Contrary to BCG, MLM fails to induce the production of TNF alpha and NO by macrophages.

Pathogenic mycobacteria must possess efficient survival mechanisms to resist the harsh conditions of the intraphagosomal milieu. In this sense, Mycobacterium lepraemurium (MLM) is one of the most evolved intracellular parasites of murine macrophages; this microorganism has developed a series of properties that allows it not only to resist, but also to multiply within the inhospitable environment of the phagolysosome. Inside the macrophages, MLM appears surrounded by a thick lipid-envelope that protects the microorganism from the digestive effect of the phagosomal hydrolases and the acid pH. MLM produces a disease in which the loss of specific cell-mediated immunity ensues, thus preventing activation of macrophages. In vitro, and possibly also in vivo, MLM infects macrophages without triggering the oxidative (respiratory burst) response of these cells, thus preventing the production of the toxic reactive oxygen intermediaries (ROI). Supporting the idea that MLM is within the most evolved pathogenic microorganisms, in the present study we found, that contrary to BCG, M. lepraemurium infects macrophages without stimulating these cells to produce meaningful levels of tumor necrosis factor alpha (TNF alpha) or nitric oxide (NO). Thus, the ability of the microorganisms to stimulate in their cellular hosts, the production of ROI and RNI (reactive nitrogen intermediates), seems to be an inverse correlate of their pathogenicity; the lesser their ability, the greater their pathogenicity.

Endogenous interleukin-12 is critical for controlling the late but not the early stage of Leishmania mexicana infection in C57BL/6 mice.

The role of interleukin-12 (IL-12) has been clearly established in the resistance of C57BL/6 (B6) mice to Leishmania major infection, but its involvement in the control of Leishmania mexicana infection remains to be determined. Here, we show the following. (i) L. mexicana, in contrast to L. major, induces the development of nonhealing lesions in B6 mice. (ii) Cells expressing IL-12p40, gamma interferon (IFN-gamma), NOS2, and CD40L are numerous in the footpad lesion and/or the draining popliteal lymph node of animals infected for up to 14 weeks with L. mexicana. (iii) B6 mice, either IL-12p40 deficient or treated with IL-12p40-neutralizing antibodies, display a dramatic enhancement of primary and secondary lesions leading to death 10 weeks after inoculation with L. mexicana. (iv) Splenocytes harvested 4 and 8 weeks after infection of IL-12p40(-/-) B6 mice with L. mexicana are unable to produce IFN-gamma, but secrete IL-4, IL-10, and IL-18. Thus, the early control of L. mexicana infection by B6 mice is independent of IL-12, whereas IL-12 and Th1 responses play a key role in controlling the late stages of L. mexicana infection. However, they fail to resolve lesions, in contrast to L. major infection, emphasizing the different outcomes induced by these two Leishmania species in B6 mice.

Parasitic load and histopathology of cutaneous lesions, lymph node, spleen, and liver from BALB/c and C57BL/6 mice infected with Leishmania mexicana.

The course of infection, parasitic loads, and histopathology of cutaneous lesions, draining lymph node, spleen, and liver were compared in BALB/c and C57BL/6 mice over a period of 34 weeks after inoculation in footpad with promastigotes of a Leishmania mexicana reference strain. The results show that the primary footpad lesions first present a 12-week phase that develops similarly in both strains of mice. Thereafter, a cutaneous and visceral dissemination of L. mexicana parasites occurs in BALB/c mice; the latter experience an extensive breakdown of the lymphoid organ microarchitecture, whereas C57BL/6 mice succeed in eliminating the parasite infection from the lymph nodes but not from the primary cutaneous lesion, which does not heal. These results highlight marked differences between responses of key anatomical compartments controlling L. mexicana infection in BALB/c and C57BL/6 mice.

Contrary to BCG, MLM fails to induce the production of TNFx and NO by macrophages

Pathogenic mycobacteria must possess efficient survival mechanisms to resist the harsh conditions of the intraphagosomal milieu. In this sense, Mycobacterium lepraemurium (MLM) is one of the most evolved intracellular parasites of murine macrophages; this microorganism has developed a series of properties that allows it not only to resist, but also to multiply within the inhospitable environment of the phagolysosome. Inside the macrophages, MLM appears surrounded by a thick lipid-envelope that protects the microorganism from the digestive effect of the phagosomal hydrolases and the acid pH. MLM produces a disease in which the loss of specific cell-mediated immunity ensues, thus preventing activation of macrophages. In vitro, and possibly also in vivo, MLM infects macrophages without triggering the oxidative (respiratory burst) response of these cells, thus preventing the production of the toxic reactive oxygen intermediaries (ROI). Supporting the idea that MLM is within the most evolved pathogenic microorganisms, in the present study we found, that contrary to BCG, M. lepraemurium infects macrophages without stimulating these cells to produce meaningful levels of tumor necrosis factor alpha (TNF alpha) or nitric oxide (NO). Thus, the ability of the microorganisms to stimulate in their cellular hosts, the production of ROI and RNI (reactive nitrogen intermediates), seems to be an inverse correlate of their pathogenicity; the lesser their ability, the greater their pathogenicity.