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Infection and Immunity, July 2001, p. 4521-4527, Vol. 69, No. 7
Division of Pulmonary and Critical Care
Medicine,1 Department of
Pediatrics,2 Belfer Gene Therapy Core
Facility,3 and Institute of Genetic
Medicine,4 Weill Medical College of Cornell
University, New York, New York
Received 8 December 2000/Returned for modification 9 February
2001/Accepted 9 April 2001
To develop a Pseudomonas aeruginosa vaccine
that allows the host immune system to select the antigens, we
hypothesized that dendritic cells (DC) pulsed with P.
aeruginosa would induce protective immunity against pulmonary
infections with P. aeruginosa. Incubation of murine bone
marrow-derived DC with P. aeruginosa in vitro led to
uptake of P. aeruginosa and activation of the DC.
Spleen-derived CD4+ cells from mice immunized with
P. aeruginosa-pulsed DC showed increased proliferation,
demonstrating that DC pulsed with P. aeruginosa were
capable of eliciting a P. aeruginosa-specific immune
response. To evaluate if P. aeruginosa-pulsed DC can
induce protective immunity against P. aeruginosa
pulmonary infection, DC incubated with P. aeruginosa in
vitro were administered systemically to syngeneic mice, and the mice
were then challenged by intrapulmonary infection with P.
aeruginosa (5 × 104 CFU/mouse) 13 days later.
Unimmunized control mice and mice who had previously received naive DC
or DC stimulated with lipopolysaccharide or Escherichia
coli died within 72 h. In contrast, 45% of mice receiving
P. aeruginosa-pulsed DC demonstrated prolonged survival (>14 days). Finally, DC-pulsed with heat-inactivated P.
aeruginosa protected CD8 Pseudomonas aeruginosa,
an environmentally ubiquitous, gram-negative, opportunistic pathogen,
is commonly associated with progressive, chronic respiratory infection
in patients with cystic fibrosis (CF) and other causes of airway
derangement (6). Once colonization of the airways is
established, P. aeruginosa is rarely eliminated, despite an
exuberant host inflammatory response (10). The treatment
of P. aeruginosa infection by antibiotic therapy is limited
due to a high incidence of drug resistance and the inability to
completely eradicate infection in CF patients (1, 6).
Bacterial virulence factors (12), as well as CF-specific host factors, may play a role in the persistence of this organism (29, 35). Despite considerable effort, vaccines against
P. aeruginosa infection involving conventional immunization
strategies have not been efficacious (18, 21, 33),
although recent novel approaches show some promise (14, 34, 36,
40). The lack of progress toward the development of a vaccine
against P. aeruginosa infection has been due, in part, to an
incomplete understanding of the optimal P. aeruginosa
antigens for the vaccine, as well as of the host immune mechanisms that
mediate protective immunity against this pathogen (5, 6,
10).
The focus of this study is to assess a new paradigm in the development
of a vaccine to protect against Pseudomonas infection, using
Pseudomonas-pulsed dendritic cells (DC) as the immunizing biologic agent. DC are potent antigen-presenting cells that play a
central role in the induction of T-cell immunity in vivo
(2) and in lung host defense (9, 27). Large
numbers of DC with powerful in vivo antigen-presenting properties can
be propagated in vitro using recombinant cytokines (16).
Ex vivo antigen-pulsed DC are effective inducers of tumor-specific
(25) or antiviral (22) protective immunity,
and a variety of bacterial pathogens have been reported to be taken up
and processed for effective antigen presentation by DC (15, 24,
26, 39, 41).
The present study analyzes the interaction of P. aeruginosa
with DC and evaluates the use of DC pulsed with Pseudomonas
to induce protection against fatal pulmonary infections with P. aeruginosa. The data presented here demonstrate that murine bone
marrow-derived DC interact with and are activated by P. aeruginosa in vitro and that DC pulsed with P. aeruginosa administered to syngeneic mice lead to induction of a
CD4+ T cell proliferative response and prolonged
survival following a lethal intrapulmonary challenge with P. aeruginosa in a process that is dependent on the presence of
CD4+ T cells.
Experimental animals.
