Characterization of the A2-A2rel gene cluster in Leishmania donovani: involvement of A2 in visceralization during infection

The A2 gene family is present in Leishmania donovani, which causes fatal visceral leishmaniasis in human patients, but is not present in Leishmania major, which causes cutaneous leishmaniasis infections. The A2 genes in L. donovani are stage specific and are expressed at high levels in the amastigote stage in the mammalian host, but are not expressed in the promastigote stage in the insect sandfly vector. The A2 genes are tandem repeated with a distinct gene family termed the A2rel genes. In order to characterize the structure and function of the A2-A2rel gene clusters, the 5' and 3' DNA sequences flanking the A2-A2rel cluster were isolated, sequenced and used to generate mutants through gene targeting. Although it was possible to generate partial A2-A2rel gene clusters knock-out mutants, it was not possible to delete all the A2-A2rel gene clusters completely from the L. donovani genome, suggesting that, within this cluster, there are genes that are essential for survival in culture. Characterization of these mutants revealed that A2 and A2rel gene expression was compensated by amplifying the remaining intact A2 and A2rel genes, and the proliferation of these mutants in culture and their virulence in BALB/c mice were compromised. In order to explore further the biological role of A2, the L. donovani A2 gene was introduced into L. major. In comparison with the control L. major, the A2-expressing L. major parasites demonstrated an increased ability to survive in the spleen of BALB/c mice. These data suggest that A2 plays a role in the visceralization of infection associated with L. donovani.     

The sterol-binding antibiotic nystatin inhibits entry of non-opsonized Leishmania donovani into macrophages

Leishmania donovani is an obligate intracellular parasite that infects macrophages of the vertebrate host resulting in visceral leishmaniasis in humans, a major public health problem worldwide. The molecular mechanisms involved in internalization of Leishmania are still poorly characterized. We report here that cholesterol sequestration by the sterol-binding antifungal polyene antibiotic nystatin markedly inhibits binding and entry of non-opsonized L. donovani promastigotes into macrophages. Interestingly, these effects are not observed when serum-opsonized L. donovani are used for infectivity studies thus pointing the essential role of cholesterol in mediating entry of the parasite via the non-opsonic pathway. Based on our earlier results where leishmanial infectivity was shown to be sensitive to physical depletion of cholesterol from macrophages, these results indicate that the mere sequestration of cholesterol in the host plasma membrane is sufficient to inhibit the binding and entry of non-opsonized L. donovani. These results represent the first report on the effect of a cholesterol-sequestering agent on the entry of Leishmania parasites to host macrophages. More importantly, these findings offer the possibility of reevaluating the mechanism behind the effectiveness of current therapeutic strategies to treat leishmaniasis.     

Viscerotropic growth pattern of Leishmania tropica in BALB/c mice is suggestive of a murine model for human viscerotropic leishmaniasis

Leishmania (L.) tropica is a causative agent of cutaneous leishmaniasis, and occasionally of visceral or viscerotropic leishmaniasis in humans. Murine models of Leishmania infection have been proven to be useful for elucidation of mechanisms for pathogenesis and immunity in leishmaniasis. The aim of this study was to establish a murine model for human viscerotropic leishmaniasis, and the growth pattern of L. tropica was studied in different tissues of BALB/c mice in order to find out whether the parasite visceralizes in this murine model. L. major was used as a control as this species is known to cause a progressive infection in BALB/c mice. L. tropica or L. major was injected into the footpad of mice, and thickness of footpad, parasite loads in different tissues, and the weight of the spleen and lymph node were determined at different intervals. Results showed that L. tropica visceralizes to the spleen and grows there while its growth is controlled in footpad tissues. Dissemination of L. tropica to visceral organs in BALB/c mice was similar to the growth patterns of this parasite in human viscerotropic leishmaniasis. The BALB/c model of L. tropica infection may be considered as a good experimental model for human diseases.     

