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Journal of Virology, August 2001, p. 7330-7338, Vol. 75, No. 16
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.16.7330-7338.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Delivery of Multiple Epitopes by Recombinant
Detoxified Adenylate Cyclase of Bordetella pertussis
Induces Protective Antiviral Immunity
Catherine
Fayolle,1
Adriana
Osickova,2
Radim
Osicka,2
Thomas
Henry,1
Marie-Jésus
Rojas,1
Marie-Françoise
Saron,3
Peter
Sebo,2 and
Claude
Leclerc1,*
Unité de Biologie des Régulations
Immunitaires1 and Unité
d'Histopathologie,3 Institut Pasteur, Paris,
France, and Cell and Molecular Microbiology Division,
Institute of Microbiology, Academy of Sciences, 142 20 Prague,
Czech Republic2
Received 20 December 2000/Accepted 15 May 2001
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ABSTRACT |
CyaA, the adenylate cyclase toxin from Bordetella
pertussis, can deliver its N-terminal catalytic domain into the
cytosol of a large number of eukaryotic cells and particularly into
professional antigen-presenting cells. We have previously identified
within the primary structure of CyaA several permissive sites at which insertion of peptides does not alter the ability of the toxin to enter
cells. This property has been exploited to design recombinant CyaA
toxoids capable of delivering major histocompatibility complex (MHC)
class I-restricted CD8+ T-cell epitopes into
antigen-presenting cells and to induce specific CD8+
cytotoxic T-lymphocyte (CTL) responses in vivo. Here we have explored
the capacity of the CyaA vector carrying several different CD8+ T-cell epitopes to prime multiple CTL responses. The
model vaccine consisted of a polyepitope made of three CTL epitopes
from lymphocytic choriomeningitis virus (LCMV), the V3 region of human
immunodeficiency virus gp120, and chicken ovalbumin, inserted at three
different sites of the catalytic domain of genetically detoxified CyaA. Each of these epitopes was processed on delivery by CyaA and presented in vitro to specific T-cell hybridomas. Immunization of mice by CyaA
toxoids carrying the polyepitope lead to the induction of specific CTL
responses for each of the three epitopes, as well as to protection
against a lethal viral challenge. Moreover, mice primed against the
vector by mock CyaA or a recombinant toxoid were still able to develop
strong CTL responses after subsequent immunization with a recombinant
CyaA carrying a foreign CD8+ CTL epitope. These results
highlight the potency of the adenylate cyclase vector for induction of
protective CTL responses with multiple specificity and/or broad MHC restriction.
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INTRODUCTION |
CD8+ cytotoxic T
lymphocytes (CTL) are recognized as important mediators of protective
immunity against many viruses (22), tumors
(25), intracellular bacteria (23), and
parasites (24, 29). Vaccination strategies aimed at
generating CTL responses in vivo have been investigated for several
years, and recombinant viruses (39), bacteria (15,
28, 34), and DNA (7, 42) have proven to be
excellent inducers of CTL. However, the inherent safety concerns linked
to these strategies of CTL induction may limit their future application
in humans. Vaccination with synthetic peptides corresponding to CTL
epitopes also appears to lead to a protective CTL-mediated immunity
against tumors or viruses (1, 35). Peptide-based vaccines,
however, require adjuvants that are often incompatible with human
vaccination. Moreover, as shown in the model of the adenovirus type 5 E1A-tumor system, immunization with tumor-specific peptides may lead to
a diminished rather than a protective immune response
(40).
An attractive approach to the design of CTL-inducing vaccines is the
delivery of peptide epitopes by nonreplicative protein vectors, such as
bacterial toxins reaching the cytosol of antigen-presenting cells
(3, 6, 10, 13). Among these, the adenylate cyclase (AC)
toxin of Bordetella pertussis (CyaA or ACT) has been gaining attention over the past few years. CyaA has a unique mechanism of cell
entry, which consists of direct translocation of the catalytic domain
(AC) of CyaA across the plasma membrane of target cells. We have
previously demonstrated that presentation of a recombinant CyaA to
CD8+ T cells does not require endocytosis of CyaA and is
mediated by the classical major histocompatibility complex (MHC) class I pathway (16). It was further shown that recombinant CyaA
toxins carrying a single CD8+ T-cell epitope, from the
nucleoprotein of the lymphocytic choriomeningitis virus (LCMV) or from
the V3 region of the human immunodeficiency virus (HIV) glycoprotein,
remained cell invasive and were able to prime protective MHC class
I-restricted cytotoxic T-cell responses (13, 31). More
recently, protective and therapeutic antitumor immunity against
melanoma cells expressing chicken ovalbumin have been induced by a
detoxified CyaA harboring a CTL epitope derived from chicken ovalbumin
(12).
Since different MHC molecules of various haplotypes generally bind
different peptides, a vaccine based on a single CTL epitope would be
effective for only a small percentage of an outbred population. To
prevent mutant escape and to overcome the MHC haplotypic diversity of
the human population, a practical vaccine would therefore have to
deliver multiple epitopes. In the present study, we investigated the
capacity of CyaA to deliver simultaneously three defined immunodominant CTL epitopes from LCMV, HIV type 1 (HIV-1), and chicken ovalbumin. We
show that on delivery by a single recombinant CyaA, all three epitopes
are efficiently processed, are presented to CD8+ T cells,
and induce epitope-specific cytotoxic responses in vivo against each
epitope. Moreover, the immunity induced by these polyepitope constructs
protected against a subsequent lethal challenge by LCMV. This
demonstrates that immunodominant epitopes derived from different
pathogens or antigens can be delivered by a single CyaA molecule
without loss of immunogenicity.
