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Infection and Immunity, September 1999, p. 4312-4319, Vol. 67, No. 9
Department of Immunology,
Received 8 February 1999/Returned for modification 30 March
1999/Accepted 23 June 1999
Stimulation of Mycobacterium tuberculosis-primed lymph
node cells from C57BL/6 mice with The interaction between specifically
sensitized T cells and activated macrophage effector cells is
considered to be the hallmark of protective immunity against the
pathogenic mycobacteria Mycobacterium tuberculosis and
Mycobacterium leprae (4, 7). Also, mice infected
with live Mycobacterium bovis BCG predominantly exhibit a
Th1 cytokine secretion profile, although some susceptible mouse strains
activate interleukin 4 (IL-4)-producing Th2 cells to some extent
(18, 20). Gamma interferon (IFN- The specific antigens eliciting protective T-cell responses are not yet
known for tuberculosis, but considerable numbers of proteins have been
identified by using both classical purification methods and,
especially, recombinant DNA technology (1, 33, 51, 52). One
of the antigens secreted from M. tuberculosis is It has previously been shown that The purpose of this study was twofold: first, we wanted to
evaluate the feasibility of peptide-25 as a vaccine against
M. tuberculosis H37Rv, and second, we wanted to
determine which amino acid residues of peptide-25 were critical
for T-cell receptor (TCR) recognition and for major histocompatibility
complex (MHC) class II binding. Our results revealed that
peptide-25 acts to some extent as a protective vehicle against
live H37Rv infection. Peptide-25 contains distinct amino acid residues
critical for TCR recognition and for MHC class II binding.
Mice.
B6 mice were obtained from Japan SLC Inc. (Hamamatsu,
Japan) and used when they were 8 to 12 weeks of age. The mice were
maintained in the animal facility at the Institute of Medical Science,
University of Tokyo, under strict pathogen-free conditions; laboratory
chow and water were available ad libitum.
Antigens and reagents.
M. tuberculosis MAbs.
The following MAbs were used: RL172.4 (8)
and GK1.5 (12) (American Type Culture Collection [ATCC],
Manassas, Va.), which recognize CD4; RA3-6B2 (9) (ATCC),
which recognizes B220; 53-6.72 (23) and 3.155 (40) (ATCC), which recognize CD8; and 2.4G2 (47)
(ATCC), which recognizes Fc Immunization.
Mice were immunized by subcutaneous injection
at the base of the tail with 500 µg of acetone powder containing
heat-killed M. tuberculosis H37Rv in paraffin oil or 10 µg
of purified protein derivative (PPD) in incomplete Freund's adjuvant
(ICFA) (39, 42, 54). In some experiments, B6 mice were
immunized with 1 to 10 µg of peptide-25 or its mutants with
substitutions in ICFA and then boosted 7 days before experiments with
10 µg of the antigen.
Bacterial load in lungs and livers of M. tuberculosis
H37Rv-challenged mice.
Mice were infected intravenously in the
lateral tail vein with 106 CFU of M. tuberculosis H37Rv or 2 × 106 CFU of M. bovis BCG (Paris strain), whose Cell culture.
Suspensions of single cells were prepared from
inguinal lymph nodes of B6 mice. For proliferation assays, cells
(5 × 105) were cultured in 96-well flat-bottom
microtiter plates (Nunc, Roskilde, Denmark) in the presence of selected
concentrations of
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Identification of Amino Acid Residues of the T-Cell
Epitope of Mycobacterium tuberculosis
Antigen
Critical for V
11+ Th1 Cells
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
antigen (also known as antigen 85B and MPT59) induced cell proliferation, production of interleukin 2 and gamma interferon, and expansion of V
11+
CD4+ T cells in conjunction with antigen-presenting cells
in an I-Ab-restricted manner. Using a series of
15-amino-acid peptides that overlapped each other by 5 amino acids and
spanned the mature antigen, we identified the antigenic epitope for
antigen-specific V11+ Th1 cells. That peptide
(peptide-25), which corresponds to amino acid residues 240 to 254 of
antigen, contains a motif that is conserved in
I-Ab and requires processing by antigen-presenting cells.
