Development of cellular immunity to individual soluble antigens of Treponema pallidum during experimental syphilis

The contribution of individual specific molecules of Treponema pallidum subspecies pallidum to cellular immunity in experimental syphilis was evaluated by combining the techniques of Ag identification and purification with the lymphocyte proliferation assay. Proliferative responses of splenic lymphocytes from syphilitic rabbits to complex treponemal Ag and Con A were vigorous throughout the course of intratesticular infection (6, 10, 17, 30, and 210 days). Normal rabbits did not respond to any treponemal preparations and all rabbits failed to respond to normal rabbit testicular Ag (NRT). Seven defined treponemal Ag (47 kDa, 37 kDa, 35, 33-kDa, 30-kDa, 14 kDa, and 12 kDa) stimulated lymphocytes from infected rabbits. Cellular responses to the 37-kDa and 30-kDa fractions were evident by day 6 of infection and responses to the 35, 33-kDa and 14-kDa Ag were first detected on day 10; responsiveness to these Ag continued throughout the observation period. Cellular responses to the 47-kDa molecule were detectable but lower when compared with other individual Ag. Responsiveness to the 12-kDa Ag was not evident until 7 mo postinfection. Specific immunoblot reactivity of serum from rabbits used in this study generally correlated with the development of cellular reactivity to individual Ag of T. pallidum.     

Characterization of lymphocyte responsiveness in early experimental syphilis. I. In vitro response to mitogens and Treponema pallidum antigens

Lymphoid cells from spleens and lymph nodes of rabbits infected with T. pallidum respond by proliferation to concanavalin A (Con A) and T. pallidum antigens. Spleen cell responsiveness to treponemal antigens appears 6 days after infection, is 100 to 600 fold higher than the response of uninfected control rabbits, and is maintained throughout the 31-day observation period. Specifically responding cells in the inguinal and popliteal lymph nodes of infected animals are demonstrable on day 10, and the magnitude of the response increases throughout the observation period. Specific responsiveness to T. pallidum antigens in vitro is enhanced in purified T cell populations and is abolished by treatment with goat anti-rabbit thymocyte serum and complement. The response of spleen and lymph node cells to Con A is unaffected during syphilitic infection. These results are consistent with a role for T cell-mediated specific immunity to treponemal antigens early after infection and do not support a hypothesis of depressed cellular immunity during syphilitic infection.     

Characterization of the serum requirement for macrophage-mediated killing of Treponema pallidum ssp. pallidum: Relationship to the development of opsonizing antibodies

Abstract Serum pools were collected from rabbits bled at various times after intra-testicular infection with Treponema pallidum ssp. pallidum . These were tested for their ability to opsonize T. pallidum and promote killing of the organisms by macrophages. Compared to normal sera, significant opsonization was first seen on day 10 of infection as measured by both ingestion ( P < 0.001) and macrophage-mediated killing ( P = 0.006); significant levels of functional antibodies persisted through 300 days of infection. Although opsonic activity peaked early in infection, antibodies that promoted optimal macrophage-mediated killing developed much later, suggesting that these two functions may represent activities of antibodies with differing specificities or affinities. The initial development of antibodies that augment both phagocytosis and killing corresponds with the in vivo clearance of treponemes from the primary site of infection. These observations support the hypothesis that macrophages are the major effector mechanism for elimination of T. pallidum during early syphilis infection.     

Assessment of cell-surface exposure and vaccinogenic potentials of Treponema pallidum candidate outer membrane proteins

Syphilis, a sexually transmitted infection caused by the spirochetal bacterium Treponema pallidum, remains a global public health problem. T. pallidum is believed to be an extracellular pathogen and, as such, the identification of T. pallidum outer membrane proteins that could serve as targets for opsonic or bactericidal antibodies has remained a high research priority for vaccine development. However, the identification of T. pallidum outer membrane proteins has remained highly elusive. Recent studies and bioinformatics have implicated four treponemal proteins as potential outer membrane proteins (TP0155, TP0326, TP0483 and TP0956). Indirect immunofluorescence assays performed on treponemes encapsulated within agarose gel microdroplets failed to provide evidence that any of these four molecules were surface-exposed in T. pallidum. Second, recombinant fusion proteins corresponding to all four candidate outer membrane proteins were used separately, or in combination, to vaccinate New Zealand White rabbits. Despite achieving high titers (>1:50,000) of serum antibodies, none of the rabbits displayed chancre immunity after intradermal challenge with viable T. pallidum.     