A proteogenomic approach to map the proteome of an unsequenced pathogen - Leishmania donovani

Visceral leishmaniasis or kala azar is the most severe form of leishmaniasis and is caused by the protozoan parasite Leishmania donovani. There is no published report on L. donovani genome sequence available till date, although the genome sequences of three related Leishmania species are already available. Thus, we took a proteogenomic approach to identify proteins from two different life stages of L. donovani. From our analysis of the promastigote (insect) and amastigote (human) stages of L. donovani, we identified a total of 22,322 unique peptides from a homology-based search against proteins from three Leishmania species. These peptides were assigned to 3711 proteins in L. infantum, 3287 proteins in L. major, and 2433 proteins in L. braziliensis. Of the 3711 L. donovani proteins that were identified, the expression of 1387 proteins was detectable in both life stages of the parasite, while 901 and 1423 proteins were identified only in promastigotes and amastigotes life stages, respectively. In addition, we also identified 13 N-terminally and one C-terminally extended proteins based on the proteomic data search against the six-frame translated genome of the three related Leishmania species. Here, we report results from proteomic profiling of L. donovani, an organism with an unsequenced genome.     

Human mixed infections of Leishmania spp. and Leishmania-Trypanosoma cruzi in a sub Andean Bolivian area: identification by polymerase chain reaction/hybridization and isoenzyme

Parasites belonging to Leishmania braziliensis, Leishmania donovani, Leishmania mexicana complexes and Trypanosoma cruzi (clones 20 and 39) were searched in blood, lesions and strains collected from 28 patients with active cutaneous leishmaniasis and one patient with visceral leishmaniasis. PCR-hybridization with specific probes of Leishmania complexes (L. braziliensis, L. donovani and L. mexicana) and T. cruzi clones was applied to the different DNA samples. Over 29 patients, 8 (27.6%) presented a mixed infection Leishmania complex species, 17 (58.6%) a mixed infection Leishmania-T. cruzi, and 4 (13.8%) a multi Leishmania-T. cruzi infection. Several patients were infected by the two Bolivian major clones 20 and 39 of T. cruzi (44.8%). The L. braziliensis complex was more frequently detected in lesions than in blood and a reverse result was observed for L. mexicana complex. The polymerase chain reaction-hybridization design offers new arguments supporting the idea of an underestimated rate of visceral leishmanisis in Bolivia. Parasites were isolated by culture from the blood of two patients and lesions of 10 patients. The UPGMA (unweighted pair-group method with arithmetic averages) dendrogram computed from Jaccard's distances obtained from 11 isoenzyme loci data confirmed the presence of the three Leishmania complexes and undoubtedly identified human infections by L. (V.) braziliensis, L. (L.) chagasi and L. (L.) mexicana species. Additional evidence of parasite mixtures was visualized through mixed isoenzyme profiles, L. (V.) braziliensis-L. (L.) mexicana and Leishmania spp.-T. cruzi.The epidemiological profile in the studied area appeared more complex than currently known. This is the first report of parasitological evidence of Bolivian patients with trypanosomatidae multi infections and consequences on the diseases' control and patient treatments are discussed.     

Paromomycin affects translation and vesicle-mediated trafficking as revealed by proteomics of paromomycin -susceptible -resistant Leishmania donovani

Leishmania donovani is a protozoan parasite that causes visceral leishmaniasis (VL) and is responsible for significant mortality and morbidity. Increasing resistance towards antimonial drugs poses a great challenge in chemotherapy of VL. Paromomycin is an aminoglycosidic antibiotic and is one of the drugs currently being used in the chemotherapy of cutaneous and visceral leishmaniasis. To understand the mode of action of this antibiotic at the molecular level, we have investigated the global proteome differences between the wild type AG83 strain and a paromomycin resistant (PRr) strain of L. donovani. Stable isotope labeling of amino acids in cell culture (SILAC) followed by quantitative mass spectrometry of the wild type AG83 strain and the paromomycin resistant (PRr) strain identified a total of 226 proteins at ≥ 95% confidence. Data analysis revealed upregulation of 29 proteins and down-regulation of 21 proteins in the PRr strain. Comparative proteomic analysis of the wild type and the paromomycin resistant strains showed upregulation of the ribosomal proteins in the resistant strain indicating role in translation. Elevated levels of glycolytic enzymes and stress proteins were also observed in the PRr strain. Most importantly, we observed upregulation of proteins that may have a role in intracellular survival and vesicular trafficking in the PRr strain. Furthermore, ultra-structural analysis by electron microscopy demonstrated increased number of vesicular vacuoles in PRr strain when compared to the wild-type strain. Drug affinity pull-down assay followed by mass spectrometery identified proteins in L. donovani wild type strain that were specifically and covalently bound to paromomycin. These results provide the first comprehensive insight into the mode of action and underlying mechanism of resistance to paromomycin in Leishmania donovani.     

