Resistance to malarial infection is achieved by the cooperation of NK1.1(+) and NK1.1(-) subsets of intermediate TCR cells which are constituents of innate immunity

We previously reported that the major expanding lymphocytes were intermediate TCR (TCR(int)) cells (mainly NK1.1(-)) during malarial infection in mice. Cell transfer experiments of TCR(int) cells indicated that these T cells mediated resistance to malaria. However, TCR(int) cells always contain NK1.1(+)TCR(int) cells (i.e., NKT cells) and controversial results (NKT cells were effective or not for resistance to malaria) have been reported by different investigators. In this study, we used CD1d((-/-)) mice, which almost completely lack NKT cells in the liver and other immune organs. Parasitemia was prolonged in the blood of CD1d((-/-)) mice and the expansion of lymphocytes in the liver of these mice was more prominent after an injection of Plasmodium yoelii-infected erythrocytes. However, these mice finally recovered from malaria. In contrast to B6 mice, CD4(-)8(-) NKT cells as well as NK1.1(-)CD3(int) cells expanded in CD1d((-/-)) mice after malarial infection, instead of CD4(+) (and CD8(+)) NKT cells. These newly generated CD4(-)8(-)NKT cells in CD1d((-/-)) mice did not use an invariant chain of Valpha14Jalpha281 for TCRalpha. Other evidence was that severe thymic atrophy and autoantibody production were accompanied by malarial infection, irrespective of the mice used. These results suggest that both NK1.1(-) and NK1.1(+) subsets of TCR(int) cells (i.e., constituents of innate immunity) are associated with resistance to malaria and that an autoimmune-like state is induced during malarial infection.     

Essential role of extrathymic T cells in protection against malaria

Athymic nude mice carry neither conventional T cells nor NKT cells of thymic origin. However, NK1.1(-)TCR(int) cells are present in the liver and other immune organs of athymic mice, because these lymphocyte subsets are truly of extrathymic origin. In this study, we examined whether extrathymic T cells had the capability to protect mice from malarial infection. Although B6-nu/nu mice were more sensitive to malaria than control B6 mice, these athymic mice were able to survive malaria when a reduced number of parasitized erythrocytes (5 x 10(3) per mouse) were injected. At the fulminant stage, lymphocytosis occurred in the liver and the major expanding lymphocytes were NK1.1(-)TCR(int) cells (IL-2Rbeta(+)TCRalphabeta(+)). Unconventional CD8(+) NKT cells (V(alpha)14(-)) also appeared. Similar to the case of B6 mice, autoantibodies (IgM type) against denatured DNA appeared during malarial infection. Immune lymphocytes isolated from the liver of athymic mice which had recovered from malaria were capable of protecting irradiated euthymic and athymic mice from malaria when cell transfer experiments were conducted. In conjunction with the previous results in euthymic mice, the present results in athymic mice suggest that the major lymphocyte subsets associated with protection against malaria might be extrathymic T cells.     

Protection against malaria due to innate immunity enhanced by low-protein diet

Mice were fed ad libitum with a normal diet (25% protein) or low-protein diets (0-12.5% protein) for a wk and then infected with a nonlethal or lethal strain of Plasmodium yoelii, that is, blood stage infection. The same diet was continued until recovery. Mice fed with a normal diet showed severe parasitemia during nonlethal infection, but survived the infection. They died within 2 wk in the case of lethal infection. However, all mice fed with low-protein diets survived without apparent parasitemia (there were small peaks of parasitemia) in cases of both nonlethal and lethal strains. These surviving mice were found to have acquired potent innate immunity, showing the expansion of NK1.1 -TCRint cells and the production of autoantibodies during malarial infection. Severe combined immunodeficiency (scid) mice, which lack TCRint cells as well as TCRhigh cells, did not survive after malarial infection of lethal strain of P. yoelii, even when low-protein diets were given. These results suggest that low-protein diets enhanced innate immunity and inversely decreased conventional immunity, and that these immunological deviations rendered mice resistant against malaria. The present outcome also reminds us of our experience in the field study of malaria, in which some inhabitants eventually avoided contracting malaria even after apparent malarial infection.     

