Bärbel Ruttkowski

Low cost whole-organism screening of compounds for anthelmintic activity.

Due to major problems with drug resistance in parasitic nematodes of animals, there is a substantial need and excellent opportunities to develop new anthelmintics via genomic-guided and/or repurposing approaches. In the present study, we established a practical and cost-effective whole-organism assay for the in vitro-screening of compounds for activity against parasitic stages of the nematode Haemonchus contortus (barbers pole worm). The assay is based on the use of exsheathed L3 (xL3) and L4 stages of H. contortus of small ruminants (sheep and goats). Using this assay, we screened a panel of 522 well-curated kinase inhibitors (GlaxoSmithKline, USA; code: PKIS2) for activity against H. contortus by measuring the inhibition of larval motility using an automated image analysis system. We identified two chemicals within the compound classes biphenyl amides and pyrazolo[1,5-α]pyridines, which reproducibly inhibit both xL3 and L4 motility and development, with IC50s of 14-47 μM. Given that these inhibitors were designed as anti-inflammatory drugs for use in humans and fit the Lipinski rule-of-five (including bioavailability), they show promise for hit-to-lead optimisation and repurposing for use against parasitic nematodes. The screening assay established here has significant advantages over conventional methods, particularly in terms of ease of use, throughput, time and cost. Although not yet fully automated, the current assay is readily suited to the screening of hundreds to thousands of compounds for subsequent hit-to-lead optimisation. The current assay is highly adaptable to many parasites of socioeconomic importance, including those causing neglected tropical diseases. This aspect is of major relevance, given the urgent need to deliver the goals of the London Declaration (http://unitingtocombatntds.org/resource/london-declaration) through the rapid and efficient repurposing of compounds in public-private partnerships.

Age, not Infection Dose, Determines the Outcome of Isospora suis Infections in Suckling Piglets

Data from 13 trials involving 124 suckling piglets experimentally infected with Isospora suis were evaluated for the effects of infection dose and age on the clinical and parasitological outcome of infection in four different models, infections with 1,000 oocysts on the 1st day of life (d.o.l.) (model 1; 9 piglets/3 litters), 1,000 oocysts on the 4th d.o.l. (model 2; 25 piglets/11 litters), 1,500 oocysts on the 4th d.o.l. (model 3; 40 piglets/20 litters) and 10,000 oocysts on the 4th d.o.l. (model 4; 50 animals/10 litters). Weights were determined on the day of birth and in weekly intervals. Faecal consistency and quantitative oocysts excretion were evaluated for 2 weeks starting 4 days after infection (d.p.i.). The weight gain depression was most noticeable in model 2 (infection on the 1st d.o.l.), where animals only gained 2.08 x their birth weight until the 22nd d.o.l., compared to 2.31–2.52 x in the other groups. This correlated with the occurrence of watery diarrhoea which was found in 37 % of the samples in the acute phase (4–11 d.p.i.) in model 2 but only in 12–20 % of the samples in the other models. Median oocyst excretion peaked earlier in the models with higher infection doses but reached the highest values in model 2 (early infection). As in previous studies, this cross-sectional analysis of a larger number of animals confirms the influence of age on the outcome of isosporosis in suckling piglets, stressing the need to control the infection at an early life phase.

Oesophagostomum dentatum Extract Modulates T Cell-Dependent Immune Responses to Bystander Antigens and Prevents the Development of Allergy in Mice

One third of the human population is currently infected by one or more species of parasitic helminths. Certain helminths establish long-term chronic infections resulting in a modulation of the host’s immune system with attenuated responsiveness to “bystander” antigens such as allergens or vaccines. In this study we investigated whether parasite-derived products suppress the development of allergic inflammation in a mouse model. We show that extract derived from adult male Oesophagostomum dentatum (eMOD) induced Th2 and regulatory responses in BALB/c mice. Stimulation of bone marrow-derived dendritic cells induced production of regulatory cytokines IL-10 and TGF-beta. In a mouse model of birch pollen allergy, co-administration of eMOD with sensitizing allergen Bet v 1 markedly reduced the production of allergen-specific antibodies in serum as well as IgE-dependent basophil degranulation. Furthermore, eMOD prevented the development of airway inflammation, as demonstrated by attenuation of bronchoalveolar lavages eosinophil influx, peribronchial inflammatory infiltrate, and mucus secretion in lungs and IL-4 and IL-5 levels in lung cell cultures. Reduced secretion of Th2-related cytokines by birch pollen-re-stimulated splenocytes and mesenteric lymph node cells was observed in eMOD-treated/sensitized and challenged mice in comparison to sensitized and challenged controls. The suppressive effects of eMOD were heat-stable. Immunization with model antigens in the presence of eMOD reduced production of antibodies to thymus-dependent but not to thymus-independent antigen, suggesting that suppression of the immune responses by eMOD was mediated by interference with antigen presenting cell or T helper cell function but did not directly suppress B cell function. In conclusion, we have shown that eMOD possesses immunomodulatory properties and that heat-stable factors in eMOD are responsible for the dramatic suppression of allergic responses in a mouse model of type I allergy. The identification and characterization of parasite-derived immune-modulating molecules might have potential for designing novel prophylactic/therapeutic strategies for immune-mediated diseases.