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MATERIALS AND METHODS |
Mice.
Female C57BL/6 (H-2b) and
BALB/c (H-2d) mice were obtained from CER
Janvier (Le Gesnet St-Isle, France). They were used at 6 to 12 weeks of age.
Synthetic peptides.
All peptides were synthetized by
Neosystem (Strasbourg, France). Peptide p118-132 corresponds to the
H-2Ld T-cell epitope of LCMV nucleoprotein
(1). Peptide p257-264 corresponds to the
H-2Kb T-cell epitope encompassing OVA residues
257 to 264 recognized by the B3Z CD8+ T-cell hybridoma
(5). Peptide p316-327 corresponds to the H-2Kd immunodominant CTL epitope from the V3
region of gp120 of the 18IIIB HIV (Lai) isolate (35).
Cells.
Target cells for CTL lysis assays were DBA/2 mouse
mastocytoma P815 (H-2d) and mouse thymoma EL4
cells (American Type Culture Collection, Manassas, Va). B3Z
(21), a CD8+ T-cell hybridoma specific for the
OVA 257-264 peptide (SIINFEKL) in the context of
Kb, was a generous gift from N. Shastri
(University of California, Berkeley, Calif.). These cells were cultured
in complete medium (CM) consisting of RPMI 1640 supplemented with 10%
heat-inactivated fetal bovine serum, 2 mM glutamine, 50 µM
2-mercaptoethanol, 100 U of penicillin per ml, and 100 µg of
streptomycin per ml. B3Z was maintained in CM containing 1 mg of G418
per ml and 400 µg of hygromycin B per ml.
Production of specific LCMV-CD8+ T-cell
hybridoma.
Female BALB/c mice were injected subcutaneously at the
base of the tail with 0.1 ml of incomplete Freund adjuvant emulsion containing 100 µg of LCMV peptide p118-126 (RPQASGVYM).
On the two following days, the mice were depleted of
CD4+ T cells with 300 µg of CD4-specific rat anti-mouse
monoclonal antibody (GK 1-5), semipurified from ascitic fluids as
previously described (11). One week later, the mice were
killed and the inguinal lymph nodes and spleens were removed
aseptically. A single-cell suspension was prepared in CM and cultured
in the presence of an equal number of irradiated syngeneic splenocytes
and 10 µg of immunizing peptide per ml. Four days later, viable
lymphocytes were isolated by fractionation with Lympholyte (Cedarlane,
Ontario, Canada) and fused with CD8-transfected BW5147 myeloma (kindly provided by Mireille Viguier, Institut Cochin, Paris, France) in a
ratio of 1:1 by using 0.5 ml of polyethylene glycol 1500 (50%;
Boehringer GmbH, Mannheim, Germany). The cell suspension was brought to
a final volume of 40 ml with RPMI 1640 supplemented with 20% fetal
calf serum, 50 µM 2-mercaptoethanol, 2 mM glutamine, and antibiotics.
After the suspension was incubated for 4 h at 37°C, feeder
HAT-sensitive A20 cells were added to a final concentration of 105/ml. Then the cells were plated onto 96-well flat-bottom
microtiter plates at 100 µl/well; 16 h later, 20 µl of HAT 6×
(Boehringer) was added to each well. Hybridomas appeared 7 to 15 days
after fusion and were assayed for peptide-specific reactivity with 1 µg of the immunizing peptide per ml and 5 × 104
P815 cells as antigen-presenting cells (APC), and 24-h supernatants were analyzed for their interleukin-2 (IL-2) content.
From over 20 hybridomas specific for LCMV p118-126, LC 3A10, an
Ld-restricted CD8
+ T-cell hybridoma,
was
selected.
Preparation of recombinant adenylate cyclase toxins carrying the
V3-OVA-LCMV polyepitope.
Escherichia coli XL1-Blue
(Stratagene, La Jolla, Calif.) was used throughout this work for DNA
manipulation and for expression of CyaA. Bacteria were grown at 37°C
in Luria-Bertani medium supplemented with 150 µg of ampicillin per
ml. pT7CACT1 is a construct with enhanced expression of the
cyaC and cyaA genes in E. coli under the control of the isopropyl-
-D-thiogalactopyranoside
(IPTG)-inducible lacZp promoter, which was
derived from pCACT3 (4). The sequence encoding the
polyepitope was inserted in frame at three different sites into the
gene for CyaA (cyaA), between codons 107 and 108, codons 232 and 233, and codons 335 and 336. For this purpose, three plasmids
derived from pT7CACT1 were used, each with a unique BsrGI
restriction site engineered at the respective position
(27). This allowed a two-step insertion of two pairs of
annealed synthetic oligonucleotides, that on assembly yielded the
sequence 5'-GTA CGT ATT CAA CGT GGA CCC GGG CGT GCA TTT GTT ACA
ATA CGT CCG CAA GCT TCT GGT GTT TAC ATG GGT AAC CTG ACC GCT CAG GCT TCA
ATA ATT AAT TTT GAA AAG CTC for the coding strand and 5'-GTA
CGA GCT TTT CAA AAT TAA TTA TTG AAG CCT GAG CGG TCA GGT TAC CCA TGT AAA
CAC CAG AAG CTT GCG GAC GTA TTG TAA CAA ATG CAC GCC CGG GTC CAC GTT GAA
TAC for the noncoding strand. This oligonucleotide was designed (i) to introduce a unique HindIII restriction site for
rapid identification of insertion mutants, (ii) to stop CyaA synthesis
when inserted in the inverted orientation, and (iii) to destroy the
original BsrGI insertion site ligation. The oligonucleotide
encoded the following CTL epitopes in the respective order: (i) the
RIQRGPGRAFVTI peptide corresponding to an
H-2d T-cell epitope from the V3 loop of gp160 of
the 18IIIB HIV-1 (Lai) isolate; (ii) the RPQASGVYMGNLTAQ
peptide corresponding to the H-2d T-cell
epitope from the LCMV nucleoprotein, and (iii) the
Kb-restricted T, CD8+ epitope
SIINFEKL corresponding to residues 257 to 264 from OVA. The
orientation and exact sequence of all inserted oligonucleotides were
verified by DNA sequencing. After characterization of the cell-invasive
AC activity of the generated CyaA-polypeptide fusions, the constructs
were detoxified by ablating their catalytic activity. For this purpose,
the individual plasmids were partially digested by EcoRV,
and the linearized molecules were purified and ligated with the
BamHI synthetic linker 5'-GGATCC, which
introduced a dipeptide GlyPhe insert between residues 188 and 189, thereby disrupting the ATP binding site of CyaA (32). The
resulting proteins were free of any detectable AC activity. Details of
the construction of the plasmids will be provided on request.