Schizodeme and zymodeme characterization of Leishmania in the investigation of foci of visceral and cutaneous leishmaniasis

Leishmania parasites were isolated from humans and canines in foci of cutaneous and visceral leishmaniasis. After in vitro cultivation the parasites were examined by the following biochemical techniques: (i) restriction analysis of kinetoplast DNA (kDNA) also known as schizodeme analysis (Morel et al., 1980); (ii) zymodeme analysis (Barret et al., 1980); by agarose gel electrophoresis and (iii) isoelectricfocusing in polyacrylamide gels. The strains of cutaneous and visceralizing leishmanias studied could be differentiated by schizodeme analysis, using the endonuclease MspI, into three complexes agreeing with those accepted for human New World leishmaniasis. In the municipality of Rio de Janeiro, isolates from a focus of cutaneous leishmaniasis were identified as L. braziliensis braziliensis and from a focus of visceral leishmaniasis were identified as L. donovani by zymodeme characterization. Identical restriction enzyme profiles of kDNA from human and canine isolates indicated that in the cutaneous focus at Jacarepaguá, Rio de Janeiro, the same strain was probably circulating in both the canine and human populations. This suggests a possible role for dogs as a reservoir host for L. braziliensis braziliensis. In addition, our results confirm the importance of dogs as reservoirs in visceral leishmaniasis. The stability of the electrophoretic patterns of restriction digest ("fingerprints") of Leishmania kDNA as well as differences in the sensitivity of the techniques used were demonstrated. Strains from widely different geographical areas as well as strains maintained in vivo and in vitro showed identical kDNA restriction patterns, while strains showing similar banding patterns by enzyme electrophoresis could be differentiated by schizodeme analysis. These results demonstrate the usefulness of an integrated biochemical approach in the identification of Leishmania.     

The dendritic cell receptor DC-SIGN discriminates among species and life cycle forms of Leishmania

Infection of dendritic cells by the human protozoal parasite Leishmania is part of its survival strategy. The dendritic cell receptors for Leishmania have not been established and might differ in their interactions among Leishmania species and infective stages. We present evidence that the surface C-type lectin DC-SIGN (CD 209) is a receptor for promastigote and amastigote infective stages from both visceral (Leishmania infantum) and New World cutaneous (Leishmania pifanoi) Leishmania species, but not for Leishmania major metacyclic promastigotes, an Old World species causing cutaneous leishmaniasis. Leishmania binding to DC-SIGN was found to be independent of lipophosphoglycan, the major glycoconjugate of the promastigote plasma membrane. Our findings emphasize the relevance of DC-SIGN in Leishmania-dendritic cell interactions, an essential link between innate and Leishmania-specific adaptive immune responses, and suggest that DC-SIGN might be a therapeutic target for both visceral and cutaneous leishmaniasis     

Involvement of the Leishmania donovani virulence factor A2 in protection against heat and oxidative stress

Leishmania is an obligate intracellular protozoan parasite that infects cells of the reticulo-endothelial system. Host defences against Leishmania include fever and oxidant production, and the parasite has developed a number of defence mechanisms to neutralize the host response. The Leishmania donovani A2 family of proteins has been shown to be essential for survival in mammalian visceral organs. Here we provide evidence that A2 proteins protect the parasite against host defences, namely heat stress (fever) and oxidative stress. A2 is however unable to protect the cells from endoplasmic reticulum stress induced by dithiothreitol. To downregulate A2 protein expression, L. donovani was transfected with an A2 antisense RNA expressing-vector, resulting in significant reduction of A2 levels. The resulting A2-deficient cells were more sensitive to heat shock and this was associated with increased production of internal oxidants during heat shock. Moreover, axenic amastigotes with downregulated A2 expression had increased internal oxidants and decreased viability following treatment with hydrogen peroxide or a nitric oxide donor when compared to control cells. Overall, these results suggest that A2 protects L. donovani from a variety of stresses, thereby allowing it to survive in the internal organs of the mammalian host and to cause visceral disease.     