Detection and functional characterization of early appearing antibodies in rabbits with experimental syphilis

Following testicular infection of rabbits with Treponema pallidum, different antibodies become detectable initially at the time of healing. Experiments were performed to determine a functional role for these antibodies. Rabbits were sacrificed after 4-8 days. Treponemal numbers steadily increased for 10-12 days. Thereafter, host defenses were sufficiently stimulated to begin clearing the organisms. Antibodies in serum and antibodies localized at the site of infection were quantitated using radioimmunoassay and enzyme-linked immunosorbent assay (ELISA) techniques. Anti-treponemal IgG was detected as early as day 4. Quantities of antibody correspondingly increased with time following infection. Treponema pallidum was harvested 7 and 14 days postinfection and tested for surface antibodies. With increasing days postinfection, more antibody was found on the organisms. Two functional properties of these antibodies were shown. Sera from 24 of 45 rabbits infected for 14 days immobilized T. pallidum in the presence of complement and 14-day sera blocked the attachment of T. pallidum to tissue culture cells. We suggest that antibody-mediated, complement-dependent immobilization of T. pallidum and blockage of attachment are at least partially responsible for healing of testicular lesions.     

Circulating immune complexes in experimental syphilis and their relation to immunological response against Treponema pallidum

It was found that circulating immune complexes (CIC) were formed in rabbits at different times after infection with Treponema pallidum. The CIC which appeared at the beginning of the disease were short-lived (2-6 weeks) but those appearing later than 20 weeks after infection remained for 10-25 weeks. CIC contained both IgM and IgG classes of immunoglobulin. The antibodies present in CIC were found to be specific and nonspecific for T. pallidum. The presence of CIC led to a marked decline of treponemal antibodies in rabbit sera. The cell-mediated immune response measured by the macrophage migration inhibition (MMI) test at the beginning of the disease (up to 12 weeks) was not decreased. However, when syphilis lasted for more than 14 weeks and when CIC were formed mainly from IgG, a distinct decrease in the ability of lymphocytes to cause MMI was observed. These findings strongly suggest that IgG-complexes suppress the immunological responsiveness of lymphocytes against T. pallidum which in turn facilitates the multiplication of treponemes in the host.     

Effect of sensitization with Propionibacterium acnes on the growth of Listeria monocytogenes and Treponema pallidum in rabbits.

Sensitization of rabbits with Propionibacterium acnes, a nonspecific stimulant of the reticuloendothelial system, was investigated as a means of enhancing resistance to Treponema pallidum. A single i.v. dose of P. acnes given 3 or 7 days before challenge with Listeria monocytogenes was capable of suppressing the growth of the heterologous organism, whereas a single i.v. dose 24 hr or 14 days before challenge was not. Reactivation via i.v. elicitation with P. acnes 14 days after sensitization (1 day before challenge) caused significant suppression of listerial growth in the major organs 30 hr after i.v. challenge. A series of similar experiments was designed with T. pallidum as the challenge organism. Sensitization and repetitive elicitation with P. acnes did not change the time of appearance or progression of syphilitic chancres after i.v or i.d. challenge. Injection of P. acnes into sites of intradermal T. pallidum challenge in previously sensitized rabbits also failed to alter the evolution of syphilitic lesions. These results suggest that macrophage activation does not alter the host's ability to suppress the growth of T. pallidum.     

Development of self-tolerance in normal mice. Appearance of suppressor cells that maintain adult self-tolerance follows the neonatal autoantibody response

T cell populations from BALB/c mice at different ages were analyzed to determine when in development Ts cells specific for the anti-mouse RBC (MRBC) autoantibody response become activated. Previous studies have shown that adult CD8+ T cells actively suppress this autoimmune response and adult spleen cells depleted of CD8+ cells can generate an anti-MRBC response in culture with MRBC. The present results demonstrate that T cells from mice less than 1 wk of age do not suppress the in vitro anti-MRBC response of adult spleen cell populations depleted of CD8+ Ts cells. By 2 wk of age Ts cells are detectable in this anti-self response and reach adult levels by 3 wk of age. Non-specific "natural suppressor" cells normally present in neonatal spleen cell populations are unable to suppress this autoantibody response, although they are active in suppressing anti-SRBC responses in the same cultures. Before the appearance of Ts cells active in the anti-MRBC response, neonatal spleen cell populations can generate anti-MRBC antibody-forming cells, both spontaneously in vivo and in vitro. The in vitro anti-MRBC response of neonatal spleen cells was shown to be Ag driven and Ag specific. The ability of unfractionated spleen cells to generate this response in vitro declines with age and is relatively low by 3 wk. This decline in responsiveness occurs simultaneously with the appearance of suppression specific for the anti-MRBC response, suggesting that the two events may be causally related.     

