Schistosoma haematobium and S. japonicum: analysis of the ribosomal RNA genes and determination of the "gap" boundaries and sequences

We have determined the intragenic organization of the rRNA genes of Schistosoma haematobium and S. japonicum and found them to be similar to that of S. mansoni and other eukaryotes. An entire ribosomal repeat approximately 10 kbp in size from each species was isolated as a SalI fragment from a genomic library constructed in bacteriophage lambda. The segments encoding both the small and large rRNAs have been identified using three cloned EcoRI fragments of S. mansoni as probes. There were three EcoRI fragments (4.2, 3.0, 1.6 kbp) from S. haematobium and four EcoRI fragments (4.6, 2.3, 1.7, 1.0 kbp) from S. japonicum. As in a wide variety of organisms within the protostome phyla, the 28S rRNA in schistosomes contains a "gap" which separates it into two fragments. The length of the gap sequence in S. haematobium is 54 bases and it is identical to that in S. mansoni in both length and sequence. However, in S. japonicum the sequence is between 64-67 bases long. In each case, irrespective of the species, the gap is located at the same position within the 28S rRNA. Secondary structures of the gap sequence derived by computer analysis predict a conformation with the minimum free energy that has an UAAU tract in a hairpin loop for S. haematobium and an UAUU tract for S. japonicum.     

The complete mitochondrial genomes of Schistosoma haematobium and Schistosoma spindale and the evolutionary history of mitochondrial genome changes among parasitic flatworms

Complete mitochondrial genome sequences for the schistosomes Schistosoma haematobium and Schistosoma. spindale have been characterized. S. haematobium is the causative agent of urinary schistosomiasis in humans and S. spindale uses ruminants as its definitive host; both are transmitted by freshwater snail intermediate hosts. Results confirm a major gene order rearrangement among schistosomes in all traditional Schistosoma species groups other than Schistosoma japonicum; i.e., species groups S. mansoni, S. haematobium, and S. indicum. These data lend support to the 'out of Asia' (East and Southeast Asia) hypothesis for Schistosoma. The gene order change involves translocation of atp6-nad2-trnA and a rearrangement of nad3-nad1 relative to other parasitic flatworm mt genomes so far sequenced. Gene order and tRNA secondary structure changes (loss and acquisition of the DHU and/or TPsiC arms of trnC, trnF, and trnR) between mitochondrial genomes of these and other (digenean and cestode) flatworms were inferred by character mapping onto a phylogeny estimated from nuclear small subunit rRNA gene sequences of these same species, in order to find additional rare genomic changes suitable as synapomorphies. Denser and wider taxon sampling of mt genomes across the Platyhelminthes will validate these putative characters.     

Identification of the Boudicca and Sinbad retrotransposons in the genome of the human blood fluke Schistosoma haematobium

Schistosomes have a comparatively large genome, estimated for Schistosoma mansoni to be about 270 megabase pairs (haploid genome). Recent findings have shown that mobile genetic elements constitute significant proportions of the genomes of S. mansoni and S. japonicum. Much less information is available on the genome of the third major human schistosome, S. haematobium. In order to investigate the possible evolutionary origins of the S. mansoni long terminal repeat retrotransposons Boudicca and Sinbad, several genomes were searched by Southern blot for the presence of these retrotransposons. These included three species of schistosomes, S. mansoni, S. japonicum, and S. haematobium, and three related platyhelminth genomes, the liver flukes Fasciola hepatica and Fascioloides magna and the planarian, Dugesia dorotocephala. In addition, Homo sapiens and three snail host genomes, Biomphalaria glabrata, Oncomelania hupensis, and Bulinus truncatus, were examined for possible indications of a horizontal origin for these retrotransposons. Southern hybridization analysis indicated that both Boudicca and Sinbad were present in the genome of S. haematobium. Furthermore, low stringency Southern hybridization analyses suggested that a Boudicca-like retrotransposon was present in the genome of B. truncatus, the snail host of S. haematobium.     

