Leishmania braziliensis panamensis: increased infectivity resulting from heat shock

Liver infusion tryptose (LIT): the best choice for growth, viability, and infectivity of Leishmania infantum parasites

Leishmania spp. parasites have a complex biological cycle presenting basically two different morphological stages, the amastigote and promastigote forms. In vitro cultivation allows a more complete study of the biological aspects of these parasites, indicating better conditions for infection, immunoassay tests, drug evaluations, and vaccines. Thus, we evaluated the three most used culture media for Leishmania spp., Grace’s insect cell culture medium (Grace’s), liver infusion tryptose (LIT), and Schneider’s insect medium (Schneider’s), without supplementation or supplemented with fetal calf serum (FCS) and bovine serum albumin (Albumin) to evaluate the growth, viability, and infectivity of the L. infantum promastigotes. It was observed that promastigote forms have a better growth in LIT and Schneider’s with or without FCS when compared to that in Grace’s. The supplementation with albumin promoted greater viability of the parasites independent of the medium. For in vitro infection of J774.A1 macrophages using light microscopy and flow cytometry analyses, FCS-supplemented LIT and Grace’s promoted higher percentage of infected macrophages and parasite load compared with Schneider’s media. Taken together, our results demonstrated that the supplementation of LIT culture medium with FCS is the most suitable strategy to cultivate Leishmania infantum parasites enabling the maintenance of growth and infective parasites for research uses.

Effect of El Niño Southern Oscillation cycle on the potential distribution of cutaneous leishmaniasis vector species in Colombia

Local anomalies in rainfall and temperature induced by El Niño and La Niña episodes could change the structure of the vector community. We aimed to estimate the effect of the El Niño–La Niña cycle in the potential distribution of cutaneous leishmaniasis (CL) vector species in Colombia and to compare the richness of the vectors with the occurrence of CL in the state of Norte de Santander. The potential distributions of four species were modeled using a MaxEnt algorithm for the following episodes: La Niña 2010–2011, Neutral 2012–2015 and El Niño 2015–2016. The relationship between the potential richness of the vectors and the occurrence of CL in Norte de Santander was evaluated with a log-binomial regression model. During the El Niño 2015–2016 episode, Lutzomyia ovallesi and Lutzomyia panamensis increased their distribution into environmentally suitable areas, and three vector species (Lutzomyia gomezi, Lutzomyia ovallesi and Lutzomyia panamensis) showed increases in the range of their altitudinal distribution. During the La Niña 2010–2011 episode, a reduction was observed in the area suitable for occupation by Lutzomyia gomezi and Lutzomyia spinicrassa. During the El Niño 2015–2016 episode, the occurrence of at least one CL case was related to a higher percentage of rural localities showing a richness of vectors = 4. The anomalies in rainfall and temperature induced by the episodes produced changes in the potential distribution of CL vectors in Colombia. In Norte de Santander, during Neutral 2012–2015 and El Niño 2015–2016 episodes, a higher probability of at least one CL case was related to a higher percentage of areas with a greater richness of vectors. The results help clarify the effect of the El Niño–La Niña cycle in the dynamics of CL in Colombia and emphasize the need to monitor climate variability to improve the prediction of new cases.

The cutaneous leishmaniasis is a disease transmitted by insects. The incidence of cutaneous leishmaniasis has increased in Colombia and the state of Norte de Santander is one of the Colombian states where cutaneous leishmaniasis transmission is high. Local changes in rainfall and temperature induced by El Niño and La Niña episodes could change the distribution of the vector. A database of published records and field collections of four vectors of cutaneous leishmaniasis in Colombia was compiled. Also, a database with cases of cutaneous leishmaniasis from Norte de Santander was obtained. Maps of potential distribution in Colombia of the four vectors during the La Niña 2010–2011, Neutral 2012–2015 and El Niño 2015–2016 episodes were elaborated. During the El Niño 2015–2016 episode, two vector species increased their distribution into environmentally suitable areas, and three vector species showed increases in the range of their altitudinal distribution. During the La Niña 2010–2011 episode, a reduction was observed in the area suitable for occupation by two vectors. During the El Niño 2015–2016 episode, the occurrence of at least one cutaneous leishmaniasis case was related to a higher percentage of area with a predicted distribution of four vectors.

Temporal lagged relationship between a vegetation index and cutaneous leishmaniasis cases in Colombia: an analysis implementing a distributed lag nonlinear model

Cutaneous leishmaniasis is a neglected tropical disease with a strong environmental component. The aim of this research was to implement a distributed lag nonlinear model to explore the temporal lagged relationship between a vegetation index and cutaneous leishmaniasis cases. In this ecological study, a time series of weekly cases of cutaneous leishmaniasis reported between 2007 and 2016 in the five municipalities in Colombia with the most cases of the disease and a vegetation index was analyzed. During the study period, a total of 16,321 cases were reported in these five municipalities. Two municipalities showed a lagged nonlinear positive association between the risk of occurrence of new cases and the magnitude of the vegetation index; two municipalities showed a negative association; and in the remaining municipality, the risk was associated with the vegetation index but its confidence interval was not significant. Our results show different patterns and magnitudes of the lagged relationship between the vegetation index and cutaneous leishmaniasis cases and suggest the possibility of using the lag pattern of the vegetation index in the development of an early warning system where a lagged positive relationship is identified.

