
cDNAs (A) or RANTES cDNAs (B) and/or gD
DNA vaccine (30 µg). After 3 weeks following the initial DNA
immunization, one group of mice was administered 100 µl of anti-CD4
(clone GK1.5) ascites fluid i.p. on days  3, 0, and 3 of viral
challenge. Mice were subsequently challenged i.vag. with 4 LD50 of HSV-2 (strain 186) and then checked for 15 days to
determine survival rates. Asterisks indicate results that are
statistically significant at a P value of <0.05 using ANOVA
compared to that for naive control mice. The experiments were repeated
with similar results.
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DISCUSSION |
HSV is the causative agent of a spectrum of human diseases, such
as cold sores, ocular infections, encephalitis, and genital infections
(28). HSV can establish viral latency with frequent recurrences in the host (34). During viral infection,
neutralizing antibody inactivates viral particles but is unable to
control intracellular HSV infection (29). Rather,
cell-mediated immunity is a major effector function which kills
HSV-infected cells (20, 39). The ability of
B-cell-suppressed mice to control primary HSV infection (11)
or the ability of adoptively transferred T cells to prevent subsequent
viral infection (39) further suggests that cell-mediated
immunity might be directly related to the inhibition of viral infection
and its spread. It has also been well documented that Th1 type
CD4+ T cells play a more crucial role for protection from
HSV-2 challenge (16, 20, 26). For example, when
CD4+ T cells were depleted in vivo, protective immunity
against HSV was lost. Moreover, Th1 type CD4+ T cells
generate a large amount of IFN- (26). IFN- upregulates major histocompatibility complex (MHC) expression on HSV-infected cells
to allow better recognition by cytotoxic CD4+ T cells
(25) and CD8+ CTLs (49), and has
direct anti-HSV effects (10). Recently, direct
antiviral effects of cytokines including IFN- and tumor necrosis
factor alpha (TNF-) have been reported in hepatitis B virus
and lymphocytic choriomeningitis virus infection models (7,
8), supporting the possibility that IFN- might have its own
anti-HSV control mechanism. We recently reported that codelivery
with Th1 type cytokine cDNAs enhanced survival after lethal
HSV-2 challenge, while codelivery with Th2 type cytokine cDNAs worsened the disease status (40).
Similarly, protection enhanced by codelivery with a prototypic
Th1 type cytokine IL-12 cDNA was mediated by Th1 type
CD4+ T cells in an HSV challenge model (41),
underscoring the importance of Th1 type T-cell-mediated protective
immunity against HSV infection.
In animal models, immunization with some HSV glycoproteins
or DNA constructs expressing specific viral components provides complete or partial protection against viral challenge (3, 15, 18,
20, 21, 32). Several HSV proteins have been analyzed as potential
immunization targets. Immunization with cDNA encoding the gC,
ICP-27, or gD protein has been shown to induce antigen-specific immune
responses and protection against in vivo challenge with HSV in animals
(3, 15, 20, 21). Recently, clinical trials using a subunit
vaccine failed to protect from recurrent HSV infection (45).
This might be due to the fact that this subunit vaccine induces Th2
type cellular responses, which are not correlated with protection from
HSV-2-derived morbidity (42). Thus, additional insight is
needed to design a more effective approach for this pathogen, and
studies should focus on morbidity as well as mortality.
We investigated the in vivo effects of selected chemokines on the
induction of protective immunity against HSV-2 infection by coinjecting
them as plasmid cassettes along with gD DNA vaccine constructs. We
observed that the groups coimmunized with IL-8 and MIP-1 chemokine
genes had slightly higher IgG responses than the gD-immunized group, an
effect similar to that with GM-CSF as a vaccine adjuvant.
Furthermore, modulation of antigen-specific IgG isotype responses
has been achieved by using chemokines as molecular adjuvants.
We have observed that IL-8 significantly increased the production
of gD-specific IgG2a, while RANTES alone inhibited IgG1
production, compared to gD DNA vaccine alone or coinjection with MCP-1.
However, coinjection with IP-10 and MIP-1 genes induced more
favorable production of IgG1, compared to IgG2a. Thus, these results
extend prior findings in the human immunodeficiency virus (HIV) model
(14) that the shift in humoral immune responses to either
Th1 or Th2 could be modulated by chemokines, again supporting the idea
that chemokines can modulate cytokine production in vivo.
In vitro immune parameters, such as Th cell proliferative and CTL
responses, have been used to evaluate the potency of cell-mediated immunity. We observed that only plasmid coinjection with IL-8 and
RANTES induced higher Th cell proliferation than the plasmid vaccine alone. IL-8 coimmunization also resulted in significantly increased production of IL-2 and IFN- over that with the gD DNA vaccine alone, further supporting the isotyping results and
demonstrating that IL-8 mediates Th1 type cellular immune responses in
an antigen-dependent fashion. IL-8 coinjection also enhanced MCP-1 and
RANTES production in an antigen-specific fashion, indicating
that IL-8 can modulate -chemokine production in vivo. We also
observed that RANTES coinjection resulted in increased
production of IFN- and RANTES, but decreased production of
IL-2 and MCP-1. This indicates that RANTES modulates antigen-specific immune responses differently from IL-8 in the HSV model.
In HSV challenge studies, gD vaccination alone showed a 70%
survival rate at the challenge inoculum of 4 LD50 of HSV-2.