Schistosoma mansoni, S. haematobium, and S. japonicum: identification of genus- and species-specific antigenic egg glycoproteins

Immunoreactive egg glycoproteins of Schistosoma mansoni, S. haematobium, and S. japonicum which are genus- and species-specific, or react with sera of patients infected with other parasites, have been identified. Egg proteins were labeled with Iodine-125, and the concanavalin A-binding glycoproteins were immunoprecipitated with sera of patients infected with one of four species of Schistosoma or Trichinella spiralis, Taenia solium, Echinococcus granulosus, Entamoeba histolytica, or Wuchereria bancrofti. These immunoprecipitates were analyzed by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Despite the strikingly different patterns of glycoproteins of the African species, the antibody immune responses of patients infected with S. mansoni and S. haematobium were found to be so similar that differentiation could not be established. In contrast, sera of patients infected with S. japonicum, S. mekongi, or parasites not of the genus Schistosoma, immunoprecipitated fewer of the major S. mansoni or S. haematobium glycoproteins. Likewise, antibody immune responses of patients infected with the Oriental schistosomes (S. japonicum and S. mekongi) could not be differentiated. Only a few quantitative differences were noted between our S. mansoni egg glycoprotein extract and a standardized soluble egg antigen extract. This study provides an explanation for the extensive cross-reactivity observed in diagnostic assays which utilize various fractions of schistosomal egg extracts as the antigen.     

Comparative glucose utilization rates in separated and mated schistosomes

The rate of phosphorylation of 2-deoxyglucose (2DG) was determined by sequential pulsing of schistosomes (Schistosoma mansoni, S. japonicum, and S. haematobium) with 3H- and 14C-labeled 2-deoxy-D-glucose. Subsequent column chromatographic separation of the neutral [3H]2DG and [14C]2DG from the 3H- and 14C-labeled 2-deoxy-D-glucose 6-phosphate permitted estimation of the quantity of [3H]2DG phosphorylated in 2 min, and the proportion of [14C]2DG phosphorylated in 1 min; thus a phosphorylation rate was determined from a single tissue sample. The relative phosphorylation rate of 2-[3H]2DG to D-1-[14C]glucose (i.e., the phosphorylation coefficient) was also measured in male and female schistosomes. It was demonstrated that even though 2DG is taken up more rapidly than glucose, it is phosphorylated at a much slower rate in both S. mansoni and S. japonicum. In both of these species, mated males phosphorylate 2DG and glucose at a greater rate than do unmated males. Similarly, mated females phosphorylate and consume more glucose than do separated females. In contrast, the phosphorylation coefficient is greater in separated than in mated schistosomes. Intraspecific comparisons suggest that, at reduced substrate concentrations, glucose utilization rates are higher in S. japonicum, intermediate in S. mansoni, and lower in S. haematobium.     

Africa or Asia, which is the evolutionary origin of human schistosomes?]

The origin and the evolution of Schistosomatidae species, due to their medical importance (responsible of the second most important human parasitosis after malaria), arouse a great interest. A combination of phylogenetic studies using several molecular markers has provided support for the traditional grouping and evolutionary inferences derived from morphological and biological data. The genus Schistosoma, which comprises all species parasitizing Man, is generally split into four evolutionary lineages (mansoni, haematobium, indicum and japonicum lineages). The group of African schistosomes (including mansoni and haematobium lineages) appears very divergent from the japonicum lineage. Recent phylogenetic studies using partial 28S rDNA sequencing and including Orientobilharzia turkestanicum from Iran, an Asian parasite of livestock, found, unexpectedly, that this species nested among Schistosoma species, thus rendering the latter paraphyletic, and suggested an Asian origin for the Schistosoma genus. The present work re-examines the question of the geographical origin of human schistosomes by analysing a new genomic marker (ITS2) as well as by including the use of O. turkestanicum originating from northeastern China. Our results are in agreement with previous work using 28S, in demonstrating that Schistosoma is not monophyletic. However, O. turkestanicum, whatever the method of analysis used (distance or parsimony), was grouped with members of the japonicum group to the exclusion of African Schistosoma species. Then, our data argue strongly for the need for further phylogenetic study including new taxa and new genomic sequences before definitely concluding either an Asian or African origin for the genus Schistosoma.     