Using peptide-25-reactive V11+ T-cell clones and
substituted peptide-25 mutants, we determined which amino acid residues
within peptide-25 were critical for T-cell receptor (TCR) recognition.
Our results showed that the amino acid residues at positions 245, 246, 248, 250, and 251 are important for recognition of TCRV11 and that
residues at positions 244, 247, 249, and 252 are I-Ab
contact residues. We also observed that active immunization of C57BL/6
mice with peptide-25 can lead to decreased bacterial load in the lungs
of M. tuberculosis H37Rv-infected mice. These results should provide us with a useful tool for delineating the regulation of
V11+ Th1-cell development during M. tuberculosis infection and for developing a vaccine inducing
a Th1-dominant immune response.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
), which has powerful immunomodulatory and macrophage-activating properties (14, 25, 29), also plays an essential role in the protective immunity against these intracellular pathogens (34); this was
convincingly demonstrated in recent experiments using IFN- and
IFN- receptor gene-disrupted mice (10, 11, 14).
antigen, which is also known as MPT59 or antigen 85B (Ag85B). This
protein has shown itself to be one of the most potent antigen species
yet purified. Our major interests are to understand how Th1 cells
develop after infection or immunization with M. tuberculosis, to characterize antigenic epitopes for Th1-cell
activation, and to determine the efficacy of DNA vaccination against tuberculosis.
antigen stimulation of M. tuberculosis-primed lymph node cells from C57BL/6 (B6) mice induced cell proliferation, production of IL-2 and IFN-, and expansion of V11+ CD4+ Th cells in
conjunction with antigen-presenting cells (APCs) in an
I-Ab-restricted manner (54). In contrast, lymph
node cells from nonprimed mice failed to proliferate in response to antigen. We also mapped the antigenic epitope for antigen-specific
V11+ T cells. That peptide (peptide-25), which
corresponds to amino acid residues 240 to 254 of antigen, contains
a motif that is conserved in I-Ab and requires processing
by APCs to trigger peptide-25-specific V11+
CD4+ T cells.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
antigen was
purified as previously described (28) and used at selected
concentrations. Peptide-25 and its substitution mutants were
synthesized by Sawaday Chemicals (Tokyo, Japan) by using
9-fluorenylmethoxycarbonyl chemical strategies and an automated Applied
Biosystems (Foster City, Calif.) 430A peptide synthesizer. Peptides
were purified via high-pressure liquid chromatography, and composition
analysis was carried out. Mouse IL-2 was purified from conditioned
medium of phorbol myristate acetate-stimulated EL-4 cells as previously
described (39) by using immunoaffinity chromatography and
S4B6, an anti-IL-2 monoclonal antibody (MAb) (26).
R. In addition, M5/114.15.2 (anti-I-Ab) (5) and 28-16-8S
(anti-I-Ab) (35) were kindly provided by
Toshinori Nakayama (University of Tokyo). B20.6 (anti-V2)
(50), 44-22-1 (anti-V6) (3), and F23.1
(anti-V8) (43) were kindly provided by Yasunobu Yoshikai (Nagoya University, Nagoya, Japan). KJ-25 (anti-V3) (36),
KT4 (anti-V4) (45), B21.5 (anti-V10) (30),
MR11-1 (anti-V12) (49), MR12-3 (anti-V13), and 14-2 (anti-V14) (44) were purchased from PharMingen (San
Diego, Calif.). MR9-4 (anti-V5) (22), MR10.2 (anti-V9)
(48), and RR3-15 (anti-V11) (6) were kindly provided by Osami Kanagawa (Washington University, St. Louis, Mo.) and
Hiromitsu Nakauchi (Tsukuba University, Tsukuba, Japan). Phycoerythrin-labeled streptavidin was purchased from GIBCO BRL (Grand
Island, N.Y.).