The recombinant CyaA proteins were produced on IPTG induction (1 mM) of
500-ml exponential cultures of
E. coli XL1-Blue transformed
with the respective plasmid constructs. The CyaA proteins were
extracted from insoluble cell debris after sonication with 8 M
urea-50
mM Tris-HCl (pH 8.0)-0.2 mM CaCl
2 and purified as
described
previously (
32). AC activities and cell-invasive
and hemolytic
activities of the CyaA constructs were measured as
previously
described (
32).
Antigen presentation assay.
The stimulation of the LC3A10
and B3Z T-cell hybridomas (105 cells/well) was monitored by
measuring the release of IL-2 into the supernatants of 24-h cultures in
96-well plates in the presence of antigens and of either BALB/c or
C57BL/6 splenocytes (3 × 105 cells/well),
respectively. The antigen concentrations used in each experiment are
indicated in the figure legends. After 24 h, the supernatants were
harvested and frozen for at least 2 h at 
70°C. Then
104 cells of the CTLL cell line, which proliferates
specifically in response to IL-2, were cultured per well with 100 µl
of supernatant in a total volume of 0.2 ml. At 2 days later,
[3H]thymidine (NEN Life Sciences Products, Boston, Mass.)
was added, and after a further 18 h of growth, the cells were
harvested with an automated cell harvester (Skatron, Lier, Norway).
Incorporated [3H]thymidine was detected by scintillation
counting. In all experiments, each point was measured at least in
duplicate. Results are expressed as 
cpm (cpm in the presence of
CyaA cpm in the absence of CyaA).
Cytotoxicity assay.
BALB/c (H-2d) and
C57BL/6 (H-2b) mice were immunized
intraperitoneally (i.p.) on days 0 and 14 with 50 µg of purified AC
toxoids in phosphate-buffered saline or mixed with 1 mg of aluminum
hydroxide. After 7 to 10 days, the spleens were removed and 2.5 × 107 cells were cultured in CM in the presence of 1 µg of
the relevant peptide per ml and 2.5 × 107 irradiated
(3,000 rads) syngeneic naive spleen cells. After 5 days, the effector
cells were harvested and cultured in duplicate with 104
target cells at the indicated effector-to-target ratio in a final volume of 200 µl per well. Target cells, P815 and EL4 (4 × 106), were sensitized during 51Cr labeling with
a 50 µM concentration of the appropriate peptide for 1 h at
37°C and were washed prior to use. In each assay, target cells
incubated in the absence of peptide were used as a control for
nonspecific lysis. After 4 h at 37°C, 50 µl of cell-free
supernatant was collected from each well and counted in a MicroBeta
Trilux Liquid Scintillation Counter (Wallac, Turku, Finland).
The amount of spontaneously released
51Cr was determined by
incubating target cells in medium alone. The total amount of
incorporated
51Cr was determined by cell permeabilization
with 10% Triton X-100,
and the percent specific release was calculated
as follows: percent
lysis = 100 × (sample cpm
spontaneous cpm release)/(total cpm
spontaneous cpm
release).
Limiting-dilution analysis.
The frequencies of LCMV-specific
effector CTL cells present in culture after in vitro stimulation were
determined by limiting-dilution analysis (LDA), as previously described
(19). Briefly, between 40,000 and 60,000 cells from a
5-day in vitro stimulation culture were assayed for cytotoxicity on
51Cr-labeled P815 target cells (104) pulsed
with 50 µM p118-132 peptide. Each dilution was tested in 24 replicate wells, and supernatants were counted for radioactivity after
5 h of incubation. A well was considered positive if the amount of
released 51Cr exceeded by 3 standard deviations the mean of
51Cr release in wells containing target cells alone.
Effector cell frequencies were calculated as previously described
(36).
