Effects if Plasmodium berghei on thymus: high levels of apoptosis and premature egress of CD4+ CD8+ thymocytes in experimentally infected mice

The thymus is the primary lymphoid organ responsible for the differentiation, maturation and development of T lymphocytes (or thymocytes, as in the thymus).This organ presents a complex architecture composed by soluble and cellular elements that support the migration of lymphocyte precursors from space perivascular to the cortical region, and then their migration toward the medullar area. The trajectory of thymocytes by thymic microenvironments allows these cells to receive stimuli that make them mature into CD4+ or CD8+ T cells, which leave the thymus to populate peripheral lymphoid organs. Studies using murine models of thymic atrophy have reported that thymus is a target organ in several parasitic, viral, helminthic, bacterial and fungal infections. In these models, one can observe intense thymic involution accompanying by disruption of thymic architecture and depletion of all thymocyte subpopulations. In a previous study, our laboratory has demonstrated profound changes in the thymus during experimental infection with Plasmodium berghei, the causative agent of Malaria. Such alterations comprised severe atrophy, histopathological changes with loss of cortical-medullary delimitation, and reduction of all thymocytes sub-populations. In addition, the presence of parasites inside the thymus was detected for the first time. In another study using the same experimental model, we have demonstrated that Plasmodium-infected animals present changes in the expression of extracellular matrix elements and chemokine protein families, which are important molecules for the dynamic thymocyte migration within the thymus. In this study we evaluate whether the acute thymic atrophy observed in Plasmodium berghei-infected animals is correlated with increased apoptotic levels of thymocytes, or with their premature emigration to the periphery. Our data showed profound histological alterations, which included a very large number of cells showing nuclear condensation and karyorrhectic changes surrounded by histiocytes suggesting increased levels of apoptosis. This was confirmed by immunohistochemistry and flow cytometry techniques. Also, increased expression of proapoptotic genes was observed in the thymus of infected animals when compared with controls, suggesting the involvement of the extrinsic, or receptor-iniciated, pathway of apoptosis. Although the rate of apoptosis in the thymus from infected animals is much higher than the controls, the hypothesis that a premature emigration of thymic cells to the peripheral lymphoid organs may also account for the severe atrophy observed during Plasmodium infection could not be ruled out. In fact, we have found a consistent fraction of immature cells, mainly double-negative and double-positive thymocytes, in mesenteric lymph nodes of infected animals. Although this result serves as an evidence of premature emigration of non-mature thymocytes, the precise mechanism by which this process occurs is not clear until now. No significant differences were found in the spleen. Taken together, our data show that thymic alterations observed during Plasmodium berghei infection can favour both the deletion of thymocyte subpopulation by apoptosis and the early emigration of immature cells to the periphery of the system immune. As a consequence, an altered peripheral immune response to the parasite can be expected. Our findings provide relevant information concerning the immune involvement in malaria infection. Moreover, the murine model described here could be useful for mechanist studies of acute thymic atrophy (AU)