Study of Leishmania major-infected macrophages by use of lipophosphoglycan-specific monoclonal antibodies.

Leishmania major infection of macrophages is followed by a time-dependent appearance of lipophosphoglycan (LPG) that can be detected on the surface of infected cells by monoclonal antibodies. The origin of these LPG epitopes is probably the intracellular amastigote. LPG epitopes could be detected on the amastigote and the infected macrophage by a number of monoclonal antibodies directed to several distinct determinants on the phosphoglycan moiety. The macrophage-expressed LPG may be modified because, unlike the parasite LPG as expressed on promastigotes or amastigotes, it could not be radiolabeled by galactose oxidase or periodate treatment of infected cells followed by reduction with 3H-labeled sodium borohydride. Some LPG epitopes displayed on the macrophage may be anchored with glycosylphosphatidylinositol, and some may be in the water-soluble phosphoglycan form bound to macrophage integrins involved in its specific recognition. The water-soluble population could be released from the infected macrophage by gentle protease treatment.     

Monoclonal antibodies recognizing determinants specific for the promastigote stage of Leishmania mexicana

Two monoclonal antibodies (IX-IF9-D8 and IX-5H9-CI) produced to a membrane enriched fraction of Leishmania mexicana amazonensis promastigotes have been demonstrated to be specific for the promastigote (insect) form and not the amastigote (mammalian host) form of the parasite. The antigens recognized by these monoclonal antibodies are not found on amastigotes isolated from infected animals or on amastigotes isolated from a macrophage cell line J774 infected initially with promastigotes. The antigens are not re-expressed by amastigotes cultured at 34°C; however, amastigotes cultured at 24°C that have begun transformation into promastigotes do express these antigens. The level of expression of these antigens in cultures of amastigotes undergoing transformation into promastigotes, increases with time from 16 to 36 h and appears to correlate with the percentage of promastigotes. Two protein molecules with apparent molecular weights of 40 000 and 92 000 have been identified by radioimmune precipitation as associated with L. mexicana promastigote stage specific determinants.     

Differences in expression and exposure of promastigote and amastigote membrane molecules in Leishmania tropica.

The accessibility of particular Leishmania tropica promastigote (extracellular) and amastigote (intracellular) membrane molecules might be related to the relative abilities of the two stages to induce host immune responses. To examine the exposure of membrane antigens on resident macrophage-susceptible promastigotes and resident macrophage-resistant amastigotes, both stages were analyzed by polyacrylamide gel electrophoresis and immunoblotting after specific labeling and extraction procedures. Protein compositional studies, using metabolic labeling of promastigotes and amastigotes, demonstrated that both forms possessed numerous endogenously synthesized proteins. In addition, a marked difference was revealed in the external exposure of promastigote and amastigote membrane constituents when analyzed by 125I surface labeling or Western blot analysis. Whereas nine promastigote proteins were intensely to moderately iodinated, only one amastigote membrane component was similarly labeled (9.5K band). Western blot analyses with serum from a rabbit immunized with a mixture of both L. tropica stages indicated that the majority of promastigote molecules accessible to 125I may also react with immune serum. However, Western blots of extracted amastigotes identified several bands not seen on radiographs and thus not accessible to 125I. The external exposure of these amastigote molecules was confirmed in that immune serum adsorbed with viable, intact amastigotes was no longer reactive with amastigote extracts. Further, by Western blot analyses of sodium dodecyl sulfate- but not Nonidet P-40-extracted amastigotes, three amastigote-specific membrane antigens not previously observed with nonionic detergent extraction methods were identified. The autofluorographic pattern of amastigotes intrinsically labeled with N-[3H]acetylglucosamine, an amino sugar which is incorporated into membrane carbohydrates, was in excellent agreement with the pattern of antigens reactive with antibody in Western blots. Thus, with these cell surface labeling and extraction methods, promastigote and amastigote membranes were shown to be significantly different. Amastigotes possessed several membrane-associated molecules, but few appeared to be either accessible or reactive with 125I. Moreover, the majority of molecules not reactive with 125I, but reactive with antibodies, may be glycosylated. These observations are discussed relative to the ability of amastigotes both to survive within the degradative milieu of macrophage phagolysosomes and to evade host immune reactivity.     