Effect of human urine on cell cycle and infectivity of Leismania species promastigotes in vitro

In vitro cultivation of Leishmania parasites plays an important role in diagnosis and treatment of leishmaniasis and in vaccine and drug development studies. Conversely, long-term cultivation of Leishmania parasites usually results in decreased infectivity potential. Some studies reported a stimulatory effect of human urine in Leishmania promastigotes. However, there is no information about the effects of urine within culture on the infectivity of Leishmania parasites. Analysis of the effect of urine have showed that proliferation indexes were significantly increased in culture medium supplemented with human urine (L. tropica = 38.17 ± 5.12, L. donovani = 34.74 ± 5.6, L. major = 34.22 ± 4.66, and L. infantum 35.88 ± 6.40) than in controls. Infection indexes were 13 ± 1.7 for L. tropica, 55 ± 2.2 for L. infantum, 41 ± 3.14 for L. donovani, and 49 ± 3.26 for L. major. Our results showed that human urine increased the infectivity and proliferation of Leishmania parasites.

Molecular chaperones in pathogen virulence: emerging new targets for therapy

Infectious organisms have to cope with demanding and rapidly changing environments during establishment in the host. This is particularly relevant for pathogens that utilize different hosts to complete their life cycle. In addition to homeotic environmental challenges, other stressful factors, such as oxidative bursts, are often triggered in response to infection. It is not surprising that many successful pathogens have developed robust chaperone systems to conquer the stressful environments in the host. In addition to discussing ingenious ways by which pathogens have utilized chaperones, the potential of exploiting pathogen chaperones as drug targets is also discussed.

Leishmania amazonensis: effects of heat shock on ecto-ATPase activity

In this work we demonstrated that promastigotes of Leishmania amazonensis exhibit an Mg-dependent ecto-ATPase activity, which is stimulated by heat shock. The Mg-dependent ATPase activity of cells grown at 22 and 28 degrees C was 41.0+/-5.2 nmol Pi/h x 10(7)cells and 184.2+/-21.0 nmol Pi/h x 10(7)cells, respectively. When both promastigotes were pre-incubated at 37 degrees C for 2h, the ATPase activity of cells grown at 22 degrees C was increased to 136.4+/-10.6 nmol Pi/h x 10(7) whereas that the ATPase activity of cells grown at 28 degrees C was not modified by the heat shock (189.8+/-10.3 nmol Pi/h x 10(7)cells). It was observed that Km of the enzyme from cells grown at 22 degrees C (Km=980.2+/-88.6 microM) was the same to the enzyme from cells grown at 28 degrees C (Km=901.4+/-91.9 microM). In addition, DIDS (4,4'-diisothiocyanatostilbene 2,2'-disulfonic acid) and suramin, two inhibitors of ecto-ATPases, also inhibited similarly the ATPase activities from promastigotes grown at 22 and 28 degrees C. We also observed that cells grown at 22 degrees C exhibit the same ecto-phosphatase and ecto 3'- and 5'-nucleotidase activities than cells grown at 28 degrees C. Interestingly, cycloheximide, an inhibitor of protein synthesis, suppressed the heat-shock effect on ecto-ATPase activity of cells grown at 22 degrees C were exposed at 37 degrees C for 2h. A comparison between the stimulation of the Mg-dependent ecto-ATPase activity of virulent and avirulent promastigotes by the heat shock showed that avirulent promastigotes had a higher stimulation than virulent promastigotes after heat stress.

Heat shock protein synthesis over time in infective Trichinella spiralis larvae raised in suboptimal culture conditions

Changes in the viability, infectivity and heat shock protein (Hsp) levels are reported in Trichinella spiralis first stage larvae (L1) stored in 199 medium for up to seven days at 37°C. These conditions induce stress that the larvae, eventually, cannot overcome. After three days of storage, the infectivity and viability were unchanged, although higher Hsp70 levels were observed. After this time, larvae gradually lost viability and infectivity, coinciding with a decrease in Hsp70 and Hsp90 and an increase in actin (a housekeeping protein). In addition, a possibly inducible heat shock protein, Hsp90i, appeared as constitutive Hsp90 disappeared. No significant changes in Hsp60 levels were detected at any time. These results suggest that heat shock proteins initially try to maintain homeostasis, but on failing, may be involved in cell death.

Relationship between heat shock protein levels and infectivity in Trichinella spiralis larvae exposed to different stressors

The aim of the present study was to investigate the relationship between infectivity and the levels of two major heat shock proteins (Hsp70 and Hsp60) in Trichinella spiralis larvae. Parasites were exposed to either sublethal thermal stress (43 and 45 degrees C) or to warm or cold temperature oxidative stress. The stressed larvae were then inoculated into female CD1 mice to determine their infectivity. Hsps were detected and quantified by Western blotting using monoclonal antibodies. Infectivity was expressed as larvae per gram of muscle. Warm temperature oxidative stress (20 mM H2O2 at 37 degrees C) caused a significant increase in Hsp levels and total loss of infectivity. Cold oxidative stress (20 mM H2O2 at 4 degrees C) caused no alterations in either Hsp levels or infectivity. However, high oxidative stress and cold (200 mM H2O2 at 4 degrees C) caused a slight increase in Hsp60 levels and a drastic reduction in infectivity. Exposure of the larvae to 43 or 45 degrees C did not significantly alter Hsp levels or infectivity. These results show that (i) cold reduces the deleterious effects of oxidative stress; (ii) heat induces neither increased Hsp60/Hsp70 levels nor reduces infectivity; (iii) increased Hsp levels induced by oxidative stress may cause lower infectivity.

