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Infect Immun, June 1998, p. 2991-2995, Vol. 66, No. 6
Microbiology Unit,
Received 1 December 1997/Returned for modification 5 January
1998/Accepted 6 March 1998
Murine antibody responses to soluble proteins are generally
restricted to the immunoglobulin G1 (IgG1) isotype. When mice were
infected with Toxoplasma gondii Beverley and concomitantly immunized with a soluble unrelated protein antigen, a modification in
the isotypic distribution of antibodies directed against this nonparasite antigen was observed, with a preferential production of
IgG2a. Interestingly, when mice were immunized with a soluble protein
antigen during the chronic phase (day 40) of infection with T. gondii Beverley, a similar modification in the isotypic distribution of antiprotein antibodies was observed.
For mice, the current paradigm is
that CD4+ T cells can be separated into subsets on the
basis of the repertoire of cytokines produced and that the distinct
cytokine profile observed in these cells determines their function.
This model includes two major subsets: Th1 cells produce interleukin-2
(IL-2) and gamma interferon (IFN- Cytokine mRNA expression by spleen cells during the different
stages of T. gondii Beverley infections.
BALB/c
female mice (8 to 10 weeks old) were bred in isolators at the Ludwig
Institute for Cancer Research by G. Warnier and were infected
intraperitoneally (i.p.) with the weakly virulent Beverley strain of
T. gondii, isolated by J. K. A. Beverley
(5) and kindly provided by G. Desmonts from the Institut de
Puériculture, Paris, France, in 1977. Splenocytes were collected
at five time points after infection, and the expression of cytokine
mRNA was analyzed by reverse transcription-PCR as described
previously (14). Briefly, unfractionated spleen cells were
resuspended in TRIzol (Gibco) and frozen at IgG subclass distribution of antiparasite antibody
responses during acute and chronic T. gondii
Beverley infections.
NMRI female mice (6 to 8 weeks old) that were
obtained from the animal facility of the Catholic University of
Louvain, Brussels, Belgium, and BALB/c mice were infected i.p. with
weakly virulent T. gondii Beverley (28),
whereas other NMRI and BALB/c mice were kept as uninfected controls.
Heart blood samples were collected from mice by cardiac puncture under
anesthesia with diethyl ether. Between 100 and 1,000 µl of blood was
collected in EDTA or heparin on days 21 and 56 p.i.; the IgG
subclasses of anti-T gondii antibodies in individual mouse
plasma samples were determined by enzyme-linked immunosorbent assay
(ELISA). Briefly, microplates (Immunoplate Maxisorp F96; Nunc,
Roskilde, Denmark) were coated by overnight incubation at 4°C
with 100 µl of a lysate of T. gondii (6.5 µg of protein/ml) in phosphate-buffered saline (PBS) (pH 7.2). The plates were washed three times in PBS (pH 7.2). Wells were
saturated with 5% fetal calf serum (Gibco) in PBS for 15 min,
and then 100 µl of plasma diluted 1:50, 1:150, 1:450, or 1:1,350 in
PBS containing 0.5% Tween 20 (PBS-Tween 20) was added and incubated at
22°C for 30 min. After three washings in PBS, 100 µl of anti-mouse
IgG subclass rabbit antibody labeled with peroxidase (Serotec, Oxford, England), diluted 1:1,000 in PBS-Tween 20, was added and incubated for
30 min at 22°C. The plates were washed again before addition of
100 µl of chromogen (tetramethylbenzidine [27 g/liter] plus hydrogen peroxide [0.1 ml/liter]) (Sorin Biomedica, Saluggia, Italy)
solution. The reaction was stopped with 1 N
H2SO4. The absorbance of each sample was read
at 450 nm with a Sorin spectrophotometer. Results, expressed in
micrograms per milliliter, were calculated from standard curves
obtained with selected anti-DNP monoclonal antibodies (11).
