Plasmodium falciparum: Attenuation by irradiation

The effect of irradiation on the in vitro growth of Plasmodium falciparum was investigated. The cultured malarial parasites at selected stages of development were exposed to gamma rays and the sensitivity of each stage was determined. The stages most sensitive to irradiation were the ring forms and the early trophozoites; late trophozoites were relatively insensitive. The greatest resistance was shown when parasites were irradiated at a time of transition from the late trophozoite and schizont stages to young ring forms. The characteristics of radiosensitive variation in the parasite cycle resembled that of mammalian cells. Growth curves of parasites exposed to doses of irradiation upto 150 gray had the same slope as nonirradiated controls but parasites which were exposed to 200 gray exhibited a growth curve which was less steep than that for parasites in other groups. Less than 10 organisms survived from the 10⁶ parasites exposed to this high dose of irradiation; the possibility exists of obtaining radiation-attenuated P. falciparum.     

Plasmodium falciparum: synchronization of asexual development with aphidicolin, a DNA synthesis inhibitor

The asexual development cycle of Plasmodium falciparum, a malarial parasite of humans, has been synchronized in culture by treating ring-stage parasites with aphidicolin, an inhibitor of DNA synthesis. Optimization of both the concentration of drug added to ring stage containing red blood cells and the duration of exposure of parasites to drug led to a reversible block of their maturation at the early trophozoite stage. Release of the aphidicolin block led to a synchronous development of parasites that was manifested by about 80% of the new ring stages being produced within a 2- to 3-hr interval.     

Stage-dependent effects of chloroquine on Plasmodium falciparum in vitro

The erythrocytic developmental cycle of Plasmodium falciparum can be conveniently divided into the ring, trophozoite, and schizont stages based on morphology and metabolism. Using highly synchronous cultures of P. falciparum, considerable variation was demonstrated among these stages in sensitivity to chloroquine. The effects of timed, sequential exposure to several clinically relevant concentrations of chloroquine were monitored by three techniques: morphological analysis, changes in the rate of glucose consumption, and changes in the incorporation of 3H-hypoxanthine into parasite nucleic acids. All three techniques gave essentially identical results. The trophozoite and schizont stages were considerably more sensitive to the drug than ring-stage parasites. Chloroquine sensitivity decreased as nuclear division neared completion. The increase in chloroquine sensitivity was coincident with a marked rise in the rate of glucose consumption and nucleic acid synthesis. The rate of nucleic acid synthesis decreased as schizogony progressed while glucose consumption continued at high rates during this process. The degree of chloroquine sensitivity was not highly correlated with either metabolic activity.     

Entamoeba invadens: restriction of ploidy by colonic short chain fatty acids

The DNA content of Entamoeba parasites appears to be regulated by an unusual mechanism. This conclusion, however, was based on experiments that examined parasites grown in media that did not contain short chain fatty acids (SCFAs) normally found in the colonic lumen. Since one of these SCFAs, butyrate, is known to affect DNA replication in eukaryotic cells, we examined the effect of SCFAs on Entamoeba trophozoite DNA content. Similar to reports from others, we found that Entamoeba invadens trophozoite cultures grown in conventional medium (TYI-S-33) contained cells with 2N, 4N, 8N, and 16N amounts of DNA. In contrast, cultures grown in TYI medium containing colonic SCFAs added in place of glucose contained a minor population with 2N, a major population with 4N, and very few cells with higher amounts of DNA. SCFAs also prevented the normal increase in the number of nuclei per cell in trophozoites that were induced to encyst. These results suggest that E. invadens trophozoite stage parasites growing in the intestine in the presence of high amounts of SCFAs have a ploidy range restricted to 2N/4N. Axenic growth of trophozoites in the absence of SCFAs, however, appears to allow trophozoites to increase the amount of DNA per cell, which they must do during the normal encystment process.     