The number of LCMV-specific CTL precursors cells present in immunized
mice was determined as follows. Microcultures were performed
under LDA
conditions with 50 to 10
6 splenocytes from immunized mice
in 24 replicate wells. Each microculture
contained 10
4
syngeneic irradiated naive spleen cells and 1 µg of p118-132
peptide
per ml. At 3 days later, 10% rat concanavalin A supernatant
was added
to each microculture as a source of IL-2. On day 10,
the microculture
in each well was split and assayed for cytotoxicity
on
51Cr-labeled P815 target cells (10
4) sensitized
with 50 µM p118-132 peptide or not sensitized. Frequencies
were
determined as mentioned
above.
Single IFN-
-producing cell enzyme-linked-immunospot assay for
secreting cells.
Multiscreen filtration plates (96 wells;
Millipore, Molshein, France) were coated with 4 µg of rat anti-mouse
gamma interferon (IFN-) antibody (clone R4-6A2; PharMingen, San
Diego, Calif.) per ml overnight at room temperature. Then the plates
were washed and blocked with RPMI supplemented with 10% fetal calf
serum. Serial twofold dilutions of spleen cells from immunized mice
were added to the wells along with 5 × 105
-irradiated (3,000 rads) syngeneic feeder cells and 10 U of recombinant murine IL-2 (PharMingen) per ml. The cells were incubated for 36 h with or without p118-132 peptide at 1 µg/ml. After
extensive washes, the plates were revealed by incubation with 4 µg of
biotinylated rat anti-mouse IFN- antibody (clone XMG 1.2;
PharMingen) per ml followed by incubation with streptavidin-alkaline
phosphatase (PharMingen). Finally, spots were revealed using
5-bromo-4-chloro-3-indolylphosphate/nitroblue tetrazolium (Sigma, St.
Louis, Mo.) as the substrate. The number of IFN--producing cells was
determined by counting the number of spot-forming cells (SFC) in each
well, and the results were expressed as the total number of SFC per
spleen (26).
Virus protection experiment.
BALB/c mice were immunized on
days 0 and 21 by the i.p. route either with 50 µg of wild-type CyaA
mixed with 1 mg of alum, with the LCMV strain Arm/53b (105
foci), with 50 µg of CyaA224LCMV-E5, or with 50 µg of the
recombinant CyaA carrying multiple epitopes mixed with 1 mg of alum.
One week later, the mice were challenged intracerebrally with
101.7 foci of LCMV and their survival was monitored for 21 days.
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RESULTS |
Insertion of several foreign CTL epitopes at three different
positions of the AC domain does not affect the cell-invasive activity
of CyaA.
It was important to determine whether the AC vector can
simultaneously deliver several CTL epitopes into the MHC class I
pathway. Therefore, three CyaA toxins were constructed, carrying at
different permissive sites of the catalytic AC domain (27)
a 36-residue polyepitope made of three CTL epitopes from LCMV, HIV-1
(Lai), or chicken OVA. Compared to intact CyaA in Table
1, the capacity of the CyaA constructs to
invade target cells was not affected by insertion of the polyepitope at
positions 108 (CyaA108MEP) and 233 (CyaA233MEP) of the catalytic
domain. The third protein (CyaA336MEP) lost the marker AC enzyme
activity on insertion of the peptide at position 336, and its
cell-invasive capacity could not be measured. However, the results
presented below strongly suggest that it was also fully cell invasive.
CyaA can therefore accommodate rather long foreign peptides at all
three insertion sites without losing the capacity to penetrate cells.
CyaA toxoids can simultaneously deliver three CD8+
T-cell epitopes to the MHC class I pathway and elicit MHC-restricted
and antigen-specific stimulation of T-cell hybridomas.
We next
analyzed the efficiency of the polyepitope CyaA delivering the
different CTL epitopes to the MHC class I pathway of APCs. To allow
cellular in vitro assays, the CyaA constructs were genetically
detoxified by ablation of the cytotoxic AC enzyme activity
(27) and the resulting CyaA toxoids (labeled by an "-E5") were purified close to homogeneity (Fig.
1). The capacity of these toxoids to
deliver CTL epitopes to the MHC class I pathway was determined by
measuring their presentation to a specific MHC class I-restricted
T-cell hybridoma. BALB/c (H-2d) or C57BL/6
(H-2b) splenocytes were incubated with various
concentrations of the toxoids and hybridomas specific for the LCMV
(hybridoma LC3A10) or OVA (hybridoma B3Z) CD8+ T-cell
epitopes. T-cell hybridoma stimulation was assessed by measuring the
amount of IL-2 secreted into culture supernatants. As shown in Fig.
2, both the LCMV and OVA-specific T-cell
hybridomas responded to the peptides processed from all three CyaA
toxoids in a concentration-dependent and epitope-specific manner. This demonstrates that the polyepitopes inserted at three different permissive sites of CyaA were appropriately delivered into APC, processed into individual epitopes, and presented on the cell surface
by the respective H-2d and
H-2b class I molecules in a form recognized by
the specific T-cell hybridoma. It should be noted that the three
epitopes inserted at all three sites of CyaA were processed and
presented with essentially the same efficiency. Moreover, all three
CyaAs bearing the polyepitope exhibited the same efficiency in
delivering the individual CTL epitopes as did the CyaA224OVA-E5 and
CyaA224LCMV-E5 toxoids carrying each a single epitope. Therefore, it
could be concluded that the processing and presentation of the three
different epitopes was not affected by their combination into a single
polyepitope or by the insertion site and that the toxoids with the
polyepitope at different sites were all efficiently reaching the MHC
class I pathway.
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FIG. 1.