Liver CD4-CD8- NK1.1+ TCR alpha beta intermediate cells increase during experimental malaria infection and are able to exhibit inhibitory activity against the parasite liver stage in vitro

Experimental infection of C57BL/6 mice by Plasmodium yoelii sporozoites induced an increase of CD4-CD8- NK1.1+ TCR alpha beta int cells and a down-regulation of CD4+ NK1.1+ TCR alpha beta int cells in the liver during the acute phase of the infection. These cells showed an activated CD69+, CD122+, CD44high, and CD62Lhigh surface phenotype. Analysis of the expressed TCRV beta segment repertoire revealed that most of the expanded CD4-CD8- (double-negative) T cells presented a skewed TCRV beta repertoire and preferentially used V beta 2 and V beta 7 rather than V beta 8. To get an insight into the function of expanded NK1.1+ T cells, experiments were designed in vitro to study their activity against P. yoelii liver stage development. P. yoelii-primed CD3+ NK1.1+ intrahepatic lymphocytes inhibited parasite growth within the hepatocyte. The antiplasmodial effector function of the parasite-induced NK1.1+ liver T cells was almost totally reversed with an anti-CD3 Ab. Moreover, IFN-gamma was in part involved in this antiparasite activity. These results suggest that up-regulation of CD4-CD8- NK1.1+ alpha beta T cells and down-regulation of CD4+ NK1.1+ TCR alpha beta int cells may contribute to the early immune response induced by the Plasmodium during the prime infection.     

Protection against malaria by anti-erythropoietin antibody due to suppression of erythropoiesis in the liver and at other sites

We have previously reported that erythropoiesis commences in the liver and spleen after malarial infection, and that newly generated erythrocytes in the liver are essential for infection of malarial parasites as well as continuation of infection. At this time, erythropoietin (EPO) is elevated in the serum. In the present study, we administered EPO or anti-EPO antibody into C57BL/6 (B6) mice to modulate the serum level of EPO. When mice were infected with a non-lethal strain (17NXL) of Plasmodium yoelii (blood-stage infection of 10(4) parasitized erythrocytes per mouse), parasitemia continued for 1 month, showing a peak at day 17. Daily injection of EPO (200 IU/day per mouse) from day five to day 14 prolonged parasitemia, whereas injection of anti-EPO antibody (1.5 mg/day per mouse) every second day from day five to day 28 decreased it. Erythropoiesis was confirmed in the liver, spleen and bone marrow by the appearance of nucleated erythrocytes (TER119+). When anti-EPO antibody was injected by the same protocol into mice infected with a lethal strain (17XL) of P. yoelii, all mice showed decreased parasitemia and recovered from the infection. These results suggest that the use of anti-EPO antibody after malarial infection may be of therapeutic value in severe cases of malaria.     

Role of the complementarity-determining region 3 (CDR3) of the TCR-beta chains associated with the V alpha 14 semi-invariant TCR alpha-chain in the selection of CD4+ NK T Cells

The NK1.1(+)TCRalphabeta(int) CD4(+), or double negative T cells (NK T cells) consist of a mixture of CD1d-restricted and CD1d-unrestricted cells. The relationships between CD4(+)NK1.1(+) T cells and conventional T cells are not understood. To compare their respective TCR repertoires, NK1.1(+)TCRalphabeta(int), CD4(+) T cells have been sorted out of the thymus, liver, spleen, and bone marrow of C57BL/6 mice. Molecular analysis showed that thymus and liver used predominantly the Valpha14-Jalpha281 and Vbeta 2, 7, and 8 segments. These cells are CD1d restricted and obey the original definition of NK T cells. The complementarity-determining region 3 (CDR3) sequences of the TCR Vbeta8.2-Jbeta2.5 chain of liver and thymus CD4(+) NK T cells were determined and compared with those of the same rearrangements of conventional CD4(+) T cells. No amino acid sequence or usage characteristic of NK T cells could be evidenced: the Vbeta8.2-Jbeta2.5 diversity regions being primarily the same in NK T and in T cells. No clonal expansion of the beta-chains was observed in thymus and liver CD1d-restricted CD4(+)NK T cells, suggesting the absence of acute or chronic Ag-driven stimulation. Molecular analysis of the TCR used by Valpha14-Jalpha281 transgenic mice on a Calpha(-/-) background showed that the alpha-chain can associate with beta-chains using any Vbeta segment, except in NK T cells in which it paired predominately with Vbeta 2, 7, and 8(+) beta-chains. The structure of the TCR of NK T cells thus reflects the affinity for the CD1d molecule rather than a structural constraint leading to the association of the invariant alpha-chain with a distinctive subset of Vbeta segment.     

