Immune depression in trypanosome-infected mice. III. suppressor cells

Low-dose intradermal infection with trypanosoma congolense leads to expansion of regulatory T cells and enhanced susceptibility to reinfection

BALB/c mice are highly susceptible to experimental intraperitoneal Trypanosoma congolense infection. However, a recent report showed that these mice are relatively resistant to primary intradermal low-dose infection. Paradoxically, repeated low-dose intradermal infections predispose mice to enhanced susceptibility to an otherwise noninfectious dose challenge. Here, we explored the mechanisms responsible for this low-dose-induced susceptibility to subsequent low-dose challenge infection. We found that akin to intraperitoneal infection, low-dose intradermal infection led to production of interleukin-10 (IL-10), IL-6, IL-12, tumor necrosis factor alpha (TNF-α), transforming growth factor β (TGF-β), and gamma interferon (IFN-γ) by spleen and draining lymph node cells. Interestingly, despite the absence of parasitemia, low-dose intradermal infection led to expansion of CD4+ CD25+ Foxp3+ cells (T regulatory cells [Tregs]) in both the spleens and lymph nodes draining the infection site. Depletion of Tregs by anti-CD25 monoclonal antibody (MAb) treatment during primary infection or before challenge infection following repeated low-dose infection completely abolished the low-dose-induced enhanced susceptibility. In addition, Treg depletion was associated with dramatic reduction in serum levels of TGF-β and IL-10. Collectively, these findings show that low-dose intradermal infection leads to rapid expansion of Tregs, and these cells mediate enhanced susceptibility to subsequent infection.

Susceptibility and resistance to Trypanosoma congolense infections

We have put emphasis on recent findings in experimental Trypanosoma congolense infections in highly susceptible BALB/c and relatively resistant C57Bl/6 mice. Based on various analyses, it has been shown that a major difference in resistance to T. congolense infections is expressed early in infection at the macrophage level. A novel plastic-adherent Thy1.2(+) suppressor lymphocyte, which in absolute synergy with a Thy 1.2(-) cell exerts its suppression via interleukin-10 and interferon-gamma opens up an exciting new field of research.

Experimental Murine Trypanosoma congolense Infections. II. Role of Splenic Adherent CD3+ Thy1.2+ TCR-αβ− γδ− CD4+8− and CD3+ Thy1.2+ TCR-αβ− γδ− CD4−8− Cells in the Production of IL-4, IL-10, and IFN-γ and in Trypanosome-Elicited Immunosuppression

Trypanosome-induced suppression of T and B cell responses to parasite-related and -unrelated Ags is considered a major mechanism of evasion of the host’s immune defenses by the parasite. Reduced T and B cell responses have been attributed to suppressor T cells, suppressor macrophages, or both. We have previously shown that endogenously produced IL-10 and IFN-γ mediate the suppression of T cell responses in Trypanosoma congolense-infected mice. Here, we show for the first time that splenic CD3+ Thy1.2+ αβ− γδ− CD4+8− and CD3+ Thy1.2+ αβ− γδ− CD4−8− cells that copurify with plastic-, nylon wool-, or Sephadex G-10-adherent cell populations, in synergy with adherent Thy1.2− cells, are the major producers of IL-4, IL-10, and IFN-γ in T. congolense-infected mice. We further demonstrate the involvement of these cells in the suppression of T cell proliferative responses to mitogen and in B cell responses to a parasite-unrelated Ag.

