Pronounced phenotype in activated regulatory T cells during a chronic helminth infection.

Although several markers have been associated with the characterization of regulatory T cells (Tregs) and their function, no studies have investigated the dynamics of their phenotype during infection. Since the necessity of Tregs to control immunopathology has been demonstrated, we used the chronic helminth infection model Schistosoma mansoni to address the impact on the Treg gene repertoire. Before gene expression profiling, we first studied the localization and Ag-specific suppressive nature of classically defined Tregs during infection. The presence of Foxp3+ cells was predominantly found in the periphery of granulomas and isolated CD4+CD25(hi)Foxp3+ Tregs from infected mice and blocked IFN-gamma and IL-10 cytokine secretion from infected CD4+CD25- effector T cells. Furthermore, the gene expression patterns of Tregs and effector T cells showed that 474 genes were significantly regulated during schistosomiasis. After k-means clustering, we identified genes exclusively regulated in all four populations, including Foxp3, CD103, GITR, OX40, and CTLA-4--classic Treg markers. During infection, however, several nonclassical genes were upregulated solely within the Treg population, such as Slpi, Gzmb, Mt1, Fabp5, Nfil3, Socs2, Gpr177, and Klrg1. Using RT-PCR, we confirmed aspects of the microarray data and also showed that the expression profile of Tregs from S. mansoni-infected mice is simultaneously unique and comparable with Tregs derived from other infections.

Immunopathology in schistosomiasis is controlled by antigen-specific regulatory T cells primed in the presence of TLR2.

Regulatory T cells (Treg) are vital in maintaining the homeostasis of immune reactions. In chronic infections, such as schistosomiasis, it remains unclear whether engagement of the TLR family is required to induce Treg activity. Thus, we performed in vivo studies using TLR2-/- mice infected with Schistosoma mansoni and found elevated immunopathology, decreased egg burden and extended antigen-specific Th1 responses. Simultaneously, the population of Treg failed to expand. To evaluate the role of Treg during infection, we functionally inactivated CD4+CD25+ T cells and observed that the resulting immunopathology mirrored that in TLR2-/- mice. Egg burden was also reduced in anti-CD25-treated mice, indicating that without Treg eggs are more efficiently destroyed. In addition, antigen-specific T cells from both TLR2-/- and anti-CD25-treated mice displayed an extended Th1 phase. Finally, adoptive transfer of schistosome-primed, but not naive CD4+CD25+ T cells was able to resolve the immunopathology in TLR2-/- recipients and interestingly, this amelioration was independent of TLR2 being present on the transferred Treg. We conclude that TLR2 is necessary for priming active Treg and their expansion during schistosomiasis.

Lack of antigen-specific Th1 response alters granuloma formation and composition in Schistosoma mansoni-infected MyD88-/- mice.

To evaluate the role of the innate immune system during schistosomiasis in vivo, we infected myeloid differentiation factor 88 (MyD88)-deficient mice with Schistosoma mansoni and analyzed their pathognomonic formation of hepatic granulomas and T cell responses. Even though the differences between knockout and wild-type mice in terms of mortality, liver damage, serum IgE and parasite burden were insignificant, the liver granulomas in the MyD88-deficient mice were significantly smaller, less cellular and contained a reduced percentage of eosinophils. Histologically, these granulomas revealed stronger fibrosis, confirmed also by increased levels of soluble collagen and IL-13, implying a Th2 bias. Spleen cells from infected MyD88-deficient mice also produced significantly less IFN-gamma than their wild-type controls upon restimulation with Schistosoma-egg-antigen (SEA). Furthermore, SEA-loaded APC from naive wild-type or MyD88-deficient mice induced equal amounts of proliferation and cytokine secretion by T cells from wild-type infected mice. In contrast, Ag-specific T cells from infected MyD88-deficient mice produced hardly any IFN-gamma but considerably more IL-10, again regardless of the APC type. These findings indicate that the loss of IFN-gamma production is not due to impaired antigen presentation but may perhaps is due to suppression by IL-10-producing T cells. Thus, MyD88 plays an important role in cellular infiltration, granuloma composition and T cell responses during schistosomiasis.

Heat shock protein 60 from Chlamydia pneumoniae elicits an unusual set of inflammatory responses via Toll-like receptor 2 and 4 in vivo.

Heat shock protein 60 (HSP60) from Chlamydia pneumoniae was described to trigger in vitro inflammatory and cytokine responses including TNF and IL-12p40. Although it can be found in atherosclerotic plaques of patients, the stimulatory potential of chlamydial and other HSP60 in vivo is unclear. We now report that chlamydial HSP60 fails to induce TNF expression in vivo, and significant serum levels of IL-12p40 are only found upon intraperitoneal injection of high doses of HSP60 or after intravenous application. Upon purification of chlamydial HSP60 with polymyxin B-agarose columns, its ability to induce TNF secretion in vitro is much reduced. However, purified chlamydial HSP60 causes increased serum levels of the CXC chemokines KC and MIP2 in vivo, as well as a strong accumulation of polymorphonuclear neutrophils (PMN) in the peritoneal cavity upon intraperitoneal challenge. With respect to PMN accumulation, chlamydial HSP60 is more potent than endotoxin or the CpG oligonucleotide 1668. The responses observed are completely abolished in Toll-like receptor (TLR)2/4-double-deficient mice, while single-deficient mice respond almost normally. Furthermore, KC induction and PMN accumulation are largely dependent on MyD88. In conclusion, HSP60 from C. pneumoniae triggers inflammatory responses in vivo that differ from responses induced by endotoxin or CpG oligonucleotides and are dependent on TLR2 and 4.