Number Of Splenic CD4 Research Articles

NK1.1+ cells and T-cell activation in euthymic and thymectomized C57Bl/6 mice during acute Trypanosoma cruzi infection.

Natural killer (NK) cells may provide the basis for resistance to Trypanosoma cruzi infection, because the depletion of NK1.1 cells causes high levels of parasitemia in young C57Bl/6 mice infected with T. cruzi. Indeed, NK1.1 cells have been implicated in the early production of large amounts of interferon (IFN)-gamma, an important cytokine in host resistance. The NK1.1 marker is also expressed on special subpopulations of T cells. Most NK1.1+ T cells are of thymic origin, and their constant generation may be prevented by thymectomy. This procedure, by itself, decreased parasitemia and increased resistance in young mice. However, the depletion of NK1.1+ cells by the chronic administration of a monoclonal antibody (MoAb) (PK-136) did not increase the parasitemia or mortality in thymectomized C57Bl/6 mice infected with T. cruzi (Tulahuen strain). To study the cross-talk between NK1.1+ cells and conventional T cells in this model, we examined the expression of activation/memory markers (CD45RB) on splenic CD4+ and CD8+ T cells from young euthymic or thymectomized mice with or without depletion of NK1.1+ cells and also in aged mice during acute infection. Resistance to infection correlated with the amount of CD4+ T cells that are already activated at the moment of infection, as judged by the number of splenic CD4+ T cells expressing CD45RB(-). In addition, the specific antibody response to T. cruzi antigens was precocious and an accumulation of immunoglobulin (Ig)M with little isotype switch occurred in euthymic mice depleted of NK1.1+ cells. The data presented here suggest that NK1.1+ cells have important regulatory functions in euthymic, but not in thymectomized mice infected with T. cruzi. These regulatory functions include a helper activity in the generation of effector or activated/memory T cells.

T lymphocyte dynamics during Listeria monocytogenes infection

Infection of mice with Listeria monocytogenes results in a robust T lymphocyte response that clears the pathogen and provides long term immunity from reinfection. The number of splenic CD4 + and CD8 + T cells and natural killer cells increases during primary and recall infection with L. monocytogenes, however the proportional increase is greatest for CD8 + T cells. The proportion of CD8 T cells expressing low levels of CD62L, a sign of activation, was increased among immune splenocytes, suggesting a substantial expansion of L. monocytogenes specific CTL. Analysis of CTL specific for the immunodominant LLO 91-99 epitope showed that essentially all were CD62L lo during the primary response, but that many upregulated expression of CD62L during the memory phase. Interestingly, the antigen specificity of nearly all additional CD62L lo CTL detected in spleens during recall L. monocytogenes infection can be accounted for with MHC class I tetramers complexed with four different epitopes. These studies demonstrate the complex T lymphocyte dynamics during infection with intracellular pathogens.

Interleukin-7 enhances cell-mediated immune responses in vivo in an interleukin-2-dependent manner.

We have engineered recombinant vaccinia virus vectors expressing murine interleukin-7 (IL-7) in order to study the activity of this factor during virus infection. Virus-encoded IL-7 dramatically increased splenic cellularity in infected mice and enhanced the proliferative activity of T cells and their capacity to secrete IL-2 and IL-6, but not IFN-gamma, TNF-alpha or IL-4. Numbers of splenic CD4+ and CD8+ T lymphocytes were elevated two- to threefold. IL-7 also mediated a marked enhancement of both antigen-specific and nonspecific cellular immune activity. Total splenic antiviral cytotoxic T cells (CTL), natural killer (NK), and lymphokine-activated killer cells (LAK) responses were augmented significantly in mice given VV-HA-IL-7 compared with those given control virus, with accelerated clearance of the former. The enhanced antiviral cellular immune activity mediated by IL-7 was critically dependent on IL-2 produced by the host, but occurred independently of IFN-gamma. The ability of IL-7 to induce cellular immune responses in vivo may have applications in antiviral immunotherapy, particularly in cases of immunodeficiency.

Gamma delta T cells function in cell-mediated immunity to acute blood-stage Plasmodium chabaudi adami malaria.

To determine whether gamma delta T cells are essential for the resolution of acute Plasmodium chabaudi adami (P. c. adami) malaria, we depleted gamma delta T cells from C57BL/6 mice with hamster monoclonal anti-TCR gamma delta Ab treatment. During the period in which control mice that had received normal hamster IgG completely resolved infections, gamma delta T cell-depleted mice were unable to suppress their infections. Because the number of splenic CD4+ alpha beta T cells in these anti-TCR-gamma delta-treated mice with nonresolving malaria was similar to control mice, it appears that CD4+ alpha beta T cells alone cannot mediate early resolution even though they are known to play a critical role in immunity to blood-stage malaria. Mice treated with anti-CD4 mAb also failed to resolve P. c. adami malaria. Depletion of CD4+ alpha beta T cells from the spleens of infected mice resulted in minimal expansion of the splenic CD4- gamma delta T cell subset compared with infected control mice. Together, these findings indicate that activation of the gamma delta T cell subset, which requires the presence of CD4+ alpha beta T cells, is essential for resolution of acute P. c. adami malaria. To determine whether gamma delta T cells require either Abs or B cells to achieve their protective activity, B cell-deficient JHD mice were treated with the same depleting anti-TCR-gamma delta Abs. Whereas control JHD mice injected with hamster IgG resolved acute P. c. adami malaria, JHD mice depleted of gamma delta T cells failed to do so. We conclude that gamma delta T cells suppress P. c. adami parasitemia by mechanisms of immunity independent of Ab and B cells.

Immunization of susceptible hosts with a soluble antigen fraction from Leishmania major leads to aggravation of murine leishmaniasis mediated by CD4+ T cells

This study was performed in order to define Leishmania major antigens that function as disease-modulating immunogens in susceptible BALB/c mice. A soluble leishmanial antigen preparation (S-SLA) derived from highly infective stationary-phase L. major parasites was fractionated by preparative gel electrophoresis. In vitro, the low molecular mass fraction (less than 31 kDa) of S-SLA fraction D (FR D) was found to be a potent stimulator of L. major-specific Th1 and Th2 helper cell clones. In vivo, immunization with FR D induced a Th2-biased immune response in BALB/c mice as determined by the numbers of splenic CD4+ cells secreting interleukin 4 and interferon-gamma according to limiting dilution analyses. In addition, FR D caused significant disease exacerbation in parasite-infected susceptible mice as assessed by the local lesion development and the numbers of parasites in lymph nodes and spleen. This effect was observed after local subcutaneous application of FR D as well as after systemic immunization (intrasplenic or intraperitoneal). Transfer experiments revealed, that the disease-aggravating effect of FR D was mediated by CD4+ T cells. From these results it is concluded that leishmanial protein preparations exist that not only fail to induce protective anitparasitic immunity, but can mediate disease exacerbation, independently of the primary application site of the immunogen. The existence of such structures may serve the parasite as a means to evade the host's immune attack and may also have implications for the development of vaccines.