Heat-stress induced modulation of protein phosphorylation in virulent promastigotes of Leishmania donovani

In parasites such as Leishmania, the study of molecular events induced in response to heat stress is of immense interest since temperature increase is an integral part of the life cycle. Protein phosphorylation is known to control major steps of proliferation and differentiation in eukaryotic cells. Studies on intracellular signaling systems in protozoa are relatively recent. We have examined the effect of heat shock on the protein phosphorylation status in promastigotes of Leishmania donovani. The patterns of total protein phosphorylation and specific phosphorylation at tyrosine residues were examined using [32P]-orthophosphate labelling of the parasites and immunoblotting with a monoclonal anti-phosphotyrosine antibody. The major proteins of L. donovani that were phosphorylated at 24 degrees C had apparent molecular weights of 110, 105, 66-68, 55, 36-40 and 20 kDa. Heat shock (from 24 to 37 degrees C) led to a significant decrease in phosphorylation of the majority of phosphoproteins in the virulent promastigotes. On the other hand, the avirulent promastigotes did not show any decrease in protein phosphorylation on exposure to heat stress. Predominant phosphorylation at tyrosine residues was detectable in proteins of putative size 105-110 kDa in both virulent and avirulent parasites. Heat shock led to a reduction in the level of phosphotyrosine in both these proteins in the case of virulent parasites, while no such reduction was detectable in avirulent parasites. Significant modifications in the phosphorylation status of proteins in response to heat stress including that of tyrosine containing proteins, observed exclusively in virulent parasites, suggest that modulation of protein phosphorylation/dephosphorylation may play a role in signal transduction pathways in the parasite upon heat shock encountered on entering the mammalian host.

Cytokines, nitric oxide, heat shock proteins and virulence in Toxoplasma

Elucidating the factors that play important roles in the expression of virulence by parasites is crucial to understanding disease pathogenesis and to developing control strategies rationally. Here, Kate Miller, Nick Smith and Alan Johnson, using Toxoplasma gondii as a model, argue that the interactions between the immune system and 70 kDa heat shock proteins of apicomplexan parasites profoundly influence parasite virulence.

Should I stay or should I go now? A stochastic model of stage differentiation in Theileria annulata

The events that initiate and determine stage differentiation of protozoan parasites are not fully understood. In this article, Brian Shiels suggests that for differentiation to the merozoite in Theileria annulata the process is predetermined by the parasite, but can be initiated and modulated by changes to the extracellular environment. Shiels proposes a mechanism operating on the basis of factors that regulate gene expression reaching a commitment threshold. Similarities across protozoan and higher eukaryotic differentiation systems lead Shiels to speculate that the T. annulata model may be of relevance to other parasites.

Leishmania major Hsp100 is required chiefly in the mammalian stage of the parasite

In Leishmania major a 100-kDa heat shock protein, Hsp100, is abundant in the intracellular amastigote stage which persists in the mammalian host. A replacement of both clpB alleles which encode Hsp100 does not affect promastigote viability under standard culture conditions but impairs thermotolerance in vitro. In experimental infections of BALB/c inbred mice, the lack of Hsp100 in the gene replacement mutants results in a markedly delayed lesion development compared with that in infections with wild-type L. major. Overexpression of exogenous clpB gene copies can partly restore virulence to the gene replacement mutants. Genetic-selection experiments also reveal a strong pressure for Hsp100 expression in the mammalian stage. This requirement for Hsp100 was also observed in in vitro infection experiments with mouse peritoneal macrophages. These experiments indicated a role for Hsp100 during the development from the promastigote to the amastigote stage. Our results suggest an important role for this parasite heat shock protein during the initial stages of a mammalian infection.

Membrane characterization of amastigote-like forms of Leishmania donovani

During in vitro transformation, Leishmania donovani promastigotes converted into amastigote-like forms and underwent several changes in membrane parameters. They exhibited significantly increased microviscosity comparable to true amastigotes. Activities of several functionally important membrane bound enzymes were also altered, thereby indicating a change in their orientation. Peanut agglutinin was found to be specific for agglutination of stationary phase promastigotes whereas wheat-germ agglutinin was specific for the amastigote-like forms as well as for pure amastigotes, implying the presence of specific glycoconjugates on the parasite surface.