Partial protection against natural trypanosomiasis after vaccination with a flagellar pocket antigen from Trypanosoma brucei rhodesiense

Cattle that were inoculated with an antigen derived from the flagellar pocket of Trypanosoma brucei rhodesiense and then infected with Trypanosoma congolense and Trypanosoma vivax were compared with unvaccinated cattle when both groups of cattle were placed in regions of Kenya endemic for tsetse flies known to harbour T. congolense and T. vivax. In one trial, 90 cattle were employed, 40 untreated controls, 30 cattle given prior treatment with samorin, and 20 inoculated with a flagellar pocket (Fp) antigen derived from T. brucei rhodesiense, with bovine serum albumin as the carrier and alum as the adjuvant. The animals were monitored for parasitaemia, by buffy coat analysis, during one rainy season. The untreated controls had 58% infection, the samorin-treated cattle had 43% infection, and the immunized cattle had 26% infection. Simultaneously, a second trial was conducted using 250 cattle, 100 untreated controls and 150 inoculated with the above antigen, carrier and adjuvant. At the end of the same rainy season, the untreated controls had 22% infection while the immunized animals had 9% infection. In a third experiment, on the same ranch as the latter experiment, ovalbumin was employed as the carrier. After 15 months, or over three rainy seasons, 13% of the untreated controls became infected while of the 177 immunized animals 0.9% became infected. These results are the first report of heterologous immunoprotection against trypanosomiasis in cattle.

Suppression of T-Cell Responsiveness during Tsetse-Transmitted Trypanosomiasis in Cattle

In the present study, we demonstrate that lymph node cells from cattle infected with T. congolense through tsetse fly challenge were unable to proliferate in vitro following activation with the T-cell mitogen Concanavalin A. This was associated with a simultaneous suppression of interleukin 2 (IL-2) production and interleukin 2 receptor (IL-2R) expression. However, the capacity of the cells to secrete interferon gamma following the mitogenic activation was not affected by the infection.

Nitric oxide mediates suppression of T cell responses in murine Trypanosoma brucei infection

African trypanosomes induce a generalized state of immunosuppression in their mammalian hosts. One characteristic of this is a suppression of lymphocyte responses to mitogen, which is mediated by suppressor macrophages. We investigated the involvement of nitric oxide in this phenomenon. Both peritoneal and splenic cell cultures from infected mice released nitrite and this was inhibitable by NG-monomethyl L-arginine (L-NMMA). The release of nitrite correlated with suppressed splenic T cell proliferative responses to concanavalin A. It was shown that adherent spleen cells from infected mice mediate suppression, which could be abrogated by L-NMMA. These results suggest that in T. brucei infection, the activation of macrophages to produce nitric oxide leads to impaired lymphocyte responses and immunosuppression.

Suppression of interleukin 2 secretion and interleukin 2 receptor expression during tsetse-transmitted trypanosomiasis in cattle

Infection with Trypanosoma congolense in cattle was found to be associated with a profound suppression of the host's immune system. Lymph node cells from infected cattle were unable to secrete interleukin 2 (IL 2) in vitro following mitogenic stimulation and the exogenous supply of IL 2 did not restore T cell proliferative responses. This was associated with an impaired expression of the alpha chain of the IL 2 receptor (IL 2R alpha). Co-culture experiments, where cells from an infected animal were mixed with cells from a major histocompatibility complex-matched normal animal, demonstrated the presence of suppressor cells capable of blocking both IL 2 secretion and IL 2R alpha expression. Removal of macrophages by fluorescence-activated cell sorting abrogated suppression in such co-cultures. Following depletion of macrophages, lymph node cells from an infected animal expressed IL 2R alpha at a normal level, but remained incapable of producing IL 2. Hence, the unresponsiveness was associated with macrophage-like suppressor cells which operated at the level of both IL 2 secretion and IL 2R alpha expression, and to an intrinsic unresponsiveness of the T cells which was restricted to IL 2 secretion. Inhibition of prostaglandin synthesis by addition of indomethacin failed to abrogate suppression of either IL 2 secretion or IL 2R alpha expression. This revealed a major difference between the regulation of suppression in murine model infections where the suppression of IL 2 secretion is due to prostaglandin secretion, and the situation in cattle where prostaglandins would not appear to be involved.

