V.M. Bowles

The immunobiology of gastrointestinal nematode infections in ruminants.

The major gastrointestinal nematode parasites of ruminants all belong to the Order Strongylida and the family Trichostrongyloidea. Despite this close evolutionary relationship, distinct differences exist in the microenvironmental niches occupied by the developmental stages of the various parasites, which may account for the variable susceptibility of the different parasite species to the immune effector mechanisms generated by the host. In addition, different manifestations of resistance have been observed against the adult and larval stages of the same parasite species, and even against the same parasite stage. In particular, both rapid and delayed rejection of infective larval stages of gastrointestinal nematode parasites has been documented. This review will give an overview of the various manifestations of resistance to gastrointestinal nematode parasites of ruminants, as well as the immune mechanisms and antigens associated with the generation of immunity by the ruminant hosts to these parasites. In addition, a working model is provided aimed at reconciling most of the present knowledge on the different immune responses generated during infection with the various parasite rejection profiles. Extrapolation of these results to field conditions will need to take into account the variability imposed by seasonal changes and management practices, as well as the individual variability in immune responsiveness present in outbred animal populations.

Biomedical applications of sheep models: from asthma to vaccines.

Although rodent models are very popular for scientific studies, it is becoming more evident that large animal models can provide unique opportunities for biomedical research. Sheep are docile in nature and large in size, which facilitates surgical manipulation, and their physiology is similar to humans. As a result, for decades they have been chosen for several models and continue to be used to study an ever-increasing array of applications. Despite this, their full potential has not been exploited. Here, we review the use of sheep as an animal model for human vaccine development, asthma pathogenesis and treatment, the study of neonatal development, and the optimization of drug delivery and surgical techniques.

Control of blowfly strike in sheep: current strategies and future prospects.

Blowfly strike is a cutaneous myiasis in sheep caused by infestations of larvae principally from the family Calliphoridae, particularly the species Lucilia cuprina and Lucilia sericata. These larval infestations cause considerable economic losses to the wool industry. Established control methods have served the industry well in the past, but there are growing deficiencies with these methods. In particular, there is widespread resistance to organophosphorus insecticides and potential difficulties associated with the presence of chemical residues derived from insecticides in wool and waste products which must be disposed of by the industry. There is also growing opposition to the radical surgical procedures used to decrease the susceptibility of sheep to blowfly strike. Consequently, there is a need for the development of alternative control measures. This review examines critically the present control methods and discusses the range of options available for the development of new control strategies. Many of the latter involve novel approaches which will strongly complement current control measures.

Cellular profiles in the abomasal mucosa and lymph node during primary infection with Haemonchus contortus in sheep.

Cellular changes in the abomasal tissue and draining abomasal lymph nodes were examined after primary infection of lambs with Haemonchus contortus for 3, 5 or 27-36 days. Infection with H. contortus larvae resulted in a rapid and selective increase in the percentage of CD4(+) T-cells in the abomasal lymph node at 3 days post-infection (PI). By 5 days PI, the lymph node weight had increased two-fold; however, the percentage of lymphocyte populations in the abomasal lymph node resembled that seen in uninfected sheep. Lymph node weights remained at increased levels in the adult nematode infected sheep and down-regulation of B-cell surface markers (sIg and MHC Class II) was apparent in this group. Significant increases in the percentage of CD4(+) T-cells co-expressing MHC Class II, but not CD25, were observed in the larval infected groups except in adult nematode infected sheep. Increased numbers of eosinophils, CD4(+), gamma delta(+) T-cells and B-cells were found in the abomasal tissue by 5 days PI, but no further increases in these cell populations were observed in the adult nematode infected group. In contrast, the level of both lamina propria and intraepithelial mast cells observed in the abomasal mucosa was highest in the sheep carrying an adult nematode burden. These findings indicate that sheep are able to generate an early immune response to infection with H. contortus larvae, characterised by the activation of CD4 T-cells and B-cells in the draining lymph nodes and recruitment of eosinophils, CD4(+) and gamma delta-TCR,WC1(+) T-cells and B-cells in larval infected tissues. However, these changes do not seem to be maintained during infection with the adult parasite where increases in mast cell numbers dominate the local response, indicating that different parasite stages may induce distinct and possibly counteractive immune responses.