Schistosoma mansoni,S. haematobium,and S. japonicum: early events associated with penetration and migration of schistosomula through human skin

Migratory pattern of schistosomula of Schistosoma mansoni, S. haematobium, and S. japonicum through human skin were analyzed in skin organ cultures. These studies showed that the schistosomula of S. mansoni and S. haematobium has similar migratory patterns through human skin. During the first 24h after infection nearly 90% of S. mansoni and S. haematobium schistosomula were present only in the epidermis. Majority of the schistosomula were found in the dermis only after 48h and they appear to reach the dermal vessels around 72h after infection. Migratory pattern of S. japonicum on the other hand was significantly different from the other two species in that over 90% of the parasites had already reached the dermis within the first 24h and schistosomula were present in the dermal vessels within 2h after infection. Analysis of the cytokine pattern at 8h after infection by a macro gene array and RT-PCR analysis showed that out of 24 different cytokines analyzed only IL-1ra, IL-10, and TNF-alpha were increased in the human skin following infections with S. mansoni and S. haematobium, whereas, after infection with S. japonicum there was significant increases in IL-1beta, IL-1ra, IL-2, IL-6, IL-8, IL-10, IL-15, IL-18, and TNF-alpha. Immunohistochemical analysis of epidermal sheets showed focal accumulation of HLA-DR(+) cells in areas where schistosomula of S. mansoni had entered the human skin.     

Is there immunity to Schistosoma japonicum?

The Oriental schistosome, Schistosoma japonicum, unlike the other two major schistosomes that infect humans (S. mansoni and S. haematobium), is a zoonotic species. The transmission dynamics and the potential effects of host-related regulatory factors, including immunity, are likely to be distinct for this parasite. Here, Allen Ross and collaborators from Australia, China and the Philippines discuss recently published and established epidemiological and laboratory data bearing on anti-infection immunity to Asian schistosomiasis, and contrast these findings with the emerging picture of development of anti-infection immunity against the African schistosomes. Implications for vaccines and other control strategies for schistosomiasis japonica are also discussed.     

Expression of Lex antigen in Schistosoma japonicum and S.haematobium and immune responses to Lex in infected animals: lack of Lex expression in other trematodes and nematodes

Adults of the human parasitic trematode Schistosoma mansoni, which causes hepatosplenic/intestinal complications in humans, synthesize glycoconjugates containing the Lewis x (Lex) Galbeta1-->4(Fucalpha1-- >3)GlcNAcbeta1-->R, but not sialyl Lewis x (sLex), antigen. We now report on our analyses of Lexand sLexexpression in S.haematobium and S.japonicum, which are two other major species of human schistosomes that cause disease, and the possible autoimmunity to these antigens in infected individuals. Antigen expression was evaluated by both ELISA and Western blot analyses of detergent extracts of parasites using monoclonal antibodies. Several high molecular weight glycoproteins in both S. haematobium and S. japonicum contain the Lexantigen, but no sialyl Lexantigen was detected. In addition, sera from humans and rodents infected with S.haematobium and S.japonicum contain antibodies reactive with Lex. These results led us to investigate whether Lexantigens are expressed in other helminths, including the parasitic trematode Fasciola hepatica , the parasitic nematode Dirofilaria immitis (dog heartworm), the ruminant nematode Haemonchus contortus , and the free-living nematode Caenorhabditis elegans . Neither Lexnor sialyl-Lexis detectable in these other helminths. Furthermore, none of the helminths, including schistosomes, express Lea, Leb, Ley, or the H- type 1 antigen. However, several glycoproteins from all helminths analyzed are bound by Lotus tetragonolobus agglutinin , which binds Fucalpha1-->3GlcNAc, and Wisteria floribunda agglutinin, which binds GalNAcbeta1-->4GlcNAc (lacdiNAc or LDN). Thus, schistosomes may be unique among helminths in expressing the Lexantigen, whereas many different helminths may express alpha1,3-fucosylated glycans and the LDN motif.      