Killing of Leishmania tropica amastigotes by factors in normal human serum

Amastigotes of Leishmania tropica and L. donovani were incubated with fresh or heat-inactivated normal human serum. Viability was estimated by amastigote conversion to promastigote forms and by the ability of serum-treated amastigotes to infect human monocytes. L. tropica, a parasite that causes local skin infection, was killed by fresh but not by heat-inactivated serum. The serum cytotoxic effect on L. tropica was inhibited by EDTA but not by Mg-EGTA. C2-deficient serum killed normally; C6-deficient serum was ineffective. These data indicate that L. tropica is killed by the complement membrane attack complex, in a sequence of reactions initiated by components of the alternate pathway. In contrast, L. donovani, a parasite that causes systemic visceral leishmaniasis, was 10-fold less susceptible to the cytotoxic effects of normal serum. Thus, a profound difference exists in the susceptibility of amastigotes of two species of Leishmania to a defense mechanism present in human serum. Serum complement factors may play an important role in limiting L. tropica to the skin. The resistance of L. donovani to such factors may be the primary reason for its ability to escape from the site of inoculation and cause catastrophic, disseminated disease.     

Leishmania donovani: development and characterisation of a kinetoplast DNA probe and its use in the detection of parasites

The polymerase chain reaction is used increasingly widely for the diagnosis of both cutaneous and visceral leishmaniasis and for the identification of asymptomatic carriers in the population in endemic disease areas. The use of complex-specific hybridisation probes in conjunction with the polymerase chain reaction increases the specificity as well as the sensitivity of the diagnostic procedure as it discriminates between different infecting Leishmania species. A minicircle kinetoplast DNA probe, B4 Rsa, which hybridizes to all members of the Leishmania (L.) donovani complex has been identified and characterised. It is a segment of a minicircle highly conserved in Bangladeshi and Indian L. (L.) donovani isolates.     

Multifaceted population structure and reproductive strategy in Leishmania donovani complex in one Sudanese village

Leishmania species of the subgenus Leishmania and especially L. donovani are responsible for a large proportion of visceral leishmaniasis cases. The debate on the mode of reproduction and population structure of Leishmania parasites remains opened. It has been suggested that Leishmania parasites could alternate different modes of reproduction, more particularly clonality and frequent recombinations either between related individuals (endogamy) or between unrelated individuals (outcrossing) within strongly isolated subpopulations. To determine whether this assumption is generalized to other species, a population genetics analysis within Leishmania donovani complex strains was conducted within a single village. The results suggest that a mixed-mating reproduction system exists, an important heterogeneity of subsamples and the coexistence of several genetic entities in Sudanese L. donovani. Indeed, results showed significant genetic differentiation between the three taxa (L. donovani, L. infantum and L. archibaldi) and between the human or canine strains of such taxa, suggesting that there may be different imbricated transmission cycles involving either dogs or humans. Results also are in agreement with an almost strict specificity of L. donovani stricto sensu to human hosts. This empirical study demonstrates the complexity of population structure in the genus Leishmania and the need to pursue such kind of analyses at the smallest possible spatio-temporal and ecological scales.     

Mechanisms of acquired immunity in leishmaniasis

Self-curing cutaneous leishmaniasis depends on T cell-mediated immune activation of infected macrophages. Failure of immune control in inbred mouse models of metastasizing mucocutaneous and visceralizing forms of the disease involves, respectively, insusceptibility of the parasite and the generation of T cells that suppress a potentially curative response. Prophylactic immunization in man has so far been restricted to cutaneous leishmaniasis and based on inducing infection under controlled conditions with virulent Leishmania tropica major promastigotes. The feasibility of immunization against visceral leishmaniasis merits reconsideration. BALB/c mice are genetically vulnerable to L. tropica major, which produces a fatal visceralizing type of disease involving specific suppression of cell-mediated immunity. Potent and lasting protection can be induced by repeated intravenous immunization with irradiated promastigotes. The efficacy of this 'vaccine' is relatively heat-stable (1 h at 56 degrees C). Immunity is not attributable to antibody but to the generation of Lyt-1+2- T cells which, although possessing helper and macrophage-activating functions, do not express classical delayed-type hypersensitivity. The immunological features of this system and its relevance to the possibility of protection against human Leishmania donovani infection are considered.     