Sodium dodecyl sulfate-polyacrylamide gel
electrophoresis of the purified CyaA constructs carrying multiple
epitopes. The individual constructs were expressed in E. coli XL-1, extracted with 8 M urea, and purified close to
homogeneity by a combination of DEAE-Sepharose and phenyl-Sepharose
chromatography, as described in Materials and Methods. Two micrograms
of each purified protein was analyzed by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis using a 7.5% acrylamide gel
and visualized by Coomassie blue staining.
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FIG. 2.
Presentation of detoxified CyaAs carrying multiple
epitopes to anti-LCMV LC3A10 and anti-OVA B3Z class I-restricted T-cell
hybridomas. APCs (splenocytes from BALB/c [A] or C57BL/6 mice [B])
were incubated in the presence of various concentrations of the CyaA
toxoids, harboring either OVA ( ) or LCMV ( ) epitope at site 224 or the three epitopes (MEP) at different sites (108 [ ], 233 [ ], or 336 [ ]) and were cocultured, respectively, with the
anti-LCMV CD8+ hybridoma LC3A10 (A) or the anti-OVA
CD8+ hybridoma B3Z (B). IL-2 secretion by the stimulated
hybridoma was determined by the CTL proliferation assay. Results are
expressed in cpm of incorporated [3H]thymidine (cpm in
the presence of CyaA cpm in the absence of CyaA). Data represent the
mean values of duplicate samples (standard error of the mean, <10%)
and are representative of two (A) and three (B) experiments.
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Immunization with CyaA toxoids bearing multiple epitopes induces
polyspecific CTL responses.
To test whether CTL responses could be
induced against all three CD8+ T-cell epitopes delivered by
a single CyaA, BALB/c and C57BL/6 mice were immunized with the
polyepitope CyaA toxoids with or without alum. Splenocytes were
harvested and stimulated in vitro with the indicated peptide. Five days
later, a 51Cr release assay was performed to determine
their ability to lyse target cells sensitized with the corresponding
peptides. As shown in Fig. 3,
immunization of BALB/c mice with all three polyepitope CyaAs mixed with
alum induced strong and specific CTL responses to both LCMV p118-132
and HIV V3 p316-327 epitopes. The CTL activities induced by all three
constructs were quite similar and high (i.e., 60 to 70% specific lysis
at an effector-to-target ratio of 10:1). Moreover, the polyepitope CyaA
toxoids exhibited the same efficiency in inducing LCMV-specific CTL
response in mice as did the CyaA carrying a single LCMV epitope.
Immunization with the polyepitope toxoids also induced CTLs specific to
OVA (p257-264) in C57BL/6 mice (Fig. 3C). As expected, in
vitro-stimulated control splenocytes from mice injected with the
control CyaA yielded no specific target cell lysis (Fig. 3). Taken
together, these results demonstrate that immunization with the
polyepitope CyaA toxoids induced specific and MHC-restricted CTL
responses to each of the three CD8+ T-cell epitopes.
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FIG. 3.
CTL induction by the detoxified CyaAs bearing multiple
epitopes. BALB/c (A and B) and C57BL/6 (C) mice (n = 3
for each group) were immunized i.p. on days 0 and 14 with 50 µg of
CyaA toxoids carrying the polyepitope at different sites (108 [],
233 [], or 336 []) or with either the LCMV ( ) or OVA ( )
epitope at site 224 or with control detoxified CyaA (CyaA w.t.-E5)
() mixed with alum. Seven days later, the animals were sacrificed,
the splenocytes were restimulated in vitro for 5 days with 1 µg of
the LCMV (A), V3 (B), or OVA (C) peptide per ml in the presence of
irradiated syngeneic splenocytes, and used as effectors against
unsensitized target cells (P815 for panels A and B and EL4 for panel C)
or against target cells sensitized with the same peptide as used for in
vitro stimulation. Target lysis was evaluated by 51Cr
release. Lysis of unsensitized target cells was less than 10% and is
not shown. (A and B) LCMV (p118-132)-specific CTL (A) and V3
(p316-327)-specific CTL (B) responses in the same BALB/c mice injected
with the detoxified recombinant CyaAs. (C) OVA (p257-264)-specific CTL
response in C57BL/6 mice injected with the detoxified recombinant
CyaAs. CTL responses of control mice injected with the wild-type
CyaA-E5 are shown to illustrate the specificity of the responses. The
data represent the mean percentage of the specific lysis values from
duplicate samples and standard error of the mean and are representative
of four experiments. E:T ratio, effector-to-target-cell ratio.
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When injected without alum, all three polyepitope toxoids also induced
good specific cytotoxic responses to LCMV, V3, and
OVA epitopes, as
shown in Fig.
4. However, an enhancement
of CTL
responses to LCMV and V3 epitopes was observed when CyaA toxoids
carrying multiepitope were injected with alum, and this observation
is
consistent with an earlier study (
8). These results show
that alum is not strictly required to induce good CTL responses
as
previously described (
8) but allows optimal CTL induction
by these recombinant molecules. Therefore, the following experiments
were carried out in the presence of alum.
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FIG. 4.