Amastigote stage-specific monoclonal antibodies against Leishmania major.

Monoclonal antibodies were produced against gamma-irradiated amastigotes of Leishmania major. Five antibodies (T16 through T20) were selected which reacted in enzyme-linked immunoassays with the intracellular stage of the parasite. These antibodies did not react with promastigotes of L. major or Leishmania donovani. One of the monoclonal antibodies (T16) reacted with amastigotes of Leishmania mexicana amazonensis and L. donovani. Western blotting (immunoblotting) and immunoprecipitation of [35S]methionine-labeled amastigotes demonstrates that T16 reacted with multiple L. major amastigote components between 12 and 180 kilodaltons. Antibody T20 was shown to recognize a low-molecular-mass doublet (less than 26 kilodaltons) in both [14C]leucine- and [35S]methionine-labeled amastigotes. A protein of less than 180 kilodaltons was also weakly recognized by T17, T19, and T20 in metabolically labeled amastigotes. This protein reacted strongly with T16. The reactive antigens could be identified on the surface of amastigotes isolated from the lesions of infected mice and on newly transformed amastigotes within 24 h after the infection of mouse peritoneal macrophages by promastigotes. These monoclonal antibodies should prove useful for the diagnosis of L. major in human tissue biopsies.     

Lipophosphoglycan blocks attachment of Leishmania major amastigotes to macrophages.

Promastigotes of the intracellular protozoan parasite Leishmania major invade mononuclear phagocytes by a direct interaction between the cell surface lipophosphoglycan found on all Leishmania species and macrophage receptors. This interaction is mediated by phosphoglycan repeats containing oligomers of beta (1-3)Gal residues specific to L. major. We show here that although amastigotes also use lipophosphoglycan to bind to both primary macrophages and a cell line, this interaction is independent of the beta (1-3)Gal residues employed by promastigotes. Binding of amastigotes to macrophages could be blocked by intact lipophosphoglycan from L. major amastigotes as well as by lipophosphoglycan from promastigotes of several other Leishmania species, suggesting involvement of a conserved domain. Binding of amastigotes to macrophages could be blocked significantly by the monoclonal antibody WIC 108.3, directed to the lipophosphoglycan backbone. The glycan core of lipophosphoglycan could also inhibit attachment of amastigotes, but to a considerably lesser extent. The glycan core structure is also present in the type 2 glycoinositolphospholipids which are expressed on the surface of amastigotes at 100-fold-higher levels than lipophosphoglycan. However, their inhibitory effect could not be increased even when they were used at a 300-fold-higher concentration than lipophosphoglycan, indicating that lipophosphoglycan is the major macrophage-binding molecule on amastigotes of L. major. In the presence of complement, the attachment of amastigotes to macrophages was not altered, suggesting that lipophosphoglycan interacts directly with macrophage receptors.     

Cutaneous host defense in leishmaniasis: interaction of isolated dermal macrophages and epidermal Langerhans cells with the insect-stage promastigote.

Leishmania species are obligate intracellular pathogens of mononuclear phagocytes. Successful infection depends on sequestration of the promastigote (insect form) within host cells, allowing transformation into the relatively hardy amastigote stage. Promastigotes are killed readily by circulating phagocytes and nonimmune serum, suggesting that cutaneous infection is initiated within a permissive cell in the epidermis or dermis. From large sections of primate skin dermal macrophages and epidermal Langerhans cells were isolated, and their interaction with promastigotes of Leishmania major was investigated in vitro. Dermal macrophages were readily infected with promastigotes, and successful transformation to and replication of amastigotes was observed. Ingestion of promastigotes by dermal macrophages was not associated with a significant respiratory burst, in contrast to that by other macrophage populations, and was associated with significantly greater survival of parasites. Stimulation of these cells with phorbol myristate acetate or opsonized zymosan revealed that those cells were generally oxidatively deficient. Langerhans cells could not be successfully infected by promastigotes under similar conditions. Examination of these cells for expression of CR3, which has been identified as a potential Leishmania receptor, revealed that Langerhans cells did not express the alpha M subunit of CR3, whereas dermal macrophages were CR3 positive. These data support the concept that dermal macrophages are the site of initiation of Leishmania infection.     

