Viability of sandflies (Diptera, Psychodidae, Phlebotominae) under the influence of infection with promastigotes of various species of Leishmania]

Sand flies were infected with different species of promastigotes from reptiles and warm-blooded animals. Optimal doses of promastigotes were used which ensured the adaptation of Protozoa in the host's intestine. The infection with a mixed culture resulted in the death of most Sand flies: the mortality rate was the highest at the simultaneous introduction of two species and was some what lower at the subsequent infection. The survival of Sand flies infected with one species of leishmania decreased to the greatest extent if "incidental" for them strains of promastigotes were introduced: for Ph. papatasi -- cultures isolated from reptiles, for Sergentomyia arpaklensis -- those isolated from L. tropica major. Natural infection rate of the genera Phlebotomus and Sergentomyia with leishmania of different species agrees with laboratory data on the survival of sand flies. Ph. caucasicus and Ph. papatasi are infected, in general, with L. tropica major, S. arpaklensis -- with L. gymnodactyli.     

The ultrastructure of the parasitophorous vacuole formed by Leishmania major

Protozoan parasites of Leishmania spp. invade macrophages as promastigotes and differentiate into replicative amastigotes within parasitophorous vacuoles. Infection of inbred strains of mice with Leishmania major is a well-studied model of the mammalian immune response to Leishmania species, but the ultrastructure and biochemical properties of the parasitophorous vacuole occupied by this parasite have been best characterized for other species of Leishmania. We examined the parasitophorous vacuole occupied by L. major in lymph nodes of infected mice and in bone marrow-derived macrophages infected in vitro. At all time points after infection, single L. major amastigotes were wrapped tightly by host membrane, suggesting that amastigotes segregate into separate vacuoles during replication. This small, individual vacuole contrasts sharply with the large, communal vacuoles occupied by Leishmania amazonensis. An extensive survey of the literature revealed that the single vacuoles occupied by L. major are characteristic of those formed by Old World species of Leishmania, while New World species of Leishmania form large vacuoles occupied by many amastigotes.     

Leishmania major: analysis of lymphocyte and macrophage cellular phenotypes during infection of susceptible and resistant mice

Genetically susceptible BALB/c and resistant C57BL/6 mice were infected with Leishmania major and the phenotypes of the responding cells in the draining lymph nodes and cutaneous lesions were analyzed. As early as 1 week, significantly increased numbers of L3T4+ cells as compared to Lyt-2+ cells were present in BALB/c mice lymph nodes (P less than 0.005). Increases in L3T4+ and Lyt-2+ cells were comparable in C57BL/6 mice, resulting in threefold lower L3T4/Lyt-2 ratio than in BALB/c mice. T cell subsets were activated in both strains to express interleukin-2 receptor (IL2R) above resting values, although greater numbers of activated L3T4+ cells were present in the draining lymph nodes from BALB/c at 1 and 3 weeks of infection than in C57BL/6 (P = 0.02). Despite the presence of activated L3T4+ cells in both strains, macrophages differed in the expression of immunologically important surface molecules during infection. Tissue macrophages from BALB/c mice were IgG1/G2b Fc receptor (FcR)+ and Ia- late in disease, whereas macrophages in C57BL/6 became FcR and Ia during healing. BALB/c mice, treated with monoclonal antibody GK1.5 to transiently deplete L3T4+ cells, became resistant to subsequent infection and developed a macrophage phenotype that was FcR- and Ia+. These differences in macrophage phenotype were closely linked to susceptibility during infection with L. major and may play a role in the pathophysiology of murine leishmaniasis.     