Immunization of mice with detoxified CyaA toxoids
bearing multiple epitopes in the absence of adjuvant induces high
specific CTL responses. BALB/c (A and B) and C57BL/6 (C) mice
(n = 3 for each group) were immunized i.p. on days 0 and 14 with 50 µg of CyaA toxoids carrying the polyepitope at
different sites (108 [], 233, [], or 336) [] or with
either the LCMV () or OVA () epitope at site 224 or with control
detoxified CyaA (CyaA wt-E5) () in PBS. Seven days later, animals
were sacrificed, the splenocytes were restimulated in vitro for 5 days
with 1 µg of the LCMV (A), V3 (B), or OVA (C) peptide per ml in the
presence of irradiated syngeneic splenocytes and used as effectors
against unsensitized target cells (P815 for panels A and B and EL4 for
panel C) or against target cells sensitized with the same peptide as
used for in vitro stimulation. Target lysis was evaluated by
51Cr release. Lysis of unsensitized target cells was less
than 10% and is not shown. (A and B) LCMV (p118-132)-specific CTL (A)
and V3 (p316-327)-specific CTL (B) responses in the same BALB/c mice
injected with the detoxified recombinant CyaA toxoids. (C) OVA
(p257-264)-specific CTL response in C57BL/6 mice injected with the
detoxified recombinant CyaAs. CTL responses of control mice injected
with the wild-type CyaA-E5 are shown to illustrate the specificity of
the responses. The data represent the mean percentage of the specific
lysis values from duplicate samples and standard error of the mean and
are representative of two experiments. E:T ratio,
effector-to-target-cell ratio.
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To estimate ex vivo the frequencies of LCMV-specific splenocytes in
mice immunized with the three recombinant CyaAs, enzyme-linked
immunospot (
26) and LDA assays were performed
(
36). First,
the number of cells producing IFN-
in
response to in vitro stimulation
with the LCMV peptide was quantified
in spleen cell preparations
from mice immunized with the recombinant
CyaA toxoids. As shown
in Fig.
5, the
T-cell frequencies were remarkably high and in
the same range for each
group of mice immunized with three different
polyepitope toxoids. A
very small number of IFN-
-producing splenocytes
was obtained from
mice immunized with the wild-type CyaA serving
as mock control (Fig.
5). Moreover, in all cases the response
was epitope specific and the
spleen cells from these mice did
not produce IFN-
in the absence of
stimulation by the LCMV peptide
(data not shown).
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|
FIG. 5.
Detection of LCMV-specific IFN-producing cells after
immunization with the CyaA toxoids carrying multiple epitopes. BALB/c
mice (n = 6 for each group) were immunized i.p. on days
0 and 14 with 50 µg of detoxified CyaAs carrying either the
polyepitope at different positions (108, 233, or 336), the LCMV epitope
alone at position 224, or control CyaA toxoid, mixed with alum. On day
21, spleen cells isolated from immunized mice were cultured in vitro
for 36 h without stimulation (i.e., no peptide) or with 1 µg of
the LCMV peptide per ml in the presence of syngeneic irradiated
splenocytes and 10 U of recombinant IL-2 per ml. The data are expressed
as the number of SFC per spleen and represent the mean and standard
error of the mean obtained with six mice in three independent
experiments.
|
|
The frequencies of LCMV-specific lytic CTL precursors and of effector
CTL induced by the polyepitope CyaA toxoids were further
determined by
LDA, both directly ex vivo and after 5 days of in
vitro
restimulation. As shown in Table
2, the
frequencies of
LCMV-specific CTL precursors induced after
immunization with the
three toxoids were rather similar. Moreover, they
were very close
to those induced by the CyaA224LCMV-E5 protein carrying
a single
LCMV epitope. Similarly, the effector CTL frequencies observed
after in vitro culture were very comparable. Taken together, these
results, confirm that the processing and the in vivo immunogenicity
of
each individual epitope within the polyepitope were not affected
by its
size, the presence of other flanking epitopes, or the insertion
site in
the CyaA vector.
View this table:
[in this window]
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|
TABLE 2.
Comparison of the frequencies of ex vivo LCMV-specific
precursor CTL and of effector CTL after in vitro stimulation of
spleens from mice immunized with the CyaA carrying multiple
epitopes
|
|
Immunization with CyaA toxoids carrying multiple epitopes protects
mice against a lethal LCMV challenge.
It was then important to
examine the capacity of CTL generated by polyepitope CyaA toxoids
to protect mice against a viral challenge. As expected, control
mice immunized with mock CyaA or PBS developed a fatal choriomeningitis
within 8 days after intracerebral inoculation of the virus (Fig.
6). In contrast, high protection rates
against a lethal intracerebral LCMV challenge (90, 78, and 90%
survival) were observed after immunization with the CyaA108MEP-E5,
CyaA233MEP-E5, or CyaA336MEP-E5 protein. Morever, the induced
protection was fully comparable to the response induced by the
CyaA224LCMV-E5 toxoid carrying the LCMV epitope alone (78% survival) and was quite close to the full protection induced by a
transient LCMV infection after i.p. administration of the virus. It
should be noticed that all surviving mice completely cleared LCMV (data
not shown). Therefore, these results demonstrate that immunization with
polyepitope CyaA toxoids induces biologically significant CTL responses
capable of protecting mice against LCMV.
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FIG. 6.
Immunization with the detoxified CyaA toxoids carrying
multiple epitopes induces full protection against a lethal LCMV
challenge. On days 0 and 14, BALB/c mice were immunized with 50 µg of
wild-type CyaA E5 (mock control, CyaA wt-E5) or the recombinant CyaA
carrying the LCMV epitope alone (CyaA224LCMV-E5) or the polyepitope at
different positions (CyaA108MEP-E5, CyaA233MEP-E5, or CyaA336MEP-E5),
mixed with 1 mg of alum. Control groups received either PBS or
105 foci of LCMV i.p. On day 21, the mice were challenged
intracerebrally with 101.7 foci of LCMV. Mortality was
monitored for 21 days. The percentage of mice that survived and the
number of surviving mice out of the total number of challenged mice are
shown for each group. The data represent the cumulative results of two
experiments.
|
|
Priming of mice with the mock CyaA vector or a detoxified
recombinant CyaA does not interfere with the subsequent induction of
epitope-specific CTL responses by CyaA carrying a heterologous
epitope.
