A purified stage-specific 31 kDa antigen as a potential protective antigen against Ostertagia circumcincta infection in lambs

Attempts to immunize sheep against Teladorsagia circumcincta using fourth-stage larval extracts

A ConcanavilinA (ConA)-binding fraction of a detergent-soluble membrane extract from Teladorsagia circumcincta (formerly Ostertagia circumcincta) fourth-stage larvae was isolated, and two vaccine trials were conducted with this preparation in groups of 7 worm-free sheep. All groups were challenged with a total of 5000 T. circumcincta larvae from 1 week after the final immunization and protection assessed by comparing the egg and worm counts, and length of developing worms, of the immunized groups with their respective controls. Immunization with the ConA-binding antigen induced high-titre serum antibody responses in both trials. However, no significant reduction in either egg count or worm burdens was observed in the vaccinated groups in either trial. It was concluded that detergent-soluble, ConA-binding extracts prepared from T. circumcincta fourth-stage larvae did not contain significantly protective antigens, despite the fact that an extract prepared in a similar manner from Ostertagia ostertagi had previously significantly protected calves against homologous challenge.

Identification of immuno-reactive proteins from a sheep gastrointestinal nematode, Trichostrongylus colubriformis, using two-dimensional electrophoresis and mass spectrometry

Gastrointestinal nematode infections of livestock animals are prevalent and costly problems worldwide. Currently, infections are controlled by anthelmintic chemicals but increasing drug resistance has prompted research interest to shift towards alternative methods of control such as vaccine development and selection of worm-resistant animals. The present study analyses proteins from Trichostrongylus colubriformis infective L3s that are recognised by IgG of immune sheep. Following protein separation via two-dimensional electrophoresis and Western blot probing with plasma from sheep resistant to T. colubriformis, mass spectrometry-based proteomic analyses were used to identify immuno-reactive protein spots. We were able to identify 28 immune targets, including aspartyl protease inhibitor, enolase, chaperone proteins, galectin, glycolytic enzymes, kinase, phosphatase and structural muscle proteins such as myosin, paramyosin, calponin and DIM-1. The data suggest that immune responses to T. colubriformis are dispersed over a relatively large number of parasite antigens, including several cytoplasmically expressed proteins. The results have new implications for understanding the molecular mechanisms that underpin host-parasite interaction during gastrointestinal nematode infections.

Jaagsiekte sheep retrovirus-specific immune responses induced by vaccination: A comparison of immunisation strategies

Jaagsiekte sheep retrovirus (JSRV) is the aetiological agent of ovine pulmonary adenocarcinoma (OPA). No JSRV-specific immunological responses have been detected in clinical cases of OPA or in experimentally infected lambs. The aim of the present study was to induce immune responses in sheep against JSRV proteins using several immunisation strategies. The vaccines were administered subcutaneously and intradermally, or intranasally, in adjuvant. Antibodies were measured by ELISA and immunoblotting, and T cell responses by lymphoproliferation assay. Antibodies specific for JSRV-capsid protein were induced by inoculation of recombinant proteins in adjuvant, and transient JSRV-specific T cell responses by intranasal inoculation with inactivated virus. These results will help in the design of a protective vaccine against JSRV infection and the development of OPA.

A preliminary proteomic survey of the in vitro excretory/secretory products of fourth-stage larval and adult Teladorsagia circumcincta

The nature of the proteins which comprise the in vitro excretory/secretory products (ES) of the fourth-stage larva (L4) and adult Teladorsagia circumcincta are largely undefined, despite the fact that this nematode induces profound changes, in part related to parasite ES, in the cellular architecture of the glands lining the abomasal surface of infected sheep and goats. In this study, the protein components of L4 and adult ES were fractionated using 1D gel electrophoresis and the major protein bands, detected by Coomassie blue staining, excised from the gel and subjected to tryptic digest and subsequent mass spectrometric analysis. The resultant peptide mass fingerprints were used to identify 15 L4 and 13 adult ES proteins. Several proteins, such as globin and some metabolic enzymes, were present in both ES. L4 ES alone contained thioredoxin peroxidase, an enzyme that can detoxify free radicals resulting from host inflammatory responses to the parasite, a cysteine proteinase which may aid penetration of the gastric mucosa and 2 different galectins which may influence cell differentiation and morphogenesis. Adult ES contained a nucleoside diphosphate kinase homologue, an enzyme which has been linked to cellular changes and can affect liquid secretion and goblet cell degranulation.

