IL-17 Promotes Differentiation of Splenic LSK- Lymphoid Progenitors into B Cells following Plasmodium yoelii Infection.

Lineage-Sca-1+c-Kit- (LSK-) cells are a lymphoid progenitor population that expands in the spleen and preferentially differentiates into mature B cells in response to Plasmodium yoelii infection in mice. Furthermore, LSK- derived B cells can subsequently contribute to the ongoing immune response through the generation of parasite-specific Ab-secreting cells, as well as germinal center and memory B cells. However, the factors that promote their differentiation into B cells in the spleen postinfection are not defined. In this article, we show that LSK- cells produce the cytokine IL-17 in response to Plasmodium infection. Using Il-17ra-/- mice, IL-17R signaling in cells other than LSK- cells was found to support their differentiation into B cells. Moreover, primary splenic stromal cells grown in the presence of IL-17 enhanced the production of CXCL12, a chemokine associated with B cell development in the bone marrow, by a population of IL-17RA-expressing podoplanin+CD31- stromal cells, a profile associated with fibroblastic reticular cells. Subsequent blockade of CXCL12 in vitro reduced differentiation of LSK- cells into B cells, supporting a direct role for this chemokine in this process. Immunofluorescence indicated that podoplanin+ stromal cells in the red pulp were the primary producers of CXCL12 after P. yoelii infection. Furthermore, podoplanin staining on stromal cells was more diffuse, and CXCL12 staining was dramatically reduced in Il-17ra-/- mice postinfection. Together, these results identify a distinct pathway that supports lymphoid development in the spleen during acute Plasmodium infection.

Trypanosoma cruzi infection selectively renders parasite-specific IgG+ B lymphocytes susceptible to Fas/Fas ligand-mediated fratricide.

The control of B cell expansion has been thought to be solely regulated by T lymphocytes. We show in this study that Trypanosoma cruzi infection induces up-regulation of both Fas and Fas ligand (FasL) molecules on B cells and renders them susceptible to B cell-B cell killing (referred to as fratricide throughout this paper) mediated via Fas/FasL. Moreover, by in vivo administration of anti-FasL blocking mAb we demonstrate that Fas-mediated B cell apoptosis is an ongoing process during this parasitic infection. We also provide evidence that B cells that have switched to IgG isotype are the preferential targets of B cell fratricide. More strikingly, this death pathway selectively affects IgG(+) B cells reactive to parasite but not self Ags. Parasite-specific but not self-reactive B cells triggered during this response are rescued after either in vitro or in vivo FasL blockade. Fratricide among parasite-specific IgG(+) B lymphocytes could impair the immune control of T. cruzi and possibly other chronic protozoan parasites. Our results raise the possibility that the blockade of Fas/FasL interaction in the B cell compartment of T. cruzi-infected mice may provide a means for enhancing antiparasitic humoral immune response without affecting host tolerance.

A mucosal IgA response, but no systemic antibody response, is evoked by intranasal immunisation of dogs with Echinococcus granulosus surface antigens iscoms.

The search for protective antigens of intestinal parasites is conditioned by the methodology used to induce a relevant local immune response against them. The present work describes the use of immuno stimulating complexes (iscoms) from tegumental antigens from protoscoleces (PSC) of the cestode Echinococcus granulosus as immunogens in dogs by the intranasal route. It also describes the evaluation of the immune response evoked at the antibody level (systemically and at a distant mucosal location) as well as at the level of antibody secreting cells in peripheral blood. Iscoms from both E. granulosus tegumental antigens and hen ovalbumin (OVA), given at 50 microg doses by intranasal route, evoked significant secretory IgA antibody responses detected in saliva. Specific IgA secreting cells in peripheral blood also increased 10-20-fold, although transiently, after primary and secondary stimulation, whereas specific IgG secreting cells in peripheral blood were only detected in some individuals after the second antigenic exposure. Generation of immune responses at a related mucosal site provides evidence of localised immunity. No significant increase in systemic antibody titers of either IgM, IgG or IgA isotype was detected in plasma as a result of the immunisation. This fact could reflect that the nasopharyngeal mucosal associated lymphoid tissue of dogs is more strictly compartmentalised than that of other mammals.