Female C57BL/6
(He-2b) and CD4 and CD8 knockout mice
(both on the C57BL/6 background), 4 to 6 weeks old, were purchased from Jackson Laboratories (Bar Harbor, Maine) and housed under pathogen-free conditions.
DC.
DC were generated from mouse bone marrow precursors
harvested from C57BL/6 mice in RPMI 1640 medium supplemented with 10% fetal bovine serum (FBS), 100 U of penicillin per ml, and 100 µg of
streptomycin, with recombinant murine granulocyte-macrophage colony-stimulating factor (100 U/liter; Sigma, St. Louis, Mo.) and
recombinant murine interleukin-4 (IL-4) (2 ng/ml; R&D Systems, Minneapolis, Minn.), for 8 days as previously described
(37).
Interaction of DC with P. aeruginosa in
vitro
To analyze the interaction of DC with
P. aeruginosa in vitro, bone marrow-derived DC (2 × 105 cells) were incubated with 20 CFU per cell of
PAO1-GFP, a nonmucoid laboratory P. aeruginosa
strain that expresses green fluorescent protein (gift from Alice
Prince, Columbia University, New York, N.Y.). The bacteria were grown
at 37°C in tryptic soy broth (TSB) (Difco Laboratories, Detroit,
Mich.) to the mid-log phase and washed four times in phosphate-buffered
saline (PBS [pH 7.4]). Following incubation in RPMI 1640 for 3 h
at 37°C, the DC were washed three times in PBS and fixed with 4%
paraformaldehyde in PBS (23°C, 15 min) on Cytospin preparations.
Nuclei were counterstained with the DNA dye
4',6'-diamino-2-phenylindole (DAPI) (1 µg/ml; Molecular Probes,
Eugene, Oreg.) in PBS with 0.1% Triton X-100 for 5 min to visualize
and quantify DC-associated bacteria. The DC were then evaluated by
fluorescence and differential interference microscopy using a Nikon
Microphot SA microscope and a 60× N.A. 1.4 objective.
Activation of DC incubated with P. aeruginosa in
vitro.
To assess whether coincubation of P. aeruginosa
with DC leads to activation of the DC, DC were incubated for 3 h
with 10 CFU of PAO1 per cell in RPMI 1640-10% FBS. The DC were then
washed and incubated for 3 h with 200 mg of gentamicin (Sigma) per
ml to kill live bacteria, and the cultures were contained for an additional 48 h in RPMI 1640-10% FBS. The DC were then washed three times with PBS, and 4 × 105 cells
were stained (30 min, 4°C) with fluorescein isothiocyanate (FITC)-conjugated monoclonal antibodies (MAb) to the costimulatory molecule CD80 (B7.1, 16-10A1) or CD86 (B7.2, GL1). An isotype-matched FITC-labeled MAb was used as a control (all antibodies from Pharmingen, San Diego, Calif.). Stained DC were analyzed by flow cytometry (EPICS
XL apparatus; Coulter Corp., Miami, Fla.).
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.7.4521-4527.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Protection against Pulmonary Infection with Pseudomonas
aeruginosa following Immunization with P.
aeruginosa-Pulsed Dendritic Cells
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ but not
CD4/ mice, demonstrating that CD4+ T cells
were required for the DC pulsed with P. aeruginosa to induce protective immunity.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
CD4+ T-cell proliferation following transfer of
Pseudomonas-pulsed DC.