Stage-Dependent Effects of Chloroquine on Plasmodium falciparum In Vitro1

The erythrocytic developmental cycle of Plasmodium falciparum can be conveniently divided into the ring, trophozoite, and schizont stages based on morphology and metabolism. Using highly synchronous cultures of P. falciparum, considerable variation was demonstrated among these stages in sensitivity to chloroquine. The effects of timed, sequential exposure to several clinically relevant concentrations of chloroquine were monitored by three techniques: morphological analysis, changes in the rate of glucose consumption, and changes in the incorporation of ³H-hypoxanthine into parasite nucleic acids. All three techniques gave essentially identical results. The trophozoite and schizont stages were considerably more sensitive to the drug than ring-stage parasites. Chloroquine sensitivity decreased as nuclear division neared completion. The increase in chloroquine sensitivity was coincident with a marked rise in the rate of glucose consumption and nucleic acid synthesis. The rate of nucleic acid synthesis decreased as schizogony progressed while glucose consumption continued at high rates during this process. The degree of chloroquine sensitivity was not highly correlated with either metabolic activity.     

Plasmodium falciparum origin recognition complex subunit 5: functional characterization and role in DNA replication foci formation

The mechanism of DNA replication initiation and progression is poorly understood in the parasites, including human malaria parasite Plasmodium falciparum . Using bioinformatics tools and yeast complementation assay, we identified a putative homologue of Saccharomyces cerevisiae o rigin r ecognition c omplex subunit 5 in P. falciparum (PfORC5). PfORC5 forms distinct nuclear foci colocalized with the replication foci marker proliferating cell nuclear antigen (PfPCNA) and co-immunoprecipitates with PCNA during early-to-mid trophozoite stage replicating parasites. Interestingly, these proteins separate from each other at the non-replicating late schizont stage, citing the evidence of the presence of both PCNA and ORC components in replication foci during eukaryotic DNA replication. PfORC1, another ORC subunit, colocalizes with PfPCNA and PfORC5 at the beginning of DNA replication, but gets degraded at the late schizont stage, ensuring the regulation of DNA replication in the parasites. Further, we have identified putative PCNA-interacting protein box in PfORC1 that may explain in part the colocalization of PfORC and PfPCNA. Additionally, use of specific DNA replication inhibitor hydroxyurea affects ORC5/PCNA foci formation and parasitic growth. These results strongly favour replication factory model in the parasites and confer great potential to understand the co-ordination between ORC and PCNA during eukaryotic DNA replication in general.     

Plasmodium falciparum: synchronization of cultures with DL-alpha-difluoromethylornithine, an inhibitor of polyamine biosynthesis

DL-alpha-Difluoromethylornithine, an inhibitor of polyamine biosynthesis, was tested for its ability to synchronize Plasmodium falciparum. Asynchronous cultures were pretreated with sorbitol and incubated for 28-30 hr. Then, when cultures consisted of mainly schizont stage parasites, DL-alpha-difluoromethylornithine was added to the growth medium for another 38-47 hr of incubation. Putrescine was added to parasites arrested at the early trophozoite stage. This resulted in a synchronous resumption of growth. After 19 hr, 83% of parasites were at the schizont stage. After 30 hr, more than 98% of the parasites were in the ring form stage. Furthermore, the transformation of early trophozoites to schizonts occurred within 3 hr, with a slight reduction in parasitemia. Synchrony was maintained for 4-5 biological cycles as confirmed also by flow fluorimetry. It appears that this new approach to synchronize P. falciparum cultures is simple, reproducible, and effective.     

Scanning electron microscope-analysis of the protrusions (knobs) present on the surface of Plasmodium falciparum-infected erythrocytes

