Here we investigated the role of the Nod/Rip2 pathway in host responses to Chlamydophila pneumoniae–induced pneumonia in mice. Rip2−/− mice infected with C. pneumoniae exhibited impaired iNOS expression and NO production, and delayed neutrophil recruitment to the lungs. Levels of IL-6 and IFN-γ levels as well as KC and MIP-2 levels in bronchoalveolar lavage fluid (BALF) were significantly decreased in Rip2−/− mice compared to wild-type (WT) mice at day 3. Rip2−/− mice showed significant delay in bacterial clearance from the lungs and developed more severe and chronic lung inflammation that continued even on day 35 and led to increased mortality, whereas WT mice cleared the bacterial load, recovered from acute pneumonia, and survived. Both Nod1−/− and Nod2−/− mice also showed delayed bacterial clearance, suggesting that C. pneumoniae is recognized by both of these intracellular receptors. Bone marrow chimera experiments demonstrated that Rip2 in BM-derived cells rather than non-hematopoietic stromal cells played a key role in host responses in the lungs and clearance of C. pneumoniae. Furthermore, adoptive transfer of WT macrophages intratracheally was able to rescue the bacterial clearance defect in Rip2−/− mice. These results demonstrate that in addition to the TLR/MyD88 pathway, the Nod/Rip2 signaling pathway also plays a significant role in intracellular recognition, innate immune host responses, and ultimately has a decisive impact on clearance of C. pneumoniae from the lungs and survival of the infectious challenge.
Experimental and clinical studies link Chlamydia pneumoniae infection to atherogenesis and atherothrombotic events, but the underlying mechanisms are unclear. We tested the hypothesis that C. pneumoniae-induced acceleration of atherosclerosis in apolipoprotein E (ApoE)−/− mice is reciprocally modulated by activation of TLR-mediated innate immune and liver X receptor α (LXRα) signaling pathways. We infected ApoE−/− mice and ApoE−/− mice that also lacked TLR2, TLR4, MyD88, or LXRα intranasally with C. pneumoniae followed by feeding of a high fat diet for 4 mo. Mock-infected littermates served as controls. Atherosclerosis was assessed in aortic sinuses and in en face preparation of whole aorta. The numbers of activated dendritic cells (DCs) within plaques and the serum levels of cholesterol and proinflammatory cytokines were also measured. C. pneumoniae infection markedly accelerated atherosclerosis in ApoE-deficient mice that was associated with increased numbers of activated DCs in aortic sinus plaques and higher circulating levels of MCP-1, IL-12p40, IL-6, and TNF-α. In contrast, C. pneumoniae infection had only a minimal effect on atherosclerosis, accumulation of activated DCs in the sinus plaques, or circulating cytokine increases in ApoE−/− mice that were also deficient in TLR2, TLR4, or MyD88. However, C. pneumoniae-induced acceleration of atherosclerosis in ApoE−/− mice was further enhanced in ApoE−/−LXRα−/− double knockout mice and was accompanied by higher serum levels of IL-6 and TNF-α. We conclude that C. pneumoniae infection accelerates atherosclerosis in hypercholesterolemic mice predominantly through a TLR/MyD88-dependent mechanism and that LXRα appears to reciprocally modulate and reduce the proatherogenic effects of C. pneumoniae infection.
