Joseph F. Urban

Intestinal epithelial cell secretion of RELM-β protects against gastrointestinal worm infection

Th2 cells drive protective immunity against most parasitic helminths, but few mechanisms have been demonstrated that facilitate pathogen clearance. We show that IL-4 and IL-13 protect against intestinal lumen-dwelling worms primarily by inducing intestinal epithelial cells (IECs) to differentiate into goblet cells that secrete resistin-like molecule (RELM) β. RELM-β is essential for normal spontaneous expulsion and IL-4–induced expulsion of Nippostrongylus brasiliensis and Heligmosomoides polygyrus, which both live in the intestinal lumen, but it does not contribute to immunity against Trichinella spiralis, which lives within IEC. RELM-β is nontoxic for H. polygyrus in vitro but directly inhibits the ability of worms to feed on host tissues during infection. This decreases H. polygyrus adenosine triphosphate content and fecundity. Importantly, RELM-β–driven immunity does not require T or B cells, alternative macrophage activation, or increased gut permeability. Thus, we demonstrate a novel mechanism for host protection at the mucosal interface that explains how stimulation of epithelial cells by IL-4 and IL-13 contributes to protection against parasitic helminthes that dwell in the intestinal lumen.

Heligmosomoides polygyrus: CD4+ but not CD8+ T cells regulate the IgE response and protective immunity in mice

Oral inoculation of BALB/c mice with infective larvae of Heligmosomoides polygyrus resulted in chronic infection characterized by the release of parasite eggs in the feces for several months. The actual number of eggs per gram of feces was dependent on the dose of the inoculum. Serum IgE in infected mice peaked at a level of greater than 70 micrograms/ml during Weeks 3 through 6 following inoculation, and high levels of IgE (greater than 40 micrograms/ml) persisted for over 14 weeks. Protective immune responses resulted in reduced egg production and the development of markedly fewer adult worms in the small intestines following a challenge inoculation. The role of CD4+ and CD8+ T cells in these responses was examined by depletion in vivo of either T cell subpopulation with rat mAb specific for the appropriate determinants. Mice treated with anti-CD4 during a primary infection had increased EPG which was due primarily to an increase in worm fecundity (eggs produced per adult female). A challenge inoculation of mice that had been cleared of the primary infection with an anthelmintic drug induced a protective response that reduced development of new adult worms by 70-80% and their fecundity by greater than 90%. This protective response was abrogated by injection of mice with anti-CD4. Serum IgE diminished when adult worms were removed after anthelmintic treatment. A more precipitous drop in serum IgE followed successive treatments of mice with an anthelmintic and anti-CD4. In addition, the anamnestic serum IgE response to a challenge inoculation was reduced by over 80% in anti-CD4-treated mice. Anti-CD8 treatment had no appreciable effect on the immunological or parasitological parameters measured following a challenge inoculation with H. polygyrus. Thus, CD4+ T cells regulate host protective immunity, worm fecundity, and IgE levels in an H. polygyrus infection. This experimental system may be particularly suitable for analysis of chronic nematode infections of humans and livestock because of the responsiveness of the parasite in vivo to changes in host immune function.

The effect of immunization of pigs with Ascaris suum cuticle components on the development of resistance to parenteral migration during a challenge infection

The development of immunity to Ascaris suum was studied in pigs immunized with isolated cuticle fragments from A. suum second and third stage larvae (L2/L3) and adult worms, and compared with other methods that stimulate a strong protective response in pigs. A significant protective response was seen in animals immunized with isolated cuticle fragments from A. suum L2/L3 and adults, but it was less than that seen in animals inoculated with UV-irradiated eggs or naturally exposed to eggs on a dirt lot. Significant IgG responses to 2-mercaptoethanol (2ME)-soluble cuticle components were seen in all groups, but the level of the antibody response did not relate to protection. Group differences in antibody and lymphocyte blastogenic responses to cuticle proteins indicated quantitative and qualitative stage specific differences in 2ME-soluble and insoluble cuticular proteins. Intestinal immunity was notably absent from cuticle immunized pigs because a marked liver white spot response was observed following the challenge inoculation. Thus, cuticle fragments from larval and adult A. suum are capable of inducing a protective response to larval migration; however, the development of intestinal immunity is not a direct function of exposure to these antigens.