The nature of the surface deformations of erythrocytes infected with the human malaria parasite Plasmodium falciparum was analyzed using scanning electron microscopy at two stages of the 48-h parasite maturation cycle. Infected cells bearing trophozoite-stage parasites (24-36 h) had small protrusions (knobs), with diameters varying from 160 to 110 nm, and a density ranging from 10 to 35 knobs X micron-2. When parasites were fully mature (schizont stage, 40-44 h), knob size decreased (100-70 nm), whereas density increased (45-70 knobs X micron-2). Size and density of the knobs varied inversely, suggesting that knob production (a) occurred throughout intraerythrocytic parasite development from trophozoite to schizont and (b) was related to dynamic changes of the erythrocyte membrane. Variation in the distribution of the knobs over the red cell surface was observed during parasite maturation. At the early trophozoite stage of parasite development, knobs appeared to be formed in particular domains of the cell surface. As the density of knobs increased and they covered the entire cell surface, their lateral distribution was dispersive (more-than-random); this was particularly evident at the schizont stage. Regional surface patterns of knobs (rows, circles) were seen throughout parasite development. The nature of the dynamic changes that occurred at the red cell surface during knob formation, as well as the nonrandom distribution of knobs, suggested that the red cell cytoskeleton may have played a key role in knob formation and patterning.     

Stage-specific inhibitory effect of cyclic AMP on asexual maturation and gametocyte formation of Plasmodium falciparum

The effect of cyclic AMP on asexual maturation and gametocyte formation of Plasmodium falciparum grown in vitro was examined over a wide range of concentrations. Cyclic AMP inhibited both processes in a stage-specific manner. Asexual maturation was inhibited from shortly after parasite entry into the red cell through the ring stage. However, trophozoites and schizonts matured normally in the presence of cyclic AMP and produced infectious merozoites. Gametocyte formation was inhibited by 95% when 1.0 mM cyclic AMP was added to synchronously growing parasites in the ring stage of development but was only inhibited by 15% when added in the trophozoite or schizont stages. Cyclic AMP was not found to increase gametocyte formation over a wide range of concentrations.     

Cryo transmission X-ray imaging of the malaria parasite,P. falciparum

Cryo transmission X-ray microscopy in the “water window” of photon energies has recently been introduced as a method that exploits the natural contrast of biological samples. We have used cryo tomographic X-ray imaging of the intra-erythrocytic malaria parasite, Plasmodium falciparum, to undertake a survey of the cellular features of this important human pathogen. We examined whole hydrated cells at different stages of growth and defined some of the structures with different X-ray density, including the parasite nucleus, cytoplasm, digestive vacuole and the hemoglobin degradation product, hemozoin. As the parasite develops from an early cup-shaped morphology to a more rounded shape, puncta of hemozoin are formed; these coalesce in the mature trophozoite into a central compartment. In some trophozoite stage parasites we observed invaginations of the parasite surface and, using a selective permeabilization process, showed that these remain connected to the RBC cytoplasm. Some of these invaginations have large openings consistent with phagocytic structures and we observed independent endocytic vesicles in the parasite cytoplasm which appear to play a role in hemoglobin uptake. In schizont stage parasites staggered mitosis was observed and X-ray-dense lipid-rich structures were evident at their apical ends of the developing daughter cells. Treatment of parasites with the antimalarial drug artemisinin appears to affect parasite development and their ability to produce the hemoglobin breakdown product, hemozoin.     

Cell cycle analysis of asexual stages of erythrocytic malaria parasites

Abstract. Intra-erythrocytic Plasmodium species can be stained with the DNA binding dye, Hoechst 33342, and the distribution of DNA content determined for parasite populations by flow cytometric measurement of fluorescence. Analysis of this distribution will determine the parasitaemia (percentage of erythrocytes infected), and the percentages of trophozoite infected red blood cells, polyparasitized (trophozoite) red blood cells, and schizont/segmenter infected red blood cells. This analysis is based on the hypothesis that the asexual parasites cycle with single G₁ period, and effectively, a single S phase with no significant G₂/M period except at schizogony when the genome DNA content is equivalent to 8 N or higher, dependent on the species. Data are presented to support this model.     

Studies in vitro on mouse-egg radiosensitivity from fertilization up to the first cleavage

Super-ovulated eggs from the Balb/c strain were incubated, at various times after injection of HCG, in Whitten's medium containing tritiated thymidine. They were fixed on the following day at the 2-cell stage and prepared for autoradiography. On the basis of the results, pregnant mice were irradiated with various doses of X-rays at 15 h post HCG (fertilization), 19 h (phonuclear stage before DNA synthesis), 24 h (maximal DNA synthesis) and 27.5 h (DNA synthesis completed). On the day following irradiation, embryos were collected and classified into incleaved or 2-cell embryos, and development of the 2-cell embryos was followed in culture.