Role of beta-D-galactofuranose in Leishmania major macrophage invasion

The role of glycosylinositol phospholipid 1 (GIPL-1) of Leishmania (Leishmania) major in the interaction of promastigotes and amastigotes with macrophages was analyzed. Monoclonal antibody MEST-1, which recognizes glycolipids containing terminal galactofuranose (Galf) residues (E. Suzuki, M. S. Toledo, H. K. Takahashi, and A. H. Straus, Glycobiology 7:463-468, 1997), was used to detect GIPL-1 in Leishmania by indirect immunofluorescence and to analyze its role in macrophage infectivity. L. major promastigotes showed intense fluorescence with MEST-1, and GIPL-1 was detected in both amastigote and promastigote forms by high-performance thin-layer chromatography immunostaining by using MEST-1. Delipidation of L. major promastigotes with isopropanol-hexane-water eliminated the MEST-1 reactivity, confirming that only GIPL-1 is recognized in either amastigotes or promastigotes of this species. The biological role of GIPL-1 in the ability of L. major to invade macrophages was studied by using either Fab fragments of MEST-1 or methylglycosides. Preincubation of parasites with Fab fragments reduced macrophage infectivity in about 80% of the promastigotes and 30% of the amastigotes. Preincubation of peritoneal macrophages with p-nitrophenyl-beta-galactofuranoside (10 mM) led to significant ( approximately 80%) inhibition of promastigote infectivity. These data suggest that a putative new receptor recognizing beta-D-Galf is associated with L. major macrophage infectivity and that GIPL-1 containing a terminal Galf residue is involved in the L. major-macrophage interaction.     

Roles of free GPIs in amastigotes of Leishmania

Glycosylated phosphatidylinositols (GPIs) are abundant cell surface molecules of the Leishmania. Amastigote-specific GPIs AmGPI-Y and AmGPI-Z, both ethanolamine (EtN)-containing glycolipids, were identified in Leishmania amazonensis. A paucity of GPI-anchored proteins in amastigotes of L. amazonensis made the kinetoplastid suitable for evaluating the importance of free (i.e. unconjugated to protein or polysaccharide) GPIs. A strain deficient in both AmGPI-Y and AmGPI-Z was produced by stable transfection of wild-type Leishmania with a GPI-phospholipase C gene. Phosphatidylinositol deficiency was not detected in the transfectants. GPI-deficient promastigotes infected murine macrophages in vitro and differentiated into amastigotes whose growth was arrested within the host cells. Cytostasis of amastigotes was also observed during axenic culture of GPI-deficient parasites. In a hamster model of leishmaniasis, GPI-deficient promastigotes produced smaller lesions with 20-fold fewer amastigotes than infections with control parasites. Together, these observations indicate that EtN-GPIs may be essential for amastigote viability, replication, and/or virulence. Implicit in these observations is the notion that drugs targeted against the GPI biosynthetic pathway might be of value in the management of human leishmaniasis.     