To analyze whether the
transfer of DC pulsed with P. aeruginosa would lead to
Pseudomonas-specific proliferation of
CD4+ T cells in vivo, the proliferative responses
of CD4+ cells derived from spleens of mice that
were primed with antigen (mice injected with DC pulsed with
heat-inactivated or live PAO1) or not primed with antigen (unstimulated
mice or mice injected with naive DC) were compared to those of
PAO1-pulsed, irradiated DC. DC were incubated with live or
heat-inactivated PAO1 (10 CFU/cell) for 3 h, washed three times
with PBS, and incubated with gentamicin (200 mg/ml) for 1 h to
kill remaining live bacteria. The DC were then washed and resuspended
in PBS, and 2 × 105 cells were injected
intravenously (via the internal jugular vein) into syngeneic
4-to-6-week-old C57BL/6 mice. Naive animals and animals injected with
naive DC served as controls. To control for any remaining live
bacteria, an aliquot of the DC preparation was plated on MacConkey agar
plates, with and without lysis of the cells with 0.5% Triton-X
(Sigma). No colonies were detected after 24 h of incubation. After
14 days, the spleens were harvested and CD4+
cells were isolated using magnetic beads (Miltenyi, Auburn, Calif.). The purity of the isolated CD4+ cells was
assessed by flow cytometry using FITC-labeled MAb to murine CD4. The
CD4+ cells (2 × 105
cells) were cocultured in 96-well plates with 2 × 104 irradiated DC (3,000 rad) that had been
generated from naive syngeneic mice and pulsed with heat-inactivated
PAO1 (10 CFU/cell) for 60 min prior to the culture with the
CD4+ cells. After 48 h,
[3H]thymidine (90 Ci/mmol, 1 µCi/well;
DuPont-NEN, Boston, Mass.) was added, and incubation was continued for
14 h at 37°C, after which the cells were harvested, and the
[3H]thymidine incorporation was measured using
a 
-counter. Cell proliferation was expressed as a stimulation index
(disintegrations per minute [dpm] for CD4+
cells cultured with Pseudomonas-pulsed DC/dpm for
CD4+ cells cultured with unpulsed DC). Control
experiments were carried out to determine the proliferative responses
of CD4+ cells derived from mice immunized with
P. aeruginosa-pulsed DC to irradiated DC pulsed with
E. coli and of CD4+ cells derived from
mice immunized with E. coli-pulsed DC to irradiated DC
pulsed with P. aeruginosa.
Serum antibody response following transfer of Pseudomonas-pulsed DC. To assess if transfer of PAO1-pulsed DC would lead to a specific anti-Pseudomonas antibody response, the sera of C57BL/6 mice which had received 3 × 105 DC pulsed with heat-inactivated or live PAO1 were analyzed 14 days after immunization by ELISA. Sera obtained from naive control mice or from mice that had received naive DC served as the controls. Flat-bottomed 96-well plates (Bio-Rad Laboratories, Hercules, Calif.) were coated at 4°C with 107 CFU of heat-killed PAO1 in 0.05 M carbonate buffer (pH 9.6; Sigma) with 0.2% sodium azide. Serial dilutions of the serum samples were incubated at 23°C for 1 h following the addition of 1% bovine serum albumin. The plates were washed with washing buffer (0.05% Tween 20 in PBS), and rabbit anti-mouse subtype-specific immunoglobulin (immunoglobulin M [IgM], IgG1, IgG2a, IgG2b, IgG3, or IgA; Bio-Rad) was added. After incubation for 1 h and rinsing with washing buffer, the plates were incubated with diluted goat anti-rabbit IgG horseradish peroxidase-conjugated antibodies (Bio-Rad) at 23°C for 1 h. After washing out unreacted conjugated antibodies, the plates were developed with a peroxidase substrate solution (Bio-Rad) for 30 min at 23°C and then evaluated in an ELISA reader at 425 nm.
Immunization with Pseudomonas-pulsed DC. To evaluate whether P. aeruginosa-pulsed DC would lead to protective responses against intrapulmonary infection with P. aeruginosa, DC generated as described above were incubated with live or heat-inactivated PAO1 for 3 h, washed, and then administered intravenously to syngeneic mice (2 × 105 cells/mouse). Naive mice, mice receiving naive DC, or mice receiving DC that had been incubated with either lipopolysaccharide (LPS) (200 ng/ml; Sigma) or heat-inactivated E. coli strain ATCC 25922 (50 CFU/cell) for 3 h intravenously were used as controls. Additional control experiments were done with intravenous injection of heat-inactivated PAO1 (2 × 106 CFU). After 14 days, the animals were challenged by an intratracheal injection of 5 × 104 CFU of agarose-encapsulated PAO1, as described by Stevenson et al. (38). For encapsulation in agarose, PAO1 cells were grown in TSB (Difco Laboratories) to mid-log phase, washed in PBS, and mixed (dilution ratio, 1:9) with 2% TSB agar in PBS at 52°C. This mixture (10 ml) was added to 100 ml of preheated (52°C) heavy mineral oil under constant stirring for 5 min, followed by rapid cooling to 4°C. After being washed three times in PBS, the beads were evaluated for size using a hemocytometer; only preparations with beads having diameters that were <100 µm were used. The number of bacteria encapsulated in the agarose was evaluated by 18-h cultures of serial dilutions at 37°C on 1.5% MacConkey agarose plates (Difco Laboratories). Following intratracheal administration of the Pseudomonas beads, the survival of the animals was assessed over time.