Mechanisms of immunity to Haemonchus contortus infection in sheep

In two separate experiments, sheep were immunized by nine to 12 weekly immunizing infections with 4000 Haemonchus contortus third stage larva (L3), drenched with anthelminthics and maintained free of H. contortus infection for a further 12 weeks. The anamnestic cellular immune responses in both the abomasal lymph node (ALN) and mucosa of the immunized sheep were examined 3 and 5 days post challenge with 50 000 H. contortus L3. Sheep in the two experiments clearly segregated out in two distinct groups, one in which challenge larvae were obviously present in the tissues of all 12 sheep at 3 and 5 days post challenge while no challenge larvae were detected in tissues of seven of the eight sheep in the other group. In sheep in which no tissue larvae were detected, very few changes were noted in either the ALN or mucosa. In contrast, dramatic changes were observed in the cellular profiles of the ALN and mucosa after challenge infection in sheep in which larvae were observed in the abomasal tissues. In the ALN, these changes were characterized by an increase in the relative percentage of γδ‐TCR+ T cells and B cells and an increase in the proportion of CD4+ T cells coexpressing the activation markers MHC class II and CD25. In the abomasal mucosa, an increase in the number of infiltrating CD4+ and γδ‐TCR+ T cells and B cells was observed by 3 days postinfection and these levels were further increased at 5 days postinfection. This infiltration of the abomasal mucosa by lymphocytes was accompanied by a dramatic increase in the number of infiltrating eosinophils, which were often in intimate association with the surface of H. contortus larvae. None of these changes occurred in the mucosa of the sheep that showed no sign of challenge larvae in the tissues; however, a transient increase in γδ T cells in the ALN and a drop in intraepithelial globule leucocytes were uniquely observed in these sheep at 5 days post challenge. These results suggest that two different types of immune responses can be generated after challenge infection of immunized sheep, one where tissue larvae are excluded from their tissue niche as observed previously and which is associated with changes in globular leucocyte population but no mobilization of the local immune system. In contrast, when challenge larvae reach their tissue niche, dramatic changes in the local immune system occur, including a pronounced infiltration of eosinophils. These two immune mechanisms may be associated with the rapid and delayed rejection of parasite infections in immune sheep.

Tryptic and chymotryptic proteases released by larvae of the blowfly, Lucilia cuprina.

Proteases released by larvae of the sheep blowfly have been suggested to have a primary role in wound formation and larval nutrition. Assays were carried out on two larval products to analyse the substrate specificity of these proteases, their abundance and approximate molecular weights. Tryptic and chymotryptic activities were found in both products though there were more chymotrypsin-like enzymes in products from 48 h cultures (CESP) than in product collected direct from 48 h larvae (LESP). Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) gels incubated with azocasein showed plaques of major enzyme activity at molecular weights of 20,000 and 26,000 in LESP and at 20,000 in CESP, SDS-PAGE gels, when reacted with peptide substrates showed tryptic activity at 20,000 and 26,000 in LESP, whereas CESP showed only chymotryptic activity at 20,000 and higher molecular weights. The results suggest at least three enzymes, a trypsin and chymotrypsin in LESP, a chymotrypsin in CESP and a tryptic enzyme which is not stable to SDS-PAGE probably in both LESP and CESP. In addition, reactivity with elastase and plasmin substrates suggests the presence of enzymes with general effects on skin substrates and inflammatory pathways.

Acquired resistance in sheep to infection with larvae of the blowfly, Lucilia cuprina

Abstract Acquired resistance in sheep to infection with larvae of the blowfly, Lucilia cuprina . International Journal for Parasitology 16 : 69–75. Resistance to blowfly larvae infections developed in sheep exposed to at least four consecutive infections. Half of the sheep treated showed significant levels of resistance, the others remained susceptible. This resistance took the form of a decreased yield of third instar larvae in comparison to controls and sheep which remained susceptible. In addition an increased sensitivity to larvae developed, as shown by the area of wound obtained per maggot recovered, by the early appearance in resistant sheep of exudate from the infection site and by skin reactions to larval products. Radioimmunoassays demonstrated high levels of serum antibody against larval excretory/secretory antigens, though the response did not peak until after four infections. Resistant animals showed somewhat lower antibody titres than susceptible sheep. Consecutive infections of only 50 larvae failed to induce resistance to larger challenge infections. It is suggested that consecutive infections of larger numbers of maggots induce a hypersensitivity response which may effect larval survival especially of first and second instar maggots.

