Project description:The excretory-secretory (ES) proteins are the molecules that actively or passively released by parasite at the parasite-host interface to maintain a physiological and immunological relationship with the host. In the present study, we characterised the excretory-secretory products from the short-term in vitro culture (i.e. within 12 h) of Haemonchus contortus (as the most important parasitic nematodes of livestock animals worldwide) using a high throughput tandem mass-spectrometry underpinned by the most recent genomic dataset. Totally, 878 unique ES proteins from three key developmental stages were identified and quantified without intracellular protein contamination (e.g. histone) typically occurred in longer term maintenance cultures. Bioinformatic analyses showed noteworthy protein excretion and secretion alterations during the transition from the free-living to the parasitic phase, especially for ES proteins which are likely involved in nutrient digestion, acquisition and parasite-host interactions, such as proteolytic cascade related peptidases, glycoside hydrolases, C-type lectins, transthyretin-like proteins and SCP/TAPS proteins. Our finding provide an avenue to better explore interactive processes between the host and this highly significant parasitic nematode, to underpin the search for novel drug and vaccine targets.

Project description:Parasitic nematodes cause diseases that adversely impact on animal health and production. Although advances in genomics and transcriptomics are revolutionising the way we explore these parasites, there is a dearth of proteomic data to underpin or support fundamental discoveries. Here, using a high throughput LC-MS/MS-based approach, we undertook the first large-scale (global) proteomic investigation of Haemonchus contortus (the barber's pole worm), one of the most important parasitic nematodes of livestock animals worldwide. In total, 2487 unique H. contortus proteins, representing five key developmental stages [i. e. eggs, third-stage (L3) and fourth-stage (L4) larvae; female (Af) and male adults (Am)] were identified and quantified with high confidence. Bioinformatic analyses of the somatic proteome of H. contortus discovered substantial alterations in protein profiles during the life cycle, particularly in the transition from the free-living to the parasitic phase, and identified groups of key proteins involved specifically in feeding, digestion, metabolism, development, parasite-host interactions (including immunomodulation), structural remodelling of the body wall and other adaptive processes during the parasitic phase. This global proteomic data set will likely facilitate future molecular, biochemical and physiological investigations of H. contortus and related nematodes, and should underpin the discovery of novel intervention targets against haemonchosis.

Project description:Illumina sequencing of small RNAs from Brugia pahangi and Haemonchus contortus 4 samples examined, larval stage 3 and mixed sex adults from two parasitic nematode species.

Project description:Parasitic worms have a major global impact in human and animal populations due to the chronicity of their infections. These parasites have an exquisite capacity to survive in host animals. There is a growing body of evidence that extracellular vesicles (EVs) are intimately involved in parasitism, and that these vesicles are instrumental in modulating (suppressing) inflammatory/immune responses. The recent expansion of proteomic and lipidomic technologies and molecular resources for some parasitic worms (order Strongylida) provide a unique opportunity to conduct profound (qualitative and quantitative) explorations of EVs, with the prospect of being able to elucidate the functional roles of key molecules within these vesicles in host tissues and cells. As one of the most pathogenic nematodes of livestock animals, the blood-feeding barber’s pole worm – Haemonchus contortus – is an ideal model system for EV exploration. Here, using advanced methods, we defined the proteome of EVs of Haemonchus contortus. We identified and quantified 561 proteins in these EVs, and compared these molecules with those of adult worms. We identified unique molecules in EVs such as proteins linked to lipid transportation and lipid species (i.e. glycerophospholipids and sphingolipids) associated with signalling, indicating an involvement of these molecules in parasite-host cross-talk. This work provides a solid starting point to explore the functional roles of EV-specific proteins and lipids in modulating parasite-host cross talk; a foundation to assess the utility of such molecules as biomarkers for the specific detection of infection or disease; and the prospect of finding ways to disrupt or interrupt this relationship to suppress or eliminate infection.