; and XMG1.2 (anti-IFN-) (27), which
was kindly provided by Maureen Howard (DNAX Research Institute, Palo
Alto, Calif.).
antigen contains an amino acid
sequence identical to that of peptide-25 (53), and were
sacrificed at various time points. To release intracellular bacteria,
lungs and livers of M. tuberculosis H37Rv- or BCG-infected mice were homogenized in distilled water. Serial 10-fold dilutions were
then made, and 100 µl of each was spread onto Middlebrook 7H10
Bacto-Agar (Difco, Detroit, Mich.) plates or 1% Ogawa Agar (Eiken Co.,
Tokyo, Japan) plates to quantitate bacterial load. The number of CFU
per lung and per liver was measured as previously described but with
slight modification (19). The cultures were incubated for 21 days at 37°C; thereafter, mycobacterium colony formation was assessed.
antigen or synthetic peptides. Each well
contained 200 µl of complete medium consisting of RPMI 1640 medium
(Sigma) supplemented with 8% fetal calf serum, penicillin (100 IU/ml),
streptomycin (50 µg/ml), and 5 × 10
5 M
2-mercaptoethanol. Cultures were set up in triplicate. The cells were
pulse-labeled with [3H]thymidine (1 µCi/well) during
the last 8 h of a 72-h culture period; incorporation of
radioactivity was measured by tritium-sensitive avalanche gas
ionization detection on a Matrix 96 direct beta counter (Packard,
Meriden, Conn.) (54). The background counts per minute was
obtained by culturing cells without any stimulation. We show
representative results from a series of three separate experiments. For
determining cytokine production, cells were cultured for either 72 h (IFN- or IL-4) or 24 h (IL-2).
Cytokine quantitation assays.
IL-2 production was determined
by bioassay by using an IL-2-dependent mouse cytotoxic T-cell line,
CTLL-2 (54). A unit of IL-2 activity was defined as the
reciprocal of the dilution yielding one-third of the maximal
proliferation induced by a standard IL-2 preparation. IFN- and IL-4
production was measured by enzyme-linked immunosorbent assay as
described previously (46, 54). Standard curves were
generated, and the concentration of each cytokine was determined by
using the computer program SOFTmax. We detected 1 U of IFN- per ml.
Establishment of cloned T cells.
antigen- and
peptide-25-reactive T-cell clones were established according to a
previously described procedure (39) with slight
modification. Briefly, lymph node cells (5 × 105/well) from B6 mice previously immunized and boosted
with PPD or M. tuberculosis were stimulated with either PPD
(5 µg/ml) or antigen (1 µg/ml) and maintained for 7 days in a
24-well plate. Cells were then restimulated with the relevant antigen;
irradiated spleen cells (2 × 106/ml) from B6 mice
were also added as APCs, and culture was continued. Surviving cells
were then stimulated again with antigen plus APCs. This procedure was
repeated three to four times with 7-day intervals in between. Cloned
T-cell lines were obtained by replating cells in 96-well microplates
with one cell in each well in the presence of APCs. These cells were
cultured in the presence of antigen plus APCs; 5% culture supernatant
from concanavalin A-stimulated rat spleen cells was also added as an
IL-2 source.
Flow cytometry.
Expression of cell surface antigens,
particularly TCRV, before and after culture was analyzed by flow
cytometry. Suspensions of single cells prepared from inguinal lymph
nodes or collected from culture were stained with fluorescein
isothiocyanate-labeled anti-CD4 MAb and biotinylated anti-V MAbs
plus streptavidin-phycoerythrin (GIBCO BRL) as described previously
(54). 2.4G2 MAb (10 µg/ml) was added during the incubation
to block nonspecific binding of the labeled MAbs. Fluorescence
intensity was measured on a FACScan analyzer (Becton Dickinson). The
gate on the lymphoid population was set by forward and side scatters.
To assess particular V+ T cells, we calculated the
percentage of V+ cells from the total CD4+ cells.
