Eimeria tenella: Parasite-Specific Incorporation of 3H-Uracil as a Quantitative Measure of Intracellular Development1

ABSTRACT. An assay has been developed using parasite-specific incorporation of ³H-uracil to assess the intracellular growth of Eimeria tenella in vitro. As shown by both scintillation counts and autoradiography, ³H-uracil was incorporated specifically into intracellular parasites from the onset of infection and continued throughout development of the first generation schizonts. Mature schizonts and first generation merozoites did not continue to incorporate additional ³H-uracil, indicating that RNA synthesis had halted in these stages. Based on these findings, a semi-automated microscale uracil incorporation assay was developed to determine parasite viability. This method should be useful for biochemical studies with intracellular parasites and for screening compounds for anticoccidial activity. The ease, rapidity, and quantitative nature of this assay contrasts favorably with standard morphometric approaches of determining parasite development. In addition, parallel studies using host cell incorporation of ³H-uridine have been introduced as a method of determining whether antiparasitic activity is direct or indirect in relation to effects on the host cell.     

Development of Eimeria auburnensis in Cell Cultures

SYNOPSIS. Monolayer established cell line cultures of bovine kidney (Madin-Darby) and human intestine (Intestine 407), as well as embryonic bovine tracheal and embryonic spleen cell line cultures were inoculated with E. auburnensis sporozoites and observed for a maximum of 22 days. Mature 1st generation schizonts developed in the kidney, tracheal and spleen cells. In the intestine cells, trophozoites were seen in 3 of 4 experiments, but schizonts were not found. Sporozoites penetrated cells, beginning within a few minutes after inoculation. Penetration was usually accomplished within 10 seconds, and the body of the sporozoite underwent a slight constriction as it passed thru the host cell membrane. Some sporozoites left cells. Numerous intracellular sporozoites were observed in kidney, tracheal and spleen cultures. Crescent bodies were seen in the parasitophorous vacuole as early as 1 day after inoculation. At this time, the nuclei of most intracellular sporozoites had changed from vesicular to compact. Beginning 4 days after inoculation, enlarged sporozoites and parasites having a sporozoite shape, but with 2-5 nuclei, were frequently seen. These enlarged sporozoites and sporozoite-shaped schizonts evidently transformed into trophozoites and spheroidal schizonts by means of lateral outpocketings. Few trophozoites were seen. More immature schizonts developed in kidney cells than in the other cell types. The numbers of mature schizonts observed in kidney and tracheal cells were similar, but development occurred less consistently in the latter. Few immature and mature schizonts developed in spleen cells. Mature schizonts, first seen 9 days after inoculation, were considerably smaller than those reported from calves. Some motile merozoites were seen; evidently no development beyond these occurred. The nucleus and nucleolus of host cells were enlarged; this enlargement was not as pronounced as in infections in calves. Multiple host cell nuclei were frequently observed. Degenerative changes in the cultured cells and in the parasites usually occurred, beginning 9-17 days after inoculation; these were more pronounced in the spleen cells than in the others.     

Development of Eimeria tenella in MDBK cell culture with a note on enhancing effect of preincubation with chicken spleen cells

Eimeria tenella, an intracellular protozoan parasite infecting the epithelial cells of the ceca of chickens, causes severe diarrhea and bleeding that can lead its host to death. It is of interest that E. tenella first penetrate into the mucosal intraepithelial lymphocytes (IEL) before they parasitize crypt or villous epithelial cells. This in vitro study was undertaken to know whether the penetration of E. tenella into such a lymphoid cell is a beneficial step for the parasite survival and development. Three sequential experiments were performed. First, the in vitro established bovine kidney cell line, MDBK cells, were evaluated for use as host cells for E. tenella, through morphological observation. Second, the degree of parasite development and multiplication in MDBK cells was quantitatively assayed using radioisotope-labelled uracil (3H-uracil). Third, the E. tenella sporozoites viability was assayed after preincubation of them with chicken spleen cells. E. tenella o?cysts obtained from the ceca of the infected chickens were used for the source of the sporozoites. Spleen cells (E) obtained from normal chickens (FP strain) were preincubated with the sporozoites (T) at the E:T ratio of 100:1, 50:1 or 25:1 for 4 or 12 hours, and then the mixture was inoculated into the MDBK cell monolayer. Morphologically the infected MDBK cells revealed active schizogonic cycle of E. tenella in 3-4 days, which was characterized by the appearance of trophozoites, and immature and mature schizonts containing merozoites. The 3H-uracil uptake by E. tenella increased gradually in the MDBK cells, which made a plateau after 48-60 hours, and decreased thereafter. The uptake amount of 3H-uracil depended not only upon the inoculum size of the sporozoites but also on the degree of time delay (preincubation; sporozoites only) from excystation to inoculation into MDBK cells. The 3H-uracil uptake became lower as the preincubation time was prolonged. In comparison, after preincubation of sporozoites with spleen cells for 4 or 12 hours, the 3H-uracil uptake was significantly increased compared with that of control group. From the results, it was inferred that, although the penetration of E. tenella sporozoites into the lymphoid cells such as IEL is not an essential step, it should be at least a beneficial one for the survival and development of sporozoites in the chicken intestine.     

