Trichobilharzia regenti: host immune response in the pathogenesis of neuroinfection in mice

Besides their natural bird hosts, Trichobilharzia regenti cercariae are able to penetrate skin of mammals, including humans. Experimental infections of mice showed that schistosomula of this species are able to avoid the immune response in skin of their non-specific mammalian host and escape the skin to migrate to the CNS. Schistosomula do not mature in mammals, but can survive in nervous tissue for several days post infection. Neuroinfections of specific bird hosts as well as accidental mammalian hosts can lead to neuromotor effects, for example, leg paralysis and thus this parasite serves as a model of parasite invasion of the CNS.Here, we show by histological and immunohistochemical investigation of CNS invasion of immunocompetent (BALB/c) and immunodeficient (SCID) mice by T. regenti schistosomula that the presence of parasites in the nervous tissue initiated an influx of immune cells, activation of microglia, astrocytes and development of inflammatory lesions. Schistosomula elimination in the tissue depended on the host immune status. In the absence of CD3+ T-cells in immunodeficient SCID mice, parasite destruction was slower than that in immunocompetent BALB/c mice. Axon injury and subsequent secondary demyelination in the CNS were associated with mechanical damage due to migration of schistosomula through the nervous tissue, and not by host immune processes. Immunoreactivity of the parasite intestinal content for specific antigens of oligodendrocytes/myelin and neurofilaments showed for the first time that schistosomula ingest the nervous tissue components during their migration.     

Schistosoma mansoni: topochemical features of cercariae, schistosomula, and adults

The teguments of developing and mature cercariae, recently transformed, and 1-wk-old schistosomula and adult worms were examined for the ultrastructural location of macromolecular carbohydrates and polyelectrolytes. The surface of mature cercariae within sporocysts and cercariae released from the snail is covered by a filamentous coat which reacts with cytochemical reagents for the demonstration of vicinal glycols, but neither the coat nor the surface of the tegument plasmalemma binds cationic colloidal iron at low pH.Upon penetrating mammalian skin, the cercaria sheds its surface coat; the tegument surface of newly transformed schistosomula, older schistosomula and adult worms stains en bloc with acidic colloidal iron, as does the tegument plasmalemma of mature cercariae if the overlying filamentous coat is first removed by physicochemical means. The cercarial coat thus serves to mask anionic groups at the surface of the tegument plasmalemma which become functionally exposed after penetration of the mammalian host. The distribution of colloidal iron binding sites coincides with those for the carbohydrate-complexing phytohemmagglutnin, concanavalin A, which suggests that these membrane-fixed anions are acid mucopolysaccharides, glycoproteins or glycolipids. Carbohydrate-containing material was also localized within membrane-bound vesicles of the tegument matrix and perikarya of developing cercariae and postcercarial schistosomes, suggesting that surface mucosubstances contributing to the tegument glycocalyx of these worms are elaborated, at least in part, by the tegument itself.     

Schistosoma mansoni and Biomphalaria glabrata have some common epitopes. I. Common epitopes are present on the surface of early stages of S. mansoni.

1. The presence of snail and glycocalyx antigens in the Schistosoma mansoni cercarial surface and their permanence throughout development in vitro and in vivo was investigated. 2. Rabbit antisera raised against two fractions of glycocalyx released from cercariae and Biomphalaria glabrata soft tissues or haemolymph were obtained. 3. All four antisera bound to cercariae and schistosomula kept in vitro or in vivo for up to 24 hr. 4. No binding to schistosomula kept in vivo for 5 days or longer was observed. 5. Schistosomula cultured in vitro for up to 12 days bound the antisera throughout the period of culture.     

Proteomic analysis of human skin treated with larval schistosome peptidases reveals distinct invasion strategies among species of blood flukes

Background

Skin invasion is the initial step in infection of the human host by schistosome blood flukes. Schistosome larvae have the remarkable ability to overcome the physical and biochemical barriers present in skin in the absence of any mechanical trauma. While a serine peptidase with activity against insoluble elastin appears to be essential for this process in one species of schistosomes, Schistosoma mansoni, it is unknown whether other schistosome species use the same peptidase to facilitate entry into their hosts.