Heat shock induction of apoptosis in promastigotes of the unicellular organism Leishmania (Leishmania) amazonensis

Apoptosis and/or programmed cell death have been described in examples ranging from fungi to man as gene-regulated processes with roles in cell and tissue physiopathology. These processes require the operation of an intercellular communicating network able to deliver alternative signals for cells with different fates and is thus considered a prerogative of multicellular organisms. Promastigotes from Leishmania (Leishmania) amazonensis, when shifted from their optimal in vitro growth temperature (22 degrees C) to the temperature of the mammalian host (37 degrees C), die by a calcium-modulated mechanism. More parasites die in the presence of this ion than in its absence, as detected by a colorimetric assay based on the activity of mitochondrial and cytoplasmic dehydrogenases which measures cell death, independently of the process by which it occurs. A heat shock, unable to induce detectable parasite death (34 degrees C for 1 h), is able to significantly raise the concentration of intracellular free calcium in these cells. Heat-shocked parasites present ultrastructural and molecular features characteristic of cells dying by apoptosis. Morphological changes, observed only in the presence of calcium, are mainly nuclear. Cytoplasmic organelles are preserved. Heat shock is also able to induce DNA cleavage into an oligonucleosomal ladder detected in agarose gels by ethidium bromide staining and autoradiography of [alpha 32P]ddATP-labeled fragments. These results indicate that death by apoptosis is not exclusive of multicellular organisms.

Developmental changes in the expression of Leishmania chagasi gp63 and heat shock protein in a human macrophage cell line

The ability of the protozoan Leishmania chagasi to infect a vertebrate host depends on its ability to survive intracellularly in a mammalian macrophage. Novel patterns of gene expression are probably important for conversion from the extracellular promastigote to the obligate intracellular amastigote parasite form. We found that the human macrophage-like cell line U937 provided an in vitro model of phagocytosis of L. chagasi promastigotes and intracellular conversion to amastigotes, allowing examination of parasite protein and RNA expression. The Leishmania surface protease gp63 assumed three isoforms during stage conversion, and a 64-kDa form of gp63 not present in promastigotes became the most prominent form in amastigotes. gp63 RNAs derived from the three different classes of msp genes (mspS, mspL, and mspC) were also differentially expressed. Infectious promastigotes contained mRNAs from mspS and mspC genes, whereas converting parasites expressed only mspL and mspC mRNAs. Sequence analysis of clones from an amastigote cDNA library confirmed the presence of gp63 mRNAs only from mspL and mspC class genes in tissue-derived amastigotes. Finally, 24 h after phagocytosis, there was a transient increase in the level of hsp70 and hsp90 proteins that subsequently decreased to baseline; this increase was not due to heat shock alone. We conclude that a unique pattern of selected L. chagasi proteins and RNAs is induced following phagocytosis by macrophages.

Heat shock proteins of Toxoplasma gondii

We have investigated heat shock protein (HSP) expression in mouse-virulent and -avirulent strains of Toxoplasma gondii by performing Western blot analysis using a monoclonal antibody against HSP65 of Mycobacterium bovis and a polyclonal antiserum against HSP70 of Plasmodium falciparum as primary antibodies. We initially observed that murine macrophages express HSP65 when infected with either virulent or avirulent strains, a result which contradicts previous reports. Differential HSP expression consistent which virulence was observed between strains, with high levels of a 70kDa HSP (HSP70) only detected in virulent strains in vivo. This protein was not observed in virulent strains in the immunocompromised mouse or in vitro, suggesting induction by immunological stress. This protein was only poorly expressed in avirulent strains. A 65kDa protein was observed in all strains in vivo and in vitro, suggesting a shared epitope with HSP70. These results are consistent with the hypothesis that the induced expression of HSP70 in virulent strains of T. gondii by immunological stresses may provide protection for these strains against cell damage associated with invasion of the host, allowing the virulent strains to persist as tachyzoites without the requirement for the encystation observed in avirulent strains.

Effects of temperature on promastigotes of several species of Leishmania

Six Leishmania species were studied comparatively, in order to determine the influence of temperature "in vitro" on differentiation, infectivity and protein synthesis. Differentiation occurred in a heterogeneous manner, even in species that produce similar clinical manifestations. Thus, no association could be found between thermosensitivity and disease. The association between expression of proteins and increasing temperatures was analyzed at 34 degrees C by polyacrylamide gel electrophoresis with sodium dodecyl sulphate (SDS-PAGE), using different incubation times, and employing a technique involving metabolic incorporation of [35S]-methionine. Protein synthesis was very similar in all the New World species apart from L. amazonensis, which expressed a protein of approximately 80 kDa when incubated at 34 degrees C for 2 hours. All the tested species had in common the expression of a 70 kDa protein. Differences, however, were observed in relation to the time interval for protein expression. In L. chagasi, synthesis was detected after 30 minutes of incubation at 34 degrees C, while L. braziliensis required 1 hour at the same temperature. The "in vivo" and "in vitro" infectivity of the differentiated forms was also analyzed, but no significant differences were observed.

Leishmania donovani: in vitro culture and [1H] NMR characterization of amastigote-like forms

When Leishmania donovani promastigote forms, were cultured in TC-199 medium at 28 degrees C and subsequently incubated at 38 degrees C, they turned into aflagellate (amastigote-like) forms. A return of the incubation-culture temperature to 28 degrees C these amastigote-like forms to revert to promastigotes. The amastigotes obtained by heat-shock, were viable and retained antigenic capacity being recognized by the sera of naturally infected patients. These forms, remained also capable of multiplying inside the J-774A.1 macrophages. When the amastigote-like forms are kept in culture at 38 degrees C retained their rounded appearance and their biological characteristics for more than 3 months subculturing every 6 days. These amastigote-like forms, when used for subcultures at 28 degrees C, transformed into promastigotes capable of multiplying as flagellate forms. The amastigote-like forms obtained in vitro can be used in biochemical studies related to chemotherapy and immunology studies, as part of an effort to combat this parasite. The end-products of of glycolysis were studied in both the amastigote-like and promastigote forms of L. donovani, by proton magnetic resonance analysis of the culture media. Alanine, succinate, and acetate, were predominant, and to a lesser extent pyruvate, glycine and D-lactate. Our results suggest that both forms of Leishmania use different biochemical strategies to obtain their energy.