Suppressor and protector factors derived from Trypanosoma lewisi

Trypanosoma lewisi is a specific protozoan blood parasite of rats. Normal rats infected 2 h after treatment with plasma from day 8 irradiated (8.5 Gy) infected rats had significantly higher parasitaemia; in contrast, animals infected 7 days post-plasma treatment were significantly protected. Trypanolytic and ablastic antibodies could be demonstrated in the serum of normal rats treated with the plasma; the trypanolytic antibodies were stage-specific. Suppression of normal rat splenocyte responses to Con A and lipopolysaccharide (LPS) stimulation were also observed in the presence of different protein concentrations of whole lysate from epimastigote forms. The suppression by mitogen Con A was ablated by the addition of exogenous IL 2, or by washing cells incubated with the lysate prior to mitogen stimulation. These results indicate that immunoregulatory factors are present in the plasma of rats infected with T. lewisi, and the effect of these factors can be demonstrated in vitro with whole parasite lysate. The restoration of normal splenocyte responses to Con A by addition of exogenous IL 2 or by washing cells suggests that the suppressor factor(s) act(s) on the T cells by inhibiting their proliferation and IL 2 production, and the continued presence of these products is essential in the maintenance of suppression.

Suppressive macrophages occurring in murine Trypanosoma brucei infection inhibit T-cell responses in vivo and in vitro

Intraperitoneal injection of Trypanosoma brucei AnTat 1.1 into mice of the C3H.He, BALB/c or C57BL/6 strains resulted in impaired immune responses from day 3 onwards, as measured by the reduction in DNA synthesis in spleen cell populations stimulated with concanavalin A (Con-A) in vitro. Adherent cells from the peritoneum (PC) or from the spleen of infected mice, consisting predominantly of macrophages, caused a 60-80% reduction of the Con-A response in spleen cells from syngeneic recipients 3-4 days after transfer in vivo. Adherent PC from irradiated or athymic mice were equally suppressive. Spleen cells from infected mice reduced the proliferative response of spleen cells from uninfected mice upon co-cultivation in vitro. This dominant suppressive effect was abolished after the selective removal of macrophages from the spleen cell population by treatment with L-leucine methylester. Moreover, the macrophage-depleted spleen cells from infected mice responded normally to Con-A provided they were supplemented with splenic adherent cells from naive mice as a source of accessory cells. Both the cell transfer and co-cultivation experiments suggest that infection with African trypanosomes changes the properties of macrophages to a state which allows them actively to suppress immune responses.

Dual role of macrophages in the suppression of interleukin 2 production and interleukin 2 receptor expression in trypanosome-infected mice

Lymph node cells derived from T. brucei-infected mice fail to produce interleukin 2-(IL2) subsequent to a potent mitogenic trigger and actively suppress the capacity of normal cells to produce IL2 in co-culture experiments. The depletion of Thy-1+ cells does not decrease but rather increases the suppressive potential of the LNC derived from infected mice. A T cell-enriched nylon wool-nonadherent fraction, on the other hand, is not suppressive. The suppression of IL2 production is promptly restored by the addition of prostaglandin synthesis inhibitors suggesting a key role of the prostaglandin-producing macrophages. Our data indicate that such macrophages do not act indirectly through the induction of suppressor T cells, but rather directly interfere with the normal lymph node cells. In contrast to the essential role of prostaglandins in the impairment of IL2 production, these mediators are not involved in the suppression of IL2 receptor expression. Lymph node cells derived from Trypanosoma brucei-infected mice fail to produce interleukin 2 (IL2) subsequent to a potent mitogenic trigger and actively suppress the capacity of normal cells to produce IL2 in co-culture experiments. The depletion of Thy-1+ cells does not decrease but rather increases the suppressive potential of the LNC derived from infected mice. A T cell-enriched nylon wool-nonadherent fraction, on the other hand, is not suppressive. The suppression of IL2 production is promptly restored by the addition of prostaglandin synthesis inhibitors suggesting a key role of the prostaglandin-producing macrophages. Our data indicate that such macrophages do not act indirectly through the induction of suppressor T cells, but rather interfere directly with the normal lymph node cells.