Ascaris suum: cDNA microarray analysis of 4th stage larvae (L4) during self-cure from the intestine

There is spontaneous cure of a large portion of Ascaris suum 4th-stage larvae (L4) from the jejunum of infected pigs between 14 and 21 days after inoculation (DAI). Those L4 that remain in the jejunum continue to develop while those that have moved to the ileum are eventually expelled from the intestines. Although increases in intestinal mucosal mast cells and changes in local host immunity are coincidental with spontaneous cure, the population of L4 that continue to develop in the jejunum may counteract host protective mechanisms by the differential production of factors related to parasitism. To this end, a cDNA library was constructed from L4 isolated from pig jejunum at 21 DAI, and 93% of 1920 original clones containing a single amplicon in the range 400-1500 bp were verified by gel electrophoresis and printed onto glass slides for microarray analysis. Fluorescent probes were prepared from total RNA isolated from: (1) 3rd stage-larvae from lung at 7 DAI, (L3); (2) L4 from jejunum at 14 DAI (L4-14-J); (3) L4 from jejunum at 21 DAI (L4-21-J); (4) L4 from ileum at 21 DAI (L4-21-I, and; (5) adults (L5). Cy3-labeled L3, L4-14-J, L4-21-I and L5 cDNA, and Cy5-labeled L4-21-J cDNA were simultaneously used to screen the printed arrays containing the L4-21-J-derived cDNA library. Several clones showed consistent differential gene expression over two separate experiments and were grouped into 3 distinct transcription patterns. The data showed that sequences from muscle actin and myosin, ribosomal protein L11, glyceraldehyde-3-phosphate dehydrogenase and the flavoprotein subunit of succinate dehydrogenase were highly expressed in L4-21-J, but not in L4-21-I; as were a collection of un-annotated genes derived from a worm body wall-hypodermis library, and a testes germinal zone tissue library. These results suggest that only actively developing A. suum L4 are destined to parasitize the host and successfully neutralize host protective responses.

A Trichuris specific diagnostic antigen from culture fluids of Trichuris suis adult worms.

Trichuris suis is a nematode parasite of swine which can cause serious pathology in infected pigs, such as anorexia, diarrhea, anemia, and death in heavy infections, especially in young animals. Infection with Trichuris suis is difficult to diagnose because much of the pathology occurs when only larval stages are present, and because of sporadic egg production by adult female worms. We have isolated a 20 kDa excretory/secretory (E/S) glycoprotein from culture fluids of adult worms by column chromatography and preparative gel electrophoresis which is diagnostic for Trichuris suis infection in pigs. The antigen did not crossreact in Western blots or enzyme-linked immunosorbent assay with sera from pigs infected with Ascaris suum, Trichinella spiralis, Oesophagostomum dentatum, or Toxoplasma gondii. The antigen was also diagnostic for Trichuris vulpis infection in dogs, and did not crossreact with sera from dogs infected with Toxocara canis, Ancylostoma caninum, or Strongyloides stercoralis. The antigen may be useful in clinical serologic assays for diagnosis of Trichuris infection in pigs and dogs in cases of scouring diarrhea of unknown etiology, and in epidemiological surveys of Trichuris suis infection in swine feeder/finishing operations.

Resource limitation alters the consequences of co-infection for both hosts and parasites

Most animals are concurrently infected with multiple parasite species and live in environments with fluctuating resource availability. Resource limitation can influence host immune responses and the degree of competition between co-infecting parasites, yet its effects on individual health and pathogen transmission have not been studied for co-infected hosts. To test how resource limitation affects immune trade-offs and co-infection outcomes, we conducted a factorial experiment using laboratory mice. Mice were given a standard or low protein diet, dosed with two species of helminths (alone and in combination), and then challenged with a microparasite. Using a community ecology trophic framework, we found that co-infection influenced parasite survival and reproduction via host immunity, but the magnitude and direction of responses depended on resources and the combination of co-infecting parasites. Our findings highlight that resources and their consequence for host defenses are a key context that shapes the magnitude and direction of parasite interactions.