Isospora suis in an Epithelial Cell Culture System – An In Vitro Model for Sexual Development in Coccidia

Coccidian parasites are of major importance in animal production, public health and food safety. The most frequently used representative in basic research on this group is Toxoplasma gondii. Although this parasite is well investigated there is no adequate in vitro model for its sexual development available and knowledge on this important life cycle phase is therefore scarce. The use of Isospora suis , a sister taxon to T. gondii and the causative agent of piglet coccidiosis, could provide a solution for this. In the present study an in vitro model for neonatal porcine coccidiosis in cells representative for the in vivo situation in the piglet gut was developed and evaluated. The parasite development was investigated by light and transmission electron microscopy and optimum culture conditions were evaluated. Intestinal porcine epithelial cells (IPEC-J2) adequately representing the natural host cells supported the development of all endogenous life cycle stages of I . suis , including gametocytes and oocysts. A concentration of 5% fetal calf serum in the culture medium led to highest gametocyte densities on day 12 post infection. Low infection doses (≤1 sporozoite for 100 host cells) were best for oocyst and gametocyte development. The presented system can also be used for immunostaining with established antibodies developed against T. gondii (in our case, anti-TgIMC3 antibodies directed against the inner membrane complex 3). The complete life cycle of I . suis in a cell line representing the natural host cell type and species provides a unique model among coccidian parasites and can be used to address a wide range of topics, especially with regard to the sexual development of coccidia.

Faeces, FACS, and functional assays - preparation of Isospora suis oocyst antigen and representative controls for immunoassays

SUMMARY Highly purified antigen and appropriate controls are essential for antigen-specific immunoassays. In the case of Isospora suis, the causative agent of neonatal porcine coccidiosis, the only current source of antigen is oocysts isolated from faeces. The aim of this study was to develop a procedure for high-grade purification of I. suis oocysts from piglet faeces to obtain both antigen and representative controls suitable for in vitro re-stimulation of lymphocytes. This was achieved by use of filtration, density-gradient centrifugation and fluorescence-activated cell sorting (FACS). The feasibility for immunological studies was demonstrated with IFN-gamma ELISPOT assays after in vitro re-stimulation of lymphocytes from previously infected swine using the obtained antigen. The developed method allowed the production of highly purified antigen and representative controls from faeces with an oocyst recovery rate of 14%. Regarding the application of the obtained material it could be shown that lymphocytes from I. suis-infected pigs react in an antigen-specific manner in terms of an in vitro recall response by the production of IFN-gamma. This demonstrates the suitability of the developed method for the production of antigen and controls for sensitive immunological readout systems. Moreover, the detected specific IFN-gamma response encourages further functional studies on the cellular immune response to I. suis.

Cracking the nodule worm code advances knowledge of parasite biology and biotechnology to tackle major diseases of livestock

Many infectious diseases caused by eukaryotic pathogens have a devastating, long-term impact on animal health and welfare. Hundreds of millions of animals are affected by parasitic nematodes of the order Strongylida. Unlocking the molecular biology of representatives of this order, and understanding nematode-host interactions, drug resistance and disease using advanced technologies could lead to entirely new ways of controlling the diseases that they cause. Oesophagostomum dentatum (nodule worm; superfamily Strongyloidea) is an economically important strongylid nematode parasite of swine worldwide. The present article reports recent advances made in biology and animal biotechnology through the draft genome and developmental transcriptome of O. dentatum, in order to support biological research of this and related parasitic nematodes as well as the search for new and improved interventions. This first genome of any member of the Strongyloidea is 443 Mb in size and predicted to encode 25,291 protein-coding genes. Here, we review the dynamics of transcription throughout the life cycle of O. dentatum, describe double-stranded RNA interference (RNAi) machinery and infer molecules involved in development and reproduction, and in inducing or modulating immune responses or disease. The secretome predicted for O. dentatum is particularly rich in peptidases linked to interactions with host tissues and/or feeding activity, and a diverse array of molecules likely involved in immune responses. This research progress provides an important resource for future comparative genomic and molecular biological investigations as well as for biotechnological research toward new anthelmintics, vaccines and diagnostic tests.