Project description:Haemonchus contortus is the most pathogenic nematode of small ruminants. Infection in sheep and goats results in anaemia that decreases animal productivity and can ultimately cause death. The involvement of ruminant-specific galectin-11 (LGALS-11) and galectin-14 (LGALS-14) has been postulated to play important roles in protective immune responses against parasitic infection; however, their ligands are unknown. In the current study, LGALS-11 and LGALS-14 ligands in H. contortus were identified from larval (L4) and adult parasitic stages extracts using immobilised LGALS-11 and LGALS-14 affinity column chromatography and mass spectrometry. Both LGALS-11 and LGALS-14 bound more putative protein targets in the adult stage of H. contortus (43 proteins) when compared to the larval stage (2 proteins). Of the 43 proteins identified in the adult stage, 34 and 35 proteins were bound by LGALS-11 and LGALS-14, respectively, with 26 proteins binding to both galectins. Interestingly, hematophagous stage-specific sperm-coating protein and zinc metalloprotease (M13), which are known vaccine candidates, were identified as putative ligands of both LGALS-11 and LGALS-14. The identification of glycoproteins of H. contortus by LGALS-11 and LGALS-14 provide new insights into host-parasite interactions and the potential for developing new interventions.

Project description:Infections and diseases caused by parasitic nematodes have a major adverse impact on the health and productivity of animals and humans worldwide. The control of these parasites often relies heavily on the treatment with commercially available chemical compounds (anthelmintics). However, the excessive or uncontrolled use of these compounds in livestock animals has led to major challenges linked to drug resistance in nematodes. Therefore, there is a need to develop new anthelmintics with novel mechanism(s) of action. Recently, we identified a small molecule, KM08948, with nematocidal activity against the free-living model organism Caenorhabditis elegans. Here, we evaluated KM08948’s potential as an anthelmintic in a structure-activity relationship (SAR) study in C. elegans and in the highly pathogenic, blood-feeding Haemonchus contortus (barber’s pole worm), and explored the compound-target relationship using thermal proteome profiling (TPP). First, we synthesised and tested a series of 25 KM08948 analogues for nematocidal activity in both H. contortus (larvae and adults) and C. elegans (young adults), establishing a preliminary nematocidal pharmacophore for both species. We identified several compounds with marked activity against either H. contortus or C. elegans which had greater efficacy than KM08948, and found a significant divergence in compound bioactivity between these two nematode species. We also identified a KM08948 analogue, 25, that moderately inhibited the motility of adult female H. contortus in vitro. Subsequently, we inferred three H. contortus proteins (HCON_00134350, HCON_00021470 and HCON_00099760) and five C. elegans proteins (F30A10.9, F15B9.8, B0361.6, DNC-4 and UNC-11) that interacted directly with KM08948; however, no conserved protein target was shared between the two nematode species. Future work aims to extend the SAR investigation in these and other parasitic nematode species, and validate individual proteins identified here as targets of KM08948. Overall, the present study describes an evaluation of this anthelmintic candidate and highlights some challenges associated with early anthelmintic discovery.

Project description:N-glycosylation is a physiologically vital post-translational modification of proteins in eukaryotic organisms. Initial work on Haemonchus contortus – an economically-important blood-sucking nematode of ruminants with a broad geographical distribution – has shown that the parasite harbors N-glycans with exclusive core chitobiose modifications, and severel immunogenic proteins (e.g., amino- and metallo-peptidases) in the adult worms are N-glycosylated. However, an informative atlas of N-glycosylation in H. contortus is not yet available. Herein, we report a total of 291 N-glycosylated proteins with 425 sites in this parasite. Functional analyses of glycoproteome revealed significant enrichment of the peptidase families (e.g., peptidase C1 and M1), many of which are potential vaccine targets. Besides, the glycan-rich conjugates are distributed primarily in the intestine and gonads of the adult worms. These data, taken together, provide a comprehensive insight into the N-glycosylation of a prevalent parasitic nematode, while underlining its significance for the infection and prophylaxis.

