Sensing Host Arginine Is Essential for Leishmania Parasites' Intracellular Development.

Arginine homeostasis in lysosomes is critical for the growth and metabolism of mammalian cells. Phagolysosomes of macrophages are the niche where the parasitic protozoan Leishmania resides and causes human leishmaniasis. During infection, parasites encounter arginine deprivation, which is monitored by a sensor on the parasite cell surface. The sensor promptly activates a mitogen-activated protein kinase 2 (MAPK2)-mediated arginine deprivation response (ADR) pathway, resulting in upregulating the abundance and activity of the Leishmania arginine transporter (AAP3). Significantly, the ADR is also activated during macrophage infection, implying that arginine levels within the host phagolysosome are limiting for growth. We hypothesize that ADR-mediated upregulation of AAP3 activity is necessary to withstand arginine starvation, suggesting that the ADR is essential for parasite intracellular development. CRISPR/Cas9-mediated disruption of the AAP3 locus yielded mutants that retain a basal level of arginine transport but lack the ability to respond to arginine starvation. While these mutants grow normally in culture, they were impaired in their ability to develop inside THP-1 macrophages and were ∼70 to 80% less infective in BALB/c mice. Hence, inside the host macrophage, Leishmania must overcome the arginine "hunger games" by upregulating the transport of arginine via the ADR. We show that the ability to monitor and respond to changes in host metabolite levels is essential for pathogenesis.IMPORTANCE In this study, we report that the ability of the human pathogen Leishmania to sense and monitor the lack of arginine in the phagolysosome of the host macrophage is essential for disease development. Phagolysosomes of macrophages are the niche where Leishmania resides and causes human leishmaniasis. During infection, the arginine concentration in the phagolysosome decreases as part of the host innate immune response. An arginine sensor on the Leishmania cell surface activates an arginine deprivation response pathway that upregulates the expression of a parasite arginine transporter (AAP3). Here, we use CRISPR/Cas9-mediated disruption of the AAP3 locus to show that this response enables Leishmania parasites to successfully compete with the host macrophage in the "hunger games" for arginine.

Lysosome assembly and disassembly changes endocytosis rate through the Leishmania cell cycle.

The Leishmania lysosome has an atypical structure, consisting of an elongated vesicle-filled tubule running along the anterior-posterior axis of the cell, which is termed the multivesicular tubule (MVT) lysosome. Alongside, the MVT lysosome is one or more microtubules, the lysosomal microtubule(s). Previous work indicated there were cell cycle-related changes in MVT lysosome organization; however, these only provided snapshots and did not connect the changes in the lysosomal microtubule(s) or lysosomal function. Using mNeonGreen tagged cysteine peptidase A and SPEF1 as markers of the MVT lysosome and lysosomal microtubule(s), we examined the dynamics of these structures through the cell cycle. Both the MVT lysosome and lysosomal microtubule(s) elongated at the beginning of the cell cycle before plateauing and then disassembling in late G2 before cytokinesis. Moreover, the endocytic rate in cells where the MVT lysosome and lysosomal microtubule(s) had disassembled was extremely low. The dynamic nature of the MVT lysosome and lysosomal microtubule(s) parallels that of the Trypanosoma cruzi cytostome/cytopharynx, which also has a similar membrane tubule structure with associated microtubules. As the cytostome/cytopharynx is an ancestral feature of the kinetoplastids, this suggests that the Leishmania MVT lysosome and lysosomal microtubule(s) are a reduced cytostome/cytopharynx-like feature.

Leishmania amazonensis hijacks host cell lysosomes involved in plasma membrane repair to induce invasion in fibroblasts.

Intracellular parasites of the genus Leishmania are the causative agents of leishmaniasis. The disease is transmitted by the bite of a sand fly vector, which inoculates the parasite into the skin of mammalian hosts, including humans. During chronic infection the parasite lives and replicates inside phagocytic cells, notably the macrophages. An interesting, but overlooked finding, is that other cell types and even non-phagocytic cells have been found to be infected by Leishmania spp. Nevertheless, the mechanisms by which Leishmania invades such cells had not been previously studied. Here, we show that L. amazonensis can induce their own entry into fibroblasts independently of actin cytoskeleton activity, and, thus, through a mechanism that is distinct from phagocytosis. Invasion involves subversion of host cell functions, such as Ca2+ signaling and recruitment and exocytosis of host cell lysosomes involved in plasma membrane repair.This article has an associated First Person interview with the first author of the paper.