Experimental congenital syphilis in rabbits

A model for congenital syphilis in rabbits was developed based on multiple intravenous injections of pregnant does with high concentrations of Treponema pallidum. A total of 48 pregnant does and 394 newborns were evaluated. Indications of in utero infection included a 7- to 10-fold increase in fetal mortality and a 49% reduction in birth weight. The size of the stillborns varied. Some developed to normal size, whereas others were poorly developed, hemorrhagic, and 1/10th normal size. Fetuses were surgically removed after 25 to 28 days of gestation and extracts of the fetal tissues were injected into adult rabbits. Syphilitic lesions resulted demonstrating the presence of T. pallidum within the fetal tissues. Treponemes were also demonstrated within splenic tissue from a 1-week-old newborn. Isolated amniotic membranes were placed in Franz Biologic chambers. Viable organisms readily penetrated through the amnion but heat-inactivated organisms did not. Further evidence for in utero transmission of organisms was provided by intradermal injection of 6- to 7-week-old newborns. In control newborns in which the does were not infected during pregnancy, lesions occurred at 90% of the sites injected and developed in typical fashion. In newborns from does infected during pregnancy, lesions occurred in 18% of the sites injected and developed in atypical fashion (flat, nonulcerating, rapid healing). Finally, overt congenital syphilis did not occur if the does were immune prior to pregnancy, then infected with T. pallidum during pregnancy. The percent mortalities and birth weights of newborns were equivalent to control newborns from noninfected does.     

The ability of peripheral blood mononuclear cells of rabbits infected with Treponema pallidum to produce IL-2

Abstract It was previously found that the cell-mediated immune response involved in protection against Treponema pallidum is distinctly suppressed during some periods in the course of syphilis infection in rabbits. This may be a result of the weak ability of cells to produce Interleukin-2 (IL-2) as well as of IL-2 absorption. The ability of peripheral blood mononuclear cells (PBMC) of syphilitic rabbits to produce IL-2 develops within the first two weeks after infection reaching a maximum in about the eleventh week. In infection of longer duration, this capability was distinctly lowered. This low level of activity (no higher than in PBMC of normal rabbits) was maintained for 31 weeks. The ability of PBMC to absorb IL-2, in parallel with its production, was found at the same time in the course of syphilis infection (7–11 weeks). In long-lasting syphilis (more than 12 weeks) both abilities seem to be inhibited. Sera of syphilitic rabbits were found to have a higher level of IL-2 inhibitor than those of normal rabbits. Only in syphilis lasting 9 to 11 weeks, when the production of IL-2 was the greatest, was the level of IL-2 inhibitor nearly the same as in normal rabbit sera. In syphilis lasting longer, the increased level of inhibitor was accompanied by a decreased ability of cells to produce IL-2. These findings suggest that IL-2 inhibitor may be bound to IL-2 or IL-2 receptor on T lymphocytes and in this way would lead to weakening of T cell function and resistance against Treponema pallidum infection.     

Antigenic complexity of Treponema pallidum: antigenicity and surface localization of major polypeptides

The protein structure of Treponema pallidum was characterized by two-dimensional electrophoresis (2DE), consisting of isoelectric focusing (IEF, pH 5 to 7) in the first dimension and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in the second dimension. Up to 85 major polypeptide species could be detected in the organisms in 2DE gels by Coomassie Blue staining. The antigenicity of the individual polypeptides was determined by transferring the 2DE pattern to nitrocellulose paper and utilizing a sensitive immunoperoxidase procedure to demonstrate the reactivity of immunoglobulins in sera obtained from rabbits infected intratesticularly at least 6 mo previously. The infected rabbit serum reacted with virtually every major polypeptide detectable by protein staining techniques, indicating that infected rabbits produce antibodies against nearly all major T. pallidum proteins at the time when the animals exhibit systemic resistance to reinfection. Surface radioiodination of freshly purified T. pallidum by an Iodogen procedure yielded preferential labeling of a major polypeptide with an apparent m.w. of 39,000. The results of this study indicate that the antigenic complexity of T. pallidum is much greater than described previously. The 39-kd polypeptide appears to be a major surface constituent of T. pallidum and as such may play an important role in the induction of immunity to syphilis.     