Immunoaffinity-isolated antigens induce protective immunity against larval Strongyloides stercoralis in mice

The objective of this study was to identify soluble protein antigens that would induce protective immunity against infective-stage larvae (L-3) of Strongyloides stercoralis in mice. Deoxycholate (DOC)-soluble proteins derived from L-3, adsorbed to aluminum hydroxide, induced protective immunity in BALB/c mice. The immunized mice generated parasite-specific IgG that could transfer passive immunity to naïve animals. The protective antibodies bound to parasite antigens found in the muscles and nerve cords of the L-3. An IgG affinity chromatography column generated with IgG from the sera of DOC-immunized mice was used to purify specific larval antigens. Proteins were eluted from the affinity column with sizes of 80, 75, 61, 57, 43, and 32 kDa. This antigen pool stimulated both proliferation and IL-5 production by splenocytes recovered from mice immunized with live L-3. Vaccination of mice with the immunoaffinity-isolated antigens led to significant protective immunity, with 83% of challenge larvae killed. This study demonstrates that IgG-isolated proteins are candidate antigens for a vaccine against larval S. stercoralis.

The recognition of molecules from fourth-stage larvae of Ostertagia circumcincta by IgA from infected sheep

The recognition of antigens from fourth-stage Ostertagia circumcincta by plasma IgA was studied in a group of 30, ten-month-old Scottish Blackface sheep which had been naturally, then deliberately infected. Western blotting revealed 49 bands that were recognized by antibody from one or more of the 30 sheep. There was a heterogeneous pattern of antigen recognition amongst the sheep. No individual recognized all the 49 bands and only one of the 49 bands was recognized by all sheep. Two antigens with approximate molecular weights 87,000 Da and 129,000 Da were significantly associated with a reduction in mean adult worm lengths. The observed variation in recognition of these two antigens on fourth-stage larval preparations accounted, in a statistical sense, for nearly 40% of the total variation in worm length. In addition to the variation in antibody mediated recognition of these two parasite molecules, three other components have been implicated in regulating worm length. They are a 37,000 Da band from adult worms, the amount of fourth-stage larval specific IgA in the abomasal mucosa and the density-dependent influence of adult worm burden. Together, these components and their interactions accounted for over 90% of the observed variation in worm length. These results indicate that the parasite-specific IgA response, or something extremely closely associated with it, is the major immunological mechanism controlling worm length.

Vaccination against the gastrointestinal nematode, Haemonchus contortus, using a purified larval surface antigen

Sheep were immunized with a purified antigen (Hc-sL3) expressed on the surface of L3 larvae of the gastro-intestinal parasite, Haemonchus contortus, using different adjuvant and immunization routes. In the first experiment, intradermal immunization of sheep with Hc-sL3 and QuilA did not result in reductions in faecal egg counts after subsequent challenge infection while significant reductions were obtained when aluminium hydroxide (AH) was used as the adjuvant. Significant protection with Hc-sL3 absorbed on AH was confirmed in a second experiment and this protection was maintained when dextran sulphate was added to the Hc-sL3/AH mixture while the addition of pertussis toxin abrogated the protective effect. Significant levels of protection, as determined by reductions in both faecal egg counts and worm burdens, were also obtained when the Hc-sL3/AH mixture was injected into the rectal mucosa or the Hc-sL3 antigen was deposited on the surface of the rectal mucosa with cholera toxin. No correlations with antibody levels or isotype and protection were observed.

Progress and expectations for helminth vaccines

The large amount of scientific progress made in the last 5 years has allowed a more rational approach to the design of nematode vaccines to develop. Successful experimental trials have been published using two different approaches, one aiming to boost acquired host immunity through vaccination with natural immunogens, the other affecting parasite viability by targeting parasite molecules crucial for nutrition or survival in the host. The individual or combined action of these two vaccination procedures will need to be evaluated with respect to their potential effects on animal health and productivity in the field. To this effect, more data are required concerning the level and duration of immunity of the vaccine-induced protection using acceptable adjuvant systems. In addition, the age at which vaccination is effective and the effect of vaccination on highly susceptible or temporarily immunosuppressed individuals will need to be considered. In the case of gastrointestinal nematodes, the level of pasture contamination with infective larvae is dependent on the worm burdens in the host animal and, in turn, affects the buildup of natural resistance in the host. An appreciation of these complex interactive factors is best achieved through computer simulation models using the powerful simulation software that has recently become available. Further animal trials will need to be performed to establish the necessary data to incorporate into the models and to adapt the model outcomes to the trial results. These epidemiologic and simulation studies should be pursued in parallel with vaccine development so that a better appreciation is gained of the requirements of a successful commercial vaccine.