Secretory protein with RING finger domain (SPRING) specific to Trypanosoma cruzi is directed, as a ubiquitin ligase related protein, to the nucleus of host cells

While some intracellular bacterial and viral proteins secreted into host cell possess ubiquitin ligase (E3) activity for their profit, it has not been reported whether intracellular parasites secrete such molecules. We identified a gene that encodes a protein containing a secretory signal peptide and a RING finger domain in the intracellular protozoan parasite, Trypanosoma cruzi . This gene was specific to T. cruzi and was designated spring ( secretory p rotein with RING finger domain). An in vitro ubiquitination assay showed that SPRING possessed E3 activity in a RING finger domain-dependent manner. SPRING could utilize human ubiquitin-activating enzymes (E2), UbcH5 and UbcH13. Although SPRING was found to be a secretory protein, the signal peptide-cleaved mature form of SPRING was localized in the nucleus of host cells, indicating that SPRING may function in the host cell nuclei. Yeast two-hybrid screening identified 52 putative SPRING interactors in HeLa cells, suggesting that SPRING affects the stability or function of a number of host proteins. Furthermore, a co-immunoprecipitation assay showed that breast cancer-associated protein 3 interacted with SPRING, as well as being ubiquitinated by SPRING in vitro . These findings are the first to show that this protozoan parasite secretes an ubiquitin ligase-related protein into host cells.     

Development of Eimeria alabamensis from Cattle in Mammalian Cell Cultures*

SYNOPSIS. Monolayer primary cultures of cells from bovine embryonic intestine (BEInt), kidney (BEK), spleen (BES), and thyroid (BETy) and cell line cultures of embryonic bovine trachea (EBTr) and synovium (BESy) as well as established cell line cultures of bovine kidney (Madin-Darby, MDBK), human intestine (Int 407) and Syrian hamster kidney (BHK) were inoculated with freshly excysted sporozoites of Eimeria alabamensis and observed for 4–5 days. Sporozoites penetrated all cell types; during the 1st 24 hr, intracellular sporozoites, trophozoites and binucleate schizonts were seen in all cell cultures. Mature schizonts were more numerous in BES and MDBK cells than in the others. Large schizonts, 14.2 (11–18.5) by 10.2 μ (8.5–11), with 6–14 short, stubby merozoites (each with 2 refractile bodies) occurred at 2 and 3 days in all cells except BESy, Int 407, and BHK. Small schizonts, 9.7 (5.5–13) by 6 μ (5–8.5), with 6–10 long, slender merozoites (each with 2 refractile bodies) were found 3 days after inoculation in all cell types. At 4 days, some intracytoplasmic merozoites and a few intranuclear 2nd generation trophozoites were found. After 4 days post-inoculation, intracellular parasites were rarely seen and these were apparently degenerate. Development within the host cell nucleus, the normal site of development in the host animal, was observed infrequently in cell cultures. Intranuclear sporozoites, found no earlier than 2 days after inoculation, developed similarly to those in the cytoplasm, and small intranuclear schizonts with 6–10 merozoites (each with 2 refractile bodies) occurred after 3 days in culture.     