Irradiation was most effective when administered at 19 h after injection of HCG. Such a treatment increased the mortality before the first cleavage and, thereafter, from the 8-cell (100 rad) or morula stage (25, 50 rad). Blastocyst hatching and implantation were also impaired. Irradiation at other times was much less harmful for the embryos, which died mainly from the blastocyst stage. Finally, radiosensitivities of the mouse zygote at the various times studied can be estimated as follows: fertilization, + + +; pronuclear stage before DNA synthesis, + + + + +; maximal DNA synthesis, +; DNA synthesis terminated, + +.     

Pyrimidine de novo synthesis during the life cycle of the intraerythrocytic stage of Plasmodium falciparum

The 6 enzymes involved in de novo synthesis of pyrimidines were measured in Plasmodium falciparum isolated by saponin lysis from RBC's nonsynchronized and synchronized in vitro cultures. The total activities were found to be dependent on the stage of the P. falciparum cycle. In parasites isolated from synchronized cultures, the highest activities for all enzymes were found at about 27 hr after synchronization in the late trophozoite stage, or just before schizont formation. Merozoites and ring forms contained little de novo activity. The first enzyme of the pathway, carbamyl phosphate synthetase (CPS-II) preferentially utilized glutamine. Ammonia was a poor substrate. CPS-II was unstable in the absence of the cryoprotectants, dimethylsulfoxide and glycerol. The apparent Km for MgATP--was 3.8 +/- 0.7 mM and the enzyme in all morphological forms of P. falciparum (ring, mature trophozoites and schizonts) was inhibited by UTP. The activity of the fourth enzyme of the pathway, dihydroorotate dehydrogenase, appeared to be linked to the cell's respiratory chain; inhibitors of mammalian electron transport such as cyanide, amytal, antimycin A, thenoyltrifluoroacetone and ubiquinone analogs also inhibited the P. falciparum enzyme. The demonstration of the variation of activity of the pyrimidine enzymes correlates with the increased synthesis of nucleic acids in the late trophozoite stage. These observations provide a basis for the testing of the effectiveness of pyrimidine analogs as potential antimetabolites against various forms of the parasite.     

Treatment and prevention of Pneumocystis carinii pneumonia and further elucidation of the P. carinii life cycle with 1,3-beta-glucan synthesis inhibitor L-671,329.

Two different classes of 1,3-beta-glucan synthesis inhibitors, the echinocandins and papulacandins, have anti-Pneumocystis activity in an immunosuppressed rat model for acute P. carinii pneumonia (PCP). This activity combined with potent anti-Candida activity makes the echinocandins attractive agents for treating both Pneumocystis and candidiasis in the immunocompromised patient. Natural product echinocandin L-671,329 rapidly eliminates greater than 99% of the P. carinii cysts after 4 days of treatment at a dose of 1 mg/kg twice daily while 2-3 weeks of therapy with trimethoprimsulfamethoxazole (TMP-SMZ) or pentamidine was required to achieve the same degree of cyst clearance. Effects of L-671,329, TMP-SMZ and pentamidine on the trophozoite stage of P. carinii were also explored using a P. carinii-specific DNA probe to quantitate organism load. Although L-671,329 was not as effective as the known agents against the trophozoite stage, prophylactic use of L-671,329 at a daily dose of 1 mg/kg prevented the development of cysts and trophozoites in the rat model. The foamy exudate commonly seen in lungs of animals with PCP is also absent in rats receiving L-671,329 prophylaxis. In addition to demonstrating the potential of L-671,329 as a prophylactic agent these studies also help in elucidating the life cycle of P. carinii. The observation that L-671,329 prophylaxis prevents the appearance of trophozoites, while acute therapy does not directly affect trophozoites, provides the first evidence that the cyst stage is required for trophozoite proliferation. The rapid elimination of cysts by L-671,329 in animals with acute PCP also indicates that all cysts are turning over within 4 days since it is the development of new cysts which is prevented with this compound.     