Heme oxygenase-1 promotes the persistence of Leishmania chagasi infection

Visceral leishmaniasis (VL) remains a major public health problem worldwide. This disease is highly associated with chronic inflammation and a lack of the cellular immune responses against Leishmania. It is important to identify major factors driving the successful establishment of the Leishmania infection to develop better tools for the disease control. Heme oxygenase-1 (HO-1) is a key enzyme triggered by cellular stress, and its role in VL has not been investigated. In this study, we evaluated the role of HO-1 in the infection by Leishmania infantum chagasi, the causative agent of VL cases in Brazil. We found that L. chagasi infection or lipophosphoglycan isolated from promastigotes triggered HO-1 production by murine macrophages. Interestingly, cobalt protoporphyrin IX, an HO-1 inductor, increased the parasite burden in both mouse and human-derived macrophages. Upon L. chagasi infection, macrophages from Hmox1 knockout mice presented significantly lower parasite loads when compared with those from wild-type mice. Furthermore, upregulation of HO-1 by cobalt protoporphyrin IX diminished the production of TNF-α and reactive oxygen species by infected murine macrophages and increased Cu/Zn superoxide dismutase expression in human monocytes. Finally, patients with VL presented higher systemic concentrations of HO-1 than healthy individuals, and this increase of HO-1 was reduced after antileishmanial treatment, suggesting that HO-1 is associated with disease susceptibility. Our data argue that HO-1 has a critical role in the L. chagasi infection and is strongly associated with the inflammatory imbalance during VL. Manipulation of HO-1 pathways during VL could serve as an adjunctive therapeutic approach.     

Macrophage interactions with neutrophils regulate Leishmania major infection

Macrophages are host cells for the pathogenic parasite Leishmania major. Neutrophils die and are ingested by macrophages in the tissues. We investigated the role of macrophage interactions with inflammatory neutrophils in control of L. major infection. Coculture of dead exudate neutrophils exacerbated parasite growth in infected macrophages from susceptible BALB, but killed intracellular L. major in resistant B6 mice. Coinjection of dead neutrophils amplified L. major replication in vivo in BALB, but prevented parasite growth in B6 mice. Neutrophil depletion reduced parasite load in infected BALB, but exacerbated infection in B6 mice. Exacerbated growth of L. major required PGE(2) and TGF-beta production by macrophages, while parasite killing depended on neutrophil elastase and TNF-alpha production. These results indicate that macrophage interactions with dead neutrophils play a previously unrecognized role in host responses to L. major infection.     

Low and high-dose intradermal infection with Leishmania major and Leishmania amazonensis in C57BL/6 mice

A model of skin infection with Leishmania amazonensis with low doses of parasites is compared to infection with high doses of L. amazonensis and low and high doses of Leishmania major. C57BL/6 mice were infected with 103 or 10(6) parasites in the ear and the outcome of infection was assessed. The appearance of lesions in mice infected with 103 parasites was delayed compared to mice infected with 10(6) Leishmania and parasites were detectable at the infection site before lesions became apparent. Mice infected with L. amazonensis displayed persistent lesions, whereas infection with L. major spontaneously healed in all groups, although lymphocytes persisted at the site of infection after healing. Macrophages persisted only in L. amazonensis-infected mice. High-dose L. amazonensis-infected mice produced lower levels of IFN-γ and TNF than mice infected with L. major. No correlation between the persistence of parasites and IL-10 levels and the production of nitric oxide or urea by macrophages was found. We conclude that infection with low doses of L. amazonensis in the dermis changes the course of infection by delaying the appearance of lesions. However, low-dose infection does not change the outcomes of susceptibility and cytokine production described for subcutaneous infection with high numbers of parasites.     

Infection-induced respiratory burst in BALB/c macrophages kills Leishmania guyanensis amastigotes through apoptosis: possible involvement in resistance to cutaneous leishmaniasis

The immune mechanisms that underlie resistance and susceptibility to leishmaniasis are not completely understood for all species of Leishmania. It is becoming clear that the immune response, the parasite elimination by the host and, as a result, the outcome of the disease depend both on the host and on the species of the infecting Leishmania. Here, we analyzed the outcome of the infection of BALB/c mice with L. guyanensis in vivo and in vitro. We showed that BALB/c mice, which are a prototype of susceptible host for most species of Leishmania, dying from these infections, develop insignificant or no cutaneous lesions and eliminate the parasite when infected with promastigotes of L. guyanensis. In vitro, we found that thioglycollate-elicited BALB/c peritoneal macrophages, which are unable to eliminate L. amazonensis without previous activation with cytokines or lipopolysaccharide, can kill L. guyanensis amastigotes. This is the first report showing that infection of peritoneal macrophages with stationary phase promastigotes efficiently triggers innate microbicidal mechanisms that are effective in eliminating the amastigotes, without exogenous activation. We demonstrated that L. guyanensis amastigotes die inside the macrophages through an apoptotic process that is independent of nitric oxide and is mediated by reactive oxygen intermediates generated in the host cell during infection. This innate killing mechanism of macrophages may account for the resistance of BALB/c mice to infection by L. guyanensis.     