Phagosome proteomics to study Leishmania's intracellular niche in macrophages.

Intracellular pathogens invade their host cells and replicate within specialized compartments. In turn, the host cell initiates a defensive response trying to kill the invasive agent. As a consequence, intracellular lifestyle implies morphological and physiological changes in both pathogen and host cell. Leishmania spp. are medically important intracellular protozoan parasites that are internalized by professional phagocytes such as macrophages, and reside within the parasitophorous vacuole inhibiting their microbicidal activity. Whereas the proteome of the extracellular promastigote form and the intracellular amastigote form have been extensively studied, the constituents of Leishmania's intracellular niche, an endolysosomal compartment, are not fully deciphered. In this review we discuss protocols to purify such compartments by means of an illustrating example to highlight generally relevant considerations and innovative aspects that allow purification of not only the intracellular parasites but also the phagosomes that harbor them and analyze the latter by gel free proteomics.

Intracellular Survival of Leishmania major Depends on Uptake and Degradation of Extracellular Matrix Glycosaminoglycans by Macrophages.

Leishmania parasites replicate within the phagolysosome compartment of mammalian macrophages. Although Leishmania depend on sugars as a major carbon source during infections, the nutrient composition of the phagolysosome remains poorly described. To determine the origin of the sugar carbon source in macrophage phagolysosomes, we have generated a N-acetylglucosamine acetyltransferase (GNAT) deficient Leishmania major mutant (∆gnat) that is auxotrophic for the amino sugar, N-acetylglucosamine (GlcNAc). This mutant was unable to grow or survive in ex vivo infected macrophages even when macrophages were cultivated in presence of exogenous GlcNAc. In contrast, the L. major ∆gnat mutant induced normal skin lesions in mice, suggesting that these parasites have access to GlcNAc in tissue macrophages. Intracellular growth of the mutant in ex vivo infected macrophages was restored by supplementation of the macrophage medium with hyaluronan, a GlcNAc-rich extracellular matrix glycosaminoglycan. Hyaluronan is present and constitutively turned-over in Leishmania-induced skin lesions and is efficiently internalized into Leishmania containing phagolysosomes. These findings suggest that the constitutive internalization and degradation of host glycosaminoglycans by macrophages provides Leishmania with essential carbon sources, creating a uniquely favorable niche for these parasites.

Biological roles of cysteine proteinases in the pathogenesis of Trichomonas vaginalis.

Human trichomonosis, infection with Trichomonas vaginalis, is the most common non-viral sexually transmitted disease in the world. The host-parasite interaction and pathophysiological processes of trichomonosis remain incompletely understood. This review focuses on the advancements reached in the area of the pathogenesis of T. vaginalis, especially in the role of the cysteine proteinases. It highlights various approaches made in this field and lists a group of trichomonad cysteine proteinases involved in diverse processes such as invasion of the mucous layer, cytoadherence, cytotoxicity, cytoskeleton disruption of red blood cells, hemolysis, and evasion of the host immune response. A better understanding of the biological roles of cysteine proteinases in the pathogenesis of this parasite could be used in the identification of new chemotherapeutic targets. An additional advantage could be the development of a vaccine in order to reduce transmission of T. vaginalis.

IL-17A promotes macrophage effector mechanisms against Trypanosoma cruzi by trapping parasites in the endolysosomal compartment.

The contribution of the IL-23-IL-17A pathway to resistance against extracellular bacterial infections is well established, whereas its role in immunity to intracellular pathogens is much less clear. To analyze the contribution of the IL-23-IL-17A-axis to resistance against Trypanosoma cruzi infection, we infected IL-23p19(-/-) mice and IL-17A(-/-) mice with T. cruzi. Both mouse strains were susceptible to T. cruzi infection despite strong Th1 immune responses. In vitro experiments revealed that IL-17A, but not IL-23, directly stimulates macrophages to internalize T. cruzi parasites by phagocytosis, which is in contrast to the active invasion process normally used by T. cruzi. In contrast to the active entry of parasites into macrophages, the IL-17A-driven phagocytosis prolonged residency of parasites in the endosomal/lysosomal compartment of the macrophage, which subsequently led to eradication of parasites. This IL-17A-dependent mechanism represents a novel function of IL-17A trapping pathogens in endosomal/lysosomal compartments and enhancing exposure time to antimicrobial effectors of the macrophage.

