Kathy M. Davern

Comparison of the cloned genes of the 26- and 28-kilodalton glutathione S-transferases of Schistosoma japonicum and Schistosoma mansoni

Both Schistosoma japonicum and S. mansoni contain 28- and 26-kDa glutathione S-transferases (GSTs). Despite their immunological cross-reactivity using rabbit antisera, the S. japonicum 28-kDa GST (Sj28) is weakly immunogenic relative to the S. mansoni protein (Sm28) in mouse immunization experiments using GSTs purified from adult worms. The difference in immunogenicity is also observed during schistosome infection in mice. Using surface-labeled living S. japonicum worms, evidence was obtained for a surface location of Sj28 comparable to that reported for the S. mansoni molecule. The nucleotide and deduced amino acid sequences of cDNA clones corresponding to Sj28 and Sm28 were compared. Despite obvious homology (77% identity), differences were found in regions known to contain T epitopes in the S. mansoni protein which may be an explanation for the striking differences in immunogenicity in regard to antibody production in mice. The 26-kDa GSTs of these two parasites (Sj26 and Sm26) are also closely related on the basis of nucleotide and deduced amino acid sequences, there being 82% identity in the putative coding regions. When the amino acid sequences of Sj28 and Sm28 were compared with those of Sj26 and Sm26, the overall sequence identity was approximately 20%. However, a relatively conserved region was identified in otherwise structurally different molecules which may participate in common properties of these enzymes.

Expression of an enzymatically active parasite molecule in Escherichia coli: Schistosoma japonicum glutathione S-transferase.

The NH2-terminal amino acid sequence of the Mr 26 000 glutathione S-transferase (EC 2.5.1.18) of Schistosoma japonicum (Sj26) has been deduced by RNA and protein sequence analysis. Using this information, a bacterial plasmid has been constructed that directs the synthesis of the entire Sj26 molecule in Escherichia coli. Recombinant Sj26 exhibits glutathione S-transferase activity and can be readily purified from bacteria in a one-step procedure under non-denaturing conditions. The availability of recombinant Sj26 in essentially unlimited quantities will aid its assessment as a candidate vaccine molecule in schistosomiasis and could eventually lead to the rational design of a drug targetted on schistosome glutathione S-transferases.

Molecular and serological characteristics of the glutathione S‐transferases of Schistosoma japonicum and Schistosoma mansoni

Summary When aqueous extracts of Schistosoma japonicum and S. mansoni adult worms are passed over columns of glutathione‐conjugated agarose, two molecular species of Mr 26000 and Mr 28000 are detected in eluates as analysed by SDS‐PAGE, these eluates having glutathione S‐transferase (GST) activity. The molecules, termed Sj26 and Sj28 from S. japonicum and Sm26 and Sm28 from S. mansoni, can be immunogenic in rabbits or mice and appear not to be linked together as subunits of GST heterodimers. The elution profile of SjGST (Sj26 + Sj28) from glutathione columns resembles that of SmGST (Sm26 + Sm28) and, by peptide mapping, radioiodinated Sj26 and Sm26 are related as are the two Mr28000 molecules. Similarities between radioiodinated Sj2S and Sm28 are also obvious on two‐dimensional gel electrophoresis with some differences being observed between Sj26 and Sm26. The Mr28000 molecules are more prominent than the Mr 26000 molecules and, although Sj28 is a poor immunogen in mice, immunological cross‐reactivity between Sj28 and Sm28 is generally more readily detected than that between Sj26 and Sm26. Whether experimental vaccination against schistosomiasis japonica and schistosomiasis mansoni reported with cloned GSTs can be improved by incorporation of both Mr28000 and Mr 26000 species into the vaccine remains to be determined. On this point, the present data suggest that vaccination of mice with Sj26 plus Sm28 should be a useful means of increasing antibody responses to the GSTs of S. japonicum.

Responses in mice to Sj26, a glutathione S-transferase of Schistosoma japonicum worms

The genetic variation in antibody responses of mice to glutathione S‐transferase (GST) enzymes of Schistosoma japonicum worms, and in particular to a Mr 26,000 species termed Sj26, was analysed. Sera from infected mice, or mice immunized with adjuvant and an Sj26 β‐galactosidase fusion protein produced in Escherichia coli (Sj26FP), or purified near‐native recombinant Sj26 produced in E. coli (rSj26), were assayed by enzyme‐linked immunosorbent assay (ELISA) for antibody titres to GST purified from adult worms. Anti‐GST antibody levels are high in a mouse strain, WEHI 129/J, that is genetically resistant to infection with S. japonicum. Antibody responses to GST are low in BALB/c mice and intermediate in most other mouse strains analysed such as CBA/H and C57B1/6. Responsiveness to Sj26 in adjuvant is dominant in (BALB/c × WEHI 129/J)F1 hybrids. BALB/c.H‐2b and BALB/c.H‐2k mice are higher responders than BALB/c. One feature of antibody responses to Sj26 is the variability within a group of mice. When rSj26 conjugated to the hapten azobenzenearsonate was used as immunogen, BALB/c mice produced substantial amounts of anti‐Sj26 antibodies. In an attempt to correlate antibody levels with resistance in infected mice, a new functional assay was devised to measure the ability of sera to inhibit the binding of rSj26 to glutathione. However, there was no correlation between inhibitory titre in this assay and the numbers of worms recovered. In regard to the candidacy of GST as a vaccinating antigen in schistosomiasis japonica, the data raise the problem of variable responsiveness to the antigen that will need to be overcome by antigen modification and/or powerful adjuvants.