Vaccination against worm parasites of animals

The 1990s have seen the culmination of decades of painstaking research with the registration and launch of Tickgard (Hoechst), a recombinant vaccine against Boophilus microplus, and the provisional registration of a Taenia ovis vaccine. Research continues to hold promise for immunological control of Echinococcus, Fasciola, Haemonchus, Trichostrongylus and Ostertagia. Blood-sucking parasites (e.g. ticks and H. contortus) are susceptible to control by vaccines containing 'novel' or 'concealed' antigens where serum antibodies in blood meals attack targets in the gut. Antibodies also provide protection in taeniid models, whereas the protective response to be sought in Fasciola remains unclear. More problematic are formulations and delivery strategies to induce expulsion of gastrointestinal nematodes, using vaccines containing recombinant 'conventional' antigens. The use of computer models to simulate vaccine efficacy in worm control and challenges to the concept of 'hypo-responsiveness' of young lambs will encourage cautious optimism and lively debate as to the prospects for integrated worm control using parasite vaccines. This review covers the aspirations, current success and problems faced by researchers in the parasite arena.

Antigens with application toward immune control of blood-feeding parasitic nematodes

This review considers progress toward immune control of nematode parasites that feed on mammalian host blood. Approaches to identify relevant parasite antigens include use of irradiated larvae, somatic antigens, metabolites, enzymes and gut antigens. Because significant immune protection has more recently been achieved using gut antigens of the blood-feeding parasite Haemonchus contortus, these antigens are considered in greater detail. Issues discussed are implications of gut antigens in immune control, potential mechanisms involved in this immunity, biochemical characteristics of gut antigens and potential application of gut antigens to immune control of other blood-feeding nematodes.

Immunisation of calves with Ostertagia ostertagi fourth stage larval antigens failed to protect calves from infection

Excretory-secretory and somatic antigens of Ostertagia ostertagi fourth stage larvae, emulsified with complete Freund's adjuvant, were intraperitoneally administered to calves on three occasions. Two weeks after the last immunisation all calves were infected with a single dose of 130,000 O. ostertagi third stage larvae. All animals were necropsied 25 days after infection. The immunisation procedure resulted in IgG1 and IgG2 antibodies, however no protective immunity was induced as O. ostertagi worm burdens and worm length were similar in all groups.

Vaccination against animal parasites

A decade of molecular parasitology is beginning to bear fruit, with the appearance of several new, highly effective, practical vaccines against parasitic diseases. Recombinant antigen vaccines have been developed against cestode, nematode, trematode, protozoan and arthropod parasites. Greatest progress has been made with veterinary vaccines, where the ability to test numerous vaccine formulations in challenge trials has allowed more rapid identification of host-protective antigens than is possible with many medically important parasites. Several quite different approaches to vaccine development have been successful. The traditional approach using live, attenuated parasites continues to provide effective vaccines against several protozoan and nematode parasites. Recombinant DNA technology, monoclonal antibody technology, protein chemistry and immunochemistry have played critical roles in the outstanding success which has been achieved over the last 5 years in the development of defined-antigen vaccines. Two approaches have been successful in research towards defined antigen vaccines against parasites: (1) the 'natural antigen' approach where immune responses are stimulated to parasite molecules which are normally antigenic, and possibly host-protective, in infected hosts; (2) the 'naive antigen' approach where parasite molecules which are not antigenic, or of very low antigenicity, in infected hosts are used to raise immune responses capable of killing the parasite. This review examines the successful approaches taken towards the development of effective anti-parasite vaccines and the vaccines which have been produced to date.

Production of vaccines against gastrointestinal nematodes of livestock

Three international collaborations involving Australian research scientists are currently developing vaccines against Haemonchus, Trichostrongylus and Ostertagia parasites using recombinant DNA technology. The variety of protective antigens identified can be classified as 'conventional' (stimulate naturally acquired immunity) or 'novel'/'convert'/'concealed' (protective once immunity is induced by vaccination). To date, the most gratifying progress has resulted in 60-90% protection against Haemonchus and other blood-sucking parasites (e.g. ticks) using novel antigens, where high titres of serum antibody ingested by feeding worms leads to their demise. A great deal of research effort is unravelling the complexity of naturally acquired immunity so that conventional antigens, which may be the principal means of removing 'mucosal-browsing' parasites, may be formulated and delivered to achieve optimal efficacy. This work reveals that to remove early stages of parasites before they take up residence, deliberate induction of hypersensitivity responses akin to asthma, may be a desirable goal for vaccines and that the two models have much in common.