Role of CD4+ T cells.
To evaluate the role of
CD4+ and CD8+ T cells in
establishing immunity by P. aeruginosa-pulsed DC,
CD4/, CD8/, and
wild-type C57BL/6 mice were immunized with 105 DC
which had been pulsed with heat-killed P. aeruginosa (10 bacteria/cell) for 3 h. Wild-type mice without immunization were
included as controls. Mice were challenged intratracheally with
105 CFU of PAO1 enmeshed in agar beads 3 weeks
after the immunization, as described above. Survival was evaluated over
time, and the results were averaged.
Statistical analysis. All data reported here are means ± standard errors of the means. Statistical comparisons were made using the unpaired Student's t test. Survival evaluation was carried out using Kaplan-Meier analysis (Statview; SAS Institute, Cary, N.C.).
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Interaction of P. aeruginosa with DC. Following incubation of DC with PAO1 at 20 CFU/cell, GFP-expressing PAO1 could be seen associated with or in the DC, but no fluorescence was visible in naive cells (data not shown). Although the determination of the localization of the bacteria within or at the cell surface was not possible using this technology, the data demonstrate that the PAO1 was associated with the DC.
Activation of DC following incubation with P.
aeruginosa
To analyze whether coincubation of P.
aeruginosa with DC leads to activation of the DC, the surface
expression of the costimulatory molecules relevant to the interaction
of DC with T cells (CD80 and CD86), as well as the secretion of the
cytokine IL-2, was evaluated. DC incubated with PAO1 demonstrated an
increase in the expression of the costimulatory molecules CD86 (74%
increase) and CD80 (67% increase) that was even greater than
that observed with naive DC (31% increase for CD86 and 40% increase
for CD80 [Fig. 1]). Analysis of the
culture supernatants showed increased secretion of IL-12 in DC
coincubated with PAO1 (152 ± 18 ng/ml) or heat-inactivated PAO1
(253 ± 42 ng/ml) compared to controls (71 ± 13 ng/ml) (for
both comparisons, the P value was <0.001). The IL-12
levels in the supernatants of the DC incubated with heat-inactivated
PAO1, which were increased compared to those in the supernatants of the
DC incubated with viable PAO1, may be a reflection of some toxic
effects of the high dose of live bacteria on these cells. Analysis of
the number of nonviable DC using trypan blue exclusion showed 9% ± 4% dead cells for the control DC versus 13% ± 2% dead cells for DC
incubated with heat-inactivated PAO1 and 24% ± 4% dead cells for DC
incubated with live PAO1 (for both comparisons, the
P value was >0.05). In our system, IL-12 served as a
marker for the activation of the DC. Overall, these data demonstrate
that coincubation of DC with P. aeruginosa leads to
activation of DC, presumably priming them for interaction with CD4+ T cells.
|
Pseudomonas-specific CD4+ T-cell
proliferation following in vivo immunization with P.
aeruginosa-pulsed DC.
To analyze if DC pulsed with PAO1
were capable of eliciting a P. aeruginosa-specific immune
response, CD4+ T cells were harvested from
spleens of mice 10 days after immunization with PAO1-pulsed DC. The
CD4+ cells were coincubated with sensitized and
irradiated syngeneic DC pulsed with PAO1 and analyzed for proliferation
of the CD4+ cells. Spleen-derived
CD4+ T cells from mice immunized with live PAO1
or heat-inactivated PAO1-pulsed DC showed increased proliferation
compared to T cells from naive mice or mice that had received naive DC
(in comparison with controls, the P value was <0.002 [Fig.