INPs, which are chemically synthesized compounds belonging to a class of acylated hydrazones of salicylaldehydes, can inhibit the growth of Chlamydiaceae. Evidence has been presented that in Yersinia and Chlamydia INPs may affect the type III secretion (T3S) system. In the present study 25 INPs were screened for antichlamydial activity at a concentration of 50 M, and 14 were able to completely inhibit the growth of Chlamydia trachomatis serovar D in McCoy and HeLa 229 cells. The antichlamydial activities of two of these INPs, INPs 0341 and 0400, were further characterized due to their low cytotoxicity. These compounds were found to inhibit C. trachomatis in a dose-dependent manner; were not toxic to elementary bodies; were cidal at a concentration of >20 M; inhibited all Chlamydiaceae tested; and could inhibit the development of C. trachomatis as determined by the yield of progeny when they were added up to 24 h postinfection. INP 0341 was able to affect the expression of several T3S genes. Compared to the expression in control cultures, lcrH-1, copB, and incA, all middle-to late-expressed T3S genes, were not expressed in the INP 0341-treated cultures 24 to 36 h postinfection. Iron, supplied as ferrous sulfate, as ferric chloride, or as holo-transferrin, was able to negate the antichlamydial properties of the INPs. In contrast, apo-transferrin and other divalent metal ions tested were not able to reverse the inhibitory effect of the INPs. In conclusion, the potent antichlamydial activity of INPs is directly or indirectly linked with iron, and this inhibition of Chlamydia has an effect on the T3S system of this intracellular pathogen.The type III secretion (T3S) system is known to be a potent virulence mechanism shared by several pathogenic bacteria, including the Chlamydiaceae (10). All T3S systems share common structural components, while their effector proteins and methods of gene regulation vary widely. Targeting and inactivating common T3S components has been proposed as a strategy to fight infections caused by pathogens that require a T3S system for virulence (13). In an attempt to identify such compounds, Kauppi et al. (13) used a chemical genetics approach to screen a large number of synthetic compounds for the ability to inhibit Yersinia T3S gene expression. They identified compounds with the general structure of an acylated hydrazone of salicylaldehydes that were able to inhibit the pathogenic Yersinia T3S system, neutralizing the virulence while not affecting the growth of the organism (13, 17).We have previously reported that INP 0400 was able to inhibit the growth of Chlamydophila pneumoniae (27a). We reported that this compound inhibited C. pneumoniae development in a dose-dependent manner, was not cytotoxic, was not directly toxic to elementary bodies (EBs), and was effective at inhibiting the growth of Chlamydia trachomatis and Chlamydia muridarum. The appearance of inclusions at lower concentrations (Ͻ20 M) of INP 0400 resembled the appearance of inclusions seen in persistent infections resulting...
Chlamydia pneumoniae is the causative agent of respiratory tract infections and a number of chronic diseases. Here we investigated the involvement of the common TLR adaptor molecule MyD88 in host responses to C. pneumoniae-induced pneumonia in mice. MyD88-deficient mice were severely impaired in their ability to mount an acute early inflammatory response toward C. pneumoniae. Although the bacterial burden in the lungs was comparable 5 days after infection, MyD88-deficient mice exhibited only minor signs of pneumonia and reduced expression of inflammatory mediators. MyD88-deficient mice were unable to up-regulate proinflammatory cytokines and chemokines, demonstrated delayed recruitment of CD8؉ and CD4؉ T cells to the lungs, and were unable to clear the pathogen from their lungs at day 14. At day 14 the MyD88-deficent mice developed a severe, chronic lung inflammation with elevated IL-1 and IFN-␥ leading to increased mortality, whereas wild-type mice as well as TLR2-or TLR4-deficient mice recovered from acute pneumonia and did not show delayed bacterial clearance. Thus, MyD88 is essential to recognize C. pneumoniae infection and initiate a prompt and effective immune host response against this organism leading to clearance of bacteria from infected lungs.
Chlamydia pneumoniae has been shown to possess at least 13 genes that are homologous with other known type III secretion (TTS) systems. Upon infection of HEp-2 cells with C. pneumoniae, the expression of these genes was followed by reverse transcriptase PCR throughout the developmental cycle of this obligate intracellular pathogen. In addition, expression was analyzed when C. pneumoniae was grown in the presence of human gamma interferon (IFN-␥). The groEL-1, ompA, and omcB genes were used as markers for the early, middle, and late stages of the developmental cycle, respectively, and the inhibition of expression of the fstK gene was used as a marker for the effect of IFN-␥ on the maturation of C. pneumoniae. In the absence of IFN-␥, the TTS genes were expressed as follows: early stage (1.5 to 8 h), yscC, yscS, yscL, yscJ and lcrH-2; middle stage (by 12 to 18 h), lcrD, yscN, and yscR; and late stage (by 24 h), lcrE, sycE, lcrH-1, and yscT. Of the genes expressed early, the lcrH-2 gene was detected the earliest, at 1.5 h. Expression of the yscU gene was not detected at any of the time points examined. Under the influence of IFN-␥, the cluster of TTS genes that were normally not expressed until the middle to late stages of the developmental cycle, namely, lcrD, lcrE, and sycE, as well as lcrH-1, were down-regulated, and expression could not be detected up to 48 h. In contrast, the expression of the other TTS genes appeared to be unchanged in the presence of IFN-␥. The lcrH-1 and lcrH-2 genes differed from one another in both their temporal expression and response to IFN-␥. In other TTS systems, these genes code for proteins that function in regulation of effector protein synthesis as well as serve as chaperones for proteins that provide for the translocation of the effector proteins into the host cell. In summary, the expression pattern of the TTS genes of C. pneumoniae examined suggests that they are temporally regulated throughout the developmental cycle. Furthermore, paralleling the inhibition of the maturation of the reticulate body to the elementary body, TTS genes expressed in the later stages of the cycle appear to be down-regulated when the organism is grown in the presence of IFN-␥.
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