The mannose receptor binds Trichuris muris excretory/secretory proteins but is not essential for protective immunity

Trichuris muris is a natural mouse model of the human gastrointestinal nematode parasite Trichuris trichiura and it is well established that a T helper type 2-dominated immune response is required for worm expulsion. Macrophages accumulate in the large intestine of mice during infection and these cells are known to express the mannose receptor (MR), which may act as a pattern recognition receptor. The data presented here show for the first time that T. muris excretory/secretory products (E/S) induce bone-marrow-derived macrophages (BMDM) to produce several cytokines and have MR-binding activity. Using alternatively activated BMDM from MR knockout mice it is shown that the production of interleukin-6 partially depends on the MR. Infection of MR knockout mice with T. muris reveals that this receptor is not necessary for the expulsion of the parasite because MR knockout mice expel parasites with the same kinetics as wild-type animals and have similar cytokine responses in the mesenteric lymph nodes. Furthermore, despite acting to reduce serum levels of proinflammatory mediators, absence of the MR does not lead to increased gut inflammation after T. muris infection when assessed by macrophage influx, goblet cell hyperplasia and crypt depth. This work suggests that, despite binding components of T. muris E/S, the MR is not critically involved in the generation of the immune response to this parasite.

The innate immune responses of colonic epithelial cells to Trichuris muris are similar in mouse strains that develop a type 1 or type 2 adaptive immune response

Trichuris muris resides in intimate contact with its host, burrowing within cecal epithelial cells. However, whether the enterocyte itself responds innately to T. muris is unknown. This study investigated for the first time whether colonic intestinal epithelial cells (IEC) produce cytokines or chemokines following T. muris infection and whether divergence of the innate response could explain differentially polarized adaptive immune responses in resistant and susceptible mice. Increased expression of mRNA for the proinflammatory cytokines gamma interferon (IFN-gamma) and tumor necrosis factor and the chemokine CCL2 (MCP-1) were seen after infection of susceptible and resistant strains, with the only difference in expression being a delayed increase in CCL2 in BALB/c IEC. These increases were ablated in MyD88-/- mice, and NF-kappaB p65 was phosphorylated in response to T. muris excretory/secretory products in the epithelial cell line CMT-93, suggesting involvement of the MyD88-NF-kappaB signaling pathway in IEC cytokine expression. These data reveal that IEC respond innately to T. muris. However, the minor differences identified between resistant and susceptible mice are unlikely to underlie the subsequent development of a susceptible type 1 (IFN-gamma-dominated) or resistant type 2 (interleukin-4 [IL-4]/IL-13-dominated) adaptive immune response.

Identification of novel genes in intestinal tissue that are regulated after infection with an intestinal nematode parasite

Infection of resistant or susceptible mice with Trichuris muris provokes mesenteric lymph node responses which are polarized towards Th2 or Th1, respectively. These responses are well documented in the literature. In contrast, little is known about the local responses occurring within the infected intestine. Through microarray analyses, we demonstrate that the gene expression profile of infected gut tissue differs according to whether the parasite is expelled or not. Genes differentially regulated postinfection in resistant BALB/c mice include several antimicrobial genes, in particular, intelectin (Itln). In contrast, analyses in AKR mice which ultimately progress to chronic infection provide evidence for a Th1-dominated mucosa with up-regulated expression of genes regulated by gamma interferon. Increases in the expression of genes associated with tryptophan metabolism were also apparent with the coinduction of tryptophanyl tRNA synthetase (Wars) and indoleamine-2,3-dioxygenase (Indo). With the emerging literature on the role of these gene products in the suppression of T-cell responses in vitro and in vivo, their up-regulated expression here may suggest a role for tryptophan metabolism in the parasite survival strategy.

Immunity to Trichuris muris in the laboratory mouse

Of all the laboratory models of intestinal nematode infection, Trichuris muris in the mouse is arguably the most powerful. This is largely due to the fact that the ability to expel this parasite is strain dependent. Thus, most mouse strains readily expel T. muris. However certain mouse strains, and indeed some individuals within particular mouse strains, are unable to mount a protective immune response and harbour long term chronic infections. This unique model thus presents an opportunity to examine the immune events underlying both resistance to infection and persistent infection within the same host species, and in some cases, the same host strain.