I-Ab-peptide binding assays. I-Ab-peptide binding assays were carried out according to a previously described procedure (16) with slight modification. Aliquots (50 µl) of immunoaffinity purified I-Ab molecule (0.5 µM) were incubated for 48 h at room temperature in 1.5-ml Eppendorf tubes with 1.7 µM biotinylated 46F50E54A (mutant peptide of pigeon cytochrome c p43-58, AEGFSYTEANKAKGIT) and nonbiotinylated competitor peptides. Protein A (10 µg of phosphate-buffered saline [PBS] per ml; Wako Pure Chemicals, Osaka, Japan) was immobilized on 96-well polystyrene microtiter plates (Sumitomo Bakelite Co. Ltd., Osaka, Japan) by incubation at room temperature overnight. The ascites form of anti-I-Ab MAb (1:10 dilution) was then applied to protein A-coated plates and incubated for 24 h at 4°C. After washing the plates with PBS containing 0.05% Tween 20 (Bio-Rad, Hercules, Calif.), the preincubated I-Ab-peptide mixtures were added and incubated for 3 h at room temperature. After washing again with Tween-PBS, streptavidin-alkaline phosphatase (1:500 dilution in PBS containing 0.05% Tween 20 and 1% bovine serum albumin) was added to the plates, and the preparation was incubated for 2 h at room temperature. Thereafter, 1 mg of p-nitrophenol phosphate (Kirkegaard & Perry Laboratories, Inc., Gaithersburg, Md.) per ml of diethanolamine buffer was added to the plates, and after washing with Tween-PBS, the absorbance of each well was read at 405 nm.
The affinity with which test peptides were bound to I-Ab was expressed in terms of their ability to competitively inhibit binding of biotinylated 46F50E54A peptide. The relative binding affinity was calculated as the ratio of the concentrations (millimolar) of unlabeled 46F50E54A and unlabeled test peptides, each of which inhibits to the same degree the binding of the biotinylated standard. In practice, the following peptides and concentrations were used: I-Ab, 0.5 mM; biotinylated 46F50E54A peptide, 1.7 mM; unlabeled 46F50E54A peptide, 0.0214 to 214 mM; and unlabeled test peptides, 24 mM. All assays were carried out in duplicates.| |
RESULTS |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Peptide-25 of antigen induces peptide-specific
V11+ T-cell development in vivo.
We first evaluated
whether peptide-25 is immunogenic in vivo. Two groups (n = 5) of B6 mice were immunized with either peptide-25 or antigen emulsified in ICFA. As a control, B6 mice were immunized with
S35 peptide, which is the leader peptide of antigen (Fig. 1) (53). Seven days after
immunization, peptide-25-induced proliferation and IFN- production
by lymph node cells were examined; the results clearly showed that both
peptide-25 and antigen are immunogenic in vivo (Table
1). Lymph node cells from B6 mice
immunized with either peptide-25 or antigen responded to the
respective antigen with cell proliferation and IFN- production,
whereas S35-immunized mice did not respond to S35. The magnitudes of
the proliferative responses were dose dependent, and the responses
reached a plateau at a peptide-25 concentration of 100 ng/ml (data
not shown). In addition, CD4+ T cells expanded by
stimulation with peptide-25 and antigen were V11+
(54) (data not shown).
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Mice immunized with peptide-25 are resistant to a subsequent challenge with M. tuberculosis H37Rv. To determine whether potent peptide-25-specific immune responses would protect mice against subsequent challenges with viable M. tuberculosis H37Rv infection, we immunized a group of B6 mice with peptide-25 and boosted them 6 weeks later. The immunized mice were then challenged by intravenous injection of 106 CFU of M. tuberculosis H37Rv 7 days after the booster injection. A group of nonimmunized, age-matched B6 mice were also infected with 106 CFU of M. tuberculosis H37Rv. The CFU of M. tuberculosis H37Rv per lung or per liver were enumerated 1, 7, 14, 21, and 28 days after infection (5 mice per group per time point). On day 1 of infection, no significant difference of CFU per lung or per liver between the nonimmunized and the peptide-25-immunized groups was observed (data not shown). Interestingly, as shown in Fig. 2A, the number of CFU per lung on days 7 and 14 in mice immunized and boosted with peptide-25 was significantly lower (about 1/10) (P < 0.04) than that in nonimmunized mice. No significant difference of CFU per lung between the nonimmunized group and the group immunized with peptide-25 was observed on days 21 and 28 of infection. The number of CFU per liver was also decreased in mice immunized with peptide-25 on days 14, 21, and 28 of infection, but this was not statistically significant (Fig. 2B). We repeated the experiments three times and obtained essentially identical results. In another experiment, we examined CFU per liver and per lung 14 days after infection. As shown in Fig. 2B, the number of CFU per lung in peptide-25-immunized mice (4.04 ± 0.02 log) was again significantly lower (P < 0.02) than that in nonimmunized mice (4.61 ± 0.01 log). Furthermore, the number of CFU per liver in mice immunized with peptide-25 (6.59 ± 0.13 log) was lower than that in nonimmunized mice (7.00 ± 0.10 log) (P < 0.02). We did not see significant differences of CFU in spleens between the immunized mice and the control mice (data not shown). Thus, active immunization with peptide-25 induces marginal protection against subsequent infection with live M. tuberculosis H37Rv and a delay of the early expansion of bacterial burden.