The antigen delivery capacity of a practical vector
should not be inhibited by priming with the vector molecule itself,
such as priming against CyaA on a natural Bordetella
infection, or after repeated administration of the CyaA-derived
toxoids. Therefore, we first examined whether priming of mice with the
mock CyaA vector has an effect on the subsequent response to
recombinant CyaA carrying an LCMV epitope. Mice received two i.p.
injections of a dose as high as 50 µg of wild-type CyaA prior to i.p.
immunizations with CyaA224LCMV. From previous experiments, it is known
that such immunization protocols typically induce very high levels of
CyaA-specific antibodies with titers above 1:125,000 (unpublished
results). Nevertheless, as shown in Fig.
7, mice which received wild-type CyaA, 15 days, 1 month, or 3 months before immunization with the recombinant
CyaA224LCMV still developed strong CTL responses to the LCMV epitope.
These responses were, indeed, fully comparable to the responses of
unprimed mice. In addition, comparable responses were obtained in mice
which were injected with CyaA wt-E5 or CyaA224OVA-E5 15 days prior
immunization with CyaA224LCMV-E5 (Fig.
8). Therefore, priming with the wild-type
CyaA, the CyaA toxoid, or a recombinant detoxified CyaA has no
inhibitory effect on the subsequent CTL response induced by a
recombinant CyaA carrying another CTL epitope.
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|
FIG. 7.
Effect of prior priming with the mock CyaA vector on the
induction of CTL responses by a recombinant CyaA carrying a
CD8+ T-cell epitope. BALB/c mice were primed with PBS ( ,
) or 50 µg of wild-type CyaA ( , , , ) mixed with 1 mg
of alum by i.p. injection on days 0 and 14. After 15 days, 1 month, or
3 months, all mice were immunized twice i.p. with 50 µg of
CyaA224LCMV (, , , ) or wild-type CyaA (, ), mixed
with 1 mg of alum, at a 3-week interval. At 7 days after the last
injection, spleen cells were stimulated in vitro with the p118-132
peptide in the presence of syngeneic spleen cells. The cytotoxic
activity of these effector cells was measured on
51Cr-labeled P815 target cells pulsed with the same peptide
(solid symbols) or incubated with medium alone (open symbols). The data
represent the mean percentage of the specific lysis values from
duplicate samples and standard error of the mean and are representative
of three experiments. E:T ratio, effector-to-target-cell ratio.
|
|
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|
FIG. 8.
Effect of prior priming with a detoxified recombinant
CyaA on the induction of CTL responses by a recombinant CyaA toxoid
carrying another CTL epitope. BALB/c mice were primed with either PBS
(, ), 50 µg of detoxified wild-type CyaA (CyaA wt-E5) (,
, , ), or 50 µg of detoxified CyaA224OVA-E5 mixed with 1 mg
of alum (, ) by i.p. injection on days 0 and 14. After 15 days,
all mice were immunized twice i.p. with 50 µg of CyaA224LCMV-E5 (,
, , , , ) or CyaA wt-E5 (, ), mixed with 1 mg of
alum, at a 3-week interval. Seven days after the last injection, spleen
cells were stimulated in vitro with the p118-132 peptide in the
presence of syngeneic spleen cells. The cytotoxic activity of these
effector cells was measured on 51Cr-labeled P815 target
cells pulsed with the same peptide (solid symbols) or incubated with
medium alone (open symbols). The data represent the mean percentage of
the specific lysis values from duplicate samples and standard error of
the mean and are representative of three experiments. E:T ratio,
effector-to-target-cell ratio.
|
|
| |
DISCUSSION |
Induction of CTL responses directed against multiple epitopes
appears to be crucial for the development of efficient recombinant vaccines against many important diseases. Several approaches have been
tested recently, involving the use of polyepitope constructs and
different vaccine vehicles, such as viral vectors or naked DNA
(2, 14, 37-39, 41). Mouse and macaque immunization
studies using polyepitope immunogens established the validity of this approach, and an HIV vaccine based on such a strategy entered a phase I
clinical trial in 2000 (17). Our previous results demonstrated that detoxified CyaA is a promising nonreplicative vector
for efficient activation of CTL responses (12, 13). The
objective of this study was therefore to evaluate the feasibility of
delivering multiple CTL epitopes by the detoxified CyaA vectors. The
data reported here clearly show that AC toxoids, carrying three
different model epitopes, were clearly capable of reaching the MHC
class I pathway and inducing in vivo MHC-restricted CTL responses
specific for each of the three inserted epitopes. In addition, strong
and protective anti-LCMV responses were obtained in mice immunized with
these polyepitope CyaA constructs, illustrating that the induced CTL
responses were fully functional in vivo.