An in-depth comparison of the porcine, murine and human inflammasomes; lessons from the porcine genome and transcriptome.

Emerging evidence suggests that swine are a scientifically acceptable intermediate species between rodents and humans to model immune function relevant to humans. The swine genome has recently been sequenced and several preliminary structural and functional analysis of the porcine immunome have been published. Herein we provide an expanded in silico analysis using an improved assembly of the porcine transcriptome that provides an in depth analysis of genes that are related to inflammasomes, responses to Toll-like receptor ligands, and M1 macrophage polarization and Escherichia coli as a model organism. Comparisons of the expansion or contraction of orthologous gene families indicated more similar rates and classes of genes in humans and pigs than in mice; however several novel porcine or artiodactyl-specific paralogs or pseudogenes were identified. Conservation of homology and structural motifs of orthologs revealed that the overall similarity to human proteins was significantly higher for pigs compared to mouse. Despite these similarities, two out of four canonical inflammasome pathways, Absent in melanoma 2 (AIM2) and NLR family and CARD domain containing 4 (NLRC4), were found to be missing in pigs. Pig M1 Mφ polarization in response to interferon-γ (IFN-γ) and lipopolysaccharide (LPS) was assessed, via the transcriptome, using next generation sequencing. Our analysis revealed predominantly human-like responses however some, mouse-like responses were observed, as well as induction of numerous pig or artiodactyl-specific genes. This work supports using swine to model both human immunological and inflammatory responses to infection. However, caution must be exercised as pigs differ from humans in several fundamental pathways.

Biotin as a probe of the surface of Ascaris suum developmental stages

Sulfo-NHS-biotin (aqueous soluble) and NHS-biotin (organic soluble) labeled similar SDS-2ME (sodium dodecyl sulfate/beta-mercaptoethanol) soluble cuticular proteins of second stage larvae (L2) and third stage Ascaris suum larvae (L3). Comparable analysis of biotin-labeled fourth stage larvae (L4), young adults, and mature adult Ascaris suum revealed strong labeling of several SDS-2ME soluble cuticular proteins with NHS-biotin, while sulfo-NHS-biotin appeared to strongly label a single SDS-2ME soluble cuticular protein. Both biotin probes labeled only cuticular proteins, since no evidence of internal labeling was observed in any developmental stage examined by either electroblot analysis or by electron microscopy. Our data suggest a greater cuticular permeability to the organic soluble biotin reagent in the later developmental stages (greater than L3) of A. suum than to the aqueous soluble biotin reagent, and may indicate the presence of a hydrophobic barrier in the cuticle of the later stages of the parasite.

Cellular basis of the non-specific potentiation of the immunoglobulin E response after helminth parasite infection.

Helminth parasites induce a substantial increase in the production of immunoglobulin E (IgE) by the host after infection. Only a portion of the IgE antibody produced is specific for parasite-derived antigens since production of IgE antibody to non-parasite-derived antigens is also stimulated after infection. Investigators have recently observed, in the parasite-infected host, the appearance of both T and B lymphocytes that synthesize lymphokines that affect the production of IgE in vitro. The results of some of these studies will be reviewed presently, and the possible role of lymphokines in the increase of IgE production after helminth infection will be discussed.

Ascaris suum: Stage-specific differences in lectin binding to the larval cuticle

A glycosylated component with affinity for wheat germ agglutinin (specific binding to n-acetyl-D-glucosamine monomers and oligomers) and weak affinity for poke weed mitogen (specific binding to n-acetyl-D-glucosamine oligomers) was detected temporally on the surface of Ascaris suum larvae developing in vitro and on in vivo-derived larvae. The component was identified on the surface of in vitro-derived late second stage larvae, on all late third stage larvae (derived from pig lung), and all fourth stage larvae (obtained from pig intestines and from in vitro culture) of A. suum. None of the newly hatched first molt, L2, or early L3 bound any of the lectins tested. The component exhibited no affinity for concanavalin A (specific binding to alpha-D-mannosyl and alpha-D-glucosyl residues) or Dolichos biflorus lectin (specific binding to n-acetyl-D-galactosamine). A component with similar lectin binding specificities had previously been found on the cuticle of adult A. suum.