Complement activation limits the rate of in vitro treponemicidal activity and correlates with antibody-mediated aggregation of Treponema pallidum rare outer membrane protein

A modification of the in vitro immobilization assay together with freeze-fracture analysis was used to determine the factors responsible for the prolonged time required in vitro to achieve killing of Treponema pallidum subsp. pallidum. The modified immobilization assay permitted separate determination of the time required for binding of antibody to the surface of T. pallidum and for C activation. Treponemes were preincubated in heat-inactivated immune rabbit serum (IRS) followed by washing the organisms in 2.5% BSA/PBS to remove unbound IRS antibody before the addition of C. The results showed that a comparable degree of C-dependent killing occurred when treponemes were preincubated in heat-inactivated IRS for either 30 min or 16 h, indicating that treponemicidal antibody rapidly binds to the surface of T. pallidum. Preincubation of treponemes for 17 h in heat-inactivated IRS followed by a 1-h incubation in C resulted in the loss of 80% treponemal motility, indicating that C activation results in rapid killing of T. pallidum. Treponemes preincubated in IRS for 1 h, then incubated for 8 h and 16 h in heat-inactivated normal serum also lost a significant level of motility after the addition of C; in contrast, motility was unaffected after 30 min and 4 h of incubation in heat-inactivated normal serum under similar conditions. These results demonstrate that, whereas antibody binding to and C-mediated killing of treponemes can proceed rapidly, the prolonged time to C activation limits the rate at which treponemicidal activity occurs in vitro. In addition, treponemicidal activity using the modified immobilization assay could not be demonstrated with antiserum against T. pallidum endoflagella, antiserum against proteins solubilized from T. pallidum using the detergent Triton X-114, and a mAb to the T. pallidum r190-kDa "4D" protein, suggesting that these molecules are not accessible to surface binding antibody. Freeze-fracture analysis, recently used in our laboratory to demonstrate that the outer membrane of T. pallidum has rare constituent protein, was utilized to demonstrate outer membrane target Ag of IRS antibody. T. pallidum rare outer membrane protein (TROMP) molecules were shown in freeze-fracture electron micrographs to be consistently aggregated following a 16-h incubation of treponemes in IRS. In contrast, no aggregation of TROMP was present in treponemes incubated in normal rabbit serum for 16 h or in treponemes incubated in IRS for 2 h. These findings suggest that the rate of C activation leading to in vitro treponemicidal activity is limited by the time required for aggregation of antibody-bound TROMP molecules.     

Depletion of eosinophils by anti-IL-5 monoclonal antibody treatment of mice infected with Trichinella spiralis does not alter parasite burden or immunologic resistance to reinfection.

Mechanisms of parasite killing by eosinophils are widely studied and are often implicated in mediating resistance to parasitic infection, especially in conjunction with specific antibodies. Evidence for the eosinophil as an anti-parasite killer cell in vivo is limited and may not justify the belief that eosinophils engage and/or kill infective helminths. We reexamined this question in a mouse model of trichinosis in which antisera to eosinophils were previously used to show the requirement for eosinophils in resistance to this nematode. The current studies used mAb to IL-5 to suppress eosinophil levels in CF1 mice infected with Trichinella spiralis. In mice given a primary infection and injected with an isotype control mAb or left untreated, the medullary and peripheral blood eosinophil numbers peaked at 3 wk postinfection (PI) and returned to baseline levels by 4 wk PI. Peripheral blood eosinophil numbers in infected mice injected with anti-IL-5 were maintained at levels below those of uninfected normal mice through 4 wk of infection. Histologically, there was a prominent eosinophil accumulation in infected, untreated, or control-mAb-treated mice associated with nurse cell complexes containing infective juveniles in skeletal muscle at 3 and 4 wk PI. This was largely eliminated in mice treated with anti-IL-5 mAb. However, the number of muscle stage juvenile worms recovered 3 and 4 wk PI after acid pepsin digestion was unaffected by eosinophil depletion. Challenge infections, in which mice were infected at day 0 with 125 muscle stage worms and challenged at day 28 PI with 350 muscle stage worms, developed peak eosinophil numbers in bone marrow and peripheral blood 3 wk after primary infection and 2 wk after challenge infection in mice receiving either no treatment or control mAb. In challenged mice receiving anti-IL-5 mAb, medullary and peripheral blood eosinophil numbers remained at or below those of uninfected animals. Although all groups exhibited significant resistance measured as muscle stage worm burdens 56 days PI, eosinophil depletion did not affect resistance of muscle worm recovery. These results suggest that eosinophils are not essential in the control of T. spiralis in either primary or challenge infections of CF1 mice. This in vivo study illustrates the questionable value of in vitro killing assays to assign effector function to any single inflammatory cell type.     

