Asako Haraguchi scite author profile

Antibodies to Encephalitozoon cuniculi were examined by enzyme-linked immunosorbent assay using E. cuniculi PTP2 recombinant protein and by Western blot analysis on a total of 472 dog serum samples that had been collected in Japan. Of these samples, 21.8% (103/472) had antibodies against E. cuniculi. Each of 5 serum samples that showed high (>1.0) or low (<0.1) OD value was selected randomly and further examined by Western blot using E. cuniculi-native antigens. All samples with high OD values reacted with specific E. cuniculi proteins, including an antigen of approximately 35 kDa corresponding with PTP2; sera with low OD values did not recognize this E. cuniculi band. This study is the first to demonstrate the prevalence of E. cuniculi infection in dogs in Japan.

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Role of Plasmodium berghei ookinete surface and oocyst capsule protein, a novel oocyst capsule-associated protein, in ookinete motility

Nakayama

Kimura

Kitahara

et al. 2021

Parasites Vectors

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Background Plasmodium sp., which causes malaria, must first develop in mosquitoes before being transmitted. Upon ingesting infected blood, gametes form in the mosquito lumen, followed by fertilization and differentiation of the resulting zygotes into motile ookinetes. Within 24 h of blood ingestion, these ookinetes traverse mosquito epithelial cells and lodge below the midgut basal lamina, where they differentiate into sessile oocysts that are protected by a capsule. Methods We identified an ookinete surface and oocyst capsule protein (OSCP) that is involved in ookinete motility as well as oocyst capsule formation. Results We found that knockout of OSCP in parasite decreases ookinete gliding motility and gradually reduces the number of oocysts. On day 15 after blood ingestion, the oocyst wall was significantly thinner. Moreover, adding anti-OSCP antibodies decreased the gliding speed of wild-type ookinetes in vitro. Adding anti-OSCP antibodies to an infected blood meal also resulted in decreased oocyst formation. Conclusion These findings may be useful for the development of a transmission-blocking tool for malaria. Graphical abstract

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Formation of free oocysts in <i>Anopheles</i> mosquitoes injected with <i>Plasmodium</i> ookinetes

Haraguchi

Takano

Hakozaki

et al. 2023

The Journal of Veterinary Medical Science

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Malaria needs new strategies for its control. Plasmodium spp., the causative agent of malaria, is transmitted by mosquitoes. These parasites develop into oocysts and sporozoites in the body of the mosquitoes. A deeper understanding of oocysts that produce the infectious form of the parasite, sporozoites, can facilitate the development of novel countermeasures. However, the isolation of Plasmodium oocysts is challenging as these are formed between midgut epithelial cells and basal lamina after gametocytes enter the mosquito’s body through blood feeding. Further research on oocysts has been impeded by issues related to oocyst isolation. Therefore, in this study, we injected Plasmodium into mosquitoes—an artificial and unique method—and aimed to clarify how oocysts were formed in mosquitoes after Plasmodium injection and whether free oocysts were formed from the mosquito tissue. Plasmodium berghei (ANKA strain) ookinetes cultured in vitro were injected into the thoracic body cavity (hemocoel) of female and male Anopheles stephensi mosquitoes. Oocysts were formed in the body of female and male mosquitoes at 14 days post injection. In addition, oocysts formed as a result of injection developed into sporozoites, which were infectious to mice. These findings suggest that P. berghei can complete its developmental stage in mosquitoes by injection. Some of the oocysts formed were free from mosquito tissue, and it was possible to collect oocysts with minimal contamination of mosquito tissue. These free oocysts can be used for investigating oocyst proteins and metabolism.

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Role of Plasmodium berghei ookinete surface and oocyst capsule protein, a novel oocyst capsule-associated protein, in ookinete motility

Nakayama

Kimura

Kitahara

et al. 2021

Preprint

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Background: Plasmodium sp., which causes malaria, must first develop in mosquitoes before being transmitted. Upon ingesting infected blood, gametes form in the mosquito lumen, followed by fertilization and differentiation of the resulting zygotes into motile ookinetes. Within 24 hours of blood ingestion, these ookinetes traverse mosquito epithelial cells and lodge below the midgut basal lamina, where they differentiate into sessile oocysts that are protected by a capsule. Methods: We identified an ookinete surface and oocyst capsule protein (OSCP) that is involved in ookinete motility as well as oocyst capsule formation. Results: We found that knockout of OSCP in parasite decreases ookinete gliding motility and gradually reduces the number of oocysts. On day 15 after blood ingestion, the oocyst wall was significantly thinner. Moreover, adding anti-OSCP antibodies decreased the gliding speed of wild type ookinetes in vitro. Adding anti-OSCP antibodies to an infected blood meal also resulted in decreased oocyst formation. Conclusion: These findings may be useful for the development of transmission-blocking tools for malaria.

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Plasmodium berghei Brca2 is required for normal development and differentiation in mice and mosquitoes

et al. 2022

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Background Malaria is a major global parasitic disease caused by species of the genus Plasmodium. Zygotes of Plasmodium spp. undergo meiosis and develop into tetraploid ookinetes, which differentiate into oocysts that undergo sporogony. Homologous recombination (HR) occurs during meiosis and introduces genetic variation. However, the mechanisms of HR in Plasmodium are unclear. In humans, the recombinases DNA repair protein Rad51 homolog 1 (Rad51) and DNA meiotic recombinase 1 (Dmc1) are required for HR and are regulated by breast cancer susceptibility protein 2 (BRCA2). Most eukaryotes harbor BRCA2 homologs. Nevertheless, these have not been reported for Plasmodium. Methods A Brca2 candidate was salvaged from a database to identify Brca2 homologs in Plasmodium. To confirm that the candidate protein was Brca2, interaction activity between Plasmodium berghei (Pb) Brca2 (PbBrca2) and Rad51 (PbRad51) was investigated using a mammalian two-hybrid assay. To elucidate the functions of PbBrca2, PbBrca2 was knocked out and parasite proliferation and differentiation were assessed in mice and mosquitoes. Transmission electron microscopy was used to identify sporogony. Results The candidate protein was conserved among Plasmodium species, and it was indicated that it harbors critical BRCA2 domains including BRC repeats, tower, and oligonucleotide/oligosaccharide-binding-fold domains. The P. berghei BRC repeats interacted with PbRad51. Hence, the candidate was considered a Brca2 homolog. PbBrca2 knockout parasites were associated with reduced parasitemia with increased ring stage and decreased trophozoite stage counts, gametocytemia, female gametocyte ratio, oocyst number, and ookinete development in both mice and mosquitoes. Nevertheless, the morphology of the blood stages in mice and the ookinete stage was comparable to those of the wild type parasites. Transmission electron microscopy results showed that sporogony never progressed in Brca2-knockout parasites. Conclusions Brca2 is implicated in nearly all Plasmodium life cycle stages, and especially in sporogony. PbBrca2 contributes to HR during meiosis. Graphical Abstract

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Asako Haraguchi

Serological Survey of Encephalitozoon cuniculi Infection in Japanese Dogs

Role of Plasmodium berghei ookinete surface and oocyst capsule protein, a novel oocyst capsule-associated protein, in ookinete motility

Formation of free oocysts in <i>Anopheles</i> mosquitoes injected with <i>Plasmodium</i> ookinetes

Role of Plasmodium berghei ookinete surface and oocyst capsule protein, a novel oocyst capsule-associated protein, in ookinete motility

Plasmodium berghei Brca2 is required for normal development and differentiation in mice and mosquitoes

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