Accumulation of macrophages expressing MRP8 and MRP14 in skin lesions during Leishmania major infection in BALB/c and RAG-2 knockout mice

Migration inhibitory factor-related protein 8 (MRP8) and MRP14 are expressed by myeloid cells and especially known as marker proteins of an immature and inflammatory subtype of macrophages. In this study, we immunohistochemically examined an accumulation of MRP8+ and MRP14+ macrophages in skin lesions during Leishmania major infection in susceptible BALB/c and RAG-2-/- mice. L. major infection caused the development of a nodular type of skin lesion at the infection site in mice and a massive accumulation of macrophages was observed in the lesions at four weeks after the infection. Immunohistochemical analyses showed MRP8+ and MRP14+ macrophages are predominant cell types in the skin lesions in both mouse strains. In contrast, F4/80+ cells, which correspond to mature macrophages, were rarely found in the skin lesions. These data suggest that the accumulation of inflammatory subtype of macrophages in BALB/c mice during L. major infection can be induced without acquired immune responses.     

Differential properties of CBA/J mononuclear phagocytes recovered from an inflammatory site and probed with two different species of Leishmania

While CBA/J mice fail to be permissive to Leishmania amazonensis-driven pathogenic processes, they heal easily following Leishmania major infection. The early-phase events are crucial to the outcome of Leishmania infection and it is known that macrophages (Mphi) are important in infection control. In the present study we investigated the role of Mphi in driving CBA/J susceptibility to L. amazonensis. We performed kinetic studies and compared the capacity of L. amazonensis and L. major to infect Mphi. There was no difference in percentages of infection or parasite burden for 6 h between the two groups. In contrast, after 12 h we observed that infection was about twice as high in L. amazonensis- than in L. major-infected Mphi. In addition, rIFN-gamma added to the cultures induced nitric oxide (NO) production, and did not modify L. amazonensis infection, although the percentage of L. major infection was significantly reduced. This reduction in L. major infection is a TNF-alpha dependent mechanism as L. major-infected Mphi expressed twice as much TNF-alpha mRNA as L. amazonensis-infected cells, and anti-TNF-alpha reversed the IFN-gamma effect. Moreover, rTNF-alpha plus IFN-gamma were able to significantly reduce the percentage of L. amazonensis-infected cells but not to the same extent as in L. major infection. Despite having higher NO production than IFN-gamma-treated cells, AMG addition to IFN-gamma-plus TNF-alpha-treated cells only partially reversed the inhibition in L. major, but not in L. amazonensis infection. Thus, in this study, we demonstrated that L. amazonensis both inactivated and resisted innate and IFN-gamma-induced Mphi killing mechanisms, indicating that the nature of the parasite and its interaction with Mphi could determine immune response polarization.     

Leishmania promotes its own virulence by inducing expression of the host immune inhibitory ligand CD200

Leishmania parasites infect macrophages, cells normally involved in innate defense against pathogens. Leishmania amazonensis and Leishmania major cause severe or mild disease, respectively, consistent with each parasite's ability to survive within activated macrophages. The mechanisms underlying increased virulence of L.?amazonensis are mostly unknown. We show that L.?amazonensis promotes its own survival by inducing expression of CD200, an immunoregulatory molecule that inhibits macrophage activation. L.?amazonensis does not form typical nonhealing lesions in CD200(-/-) mice and cannot replicate in CD200(-/-) macrophages, an effect reversed by exogenous administration of soluble CD200-Fc. The less virulent L.?major does not induce CD200 expression and forms small, self-healing lesions in both wild-type and CD200(-/-) mice. Notably, CD200-Fc injection transforms the course of L.?major infection to one resembling L.?amazonensis, with large, nonhealing lesions. CD200-dependent iNOS inhibition allows parasite growth in macrophages, identifying a mechanism for the increased virulence of L.?amazonensis.     