NK cell responses to Plasmodium infection and control of intrahepatic parasite development

Various components of innate and adaptive immunity contribute to host defenses against Plasmodium infection. We investigated the contribution of NK cells to the immune response to primary infection with Plasmodium yoelii sporozoites in C57BL/6 mice. We found that hepatic and splenic NK cells were activated during infection and displayed different phenotypic and functional properties. The number of hepatic NK cells increased whereas the number of splenic NK cells decreased. Expression of the Ly49 repertoire was modified in the spleen but not in the liver. Splenic and hepatic NK cells have a different inflammatory cytokines profile production. In addition, liver NK cells were cytotoxic to YAC-1 cells and P. yoelii liver stages in vitro but not to erythrocytic stages. No such activity was observed with splenic NK cells from infected mice. These in vitro results were confirmed by the in vivo observation that Rag2(-/-) mice were more resistant to sporozoite infection than Rag2(-/-) gamma c(-/-) mice, whereas survival rates were similar for the two strains following blood-stage infection. Thus, NK cells are involved in early immune mechanisms controlling Plasmodium infection, mostly at the pre-erythrocytic stage.     

CD4+ T cells are required for HSP65 expression in host macrophages and for protection of mice infected with Plasmodium yoelii

We have reported that macrophages expressing heat-shock protein 65 play an essential role in protection of mice infected with Plasmodium yoelii. In this study, we investigated the function and expression mechanism of HSP65 in macrophages of mice infected with P. yoelii. C57BL/6 (B6) mice are susceptible to infection with the lethal (L) strain but resistant to infection with the non-lethal (NL) strain of P. yoelii. The percentage of apoptotic macrophages in mice infected with the L strain was higher than that in mice infected with the NL strain. However, the percentage was low in L strain infected mice if they acquired resistance to the infection by primary infection with the NL strain. That apoptosis was reversely correlated with HSP65 expression in splenic macrophages from mice infected with P. yoelii suggests HSP65 may contribute to protective immunity by preventing apoptosis of macrophages in malarial infection. Cell depletion/transfer experiments showed that CD4+ T cells, but not CD8+ T cells, gammadelta T cells, NK cells or NK T cells, were required for HSP65 expression in macrophages as well as for protection of mice infected with P. yoelii. In conclusion, HSP65 may play a role in preventing apoptosis of macrophages in mice infected with P. yoelii. CD4+ T cells are required for HSP65 expression and for protective immunity against P. yoelii infection.     

Reversible NK1.1 surface expression on invariant liver natural killer T cells during Listeria monocytogenes infection

The invariant (i) natural killer (NK)T cells consistently express the Valpha14 chain of the T cell receptor (TCR) and recognize alpha-galactosylceramide (alpha-GalCer) presented by the nonpolymorphic presentation molecule CD1d. Despite their name, the iNKT cells represent a heterogeneous population, which can be divided on the basis of NK1.1 surface expression. Here we show that NK1.1 surface expression on liver iNKT cells in mice fluctuates during Listeria monocytogenes infection. At early stages of listeriosis, iNKT cells expressing NK1.1 were numerically reduced and those lacking NK1.1 were increased. At later time points, the NK1.1(-) iNKT cell population contracted, whereas NK1.1(+) iNKT cells reemerged. Alterations in NK1.1 surface expression on iNKT cells were paralleled by numerical changes of interleukin (IL)-12 producers in the liver and were completely prevented by endogenous IL-12 neutralization, whereas NK1.1 surface alterations on iNKT cells following alpha-GalCer stimulation were not prevented. Adoptive cell transfer experiments revealed that the liver NK1.1(-) iNKT cells from NK1.1(+) cell-depleted L. monocytogenes-infected mice accumulated in the liver of recipient recombination-activating gene-1-deficient mice where they acquired NK1.1 surface expression. Thus, we present first evidence that NK1.1 surface expression on liver iNKT cells is reversible during L. monocytogenes infection, and that different mechanisms underlie stimulation by TCR and IL-12.     