Suppression of interleukin-2 production by macrophages in genetically susceptible mice infected with Leishmania major

Spleen cells from BALB/c mice infected with 2 X 10(7) L. major promastigotes and developing progressive disease produced significantly lower levels of interleukin-2 (IL-2) in response to concanavalin A stimulation than did spleen cells from uninfected mice. In contrast, spleen cells from sublethally irradiated and infected mice, which were able to contain lesion development, produced significantly higher levels of IL-2. The increase in IL-2 production closely paralleled lesion regression. Mice protectively immunized by four intravenous injections with lethally irradiated promastigotes also produced enhanced levels of IL-2, which were sustained after challenge infection. In contrast, spleen cells from BALB/c mice given four s.c. injections of irradiated promastigotes produced high levels of IL-2 before but not after infection. These mice eventually produced levels of IL-2 indistinguishable from those of unimmunized mice with progressive disease. There is thus an inverse relation between disease progression and the ability of spleen cells to produce IL-2. Spleen cells from mice with uncontrolled disease not only produced lower levels of IL-2 but also impaired IL-2 production by normal spleen cells. The ability to inhibit IL-2 was abrogated by passing the cells through a Sephadex G-10 column, removal of plastic adherent cells, and removal of carbonyl iron-ingesting cells. Furthermore, Sephadex G-10 column-treated and plastic adherent, nonspecific esterase-positive spleen cells from mice with progressive disease were able to suppress IL-2 production by normal splenic T cells. The suppressive activity of the adherent cells was not affected by treatment with anti-Thy-1.2 antibody and complement. In contrast, adherent spleen cells from uninfected mice were devoid of such suppressor activity. The depressed IL-2 production by spleen cells from progressively infected mice could be restored to that of normal spleen cells by the addition of indomethacin to the culture. There was however, no correlation between IL-2 production and IL-1 activity in infected or immunized BALB/c mice. Thus, it appears that the suppression of IL-2 production is mediated by prostaglandins elaborated by macrophages from chronically infected mice.

Suppressor factor of T-cell activation and decreased interleukin 2 activity in experimental African trypanosomiasis

Spleen cells from Trypanosoma brucei-infected BALB/c mice were unable to respond to a T-cell mitogen, concanavalin A. Moreover, they were unable to produce detectable amounts of the growth factor required for T cell proliferation, interleukin 2. In addition, supernatants from 24-h in vitro cultures of these cells produced a slight but detectable suppressive activity of the interleukin 2-dependent proliferation of a T-cell line. Infected spleen cells also suppressed the response of T. brucei-immunized spleen cells as well as normal spleen cells to concanavalin A. However, a major difference was shown in the mechanism of the suppression in both systems. Suppression of normal spleen cells required cell-to-cell contact. In contrast, suppression of 30-day T. brucei-immune cells could be mediated by a soluble suppressor factor released by in vitro culture of infected spleen cells. This molecule had an apparent molecular weight of 18,000. Finally, similar suppression could be generated in 30-day T. brucei-immune spleen cells but not in normal cells, with living cells but not with extracts of T. brucei.

Lymphocyte function in experimental African trypanosomiasis. VIII. Loss of suppressor T cell function in lymph nodes

The immunosuppression that occurs in mice experimentally infected with African trypanosomiasis has been examined further. In the present study we have examined lymph node cells from Trypanosoma rhodesiense-infected C57Bl/6J mice for the ability to produce mitogen induced antigen-nonspecific suppressor T cells (Ts). Inguinal, mesenteric, and brachial lymph node cells were harvested from uninfected control mice and from mice at different periods of infection. These cells were cultured with or without concanavalin A (Con A) for 48 hr to induce Ts activity. After stimulation, the control and infected lymph node cells were passed over Sephadex G-10 columns to remove suppressor macrophages that arise during the infection from Con A-induced Ts. The column passed cells were then added to normal mouse responder spleen cells in a primary in vitro antibody response culture system with sheep erythrocytes (SRBC) as antigen. The resultant plaque-forming cell responses to SRBC indicated that Ts function was not induced in infected lymph node cell populations. However, early in the infection, a stimulatory signal was provided by both the untreated and Con A-treated infected lymph node cells, which was lost in the terminal stage. Determinations of T cell subpopulations revealed that the infected Lyt 2.2-bearing subpopulation was not significantly altered from normal controls. We conclude that T. rhodesense infected mice fail to mount normal lymph node cell antigen nonspecific Ts responses and that this loss of activity may be due to an intrinsic dysfunction in the suppressor T cell population.