Absence of CC chemokine ligand 2 results in an altered Th1/Th2 cytokine balance and failure to expel Trichuris muris infection

Despite a growing understanding of the role of cytokines in immunity to intestinal helminth infections, the importance of chemokines has been neglected. As a chemokine with both chemoattractive properties and an ability to shape the quality of the adaptive immune response, CC chemokine ligand 2 (CCL2) was investigated as an attractive candidate for controlling resistance to these types of infection, which require highly polarized Th cell responses. We show here for the first time that CCL2 plays an important role in the development of resistance to infection by the gastrointestinal nematode Trichuris muris. Thus, in the absence of CCL2, worm expulsion does not occur, and the lymph node draining the site of infection becomes a Th1-promoting environment. Elevated levels of IL-12 are produced by polarizing APCs, and the composition of the APC environment itself is perturbed, with reduced numbers of macrophages.

The p36 isoform of BAG-1 is translated by internal ribosome entry following heat shock

BAG-1 (also known as RAP46/HAP46) was originally identified as a 46 kDa protein that bound to and enhanced the anti-apoptotic properties of Bcl-2. BAG-1 exists as three major isoforms (designated p50, p46 and p36 or BAG-1L, BAG-1M and BAG-1S respectively) and one minor isoform (p29), which are translated from a common transcript. The differing amino terminus determines both the intracellular location and the repertoire of binding partners of the isoforms which play different roles in a variety of cellular processes including signal transduction, heat shock, apoptosis and transcription. Although in vitro data suggest that the four BAG-1 isoforms are translated by leaky scanning, the patterns of isoform expression in vivo, especially in transformed cells, do not support this hypothesis. We have performed in vivo analysis of the BAG-1 5' untranslated region and shown that translation initiation of the most highly expressed isoform (p36/BAG-1S) can occur by both internal ribosome entry and cap-dependent scanning. Following heat shock, when there is a downregulation of cap-dependent translation, the expression of the p36 isoform of BAG-1 is maintained by internal ribosome entry.

Trichuris muris: CD4+ T cell-mediated protection in reconstituted SCID mice

Resistance to the murine intestinal nematode Trichuris muris requires the development of a strong Th2 response. In a reconstituted SCID mouse model, CD4+ Th2 cells can mediate resistance to infection in the absence of antibody (Else & Grencis, 1996). The data presented here address the issue of how CD4+ T cells mediate this protective immunity within the SCID host. These studies demonstrate that timing and cell dose are critical if transfer is to result in resistance, with a minimum of 5 x 10(6) immune donor cells required to confer immunity. Furthermore, this CD4-mediated protective immunity only operates against the larval stages of the parasite. When the molecules necessary for activated CD4+ T cell migration to the GALT are inhibited with a cocktail of anti-integrin/addressin antibodies (anti-beta7, anti-MAdCAM-1 and anti-alphaE), the resistance conferred by immune donor cells is completely abrogated. This implies that the effector mechanism acts locally at the level of the gut. CD4+ mediated cytotoxicity, directed against the epithelial cells inhabited by the parasite, could represent a novel, locally acting effector mechanism. However, Fas and Fas ligand-deficient mice, which are unable to mount CD4-mediated cytotoxic responses, readily expel T. muris indicating that the mechanism by which CD4-T cells mediate protective immunity is unlikely to involve killing of infected gut epithelial cells.

A mutation in the c-myc-IRES leads to enhanced internal ribosome entry in multiple myeloma: a novel mechanism of oncogene de-regulation

The 5' untranslated region of the proto-oncogene c-myc contains an internal ribosome entry segment (IRES) (Nanbru et al., 1997; Stoneley et al., 1998) and thus c-myc protein synthesis can be initiated by a cap-independent as well as a cap-dependent mechanism (Stoneley et al., 2000). In cell lines derived from patients with multiple myeloma (MM) there is aberrant translational regulation of c-myc and this correlates with a C-T mutation in the c-myc-IRES (Paulin et al., 1996). RNA derived from the mutant IRES displays enhanced binding of protein factors (Paulin et al., 1998). Here we show that the same mutation is present in 42% of bone marrow samples obtained from patients with MM, but was not present in any of 21 controls demonstrating a strong correlation between this mutation and the disease. In a tissue culture based assay, the mutant version of the c-myc-IRES was more active in all cell types tested, but showed the greatest activity in a cell line derived from a patient with MM. Our data demonstrate that a single mutation in the c-myc-IRES is sufficient to cause enhanced initiation of translation via internal ribosome entry and represents a novel mechanism of oncogenesis.