免疫小鼠及正常小鼠巨噬细胞对利什曼无鞭毛期的吞噬作用

内脏利什曼原虫主要寄生在巨噬细胞系统的单核吞噬细胞内,在一般情况下其无鞭毛期能抵抗巨噬细胞的杀灭作用。 为了观察经杜氏利什曼原虫免疫后的小鼠其巨噬细胞的作用,我们采用了CFW纯系小鼠,经不同免疫方法于免疫后不同时间观察了体外培养中巨噬细胞的吞噬功能。实验采用的巨噬细胞与杜氏利什曼原虫前鞭毛期的比例为1:4。从每24小时吞噬功能的结果表明,经利什曼鞭毛体纯抗原免疫及福氏佐剂加利什曼抗原免疫的两组小鼠,均以免疫后3周的吞噬率最高,分别为72％及96％;两组吞噬指数的均值±SD(4.46±1.72,6.99±4.36)亦较正常组小鼠(1.68±1.25,1.72±1.15)为高,并具有显著差异(P<0.05)。提示了特异性抗原以及与佐剂合并具有对吞噬功能的激活作用。实验并观察了巨噬细胞内利什曼原虫无鞭毛期的活力作用,从吞噬原虫后20小时开始至 144小时,正常小鼠巨噬细胞内的无鞭毛期再经三恩氏培养基培养后均能恢复为前鞭毛期,而经免疫小鼠巨噬细胞内的利什曼原虫无鞭毛期在72小时后即消失活力。 另外,对小鼠腹腔巨噬细胞吞噬利什曼原虫的动态亦作了仔细观察。 实验结果说明了经过免疫的小鼠,由于被淋巴细胞激活后的巨噬细胞能杀死利什曼原虫,巨噬细胞在宿主对感染应答中是一个重要部分,对于探索黑热病的免疫机理具有一     

Strain-specific recognition of live Leishmania donovani promastigotes by homologous antiserum raised against a crude membrane fraction of infected macrophages

Surface antigens on Leishmania promastigotes and infected macrophages are obvious targets in immunoprophylaxis for leishmanial infection. We have recently demonstrated that the polyclonal antiserum and monoclonal antibodies generated by homologous immunizations with the crude membranes of parasite-infected cells react effectively with the `neo-antigenic' determinants on the infected cell surface. In the present study, we investigated the utility of such polyclonal antisera for identifying `minor' surface components of promastigotes. The reactivity of anti-Leishmania donovani-(strain RMRI68) infected macrophage membrane (anti-IMm) antiserum was compared with that of anti-promastigote (anti-Pr) antiserum towards the infected macrophage surface and promastigotes of three Indian strains of L. donovani, RMRI68, AG83 and DD8. While anti-Pr antiserum showed no reactivity with the infected macrophage surface but reacted strongly with air dried and live promastigotes of all three strains, anti-IMm antiserum reacted with the infected cell surface and, interestingly, specifically recognized live promastigotes of the strain used for infection, i.e., strain RMRI68. The reactivity patterns of the two antisera with the immunodominant components of the L. donovani promastigote surface, i.e., purified LPG-KMP11 complex and gp63 molecules, indicated that unlike anti-Pr antiserum, the specificities in anti-IMm antiserum were mainly directed towards molecules other than the LPG-KMP11 complex and gp63. Antiserum generated in a similar fashion against the macrophage membrane of cells infected in vitro with strain AG83 also contained antibodies specific to strain AG83 promastigotes. The present approach may therefore greatly help in identifying specific antigen(s) important in clinical and epidemiological control of leishmaniasis. Received: 17 April 1998 / Accepted: 15 June 1998     

Glycosphingolipid antigens of Leishmania (Leishmania) amazonensis amastigotes identified by use of a monoclonal antibody.

Monoclonal antibodies directed against Leishmania (Leishmania) amazonensis amastigotes were produced. One monoclonal antibody (1C3) selected by indirect immunofluorescence reacted with both amastigotes and promastigotes of L. (L.) amazonensis. Glycolipid extraction from L. (L.) amazonensis amastigotes and separation by high-performance thin-layer chromatography followed by immunoblotting demonstrated that 1C3 reacts with two glycosphingolipids which migrate chromatographically similarly to ceramide-N-acetylneuraminic acid (GM1) and ceramide-N-tetrose-di-acetylneuraminic acid (GD1a). The antibody did not react with glycosphingolipids from L. (L.) amazonensis promastigotes. Immunoprecipitation of 125I- and 35S-methionine-labeled promastigotes demonstrated that 1C3 recognizes gp63 from L. (L.) amazonensis promastigotes. Biosynthetic incorporation of labeled lipids by L. (L.) amazonensis amastigotes indicated that the glycosphingolipids reactive with 1C3 contain oleic acid in their structures. Surface labeling with galactose oxidase and sodium boro[3H]hydride indicated that galactose is present in 1C3-reactive antigens, strongly suggesting that these glycosphingolipids are localized on the surface of L. (L.) amazonensis amastigotes. Inhibition experiments of macrophage infection implicated the 1C3-reactive glycosphingolipids from L. (L.) amazonensis amastigotes in Leishmania invasion. The role of gp63 in promastigote-macrophage attachment was also demonstrated by inhibition experiments performed with 1C3, consistent with data from the literature.     