For NMRI mice, the specific antibody concentration for each isotype
could be ranked in the acute phase (21 days p.i.) as IgG2b > IgG2a > IgG3 > IgG1 and in the chronic phase (56 days p.i.)
as IgG2a >> IgG2b > IgG3 > IgG1 (Table
1). For BALB/c mice, the levels of
T. gondii-specific IgG antibody isotypes could be ranked in the acute phase (21 days p.i.) as IgG2b = IgG2a > IgG3 > IgG1, whereas the chronic phase (56 days p.i.) was
characterized by higher levels, with IgG2a >> IgG2b > IgG3 > IgG1 (Table 1). This investigation has shown that T. gondii infection in mice induces a stable polyisotypic
parasite-specific response characterized by high concentrations of
IgG2a but not IgG1 antibodies. These findings confirm the observations
of Burke et al. (8), Suzuki et al. (33), and
Villard et al. (36). This positivity was maintained during
325 days (not shown). Little variation was observed between BALB/c and
NMRI mouse strains (Table 1). However, C57BL/10 mice produce less
IgG1 than BALB/c mice after infection with cysts of the RRA strain
(8, 29), whereas C57BL/6 animals produce IgG3 after
infection with cysts of the ME49 strain (33). The differences of the IgG subclass responses in different strains of
T. gondii or strains of mice can be influenced by the
susceptibility of the mice (15, 32). Different routes of
infection (orally, i.p., and subcutaneously) gave no significant
differences for the IgG subclass responses in mice (data not shown).
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Copyright © 1998, American Society for Microbiology. All rights reserved.
Acute and Chronic Phases of Toxoplasma
gondii Infection in Mice Modulate the Host Immune
Responses
ABSTRACT
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) and control the production of
immunoglobulin G2a (IgG2a), whereas Th2 cells produce IL-4, IL-5, and
IL-10 and control the production of IgG1 and IgE (17, 27).
These subsets cross-regulate each other. Which subset predominates may
determine the outcome of an infection. The weakly virulent species
Toxoplasma gondii triggers high levels of IgG2a in serum
(8, 33, 36) and induces persistent expression of IFN- and
IL-12 cytokines (19, 20, 22). In contrast, antibodies raised
after immunization with a soluble protein predominantly belong to the
IgG1 subclass (13); such soluble proteins induce IL-4 and
IL-10 cytokine expression (10, 26, 37). When some viruses,
like murine hepatitis virus or lactate dehydrogenase-elevating virus,
are inoculated concomitantly with such an immunization, the isotypic
distribution of antiprotein antibodies is biased in favor of IgG2a
(12); this phenomenon could have implications for the
development of autoimmune reactions (35). In the present
study, we analyzed the effect of acute and chronic infections with
T. gondii on the isotypic pattern of antibodies raised
against nonparasitic soluble protein antigens that usually raise a Th2
response characterized by IgG1 antibodies.
80°C. The cells were
then homogenized and processed for RNA isolation, after separation with
chloroform and precipitation with isopropanol as recommended by the
manufacturer; cDNA was prepared with Moloney murine leukemia virus
reverse transcriptase (Gibco) and amplified by PCR with a Gene Amp kit
(Perkin-Elmer Cetus) in a Techne PHC 3 programmable Dri-block (New
Brunswick Scientific, Duxford Cambridge, United Kingdom). Nucleotide
sequences of primers for actin, IL-12 (p40) (35 to 40), IFN- (30 to
35), and IL-4 (35 to 40) were the same as those we described previously (14, 26), as were the experimentally determined optimal
cycle numbers (indicated in parentheses). Nucleotide sequences of
primers for actin were 5'-ATG GAT GAC GAT ATC GCT GC-3' and 5'-GCT GGA AGG TGG ACA GTG AG-3', those for IL-12 (p40) were 5'-CTC ACA TCT GCT
GCT CCA CAA-3' and 5'-CTC CTT CAT CTT TTC TTT CTT-3', those for IFN-
were 5'-GAC AAT CAG GCC ATC AGC AAC-3' and 5'-CGC AAT CAC AGT CTT GGC
TAA-3', and those for IL-4 were 5'-ATG GGT CTC AAC CCC CAG CTA-3'
and 5'-GCA TGG TGG CTC AGT ACT ACG-3'. Analysis of cytokine messages
showed increased expression of IL-12 (p40) and IFN- mRNAs
in spleen cells as early as 2 days postinfection (p.i.) and up to 30 days p.i. (Fig. 1). These findings
confirm the recent observations of Burke et al. (8) and
Gazzinelli et al. (20). We could not detect expression of
IL-4 (Fig. 1). Because T. gondii is a potent stimulator
of IL-12 release by macrophages, the production of this cytokine early
in infection could be responsible for driving the parasite-specific
T-cell response in the Th1 direction. In addition, the effect may be
enhanced by IFN-, which has been shown to be a potent inhibitor of
Th2 cell proliferation (18). The observations by Gazzinelli
et al. (20) on levels of IL-4 and IL-10 synthesis in
anti-IL-12-treated mice support this hypothesis.