Exacerbation of murine cutaneous leishmaniasis by adoptive transfer of parasite-specific helper T cell populations capable of mediating Leishmania major-specific delayed-type hypersensitivity

The effect of adoptive transfer of in vitro-propagated Leishmania major-specific T cell populations on the course of experimentally induced cutaneous leishmaniasis was studied in mice. The L. major-specific T cells expressed the T helper/inducer phenotype and were able in vitro to a) mount a specific proliferative response, b) provide specific helper activity for antibody responses, c) activate parasitized macrophages resulting in L. major destruction, and d) secrete macrophage-activating factors as tested in a tumoricidal assay. These T cells were also found capable of transferring parasite-specific delayed-type hypersensitivity responses to normal syngeneic mice. Results indicated that the i.v. transfer of these L. major-specific T cell populations into normal syngeneic mice exacerbated cutaneous lesions induced by infection with L. major. This effect on the disease process appeared to be dependent upon recognition of parasite antigens by the injected T cells because no exacerbation of the disease process was seen after the transfer of similar T cell populations specific for an antigen unrelated to the parasite, namely ovalbumin. However, the inclusion of ovalbumin in the L. major infecting inoculum resulted in an exacerbating effect of ovalbumin-specific T cells on cutaneous leishmaniasis. These unexpected results were supported by observations showing that immunization of mice with L. major antigens in complete Freund's adjuvant 7 days before infection with L. major led to exacerbated lesions. A similar aggravation of L. major-induced cutaneous lesions was also observed in mice previously immunized with an unrelated antigen provided that this antigen was included in the L. major infecting inoculum.     

Protective immunity against the protozoan Leishmania chagasi is induced by subclinical cutaneous infection with virulent but not avirulent organisms

Protective immunity against Leishmania major is provided by s.c. immunization with a low dose of L. major promastigotes or with dihydrofolate-thymidylate synthase gene locus (DHFR-TS) gene knockout L. major organisms. Whether these vaccine strategies will protect against infection with other Leishmania species that elicit distinct immune responses and clinical syndromes is not known. Therefore, we investigated protective immunity to Leishmania chagasi, a cause of visceral leishmaniasis. In contrast to L. major, a high dose s.c. inoculum of L. chagasi promastigotes was required to elicit protective immunity. Splenocytes from mice immunized with a high dose produced significantly greater amounts of IFN-gamma and lower TGF-beta than mice immunized with a low dose of promastigotes. The development of protective immunity did not require the presence of NK cells. Protection was not afforded by s.c. immunization with either attenuated L. chagasi or with L. major promastigotes, and s.c. L. chagasi did not protect against infection with L. major. Subcutaneous immunization with DHFR-TS gene knockouts derived from L. chagasi, L. donovani, or L. major did not protect against L. chagasi infection. We conclude that s.c. inoculation of high doses of live L. chagasi causes a subclinical infection that elicits protective immune responses in susceptible mice. However, L. chagasi that have been attenuated either by long-term passage or during the raising of recombinant gene knockout organisms do not elicit protective immunity, either because they fail to establish a subclinical infection or because they no longer express critical antigenic epitopes.     

Soluble factors from Leishmania major-specific CD4+T cells and B cells limit L. amazonensis amastigote survival within infected macrophages

In contrast to L. major, the factors required for clearance of Leishmania amazonensis parasites from infected macrophages have been difficult to define. Multiple studies have made progress towards identifying the phenotypic differences in various cell types secondary to L. amazonensis infection as compared to L. major infection, but few have shown the cell types or factors required for parasite clearance. Based on studies which identified that mice previously infected with L. major and healed can mount a protective immune response against L. amazonensis, this study identifies cell types and factors from draining lymph node cells of L. major-infected mice that are necessary and sufficient to control infection in L. amazonensis-infected bone-marrow derived macrophages. Using a transwell system we show that soluble factors from CD4+T cells and B cells were required to kill intracellular parasites. One of these factors, L. major-specific immunoglobulin, may serve to trigger macrophage activation and promote parasite killing via superoxide production. Identification of these factors will provide more precise knowledge of host-cell signaling required to promote an effective immune response against L. amazonensis.     