Correlation of treponemicidal activity in normal human serum with the presence of IgG antibody directed against polypeptides of Treponema phagedenis biotype Reiter and Treponema pallidum, Nichols strain

Normal human serum (NHS) was shown to have complement-dependent treponemicidal activity against both Treponema pallidum and Treponema phagedenis biotype Reiter (TPR) by employing in vitro-in vivo neutralization and TPR plaque assays, respectively. The molecular basis of NHS treponemicidal activity was studied by immunoblot analysis in conjunction with treponemicidal assays. Five major T. pallidum polypeptide bands (47kDa, 35kDa, 33kDa doublet, and 30 kDa) and three major TPR polypeptide bands (47kDa and 33kDa doublet) bound IgG present in NHS. Absorption of NHS with TPR completely removed both TPR and T. pallidum treponemicidal activity; corresponding immunoblots demonstrated a significant removal of IgG antibody against all three TPR polypeptide bands as well as four T. pallidum polypeptide bands (30kDa, 33kDa doublet, and 35kDa). In contrast, T. pallidum absorption of NHS was found to remove treponemicidal activity against T. pallidum but not TPR; corresponding Western blots showed the complete removal of IgG antibody against all but one T. pallidum polypeptide band (47kDa) but no detectable loss in IgG antibody against the TPR polypeptides. These results suggest that antibody in NHS generated against nonpathogenic, indigenous treponemes is responsible for the T. pallidum treponemicidal activity. Furthermore, the treponemicidal activity against T. pallidum correlated with the presence of IgG antibody against T. pallidum polypeptides of 30kDa, 35kDa, and a 33kDa doublet.     

Further evidence for hyaluronidase activity of Treponema pallidum

The presence of hyaluronidase in preparations of Treponema pallidum was previously shown using acidified bovine serum albumin reactions and Ouchterlony immunodiffusion. To expand on these preliminary findings more sensitive techniques of viscometry, additional immunologic reactions, and altered capillary permeability were used to characterize treponemal-associated hyaluronidase. The pathogens T. pallidum and T. pertenue degraded hyaluronic acid, whereas the nonpathogens T. denticola and T. vincentii did not. As syphilitic infection progressed, hyaluronidase activity decreased; organisms harvested from 14-day testicular infections degraded hyaluronic acid less rapidly than organisms from 4-day infections. Uninfected rabbit testicular extract also exhibited significant enzyme activity. The neutralizing activity of immune sera was decreased by prior adsorption with bovine hyaluronidase, suggesting that some of the neutralizing factors are associated with this enzyme. Radioimmunoassay was used to quantitate antibodies to hyaluronidase in immune sera. Antihyaluronidase sera were isolated from rabbits immunized with bovine hyaluronidase. Treponema pallidum, as well as uninfected rabbit testicular extract, cross-reacted with these antisera. Immunofluorescence indicated that the hyaluronidase was uniformly distributed along the treponemal surface. As a final indicator of hyaluronidase activity, alterations in capillary permeability were detected 1 h after intradermal injection of T. pallidum.     

Automated, Quantitative Microhemagglutination Assay for Treponema pallidum Antibodies

An automated, quantitative microhemagglutination assay for antibodies to Treponema pallidum was developed by using T. pallidum-sensitized erythrocytes and an automatic serial-dilution instrument. Reactivity was found in sera from 54 rabbits and 6 chimpanzees infected with T. pallidum. Reactivity was also found in sera from animals infected with T. pertenue, T. carateum, and T. cuniculi. No reactivity was found in sera from 75 normal rabbits or from 129 rabbits immunized with cultivatable treponemes or a variety of other bacteria. In approximately 3 min, 13 twofold serial dilutions of each of 8 preabsorbed sera and the addition of sensitized erythrocytes to each dilution were accomplished automatically. The automated assay can serve as a research tool in quantitating antibodies to pathogenic treponemes, and evaluation of its clinical usefulness seems warranted.     

