Previous observations demonstrated severe thymocyte depletion in mice undergoing acute Chagas' disease. These data led us to investigate the status of the thymic microenvironment in these animals. Young adult C57BL/6 and C3H/HeJ mice were infected i.p. with 10(5) blood-derived trypomastigote forms of Trypanosoma cruzi (CL strain) and killed 7-14 days after infection. Sera were then analyzed for thymic hormone (thymulin) levels, and frozen thymus sections were studied by immunohistochemistry for the expression of functional antigens (thymulin and Ia), the distribution of distinct thymic epithelial cell subsets and extracellular matrix components. Infected mice exhibited a transient decrease in thymulin production and those with severe thymic atrophy showed a denser Ia-bearing cellular network. In addition, an abnormal localization of the TR5 and CK18 antigens restricted to the medullary and cortical TEC subsets, respectively, was observed. Furthermore, an increase in the basement membrane proteins was detected within thymic lobules. We suggest that the thymic microenvironment is also affected during T. cruzi infection, extending the concept that the thymus should be regarded as a target in Chagas' disease.
Converging data suggest an important role for IL-7 in T lymphocyte maturation as illustrated by the severe T lymphopenia observed in IL-7-deficient mice. We recently reported that IL-7 preferentially promotes the in vitro expansion of a discrete MHC class I-dependent lymphocyte subset comprising both CD4+ and CD4-CD8- TCR alpha beta + cells bearing several NK cells markers such NK1.1 and Ly-49. These T cells, designated as NK1+ T cells, have the unique property among thymocytes of producing large amounts of IL-4 upon primary stimulation via the TCR. We have further demonstrated that thymic NK1+ T cells of non-obese diabetic (NOD) mice, a spontaneous model of autoimmune type I diabetes, are markedly deficient in maturation both quantitatively and functionally (IL-4 production). In the present experiments, the addition of exogenous IL-7 completely restored IL-4 production by anti-TCR alpha beta-stimulated mature (HSA-CD8-) thymocytes in NOD mice. A short 2 h preincubation with IL-7 was sufficient to restore both the expression of IL-4 mRNA and IL-4 production capacity. This was related to a direct effect on NK1+ thymocytes since: (i) the effect of IL-7 was restricted to the non-mainstream MEL-14- 3G11- TCR alpha beta + subset which mostly concentrates the IL-4-producing capacity and (ii) IL-7 did not restore IL-4 production in class I-deficient mice which lack the NK1+ T cell subset. Importantly, this activity of IL-7 on NK1+ T cells was also demonstrated in non-autoimmune strains of mice. These results were extended in vivo by showing that the IL-7 treatment significantly increased the anti-CD3 triggered IL-4 production by NK1+ T spleen cells. These findings confirm the role of IL-7 in NK1+ T cell maturation and suggest that the NK1+ T cell defect in NOD mice could be related to insufficient intrathymic IL-7 bioavailability.
We have followed CD4 and CD8 TCR V beta repertoires during the acute phase of Trypanosoma cruzi infection in a resistant mouse strain (C57BL/6). No major changes were found in the V beta TCR distributions analyzed (covering roughly 40% of the TCR repertoire) in peripheral CD4 T lymphocytes, confirming the polyclonal nature of CD4 T cell responses. In contrast, in most animals, an over-representation of V beta 5 and V beta 14 TCR families was disclosed in the CD8 T cell compartment, superimposed on a predominantly polyclonal response. The preferential expansion of V beta 5+CD8+ T cells was also observed after infection of sensitive (C3H/HeJ, BALB/c) mouse strains. These observations suggest the existence of CD8 T cell-directed superantigenic activities associated with parasites.
The thymic epithelium, a major component of the thymic microenvironment, is a heterogeneous tissue bearing distinct monoclonal antibody-defined subsets. Among these, KL1+ cells represent a mouse medullary subpopulation characterized by high mol wt cytokeratin expression. Given the fact that thymic epithelial cells (TEC) express glucocorticoid receptors and that glucocorticoid hormones are known to modulate the expression of keratins, we decided to study the in vivo effects of hydrocortisone on KL1+ cells in normal and autoimmune mice. Within 24 h after a single injection of this steroid we observed a significant increase in the number of KL1+ cells. Interestingly, this effect was reversible and was no longer detected 7 days after treatment. Parallel studies analyzing the effects of hydrocortisone on the secretion of thymulin, a chemically defined thymic hormone revealed a transient decrease in serum levels of this hormone, but with different kinetics than the effects on KL1+ cells. Ontogenetic studies showed that the responsiveness of TEC to hydrocortisone, in terms of high mol wt cytokeratin expression, appeared late in fetal life and disappeared in aging animals. Importantly, aging, but also young adult, autoimmune mice were not responsive. In vitro experiments using a mouse TEC line confirmed the data observed in vivo demonstrating that the increase in KL1+ cells is a direct effect of hydrocortisone on TEC. The bulk of the data presently reported demonstrates that glucocorticoid hormone can act on TEC modulating the expression of both secretory and cytoskeletal protein families.
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