Parasitic protozoa of the genus Leishmania have provided a useful perspective for immunologists in terms of host defense mechanisms critical for the resolution of infection caused by intracellular pathogens. These organisms, which normally reside in a late endosomal, major histocompatibility complex (MHC) class II(+) compartment within host macrophages cells, require CD4(+) T-cell responses for the control of disease. The paradigm for the CD4(+) T-helper 1 (Th1)/Th2 dichotomy is largely based on the curing/non-curing responses, respectively, to Leishmania major infection. However, this genus of parasitic protozoa is evolutionarily diverse, with the cutaneous disease-causing organisms of the Old World (L. major) and New World (Leishmania mexicana/ Leishmania amazonensis) having diverged 40-80 million years ago. Further adaptations to survive within the visceral organs (for Leishmania donovani, Leishmania chagasi, and Leishmania infantum) must have been required. Consequently, significant differences in host-parasite interactions have evolved. Different virulence factors have been identified for distinct Leishmania species, and there are profound differences in the immune mechanisms that mediate susceptibility/resistance to infection and in the pathology associated with disease. These variations not only point to interesting features of the host-pathogen interaction and immunobiology of this genus of parasitic protozoa, but also have important implications for immunotherapy and vaccine development.
To study the role of CD40 ligand (CD40L) in the host immune responses against intracellular pathogens, we infected CD40L knockout (CD40L-/-) mice with Leishmania amazonensis. Although wild-type mice were susceptible to infection and developed progressive ulcerative lesions, tissue parasite burdens in CD40L-/- mice were significantly higher. This heightened susceptibility to infection was associated with an impaired T cell and macrophage activation and altered inflammatory response, as reflected by low levels of IFN gamma, lymphotoxin-tumor necrosis factor (LT-TNF), and nitric oxide (NO) production. Furthermore, CD40L-/- mice failed to generate a protective immune response after immunization. These results indicate an essential role of cognate CD40-CD40L interactions in the generation of cellular immune responses against an intracellular parasite.
We show here that maintenance of Leishmania infections with Leishmania mexicana complex parasites (Leishmania amazonensis and Leishmania pifanoi) is impaired in the absence of circulating antibody. In these studies, we used mice genetically altered to contain no circulating antibody, with and without functional B cells. This experimental design allowed us to rule out a critical role for B cell antigen presentation in Leishmania pathogenesis. In addition, we show that mice lacking the common γ chain of Fc receptors (FcγRI, FcεRI, and FcγRIII) are similarly refractory to infection with these parasites. These observations establish a critical role for antibody in the pathogenesis associated with infection by members of the L. mexicana complex.
Leishmania, an obligate intracellular parasite, binds several receptors to trigger engulfment by phagocytes, leading to cutaneous or visceral disease. These receptors include complement receptor 3 (CR3), used by promastigotes, and the Fc receptor (FcR), used by amastigotes. The mechanisms mediating uptake are not well understood. Here we show that Abl family kinases mediate both phagocytosis and the uptake of Leishmania amazonensis by macrophages (Ms). Imatinib, an Abl/Arg kinase inhibitor, decreases opsonized polystyrene bead phagocytosis and Leishmania uptake. Interestingly, phagocytosis of IgG-coated beads is decreased in Arg-deficient Ms, while that of C3bi-coated beads is unaffected. Conversely, uptake of C3bi-coated beads is decreased in Abl-deficient Ms, but that of IgG-coated beads is unaffected. Consistent with these results, Abl-deficient Ms are inefficient at C3bi-opsonized promastigote uptake, and Arg-deficient Ms are defective in IgG1-opsonized amastigote uptake. Finally, genetic loss of Abl or Arg reduces infection severity in murine cutaneous leishmaniasis, and imatinib treatment results in smaller lesions with fewer parasites than in controls. Our studies are the first to demonstrate that efficient phagocytosis and maximal Leishmania infection require Abl family kinases. These results highlight Abl family kinase-mediated signaling pathways as potential therapeutic targets for leishmaniasis. L eishmania parasites cause cutaneous or visceral disease in 1 to 2 million people a year in the developing world (17). Leishmania undergoes two life cycle stages: (i) the promastigote, found in the sand fly, and (ii) the amastigote, found in mammalian hosts. When an infected sand fly bites a host, the injected promastigotes must be engulfed by phagocytes to establish infection. The promastigotes then differentiate into amastigotes within the phagolysosome. If the amastigote finds itself outside a cell, it must be reengulfed for continued infection (23).Several M surface proteins permit Leishmania uptake. Promastigote internalization is mediated by the fibronectin receptor (integrin ␣51) (2), the mannose-fucose receptor (63, 64), and complement receptors CR1 (10) and CR3 (38). Promastigotes may interact directly with CR3 (49), but binding is facilitated by opsonization with C3bi, a complement component (22,37,40,45). Both CR3 and the Fc receptor (FcR) mediate amastigote uptake (16); interactions with the latter are facilitated by IgG opsonization (35). The FcR subclass Fc␥R, which mediates IgG-mediated phagocytosis (33), is most likely responsible for amastigote uptake by Ms. Indeed, internalization of IgG-opsonized amastigotes via FcR␥I and -III sustains infection in murine cutaneous leishmaniasis (8,24,65). Adhesion of Leishmania to any of these receptors causes an actin-rich phagocytic cup to form and engulf the parasite (30). Our study explores the requirement for actin regulatory proteins in efficient Leishmania internalization.The Abl family kinases Abl and Arg translate signals from adhesion and growth...
Parasitic organisms have evolved specialized strategies to evade immune defense mechanisms. We describe herein an ortholog of the cytokine, macrophage migration inhibitory factor (MIF), which is produced by the obligate intracellular parasite, Leishmania major. The Leishmania MIF protein, Lm1740MIF, shows significant structural homology with human MIF as revealed by a high-resolution x-ray crystal structure (1.03 Å). Differences between the two proteins in the N-terminal tautomerization site are evident, and we provide evidence for the selective, species-specific inhibition of MIF by small-molecule antagonists that target this site. Lm1740MIF shows significant binding interaction with the MIF receptor, CD74 (Kd = 2.9 × 10−8 M). Like its mammalian counterpart, Lm1740MIF induces ERK1/2 MAP kinase activation in a CD74-dependent manner and inhibits the activation-induced apoptosis of macrophages. The ability of Lm1740MIF to inhibit apoptosis may facilitate the persistence of Leishmania within the macrophage and contribute to its evasion from immune destruction.
Trypanosomatid protozoan parasites cause several important tropical diseases and have been a fertile ground for the discovery of molecular paradigms such as trans-splicing and RNA editing. Transfection-based methods for the study of these organisms have recently been developed, and we have now designed an expression vector, pX, which contains only 2.3 kilobases of Leishmania DNA and can be stably transfected with high efficiency. Genes encoding Escherichia coli ,B-galactosidase or a Leishmania amazonensis protective membrane glycoprotein (GP46A/M-2) were inserted into the pX expression site and transfected into Leishmania major, where they directed the synthesis of high levels of mRNAs formed by 5' and 3' processing events occurring predominantly at the sites used by the normal transcripts. Colony assays and immunoblot analysis showed that both proteins were produced; enzymatically active f8-galactosidase comprised =1% of total protein. Sizes of the GP46A protein synthesized in transfected L. major or L. amazonensis were similar and differed from the predominant L. amazonensis GP46, suggesting that the GP46A gene may encode a variant GP46 family member. Because these vectors function efficiently in pathogenic species of Leishmania, pX will facilitate the genetic analyses of parasite proteins crucial for infectivity as well as the identification of cis-acting elements mediating transcription and replication.
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