Tumour necrosis factor-alpha induces preferential expression of stress proteins in virulent promastigotes of Leishmania donovani

Intracellular replication of Leishmania donovani inside macrophages is essential for production of disease and development of the parasite. Tumour necrosis factor-alpha (TNF) plays an integral role in host response to Leishmania. The effect of TNF on expression of heat-shock proteins (Hsp) was examined in promastigotes of L. donovani. TNF treatment led to an increased expression of Hsp83, Hsp70 and Hsp65 in virulent, but not avirulent, parasites. In response to stress by H2O2 or sodium arsenite, an increased expression of Hsp60 was observed in the virulent, but not avirulent, parasites. The virulent promastigotes were found to be more resistant to the toxic effects of TNF and other stresses. The data indicated that Hsp expressed in response to stress encountered in macrophages may confer protection to parasites and play a crucial role in their survival in the mammalian host.

Protective effects of hsp70 in inflammation

Inflammation results from the recruitment to a given tissue or organ and the activation of leucocytes, among which the monocytes-macrophages play a major role. These phagocytic cells produce high levels of reactive oxygen species (ROS) as well as cytokines. Whereas both ROS and cytokines have the potential to regulate the expression of heat shock (HS)/stress proteins (HSP), it appears that these proteins in turn have the ability to protect cells and tissues from the deleterious effects of inflammation. The mechanisms by which such protection occurs include prevention of ROS-induced DNA strand breaks and lipid peroxidation as well as protection from mitochondrial structure and function. In vivo, HS protects organs against a number of lesions associated with the increased production of ROS and/or cytokines. In an animal model for adult respiratory distress syndrome, an acute pulmonary inflammatory condition, HS completely prevented mortality. HSP (hsp70 in particular) may also exert protective effects in the immune system by contributing to the processing and presentation of bacterial and tumoral antigens. The analysis of the expression of hsp70 may prove of diagnostic and prognostic value in inflammatory conditions and therapeutical applications are being considered.

Hsp70 in parasites: as an inducible protective protein and as an antigen

The heat shock (HS) response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stresses. It has been demonstrated that heat shock proteins (HSP) play major roles in many cellular processes, and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology, from cancer research to interaction between host and parasites. This review deals with the hsp70 gene family and with its protein product, hsp70, as an antigen when pathogens infect humans. Members of HSP have been shown to be major antigens of many pathogenic organisms when they experience a major temperature shift upwards at the onset of infection and become targets for host B and T cells.

Response of Leishmania chagasi promastigotes to oxidant stress

At the onset of infection, Leishmania promastigotes are phagocytized by mammalian macrophages. They must survive despite exposure to toxic oxidants such as hydrogen peroxide (H2O2) and superoxide (.O2-) generated during phagocytosis. We investigated the effects of these oxidants on Leishmania chagasi promastigotes and promastigote mechanisms for oxidant resistance. According to spin trapping and electron paramagnetic resonance spectrometry, .O2- could be generated by exposure of promastigotes to the redox-cycling compound menadione. Incubation in either menadione or H2O2 caused a concentration-dependent loss of promastigote viability. However, incubation in sublethal concentrations of H2O2 or menadione caused a stress response in promastigotes. This oxidant-induced response was associated with an increase in the amount of heat shock protein hsp70. Induction of a stress response by exposure of promastigotes either to heat shock or to sublethal oxidants (H2O2 or menadione) caused promastigotes to become more resistant to H2O2 toxicity. Sublethal menadione also caused promastigotes to become more virulent in a BALB/c mouse model of leishmaniasis. We previously correlated H2O2 cytotoxicity for promastigotes with the formation of hydroxyl radical (.OH) from H2O2. However, according to electron paramagnetic resonance spectrometry, the increase in H2O2 resistance after exposure to sublethal oxidants was not associated with diminished generation (i.e., scavenging) of .OH. These data suggest that there is a cross-protective stress response that occurs after exposure of L. chagasi promastigotes to heat shock or to sublethal H2O2 or .O2-, exposures that also occur during natural infection. This response results in increased resistance to H2O2 toxicity and increased virulence for a mammalian host.