Changes in antigen and glycoprotein patterns during the development of Oesophagostomum dentatum.

During its development from free-living infectious third-stage larvae to the adult worms in the large intestines of pigs, Oesophagostomum dentatum experiences several environmental changes. Differences in protein patterns can reflect such changes. Somatic and ES antigens and glycoproteins of pre-parasitic, histotropic and intestinal stages were compared by single-dimension SDS-PAGE and stage-specific proteins were defined. Furthermore, fourth-stage larvae derived from different sources--in-vitro cultivation and intestinal contents--were compared and also found to be different. It is hypothesised that O. dentatum reacts to environmental stimuli by differential expression of specific proteins as a possible mode of adaptation to the host.

Cytosolic glutathione S-transferases of Oesophagostomum dentatum

Oesophagostomum dentatum stages were investigated for glutathione S-transferase (GST) expression at the protein and mRNA levels. GST activity was detected in all stages (infectious and parasitic stages including third- and fourth-stage larvae of different ages as well as males and females) and could be dose-dependently inhibited with sulfobromophthalein (SBP). Addition of SBP to in vitro larval cultures reversibly inhibited development from third- to fourth-stage larvae. Two glutathione-affinity purified proteins (23 and 25 kDa) were detected in lysates of exsheathed third-stage larvae by SDS-PAGE. PCR-primers were designed based on peptide sequences and conserved GST sequences of other nematodes for complete cDNA sequences (621 and 624 nt) of 2 isoforms, Od-GST1 and Od-GST2, with 72% nucleotide similarity and 75% for the deduced proteins. Genomic sequences consisted of 7 exons and 6 introns spanning 1296 bp for Od-GST1 and 1579 and 1606 bp for Od-GST2. Quantitative real-time-PCR revealed considerably elevated levels of Od-GST1 in the early parasitic stages and slightly reduced levels of Od-GST2 in male worms. Both Od-GSTs were most similar to GST of Ancylostoma caninum (nucleotides: 73 and 70%; amino acids: 80 and 73%). The first three exons (75 amino acids) corresponded to a synthetic prostaglandin D2 synthase (53% similarity). O. dentatum GSTs might be involved in intrinsic metabolic pathways which could play a role both in nematode physiology and in host-parasite interactions.

Prostaglandin D2 synthesis in Oesophagostomum dentatum is mediated by cytosolic Glutathione S-transferase

Glutathione S-transferases (GSTs) of Oesophagostomum dentatum possess considerable similarity to synthetic prostaglandin D synthase (PGDS), and therefore their ability to convert prostaglandin (PG) H(2) to PGD(2)in vitro was investigated with a commercial Prostaglandin D Synthase Inhibitor Screening Assay Kit. Fractioned homogenates of O. dentatum third-stage larvae only displayed cytosolic but not microsomal GST. Both total larval homogenate and isolated GST could metabolise PGH(2) to PGD(2), which could be inhibited by the GST inhibitor sulfobromophthalein (SBP) in a dose-dependent manner, whereas reactions to the specific PGDS inhibitor HQL-79 were not dose-dependent. Inhibition of larval development by SBP in vitro was abolished by the addition of PGD(2) but not by PGH(2), supporting the assumption that GST acts as PGDS and is important for nematode development. Since motility and viability of O. dentatum larvae are reduced in vitro by various inhibitors of eicosanoid metabolism, enzymes of this pathway, including GST, constitute putative intervention targets.

Comparative studies on the development of Oesophagostomum dentatum in vitro and in vivo

Abstract Although in vitro cultivation of Oesophagostomum dentatum provides defined material of third- (L3) and fourth- (L4) stage larvae, these are morphologically and biochemically different from larvae recovered ex vivo. The development of pre-cultivated larvae was investigated by rectal transplantation into worm-free pigs with subsequent recovery of worms from intestinal contents after different time periods and determination of worm burdens and sizes. Additionally, the in vitro maintenance of L4 and adults recovered from intestinal contents of orally infected pigs in different media was investigated. Although growth and development rates of cultivated L4 are lower than those of larvae recovered from intestinal contents after oral infection, pre-cultured L4 are able to develop into egg-laying adults in the large intestines (without nodule formation) within 9–14 days in rates comparable with those after oral infection. In contrast, rectally transplanted L3 only establish in low numbers without egg excretion. L4 and adult worms recovered from intestinal contents cannot be maintained in cultivation medium for more than 1 week, although most L4 grow and moult during the first 3 days. Although the standard cultivation conditions for mass production of L4 are not suitable for development or maintenance of preadult and adult stages, L4 recovered from cultures have the ability to establish in vivo as fertile adults, indicating that the basic biological functions are retained in vitro.