Actin‐mediated plasma membrane plasticity of the intracellular parasite Theileria annulata

Pathogen–host interactions are modulated at multiple levels by both the pathogen and the host cell. Modulation of host cell functions is particularly intriguing in the case of the intracellular Theileria parasite, which resides as a multinucleated schizont free in the cytosol of the host cell. Direct contact between the schizont plasma membrane and the cytoplasm enables the parasite to affect the function of host cell proteins through direct interaction or through the secretion of regulators. Structure and dynamics of the schizont plasma membrane are poorly understood and whether schizont membrane dynamics contribute to parasite propagation is not known. Here we show that the intracellular Theileria schizont can dynamically change its shape by actively extending filamentous membrane protrusions. We found that isolated schizonts bound monomeric tubulin and in vitro polymerized microtubules, and monomeric tubulin polymerized into dense assemblies at the parasite surface. However, we established that isolated Theileria schizonts free of host cell microtubules maintained a lobular morphology and extended filamentous protrusions, demonstrating that host microtubules are dispensable both forthe maintenance of lobular schizont morphology and for the generation of membrane protrusions. These protrusions resemble nanotubes and extend in an actin polymerization‐dependent manner; using cryo‐electron tomography, we detected thin actin filaments beneath these protrusions, indicating that their extension is driven by schizont actin polymerization. Thus the membrane of the schizont and its underlying actin cytoskeleton possess intrinsic activity for shape control and likely function as a peri‐organelle to interact with and manipulate host cell components.     

Specific labeling of intracellular Toxoplasma gondii with uracil.

Radioactive uracil was not significantly incorporated into the nucleic acids of human fibroblast cells. Infection of these cells with Toxoplasma gondii resulted in an exponential increase in the rate of uracil incorporation that paralleled the exponential growth of the parasite. One day after infection the rate of uracil incorporation was increased 100-fold. It was established by autoradiography that all of the [3H] uracil was incorporated into the intracellular parasites. A possible explanation for this difference in ability to use uracil is our observation that the specific activity of uridine phosphorylase was 100-fold greater in partially purified parasites than in the host cell.     

An assay of malaria parasite invasion into human erythrocytes. The effects of chemical and enzymatic modification of erythrocyte membrane components

Invasion of erythrocytes by malaria parasites is known to be blocked by proteolytic digestion of merozoite receptors allegedly present in red cell membranes. This information was used in the present work to develop a simple and convenient assay for parasite invasion into red blood cells and for evaluating the role played by red cell membrane components in this process. Synchronized in vitro cultures of Plasmodium falciparum containing only ring stages were subjected to either trypsin or pronase digestion, a treatment that neither affected ring development into schizonts nor mature merozoite release. Cells from this culture were not invaded by the released merozoites. However, upon addition of untreated human red blood cells, marked invasion was observed, either microscopically or as [3H]isoleucine incorporation. The new assay circumvents the need for separating schizonts from uninfected cells and provides a convenient means for assessing how chemical and biochemical manipulation of red blood cells affects their invasiveness by parasites. Using this assay, we verified that sheep and rabbit erythrocytes were resistant to invasion, as were human erythrocytes which had been treated with trypsin, pronase or neuraminidase. Chymotrypsin digestion of human erythrocytes was without effect on invasion. Human erythrocytes which were chemically modified with the impermeant amino reactive reagent H2DIDS, or with the crosslinker of spectrin, TCEA, were found to resist invasion. The results underscore the involvement of surface membrane components as well as of elements of the cytoskeleton in the process of parasite invasion into erythrocytes.     

A Plasmodium Phospholipase Is Involved in Disruption of the Liver Stage Parasitophorous Vacuole Membrane

The coordinated exit of intracellular pathogens from host cells is a process critical to the success and spread of an infection. While phospholipases have been shown to play important roles in bacteria host cell egress and virulence, their role in the release of intracellular eukaryotic parasites is largely unknown. We examined a malaria parasite protein with phospholipase activity and found it to be involved in hepatocyte egress. In hepatocytes, Plasmodium parasites are surrounded by a parasitophorous vacuole membrane (PVM), which must be disrupted before parasites are released into the blood. However, on a molecular basis, little is known about how the PVM is ruptured. We show that Plasmodium berghei phospholipase, PbPL, localizes to the PVM in infected hepatocytes. We provide evidence that parasites lacking PbPL undergo completely normal liver stage development until merozoites are produced but have a defect in egress from host hepatocytes. To investigate this further, we established a live-cell imaging-based assay, which enabled us to study the temporal dynamics of PVM rupture on a quantitative basis. Using this assay we could show that PbPL-deficient parasites exhibit impaired PVM rupture, resulting in delayed parasite egress. A wild-type phenotype could be re-established by gene complementation, demonstrating the specificity of the PbPL deletion phenotype. In conclusion, we have identified for the first time a Plasmodium phospholipase that is important for PVM rupture and in turn for parasite exit from the infected hepatocyte and therefore established a key role of a parasite phospholipase in egress.     

