Phytohormones regulate asexual Toxoplasma gondii replication.

The protozoan Toxoplasma gondii (T. gondii) is a zoonotic disease agent causing systemic infection in warm-blooded intermediate hosts including humans. During the acute infection, the parasite infects host cells and multiplies intracellularly in the asexual tachyzoite stage. In this stage of the life cycle, invasion, multiplication, and egress are the most critical events in parasite replication. T. gondii features diverse cell organelles to support these processes, including the apicoplast, an endosymbiont-derived vestigial plastid originating from an alga ancestor. Previous studies have highlighted that phytohormones can modify the calcium-mediated secretion, e.g., of adhesins involved in parasite movement and cell invasion processes. The present study aimed to elucidate the influence of different plant hormones on the replication of asexual tachyzoites in a human foreskin fibroblast (HFF) host cell culture. T. gondii replication was measured by the determination of T. gondii DNA copies via qPCR. Three selected phytohormones, namely abscisic acid (ABA), gibberellic acid (GIBB), and kinetin (KIN) as representatives of different plant hormone groups were tested. Moreover, the influence of typical cell culture media components on the phytohormone effects was assessed. Our results indicate that ABA is able to induce a significant increase of T. gondii DNA copies in a typical supplemented cell culture medium when applied in concentrations of 20 ng/µl or 2 ng/µl, respectively. In contrast, depending on the culture medium composition, GIBB may potentially serve as T. gondii growth inhibitor and may be further investigated as a potential treatment for toxoplasmosis.

Correlative light and electron microscopy of wall formation in Eimeria nieschulzi.

Coccidian parasites possess complex life cycles involving asexual proliferation followed by sexual development leading to the production of oocysts. Coccidian oocysts are persistent stages which are secreted by the feces and transmitted from host to host guaranteeing life cycle progression and disease transmission. The robust bilayered oocyst wall is formed from the contents of two organelles, the wall-forming bodies type I and II (WFBI, WFBII), located exclusively in the macrogametocyte. Eimeria nieschulzi has been used as a model parasite to study and follow gametocyte and oocyst development. In this study, the gametocyte and oocyst wall formation of E. nieschulzi was analyzed by electron microscopy and immuno-histology. A monoclonal antibody raised against the macrogametocytes of E. nieschulzi identified a tyrosine-rich glycoprotein (EnGAM82) located in WFBII. Correlative light and electron microscopy was used to examine the vesicle-specific localization and spatial distribution of GAM82-proteins during macrogametocyte maturation by this monoclonal antibody. In early and mid-stages, the GAM82-protein is ubiquitously distributed in WFBII. Few hours later, the protein is arranged in subvesicular structures. It was possible to show that the substructure of WFBII and the spatial distribution of GAM82-proteins probably represent pre-synthesized cross-linked materials prior to the inner oocyst wall formation. Dityrosine-cross-linked gametocyte proteins can also be confirmed and visualized by fluorescence microscopy (UV light, autofluorescence of WFBII).

Risk Evaluation of Passive Transmission of Animal Parasites by Feeding of Black Soldier Fly (Hermetia illucens) Larvae and Prepupae.

HIGHLIGHTS: Black soldier fly larval intestine extracts do not affect coccidian oocysts or nematode eggs. Studied parasites passed through black soldier fly larvae or attached to the larval surface. Black soldier fly larvae as animal feed may pose a risk of parasite transmission. Larval washing is not sufficient for removing parasites; further hygiene steps are needed.

Distribution and Processing of Eimeria nieschulzi OWP13, a New Protein of the COWP Family.

Eimeria species are important veterinary coccidian parasites and are transmitted between hosts via oocysts. The infectious sporozoites are protected by the oocyst and sporocyst wall. Tyrosine-rich proteins are well-known components of the Eimeria oocyst wall. Recently, cysteine motif containing proteins (COWP family), as described in Toxoplasma gondii and Cryptosporidium spp., have also been characterized in Eimeria. Here, we identified a novel COWP-related protein, EnOWP13, and tracked it via transfection technology in Eimeria nieschulzi. The subsequent analysis suggests that the mCherry-tagged EnOWP13 localizes to the wall-forming bodies I and the outer wall. Immunohistochemical analysis confirmed the distribution of wall-forming bodies similar to avian Eimeria species and revealed that the wall-forming bodies I show peroxidase activity. The EnOWP13 amino acid composition and FITC-cadaverine-positive wall-forming bodies I suggest a participation of an enzyme with transglutaminase activity. This is the first description and characterization of this novel outer oocyst wall protein, which is also orthologous to other Eimeria species and Toxoplasma gondii, suggesting a new potential cross-linking mechanism of wall-forming proteins via isopeptide bonds.

Identification and analysis of Eimeria nieschulzi gametocyte genes reveal splicing events of gam genes and conserved motifs in the wall-forming proteins within the genus Eimeria (Coccidia, Apicomplexa).

The genus Eimeria (Apicomplexa, Coccidia) provides a wide range of different species with different hosts to study common and variable features within the genus and its species. A common characteristic of all known Eimeria species is the oocyst, the infectious stage where its life cycle starts and ends. In our study, we utilized Eimeria nieschulzi as a model organism. This rat-specific parasite has complex oocyst morphology and can be transfected and even cultivated in vitro up to the oocyst stage. We wanted to elucidate how the known oocyst wall-forming proteins are preserved in this rodent Eimeria species compared to other Eimeria. In newly obtained genomics data, we were able to identify different gametocyte genes that are orthologous to already known gam genes involved in the oocyst wall formation of avian Eimeria species. These genes appeared putatively as single exon genes, but cDNA analysis showed alternative splicing events in the transcripts. The analysis of the translated sequence revealed different conserved motifs but also dissimilar regions in GAM proteins, as well as polymorphic regions. The occurrence of an underrepresented gam56 gene version suggests the existence of a second distinct E. nieschulzi genotype within the E. nieschulzi Landers isolate that we maintain.