2]). However, the CD4+ cells of all four groups (i.e., cells
derived from naive animals, from animals that had received naive DC,
from animals that had received DC pulsed with heat-inactivated PAO1,
and from animals that had received DC pulsed with live PAO1) incubated
with syngeneic unstimulated DC showed no proliferation (data not
shown). The absolute counts of unstimulated
CD4+ were low (<500 dpm) and comparable for all
groups. These results demonstrate that immunization with P. aeruginosa-pulsed DC leads to induction of a
CD4+ T-cell proliferative response against DC
presenting a P. aeruginosa antigen(s). However,
CD4+ cells derived from mice immunized with DC
pulsed with PAO1 previously exposed to irradiated, E. coli-pulsed DC and CD4+ cells derived from
mice immunized with DC pulsed with E. coli previously
exposed to irradiated, PAO1-pulsed DC showed levels of proliferation
(stimulation index values, 3.01 ± 0.2 and 3.2 ± 0.2, respectively) even lower than those shown by
CD4+ cells derived from mice immunized with DC
pulsed with PAO1 exposed to irradiated, PAO1-pulsed DC (stimulation
index, 4.4 ± 0.2, P < 0.001). This suggests
that, in part, the proliferative in vitro responses could be due to
endotoxin adjuvant effects. As seen with the secretion of IL-12, the
heat-inactivated PAO1 leads to a higher proliferation response than
does live PAO1, which may be a reflection of some toxicity of the live
bacteria on the DC during the 3-h incubation period.
|
Pseudomonas-specific antibody response following
immunization with P. aeruginosa-pulsed DC.
To
analyze whether DC pulsed with PAO1 induced an increase in
Pseudomonas-specific antibodies in the serum, the sera of
the mice were evaluated 14 days following immunization with PAO1-pulsed DC for the presence of Pseudomonas-specific IgM, IgG1,
IgG2a, IgG2b, IgG3, and IgA by ELISA. Although increased levels of IgM and IgA were found in the sera of mice immunized with DC pulsed with
live or heat-inactivated PAO1, the differences were not statistically significant when data were compared to those of either control group
(mice not immunized or immunized with naive DC [Fig.
3]).
|
Protection against P. aeruginosa following
immunization with P. aeruginosa-pulsed DC.
To
determine whether mice immunized with P. aeruginosa-pulsed
DC were protected against a lethal, intratracheal dose of P. aeruginosa, the survival of mice that had been immunized
intravenously with P. aeruginosa-pulsed DC (2 × 105) were analyzed following intrapulmonary
infection with a lethal dose of P. aeruginosa encapsulated
in agarose beads. Naive mice and mice receiving naive DC, DC pulsed
with LPS, or DC pulsed with E. coli all died within 72 h following intrapulmonary challenge with PAO1 (Fig.
4). However, the animals which had
previously been immunized with DC pulsed with either live or
heat-inactivated PAO1 demonstrated prolonged survival (45% survived
for more than 10 days; for both, comparison with the controls resulted
in a P value of <0.0001 [Fig. 4]). Animals which had
received heat-inactivated PAO1 without DC did not survive longer than
72 h following intrapulmonary challenge with PAO1 (data not
shown).
|
) or heat-inactivated (
) PAO1 for 3 h, washed,
and then readministered intravenously to syngeneic mice. Naive mice
(
) and mice receiving naive DC (
), LPS-stimulated DC (
), or DC
pulsed with E. coli (
) served as controls. Two weeks
later, PAO1 encapsulated in agarose beads (2 × 104
CFU) was administered to the animals intratracheally and survival was
evaluated over time (n = 15 animals/group for
animals who received PAO1-pulsed or naive DC, n = 5 animals/group for animals who received LPS-stimulated or E.
coli-pulsed DC).
Role of CD4+ T cells.
To evaluate the role of
CD4+ and CD8+ T cells in
the induction of protective immunity following immunization with
P. aeruginosa-pulsed DC, immunization with P. aeruginosa-pulsed DC was analyzed in CD4 and CD8 knockout mice.
Twenty-one days after immunization, the mice underwent intratracheal
infection with agarose-encapsulated PAO1 at a dose of
105 CFU. Immunized wild type mice and CD8
knockout mice showed prolonged survival (percent survival, 40 and 30%,
respectively), whereas nonimmunized mice and CD4 knockout mice all died
within the first 96 h (P < 0.005 [Fig.