Existence of host DNA sequences in schistosomes--horizontal and vertical transmission

The localization of repetitive DNA sequences in the mouse genome such as mouse type 2 Alu sequence (B2) and mouse retrovirus-related sequences was shown in the body of adult Schistosoma japonicum and Schistosoma mansoni by applying an in situ PCR and hybridization technique. Using the same method, mouse major histocompatibility complex (MHC) class I sequence was also found in schistosomes. Furthermore, mouse MHC class I sequence and type A retroviral sequence were detected in S. japonicum and S. mansoni cercarial DNA by blot hybridization. These findings indicated that horizontal and vertical transmission of host DNA sequences occurred in schistosomes. The incorporation and propagation of host sequences in schistosomes and the roles played by such host sequences form the focus of this brief review.     

Schistosoma japonicum: analysis of eggshell protein genes, their expression, and comparison with similar genes from other schistosomes.

As the egg of Schistosoma japonicum plays a central role in transmission and in pathogenesis, we sought to understand the molecular biology of egg formation. In this study we characterized an eggshell protein gene of S. japonicum and compared it with similar genes from S. mansoni and S. haematobium. To initiate studies on the eggshell protein genes of S. japonicum, a cloned genomic fragment containing an entire copy of a S. haematobium eggshell protein gene was used to identify three EcoRI hybridizing fragments of 2.6, 2.0, and 1.3 kbp in S. japonicum genomic DNA and to isolate three independent genomic clones from a S. japonicum genomic library. Two genomic clones, SJ 4-1 and SJ 3-1, contain at least two copies of the gene. The DNA sequence of a 2.0-kbp EcoRI fragment of clone SJ 3-1 showed two open reading frames (ORF), one of which showed a strong homology to the chorion proteins of insects. This ORF had 207 amino acids with a calculated molecular size of 18.5 kDa. The predicted peptide was glycine (50%) and tyrosine (10%) rich like other described schistosome eggshell proteins. Primer extension and the dideoxynucleotide sequence of the mRNA defined the cap site of the RNA and positioned the putative TATA and CAAAT elements and other cis-acting elements. Northern analysis demonstrated that eggshell protein mRNA was only detected in mature female parasites. The appearance of the female-specific mRNA was dependent on pairing with the male parasite and increased with egg production (as determined by hybridization intensity). A comparison of the DNA and deduced protein sequences of eggshell protein genes from S. japonicum with those of similar genes from S. mansoni and S. haematobium indicated that the genes are highly conserved, with S. mansoni and S. haematobium genes being more similar to each other than either is to S. japonicum.     

Chromosomal differentiation of the Schistosoma japonicum complex

The C-banding pattern, location of telomere sequence and chiasma frequency of four species of the Schistosoma japonicum complex were compared with those of two African species, Schistosoma mansoni and Schistosoma haematobium. In the six species, C-banding patterns of seven autosomes and the two sex chromosomes (Z and W) showed relatively species-specific and geographical (Asian and African) differences. Particularly, a plausible pathway of alteration of chromosome 2 revealed a direction from the A-chromosome to the M- chromosome in terms of rearrangements of pericentric inversion and elimination of constitutive heterochromatin (AM inversion). This chromosome change suggested hypothetically that the S. japonicum complex is the original type, and the African species represents the derived type. Moreover, the mosaic construct of the Asian and African types in Schistosoma sinensium chromosomes prompted us to propose that the species might have been formed by hybrid speciation of the genomes of Asian and African species. Localisation of telomeric repeats enabled Asian and African schistosomes to be distinguished clearly by simple terminal location and by terminal and interstitial locations, respectively. Change of chiasma frequency in the S. japonicum complex might be caused by the reduction of interstitial chiasmate (Xi) in the larger chromosomes, 1 and Z (or W), and the change seems to have progressed to Japan from South East Asia. These data enabled us to predict a tentative evolutionary pathway of schistosomes at the cytogenetic level.     

