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Infection and Immunity, October 1998, p. 4696-4699, Vol. 66, No. 10
Department of Microbiology and Molecular
Genetics, Harvard Medical School, Boston, Massachusetts
Received 12 March 1998/Returned for modification 15 May
1998/Accepted 7 July 1998
We have previously demonstrated that anthrax toxin-derived
proteins, protective antigen (PA) and the amino-terminal portion of
lethal factor (LFn), can be used in combination to deliver heterologous
molecules to the cytosol of mammalian cells. In this study we examined
the ability of an LFn-peptide disulfide-linked heterodimer to prime
cytotoxic T lymphocytes (CTL) in the presence of PA. A mutant of LFn
that contains a carboxy-terminal reactive cysteine was generated. This
form of LFn could be oxidized with a synthetic cysteine containing
peptide to form a heterodimer of the protein and peptide. Mice injected
with the heterodimer plus PA mounted a peptide-specific CTL response,
indicating that this molecule functioned similarly to the genetically
fused forms used previously. We also report the results of an analysis
of two aspects of this system important for the development of
experimental vaccines. First, CD4 knockout mice were unable to generate
a CTL response when treated with PA plus an LFn-epitope fusion protein, suggesting that CD4+ helper responses are essential for
stimulating specific CTL with the PA-LFn system. Second, we now show
that primary injection with this system does not generate any
detectable antibody response to the vaccine components and that prior
immunization has no effect on priming a CTL response to an unrelated
epitope upon subsequent injection.
Cytotoxic T lymphocytes (CTL) are
important immune effector cells in the response to intracellular
pathogens, including viruses and some bacteria (1, 10). CTL
respond to infected cells following recognition of pathogen-derived
epitopes presented at the cell surface by class I major
histocompatibility complex (MHC-I) molecules. These epitopes are small
peptides (8 to 10 residues) derived from pathogen proteins and are
generated through proteasome-mediated cleavage within the cytosol
(9, 17). Following recognition of foreign peptide-MHC-I
complexes, CTL lyse the target cell and then expand and differentiate.
Expansion is important to ensure clearance of other defective cells,
and differentiation results in the establishment of memory CTL. These
memory CTL provide a more efficient response upon subsequent pathogen
exposure. It is the establishment of these specific memory CTL that
results in immune protection against these pathogens. For this reason, priming of memory CTL is central to vaccination against these pathogens.
The need for the vaccinating epitope to be delivered to the cytosol has
required the development of systems to translocate the molecule across
the cell membrane to the interior of the cell, where appropriate
processing and MHC-I interaction of the peptide can occur. To overcome
this barrier, we have used a modified form of anthrax toxin that is
able to enter the cytosol of mammalian cells but is nontoxic (3,
13).
Anthrax toxin is a tripartite bacterial toxin that elicits two toxic
effects, edema and lethality (11). Lethal factor (LF) and
edema factor (EF) are intracellularly acting proteins, and both require
protective antigen (PA) for translocation to the cytosol of mammalian
cells. As part of this process, LF and EF compete for binding to a
proteolytically activated form of PA (PA63) at the cell
surface. Following binding the complex is endocytosed, and after
endosomal acidification LF or EF is translocated to the cellular
cytosol. Within the cytosol EF expresses its adenylate cyclase
activity, generating increased levels of cyclic AMP. The cytosolic
activity and the specific target of LF remain undefined. It does
appear, however, that LF particularly targets macrophages and induces
lethal overproduction of certain cytokines (7, 8).
By eliminating the carboxy-terminal toxic domain of LF, we have
generated a form of this protein (the amino-terminal 255 residues [LFn]) that can bind to PA, can be efficiently delivered to cellular cytosol, and is nontoxic. Previously, we have genetically fused specific CTL epitopes to LFn and used these fusions in combination with
PA to deliver these epitopes to the interior of cells both in vitro and
in vivo (4, 5). We have now expanded this work to examine
the ability of this system to deliver an epitope that is disulfide
linked to LFn instead of genetically fused. Furthermore, we have
examined the role CD4+ T-cell help may play in priming CTL
with the PA-LFn system. We have also investigated whether an
antibody response is generated following initial immunization and
whether this initial vaccination precludes subsequent immunization with
different epitopes.
Peptides.
Synthetic peptides
cysLLO91-99 (CGYKDGNEYI), LLO91-99
(GYKDGNEYI), OVA257-264 (SIINFEKL), and
NP118-126 (RPQASGVYM) were purchased from Biosynthesis
Incorporated (Lewisville, Tex.).
Animals and cell culture.
CD4 knockout
C57BL/6J-Cd4tm1Knw
(H-2b), C57BL/6J (H-2b),
and BALB/cByJ (H-2d) mice were obtained from
Jackson Laboratory (Bar Harbor, Maine). All mice were females between 8 and 12 weeks of age.