Coinfection with nonlethal murine malaria parasites suppresses pathogenesis caused by Plasmodium berghei NK65

Mixed infection with different Plasmodium species is often observed in endemic areas, and the infection with benign malaria parasites such as Plasmodium vivax or P. malariae has been considered to reduce the risk of developing severe pathogenesis caused by P. falciparum. However, it is still unknown how disease severity is reduced in hosts during coinfection. In the present study, we investigated the influence of coinfection with nonlethal parasites, P. berghei XAT (Pb XAT) or P. yoelii 17X (Py 17X), on the outcome of P. berghei NK65 (Pb NK65) lethal infection, which caused high levels of parasitemia and severe pathogenesis in mice. We found that the simultaneous infection with nonlethal Pb XAT or Py 17X suppressed high levels of parasitemia, liver injury, and body weight loss caused by Pb NK65 infection, induced high levels of reticulocytemia, and subsequently prolonged survival of mice. In coinfected mice, the immune response, including the expansion of B220(int)CD11c(+) cells and CD4(+) T cells and expression of IL-10 mRNA, was comparable to that in nonlethal infection. Moreover, the suppression of liver injury and body weight loss by coinfection was reduced in IL-10(-/-) mice, suggesting that IL-10 plays a role for a reduction of severity by coinfection with nonlethal malaria parasites.     

A comparative study of the kinetic changes of hemopoietic stem cells in mice infected with lethal and non-lethal malaria.

The kinetic changes of hemopoietic stem cells in bone marrow and spleen were compared between lethal Plasmodium berghei- and non-lethal P. yoelii 17x-infected mice. P. yoelii 17x-infected mice showed more severe splenomegaly than those infected with P. berghei. P. yoelii 17x-infected mice also showed a greater degree of sustained increase in number of multipotent hemopoietic stem cells (colony-forming units in spleen: CFU-S) and committed stem cells for granulocytes and macrophages (CFU-GM) and for erythrocytes (CFU-E) than P. berghei-infected mice. Such an increase was predominantly seen in the spleen of P. yoelii 17x-infected mice. In P. berghei-infected mice, the number of CFU-S, CFU-GM and also CFU-E only transiently increased and then decreased to a subnormal level at the late stage of infection. The proportion of cycling CFU-S was higher in P. berghei-infected mice than in P. yoelii 17x-infected mice. The IL-3 producing activity per spleen was much higher in P. yoelii 17x-infected than in P. berghei-infected mice at any point in time during the infection. Thus, hemopoietic changes seen after malaria infection seem to be closely related to the pathogenicity of the malaria parasite.     

Regulation of experimental autoimmune encephalomyelitis in the C57BL/6J mouse by NK1.1+, DX5+, alpha beta+ T cells

C57BL/6 (B6) mice with targeted mutations of immune function genes were used to investigate the mechanism of recovery from experimental autoimmune encephalomyelitis (EAE). The acute phase of passive EAE in the B6 mouse is normally resolved by partial recovery followed by mild sporadic relapses. B6 TCR beta-chain knockout (KO) recipients of a myelin oligodendrocyte glycoprotein p35-55 encephalitogenic T cell line failed to recover from the acute phase of passive EAE. In comparison with wild-type mice, active disease was more severe in beta(2)-microglobulin KO mice. Reconstitution of TCR beta-chain KO mice with wild-type spleen cells halted progression of disease and favored recovery. Spleen cells from T cell-deficient mice, IL-7R KO mice, or IFN-gamma KO mice were ineffective in this regard. Irradiation or treatment of wild-type spleen cell population with anti-NK1.1 mAb before transfer abrogated the protective effect. Removal of DX5(+) cells from wild-type spleen cells by anti-DX5 Ab-coated magnetic beads before reconstitution abrogated the suppressive properties of the spleen cells. TCR-deficient recipients of the enriched DX5(+) cell population recovered normally from passively induced acute disease. DX5(+) cells were sorted by FACS into DX5(+) alpha beta TCR(+) and DX5(+) alpha beta TCR(-) populations. Only recipients of the former recovered normally from clinical disease. These results indicate that recovery from acute EAE is an active process that requires NK1.1(+), DX5(+) alpha beta(+) TCR spleen cells and IFN-gamma.     