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FIG. 1.
Detection of IL-12 (p40), IFN- , IL-4, and actin
mRNAs in spleen cells of BALB/c mice infected with 20 cysts of
T. gondii Beverley. Spleen cells were harvested at time
zero (control animals) and at 1, 2, 4, 10, and 30 days p.i. as
indicated above the lanes and then frozen in TRIzol; mRNA
preparations were reverse transcribed, and specific messages were
amplified by PCR. Products of PCR amplification were detected by
ethidium bromide staining in agarose gels. Lane +, control for cytokine
mRNAs.
TABLE 1.
IgG subclass distribution of antibody responses during
acute and chronic T. gondii Beverley infections
IgG subclass distribution of anti-soluble-protein antibody
responses elicited concomitantly with acute and chronic T. gondii Beverley infections.
For the acute phase, the
experimental protocol is shown in Table
2. Six groups of BALB/c mice were used,
with five mice in each group. On day 0, three groups were immunized
with tetanus toxoid obtained from the Institut Pasteur (Brussels,
Belgium) or keyhole limpet hemocyanin or lactoferrin obtained from
Sigma (St. Louis, Mo.), while three other groups received the same
amount of antigen concomitantly with T. gondii Beverley
infection. In the chronic phase, 40 days after this infection with
T. gondii, the mice received one injection of
lactoferrin in PBS. All mice were bled on day 21. IgG antibody
subclasses in plasma were determined by ELISA as described by Coutelier
et al. (11). Briefly, microplates (Immunoplate Maxisorp F96)
were coated by overnight incubation at 4°C with purified proteins (10 µg/ml) and incubated with serial dilutions of sera. Binding of
antibodies was measured and calculated as for the anti-T.
gondii antibody ELISA. Antibodies raised in uninfected mice after
primary immunization with a soluble protein predominantly belonged to
the IgG1 subclass. The acute infection strongly increased the
proportion of IgG2a in antibodies directed against all of the antigens
tested (Table 2). Those modifications were mainly due to a dramatic
increase in absolute amounts of IgG2a (19.4- to 211.6-fold) rather
than to a decrease in IgG1 (1.2- to 7.4-fold). The isotypic profiles of
immunoglobulins after some DNA and RNA murine virus infections, as well
as parasitic diseases (malaria or trypanosomiasis), have been studied
previously; these infections mainly enhance IgG2a (3, 12,
34). Nematode and cestode parasites preferentially stimulate a
concomitant increase of IgG1 associated with a decrease of IgG2a levels
(39). The trematode Schistosoma mansoni induces
increased IgG1 without modification of IgG2a and IgG2b levels
(7). Coinfection with T. gondii and murine leukemia viruses (murine AIDS) increased susceptibility to
T. gondii and may alter the progression of murine AIDS
(24). Coinfection with Leishmania major and
T. gondii in albino mice showed that the clinical and
histopathological pictures for this concomitant infection differ
from those for infection with either parasite alone
(1). In L. major infection, BALB/c
mice immunized subcutaneously with a soluble leishmanial antigen
develop a Th2-like response in which IL-4-producing cells
dominate; in this model, coimmunization with recombinant IL-12
(rIL-12) induces a switch from Th2 to Th1 responses in which
IFN--producing cells dominate (2). IL-12
stimulates IFN- production by natural killer (NK) cells and T
cells (9, 19, 38), which in turn can trigger IgG2a
production by B lymphocytes (16, 31).
|
to protect mice against lethal challenge with
tetanus toxin (4). However, when some viruses
for example,
murine hepatitis virus or lactate dehydrogenase-elevating virusare
inoculated concomitantly with such a protein immunization, the isotypic
distribution of antiprotein antibodies is biased in favor of IgG2a.