Methods

Recent genome sequencing projects, together with a number of biochemical studies, identified alternative peptidases that Schistosoma japonicum or Trichobilharzia regenti could use to facilitate migration through skin. In this study, we used comparative proteomic analysis of human skin treated with purified cercarial elastase, the known invasive peptidase of S. mansoni, or S. mansoni cathespin B2, a close homolog of the putative invasive peptidase of S. japonicum, to identify substrates of either peptidase. Select skin proteins were then confirmed as substrates by in vitro digestion assays.

Conclusions

This study demonstrates that an S. mansoni ortholog of the candidate invasive peptidase of S. japonicum and T. regenti, cathepsin B2, is capable of efficiently cleaving many of the same host skin substrates as the invasive serine peptidase of S. mansoni, cercarial elastase. At the same time, identification of unique substrates and the broader species specificity of cathepsin B2 suggest that the cercarial elastase gene family amplified as an adaptation of schistosomes to human hosts.     

Bird schistosomes: do they die in mammalian skin?

The cercariae of bird schistosomes, released from the intermediate water snail host, actively penetrate the skin of both birds and mammals. Whereas in birds the infection leads to worm maturation and egg production, in the mammalian hosts skin invasion is accompanied by cercarial dermatitis (swimmer's itch, clam-digger's disease) and the fate of the parasites is not clear. Here, we review bird schistosomes as causative agents of cercarial dermatitis, underline adaptations of bird schistosomes to their life in vertebrate hosts, and discuss potential risks caused by the parasites migrating in humans.     

The cercarial glycocalyx of Schistosoma mansoni

Cercariae, the freshwater stage of Schistosoma mansoni infectious to man, are covered by a single unit membrane and an immunogenic glycocalyx. When cercariae penetrate the host skin, they transform to schistosomula by shedding tails, secreting mucous and enzymes, and forming microvilli over their surface. Here the loss of the glycocalyx from cercariae transforming in vitro was studied morphologically and biochemically. By scanning electron microscopy, the glycocalyx was a dense mesh composed of 15-30 nm fibrils that obscured spines on the cercarial surface. The glycocalyx was absent on organisms fixed without osmium and was partially lost when parasites aggregated in their own secretions before fixation. By transmission electron microscopy, a 1-2 microns thick mesh of 8-15-nm fibrils was seen on parasites incubated with anti-schistosomal antibodies or fixed in aldehydes containing tannic acid or ruthenium red. Cercariae transformed to schistosomula when tails were removed mechanically and parasites were incubated in saline. Within 5 min of transformation, organisms synchronously formed microvilli which elongated to 3-5 microns by 20 min and then were shed. However, considerable fibrillar material remained adherent to the double unit membrane surface of schistosomula. For biochemical labeling, parasites were treated with eserine sulfate, which blocked cercarial swimming, secretion, infectivity, and transformation to schistosomula. Material labeled by periodate oxidation and NaB3H4 was on the surface as shown by autoradiography and had an apparent molecular weight of greater than 10(6) by chromatography. Periodate-NaB3H4 glycocalyx had an isoelectric point of 5.0 +/- 0.4 and was precipitable with anti-schistosomal antibodies. More than 60% of the radiolabeled glycocalyx was released into the medium by transforming parasites in 3 h and was recovered as high molecular weight material. Parasites labeled with periodate and fluorescein-thiosemicarbazide and then transformed had a corona of fluorescence containing microvilli, much of which was shed onto the slide. Material on cercariae labeled by lodogen-catalyzed iodination was also of high molecular weight and was antigenic. In conclusion, the cercarial glycocalyx appears to be composed of acidic high molecular weight fibrils which are antigenic and incompletely cleared during transformation.     

Schistosoma mansoni: a comparative study of artificially transformed schistosomula and schistosomula recovered after cercarial penetration of isolated skin.