Effects of red blood cell potassium and hypertonicity on the growth of Plasmodium falciparum in culture

Malarial parasites reproduce asexually inside the erythrocytes of their vertebrate host. Relatively little is known about the interaction between host cell and parasite metabolism. In the present study the effect of host cell cation composition and osmotic shrinkage on in vitro growth and propagation of Plasmodium falciparum in human erythrocytes was investigated. It is shown that throughout the parasite cell cycle, infected cells lose potassium and gain sodium. Compartment analysis of infected cells revealed that host cell cytosol is poor in potassium and rich in sodium while in the parasite this relationship is reversed, indicating that the parasite is able to regulate its ionic composition independently. Parasites proceeded normally through their cell cycle in the presence of the sodium-pump inhibitor ouabain, although host cells lost up to 75-80% of their normal potassium content. Potassium-depleted erythrocytes harboring trophozoites and schizonts also display normal rates of protein synthesis as measured by isoleucine incorporation. Parasite growth was inhibited when infected cells were osmotically shrunken in hypertonic media, but this was not due to parasite dehydration. It is suggested that increased viscosity of host cell cytosol and/or hemoglobin gelation, are responsible for the effect, probably through interference with parasite feeding. The relevance of these results to understanding of the cellular mechanism involved in the inhibiton of parasite growth in deoxygenated sickle-trait erythrocytes is discussed.     

An assay of malaria parasite invasion into human erythrocytes: The effects of chemical and enzymatic modification of erythrocyte membrane components

Invasion of erythrocytes by malaria parasites is known to be blocked by proteolytic digestion of merozoite receptors allegedly present in red cell membranes. This information was used in the present work to develop a simple and convenient assay for parasite invasion into red blood cells and for evaluating the role played by red cell membrane components in this process. Synchronized in vitro cultures of Plasmodium falciparum containing only ring stages were subjected to either trypsin or pronase digestion, a treatment that neither affected ring development into schizonts nor mature merozoite release. Cells from this culture were not invaded by the released merozoites. However, upon addition of untreated human red blood cells, marked invasion was observed, either microscopically or as [³H]isoleucine incorporation. The new assay circumvents the need for separating schizonts from uninfected cells and provides a convenient means for assessing how chemical and biochemical manipulation of red blood cells affects their invasiveness by parasites. Using this assay, we verified that sheep and rabbit erythrocytes were resistant to invasion, as were human erythrocytes which had been treated with trypsin, pronase or neuraminidase. Chymotrypsin digestion of human erythrocytes was without effect on invasion. Human erythrocytes which were chemically modified with the impermeant amino reactive reagent H₂DIDS, or with the crosslinker of spectrin, TCEA, were found to resist invasion. The results underscore the involvement of surface membrane components as well as of elements of the cytoskeleton in the process of parasite invasion into erythrocytes.     

New roles for perforins and proteases in apicomplexan egress

Egress is a pivotal step in the life cycle of intracellular pathogens initiating the transition from an expiring host cell to a fresh target cell. While much attention has been focused on understanding cell invasion by intracellular pathogens, recent work is providing a new appreciation of mechanisms and therapeutic potential of microbial egress. This review highlights recent insight into cell egress by apicomplexan parasites and emerging contributions of membranolytic and proteolytic secretory products, along with host proteases. New findings suggest that Toxoplasma gondii secretes a pore-forming protein, TgPLP1, during egress that facilitates parasite escape from the cell by perforating the parasitophorous membrane. Also, in a cascade of proteolytic events, Plasmodium falciparum late-stage schizonts activate and secrete a subtilisin, PfSUB1, which processes enigmatic putative proteases called serine-repeat antigens that contribute to merozoite egress. A new report also suggests that calcium-activated host proteases called calpains aid parasite exit, possibly by acting upon the host cytoskeleton. Together these discoveries reveal important new molecular players involved in the principal steps of egress by apicomplexans.     

Developmental biology of Pneumocystis carinii, and alternative view on the life cycle of the parasite.

In this paper we present, based on elaborate ultrastructural studies, data on the existence of both intracellular and extracellular stages of Pneumocystis carinii, which result in a proposal of a new life cycle of the parasite. Up to now the formation of daughter cells in thick-walled pneumocysts is supposed to be the only way of multiplication. The present study shows that in rats treated with cortisone acetate the formation of daughter cells also takes place within thin-walled pneumocysts. In our opinion this way of multiplication is important for the understanding of the rapid increase in number of the parasites in an infected lung. The presence of pneumocysts inside the alveolar epithelial cells suggests that intracellular development of the parasites can occur, but the method of cell penetration, intracellular multiplication and parasite liberation is still unknown. Moreover our observations for the first time indicate a direct pathogenicity of the parasites in host cells.     