Presentation of the Leishmania antigen LACK by infected macrophages is dependent upon the virulence of the phagocytosed parasites

We have previously demonstrated that murine macrophages (Mphi) infected with Leishmania promastigotes, in contrast to Mphi infected with the amastigote stage of these parasites, are able to present the Leishmania antigen LACK (Leishmania homologue of receptors for activated C kinase) to specific, I-Ad-restricted T cell hybrids and to the T cell clone 9.1-2. These T cells react with the LACK (158-173) peptide, which is immunodominant in BALB/c mice. Here, we show that the level of stimulation of the LACK-specific T cell hybridoma OD12 by promastigote-infected Mphi is clearly dependent upon the differentiation state of the internalized parasites. Thus, shortly after infection with log-phase or stationary-phase promastigotes of L. major or of L. amazonensis, Mphi strongly activated OD12. The activity was transient and rapidly lost. However, under the same conditions, activation of OD12 by Mphi infected with metacyclic promastigotes of L. major or of L. amazonensis was barely detectable. At the extreme, Mphi infected with amastigotes were incapable to stimulate OD12. Thus, the presentation of LACK by infected Mphi correlates with the degree of virulence of the phagocytosed parasites, the less virulent being the best for the generation/expression of LACK (158-173)-I-Ad complexes. While the intracellular killing of the parasites appears to be an important condition for the presentation of LACK, it is not the only requisite. The partial or total destruction of intracellular L. amazonensis amastigotes does not allow the presentation of LACK to OD12. A preferential interaction of LACK (158-173) with recycling rather than newly synthesized MHC class II molecules does not explain the transient presentation of LACK by Mphi infected with log-phase or stationary-phase promastigotes because brefeldin A strongly inhibited the presentation of LACK to OD12. Taken together, these results suggest that virulent stages of Leishmania, namely metacyclics and amastigotes, have evolved strategies to avoid or minimize their recognition by CD4+ T lymphocytes.     

Susceptibility of 3H-thymidine-prelabelled Leishmania donovani amastigotes and promastigotes to the cytotoxic activity of peritoneal, splenic and liver macrophages

C57BL/6 macrophage populations from spleen and liver, the main organs for the manifestation of visceral leishmaniasis, were investigated for their ability to perform spontaneous phagocytosis-associated killing of 3H-thymidine (3H-TdR)-prelabelled L. donovani amastigotes and promastigotes. The results showed that organ macrophages from spleen and liver killed L. donovani amastigotes and promastigotes spontaneously with high efficiency. This consistent finding was first detectable at 2-3 h, and the reaction was completed at 12 h. This type of killing was strongly enhanced when spleen and liver macrophages were activated. This phagocytosis-associated killing mechanism may contribute, to a large extent, in maintaining the infection under control in vivo, by drastically reducing the amount of parasites that is required to establish intracellular parasitism. To be able to assay phagocytosis-associated destruction of both promastigotes and amastigotes, a reproducible system for the production in vitro of Leishmania donovani amastigotes by the macrophage cell-line J774 was developed. The DNA of the Leishmania amastigotes was labelled with 3H-TdR with high efficiency. The spontaneous label release of prelabelled L. donovani amastigotes was comparable to that of prelabelled promastigotes over an assay period of 24 h.     