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) and
peptide-25-primed (
) mice (five mice per group per time point).
Establishment of peptide-25-reactive T-cell clones.
To define
which peptide-25 amino acid residues are critical for
V11+ CD4+ T cells, lymph node cells from
either M. tuberculosis-primed or PPD-primed B6 mice were
cultured with PPD or antigen, and T-cell clones were established
according to procedures described in Materials and Methods. We
established 15 different CD4+ T-cell clones, 12 of which
expressed V11. Other clones expressed V14, V10, and V5.
antigen protein, we determined the peptide specificity of the cloned T cells. Each clone was stimulated with each
of the test peptides at a concentration of 1 µg/ml in the presence of
irradiated B6 spleen cells as APCs, and proliferative responses were
monitored. All clones expressing V11 responded exclusively to
peptide-25 (Table 2). The magnitude of
the effect of peptide-25 was dose dependent: 5 ng of peptide-25 per ml
induced significant proliferative responses and <100 ng of peptide per ml elicited the plateau level of proliferative response. In contrast, stimulation with as much as 10 µg of other synthetic peptides per ml
had no effect on T-cell proliferation. Peptide-25-specific clones
produced IFN- and IL-2 upon stimulation with peptide-25, but they
did not produce IL-4 (data not shown). The clone expressing V14 also
responded to peptide-25, while clones expressing V10 and V5 did
not. These results confirm our previous studies (54) showing
that peptide-25 is the potent antigenic epitope of antigen, preferentially stimulating V11+ antigen-reactive Th1
cells.
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Amino acid residues of peptide-25 critical for TCR recognition and
MHC binding.
Peptide-25, which consists of amino acids 240 to 254 of antigen contains a motif (Y-x-x-x-x-x-x-x-A) similar to the
I-Ab motif (F-x-x-x-x-x-x-x-A) described by Itoh et al.
(21). To examine the role played by individual amino acid
residues in peptide-25-evoked activation of T cells, we analyzed the
proliferative response of T-cell clones to a group of peptide-25
mutants that each contained a single amino acid substitution. Although
the clones displayed varying patterns of reactivity to the substituted
peptides, some general features of the T-cell responses were identified
(Fig. 3). No T-cell clones responded to
N245A mutant peptides. Other amino acid residues important to the
majority of T-cell clones were 244 and 246 to 251; substitution of any
one of these residues significantly reduced the capacity of peptide-25
to stimulate proliferation of cloned T cells. IFN- secretion induced
by peptide-25 and its substitution mutants generally paralleled the
proliferative responses (data not shown). Based on these results, we
conclude that amino acids 244 to 252 of peptide-25 are critical for its recognition by reactive T-cell clones expressing TCRV11.
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, SI was <1.
(B) Results are expressed as the frequency of critical residues and
were calculated by dividing the number of clones responsive to a mutant
peptide by the total number of clones.
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) or
peptide-25
(
) or were
left unstimulated (
); their proliferative responses were assessed as
a function of [3H]thymidine incorporation. Results are
expressed as mean counts per minute ± SD of triplicate
cultures.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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We have demonstrated that stimulation of M. tuberculosis-primed CD4+ V11+ T cells
from B6 mice with mycobacterium antigen induces cell proliferation
and production of IFN- and IL-2 (54).