A comparison was made of the ultrastructure, development and antigenic nature of the surfaces and of the viability of three types of Schistosoma mansoni: schistosomula formed after cercariae had penetrated isolated skin (SS) schistosomula produced after mechanical separation of cercarial tails from bodies (MS), and schistosomula transformed from cercariae after incubation in fresh rat serum (RS). Within 2h of transformation, the surface membranes of all three types of schistosomula had changed from trilaminate to heptalaminate structures and SS and MS had lost their cercarial glycocalyx. Initially a dense amorphous material was demonstrated on the surfaces of RS, which was thought to be the result of an interaction between a factor in rat serum and the glycocalyx; this material was greatly reduced within 2 h of transformation. The pre-acetabular glands of SS were emptied while those of MS and RS retained their contents. Immunofluorescent studies showed that all schistosomula bound serum from mice immune to S. mansoni, but the binding was stronger with MS and RS. The mixed agglutination reaction demonstrated the presence of human A and B blood group-like antigenic determinants on approximately 30% of 3h old SS; these determinants were not detected on MS or RS. In vitro, the development of MS and RS was similar to SS; the first schistosomula reached the "gut-closed" stage by day 10; 50-70% of SS reached this stage by day 12, in contrast to only 25-50% of MS and RS. Between 28 and 45% of all schistosomula developed to maturity when injected intravenously into mice. It was concluded that the two types of artificially prepared schistosomula fulfil the main criteria of transformation from cercaria to schistosomulum. Further, it is suggested that MS are the most appropriate source of material for immunochemical and physiological studies.     

Schistosoma mansoni: increasing saline concentration signals cercariae to transform to schistosomula

Cercariae of S. mansoni shed the surface glycocalyx, form a double lipid bilayer on their surface, and transform to schistosomula when tails are removed and parasites are transferred from pond water to 300 mOsm phosphate-buffered saline. To determine whether the absolute concentration of saline or the relative change in saline concentration was the signal for surface transformation, cercariae were isolated from the snail hepatopancreas, sheared to remove the tails, and incubated in defined media for 3 hr at 37 degrees C. Surface transformation was assayed using the binding of the fluorescein-conjugated lectin concanavalin A to the schistosomular double unit membrane but not to the cercarial glycocalyx. An increase in salinity either from 18 mOsm (artificial pond water) to 120 mOsm (the snail osmolarity) or from 120 to 300 mOsm (the mammalian osmolarity) triggered transformation to schistosomula. Organisms constantly exposed to 120 mOsm or shifted from 120 mOsm to pond water did not transform their surfaces. The signal for transformation appeared to be increasing salinity rather than increasing osmolarity because cercarial bodies did not become schistosomula in 300 mOsm mannitol. Surface transformation was inhibited when cercariae were incubated with the acetylcholinesterase inhibitor eserine sulfate during a 10 min time when the osmolarity was raised. We conclude that increasing salinity rather than the absolute saline concentration is the signal for surface transformation and that eserine sulfate may inhibit the receipt of this signal.     

Individual and population variation in cercariae of bird schistosomes of the <Emphasis Type="Italic">Trichobilharzia ocellata</Emphasis> species group as revealed with the polymerase chain reaction

The polymerase chain reaction with arbitrary (RAPD-PCR) or specific primers was used to study the population variation and to identify the species in cercariae of schistosomes of the Trichobilharzia ocellata species group (Trematoda, Schistosomatidae). In total, 28 cercariae were obtained from two spontaneously invaded mollusks Lymnaea stagnalis (LS) and L. ovata (LO), which were collected in different ponds of Moscow. RAPD-PCR was carried out with two arbitrary primers, OPA9 and OPB11, which each detected different levels of individual and among-group variation and revealed considerable genetic differentiation of cercariae from different host mollusks. To check whether the cercariae of the two samples belong to one species, sequencing was performed with a region corresponding to intergenic transcribed spacer 2 (ITS2), which was earlier proposed for cercaria identification in three European species of bird schistosomes of the genus Trichobilharzia (T. franki, T. regenti, and T. szidati). The ITS2 sequences of two LO cercariae were identical, each consisted of 319 bp, and showed 100% homology to the T. franki ITS2 sequence. The ITS2 sequences of two LS cercariae were identical, each consisted of 323 bp, and showed 99.4% homology to the T. szidati counterpart. The causes of genetic variation in cercariae and prospects of using RAPD markers to study different stages of the life cycle in trematodes are discussed.Translated from Genetika, Vol. 41, No. 1, 2005, pp. 17–22.Original Russian Text Copyright © 2005 by Semyenova, Chrisanfova, Filippova, Beer, Voronin, Ryskov.     