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Anthrax Toxin as a Molecular Tool for Stimulation
of Cytotoxic T Lymphocytes: Disulfide-Linked Epitopes, Multiple
Injections, and Role of CD4+ Cells
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
Construction and expression of modified forms of LFn.
Four
modified forms of LFn were used in this study:
LFn(S255
C255), referred to herein as
LFncys, LFn-NP118-126,
LFn-LLO91-99, and LFn-OVA257-264.
-D-thiogalactopyranoside) for
approximately 3 h. Cells were then pelleted and disrupted by
sonication. The sonicate was centrifuged, and the supernatant was
passed over an equilibrated Ni2+-charged column. The bound
fusion protein was removed with 0.5 M imidazole according to the
manufacturer's instructions (Novagen). The eluted protein was then
equilibrated in 20 mM Tris-HCl, pH 7.5. LFncys was isolated
in the presence of 10 mM -mercaptoethanol to prevent oxidation. The
protein concentration was determined, and the sample was frozen at
20°C.
Wild-type PA was isolated from supernatant cultures of an attenuated
strain of B. anthracis according to an established protocol (12).
Disulfide linkage of LFncys with
cysLLO91-99.
To generate the
disulfide-linked LFn-LLO91-99, the following protocol was
used. Purified LFncys was buffer exchanged into 20 mM Tris,
pH 7.5, by gel filtration on a prepared PD-10 column (Pharmacia). The
synthetic cysLLO91-99 peptide was added to the sample at increasing peptide-to-LFncys ratios of 0, 1, 10, 50, and 100. The mixtures were allowed to incubate for 16 h at
4°C. Samples of these mixtures were then resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and analyzed for
heterodimers. The mixture yielding the optimal amount of heterodimer
was then passed over a PD-10 column to remove any unlinked peptide. The concentration of this sample was then determined, and aliquots were
frozen at 20°C and later thawed for use in the appropriate CTL
priming study.
Stimulation of peptide-specific CTL. Mouse splenocytes were harvested and CTL were stimulated as described previously (15), with the following modifications. Spleen cells from immunized and control mice were isolated and washed once in RP-10. Cells used as stimulators were naive, irradiated (2,000 rads), syngeneic splenocytes incubated for 1 h with a 10 µM concentration of the appropriate synthetic peptide. The stimulator cells were washed once in RP-10, and cultures containing 3 × 107 stimulator cells and 3 × 107 splenocytes from either immunized or control mice were established. These were incubated upright in a T-25 flask at 37°C in 7% CO2 in a total volume of 20 ml of RP-10.
Assay for CTL responses.
Mouse thymoma EL-4
(H-2b) or mouse mastocytoma P815
(H-2d) target cells were incubated with a 10 µM solution of the appropriate synthetic peptide and 20 µl of
sodium [51Cr]chromate (600 Ci/ml; 1 Ci = 37 GBq) for
1 h. The cells were then washed three times with medium to remove
unbound peptide and extracellular radionuclide. Radiolabeled cells
(10,000), either treated with peptide or untreated (negative control),
were then added to stimulated effector-cell dilutions in a 96-well
assay plate. The total volume in each assay well was 200 µl.
Spontaneous and complete lysis of target cells was determined by
incubating target cells with either RP-10 or 1% Triton X-100,
respectively. After 4 h of incubation at 37°C, the 96-well
plates were centrifuged at 2,000 × g, and 100 µl of
the supernatant was analyzed for release of 51Cr. Percent
specific lysis was determined as 100 × [(CTL release spontaneous release)/(maximum release spontaneous release)].
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Disulfide linkage of LFncys and cysLLO91-99. To determine if a disulfide-linked heterodimer of LFn and a synthetic peptide could be generated, we constructed a mutant form of LFn that expressed a single reactive cysteine. This modified form of LFn, LFncys, was oxidized with increasing amounts of the synthetic peptide cysLLO91-99. As shown in Fig. 1, at low peptide-to-LFncys ratios there are three LFn-containing reaction products. Based on relative electrophoretic migration of the products, these correspond to an unlinked form of LFncys, an LFncys, homodimer, and an LFncys-cysLLO91-99 heterodimer. As the amount of cysLLO91-99 is increased there is no detectable LFncys homodimer and the protein species become largely LFncys-cysLLO91-99 heterodimers. Estimates from relative band intensities suggest that more than 80% of the LFncys is linked to the synthetic peptide. Further increases in time of incubation or amount of synthetic peptide did not improve the yield of heterodimer.
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CTL responses in CD4 knockout mice.
Both the experimental
CD4
/ and control C57BL/6 mice were immunized as
previously described with PA and LFn-OVA257-264. Mice were
injected intraperitoneally (i.p.) with 30 pmol of the fusion protein
mixed with 6 pmol of PA. Fourteen days after injection, splenocytes
were harvested from the immunized mice and assayed for specific CTL
responses. As seen in Fig. 3, the CD4
knockout mice did not mount a detectable CTL response, suggesting that CD4 help is required to generate a response with this system.