Immunity to Plasmodium yoelii: kinetics of the generation of T and B lymphocytes that passively transfer protective immunity against virulent challenge

Adoptive immunization of A/Tru mice with splenic B cells or T cells from syngeneic donors with a primary, nonvirulent, Plasmodium yoelii (17X) infection confers on these recipients the capacity to resist a challenge infection with a virulent strain (YM) of P. yoelii. Unfractionated spleen cells as well as spleen cells enriched for T or B cells capable of transferring protective immunity were detected as early as Day 7 of the primary nonvirulent infection, and reached peak levels on Day 14. Spleen cells that were harvested from donor animals after resolution of the immunizing infection [on Days 21 or 28] were incapable of transferring protective immunity. The capacity of 7-day immune spleen cells to transfer immunity could be abolished by pretreatment with mitomycin C. In addition, it was found that immunocompetent recipient mice were required for successful adoptive immunization, since thymectomized, irradiated, bone marrow reconstituted mice infused with immune spleen cells failed to survive lethal challenge infections.     

Influence of CD4+CD25+ T cells on Plasmodium berghei NK65 infection in BALB/c mice

CD4(+) T cells co-expressing CD25 (CD4(+)CD25(+) T cells) have been identified as immunoregulatory suppressors modulating autoimmune response. Beside that, autoimmune response was supposed to be associated with malaria infection. Based on these data, we hypothesised that CD4(+)CD25(+) T cells may influence protective immunity to malaria parasites, while suppressing autoimmune response arising throughout the course of malarial infection. To test this possibility, we evaluated the kinetics of CD4(+)CD25(+) T cells during malaria infection and investigated the influence of CD25 depletion by anti-mouse CD25 monoclonal antibody (PC61) on the infection, using a mouse model of premunition to Plasmodium berghei NK65 malaria. The results showed that, during exacerbation of P. berghei NK65 infection, the proportion of CD4(+)CD25(+) T cells among CD4(+) T cells decreased, although that of CD4(+) T cells increased. CD25 depletion clearly delayed the growth of parasitaemia during parasite challenge, particularly in immunised mice. These findings demonstrated that CD4(+)CD25(+) T cells are able to influence protective immunity underlying premunition to P. berghei NK65 parasites.     

Regulatory role of peritoneal NK1.1+ alpha beta T cells in IL-12 production during Salmonella infection.

NK1.1+ alpha beta T cells emerge in the peritoneal cavity after an i.p. infection with Salmonella choleraesuis in mice. To elucidate the role of the NK1.1+ alpha beta T cells during murine salmonellosis, mice lacking NK1.1+ alpha beta T cells by disruption of TCR beta (TCR beta-/-), beta 2m (beta 2m-/-), or J alpha 281 (J alpha 281-/-) gene were i.p. inoculated with S. choleraesuis. The peritoneal exudate T cells in wild type (wt) mice on day 3 after infection produced IL-4 upon TCR alpha beta stimulation, whereas those in TCR beta-/-, beta 2m-/-, or J alpha 281-/- mice showed no IL-4 production upon the stimulation, indicating that NK1.1+ alpha beta T cells are the main source of IL-4 production at the early phase of Salmonella infection. Neutralization of endogenous IL-4 by administration of anti-IL-4 mAb to wt mice reduced the number of Salmonella accompanied by increased IL-12 production by macrophages after Salmonella infection. The IL-12 production by the peritoneal macrophages was significantly augmented in mice lacking NK1.1+ alpha beta T cells after Salmonella infection accompanied by increased serum IFN-gamma level. The aberrantly increased IL-12 production in infected TCR beta-/- or J alpha 281-/- mice was suppressed by adoptive transfer of T cells containing NK1.1+ alpha beta T cells but not by the transfer of T cells depleted of NK1.1+ alpha beta T cells or T cells from J alpha 281-/- mice. Taken together, it is suggested that NK1. 1+ alpha beta T cells eliciting IL-4 have a regulatory function in the IL-12 production by macrophages at the early phase of Salmonella infection.     