Enhanced replication of Leishmania amazonensis amastigotes in gamma interferon-stimulated murine macrophages: implications for the pathogenesis of cutaneous leishmaniasis

During Leishmania major infection in mice, gamma interferon (IFN-gamma) plays an essential role in controlling parasite growth and disease progression. In studies designed to ascertain the role of IFN-gamma in Leishmania amazonensis infection, we were surprised to find that IFN-gamma could promote L. amazonensis amastigote replication in macrophages (Mphis), although it activated Mphis to kill promastigotes. The replication-promoting effect of IFN-gamma on amastigotes was independent of the source and genetic background of Mphis, was apparently not affected by surface opsonization of amastigotes, was not mediated by interleukin-10 or transforming growth factor beta, and was observed at different temperatures. Consistent with the different fates of promastigotes and amastigotes in IFN-gamma-stimulated Mphis, L. amazonensis-specific Th1 transfer helped recipient mice control L. amazonensis infection established by promastigotes but not L. amazonensis infection established by amastigotes. On the other hand, IFN-gamma could stimulate Mphis to limit amastigote replication when it was coupled with lipopolysaccharides but not when it was coupled with tumor necrosis factor alpha. Thus, IFN-gamma may play a bidirectional role at the level of parasite-Mphi interactions; when it is optimally coupled with other factors, it has a protective effect against infection, and in the absence of such synergy it promotes amastigote growth. These results reveal a quite unexpected aspect of the L. amazonensis parasite and have important implications for understanding the pathogenesis of the disease and for developing vaccines and immunotherapies.     

Involvement of a Leishmania thymidine kinase in flagellum formation, promastigote shape and growth as well as virulence

Leishmania promastigote cells transmitted by their insect vector get phagocytosed by macrophages and convert into the amastigote form. In a recently performed proteomic study, a thymidine kinase (TK) was found to be preferentially expressed in amastigotes. Western blot analysis showing a marked increase in TK protein synthesis during stage differentiation from promastigotes to amastigotes confirmed this result. After comparison of the amino acid sequence of Leishmania donovani and Leishmania major thymidine kinases with thymidine kinases of other organisms the Leishmania protein has to be classified as a type II TK. Therefore, in accordance with the nomenclature of other thymidine kinases we named the Leishmania enzymes LdTK1 and LmTK1, respectively. The LdTK1 is localised within the cytoplasm of promastigotes. In amastigotes, increased expression and a clustered distribution of the protein can be observed. Lmtk1 single allele gene replacement mutants have significantly elongated flagellum. In contrast, lmtk1 double allele gene replacement mutants show a remarkably reduced flagellar length, diminished overall size and a deformed body shape. In addition, they have a 12-fold reduced growth rate. For both mutant strains, macrophage infectivity is clearly reduced compared to a L. major wildtype infection.     

Freeze-fracture and cytochemistry study of the interaction between Leishmania mexicana amazonensis and macrophages

The process of interaction between macrophages and promastigote and amastigote forms of Leishmania mexicana amazonensis was analyzed using freeze fracture and cytochemistry. The promastigotes inside endocytic vacuoles of macrophages presented an altered distribution of intramembranous particles and a wavy aspect of the plasma membrane. However, amastigotes did not show such alterations. The membrane alterations are probably caused by intracellular cell lysis of the promastigotes by the macrophages. An accumulation of intramembranous particles was seen in the plasma membrane of amastigote forms in the area of adhesion to the macrophages. The parasitophorous vacuole membrane had intramembranous particles randomly distributed. The enzyme activity of Mg++-ATPase, 5'-nucleotidase and NAD(P)H-oxidase was cytochemically detected, at the ultrastructural level, in normal mouse peritoneal macrophages and in macrophages infected with Leishmania mexicana amazonensis. Mg++-ATPase and 5'-nucleotidase are uniformly distributed throughout the macrophage's plasma membrane but were not detected in the membrane lining endocytic vacuoles containing ingested parasites (parasitophorous vacuole). NAD(P)H-oxidase activity was seen in those portions of the macrophage's plasma membrane which enter in direct contact with parasites and also in association with the membrane of the parasitophorous vacuole. The amount of reaction product, indicative of NAD(P)H-oxidase activity, was larger in macrophages which interacted with the promastigote than in those which interacted with the amastigote form of L. mexicana amazonensis. Concanavalin A binding sites and anionic sites of the macrophage's surface, labeled before the interaction, are not interiorized together with the parasites, however, are observed in endocytic vacuoles which do not contain parasites.     