Autophagy in immunity against Toxoplasma gondii.

A decisive outcome during host-pathogen interaction is governed by whether pathogen-containing vacuoles fuse with lysosomes. Fusion with lysosomes typically kills microbes. Toxoplasma gondii represents a classical example of an intracellular pathogen that survives within host cells by preventing the endosomal-lysosomal compartments from fusing with the vacuoles that contain the pathogen. Thus, T. gondii provides an excellent model to determine if the immune system can target a pathogen for lysosomal degradation. CD40, a major regulator of cell-mediated immunity, activates macrophages to kill T. gondii through a process that requires recruitment of autophagosomes around the parasitophorous vacuole, leading to lysosomal degradation of the parasite. These studies demonstrate that cell-mediated immunity can activate autophagy to kill a pathogen. CD40-induced autophagy likely contributes to resistance against T. gondii, particularly in neural tissues, the main sites affected by this pathogen.

Differences in human macrophage receptor usage, lysosomal fusion kinetics and survival between logarithmic and metacyclic Leishmania infantum chagasi promastigotes.

The obligate intracellular protozoan, Leishmania infantum chagasi (Lic) undergoes receptor-mediated phagocytosis by macrophages followed by a transient delay in phagolysosome maturation. We found differences in the pathway through which virulent Lic metacyclic promastigotes or avirulent logarithmic promastigotes are phagocytosed by human monocyte-derived macrophages (MDMs). Both logarithmic and metacyclic promastigotes entered MDMs through a compartment lined by the third complement receptor (CR3). In contrast, many logarithmic promastigotes entered through vacuoles lined by mannose receptors (MR) whereas most metacyclic promastigotes did not (P < 0.005). CR3-positive vacuoles containing metacyclic promastigotes stained for caveolin-1 protein, suggesting CR3 localizes in caveolae during phagocytosis. Following entry, the kinetics of phagolysosomal maturation and intracellular survival also differed. Vacuoles containing metacyclic parasites did not accumulate lysosome-associated membrane protein-1 (LAMP-1) at early times after phagocytosis, whereas vacuoles with logarithmic promastigotes did. MDMs phagocytosed greater numbers of logarithmic than metacyclic promastigotes, yet metacyclics ultimately replicated intracellularly with greater efficiency. These data suggest that virulent metacyclic Leishmania promastigotes fail to ligate macrophage MR, and enter through a path that ultimately enhances intracellular survival. The relatively quiescent entry of virulent Leishmania spp. into macrophages may be accounted for by the ability of metacyclic promastigotes to selectively bypass deleterious entry pathways.

Autophagosome-independent essential function for the autophagy protein Atg5 in cellular immunity to intracellular pathogens.

The physiologic importance of autophagy proteins for control of mammalian bacterial and parasitic infection in vivo is unknown. Using mice with granulocyte- and macrophage-specific deletion of the essential autophagy protein Atg5, we show that Atg5 is required for in vivo resistance to the intracellular pathogens Listeria monocytogenes and Toxoplasma gondii. In primary macrophages, Atg5 was required for interferongamma (IFN-gamma)/LPS-induced damage to the T. gondii parasitophorous vacuole membrane and parasite clearance. While we did not detect classical hallmarks of autophagy, such as autophagosomes enveloping T. gondii, Atg5 was required for recruitment of IFN-gamma-inducible p47 GTPase IIGP1 (Irga6) to the vacuole membrane, an event that mediates IFN-gamma-mediated clearance of T. gondii. This work shows that Atg5 expression in phagocytic cells is essential for cellular immunity to intracellular pathogens in vivo, and that an autophagy protein can participate in immunity and intracellular killing of pathogens via autophagosome-independent processes such as GTPase trafficking.