Interaction of African trypanosomes with the immune system

African trypanosomes cause disease in man and domestic animals. The parasites have the ability to escape immune control by two means: by antigenic variation of the surface glycoprotein coat so that waves of variant parasites arise and by inducing a general immunosuppression affecting immune responses to the parasite as well as to parasite-unrelated antigens. The cellular basis of the immune dysfunction will be discussed in relation to a mouse model system - it is the result of proliferative stimuli to T- or B-cells which then become refractory to selection by antigen and normal control signals. Recent experiments have focused on macrophages as important direct target cells for parasite action. We have obtained no evidence for a parasite derived mitogen acting directly on B- or T-cells. In vitro cell proliferation is associated with accessory cells and relates only to T-cells. During infection, macrophages become activated with changes in receptor expression and mediator release, so that there is, for example, spontaneous IL-1 release (with a role in T- and possibly in B-cell proliferation) and several-fold increases in PGE2 secretion, with its immunosuppressive activities. We also find parasitaemia-associated release of alpha-beta and gamma interferon by various cells which in turn influences immune function. The active parasite component is associated with parasite membranes, but its nature has not been further defined. We proposed that the macrophage changes provide a general pathway causing immune dysfunction associated with many infections, be they parasitic or caused by other invading organisms.

Lymphocyte function in experimental African trypanosomiasis. VII. Loss of antigen-nonspecific suppressor-T-cell activity

The extent of immunosuppression occurring in mice infected with the pathogenic African trypanosomes was studied. Spleen cells from Trypanosoma rhodesiense-infected C57BL/6J mice were tested for antigen-nonspecific suppressor-T-cell (Ts) activity after concanavalin A (Con A) treatment in vitro. After exposure to Con A, control and infected mouse spleen cells were added to responder spleen cell cultures stimulated with sheep erythrocytes (SRBC). Assays for the resultant plaque-forming cell responses to SRBC revealed that antigen-nonspecific Ts activity was lost during the first week of infection. Changes in infected mouse T-cell subpopulations, including a terminal loss of Lyt 2.2+ cells, accompanied but did not precede the demonstrable loss of Ts function. Splenic suppressor macrophages which arise during infections with T. rhodesiense also did not seem to be associated with the loss of antigen-nonspecific Ts activity. It is concluded that the generalized immunosuppression associated with experimental African trypanosomiasis extends to the mitogen-induced Ts population.

Regulation of the growth and differentiation of Trypanosoma (Trypanozoon) brucei brucei in resistant (C57Bl/6) and susceptible (C3H/He) mice