5]). These data demonstrate the
necessity of the presence of CD4+ T cells for the
protective effect of the immunization of DC pulsed with P. aeruginosa, whereas the presence of CD8+
cells seems to be negligible for the induction of the protective immune
response using PAO1-pulsed DC.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
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The present study describes a new strategy to induce immunity against pulmonary infections with P. aeruginosa utilizing the potent antigen-presenting potential of DC. DC activated in vitro with whole P. aeruginosa organisms induced systemic Pseudomonas-specific CD4+ T-cell proliferation in vivo. Importantly, intravenous vaccination of DC pulsed with P. aeruginosa was able to improve survival following a lethal intrapulmonary infection with P. aeruginosa, a process that was dependent on the presence of CD4+ T cells.
Protective immunity against P. aeruginosa P. aeruginosa is the most common respiratory pathogen found in CF patients and is thought to play a major role in eliciting damage to the pulmonary tract (6, 10). The host response to P. aeruginosa is a complex immunoinflammatory interaction that results in damage to the airways and lung parenchyma. Opsonizing antibodies, as well as cell-mediated immunity, seem to be associated with protective immune responses (3, 5, 11, 17, 18, 20, 21, 28, 33), although an effective vaccine for protection against chronic pulmonary colonization has not been developed. Although the present study does not define all of the mechanisms of DC-pulsed Pseudomonas induction of Pseudomonas-specific protective immunity, there is a clear demonstration of some protection of systemic administration of Pseudomonas-pulsed DC against intrapulmonary infection with P. aeruginosa. Immunization with heat-killed PAO1 at a comparable dose did not lead to protection, suggesting that DC were necessary for the observed effect. CD4+ T cells likely play an important role, as no survival advantage was observed in CD4 knockout mice. Consistent with this observation, mice with an intact immune system immunized with Pseudomonas-pulsed DC had primed CD4+ cells which proliferated in response to Pseudomonas antigens presented by DC in vitro, although part of the in vitro proliferative response could be due to an endotoxin adjuvant effect. Serum anti-Pseudomonas IgM and IgA antibody levels were found to be slightly but not statistically significantly elevated, and thus, these antibodies do not seem to play the major role in the observed protective effect, although the presence of mucosal antibodies in the respiratory tract, which was not evaluated in the present study, could theoretically play a role. Nonspecific cross-reactivity to anti-LPS cannot be completely excluded for the ELISA assay used in the present study; however, with the use of the identical assay, no anti-P. aeruginosa antibodies were detected in mouse serum immunized with E. coli (19). The presence of antibodies in the nonimmunized mice is most likely due to background levels of antibody to P. aeruginosa, due to the ubiquitous nature of this organism. We have recently demonstrated that using DC genetically modified to express CD40 ligand and pulsed with heat-inactivated P. aeruginosa induced protective immunity independent of CD4+ T cells (19). In that study, a lower dose of DC (5 × 104 DC/animal) and a subsequent higher dose of P. aeruginosa (2 × 105 CFU/animal) for the intratracheal challenge were used. Interestingly, we observed a protective effect of DC pulsed with P. aeruginosa modified with a control Ad vector (AdNull) for 10% of the immunized animals.
