Adam Balic

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.

Isolation and characterization of a novel inducible mammalian galectin.

A novel mammalian galectin cDNA (ovgal11) was isolated by representational difference analysis from sheep stomach (abomasal) tissue infected with the nematode parasite, Haemonchus contortus. The mRNA is greatly up-regulated in helminth larval infected gastrointestinal tissue subject to inflammation and eosinophil infiltration. Immunohistological analysis indicates that the protein is localized in the cytoplasm and nucleus of upper epithelial cells of the gastrointestinal tract. The protein is also detected in mucus samples collected from infected abomasum but not from uninfected tissue. The restricted and inducible expression of ovgal11 mRNA and limited secretion of the protein support the hypothesis that OVGAL11 may be involved in gastrointestinal immune/inflammatory responses and possibly protection against infection.

Eosinophil interactions with Haemonchus contortus larvae in the ovine gastrointestinal tract.

Sheep were immunized by weekly oral infections with Haemonchus contortus for 9 weeks followed by anthelmintic treatment. They were challenged either 9 or 22 weeks later with PBS (sham controls) or one million exsheathed L3 surgically injected in the abomasum, and killed 24 h or 48 h later. Sheep challenged 9 weeks after immunization displayed varying degrees of tissue eosinophilia that showed a significant inverse relationship with the number of intra‐epithelial mast cells (globule leucocytes). Close association of eosinophils with tissue larvae was observed mainly in the gastric pits (24 h) or on the mucosal surface (48 h). All L3‐challenged sheep in this group had detectable globule leucocytes and tissue IL‐4 mRNA, as measured by Southern blot RT‐PCR. In contrast, sheep challenged 22 weeks after immunization had no detectable globule leucocytes or IL‐4 mRNA and although they exhibited consistent tissue eosinophilia, eosinophils were not closely associated with tissue larvae. Scanning and transmission electron microscopy of sheep sensitized and rested for 9 weeks before challenge showed that L3 surrounded by eosinophils were at varying stages of damage and structural collapse. These studies strongly indicate that eosinophils can damage and probably kill gastrointestinal nematode larvae in vivo. In addition, they also suggest that effective killing by tissue eosinophils may depend on other microenvironmental factors such as intra‐epithelial mast cells and IL‐4.

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.

Isolation, characterisation and expression of mRNAs encoding the ovine CC chemokines, monocyte chemoattractant protein (MCP)-1α and -2

CC chemokines are important mediators of immune responses, orchestrating the differential recruitment of various leukocyte populations. Despite the large number of known CC chemokines in other species, no cDNA encoding ovine CC chemokines have been isolated. A homology cloning strategy was utilised to isolate the cDNA of ovine CC chemokines. Full-length monocyte chemoattractant protein (MCP)-1alpha and -2 cDNA have been isolated. The predicted ovine MCP-1alpha amino acid sequence shares 87 and 75% identity with bovine MCP-1alpha and porcine MCP-1, respectively. The predicted ovine MCP-2 amino acid sequence shares 92 and 85% identity with bovine and porcine MCP-2, respectively. Northern blot analysis of MCP-1alpha revealed that it is strongly expressed in cells isolated from mammary lavage fluid (MAL) of ewes given intramammary infusions of Haemonchus contortus. Weak signals were detected in mammary and abomasal tissue. Southern blot analysis of reverse transcriptase-polymerase chain reaction (RT-PCR) products indicates that MCP-1alpha mRNA levels increase in abomasum after challenge with H. contortus. MCP-1alpha mRNA levels were also increased in bronchoalveolar lavage (BAL) cells and lung tissue after house dust mite extract (HDME) challenge. Similarly, MCP-2 mRNA was detected by Northern blot analysis at high levels in MAL cells after H. contortus intramammary infusion, and increased in BAL cells and lung tissue in HDME-challenged sheep. MCP-2 mRNA was not detected by Northern blots in whole mammary or abomasal tissue, but Southern blot analysis of RT-PCR products also indicates that MCP-2 mRNA increases in abomasal tissue after challenge with H. contortus. Hence, two ovine CC chemokine mRNA have been isolated that are up-regulated in response to parasite infection and allergen challenge. Ultimately the isolation of these and other ovine CC chemokines will help elucidate a wide variety of immune responses in sheep.

The antiandrogen flutamide perturbs inguinoscrotal testicular descent in the rat and suggests a link with mammary development

AIM Inadequate androgen activity is a likely cause of cryptorchidism in humans, affecting inguinoscrotal testicular descent. Flutamide, a nonsteroidal antiandrogen, produces cryptorchidism in rats. We aimed to determine the anatomical and histologic effects of flutamide. METHODS Time-mated Sprague-Dawley female rats were injected subcutaneously with flutamide (75 mg/kg in sunflower oil) on days 16 to 19 of pregnancy. Embryonic (E) and postnatal (P) male offspring were collected (E16, E19, P0, P2, P4, P8) in control and flutamide-treated groups (n = 5-10). Samples were fixed in 4% paraformaldehyde. Five-micrometer-thick sections were prepared for hematoxylin and eosin, trichrome and immunohistochemical stains (Desmin, TuJ1, Ki67). This identified muscle and neural cells and areas of cell proliferation. RESULTS Postnatally, the gubernaculum in flutamide-treated rats had more mesenchyme and muscle than controls. Gubernacular eversion failed, and mammary tissue persisted around the gubernaculum in flutamide-treated rats. Flutamide had no effect on embryonic gubernacular anatomy and histology. CONCLUSIONS Prenatal androgens altered postnatal gubernacular anatomy and histology in the postnatal period. Our findings indicate that the failure of gubernacular differentiation and migration may be because of the ongoing presence of mammary tissue in the region of the external inguinal ring.