Expression of 65- and 67-kilodalton heat-regulated proteins and a 70-kilodalton heat shock cognate protein of Leishmania donovani in macrophages

Heat shock protein (HSP) expression was examined in murine bone marrow-derived macrophages infected with stationary-phase promastigotes of Leishmania donovani. Immunoblotting performed with a rabbit polyclonal antiserum raised against HSP60 from Heliothis virescens (moth) revealed the de novo appearance of 65- and 67-kDa proteins in leishmania-infected macrophages. A third protein of 60 kDa, which represented murine HSP60, was also detected, and its expression did not change in response to infection. In contrast, expression of the novel 65- and 67-kDa proteins in infected cells was coordinately regulated and, at 24 h of infection, reached maximal levels of 52 to 100% increases above initial levels determined at 3 h. Proteins which had identical electrophoretic mobilities and were similarly regulated in response to heat were also detected in promastigotes. The appearance of these proteins in macrophages was specific to leishmania infection in that neither protein was detected in noninfected cells either in the basal state or following several treatments, including (i) infection with Yersinia pseudotuberculosis, (ii) phagocytosis of Staphylococcus aureus, (iii) NaAsO2 treatment, and (iv) heat shock. Expression of the 65- and 67-kDa heat-regulated Leishmania proteins was also observed to be selective, in that as their concentration was increasing, the abundance of the Leishmania surface protease gp63 in infected cells was noted to decrease. Murine HSP60 but not the Leishmania heat-regulated proteins was also recognized by a distinct rabbit antiserum raised against human HSP60, suggesting the presence of specific determinants within these Leishmania proteins. A monoclonal antibody that recognizes both mammalian HSP70 and HSP70 from plasmodia detected single isoforms of both Leishmania and murine HSP70 in infected cells, and the level of neither protein changed during infection. Moreover, although a murine HSP of 73 kDa was induced in response to both heat shock and NaAsO2 treatment, it was not induced to detectable levels by infection. The rapid and relatively high level of expression of inducible HSP60-related proteins of L. donovani and Leishmania HSP70 in infected macrophages suggests that these proteins are involved in pathogenesis and may be important targets of the immune response.

Developmental life cycle of Leishmania--cultivation and characterization of cultured extracellular amastigotes

The biochemistry and immunology of Leishmania promastigotes has been extensively studied; this is due primarily to the facility with which this stage, in contrast to the amastigotes stage, can be maintained in axenic culture. Several attempts to axenically culture lines of Leishmania amastigotes have been reported in the literature. This paper summarizes methods of adaptation (low pH, elevated temperature and culture medium) and characterization of several axenic lines of Leishmania amastigotes. Based on morphological, biological, immunological and biochemical evidence, these organisms appear to resemble amastigotes from infected macrophages or tissue. The axenically cultured amastigotes appear to be distinct from shocked (heat, serum deprivation, stressed) Leishmania promastigotes in the plethora of proteins synthesized, growth (multiplication) in culture, and developmental regulation observed. These data suggest that Leishmania organisms have a significant developmental response to certain signals (pH, temperature) mimicking their in vivo macrophage milieu. The response to other environmental parameters characteristic of the host-macrophage remain to be determined. These axenically cultured amastigotes should be of interest for further immunological, biochemical and developmental investigations of the disease-maintaining stage of this parasite.

Axenic cultivation and characterization of Leishmania mexicana amastigote-like forms

A new method is described which has made possible the long-term axenic cultivation of Leishmania mexicana amastigote-like forms in Schneider's Drosophila medium supplemented with 20% (v/v) foetal calf serum. Unlike previous methods, it utilizes direct culture of parasites obtained from the lesions of infected animals rather than adaptation of promastigotes in vitro. Ultrastructural (possession of megasomes), biochemical (cysteine proteinase activity and gelatin SDS-PAGE banding pattern) and infectivity (in vivo) data are presented which show the close similarity of the cultured forms to lesion amastigotes. The axenically cultured forms grew optimally at a temperature of 32-33 degrees C, providing further evidence for their amastigote nature. It was found that adjustment of the pH of the growth medium to 5.4 was required in order to retain the amastigote morphology of the cultured parasites. This supports the notion that leishmanial amastigotes are acidophiles.

Axenic cultivation of amastigotes of Leishmania donovani and Leishmania major and their infectivity

Two clones of promastigotes, one of Leishmania donovani and one of L. major, and an uncloned stock of L. major were axenically transformed to heat-shock amastigotes, at 35 and 37 degrees C, respectively. Of the four different culture media tested, a relatively cheap, liquid medium, RBLM, was found to be the best, both for the transformation of the promastigotes and the serial, axenic cultivation of the amastigotes. In an experiment of 30 days duration, serial cultivation, in an atmosphere with 5% CO2, was possible by subculturing every three days. There were significant differences in virulence in BALB/c mice between axenically-cultured amastigotes and promastigotes, both in terms of the weights, lengths and parasite burdens of the spleens of mice infected intraperitoneally (ip) with L. donovani or L. major and of the appearance, type and size of the cutaneous lesions which developed in mice given L. major by intradermal inoculation.

The biology of the heat shock response in parasites

The heat shock response is a general homeostatic mechanism that protects cells and the entire organism from the deleterious effects of environmental stress. It has been shown that heat shock proteins play major roles in many cellular processes and have a unique role in several areas of cell biology, from chronic degenerative diseases to immunology and from cancer research to interactions between host and parasite. In this review, Bruno Maresca and Luisella Carratu deal with some of the unique characteristics of the heat shock response in parasitic organisms.