Developmentally regulated sphingolipid degradation in Leishmania major

Leishmania parasites alternate between extracellular promastigotes in sandflies and intracellular amastigotes in mammals. These protozoans acquire sphingolipids (SLs) through de novo synthesis (to produce inositol phosphorylceramide) and salvage (to obtain sphingomyelin from the host). A single ISCL (Inositol phosphoSphingolipid phospholipase C-Like) enzyme is responsible for the degradation of both inositol phosphorylceramide (the IPC hydrolase or IPCase activity) and sphingomyelin (the SMase activity). Recent studies of a L. major ISCL-null mutant (iscl(-)) indicate that SL degradation is required for promastigote survival in stationary phase, especially under acidic pH. ISCL is also essential for L. major proliferation in mammals. To further understand the role of ISCL in Leishmania growth and virulence, we introduced a sole IPCase or a sole SMase into the iscl(-) mutant. Results showed that restoration of IPCase only complemented the acid resistance defect in iscl(-) promastigotes and improved their survival in macrophages, but failed to recover virulence in mice. In contrast, a sole SMase fully restored parasite infectivity in mice but was unable to reverse the promastigote defects in iscl(-). These findings suggest that SL degradation in Leishmania possesses separate roles in different stages: while the IPCase activity is important for promastigote survival and acid tolerance, the SMase activity is required for amastigote proliferation in mammals. Consistent with these findings, ISCL was preferentially expressed in stationary phase promastigotes and amastigotes. Together, our results indicate that SL degradation by Leishmania is critical for parasites to establish and sustain infection in the mammalian host.     

Interactions between Leishmania parasites and host cells.

Several species of protozoa belonging to the genus Leishmania are pathogenic for humans, causing visceral and cutaneous diseases. They are transmitted by phlebotomine sandflies as flagellated promastigotes to mammals hosts, where they live as aflagellated amastigotes mainly within macrophages. Studies performed on mice infected with Leishmania major demonstrated that host defence against this infection depends on the interleukin-12-driven expansion of the T helper 1 cell subset, with production of cytokines such as interferon-gamma, which activate macrophages for parasite killing through the release of nitric oxide. The parasitocidal role of this radical is now emerging also in the human and canine model. Healing or progression of the infection is related to the genetic and immune status of the host, and to the virulence of different species and strains of Leishmania. The parasite survival ultimately depends on the ability to evade the host immune response by several mechanisms. Among them, inhibition of the signal transduction pathway of the host cells is particularly important. In fact, promastigotes inhibit protein kinase C activation, cause Ca++ influx into the host cell and decrease the levels of myristoylated alanine-rich C kinase substrate-related proteins, which are substrates for PKC. In addition, Leishmania infection blocks IFN-gamma-induced tyrosine kinase phosphorylation, with consequent impairment of signalling for IL-12 and nitric oxide production. Finally, Leishmania activates protein phosphotyrosine phosphatases, which down-regulate mitogen-activated protein kinase signalling and c-fos and nitric oxide synthase expression. New pharmacological applications, including protein tyrosine phosphatase and protein farnesyltransferase inhibitors, are being evaluated against leishmaniosis in vitro and in vivo in the murine model.     