Schistosoma mansoni: immunogenic glycoproteins of the cercarial glycocalyx

Immunochemical studies at the level of the light and electron microscope showed that a monoclonal antibody, 128C3/3, was directed to an epitope in the glycocalyx of Schistosoma mansoni cercariae. Immunoprecipitation of surface labeled cercarial extracts with this monoclonal antibody demonstrated that the glycocalyx is composed of at least five components, including a very large molecular size polypeptide and polypeptides of 220, 180, 170, and 15 kDa. After transformation of cercariae to schistosomula, these polypeptides were shed from the surface and were therefore no longer accessible to surface labeling. Monoclonal antibody 128C3/3 was also reactive with a 38 kDa polypeptide from schistosomula; this polypeptide was weakly expressed on the surface of cercariae. Analysis of immunoprecipitates of radioiodinated protein extracts of cercariae, newly transformed schistosomula, and 36 hr in vitro cultured schistosomula showed that the 180 and 170 kDa polypeptides continued to be expressed within the organism following transformation, but were not accessible to surface labeling. Lectin binding studies revealed differences in the oligosaccharide composition of the six polypeptides. With the exception of the 15 kDa antigen, all the polypeptides reactive with 128C3/3 were highly immunogenic in infected mice and humans.     

Evidence that a protective membrane epitope is involved in early but not late phase immunity in Schistosoma mansoni

An anti-egg monoclonal antibody E.1, which is partially protective in passive transfer experiments, is shown in this study to recognize a membrane epitope on cercariae, schistosomula, and the ciliary plates of miracidia. E.1 did not bind to the surface membranes of lung or adult worms, or recognize secreted egg antigen in infected liver tissue. The E.1 epitope was present in the glycocalyx of cercariae, as well as on the syncytial membrane as determined by electron microscopy. Immunoprecipitation of iodinated surfaces of cercariae and schistosomula demonstrated E.1 binding to a high m.w. moiety in cercariae, which corresponds to the glycocalyx because it was not immunoprecipitated from schistosomula. In addition, a band at 38,000 daltons was immunoprecipitated from both cercariae and schistosomula. When compared with in vitro cultured parasites, schistosomula that were obtained from mice 1 to 24 hr after tail vein injection showed significant loss of E.1 binding. Consistent with the rapid loss of antigen in vivo, E.1 antibody was unable to passively transfer protection to naive mice when administered 5 days after cercarial challenge.     

Polymorphism of the <Emphasis Type="Italic">cox1</Emphasis> gene in cercariae isolates of bird schistosomes (Trematoda:Schistosomatidae) from ponds of Moscow and Moscow region

Polymorphism of a 810-bp fragment of mitochondrial cox1 gene was studied in 15 cercariae isolates of bird schistosomes (family Schistosomatidae), which were collected in water bodies of Moscow and Moscow oblast and represented three species: Trichobilharzia szidati, T. franki, and T. regenti. A substantial predominance of AT (65.4%) was characteristic of the cox1 sequences in all three species. Rare single nucleotide substitutions determined low (0.2–0.9%) intraspecific nucleotide and amino acid sequence diversity. Haplotype diversity h was high (80–100%) in all three species, suggesting a unique character for almost all cox1 sequences in the sample. Phylogenetic trees based on the nucleotide and amino acid sequence variations were constructed to study the relationships of the three schistosome species. A high support was observed for the main branching node that reflects differentiation of the monophyletic group Trichobilharzia and species of the genera Bilharziella (B. polonica), Dendritobilharzia (D. pulverulenta), and Gigantobilharzia (G. huronensis). Based on the nucleotide substitutions and amino acid polymorphisms, two groups of isolates, which parasitize Lymnaea stagnalis (T. szidati) and snails of the group Radix (T. franki and T. regenti) respectively, were isolated in the genus Trichobilharzia. The time of divergence between the two schistosome groups infecting snails of the genera Radix and Lymnaea was calculated from the cox1 nucleotide substitution rate, which is known for Asian and Indian blood flukes from the genus Schistosoma and is 2–3% per million years on average. Divergence of the three bird schistosome species under study and divergence of the Asian species of mammalian schistosomes were almost concurrent, dating back to 2.5–3.8 Myr ago. Factors responsible for the lack of intraspecific subdivision with respect to the cox1 in bird schistosomes and the lack of separation between two species (T. franki and T. regenti) are discussed.     