Plasmodium falciparum: protease inhibitors and inhibition of erythrocyte invasion

Invasion of human red blood cells by Plasmodium falciparum is inhibited by the protease inhibitors, leupeptin and chymostatin. The efficacy of chymostatin was reduced if the cells were first treated with chymotrypsin. On the other hand, exposure of fresh cells to the supernatant from a synchronous culture at the reinvasion stage showed no such effect. This suggests that a proteolytic step occurs in the course of invasion and may be confined to the region of contact between the invading parasite and the erythrocyte. To test this, leupeptin or chymostatin was introduced into lysed cells, which were then resealed. The intracellular inhibitor strongly reduced invasion. Leupeptin also caused a striking effect on the development of the trophozoite stage of the parasites: a massive vacuole, apparently containing undigested haemoglobin, developed within the parasite. This did not totally stop development and the vacuolated parasites could be recovered in relatively pure form by lysis of the parasitised host cells with saponin.     

Plasmodium falciparum-infected erythrocytes: qualitative and quantitative analyses of parasite-induced knobs by atomic force microscopy

We used the combination of an atomic force microscope and a light microscope equipped with epifluorescence to serially image Plasmodium falciparum-infected erythrocytes. This procedure allowed us to determine unambiguously the presence and developmental stage of the malaria parasite as well as the number and size of knobs in singly, doubly, and triply infected erythrocytes. Knobs are not present during the ring stage of a malaria infection but a lesion resulting from invasion by a merozoite is clearly visible on the erythrocyte surface. This lesion is visible into the late trophozoite stage of infection. Knobs begin to form during the early trophozoite stage of infection and have a single-unit structure. Our data suggest the possibility that a two-unit structure of knobs, which was reported by Aikawa et al. (1996, Exp. Parasitol. 84, 339-343) using atomic force microscopy, appears to be a double-tipped image. The number of knobs per unit of host cell surface area is directly proportional to parasite number in both early and late trophozoite stages. These results indicate that knob formation by one parasite does not influence knob formation by other parasites in a multiply infected erythrocyte. In addition, knob volume is not influenced by either parasite stage or number at the late trophozoite stage, indicating that the number of component molecules per knob is constant throughout the parasite maturation process.     

Plasmodium ovale: in vitro development of hepatic stages

Primary cultures of human hepatocytes, a culture-derived clone from the human hepatoma Hep G2 line, and cultured rat hepatocytes were inoculated in vitro with Plasmodium ovale sporozoites extracted from Anopheles stephensi, An. gambiae, and An. dirus mosquitoes. Penetration and differentiation of P. ovale sporozoites into trophozoite stage parasites occurred in all three cell types, but with a lower transformation rate in the Hep G2 cell line than in the primary cultured hepatocytes. Further maturation was obtained only in the human hepatocytes, in which the parasites were uninucleate until the third day after infection, before development to 60 micron in length by the eighth day. Additionally, this culture system was used to assess the ability of an anti-P. ovale sporozoite monoclonal antibody to inhibit penetration of sporozoites into hepatocytes and to detect sporozoite determinants in the maturing liver stage parasites.     

Sensitivity of meiotic yeast cells to ultraviolet light

Sporulating cells of Saccharomyces cerevisiae show an increasing sensitivity to ultraviolet irradiation. Maximum sensitivity is reached at a time comparable to meiotic prophase. Sensitivity is expressed as reduced sporulation after the irradiation. The uv effect can be efficiently reversed by photoreactivating light. Viability is also more severely affected during premeiotic DNA synthesis and during meiosis than in earlier stages in sporulation. Cells left in sporulation medium after the irradiation show a reduced viability compared with the cells plated immediately after the irradiation. Non-sporulating diploids do not acquire sensitivity when exposed to sporulation medium, hence the sensitivity is related to the sporulation process. That meiosis itself is affected, rather than spore formation alone, is evident from experiments in which the uv irradiation interferes with the uncovering of a recessive marker and with commitment to meiosis. It is proposed that during meiotic prophase, the DNA repair system is different from that found in vegetative cells.