Trafficking of Leishmania donovani promastigotes in non-lytic compartments in neutrophils enables the subsequent transfer of parasites to macrophages.

Inoculation of Leishmania (L.) spp. promastigotes in the dermis of mammals by blood-feeding sand flies can be accompanied by the rapid recruitment of neutrophils, inflammatory monocytes and dendritic cells. Despite the presence of these lytic leucocytes, parasitism is efficiently established. We show here that Leishmania donovani promastigotes are targeted to two different compartments in neutrophils. The compartments harbouring either damaged or non-damaged parasites were characterized at the electron microscopy (EM) level using the glucose 6-phosphatase cytochemistry and endosome-phagosome fusion assays. One involves the contribution of lysosomes leading to the formation of highly lytic compartments where parasites are rapidly degraded. The other is lysosome-independent and involves the contribution of a compartment displaying some features of the endoplasmic reticulum (ER) where parasites are protected from degradation. Using genetically modified parasites, we show that the promastigote surface lipophosphoglycan (LPG) is required to inhibit lysosome fusion and maintain parasites in neutrophil compartments displaying ER features. L. donovani-harbouring neutrophils that eventually enter apoptosis can be phagocytosed by macrophages enabling the stealth entry of parasites into their final replicative host cells. Thus, the ability of L. donovani to avoid trafficking into lysosomes-derived compartments in short-lived neutrophils constitutes a key process for the subsequent establishment of long-term parasitism.

A Leishmania amazonensis ZIP family iron transporter is essential for parasite replication within macrophage phagolysosomes.

Infection of mammalian hosts with Leishmania amazonensis depends on the remarkable ability of these parasites to replicate within macrophage phagolysosomes. A critical adaptation for survival in this harsh environment is an efficient mechanism for gaining access to iron. In this study, we identify and characterize LIT1, a novel L. amazonensis membrane protein with extensive similarity to IRT1, a ZIP family ferrous iron transporter from Arabidopsis thaliana. The ability of LIT1 to promote iron transport was demonstrated after expression in yeast and in L. amazonensis LIT1-null amastigotes. Endogenous LIT1 was only detectable in amastigotes replicating intracellularly, and its intracellular expression was accelerated under conditions predicted to result in iron deprivation. Although L. amazonensis lacking LIT1 grew normally in axenic culture and had no defects differentiating into infective forms, replication within macrophages was abolished. Consistent with an essential role for LIT1 in intracellular growth as amastigotes, Deltalit1 parasites were avirulent. After inoculation into highly susceptible mice, no lesions were detected, even after extensive periods of time. Despite the absence of pathology, viable Deltalit1 parasites were recovered from the original sites of inoculation, indicating that L. amazonensis can persist in vivo independently of the ability to grow in macrophages. Our findings highlight the essential role played by intracellular iron acquisition in Leishmania virulence and identify this pathway as a promising target for therapeutic intervention.

Role of caveolae in Leishmania chagasi phagocytosis and intracellular survival in macrophages.

Caveolae are membrane microdomains enriched in cholesterol, ganglioside M1 (GM1) and caveolin-1. We explored whether caveolae facilitate the entry of Leishmania chagasi into murine macrophages. Transient depletion of macrophage membrane cholesterol by 1 h exposure to methyl-beta-cyclodextrin (MbetaCD) impaired the phagocytosis of non-opsonized and serum-opsonized virulent L. chagasi. In contrast, MbetaCD did not affect the phagocytosis of opsonized attenuated L. chagasi. As early as 5 min after phagocytosis, virulent L. chagasi colocalized with the caveolae markers GM1 and caveolin-1, and colocalization continued for over 48 h. We explored the kinetics of lysosome fusion. Whereas fluorescent-labelled dextran entered macrophage lysosomes by 30 min after addition, localization of L. chagasi in lysosomes was delayed for 24-48 h after phagocytosis. However, after transient depletion of cholesterol from macrophage membrane with MbetaCD, the proportion of L. chagasi-containing phagosomes that fused with lysosomes increased significantly. Furthermore, intracellular replication was impaired in parasites entering after transient cholesterol depletion, even though lipid microdomains were restored by 4 h after treatment. These observations suggest that virulent L. chagasi localize in caveolae during phagocytosis by host macrophages, and that cholesterol-containing macrophage membrane domains, such as caveolae, target parasites to a pathway that promotes delay of lysosome fusion and intracellular survival.