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Influences of primary injections upon subsequent treatments with PA-LFn. In these experiments, two LFn-peptide fusions were used, the previously described LFn-LLO91-99 fusion protein and another fusion protein, LFn-NP118-126. We have constructed LFn-NP118-126 to study immunization against the model pathogen lymphocytic choriomeningitis virus (unpublished data). To determine whether initial vaccination precludes a subsequent immunization with this system, two groups of mice (seven mice per group) were injected with either LFn-NP118-126 plus PA or LFn-LLO91-99 plus PA. Twenty-eight days after the initial injection, two mice from each group were sacrificed, serum was collected, and splenocytes were stimulated and tested for evidence that a CTL response against the antigen was primed. The remaining five mice in each group were injected with the reciprocal protein: mice initially injected with LFn-NP118-126 were injected with LFn-LLO91-99 plus PA, and mice previously injected with LFn-LLO91-99 were injected with LFn-NP118-126 plus PA. Two weeks after the second injection, splenocytes were harvested from each mouse, stimulated in vitro, and assayed for CTL activity against both epitopes.
As shown in Fig. 4, mice initially injected with either fusion plus PA mounted an epitope-specific CTL response, and this response did not prevent subsequent toxin-mediated priming of CTL against a different epitope. Immunoblot analysis with serum taken from mice 28 days after immunization did not reveal an antibody response to PA, LFn, or the fused peptide (data not shown).
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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In previous studies as well as in part of this study, we have used genetic fusion to generate LFn-peptide hybrid molecules. Here we investigated disulfide linkage as another method of generating LFn-peptide molecules. A mutant form of LFn, containing a carboxy-terminal cysteine residue, was oxidized with a synthetic form of LLO91-99 to form an LFn-peptide heterodimer. The molecule appears to function similarly to molecules created by genetic fusion, since specific CTL can be primed by the heterodimer in the presence of PA. Although more detailed analysis is required, these initial results suggest that disulfide bonds in this form do not block translocation. We can envision this system being used in broader applications in which a given molecule with a reactive cysteine is linked to this form of LFn and delivered to the cytosol of cells by PA.
CD4+ T-helper cells have generally been considered important in the establishment of productive antibody responses. In addition, CD4+ helper responses may also be required for the generation and establishment of the CTL response. However, in some systems it has been demonstrated that CTL can be primed in animals that have depleted populations of CD4+ cells. This has been especially true in studies of CTL responses to certain viruses. Buller et al. (6) clearly demonstrated that mice depleted of CD4+ cells were able to mount specific CTL responses to ectromelia virus. Furthermore, the CD4+-cell-depleted mice were protected against establishment of the disease. Studies by Ahmed et al. (2) have shown that depletion of CD4+ cells leads to abrogation of antibody responses to lymphocytic choriomeningitis virus but does not lead to a decline in the number of CTL directed toward the virus. Finally, work by Sauzet et al. (14) has shown that while help from CD4+ cells may not be necessary for establishment of specific CTL, it may be important for long-term maintenance of the response. The studies here suggest that CD4+ T cells are essential for induction of specific CTL following immunization with toxin fusions. The mechanism by which CD4+ help is stimulated is not clear. It is possible that individual polypeptides may be taken up by antigen-presenting cells and presented to CD4+ helper cells by MHC-II. As a result of these findings, we are presently investigating whether approaches that improve CD4+ help may lead to more efficient CTL priming. We are focusing on methods which enhance this helper response while keeping antibody responses to the vaccinating proteins at a minimum.
As a general approach, vaccination against a wide variety of pathogen-infected or defective cells may require multiple injections. For this reason, we are interested in whether initial vaccination prevents the use of this system in subsequent treatments. The results presented in this report suggest that initial injection with the PA-LFn system does not preclude secondary immunization directed toward priming CTL unrelated to the first injection. As part of this experiment, the test animals were assayed for antibody responses to PA, LFn, or the CTL-priming peptide. Even though CD4+ responses were important, we were unable to detect antibody responses to any of the proteins used in this system. An appealing aspect of the PA-LFn vaccination system is the wide range of pathogens for which it could be applied. This system might even be used to vaccinate against other defective cells, such as cancers.
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ACKNOWLEDGMENTS |
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This work was supported by National Institutes of Health grants AI42671, AI41526, and AI22021.
We thank Amy Doling for her suggestions and careful review of the manuscript.
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FOOTNOTES |
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* Corresponding author. Mailing address: Harvard Medical School, Department of Microbiology and Molecular Genetics, 200 Longwood Ave., Boston, MA 02115. Phone: (617) 432-1873. Fax: (617) 738-7664. E-mail: starnbach{at}hms.harvard.edu.
Present address: The University of Oklahoma, Department of Botany
and Microbiology, GLCH 516, Norman, OK 73019.
Editor: J. T. Barbieri
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Discussion
References
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Infection and Immunity, October 1998, p. 4696-4699, Vol. 66, No. 10
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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