Comparative in vivo expression of amastigote up regulated Leishmania genes in three different forms of Leishmaniasis

In Old World Leishmania infections in India, Leishmania donovani is responsible for visceral leishmaniasis (VL) and post kala-azar dermal leishmaniasis (PKDL) while L. tropica is responsible for cutaneous leishmaniasis (CL) in humans. The molecular differences between the two species of Leishmania and within the same species causing distinct pathologies that govern the outcome of infection and pathogenesis in the human host are unknown. Quantitative expression of selected genes was evaluated directly in lesion tissues of VL, PKDL and CL patients. Assessment of in vivo mRNA level highlighted substantial differences in gene expression patterns, providing an indication of the genes involved in pathogenesis in the three different forms of Leishmaniasis.     

Identification and characterisation of a Leishmania donovani antigen belonging to the 70-kDa heat-shock protein family

A Leishmania donovani promastigote cDNA library was screened with serum obtained from a patient infected with visceral leishmaniasis. Sequence analysis of a clone obtained from this library revealed that the 600-bp insert corresponded to the carboxy-terminal region of an antigen related to the 70-kDa heat-shock protein family. The full-length sequence of the corresponding gene (1959 nucleotides) was determined after isolation of genomic clones. Genes encoding the antigen are present on a single chromosome as a series of approximately twelve 3.7-kb direct tandem repeats. The antigen can be identified as a 70-kDa heat-shock cognate protein by virtue of its molecular mass, sequence and constitutive expression during heat shock. It is expressed at all stages of the parasite life-cycle. Antibodies against the lambda gt11 fusion protein were detected in more than 50% of serum samples obtained from patients with visceral leishmaniasis, but were not detected in sera from patients with cutaneous leishmaniasis or Chagas' disease.     

Glyoxalase I from Leishmania donovani: a potential target for anti-parasite drug

Glyoxalases are involved in a ubiquitous detoxification pathway. In pursuit of a better understanding of the biological function of the enzyme, the recombinant glyoxalase I (LdGLOI) protein has been characterized from Leishmania donovani, the most important pathogenic Leishmania species that is responsible for visceral leishmaniasis. A 24kDa protein was heterologously expressed in Escherichia coli. LdGLOI showed a marked substrate specificity for trypanothione hemithioacetal over glutathione hemithioacetal. Antiserum against recombinant LdGLOI protein could detect a band of anticipated size approximately 16kDa in promastigote extracts. Several inhibitors of human GLOI showed that they are weak inhibitors of L. donovani growth. Overexpression of GLOI gene in L. donovani using Leishmania expression vector pspalpha hygroalpha, we detected elevated expression of GLOI RNA and protein. Comparative modelling of the 3-D structure of LDGLOI shows that substrate-binding region of the model involves important differences compared to the homologues, such as E. coli, specific to glutathione. Most notably a substrate-binding loop of LDGLOI is characterized by a deletion of five residues compared to the E. coli homologue. Further, a critical Arg in the E. coli variant at the substrate-binding site is replaced by Tyr in LDGLOI. These major differences result in entirely different shapes of the substrate-binding loop and presence of very different chemical groups in the substrate-binding site of LDGLOI compared to E. coli homologue suggesting an explanation for the difference in the substrate specificity. Difference in the substrate specificity of the human and LDGLOI enzyme could be exploited for structure-based drug designing of selective inhibitors against the parasite.     

Species and stage specificity of Leishmania donovani antigens.

Monoclonal antibodies D2 and D13 were produced in mice using Leishmania donovani promastigote membrane fractions. To study the species and stage specificity of the antigens recognized by these antibodies, we examined amastigotes prepared in vitro and cultured promastigotes by indirect immunofluorescence with monoclonal antibodies D2 and D13. Monoclonal antibody D2 showed weak reactivity for 9 of 9 strains of L. donovani complex promastigotes and 8 of 9 amastigotes. In contrast, only 2 of 22 strains from other complexes yielded equivocal reactions. Monoclonal antibody D13, however, had much broader reactivity. D13 reacted with all the promastigotes and amastigotes of L. donovani complex isolates as well as with 10 of 22 promastigotes and 8 of 13 amastigotes from other complexes. The high degree of species specificity seen with monoclonal antibody D2 provides a rationale for further study of this antibody and its purified antigen for parasite identification and serodiagnosis of visceral leishmaniasis. The strong fluorescent signal noted with D13 and the presence of the D13 epitope on all L. donovani complex parasites supports studies on its role as an antigen in immunoprophylaxis of visceral leishmaniasis.