Project description:Parasitic diseases of humans and other animals represent a major socioeconomic burden worldwide. In humans, parasitic worms (helminths) that cause neglected tropical diseases (NTDs) affect ~ billion people, equating to a burden of >12 million disability-adjusted life years (DALYs) (Hotez et al., 2014). In other animals, although challenging to quantitate, the disease impact of such helminths is major (Pedersen, et al., 2015; Charlier et al., 2020; Selzer and Epe, 2021), and some of these parasites are also transmissible to humans (i.e. zoonotic) (McCarthy et al., 2000; Gordon et al., 2016). The control of these diseases relies on diagnosis, treatment and management strategies, and anthelmintic treatment is usually a central component of a control campaign, as vaccines are not available for the vast majority of them. These treatments are not always highly efficacious/effective, and the reliance on them, particularly if they are used excessively in an uncontrolled (suppressive) manner, has led to the emergence and spread of anthelmintic resistances in parasitic worms (within 4-X generations; REF), particularly those of animals. Although the resistance status of worms of humans to available compounds is somewhat unclear (Prichard, 2005; Keiser and Utzinger, 2008; Vercruysse et al., 2011), this is not the case for worms of important production animals (e.g., sheep, goats and pigs), where such resistance(s) is/are widespread and essentially worldwide. In recent work, we established a high-throughput whole-organism, phenotypic assay for the screening of relatively large libraries of tens to hundreds of thousands of compounds, the subsequent evaluation of active compounds and structure-activity relationship (SAR) studies to strive toward the optimisation of the activity and potency of analogs, and the minimisation of side effects and toxicity (Taki et al., 2021b; Taki et al., 2021c; Shanley et al., 2022). However, our early discovery work has been hampered by not knowing the target(s) to which compounds might bind and how they might work. In recent years, there have been major advances in the development of methods for identifying drug-target interactions (reviewed by Mateus et al., 2021), which include affinity purification, activity-based protein profiling, kinobeads (for kinases), stability of proteins from rates of oxidation, protein painting, limited proteolysis/drug affinity responsive target stability and thermal proteome profiling (TPP). Published evidence (Savitski et al., 2014; Perrin et al., 2020; Selkrig et al., 2020) demonstrates clearly the exquisite capacity of TPP to define or infer target molecules in projects with a biomedical focus (e.g., cancer, autophagy or infectious disease), but this method has not yet been utilised to define an anthelmintic target. This context provides the very exciting prospect of being able to rapidly provide evidence of drug-target interactions. For these reasons, in the present study, we undertook a high-throughput whole-organism, phenotypic screen of a well-curated compound library, identified ‘hit’ compounds for evaluation, identified one candidate with lead-like characteristics and inferred the target of this promising small molecule in H. contortus.

Project description:Once Haemonchus contortus infects sheep it receives a series of host attacks, especially those relating to the infected animal’s T lymphocytes immune response. To obtain a systematic genome-wide profiling of the T lymphocyte genes involved, microarrays were used to compare gene expression between 0 days post infection (dpi), 3-5 dpi, 25-30 dpi and 60dpi in infected sheep. In this 853, 242 and 42 differentially expressed genes were acquired in the 3d vs. 0d comparison, the 30d vs. 0d comparison and the 60d vs. 0d comparison, respectively. Gene Ontology and pathway analysis indicated that modulated genes including SUGT1, FCER1G, CD23, IL-13 and galectin-14, were mostly associated with cellular homeostasis maintaining and immune response. Haemonchus contortus infection induced gene expression in sheep T lymphocytes was measured at 0, 3, 30 and 60 days post infection. Four time-series experiments were performed at each sheep (2#, 3# and 5#).

Project description:Parasitic nematodes of humans, animals and plants cause significant economic losses worldwide. Control of these pathogens is currently challenging due to the widespread problem of nematode anthelmintic resistance. Unfortunately, most efforts to develop anti-nematode vaccines for use in animals and humans have not succeeded. However, one effective (dead) anti-nematode vaccine (Barbervax) has been developed to protect livestock animals against the socioeconomically important parasitic nematode Haemonchus contortus (barber’s pole worm). This vaccine contains a major native antigen, termed H11. In its native form, H11 alone consistently induces high immunoprotection (75-95%) in animals, but recombinant forms thereof do not. Here, to test the hypothesis that post-translation modification of H11 is responsible for achieving the immunoprotection. We explored the N-glycoproteome and N-glycome of H11 using high-resolution mass spectrometry and assessed the roles of N-glycosylation in protective immunity against H. contortus. We demonstrated that N-glycans are a predominant protective component that induces protection and an associated IgG antibody response in immunised animals. We also showed that anti-H11 IgG antibodies confer specific, passive immunity in naïve animals. This study is the first detailed investigation of the relevance of protein glycosylation in protective immunity against a parasitic nematode, and should have important implications for developing vaccines against metazoan parasites.