Mice deficient in the hemochromatosis gene, Hfe, have attenuated inflammatory responses to Salmonella infection associated with decreased macrophage TNF-α and IL-6 biosynthesis after exposure to LPS. In this study, we show that the abnormal cytokine production is related to impaired TLR4 signaling. Despite their abnormal response to LPS, Hfe KO macrophages produced amounts of TNF-α similar to those in WT cells after TLR2 stimulation. Consistent with this finding, LPS-induced activation of Mal/MyD88-dependent events was normal in the mutant macrophages. However, LPS-induced IFN-β expression, a TRAM/TRIF-dependent response activated by TLR4, was reduced by Hfe deficiency. This reduction could be replicated in WT macrophages with the use of iron chelators. In contrast, TLR3-activated expression of IFN-β, a TRIF-dependent response, was normal in Hfe KO macrophages and was unaffected by iron chelation. Our data suggest that low intracellular iron selectively impairs signaling via the TLR4/TRAM/TRIF pathway proximal to TRIF and results in reduced LPS-induced cytokine expression. Furthermore, by mimicking the altered iron metabolism associated with Hfe deficiency, we found that 3 different inhibitors of hepcidin attenuated Salmonella-induced and noninfectious enterocolitis. Thus, manipulation of iron homeostasis could represent a new therapeutic approach to controlling inflammation.
We investigated the influence of the macrophage iron exporter ferroportin and its ligand hepcidin on intracellular Salmonella growth. Elevated ferroportin expression inhibited bacterial multiplication; hepcidininduced ferroportin down-regulation enhanced it. Expression analysis of iron-responsive Salmonella genes indicated ferroportin-mediated iron deprivation. These results demonstrate a role for ferroportin in antimicrobial resistance.
Indoleamine 2,3-dioxygenase (IDO) is a negative regulator of lymphocyte responses that is expressed predominantly in macrophages and dendritic cells. We detected it at high levels in the small intestine and mesenteric lymph node of young adult mice, suggesting a role in intestinal immunity. Consistent with this idea, we found that IDO-deficient mice had elevated baseline levels of immunoglobulin A (IgA) and IgG in the serum and increased IgA in intestinal secretions. These abnormalities were corrected by a course of broad-spectrum oral antibiotics started at weaning, indicating that they were dependent on the intestinal microbiota. Kynurenine and picolinic acid, two IDO-generated metabolites of tryptophan, were able to inhibit lipopolysaccharide-induced antibody production by splenocytes in vitro, and kynurenine also induced B-cell apoptosis, findings that provide an explanation for the elevated Ig levels in animals lacking IDO. The intestinal secretions of IDO-deficient mice had elevated levels of IgA antibodies that cross-reacted with the gram-negative enteric bacterial pathogen Citrobacter rodentium. In keeping with the functional importance of this natural secretory IgA, the mutant animals were more resistant to intestinal colonization by Citrobacter, developed lower levels of serum Citrobacter-specific IgM and IgG antibodies following oral infection, and had significantly attenuated Citrobacter-induced colitis. Our observations point to an important role for IDO in the regulation of immunity to the gut commensal microbiota that has a significant impact on the response to intestinal pathogens.Indoleamine 2,3-dioxygenase (IDO) is an intracellular enzyme that catalyzes the initial rate-limiting step in the catabolism of tryptophan via the kynurenine pathway (21). It is expressed in a number of tissues, predominantly in dendritic cells and macrophages, and is up-regulated by immune and inflammatory stimuli. IDO-mediated depletion of tryptophan from the local microenvironment inhibits the proliferation of T cells, NK cells, and possibly B cells (1,13,22,29,40). The response to tryptophan deprivation in T cells has been shown recently to involve the activation of the GCN2 kinase, a key component of a stress response signaling pathway that can lead to cell cycle arrest or alterations in T-cell differentiation and function (11,28,36). The cytotoxicity of tryptophan catabolites such as kynurenine, picolinic acid, and quinolinic acid also contributes to the effects of IDO (13,35,40). Because of its ability to inhibit lymphocyte activation and expansion in various ways, IDO is generally considered to be immunosuppressive and anti-inflammatory in function. Indeed, immune-mediated pathology is exacerbated by inhibition of IDO in several experimental models and attenuated by increased expression of the enzyme (1,4,14,15,23,42).In our earlier experiments, we showed that expression of IDO in the murine gut increases significantly with age via a gamma interferon-dependent mechanism (34). Furthermore, levels of IDO in the ad...
Acute gastroenteritis caused by Salmonella infection is a significant public health problem. Using a mouse model of this condition, the authors demonstrated previously that the cytokine gamma interferon (IFN-gamma) is required for a normal intestinal inflammatory response to the pathogen. In the present study, these experiments are extended to show that natural killer (NK) cells constitute an early source of intestinal IFN-gamma during Salmonella infection, and that these cells have a significant impact on intestinal inflammation. It was found that infection of mice with Salmonella increased both intestinal IFN-gamma production and the numbers of NK cells in the intestine and mesenteric lymph nodes. NK cells, along with other types of lymphocytes, produced IFN-gamma in response to the bacteria in vitro, while antibody-mediated depletion of NK cells in vivo resulted in a significant reduction in Salmonella-induced intestinal IFN-gamma expression. In a mouse strain lacking NK cells and T and B lymphocytes, intestinal production of IFN-gamma and Salmonella-induced intestinal inflammation were both significantly decreased compared with a strain deficient only in T and B cells. The authors' observations point to an important function for NK cells and NK-derived IFN-gamma in regulating the intestinal inflammatory response to Salmonella.
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