Specific Labeling of Intracellular Toxoplasma gondii with Uracil*

SYNOPSIS Radioactive uracil was not significantly incorporated into the nucleic acids of human fibroblast cells. Infection of these cells with Toxoplasma gondii resulted in an exponential increase in the rate of uracil incorporation that paralleled the exponential growth of the parasite. One day after infection the rate of uracil incorporation was increased 100-fold. It was established by autoradiography that all of the [³H] uracil was incorporated into the intracellular parasites. A possible explanation for this difference in ability to use uracil is our observation that the specific activity of uridine phosphorylase was 100-fold greater in partially purified parasites than in the host cell.     

Oligopeptidase B-dependent signaling mediates host cell invasion by Trypanosoma cruzi.

Mammalian cell invasion by the intracellular protozoan parasite Trypanosoma cruzi is mediated by recruitment and fusion of host cell lysosomes, an unusual process that has been proposed to be dependent on the ability of parasites to trigger intracellular free calcium concentration ([Ca2+]i) transients in host cells. Previous work implicated the T.cruzi serine hydrolase oligopeptidase B in the generation of Ca2+-signaling activity in parasite extracts. Here we show that deletion of the gene encoding oligopeptidase B results in a marked defect in host cell invasion and in the establishment of infections in mice. The invasion defect is associated with the inability of oligopeptidase B null mutant trypomastigotes to mobilize Ca2+ from thapsigargin-sensitive stores in mammalian cells. Exogenous recombinant oligopeptidase B reconstitutes the oligopeptidase B-dependent Ca2+ signaling activity in null mutant parasite extracts, demonstrating that this enzyme is responsible for the generation of a signaling agonist for mammalian cells.     

Plasmodium berghei: Osmotic fragility of malaria parasites and mouse host erythrocytes

The osmotic properties of intraerythrocytic and ultrasonically liberated malaria parasites (Plasmodium berghei) were analyzed and compared with those of mouse host erythrocytes utilizing a multiple tube fragility test. Cells were incubated in phosphate buffered saline solutions of varying osmolalities ranging from 20–4000 mOsm. Changes in cell ultrastructure and parasite infectivity were used as indicators of osmotic damage. Intraerythrocytic and host cell-free plasmodia showed similar patterns of cell alteration and changes in infectivity following osmotic stress. The various developmental forms within each of the preparations responded somewhat differently to hypo-osmotic stress, however. The majority of merozoites seemed to be more sensitive than many trophozoites, schizonts, and segmenters. Small trophozoites were, on the average, more resistant than other developmental forms. Incubation of parasite populations in hypotonic salt solutions with osmolalities slightly greater than the infectivity threshold of 100 mOsm lysed the majority of the merozoites, whereas many small trophozoites were still intact. While normal erythrocytes were more resistant to hypo-osmotic stress than were either intracellular or free parasites, the majority of parasitized erythrocytes was less resistant than normal erythrocytes. The predominant alteration induced by hyperosmotic stress appears in the parasite's nuclear region with myelination of the nuclear membranes and chromatin clumping. The infectivity threshold in the hypertonic range was found to be approximately 2500 mOsm. Results indicate that these obligate intracellular parasites have a wide range of osmotic sensitivities and that they are capable of existing for short periods in various osmotic environments ranging from 100–2500 mOsm without complete loss of infectivity. This suggests that these parasites have osmotic regulatory capabilities at least comparable to those of host cells.     

Targeting of host cell lineages by vertically transmitted, feminising microsporidia

Feminising microsporidian parasites are transmitted vertically from generation to generation of their crustacean hosts. Little is known about the mechanisms underpinning vertical transmission, in particular, parasite transmission to the host gonad during host development. Here, we investigate the burden and distribution of two species of vertically transmitted, feminising microsporidia (Dictyocoela duebenum and Nosema granulosis) during early embryogenesis (zygote to eight-cells) of the Gammarus duebeni host. Parasite burden differs between the two parasites with N. granulosis being higher by a factor of 10. Whilst D. duebenum replicates during the first few host cell divisions, there is no increase in N. granulosis burden. Only merogonic parasite stages were observed in the host embryo. Distribution of both parasites was non-random from the two-cell embryo stage, indicating biased parasite segregation at host cell division. Dictyocoela duebenum burden was low in the germline and somatic gonad progenitor cells but was highest in the ectoderm precursors, leading us to propose that the parasite targets these cells and then secondarily infects the gonad later in host development. Targeting by N. granulosis was less specific although there was a persistent bias in parasite distribution throughout host cell divisions. Parasite burden was highest in the ectoderm precursors as well as the germline progenitors leading us to suggest that, in addition to using the ectodermal route, N. granulosis may also target germline directly. Biased segregation will be adaptive for these parasites as it is likely to lead to efficient transmission and feminisation whilst minimising virulence in the host.     