While Trypanosoma brucei brucei GUTat 3 were equally infective for C3H/He and for C57Bl/6 mice at doses ranging from 5 to 5 x 10(3) organisms and had similar prepatent periods in both strains of mice, infected C57Bl/6 mice displayed lower parasitaemia, shorter times to parasite wave remission and survived for a longer time than infected C3H/He mice. Parasite growth and differentiation rates and host immune responses were similar for the first 5 days in both strains of mice after infection with 10(3) T.b.brucei GUTat 3 but, thereafter, parasite differentiation proceeded more rapidly and specific antibodies reached higher titres in C57Bl/6 than in C3H/He mice. In contrast, parasite growth and differentiation rates were similar in irradiated mice of both strains. Furthermore, following inoculation of intact mice with irradiated T.b.brucei GUTat 3, C3H/He mice actually mounted higher titred antibody responses than C57Bl/6 mice showing that they were not intrinsically defective in their capacity to respond to GUTat 3 antigens. Parasite differentiation occurred at the same rate in irradiated (650r) C57Bl/6 mice and in irradiated C57Bl/6 mice reconstituted with syngeneic spleen cells although T.b.brucei GUTat 3 specific antibody was detected in the latter mice prior to peak parasitaemia. Furthermore, it was shown directly in C57Bl/6 mice that there was no selective destruction of slender form T.b.brucei GUTat 3 parasites during the phase of accumulation of stumpy form parasites. These studies indicate that the more rapid differentiation of T.b.brucei GUTat 3 parasites in infected C57Bl/6 mice as compared to infected C3H/He mice was unlikely to be directly related to the more efficient antibody response in the infected C57Bl/6 mice. The observations suggest that there might be an association between host mechanisms which regulate differentiation of T.b.brucei parasites and those which regulate antibody responses.

Antibody responses induced by immunization of inbred mice susceptible and resistant to African trypanosomes

We tested the ability of inbred mice that were either susceptible (strain A/J) or resistant (strain C57BL/6 and A/J X C57BL/6 hybrids) to African trypanosomes to produce specific antibodies to trypanosome antigens in the absence of living parasites. This experiment was carried out to eliminate the influence of trypanosome growth or metabolism on immune responsiveness. Mice were immunized with keyhole limpet hemocyanin or solubilized Trypanosoma brucei gambiense, and serum antibodies were measured in solid-phase radioimmunometric assays after primary and challenge injections. Both susceptible and resistant mice showed increases in keyhole limpet hemocyanin-specific or trypanosome-specific immunoglobulin M and immunoglobulin G after immunization. When immunized with trypanosome antigens, resistant mice made qualitatively and quantitatively superior specific immunoglobulin M responses, particularly to the trypanosome major variable surface glycoprotein. Susceptible A/J mice produced good specific antibody responses, although these were predominantly of the immunoglobulin G isotypes. These results show that A/J and C57BL/6 mice respond differentially in terms of immunoglobulin isotype and repertoire in response to injected antigens. The possibility that this differential antibody response influences susceptibility to African trypanosomes is discussed.

Effect of murine cytomegalovirus infection on mitogen responses in genetically resistant and susceptible mice

Suppression of the blastogenic response of spleen cells was found during murine cytomegalovirus infection of the genetically susceptible BALB/c and also the more resistant BALB.K strains of mice. These results were observed for both the T-cell mitogen concanavalin A and the B-cell mitogen lipopolysaccharide. As the viral inoculum was increased, there was greater immunosuppression within each strain, the time of maximum depression coinciding with peak virus titers in the spleen. Although both strains developed similar splenic virus titers and exhibited a similar decrease in the proportion of splenic T-lymphocytes, there was greater suppression of the mitogenic response during sublethal infection of the more susceptible BALB/c strain. The suppression could not be readily accounted for by the presence of suppressor cells or by a change in sensitivity to mitogen. The results suggest that the extent of immunosuppression induced by murine cytomegalovirus is determined in part by host genotype.

Histopathological and immunocytochemical studies of Trypanosoma musculi infection of mice

Mice infected with Trypanosoma musculi developed hyperplasia of the spleen, lymph nodes, and liver; in contrast, their thymuses displayed transient involution. All organs returned to normal in a month or less. There was modest anemia, lasting until the parasites were cleared from the bloodstream, followed by a rapid influx of erythrocytes into the blood and a subsequent return to normal erythrocyte numbers. During the first 2 weeks, trypanosomes and trypanosome-derived substances were found in the livers and, in moderate amounts, in the red pulp of the spleens; thereafter, trypanosomes and trypanosome-derived substances gradually decreased in these organs. The lymphoreticular hyperplasia involved a large increase of immunoglobulin G (IgG)-containing cells in the spleens and lymph nodes at 2 weeks of infection. Hyperplasia of immunoglobulin-producing cells correlated with elevation of serum immunoglobulins, especially IgG. Cells producing IgG in the spleens proliferated mainly around the central arterioles of the white pulp, i.e., in the T-cell-dependent areas. The decline of trypanosome-derived substances in the livers and spleens was associated with marked hyperplasia of IgG-containing cells in the spleens and lymph nodes. These results suggest that trypanosome-mediated depression of murine immune responses is attributable to proliferation and terminal differentiation of more-mature lymphoid cells and temporary inhibition of normal maturation of less-mature precursor cells.