Investigation of the immune mechanisms leading to host resistance to bronchopulmonary infection with P. aeruginosa have focused on humoral immunity and nonspecific inflammatory responses, such as neutrophil and macrophage responses (3, 11, 17, 20, 21, 28, 33). For humans, a vaccine directed against Pseudomonas have failed to be effective, despite good antibody responses to the vaccine (21, 33). Passive immunization with mucoid exopolysaccharide-specific opsonizing antibody protects against chronic P. aeruginosa infection in rats. Association between the presence of opsonizing mucoid exopolysaccharide antibodies and a lack of colonization with P. aeruginosa in elderly, relatively healthy patients suggests that this antibody plays a protective role (30). Recently, various novel approaches to vaccination, including the use of human MAb against LPS, elastase peptidase, or catalase and genetic vaccination against exotoxin A have demonstrated promising results (14, 34, 36, 40). The role of T-cell mediated immunity has received less attention in efforts to develop a vaccine against P. aeruginosa (7). T cells are responsible for many host responses against pulmonary infections, and T cells are necessary to provide help for most antibody responses (8). Normal human T cells proliferate in response to P. aeruginosa (31). Intestinal immunization of rats with killed P. aeruginosa protected the lung against bacterial infection in a T-cell-dependent process (7, 8). The presence of protective T-cell responses in the absence of detectable antibody responses have been described in mice following low systemic doses of live P. aeruginosa (23), and protection against Pseudomonas could be transferred to nonimmune mice by CD8+ and CD4+ T cells (32). Immunized animals demonstrated enhanced macrophage activation and neutrophil recruitment and activation, i.e., Pseudomonas-related immune T cells may enhance elimination of P. aeruginosa from the lung via recruitment and activation of macrophages and neutrophils (32).DC and immunity. DC pulsed ex vivo with various protein antigens have the capacity to prime naive T cells in vivo and induce protective immunity against various tumors and microbial infections (2, 22, 24-26, 39, 41). The use of antigen-pulsed DC for the induction of protective immunity against bacteria has been assessed against intracellular pathogens, where a Th1 T-cell-dominant response is thought to be important in controlling the infection (15, 24, 26, 39, 41). Consistent with the observations of the present study, experimental murine eye infection with P. aeruginosa is associated with increased accumulation of DC at the site of infection (13).
Incubation of DC with heat-inactivated PAO1 was as effective as using live bacteria in the induction of a protective effect, suggesting that the processing of the antigens in the DC relevant to induction of anti-Pseudomonas immunity was independent of the viability of the bacteria. Using killed PAO1 in conjunction with DC may be more immunostimulatory, potentially due to lysis or denaturation of immunogens. Studies using DC pulsed with Chlamydia trachomatis to induce protective immunity against genital or pulmonary infection with this organism also used inactivated bacteria (39). As we did not observe any antigen processing and presentation in the PAO1-pulsed DC, the possibility that the observed protective effect might be based on a superantigen effect cannot be ruled out. The usage of DC pulsed with the intact P. aeruginosa organism as a vaccination strategy has the potential advantage of inducing immunity against multiple antigens simultaneously, as opposed to vaccination strategies using single antigenic components of P. aeruginosa. This is especially relevant in the light of the capacity of P. aeruginosa to commonly mutate in vivo into a mucoid form (10). The appearance of mucoid forms includes overproduction of the polysaccharide alginate, leading to increased bacterial adherence and thus imposing a barrier for phagocytosis, and usually correlates with the formation of a bacterial biofilm containing microcolonies (4). There is genetic diversity among P. aeruginosa strains isolated from patients with CF, with various patterns of colonization, such as colonization with multiple resistant strains, a single strain, or periodically changing dominant strains (10). A vaccination strategy utilizing the whole Pseudomonas organism presented by DC may be able to induce immunity to multiple Pseudomonas antigens before the appearance of a bacterial biofilm. The P. aeruginosa strain used in the present study, PAO1, is a nonmucoid laboratory isolate. Future studies will have to use mucoid strains and various clinical isolates recovered from infected patients with CF at various times during the progression of their disease to further evaluate the efficacy of this strategy.| |
ACKNOWLEDGMENTS |
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We thank P. Leopold and R. Ramalingam in our laboratory for helpful discussions and N. Mohamed for help in preparing the manuscript.
These studies were supported, in part, by the Will Rogers Memorial Fund, Los Angeles, Calif.; the Cystic Fibrosis Foundation, Bethesda, Md.; and GenVec, Inc., Gaithersburg, Md.
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FOOTNOTES |
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* Corresponding author. Mailing address: Weill Medical College of Cornell University, New York Presbyterian Hospital, 520 East 70th St., ST 505, New York, NY 10021. Phone: (212) 746-2258. Fax: (212) 746-8383. E-mail: geneticmedicine{at}med.cornell.edu.
Editor: J. T. Barbieri
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Discussion
References
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Infection and Immunity, July 2001, p. 4521-4527, Vol. 69, No. 7
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.7.4521-4527.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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