Purine and Pyrimidine Synthesis by the Avian Malaria Parasite,Plasmodium lophurae*

SYNOPSIS. Purine and pyrimidine biosynthesis in the avian malaria parasite Plasmodium lophurae and its host cell, the duck erythrocyte, were investigated in vitro. Pyrimidine synthesis, as measured by the incorporation of C¹⁴-NaHCO₃ into cytosine, uracil and thymine was slight in uninfected duck erythrocytes, whereas infected erythrocytes and erythrocyte-free parasites had high rates of incorporation of NaHCO₃ into these bases. In addition, orotidine-5′-monophosphate pyrophosphorylase and thymidylate synthetase, 2 enzymes of the pyrimidine biosynthetic pathway, were found in cell-free extracts of the plasmodia. Purine synthesis was measured by determining the extent of incorporation of C¹⁴-Na-formate into adenine and guanine. Uninfected and infected erythrocytes had similar rates of Na-formate incroporation into adenine. whereas free parasites incorporated little of this compound into adenine, or guanine. On the other hand, the incorporation of Na-formate into guanine was 54% higher in infected erythrocytes than in uninfected erythrocytes. It is suggested that P. lophurae synthesizes purines to a limited extent, and derives most of its purines from the host erythrocyte. The greater incorporation of Na-formate into guanine by infected cells, and its low incorporation into free parasites may be accounted for by parasite conversion of host cell adenine (in the form of ATP) into guanine. Pyrimidine biosynthesis in infected cells can be accounted for by de novo synthesis by the parasite itself.     

A Novel Fluorescent Labeling Method Enables Monitoring of Spatio‐Temporal Dynamics of Developing Microsporidia

The microsporidium, Anncaliia algerae (Brachiola algerae), is a eukaryotic obligate intracellular parasite first isolated from mosquitoes and is an important opportunistic human pathogen that can cause morbidity and mortality among immune‐compromised individuals including patients with AIDS and those undergoing chemotherapy. There is little known about the Microsporidia–host cell interface in living host cells, due to current approaches being limited by the lack of fluorescent reporters for detecting the parasite lifecycle. Here, we have developed and applied novel vital fluorescent parasite labeling methodologies in conjunction with fluorescent protein‐tagged reporters to track simultaneously the dynamics of both parasite and host cell specific components, including the secretory and endocytic trafficking pathways, during the entire infection time period. We have found dramatic changes in the dynamics of host secretory trafficking organelles during the course of infection. The Golgi compartment is gradually disassembled and regenerated into mini‐Golgi structures in parallel with cellular microtubule depolymerization. Importantly, we find that Microsporidia progeny are associated with these de novo formed mini‐Golgi structures. These host structures appear to create a membrane bound niche environment for parasite development. Our studies presented here provide novel imaging tools and methodologies that will facilitate in understanding the biology of microsporidial parasites in the living host.     

An image-based high-content screening assay for compounds targeting intracellular Leishmania donovani amastigotes in human macrophages

Leishmaniasis is a tropical disease threatening 350 million people from endemic regions. The available drugs for treatment are inadequate, with limitations such as serious side effects, parasite resistance or high cost. Driven by this need for new drugs, we developed a high-content, high-throughput image-based screening assay targeting the intracellular amastigote stage of different species of Leishmania in infected human macrophages. The in vitro infection protocol was adapted to a 384-well-plate format, enabling acquisition of a large amount of readouts by automated confocal microscopy. The reading method was based on DNA staining and required the development of a customized algorithm to analyze the images, which enabled the use of non-modified parasites. The automated analysis generated parameters used to quantify compound activity, including infection ratio as well as the number of intracellular amastigote parasites and yielded cytotoxicity information based on the number of host cells. Comparison of this assay with one that used the promastigote form to screen 26,500 compounds showed that 50% of the hits selected against the intracellular amastigote were not selected in the promastigote screening. These data corroborate the idea that the intracellular amastigote form of the parasite is the most appropriate to be used in primary screening assay for Leishmania.