[Formation and diversity of parasitophorous vacuoles in parasitic protozoa. The Coccidia (Sporozoa, Apicomplexa)]. / Puti formirovaniia parazitofornykh vakuolei i ikh raznoobrazie u paraziticheskikh prosteishikh. Koktsidii (Sporozoa, Apicomplexa).

Data on parasitophorous vacuole (PV) formation in host cells (HC) harbouring different intracellular protozoan parasites have been reviewed and critically analysed, with special reference to the main representatives of the Coccidia. The vacuole membrane (PVM) is the interface between host and parasite, playing a role in nutrient acquisition by the parasite from the HC. The PV phenomenon is regarded as a generalized HC response to the introduction of alien bodies (microorganisms), which eventually reflects the evolutionary established host-parasite relationships at cellular, subcellular and molecular levels. Special attention has been paid to the existing morpho-functional diversity of the PVs within the same genera and species of parasites, and even at different stages of the parasite life cycle. The PVM is generally considered to derive from the HC plasmalemma, whose biochemical composition undergoes significant changes as the intravacuolar parasite grows. The original HC proteins are selectively excluded from the PVM, while those of the parasite are incorporated. As the result, the changed PVM becomes not fusigenic for HC lysosomes. For Toxoplasma gondii and other cyst-forming coccidia (Isospora, Sarcocystis), a definite correlation has been noticed between the extent of rhoptry and dense granule secrets released by a zoite during HC internalization, on the one hand, and the pattern of the PV that forms, on the other one. In T. gondii, tachyzoites, known to discharge abundant secrets, commonly force the development of PVs limited with a single unit membrane and equipped with a tubulovesicular network in the lumen. Unlike, bradyzoites known to be deficient in secretory materials trigger the formation of PVs with a three-membrane lining composed of the changed invaginated plasmalemma in addition to two membranes of endoplasmic reticulum. The two different types of PV harbour, respectively, exoenteric and enteric stages of T. gondii, the latter being confined to the cat intestine only. Unlike, all endogenous stages of the classic intestinal coccidia (Eimeria spp.) develop within PVs limited with a single membrane, with some invaginations extending into the PV lumen. Unusual PV patterns are characteristic of the extracytoplasmic eimerian coccidia (Cryptosporidium, Epieimeria) and adeleid haemogreagarines (Karyolysus). In cyst-forming coccidia, the PVM is actively involved in tissue cyst wall formation, thus protecting the encysted parasites from recognition by the host immune system. All this strongly suggests that the PV is far from being an indifferent membraneous vesicle containing a parasite, but represents a metabolically active compartment in infected cells. Since all the coccidia are obligate intracellular parasites, the mode of their intimate interaction with the HC, largely accomplished via the PV and its membrane, is vital for their survival as biological species.

Leishmania RAB7: characterisation of terminal endocytic stages in an intracellular parasite.

Leishmania species are intracellular parasites that inhabit a parasitophorous vacuole (PV) within host macrophages and engage with the host endo-membrane network to avoid clearance from the cell. Intracellular Leishmania amastigotes exhibit a high degree of proteolytic/lysosomal activity that may assist degradation of MHC class II molecules and subsequent interruption of antigen presentation. As an aid to further analysis of the endosomal/lysosomal events that could facilitate this process, we have characterised a Leishmania homologue of the late endosomal marker, Rab7, thought to be involved in the terminal steps of endocytosis and lysosomal delivery. The Leishmania major Rab7 (LmRAB7) protein is expressed throughout the life-cycle, shows 73 and 64% identity to Trypanosoma cruzi and Trypanosoma brucei Rab7s (TcRAB7 and TbRAB7), respectively, and includes a kinetoplastid-specific insertion. The recombinant protein binds GTP and polyclonal antibodies raised against this antigen recognise structures in the region of the cell between the nucleus and kinetoplast. By immunoelectron microscopy of axenic amastigotes, Leishmania mexicana Rab7 (LmexRAB7) is found juxtaposed to and overlapping membrane structures labelled for the megasomal marker, cysteine proteinase B, confirming a late-endosomal/lysosomal localisation.