Comparison of the A2 gene locus in Leishmania donovani and Leishmania major and its control over cutaneous infection

In Old World Leishmania infections, Leishmania donovani is responsible for fatal visceral leishmaniasis, and L. major is responsible for non-fatal cutaneous leishmaniasis in humans. The genetic differences between these species which govern the pathology or site of infection are not known. We have therefore carried out detailed analysis of the A2 loci in L. major and L. donovani because A2 is expressed in L. donovani but not L. major, and A2 is required for survival in visceral organs by L. donovani. We demonstrate that although L. major contains A2 gene regulatory sequences, the multiple repeats that exist in L. donovani A2 protein coding regions are absent in L. major, and the remaining corresponding A2 sequences appear to represent non-expressed pseudogenes. It was possible to restore amastigote-specific A2 expression to L. major, confirming that A2 regulatory sequences remain functional in L. major. Although L. major is a cutaneous parasite in rodents and humans, restoring A2 expression to L. major inhibited its ability to establish a cutaneous infection in susceptible BALB/c or resistant C57BL6 mice, a phenotype typical of L. donovani. There was no detectable cellular immune response against L. major after cutaneous infection with A2-expressing L. major, suggesting that the lack of growth was not attributable to acquired host resistance but to an A2-mediated suppression of parasite survival in skin macrophages. These observations argue that the lack of A2 expression in L. major contributed to its divergence from L. donovani with respect to the pathology of infection.     

Leishmania inhibits STAT1-mediated IFN-gamma signaling in macrophages: increased tyrosine phosphorylation of dominant negative STAT1beta by Leishmania mexicana

Previous studies have demonstrated that Leishmania donovani attenuates STAT1-mediated signaling in macrophages; however it is not clear whether other species of Leishmania, which cause cutaneous disease, also interfere with macrophage IFN-gamma signaling. Therefore, we determined the effect of Leishmania major and Leishmania mexicana infection on STAT1-mediated IFN-gamma signaling pathway in J774A.1 and RAW264.7 macrophages. We found that both L. major and L. mexicana suppressed IFNgammaRalpha (alpha subunit of interferon gamma receptor) and IFN-gammaRbeta (beta subunit of interferon gamma receptor) expression, reduced levels of total Jak1 and Jak2, and down-regulated IFN-gamma-induced Jak1, Jak2 and STAT1 activation. The effect of L. mexicana infection on Jak1, Jak2 and STAT1 activation was more profound when compared with L. major. Although tyrosine phosphorylation of STAT1alpha was decreased in IFN-gamma stimulated macrophages infected with L. major or L. mexicana, those infected with L. mexicana showed a significant increase in phosphorylation of the dominant negative STAT1beta. These findings indicate that L. major and L. mexicana attenuate STAT1-mediated IFN-gamma signaling in macrophages. Furthermore, they also demonstrate that L. mexicana preferentially enhances tyrosine phosphorylation of dominant negative STAT1beta, which may be one of the several survival mechanisms used by this parasite to evade the host defense mechanisms.     

Control of infection with Leishmania major in susceptible BALB/c mice lacking the common gamma-chain for FcR is associated with reduced production of IL-10 and TGF-beta by parasitized cells

Previous studies have shown that the in vitro ligation of FcgammaRs with IgG-opsonized Leishmania amastigotes promotes IL-10 production by macrophages. In addition, infection of either BALB/c mice lacking the common gamma-chain of Fc receptors (FcgammaR(-/-)) or mice genetically altered to lack circulating Ab (J(H)D) with Leishmania pifanoi results in reduced and delayed lesion development and a deficit in the recruitment of inflammatory cells into infected lesions. We show in this study that FcgammaR(-/-) mice can control infection with Leishmania major and totally resolve cutaneous lesions. The ability to eventually control infection is not associated with a reduction in lesion inflammation or a reduction in the ability of Leishmania to parasitize cells through week 6 of infection. The immune response in healing FcgammaR(-/-) mice is associated with a reduction in numbers of cells producing Th2-type cytokines, including IL-4 and IL-10, but not an increase in numbers of IFN-gamma-producing cells characteristic of a dominant Th1-type response. Instead, we observe a reduction in levels of IL-10 and TGF-beta within infected lesions, including reduced levels of these cytokines within parasitized macrophages. Together, these results suggest that uptake of opsonized parasites via FcgammaRs may be a strong in vivo stimulus for the production of anti-inflammatory cytokines that play a role in susceptibility to infection.