Evidence for depletion of Ia+ macrophages and associated immunosuppression in African trypanosomiasis

The percentage of Ia antigen-bearing (Ia+) macrophages was significantly lower in mice infected with Trypanosoma rhodesiense than in normal controls. The degree of difference varied with the source of macrophages and time course of infection. The percentage of Ia+ macrophages isolated from spleens 10 days after infection was 71% of that in the controls, and depletion continued until Ia+ macrophages were almost undetectable 30 days after infection. The rate of depletion was slower in the peritoneal cavity. In contrast, Ia+ macrophages were not significantly depleted from the lymph nodes until 30 days after infection. The ability of macrophages from trypanosome-infected mice to present listerial antigen to sensitized T cells was significantly lower than in controls. Immune T cells had significantly less ability (43% of controls) to incorporate thymidine when exposed to splenic macrophages from infected mice during the early stage of disease. This loss of antigen presentation increased during the course of infection. Peritoneal macrophages also exhibited an early loss of ability to present antigen, but no significant decline occurred thereafter. No significant loss of antigen had occurred in the lymph node macrophages 10 days after infection, but during the later stages of the disease a significant loss was detected. Treatment of macrophages from infected and control mice with anti-Iab serum and complement inhibited their ability to present antigen. Our results demonstrate that Ia+ macrophages and their distribution can influence the ability of infected animals to process antigens and may therefore account in part for the immunosuppression observed in trypanosomiasis.

Immunodepression in trypanosome-infected mice. VI. Comparison of immune responses of different lymphoid organs

Mitogen stimulation of cells from various lymphoid organs of C3H/He mice chronically infected with an isolate of Trypanosoma congolense was studied at different time intervals after infection, using concanavalin A (Con A) and lipopolysaccharide (LPS). At the same time, changes in the percentages of T, B and null lymphocytes in these organs were determined by immunofluorescence staining. The responses of T and B lymphocytes in the spleen were totally depressed, and the cellular composition was drastically altered by day 14 after infection. Unlike the spleen, the lymph nodes showed minor changes in their T and B lymphocyte responses and cell composition during the course of the infection, except the B cell response and composition which were altered late in the infection. The thymus and bone marrow did not show any appreciable changes in their mitogen responses and cell composition throughout the infection. The peripheral blood lymphocytes showed reduced B cell responses. Spleen cells from chronically infected mice suppressed lymphocyte stimulation induced in normal spleen and lymph node cell populations by Con A, LPS and allogeneic stimulator cells. Lymph node cells from the same group of mice did not exhibit any such suppressor activity. In the experimental system used here, the spleen is the primary site of immune depression, and other lymphoid organs such as the lymph nodes and thymus are very little affected.

Immune depression in trypanosome-infected mice. II. Characterization of the spleen cell types involved

Spleen cells from Trypanosoma congolense-infected mice showed a drastic depression in their capacity to respond to B and T lymphocyte mitogens and to allogeneic spleen cells in mixed lymphocyte cultures. Spleen cells from infected mice were also poor stimulators in mixed lymphocyte cultures. The poor responsiveness or stimulation capacity was not due simply to dilution of relevant B or T lymphocytes by the large number of null cells found in the spleens of infected animals. These null cells expressed approximately eight times more H-2 antigen than spleen cells from normal (uninfected) mice and were devoid of Ia antigens.