Sensitization against the parasite antigen Sj26 is not sufficient for consistent expression of resistance to Schistosoma japonicum in mice

Mice immunized with purified antigen preparations produced in Escherichia coli and containing the glutathione S-transferase (GST) isoenzyme of Schistosoma japonicum (Sj26) can be partially resistant to infection with this parasite. Maximum resistance was approximately 50% and no protection was obtained in BALB/c mice, known low responders to Sj26. Although only Freunds complete adjuvant has been used, the data obtained indicate that satisfactory levels of resistance to S. japonicum will not be attained by vaccination with Sj26 alone. Other antigens, including the additional GST isoenzyme of S. japonicum Sj28, will probably be required to establish whether Sj26 will be an important component of a defined multivalent vaccine against schistosomiasis japonica.

The functional and immunological significance of some schistosome surface molecules

The molecules discussed in this review include some of the leading vaccine candidates in schistosomiasis: the glutathione S-transferases, triose-phosphate isomerase, glyceraldehyde-3-phosphate dehydrogenase and the 23 and 25 kDa surface integral membrane proteins. Mark Wright, Kathy Davem and Graham Mitchell highlight the possible biological roles and immunological relevance of these molecules.

Attempts to induce resistance in mice to Schistosoma japonicum and Schistosoma mansoni by exposure to crude schistosome antigens plus cloned glutathione-S-transferases

Several attempts have been made to induce resistance in mice to Schistosoma japonicum (Philippines) or Schistosoma mansoni by exposure to living male and/or female adult worms, their antigens or irradiated cercariae. No resistance was demonstrated in the following cases: re‐exposure of mice to cercariae following praziquantel (PZQ) treatment of existing infection; re‐exposure of mice following cyclosporin A (CsA) treatment at the time of first cerearial exposure; subcutaneous or intraperitoneal deposition of living male or female worms; repeated intranasal administration of crude worm homogenates plus Bordetella pertussis vaccine (BPV) as adjuvant. Homologous 60Co‐irradiated cercariae were very effective at inducing resistance to infection with S. mansoni but not to infection with S. japonicum (Philippines) in a limited series of experiments. A regime of infection, immunization with homologous Escherichia coli‐derived glutathione‐S‐transferases (GST), then PZQ treatment followed by homologous re‐exposure did not result in significant resistance in either the S. mansoni or the S. japonicum (Philippines) systems. Mice given irradiated cercariae plus GST were not more resistant to subsequent S. mansoni infection than mice given irradiated cercariae alone. The results generally confirm and extend those reported by others with the conclusion that resistance to schistosomes in mice is difficult to achieve by exposure to adult worm antigens alone. Moreover, additional immunization with the GST available to date as cloned gene products, and injected in Freunds complete adjuvant, does not influence the outcome of exposure to crude worm antigens including any additive effects of protective irradiated cercariae.

Immunoblotting analysis of the major integral membrane protein antigens of Schistosoma japonicum

Triton X-114 has been employed to isolate integral membrane proteins from Schistosoma japonicum and Schistosoma mansoni adult worms. Suitable marker molecules and antisera directed or raised against schistosome proteins partitioned by Triton X-114 extraction indicated that the phase separation and purification of integral membrane proteins had been successful and this fraction was free of contamination with aqueous (soluble) or secretory antigens. Two dimensional immunoblots further exemplified differences between antigens in the integral membrane protein extract and those of the aqueous fraction. Seven S. japonicum integral membrane proteins have been identified on immunoblots by serum from a hyperimmune and an infected rabbit and by sera from Philippine patients with a history of schistosomiasis japonica. Integral membrane proteins of S. mansoni and S. japonicum had surprisingly little conformity in the molecular weights and electrophoretic mobilities between the two species.

Monoclonal antibodies reacting with Schistosoma japonicum eggs and their target epitopes

Ten monoclonal antibodies (McAbs) raised to Schistosoma japonicum eggs could be assigned using several serological and immunochemical techniques to 3 groups. The McAbs, termed A, B and C-McAbs, apparently recognize carbohydrate epitopes that can be located on the same antigen molecule. The antibodies, generally of IgM isotype, are idiotypically related. They are distinct from another IgM McAb (Group D-McAb) the carbohydrate target epitope of which can also be associated with the epitopes of A, B and C-McAbs. The McAbs produce large vacuolated bleb reactions in the circumoval precipitin test (COPT) and target epitopes have different representations in various life cycle stages such as immature and mature eggs, male and female worms (including S. mansoni). Antigens affinity purified on columns containing A, B, C and D-McAbs stimulate proliferation of T cells from egg-sensitized mice and elicit DTH reactions in such mice. This raises the possibility that the target antigens of these carbohydrate-reactive monoclonal antibodies are immunopathologic and involved in egg-induced granuloma formation.

Anti-embryonation immunity in murine schistosomiasis japonica (Philippines)

The hypothesis that granuloma modulation and disease abatement in chronic infection with Schistosoma japonicum could be ascribed to antibody-mediated effects on egg maturation and egg viability, arose from studies performed with mice in the Philippines. This novel hypothesis has not yet been integrated into the schistosomiasis literature despite being formulated more than a decade ago. One reason for this is that the phenomenon might be confined to S. japonicum, even S. japonicum (Philippines).