Passive immunization with Eimeria tenella gametocyte antigen 56 (EtGAM56) specific antibodies and active immunization trial with the epitope containing peptide.

Eimeria species cause avian coccidiosis leading to substantial economic losses in the poultry industry. Hence, anticoccidial drugs and vaccines have been used to combat this devitalizing disease. An effective vaccine based on gametocyte recombinant proteins would be very useful in terms of cost, labor and ethics (no animal experimentation). A mouse derived monoclonal antibody against Eimeria tenella gametocyte antigen 56 (EtGAM56) was used to immunize peritoneally E. tenella infected chicken a reduction of oocyst shedding by up to 78% was observed. The epitope recognized by the monoclonal antibody was mapped, recombinant expressed and used to immunize chicken (rEtGAM56N). After rEtGAM56N intramuscular immunization and parasite challenge, clinical parameters like faecal oocyst output, body weight gain, lesion score, feed conversion rate and serum antibody response were assessed to test the efficacy of vaccination against experimental infection with E. tenella. Chicken immunized with rEtGAM56N and challenged with E. tenella oocysts showed a robust antibody response against the rEtGAM56N peptide but no considerable effects on oocyst output and clinical parameters (weight gain, lesion score, feed conversion rate) compared to the mock control group. This study demonstrates the complexity of an effective vaccination. The immunoprotective epitope might be a conformational epitope that was recognized by the monoclonal mouse antibody but only weakly by the antibodies produced against the linear peptide leading to a divergent outcome between the passive and active immunization.

Development of Eimeria nieschulzi (Coccidia, Apicomplexa) Gamonts and Oocysts in Primary Fetal Rat Cells.

The in vitro production of gametocytes and oocysts of the apicomplexan parasite genus Eimeria is still a challenge in coccidiosis research. Until today, an in vitro development of gametocytes or oocysts had only been shown in some Eimeria species. For several mammalian Eimeria species, partial developments could be achieved in different cell types, but a development up to gametocytes or oocysts is still lacking. This study compares several permanent cell lines with primary fetal cells of the black rat (Rattus norvegicus) concerning the qualitative in vitro development of the rat parasite Eimeria nieschulzi. With the help of transgenic parasites, the developmental progress was documented. The selected Eimeria nieschulzi strain constitutively expresses the yellow fluorescent protein and a macrogamont specific upregulated red tandem dimer tomato. In the majority of all investigated host cells the development stopped at the second merozoite stage. In a mixed culture of cells derived from inner fetal organs the development of schizont generations I-IV, macrogamonts, and oocysts were observed in crypt-like organoid structures. Microgamonts and microgametes could not be observed and oocysts did not sporulate under air supply. By immunohistology, we could confirm that wild-type E. nieschulzi stages can be found in the crypts of the small intestine. The results of this study may be helpful for characterization of native host cells and for development of an in vitro cultivation system for Eimeria species.

Improvement of ultrastructural preservation of Eimeria oocysts by microwave-assisted chemical fixation or by high pressure freezing and freeze substitution.

Fixation and preparation for electron microscopy of coccidian oocysts is a general problem. Especially in sporulated oocysts, proper fixation and resin infiltration are hindered by the robust oocyst wall. Conventional chemical fixation therefore leads to artefacts that obscure cellular details in the oocysts. In this study, sporulated oocysts of Eimeria nieschulzi were subjected to different fixation and embedding protocols: conventional chemical fixation and embedding in Spurr's resin, microwave-assisted fixation and processing followed by embedding in epon, and high pressure freezing followed by freeze substitution and epon embedding. The samples were finally studied by transmission electron microscopy. Many ultrastructural features of the oocyst wall and the sporozoites were already substantially improved after microwaved-assisted fixation and processing. However, the fine structural preservation still suffered from shrinkage and artificial extraction, which occured during dehydration and infiltration. High pressure freezing (HPF) and freeze substitution (FS) revealed much better preservation. Oocyst walls retained their ovoid shape, and the ultrastructure of sporozoites was well preserved with no signs of shrinkage or extraction. HPF and FS are therefore a suitable method for the ultrastructural analysis of coccidian oocysts.

New insights into the excystation process and oocyst morphology of rodent Eimeria species.

In this study, the mechanism of excystation of the rodent parasites Eimeria nieschulzi, from rats, and Eimeria falciformis, from mice, was investigated. In vitro, oocysts of both species are susceptible to the protease pepsin, and sporocysts and sporozoites can be excysted in a similar way. Scanning electron microscopy (SEM) revealed a collapse of the oocysts wall at both polar ends after pepsin treatment. This occurs without any visible damage of the outer wall. Using fluorescence and transmission electron microscopy (TEM) we observed that pepsin enters sporulated oocysts at both polar ends and causes degradation of the inner oocyst wall. Using scanning electron microscopy we could identify two polar caps in both investigated rodent Eimeria species, but only one is harbouring the micropyle. Thus the polar caps are the entry site for the pepsin. Furthermore, we provide evidence that the oocyst cap and micropyle are functionally different structures. This study complements the morphological description of both Eimeria species and is of relevance for other coccidian species.