This isotype modulation, which effects T-cell-dependent responses, is
observed only when the infection occurs around the time of immunization
(13). The isotypic bias induced at the time of the primary
immunization persists in subsequent secondary responses. Whether such a
bias in concomitant immune responses may increase the pathogenicity,
for instance, of other parasitic infections or of autoimmune diseases
remains to be determined.
In the viral model, infection initiated 3 days before or 4 days after
injection of soluble proteins does not influence the subclass
proportion of antibodies reacting with the nonviral protein antigen. In
contrast, and interestingly, we show here that after T. gondii inoculation, antilactoferrin IgG subclasses assayed in sera
of mice immunized with this antigen during the chronic infection with
the parasite display a sharp increase in IgG2a (18.9-fold) and a
decrease in IgG1 (12.5-fold) (Fig. 2).
The same results were observed at 40 days p.i. with NMRI mice. The
difference may be due to a more important Th1 cytokine environment in
chronically infected mice, preventing IL-4 secretion and IgG1
production in these animals. Experiments with mice infected with
T. gondii indicate that resistance to infection is
dependent upon IFN- during both the acute and chronic stages of
infection. NK cell production of IFN- is necessary but not
sufficient for acquired immunity to T. gondii, and T
cells (CD4+ and CD8+) are necessary to maintain
resistance in chronically infected mice (19, 20, 22).
IFN- production by these T cells may also stimulate antilactoferrin
IgG2a production, although IL-12 and IFN- produced by cells
that are activated during chronic infection are probably
responsible for the enhanced level of IgG2a antibodies
(18.9-fold).
|
IgG subclass distribution of primary antibody responses to
lactoferrin administered concomitantly with IL-12.
Two
groups of BALB/c mice were used, with five mice in each group. On
day 0, one group received 100 µg of lactoferrin per mouse, while the
other group received the same amount of antigen with 0.05 µg of
murine rIL-12 (provided by Genetics Institute, Inc., Cambridge, Mass.)
diluted in sterile PBS containing 1% normal mouse serum. All mice were
bled on day 21. Antibodies raised after immunization with lactoferrin
alone belonged predominantly to the IgG1 subclass. Immunization with
lactoferrin plus rIL-12 increased the IgG2a subclass antilactoferrin
antibodies. This modification was mainly due to a dramatic increase in
absolute amounts of IgG2a (20.1-fold) rather than to a decrease in IgG1
(1.6-fold) (Fig. 3). In mice immunized
with protein antigens or hapten-protein conjugate, IL-12 strongly
enhanced the humoral immune response by increasing the synthesis of
antigen-specific antibody of the IgG2a subclass (21, 25,
30). This influence on B-cell responses persists in the memory of
the immune system (6). In addition, the protein-IL-12
fusion protein was much more effective than free rIL-12 in enhancing
IFN- synthesis (by T-helper cells) and increasing serum antiprotein
IgG2a (23). In our study, rIL-12 administered together with
lactoferrin similarly increased the IgG2a subclass (20.1-fold) and
slightly decreased the IgG1 isotype (1.6-fold) (Fig. 3).
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ACKNOWLEDGMENTS |
|---|
We thank M. El Azami El Idrissi and N. Havaux for expert technical assistance.
J.P.C. is research associate with the Fonds National de la Recherche Scientifique (FNRS). This work was supported by a grant from Sorin Biomedica, Brussels, Belgium.
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FOOTNOTES |
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* Corresponding author. Mailing address: Cliniques Universitaires Saint-Luc, Avenue Hippocrate, 10, B-1200 Brussels, Belgium. Phone: 32-2-764 17 50. Fax: 32-2-7649310. E-mail: bigaignon{at}lewsun.md.ucl.ac.be.
Editor: J. M. Mansfield
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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