Comparative histopathology of mice infected with the 17XL and 17XNL strains of Plasmodium yoelii

Plasmodium yoelii 17XL was used to investigate the mechanism of Plasmodium falciparum-caused cerebral malaria, although its histological effect on other mouse organs is still unclear. Here, histological examination was performed on mice infected with P. yoelii 17XL; the effect of P. yoelii 17XL infection on anemia and body weight loss, as well as its lesions in the brain, liver, kidney, lung, and spleen, also was investigated. Plasmodium yoelii 17XL-infected red blood cells were sequestered in the microcirculation of the brain and in the kidney. Compared with the nonlethal P. yoelii 17XNL strain, infection by P. yoelii 17XL caused substantial pulmonary edema, severe anemia, and significant body weight loss. Although P. yoelii 17XNL and 17XL produced a similar focal necrosis in the mouse liver, infection of P. yoelii 17XL induced coalescing of red and white pulp. Mortality caused by P. yoelii 17XL may be due to cerebral malaria, as well as respiratory distress syndrome and severe anemia. Plasmodium yoelii 17XL-infected rodent malaria seems to be a useful model for investigating severe malaria caused by P. falciparum.     

Natural killer cells utilize both perforin and gamma interferon to regulate murine cytomegalovirus infection in the spleen and liver

Natural killer (NK) cells are critical for innate regulation of the acute phase of murine cytomegalovirus (MCMV) infection and have been reported to utilize perforin (Pfp)- and gamma interferon (IFN-gamma)-dependent effector mechanisms in an organ-specific manner to regulate MCMV infection in the spleen and liver. In this study, we further examined the roles of NK cells, Pfp, and IFN-gamma in innate immunity to MCMV infection. With the recently described NK cell-deficient (NKD) mouse, we confirmed previous findings that NK cells, but not NKT cells, are required for control of the acute phase of MCMV infection in spleen and liver cells. Interestingly, we found that Pfp and IFN-gamma are each important for regulating MCMV replication in both the spleen and the liver. Moreover, NK cells can regulate MCMV infection in the spleens and livers of Pfp(-/-) mice in a Pfp-independent manner and can use an IFN-gamma-independent mechanism to control MCMV infection in IFN-gamma(-/-) mice. Thus, contrary to previous reports, NK cells utilize both Pfp and IFN-gamma to control MCMV infection in the spleen and liver.     

Identification and characterization of autoantibody-producing B220 B (B-1) cells appearing in malarial infection

Mice with malaria showed unique immunological responses, including the expansion of NK1.1⁻TCR^int cells (extrathymic T cells). Since TCR^int cells with autoreactivity and autoantibody-producing B cells (B-1 cells) are often simultaneously activated under autoimmune conditions, it was examined whether B-1 cells were activated in the course of malarial infection. From days 14 after infection, B220^low B-1 cells appeared in the liver and spleen. The number of B220^low B cells was highest at day 14, but the ratio was highest at days 28-35. In parallel with the appearance of B220^low cells, autoantibodies against HEp-2 cells and double-stranded DNA were detected in sera. These B220^low cells had phenotypes of CD44^high, CD23⁻ and CD62L⁻. In sharp contrast, conventional B220^high B cells (B-2 cells) were CD44^low, CD23⁺ and CD62L⁺. These results suggested that malaria immune responses were not mediated by conventional T and B cells but resembled the responses during autoimmune diseases.