Role of IFN-gamma in regulating T2 immunity and the development of alternatively activated macrophages during allergic bronchopulmonary mycosis

Pulmonary Cryptococcus neoformans infection of C57BL/6 mice is an established model of a chronic pulmonary fungal infection accompanied by an "allergic" response (T2) to the infection, i.e., a model of an allergic bronchopulmonary mycosis. Our objective was to determine whether IFN-gamma plays a role in regulating the pulmonary T2 immune response in C. neoformans-infected C57BL/6 mice. Long-term pulmonary fungistasis was lost in IFN-gamma knockout (KO) mice, resulting in an increased pulmonary burden of fungi at wk 3. IFN-gamma was required for the early influx of leukocytes into the lungs but was not required later in the infection. By wk 3, eosinophil and macrophage numbers were elevated in the absence of IFN-gamma. The inducible NO synthase to arginase ratio was lower in the lungs of IFN-gamma KO mice and the macrophages had increased numbers of intracellular cryptococci and YM1 crystals, indicative of alternatively activated macrophages in these mice. There was evidence of pulmonary fibrosis in both wild-type and IFN-gamma KO mice by 5 wk postinfection. IFN-gamma production was not required for the development of T2 cytokine (IL-4, IL-5, IL-13) producing cells in the lungs and lung-associated lymph nodes or induction of an IgE response. At a number of time points, T2 cytokine production was enhanced in IFN-gamma KO mice. Thus, in the absence of IFN-gamma, C57BL/6 mice develop an augmented allergic response to C. neoformans, including enhanced generation of alternatively activated macrophages, which is accompanied by a switch from a chronic to a progressive pulmonary cryptococcal infection.     

Delayed onset muscle soreness following repeated bouts of downhill running

Perceived muscle soreness ratings, serum creatine kinase (CK) activity, and myoglobin levels were assessed in three groups of subjects following two 30-min exercise bouts of downhill running (-10 degrees slope). The two bouts were separated by 3, 6, and 9 wk for groups 1, 2, and 3, respectively. Criterion measures were obtained pre- and 6, 18, and 42 h postexercise. On bout 1 the three groups reported maximal soreness at 42 h postexercise. Also, relative increases in CK for groups 1, 2, and 3 were 340, 272, and 286%, respectively. Corresponding values for myoglobin were 432, 749, and 407%. When the same exercise was repeated, significantly less soreness was reported and smaller increases in CK and myoglobin were found for groups 1 and 2. For example, the percent CK increases on bout 2 for groups 1 and 2 were 63 and 62, respectively. Group 3 demonstrated no significant difference in soreness ratings, CK activities, or myoglobin levels between bouts 1 and 2. It was concluded that performance of a single exercise bout had a prophylactic effect on the generation of muscle soreness and serum protein responses that lasts up to 6 wk.     

Use of recombinant antigens for detection of Toxoplasma gondii infection in swine

Five recombinant Toxoplasma gondii antigens, designated B427, C51, C55, V22, and MBP30 were assessed for their potential use in an enzyme-linked immunoassay (EIA) for detection of T. gondii infection in swine. The antigens were evaluated with sera from young pigs that had been fed 1-10,000 T. gondii oocysts of the VEG or GT-1 strains. Results were compared with an EIA using a native T. gondii antigen extract. All 5 recombinant antigens, as well as native antigen, detected antibody responses as soon as 3 wk after infection in pigs inoculated with 1 or 10 oocysts of the VEG strain. This antibody response persisted, at varying levels, for 14 wk when the experiment was terminated. All antigens also detected antibody responses in pigs 4 wk after inoculation with 10,000 oocysts of the GT-1 strain. The antibody response recognized by native antigen remained high through 51 wk after inoculation. However, there was considerable animal-to-animal variation in responses to the individual recombinant antigens. Only antigens C51 and MBP30 consistently detected a positive antibody response over the entire 51-wk course of the experiment. These results suggest that these antigens might be useful for the serological detection of T. gondii infection in pigs.