Regulation of hsp70 expression in Trypanosoma cruzi by temperature and growth phase

The steady-state level of the hsp70 mRNAs of Trypanosoma cruzi cultured at different temperatures and growth conditions has been analyzed by Northern blotting. We show that only one size class of hsp70 mRNA, of about 2.2 kb, is transcribed from the hsp70 cluster and that its transcription is constitutive at 28 degrees C. However, after a heat shock treatment at 37 degrees C for 2 h of logarithmically growing parasites, the abundance of the hsp70 mRNA increased about 4-fold. A similar increase was observed at 28 degrees C when the parasite culture reached the stationary phase of growth. On the other hand, a heat shock at 42 degrees C did not change the steady state level of the 2.2-kb size class of hsp70 mRNA. However, accumulation of transcripts of high molecular weight was detected when stationary growing parasites were cultured at 42 degrees C for 2 h. Also at 37 degrees C the steady state level of the alpha- and beta-tubulin mRNAs of logarithmically growing parasites exhibited a slight increase but only after a period of 24 h. Analysis by one-dimensional immunoblots of the Hsp70 levels showed that at 37 degrees C the abundance of the protein was 4-fold higher than at 28 degrees C. Immunoblots of high-resolution two-dimensional gel electrophoresis showed, moreover, that various isoforms of this protein are constitutively expressed at 28 degrees C and that some of them have a specific pattern of induction at 37 degrees C. We observed, moreover, that the heat shock induces the expression of a series of proteins while it causes repression of others.

Induction of heat shock protein closely correlates with protection against Toxoplasma gondii infection

Heat shock proteins (HSPs) are evolutionarily highly conserved polypeptides that appear to be produced by many cells to preserve cellular functions under a variety of conditions of stress, including infections. We report that a 65-kDa HSP is present in mouse peritoneal cells that have been infected with a low-virulence (Beverley) strain of Toxoplasma gondii, as determined by electroblot assay using a monoclonal antibody specific for microbial HSP65. This HSP is, however, not expressed when infection occurs with the high-virulence RH strain of T. gondii. Furthermore, HSP was demonstrable in mice that acquired resistance against infection with a lethal dose of bradyzoites of the Beverley strain or even of an inoculum of a highly virulent strain of T. gondii (RH). From these results, it can be suggested that HSPs play an important role in developing effective defenses that include effective immune responses against infection with Toxoplasma parasites in vivo.

Hydrogen peroxide-mediated toxicity for Leishmania donovani chagasi promastigotes. Role of hydroxyl radical and protection by heat shock

Leishmania must survive despite exposure to the toxic oxidant hydrogen peroxide (H2O2) during phagocytosis by macrophages. We investigated the mechanism of H2O2 toxicity for L. donovani chagasi promastigotes, and factors responsible for their relative H2O2 resistance. There was a dose-dependent toxic effect of H2O2 for promastigotes isolated during logarithmic phase of growth. In contrast, stationary phase promastigotes were less susceptible to H2O2 toxicity, and more infectious for BALB/c mice. By spin trapping we found that hydroxyl radical (.OH) was generated after exposure of promastigotes to H2O2, and the amount of .OH was greater with log-phase than with stationary-phase promastigotes. .OH was generated after the addition of H2O2 to the cytosol but not the membranes of fractionated promastigotes, and the magnitude of .OH was greater in log than in stationary promastigote cytosol. Deferoxamine inhibition suggested that intracellular promastigote iron catalyzes .OH formation via the Fenton reaction. Furthermore, exposure of log-phase promastigotes to heat shock induced a relative H2O2-resistant state, which was not associated with a decrease in .OH formation but which required ongoing transcription. Thus, growth to stationary phase and heat shock both induce a state of relative H2O2 resistance, but these are probably due to different resistance mechanisms.

Biochemical and molecular characterization of Leishmania pifanoi amastigotes in continuous axenic culture

Inability to culture the disease-producing amastigote form of Leishmania has greatly hampered its study. We have biochemically characterized an axenically cultured amastigote-like form of Leishmania pifanoi. This form closely resembles amastigotes in proteinase, ribonuclease, adenine deaminase and peroxidase activity. It also exhibits comparable rates of growth, transformation, synthesis of DNA, RNA and protein, and metabolism of glucose and linoleic acid. It is distinct from promastigotes in these characteristics. The expression of the genes for beta-tubulin and the P100/11E reductase is developmentally regulated in this axenic form as in amastigotes. These results, combined with previous demonstrations of amastigote morphology and antigenicity in the culture form, confirm that Leishmania amastigotes have been successfully propagated in axenic media. This strain should serve as an excellent model for the study of amastigote biochemistry, pharmacology and immunology, and the molecular genetics of the transformation between amastigote and promastigote forms.

Leishmania donovani: long-term culture of axenic amastigotes at 37 degrees C

L. donovani promastigotes were subjected to heat treatment yielding an axenic amastigote stage which was long-term cultured at 37 degrees C. No differences were observed between the growth rates of axenic amastigotes and promastigotes. Flow cytometry-derived DNA histograms of axenic amastigotes and promastigotes were typical of exponentially growing cell populations. Moreover, axenic amastigotes were metabolically active as evidenced by the release of an immunoprecipitable extracellular acid phosphatase (SAcP) into their culture supernatant. Cell transformation was confirmed by transmission electronmicroscopic examination of thin sections and extended by fracture-flip survey which allowed differentiation of cell membranes. The ultrastructure and nanoanatomy of axenic amastigotes was identical to that of intracellular amastigotes. The production of large amounts of heat-shock axenic amastigotes suitable for biochemical and biological studies of differentiation in Leishmania donovani may have important implications in the development of prevention and/or treatment strategies.