This study thus established that insertion of a foreign 35-amino-acid
polypeptide into three different sites of the catalytic domain of CyaA
did not affect its capacity to target and penetrate APCs. Indeed, we
have previously demonstrated that the permissive site at residue 224 of
the catalytic domain of CyaA can accommodate up to four copies of the
CD8+ T-cell LCMV epitope, corresponding to a 76-residue
heterologous polypeptide insert (8, 33). In that case,
however, both the specific AC activity and the cell invasiveness of the
toxin progressively decreased with increasing numbers of inserted
copies of the LCMV epitope. The construct carrying four copies of this
epitope exhibited about 50% of the activities of wild-type CyaA
(8, 33). In the present study, no decrease of cell
invasiveness was observed for the two CyaA constructs with polyepitope
inserts at positions 108 and 233, which exhibited AC activity and could
be characterized. Given the identical efficiency of epitope delivery
for presentation, which depends strictly on cell invasiveness, it could
be concluded that the third toxoid (CyaA336MEP) was most probably also
fully cell invasive. This difference in specific cell invasiveness of toxoids presented here and of the previous constructs with inserts at
position 224 could be due to the characteristics of the inserted polypeptide, to the sites used for polypeptide insertion, or to a
combination of the two. Indeed, the local electrostatic charge of the
insert was shown to be crucial when located at site 224 (20). Introduction of a net negative charge higher than
1 at this position completely blocked translocation of the AC domain of CyaA across target membranes. However, this does not seem to be the
case for introduction of negative charges at positions 108, 233, and
336 of the AC domain (P. Sebo, unpublished data). Therefore, it appears
that the difficulty of delivery by CyaA of negatively charged but
immunologically relevant epitopes could be overcome by inserting these
peptides into the permissive sites newly characterized here.
We recently analyzed in vitro the presentation of the OVA
CD8+ T-cell epitope inserted at 10 different permissive
sites of CyaA along the toxin molecule (27). While all six
constructs bearing the OVA epitope within the noninvasive part of the
molecule failed to deliver the epitope to the MHC class I molecules,
all four toxoids with inserts in different sites of the AC domain
(including positions 108, 233, and 336) efficiently delivered the
epitope into the cytosolic pathway. However, these results were based on in vitro stimulation of a specific CD8+ T-cell
hybridoma; the capacity of the hybrid toxins to stimulate CTL responses
was not evaluated in vivo. The present study provides clear evidence
that these three sites are also fully permissive for the insertion of
multiple heterologous peptides and can be used for constructing CyaA
toxoids directing in vivo CTL activation. It also shows that the
position of the polyepitope within the N-terminal domain of the CyaA
does not affect the induction of specific CTLs, as demonstrated here by
the similar frequency and magnitude of the LCMV-specific CTL responses
induced after immunization with the three polyepitope toxoids.
Flanking sequences are also important for the efficient processing of
CD8+ T-cell epitopes (9), but there are now
many examples of presentation of epitopes regardless of their context
(38). The finding reported here, i.e., that individual CTL
epitopes can be processed from the polyepitope when linked together
without intervening sequences, shows that the environment of the CTL
epitopes did not interfere with the processing events. Hence, the
present study opens the way toward rational design of a new generation
of polyvalent hybrid toxoids carrying strings of epitopes inserted into
different sites along the catalytic domain of CyaA and with
specifically designed properties and increased versatility.
The development of CyaA carrying protective antigens therefore
represents a promising option in the development of efficient vaccines
against various pathogens. However, immune reponses induced by
vaccination against pertussis or natural infections by
Bordetella, which appear to be much more common in
vaccinated populations than was previously appreciated
(18), might interfere with the immunogenicity of future
CyaA vaccines. Therefore, the effect of sequential immunizations by
this delivery system was analyzed. Our results demonstrate that
previous immunization with the CyaA toxin or the CyaA toxoid carrying a
CTL epitope does not prevent secondary immunization directed toward
another CTL epitope carried by CyaA. This suggests that preexisting
immunity against the CyaA toxin does not prevent its presentation by
MHC class I molecules. Thus, the immunity against the carrier toxin
does not limit the use of this delivery system as a potential vaccine,
in comparison with recombinant life vectors (30).
Besides these attractive properties, the adenylate cyclase of B. pertussis appears to exhibit several additional advantages for
vaccine use. Indeed, we have recently established that the recombinant
CyaA carrying the OVA epitope can specifically target myeloid dendritic
cells by means of its specific interaction with the CD11b integrin at
the cell surface and can deliver the OVA epitope to the cytosolic
antigen-processing pathway for efficient MHC class I presentation in
vivo (P. Guermonprez et al., submitted for publication). As a result,
efficient and specific CTL responses can be induced in vivo
independently on CD4+ helper T cells (notably via CD40)
(11; Guermonprez et al., submitted). All these
observations indicate that CyaA has a strong potential for use in
preventive or therapeutic treatments of cancers as well as infectious diseases.
| |
ACKNOWLEDGMENTS |
This work was supported by Agence Nationale de Recherche sur le
SIDA (ANRS), by grant QLK2-CT-1999-00556 from the 5th FP of EU, and
grants 310/95/0432 from the Grant Agency and ME167 and VS96149 of the
Ministry of Education, Youth, and Sports of the Czech Republic.
We thank Gilles Dadaglio and Mohammed El Azami El-Idrissi for critical
reading of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Unité de
Biologie des Régulations Immunitaires, Institut Pasteur, 25 rue
du docteur Roux, 75724 Paris Cedex 15, France. Phone: 33-1 45.68.86.18. Fax: 33-1 45.68.85.40. E-mail: cleclerc{at}pasteur.fr.
| |
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Journal of Virology, August 2001, p. 7330-7338, Vol. 75, No. 16
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.16.7330-7338.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