MHC-restricted interaction between antigen-reactive T cells and
irradiated spleen cells as APCs is required for the response. The major
antigenic epitope of antigen for V11+ Th1
cells in M. tuberculosis-primed mice is mapped as peptide-25 (amino acids 240 to 254). Neither antigen nor peptide-25 is a
superantigen (54). In this study, we were able to extend our previous findings and provide a more detailed analysis of the amino
acid residues of peptide-25 that are critical for TCRV11 and MHC
class II binding with peptide-25-reactive Th1 clones. Peptide-25 was
immunogenic in vivo and induced preferential generation of
V11+ Th1 cells. We also showed the efficacy of
peptide-25 immunization in protection against a subsequent challenge
with live M. tuberculosis H37Rv.
Over the past several years, a number of studies have attempted to
define the T-cell determinants of various antigens; common structures
or specific alignment of amino acids within peptides (motifs) is
required for binding to certain MHC molecules (37). In
contrast to MHC class I-bound peptides, demonstration of a distinct,
specific motif among peptides binding to MHC class II molecules has
proved difficult. Nonetheless, some motifs for particular MHC class II
molecules have emerged. For instance, it is known that antigenic
peptides comprising 10 to 12 amino acid residues are able to bind MHC
class II molecules. As was previously described (54),
peptide-25 consists of 15 amino acids and 11 amino acid residues at
positions 244 to 252 that are sufficient to stimulate peptide-25-reactive T-cell clones expressing TCRV11. This was confirmed by using a deletion mutant of peptide-25 [s-peptide-25 (AA243-253)] that retains the capacity to stimulate
peptide-25-reactive T-cell clones and is able to prime
s-peptide-25-reactive T cells in vivo (data not shown).
Peptide-25 contained a motif (Y-x-x-x-x-x-x-x-A) similar to the
I-Ab motif (F-x-x-x-x-x-x-x-A) described by Itoh et al.
(21). To examine the anchoring role of Y at position 244, we
made either an alanine or an aspartic acid substitution at this
position (Y244A or Y244D). Y244 of peptide-25 was important for
recognizing the MHC class II antigen. Evidence of this is the
comparative insensitivity of peptide-25-reactive V11+
T-cell clones to Y244D-substituted peptides: their effects were less
than 20% that of peptide-25 and were detectable only at higher concentrations (>10 µg/ml) (Fig. 3). It has been demonstrated that
there is a core sequence (P1 through P9) with nine amino acids for the
interaction between the antigenic peptide and MHC class II molecule, in
which P1 is the most conserved and the first anchoring amino acid
interacting with the HLA-DR or mouse I-E molecule (38).
Recently, it was also shown that P4 through P9, in particular P4, but
not P1 are able to interact with mouse I-Ak and
I-Ad molecules (15, 41). In these studies, we
observed that the responsiveness of peptide-25-reactive T-cell clones
to mutants of peptide-25 (Y244D and A247K) at positions P1 and P4 was
significantly lower than that to peptide-25. In contrast, the cells
responded similarly to A252R, a mutant of peptide-25 at position 252 (P9), as they did to peptide-25. Also, a binding assay revealed that A252R bound to the I-Ab molecule better than Y244D and
A247K. P1 through P4 of peptide-25 may be important in I-Ab
binding, and P9 might not be involved in the binding.
Mycobacteria has long been recognized for showing powerful immunologic
adjuvant activity that augments both cell-mediated and humoral immune
responses. A study of the mechanisms of pertussis and mycobacterial
adjuvants showed that adjuvants induced soluble mediators
later
determined to be cytokinesin T cells mediating the augmentation of
antibody responses (24). It is possible that the strong
immunogenicity of peptide stimuli contributes to the unique adjuvant
activity of mycobacteria by providing an initial burst of cytokines
favorable to the expansion of the T cells required for both antibody
production and cell-mediated immunity. In this regard, it is
interesting that immunization of B6 mice with 0.1 µg of peptide-25
(amino acids 240 to 254) or s-peptide-25 (amino acids 243 to 253) in
ICFA induces the development of V11+ T cells. Indeed,
our recent studies showed that 1 µg of peptide-25 in solution was
sufficient to induce the development of peptide-25-reactive V11+ Th1 cells in vivo.