The developmental expression of Leishmania donovani A2 amastigote-specific genes is post-transcriptionally mediated and involves elements located in the 3'-untranslated region.

Leishmania donovani is a protozoan parasite that exists as a free-living promastigote in the sandfly insect vector and as an amastigote inside the mammalian host macrophage phagolysosome compartment. The L. donovani A2 genes have been described previously as developmentally expressed in amastigotes but can be induced experimentally in promastigotes by a combination of pH and temperature shifts, conditions that mimic the phagolysosomal compartment of the macrophage cell. Considering the importance of the amastigote stage in human infections, we have examined the molecular basis for amastigote stage-specific gene expression. Our results provide evidence that A2 developmental expression during the promastigote-to-amastigote cytodifferentiation is mediated through differential RNA stability and involves the A2 mRNA 3'-untranslated region. The site of processing in the 3'-untranslated region was a major factor for the accumulation of A2 mRNAs in cells incubated under phagolysosomal conditions. The stability of reporter gene transcripts bearing the A2 3'-untranslated region was increased in cells incubated at low pH, further confirming the importance of pH shift as an inducer for A2 expression. These observations contribute to defining the mechanism of amastigote-specific gene regulation in L. donovani. We also demonstrate the feasibility of using the A2 locus to express heterologous genes differentially in the amastigote form of the L. donovani parasite.

Estrategias del Histoplasma capsulatum para evadir los mecanismos citocidas de los fagocitos / Strategies of Histoplasma capsulatum to circumvent the cytocidal mechanisms of phagocytes

A pesar de que la proliferación de Histoplasma capsulatum dentro de los macrófagos está restringida por el desarrollo de la inmunidad mediada por células, y de que no existe una aparente falla en la capacidad fungicida de los macrófagos, bajo ciertas circunstancias, el H. capsulatum puede desenvolverse en este medio intracelular, el cual provee las condiciones nutricionales para el crecimiento del hongo y además, la posibilidad de acceso a otros órganos por las vías linfáticas y hemáticas. Pese a sucrecimiento intracelular, el medio interno dentro de los fagocitos es complejo y frecuentemente hostil al microorganismo. Los patógenos intracelulares deben superar una serie de obstáculos con el fin de prevenir su posible destrucción. En el presente artículo se revisan las estrategias de H. capsulatum para escapar a las agresiones del hospedero, desde el momento en que el parásito se encuentra sobre la superficie de la células hospedera hasta su sobrevivencia dentro de ésta. Además, se destacan los avences contemporáneos de los mecanismo de escape, utilizados por H. capsulatum, para facilitar su sobrevivencia en el medio ambiente intracelular

Phagolysosomes induits par Leishmania amazonensis et Coxiella burnetii: modèle pour l´étude de fusion entre grandes vacuoles de pahgocytose / Phagolysosomes induced by Leishmania amazonensis and Coxiella burnetii: a model for the study of merger between large vacuoles of pahgocytose