Survival of bird schistosomes in mammalian lungs

Bird schistosome cercariae have a low specificity to vertebrate skin and, thus, they are also able to penetrate into mammals. As a consequence, a hypersensitive skin response-cercarial dermatitis-develops. It was thought that the parasites die in the skin soon after penetration. Our results on Trichobilharzia szidati and Bilharziella polonica in the non-specific murine host confirm that some of the penetrating bird schistosomes may fully transform to schistosomula and migrate to the lungs. They persist there for up to 10days post exposure. In a duck, the worms grow and feed rapidly, but in a mouse the lung schistosomula seem to be inhibited in their development. However, TEM results show that there is no damage to the tegument of these larvae and no immune effector cells attack the parasites. These results suggest that the parasite's failure in the murine host might be caused by some immunologically unrelated factors.     

Intermediate host antigens associated with the cercariae of Schistosoma haematobium.

Bulinus (Physopsis) africanus antigens were shown to be associated with the cercarial glycocalyx of Schistosoma haematobium using immunofluorescence and the Cercarienhüllen Reaktion. It is proposed that this snail antigen may sensitise the definitive host and that resistance to further invasion by cercariae could be induced in this manner.     

Schistosoma mansoni: development of the cercarial glycocalyx

The development of the cercarial glycocalyx of Schistosoma mansoni was studied by transmission electron microscopy and immunofluorescence light microscopy employing antibodies raised against extracted and chromatographed glycocalyx. By electron microscopy, cercariae present in the brood chamber of daughter sporocysts were surrounded by an electron-dense granular and fibrillar matrix. This material appeared structurally distinct from the glycocalyx which was coarsely fibrillar and located only on the surface of organisms that had developed a final tegument. The thickness of the glycocalyx apparently increased with the maturation of the tegument, since teguments that had many spines also had the thickest glycocalyx. Immunofluorescent staining of frozen sections of infected snail hepatopancreas showed that glycocalyx antigens were present on the surface of the cercariae and not in the matrix within the brood chamber or in snail tissues. Immunofluorescent staining of isolated larval cercariae showed staining of some but not all parasites with partially elongated tails. These studies suggest that the glycocalyx develops late in cercarial development (late in Stage 6 or in Stage 7 of Cheng and Bier), is made by the cercariae themselves, and is not a product of either the sporocyst wall cells or snail hepatopancreas.     

Surface antigens on cercariae,schistosomula and adult worms of Schistosoma mansoni

Shah J. and Ramasamy R. 1982. Surface antigens on cercariae, schistosomula and adult worms of Schistosoma mansoni. International Journal for Parasitology12: 451–461. The surface protein antigens of Schistosoma mansoni were radiolabelled by lactoperoxidase catalysed I¹²⁵-iodination and analysed by immune-precipitation and polyacrylamide gel electrophoresis. The results showed that regularly labelled surface antigens of mol. wts >150,000, 78,000, 45,000 and 22,000 were present on adult worms. Common surface antigens were observed on the cercariae, schistosomula and adult worms. It is suggested that surface antigens released from living adult worms can sensitise a host to react against the invading schistosomula of a secondary infection. However, the failure to vaccinate mice using material containing adult worm surface antigens suggests that the induction of protective immunity is a complex phenomenon.