Antigenic changes during intracellular differentiation of Leishmania mexicana in cultured macrophages.

Antigenic changes during the intracellular transformation of Leishmania mexicana subsp. amazonensis from promastigotes to amastigotes in macrophages of J774G8 line were noted mostly among protein bands of 24 to 68 kilodaltons in apparent molecular weight. In this region, six were identified as common antigens of both stages, six to seven were identified as promastigote specific, and three to five were identified as amastigote specific. At the higher-molecular-weight region (greater than 68 kilodalton) were two bands, one being predominant in amastigotes and the other in promastigotes. There may be a transformation-specific band (apparent molecular weight = 20 kilodaltons). The transition of these stage-specific antigens varies considerably with different protein species and may play important roles in intracellular leishmanial differentiation.     

Interaction of Leishmania donovani promastigotes with human monocyte-derived macrophages: parasite entry, intracellular survival, and multiplication.

Leishmania donovani promastigotes were incubated with human monocyte-derived macrophages in vitro to assess the role of macrophages in the early stage of visceral leishmaniasis. Adherent mononuclear cells, obtained from nonimmune human donors, were cultivated on glass cover slips for 5 days and then incubated with axenically grown promastigotes in the presence of heat-inactivated autologous serum. Promastigotes attached to macrophages with either their flagellar or aflagellar ends, and macrophage pseudopodia formed around them. Intracellular parasites were identified within phagocytic vacuoles by electron microscopy, and the parasites assumed a form similar to that of amastigotes obtained from infected hamster spleens. Initially, 67 +/- 5% of the macrophages were infected with a mean of 4.2 +/- 0.7 parasites per infected cell. After 6 days of incubation, 79 +/- 7% of the macrophages were infected with 15.9 +/- 3.2 parasites per infected cell. The total number of parasites per monolayer increased from 4.8 +/- 0.8 x 10(5) to 1.8 +/- 0.4 x 10(6) (P less than 0.05). Dividing parasites were identified in macrophage vacuoles by electron microscopy. Human monocyte-derived macrophage vacuoles by electron microscopy. Human monocyte-derived macrophages can phagocytize promastigotes, allow the conversion of promastigotes to an amastigote-like state, and support intracellular multiplication.     

Fast high yield of pure Leishmania (Leishmania) infantum axenic amastigotes and their infectivity to mouse macrophages

Leishmania (L.) infantum (syn. Leishmania chagasi) is a dimorphic protozoan parasite that lives in promastigote and amastigote form in its sandfly vector and mammalian hosts, respectively. Here, we describe an in vitro culture system for the generation of a pure population of L. infantum axenic amastigotes after only 4 days incubation in culture medium supplemented with fetal calf serum, human urine, l-glutamine, and HEPES at 37oC (pH 5.5). Ultrastrutural analysis and infection assays in two macrophage populations (Kupffer cells (KUP) and peritoneal macrophages (PM)) infected with axenic amastigotes demonstrated that they maintained morphological and biochemical (A2 expression) features and a similar infection pattern to tissue-derived L. infantum amastigotes. The susceptibility of the macrophage lines to axenic or tissue-derived amastigotes and promastigotes was investigated. We found a completely different susceptibility profile for KUP and PM. Liver macrophages, both KUP and immigrant macrophages, are intimately involved in the response to L. infantum infection; this difference in susceptibility is probably related to their capacity to eliminate these parasites. Our in vitro system was thus able to generate axenic amastigotes that resemble tissue-derived amastigotes both in morphology and infectivity pattern; this will help in further investigation of the biological characteristics of the host–parasite relationship as well as the process of pathogenesis.