Actuellement, les connaissances sur l'interaction entre grandes vacuoles de phagocytose sont tres limitées. Il est important de signaler, les travaux pionniers sur la fusion entre les vacuoles contenant différents types des particu1es chez les Acantamcebas et les études sur l'interaction entre les phagosomes contenant le Staphylococcus aureus et les endosomes. L'objectif du travail ici présenté était d'étudier l'interaction entre grandes vacuoles de phagocytose en utilisant les cellules intactes de mammifere, les macrophages ou les cellules CHO ("chinese hamster ovary"). Nous avons utilisé comme vacuoles réceptrices deux types de phagolysosomes, la vacuole parasitophore induite par le parasite Leishmania amazonensis et celle induite par la bactérie Coxiella burnetii (vacuole de Coxiella). Ces grands phagolysosomes ont été choisis parce qu'elles sont facilement repérable au microscope optique et partagent entre elles des caractéristiques similaires. La vacuole parasitophore et la vacuole de Coxiella sont addifiées, contiennent des enzymes hydrolytiques, et il est connu que, les deux vacuoles se fusionnent avec les compartiments tardifs d'endocytose. Dans um premier temps, les vacuoles contenant les particu1es inertes, comme celles dérivées de la levure, les billes de latex ainsi que, les globules rouges fixés ou opsonisés, ont été utilisées comme les vacuoles donatrices. Nous avons démontré que les particu1es dérivées de la levure, le zymosan ou la levure tuée, étaient sélectivement transférées aux vacuoles parasitophores, puisque les billes de latex ou les globules rouges également phagocytés par les macrophages, étaient exc1us de ces vacuoles. D'abord, nous avons établi une méthode en pulse-chasse pour étudier le transfert de particules zymosan aux vacuoles parasitophores dans les macrophages infectés par L. amazonensis. Nous avons démontré que le transfert était vectoriel et quantal. Les études pharmacologiques ont montré que l'alcalinisation, par des bases faibles ou l'ionophore monensine, augmentait le transfert. Nous avons également démontré que la toxine cholérique augmentait le transfert probablement par des mécanismes, au moins en partie, dépendants de sa sous-unité B et indépendants de l' AMPc intracellulaire. Nous avons alors montré que la sous-unité B purifiée ou recombinante stimulait le transfert et que d'autres molécu1es qui augmentent l'AMPc intracellulaire, comme les inhibiteurs de phosphodiesterases, la forskoline ou le Br-AMPc réduisaient le transfert. Deuxiemement, nous avons comparé la capadté de fusion entre les vacuoles induites par L. amazonensis ou par C. burnetii dans les cellules CHO, et les vacuoles contenant différents particu1es inertes...

Distribution of parasite cysteine proteinases in lesions of mice infected with Leishmania mexicana amastigotes.

It is well established that Leishmania mexicana amastigotes contain large amounts of cysteine proteinases in their extended lysosomes. In this study it is shown that the cell-free supernatant of homogenized lesion tissue from infected mice contains large amounts of acid proteinases. The majority of this enzymatic activity also corresponds to cysteine proteinases from L. mexicana amastigotes. Immunoelectron microscopy of mouse lesion sections suggests, that frequently amastigotes lyse and release lysosomal cysteine proteinases into the parasitophorous vacuole of infected macrophages. The cysteine proteinases are also found extracellularly in the tissue presumably as a result of macrophage rupture and appear to persist in the lesion tissue, where they may damage host cells and the extracellular matrix.

Localization of major histocompatibility complex class II molecules in phagolysosomes of murine macrophages infected with Leishmania amazonensis.

Leishmania-infected macrophages are potential antigen-presenting cells for CD4+ T lymphocytes, which recognize parasite antigens bound to major histocompatibility complex class II molecules (Ia). However, the intracellular sites where Ia and antigens may interact are far from clear, since parasites grow within the modified lysosomal compartment of the host cell, whereas Ia molecules seem to be targeted to endosomes. To address this question, the expression and fate of Ia molecules were studied by immunocytochemistry in Leishmania amazonensis-infected murine macrophages stimulated with gamma interferon. In uninfected macrophages, Ia molecules were localized on the plasma membrane and in perinuclear vesicles, but they underwent a dramatic redistribution after infection, since most of the intracellular staining was then associated with the periphery of the parasitophorous vacuoles (p.v.) and quite often polarized towards amastigote-binding sites. The Ii invariant chain, which is transiently associated with Ia during their intracellular transport, although well expressed in infected macrophages, apparently did not reach the p.v. Similar findings were observed with macrophages from mice either resistant or highly susceptible to Leishmania infection. In order to determine the origin of p.v.-associated Ia, the fate of plasma membrane, endosomal, and lysosomal markers, detected with specific antibodies, was determined after infection. At 48 h after infection, p.v. was found to exhibit a membrane composition typical of mature lysosomes. Overall, these data suggest that (i) Ia located in p.v. originate from secondary lysosomes involved in the biogenesis of this compartment or circulate in several endocytic organelles, including lysosomes and (ii) p.v. could play a role in antigen processing and presentation. Alternatively, the presence of high amounts of Ia in p.v. could be due to a Leishmania-induced mechanism by means of which this organism may evade the immune response.