Heat shock proteins in host-parasite interactions

For most living organisms, heat shock represents an unusual stress situation, but for parasites that are transmitted between invertebrate vectors and mammalian hosts it is a frequent physiological occurrence. Because of the extraordinary conservation of heat shock proteins (HSPs) and their potential immunogenicity, much attention has recently focused on the role of HSPs in infection and immunity. In parasites, HSPs appear to play specific functions in differentiation, in protection from the host cell's killing mechanisms, including oxygen free radicals, and even in virulence. In this article, Barbara Polla uses the example of malaria to illustrate the possible role of HSPs in host-parasite relationships.

Effects of culture age and hexoses on fatty acid oxidation by Leishmania major

The effect of culture age on the rate of oxidation of short-, medium, and long-chain fatty acids by Leishmania major promastigotes was investigated. Promastigotes from 5-day stationary phase cultures oxidized several saturated fatty acids about 3-to-4-fold faster than cells from late log phase cultures, but [10-14C]oleate was oxidized 9-fold faster. The increase in rate of oxidation was partially reversed within 5 h and almost completely reversed within 30 h after resuspending cells from a 5-day stationary culture in fresh medium. Addition of acetate, leucine, or alanine caused moderate inhibitions of [1-14C]palmitate oxidation, while glycerol had little effect. Glucose, however, was a powerful inhibitor of the oxidation of [1-14C]palmitate and of [1-14C]octanoate. Mannose and fructose were also strong inhibitors of palmitate oxidation, but neither galactose, 2-deoxyglucose or 6-deoxyglucose caused appreciable inhibition. The extent of inhibition by acetate increased with increasing culture age, whereas inhibition by glucose decreased. In addition to demonstrating a reversible rise in beta-oxidation capacity with culture age, these data also demonstrate a hitherto unrecognized strong and culture age-dependent inhibition of fatty acid oxidation by glucose.

Changes in the antigenic profile of Leishmania parasites following shifts in temperature

We have examined by immunoblotting the antigen profiles of Leishmania parasites which have undergone upward shifts in ambient temperature during culture. Parasites in the promastigote insect vector stage were grown to stationary growth phase at 25 degrees C, and then further cultured at the 37 degrees C temperature experienced in the mammalian host. Changes in the immunoblot profiles of the parasites occurred within one day of culture at mammalian ambient temperature. Serum antibodies from patients with active Leishmania infections showed reactivity with antigenic determinants of greater than Mr 38,000 that were expressed by parasites at 37 degrees C, and which were not comparably observed on immunoblots of 25 degrees C cultured organisms. The promastigotes of Leishmania species which cause either cutaneous or visceral leishmaniasis express differing forms of the 37 degrees C induced high molecular weight determinants, however, these molecules express cross-reactive epitopes. Previous studies have suggested that temperature may play a role in the differentiation process between the insect and host life cycle stages of Leishmania. Our results suggest that the antigenic profile of Leishmania parasites may also be affected by the expression of products from temperature sensitive biosynthetic pathways.

Extracellular cultivation and morphological characterization of amastigote-like forms of Leishmania panamensis and L. braziliensis

Two strains of the Leishmania braziliensis complex have been adapted to grow extracellularly at elevated temperature as amastigote-like forms in a cell-free medium. These parasites can be serially cultivated and maintained at 32 degrees C for L. panamensis (WR442; L. braziliensis panamensis) and at 28 degrees C for L. braziliensis (M5052; L. braziliensis braziliensis). Several observations are presented that the forms adapted at elevated temperature are amastigote-like. Morphologically, the amastigote-like organisms appear rounded to ovoid and are immotile and smaller than promastigotes; the flagellum of the amastigote-like forms does not extend beyond the flagellar pocket. In comparison, the promastigotes are very elongated, with a nucleus at mid-cell length and a very long flagellum. By electron microscopy, the short flagellum of the amastigote-like form is within a distended flagellar pocket; the 9 + 2 axonemal configuration is present but the paraxial rod is not observed. By contrast, the flagellum of the promastigote has a paraxial rod which extends from the axosome level. In addition, these amastigote-like forms of Leishmania are able to infect, to survive and to divide within the macrophage cell line J774.

Parasite heat-shock proteins

Many parasites, including most of those of medical or veterinary importance, experience a major increase in ambient temperature at some stage during their life cycle. This occurs when a cyst or free-living larval form is ingested by a warm-blooded host, when a poikilotherm-infecting parasite is transmitted to a homeotherm, or when a transiently free-living invasive larva penetrates the skin of a mammal. This sudden change in temperature could be expected to stress the intruder, as it should dramatically alter rates of metabolic reactions and of denaturation of proteins. This would especially affect the function of near-equilibrium, regulatory, and membrane-bound enzymes (changes in temperature affect membrane fluidity). In this article George Newport, Janice Culpepper and Nina Agabian consider how parasites cope with this problem, emphasizing the possible role of heat-shock proteins (HSPs), how the expression of these molecules is regulate, and how HSPs interact with the host immune system.