Inflammation‐induced changes in the phenotype and cytokine profile of cells migrating through skin and afferent lymph

In the present study, we have localized cytokine‐secreting cells within an ectoparasite‐induced inflammatory lesion and monitored the phenotype and cytokine profile of cells migrating from the inflammatory lesion to the local draining lymph node via the afferent lymphatics. Interleukin (IL)‐8‐producing cells were first detected in skin within 6 hr of infection, with increased numbers observed at 24 and 48 hr post infection. While these cells were concentrated within the neutrophil influx, adjacent to disrupted epidermis; they were also found scattered throughout the surrounding dermis in areas where significant cellular infiltration was not apparent. IL‐1α‐ and IL‐1β‐producing cells could not be detected until 24 hr after infection and were restricted to areas of intense neutrophil accumulation. Concurrent with the onset of inflammation was a threefold increase in the total number of cells migrating through the draining afferent lymph. This increase in cellularity was due primarily to increased migration of CD4 and γδ T cells. Cytokine mRNA synthesis by migrating afferent lymph cells was examined by reverse transcription–polymerase chain reaction (RT–PCR) analysis of RNA extracted prior to, and at regular intervals during the course of the inflammatory response. IL‐1β and IL‐8, but not IL‐1α or IL‐6 mRNA, was detected in migrating afferent lymph cells. Tumour necrosis factor (TNF)‐α‐specific mRNA was present in migrating afferent lymph cells at all time points both prior to, and following infection. Soluble IL‐8 protein, but not IL‐1α, IL‐1β or TNF‐α protein, could be detected in lymph, with the amount of IL‐8 detected increasing as the infection progressed. mRNA coding for cytokines associated with T‐cell activation, such as IL‐2, IL‐4 or interferon (IFN)‐γ, was also detected in migrating cells, although the cytokine profiles of different experimental animals were extremely variable.

Role of oligosaccharides in the immune response of sheep vaccinated with Lucilia cuprina larval glycoprotein, peritrophin-95

The larvae of the fly Lucilia cuprina cause a cutaneous myiasis in mammalian hosts, particularly sheep. The glycoprotein, peritrophin-95, isolated from Lucilia cuprina larval peritrophic matrix, is a candidate vaccine antigen. This protein induced an immune response in vaccinated sheep that inhibited larval growth. Recombinant forms of peritrophin-95 were produced in bacteria and baculovirus-infected insect cells. The bacterial protein was not glycosylated and incorrectly folded whereas the insect cell-expressed protein was glycosylated and probably correctly folded. Sheep immunised with purified native peritrophin-95 generated strong larval growth inhibitory activity in their sera, whereas sheep immunised with either recombinant form of peritrophin-95 generated only relatively weak inhibitory activity. Ingested ovine antibodies to native peritrophin-95 mediated the anti-larval growth activity and this was independent of the presence of ovine complement. The activity was associated with IgG(1) and IgG(2) but not IgM. There were strong antibody responses to both the correctly folded native peritrophin-95 polypeptide and the oligosaccharides present on this glycoprotein. Immuno-affinity isolation of antibody to the peritrophin-95 polypeptide and antibody to peritrophin-95 oligosaccharides demonstrated that the larval growth inhibitory activity resided with both antibodies. Lectin blots and ELISA data showed substantial differences between the oligosaccharides attached to native peritrophin-95 and insect cell-expressed recombinant peritrophin-95. It was concluded that the oligosaccharides attached to native peritrophin-95 and its unique polypeptide structure are essential for the induction of larval growth inhibitory activity in the sera of sheep vaccinated with this antigen.

Cellular immune responses in the skin of sheep infected with larvae of Lucilia cuprina, the sheep blowfly

Cellular immune responses were observed in the skin of sheep after primary and secondary infection with sheep blowfly (Lucilia cuprina) larvae. Both primary and secondary infections resulted in a massive cellular infiltration within 48 h of wound initiation, with the majority of cells having the CD45 phenotype. Neutrophils comprised the major cell type at the skin surface. In the dermis, the number of CD4+ T helper, gamma delta-TCR+ cells and T19+ (CD4-, CD8-) T cells also increased significantly in skin during both primary and secondary infections compared with control sites. However, there was no significant difference in the numbers of these cells between primary and secondary infections. An increase in the expression of the CD1 antigen on Langerhans/dendritic cells was observed, along with an apparent increase in the number of these cells in secondary lesions, with the majority of the cells being concentrated in the upper dermis and epidermis. While there was no increase in mast cells, eosinophils increased significantly during infection compared with control sites. The cellular infiltration observed following primary and secondary infections suggests polyclonal activation of T cells and their selective recruitment to the lesion site.