The common fetal development of the mammary fat pad and gubernaculum

BACKGROUND/AIMS Recent work both from our laboratory and in marsupial models of testicular descent suggests a strong connection between the mammary line and gubernacular migration. This study investigated the relationship between the mammary fat pad (MFP) that underlies the mammary line and the developing gubernaculum by fluorescent immunohistochemistry. METHODS Rats at E17 and E19 were fixed and processed for immunohistochemistry. Sagittal sections of male fetuses were stained with antibodies against androgen receptor (AR), prolyl-4 hydroxylase β, Desmin, activated Notch-1, Jagged-1, and Ki-67. These were analyzed by fluorescent confocal microscopy. RESULTS At E17 and E19, the MFP anlage forms a continuous distribution of fibroblasts passing immediately adjacent the gubernaculum to the future scrotum. Within this exists a distinct subpopulation of fibroblasts expressing AR distributed over the path of inguinoscrotal descent of the gubernaculum. Proliferation and Notch-1 signaling were similar throughout the MFP with differential Notch-1 signaling in the E19 gubernaculum. CONCLUSION This investigation has identified the presence of a distinct AR-expressing subpopulation of MFP fibroblasts over the path of inguinoscrotal descent during the key androgenic programming window of this phase. This unique developmental pattern is consistent with a prime role for the MFP in testicular descent.

Development of the Gubernaculum During Testicular Descent in the Rat

Gubernacular elongation during inguinoscrotal testicular descent and cremaster muscle development remains poorly described in mammals. The role of the genitofemoral nerve (GFN) remains elusive. We performed detailed histological analysis of testicular descent in normal rats to provide a comprehensive anatomical description for molecular studies. Fetuses and neonatal male offspring (5–10 per group) from time‐mated Sprague‐Dawley dams (embryonic days 15, 16, and 19; postnatal days 0, 2, and 8) were prepared for histology. Immunohistochemistry was performed for nerves (Class III tubulin, Tuj1) and muscle (desmin). At embryonic days 15 and 16, the gubernaculum and breast bud are adjacent and both supplied by the GFN. By embryonic day 19, the breast bud has regressed and the gubernacular swelling reaction is completed. Postnatally, the gubernacular core regresses, except for a cranial proliferative zone. The cremaster is continuous with internal oblique and transversus abdominis. By postnatal day 2 (P2), the gubernaculum has everted, locating the proliferative zone caudally and the residual mesenchymal core externally. Eversion creates the processus vaginalis, with the everted gubernaculum loose in subcutaneous tissue but still remote from the scrotum. By P8, the gubernaculum has nearly reached the scrotum with fibrous connections attaching the gubernaculum to the scrotal skin. A direct link between GFN, gubernaculum, and breast bud suggests that the latter may be involved in gubernacular development. Second, the cremaster muscle is continuous with abdominal wall muscles, but most of its growth occurs in the distal gubernacular tip. Finally, gubernacular eversion at birth brings the cranial proliferative zone to the external distal tip, enabling gubernacular elongation similar to a limb bud. Anat Rec, 2011.

Cremaster Muscle Myogenesis in the Tip of the Rat Gubernaculum Supports Active Gubernacular Elongation During Inguinoscrotal Testicular Descent

PURPOSE Cryptorchidism is a common abnormality and normal testicular descent is controlled by the gubernaculum. The cremaster may originate from abdominal muscles during gubernacular eversion or alternatively it may develop inside the gubernaculum. We studied cremaster myogenesis to determine how it develops. MATERIALS AND METHODS Coronal sections of the pelvis were prepared from male Sprague-Dawley® rats and from males treated prenatally with the antiandrogen flutamide at embryonic day 19, and postnatal days 10, 19 and 35 after receiving ethical approval. Immunohistochemical stains were prepared for Ki67, Pax-7, myogenin, myosin heavy chain 7, Myh1, Myh2, Myh4, embryonic myosin, and slow and cardiac troponin T. Cell counts of the 1) gubernacular tip, 2) proximal gubernaculum/cremaster muscle and 3) adjacent abdominal wall are shown as a percent of positive fibers or positive cells per area. RESULTS Throughout embryonic day 19, and postnatal days 10 and 19 proliferation (Ki67) was maximal at the gubernacular tip (p <0.001), as were muscle stem cells markers (Pax-7 p <0.05), early myogenesis (myogenin p <0.001) and immature muscle (Myh7, and slow and cardiac troponin T p <0.0001). In contrast, secondary (fast twitch, Myh1, 2 and 4) fibers were more common in abdominal muscles (p <0.0001). Differences in muscle maturity and composition decreased with time. Flutamide treated rats showed more cellular proliferation than controls postnatally on postnatal day 10 (p <0.001) as well as persistent immature embryonic myosin at the tip from postnatal day 19 (p <0.05). CONCLUSIONS Results show that the rat cremaster muscle is more immature at the gubernacular tip, consistent with myogenesis occurring in the gubernaculum during migration to the scrotum, as proposed in humans.