It is worthwhile to test the feasibility of peptide-25 as an immunogen to protect live M. tuberculosis infection. Our experiments using M. tuberculosis H37Rv revealed that fewer CFU per lung in the immunized mice are observed early following challenge (days 7 and 14) but not later (days 21 and 28) (Fig. 2). Immunization of B6 mice with peptide-25 also induced a decreased number of CFU per lung 14 days after BCG infection (data not shown). Although results were variable from experiment to experiment, the differences in the bacterial burden in the liver between the immunized mice and the control mice never exceeded more than 0.5 log at any time point. Only on day 28 after M. tuberculosis H37Rv infection was the number of CFU per liver in immunized mice significantly decreased compared with that in control mice. In the spleen, there was no significant difference between the two groups. This may be due to the fact that immunization might decrease initial infection in the lungs but does not inhibit growth of the organisms implanted in the lungs. This may not be the case, though, because the number of CFU per lung at day 1 of infection in peptide-25-immunized mice was similar to that in nonimmunized mice (3.85 ± 0.23 log versus 3.73 ± 0.15 log). Because it is apparent that CD4+ T-cell responses are required for immunity to mycobacterium infection, peptide-25 immunization may not be sufficient to induce full immunity, as reported recently for the Listeria infection system. IL-12, IL-18, and tumor necrosis factor alpha may enhance the priming effect of peptide-25 on Th1 development during the process of inducing antituberculosis immunity. We may have to apply a more efficient regimen by employing a potent vehicle or by applying a different immunizing route for peptide-25 to induce potent protective immunity against M. tuberculosis H37Rv.
We infer from the data presented above that immunization with
peptide-25 does activate CD4 T cells that can participate in the
antituberculosis response but that these T cells, at least on their
own, are not fully protective. How may our results be extended to the
human situation, since the T-cell epitope of antigen is useful in
I-Ab mice? As discussed above, P1 and P4 of a core sequence
with nine antigenic amino acids for T-cell stimulation appear to be
important for binding to HLA-DR. In our analysis, P1 and P4 of
peptide-25 are important for mouse MHC class II binding. So, we believe
that our results might be extended to the human situation by using a
combination of peptide-25 antigens, each of which has amino acid
substitutions at P1 and P4 that bind to the HLA-DR molecule. Further
studies are needed to prove this hypothesis.
Recently, Huygen and his colleagues (19) found that a vaccination with plasmid DNA containing M. tuberculosis genes encoding hsp65, the 38-kDa PstS-1 homologue, and the Ag85 complex, which includes Ag85B, is an effective means of inducing protective immunity in animal models. Our data enhance the likelihood of using peptide-25 as a vaccine conferring antituberculosis immunity in humans.
In conclusion, the T-cell epitope mapping performed here shows that
peptide-25 of the mycobacterium antigen is able to prime and
stimulate IFN--producing Th1 cells in vivo. Synthetic peptide-25 is
not a mycobacterial superantigen, and it may contribute to pathogenesis by inducing the local release of a spectrum of cytokines from antigen-reactive T cells bearing V11-encoded mouse
TCRs. These observations underscore the immunodominant and
potentially protective character of antigen protein. Vaccination
experiments with defined peptides are now needed to further elucidate
the potential role of antigen and peptide-25 in protective immunity against mycobacteria.
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ACKNOWLEDGMENTS |
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We thank M. Howard, H. Nariuchi, H. Nakauchi, W. E. Paul, Y. Yoshikai, and O. Kanagawa for providing MAbs and S. Takaki and Y. Kikuchi for their valuable suggestions throughout this study. We are indebted to Williams F. Goldman and T. Kinashi for their critical review of this paper.
This study was supported in part by a grant-in-aid, a special grant for advanced research on molecular pathogenesis and immunointervention of immune disorders, from the Ministry of Education, Science, Sports and Culture of Japan and by research funds from the Meiji Milk Product Co. Ltd.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Immunology, Institute of Medical Science, University of Tokyo, 4-6-1 Shirokanedai, Minato-ku, Tokyo 108-8639, Japan. Phone: 81-3-5449-5260. Fax: 81-3-5449-5407: E-mail: takatsuk{at}ims.u-tokyo.ac.jp.
Editor: R. N. Moore
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REFERENCES |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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