By coinjection of chemokine IL-8 and RANTES cDNAs,
better survival rates (90 to 100%) were achieved. In contrast,
codelivery of chemokine genes (IP-10, MCP-1, or MIP-1) reduced the
rate of survival of challenged mice to 40 to 50%, more than a 20 to
30% reduction in overall survival from that with the gD vaccine alone.
At the challenge inoculum of 200 LD50 of HSV-2, gD
vaccination alone showed 63% survival rates. By coinjection of
chemokine IL-8 and RANTES cDNAs, better survival
rates (88%) and less-severe herpetic lesion formation were achieved.
In contrast, codelivery of chemokine genes (IP-10 and MCP-1) reduced
the rate of survival of challenged mice to 25%, more than a 50%
reduction in overall survival from that with the gD vaccine alone.
Similarly, MIP-1 coinjection also negatively influenced the survival
rate of vaccinated animals. This indicates that coinjection with IL-8
and RANTES chemokine-expressing plasmids enhances protection
from lethal HSV challenge, while coinjection with IP-10, MCP-1, and
MIP-1 makes animals more susceptible to the effects of viral
infection. In the case of morbidity, we also observed that coinjection
with IL-8 and RANTES resulted in a reduction in the number of
mice with herpetic lesions, compared to that with the pgD vaccine
alone. We previously reported that coinjection with a Th1 type cytokine
gene enhances the rate of protection from lethal HSV challenge, while
Th2 type cytokine coinjection increases the susceptibility of animals
to viral infection (40). In pathogenesis studies, the
importance of a Th1-like cytokine response for resistance to other
pathogenic infections has been reported (7, 9, 38). In
particular, Th1 type CD4+ T-cell responses mediate
protective immunity against HSV infections (16, 20, 26). We
hypothesized that chemokine adjuvanting plasmid vaccines act either
directly or indirectly on CD4+ T cells, thus stimulating
greater immunity against HSV challenge. To test this hypothesis, in
vitro and in vivo subset depletion studies were performed. Our T-cell
subset depletion studies confirmed that IL-8 or RANTES
coinjection enhanced Th1 type CD4+ T cells, resulting in
enhanced protection from HSV challenge. Thus, it seems likely that Th1
and/or Th2 type immune responses are being driven by these chemokines,
resulting in an impact on protection from HSV infectious challenge
based on the quality of the immune responses.
Chemokines have been known to recognize different types of
receptors for immune cell functions (33). In particular,
RANTES recognizes four different chemokine receptors, CCR1,
CCR3, CCR4, and CCR5, whereas MIP-1 recognizes three different
chemokine receptors, CCR1, CCR4, and CCR5. In contrast, MCP-1
recognizes CCR2 and CCR4. In our studies, RANTES had stronger
immune-stimulatory effects and protective immunity against HSV-2,
compared to MIP-1 and MCP-1. This indicates that selective
interaction of RANTES with one of these receptors could be
important for inducing greater protective immunity against HSV-2.
Similarly, the IL-8 receptors, CXCR1 and CXCR2, could play an important
role in triggering and enhancing Th1 type immune responses.
RANTES has also been reported to chemoattract both
antigen-producing cells (APCs) and memory T cells (37).
Changing the environment that is responsible for APC activity could
impact on the Th1 versus Th2 nature of the response. However, the IL-2
and IFN- production data support a direct effect on T cells.
Similarly, the IL-8 response could again take place through attraction
and activation of APCs or through direct effects on lymphocyte subsets,
or both. However, it is more likely that IL-8 and RANTES play
more important roles in acting directly on T cells, as a combination
study using IL-8 and RANTES plasmid adjuvants resulted in
inhibition of antigen-specific T-cell responses (data not shown).
Further study of the direct immune biology is important and will give
insight into the mechanism of immune stimulation by these potent adjuvants.
In conclusion, the data presented here demonstrate that chemokines can
modulate immune responses towards a Th1 and/or Th2 phenotype in an
antigen-dependent fashion and thus modulate protection from lethal
challenge in vivo (Table 2). Such
activities have been previously associated particularly with cytokines.
These data imply that chemokines may have as central a role as
cytokines in the induction of antigen-specific CD4+ T-cell
immunity. This finding broadens our weapons for vaccination as well as
therapy for infectious diseases. Furthermore, the use of chemokines to
modulate immune responses for the beneficial manipulation of cancer
therapies could also be considered.
View this table:
[in this window]
[in a new window]
|
TABLE 2.
Summary of the effects of - and -chemokine
coinjection on IgG levels, the ratio of IgG2a to IgG1, T helper cell
proliferation responses, mortality, and morbidity
|
|
| |
ACKNOWLEDGMENTS |
We thank G. Cohen and R. Eisenberg for providing HSV-2 gD (306t).
We also thank P. Schaffer for providing a stock of HSV-2 for this
study. Also, Naren Chirmule kindly provided anti-CD4 ascites fluids for
this study. J.-I. Sin thanks Weibin Xu for advice on statistical analysis.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology and Laboratory Medicine, University of Pennsylvania, 505 Stellar-Chance Lab, 422 Curie Dr., Philadelphia, PA 19104. Phone: (215)
662-2352. Fax: (215) 573-9436. E-mail:
dbweiner{at}mail.med.upenn.edu.
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Journal of Virology, December 2000, p. 11173-11180, Vol. 74, No. 23
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Abstract
Introduction