Mating interactions between Schistosoma haematobium and S. mansoni

Schistosoma haematobium and S. mansoni are two medically important schistosomes, commonly occurring sympatrically in Africa and so potentially able to infect the same human host. Experiments were designed to study the mating behaviour of these two species in mixed infections in hamsters. Analysis of the data obtained showed that both heterospecific and homospecific pairs readily form. No significant difference was seen between the two species in their ability in forming pairs, however, S. mansoni showed a greater homospecific mate preference. Analysis of the data using the Mantel-Haenszel test suggests that mating competition does occur between S. haematobium and S. mansoni, the former being the more dominant species. Both species appeared to be able to change mate, with S. haematobium showing a greater ability in taking S. mansoni females away from S. mansoni males when introduced into a pre-established S. mansoni infection highlighting the competitiveness of S. haematobium. The significance of the results is discussed in relation to the epidemiological consequences occurring in Senegal, and other areas where both species are sympatric.     

Comparison of skin invasion among three major species of Schistosoma

A comparison of the host-finding behavior, mode of skin invasion and skin-migratory patterns of the three major schistosomes of humans reveals major differences. Among the three species, Schistosoma japonicum is remarkable at conserving energy during the host-finding process, and exhibiting swift migration through the skin to reach the predilection site sooner and mature earlier compared with Schistosoma mansoni and Schistosoma haematobium. In this article, we summarize and compare the penetration and migratory behavior of schistosomula of the three major human schistosomes through mouse and human skin.     

Schistosoma japonicum: the pathology of experimental infection

The pathology of experimental schistosomiasis japonica is reviewed and compared with the pathology of schistosomiasis japonica in man and to some aspects of schistosomiasis mansoni and schistosomiasis haematobia in experimental animals. The induction of granulomas around Schistosoma japonicum eggs depends upon cell mediated immunity, as do the reactions to Schistosoma mansoni and Schistosoma haematobium eggs. However, the modulation of the reaction to S. japonicum eggs can be greatly influenced by antibody, while antibody has no effect on the granulomas around S. mansoni eggs. Adult worm pairs of S. japonicum tend to cluster in the mesenteric venules, and most eggs are laid in a few sites. This leads to large, focal intestinal lesions similar to the discrete lesions produced by S. haematobium in the intestine and urinary tract but in contrast to the widespread, diffuse lesions produced by S. mansoni. Comparison with S. japonicum infection in humans is limited chiefly by our scant knowledge of the pathology produced by S. japonicum in infected persons. Most such comparisons are, in any case, limited by the marked differences in the reactions of various experimental host species to the infection and by differences in the reaction of a given host species to different strains of the parasite.     

Invasion by schistosome cercariae: neglected aspects in Schistosoma japonicum

Skin invasion by schistosome cercariae was recently discussed in Trends in Parasitology. However, only Schistosoma mansoni was considered, possibly because this species predominates in laboratory studies (at least outside China). One may be tempted to extrapolate from the "model" S. mansoni to other schistosomes, but Schistosoma japonicum must not be neglected. This schistosome is distinguishable from others (particularly S. mansoni) by virtue of its remarkable speed and success of migration, as well as by specific biochemical and immunological features. This leads to the hypothesis that S. japonicum is atypical with respect to the enzymes that facilitate skin penetration.     

Analysis and comparison of cercarial emergence rhythms of Schistosoma haematobium, S. intercalatum, S. bovis, and their hybrid progeny

In identical experimental conditions, the three schistosomes of the terminal spined egg group (S. haematobium, S. intercalatum and S. bovis) showed significant differences in their cercarial shedding patterns. The cercariae of the F1 hybrids, obtained by experimental crosses between these three species, showed the same circadian emergence rhythm (with one peak) as the cercariae of the parental species. However, the mean shedding time of these hybrid parasites (12:14 +/- 1 h 34 min for S. haematobium x S. intercalatum; 09:58 +/- 1 h 24 min for S. haematobium x S. bovis; 08:57 +/- 1 h 19 min for S. bovis x S. intercalatum) was always in advance to the one of their parental species (13:51 +/- 2 h 04 min for S. haematobium; 13:59 +/- 1 h 55 min for S. intercalatum; 10:09 +/- 2 h 04 min for S. bovis). These results are compared with those obtained from crosses between schistosomes with lateral spined eggs, and from crosses between intraspecific chronobiological variants of S. mansoni. They corroborate the genetic determinism of the cercarial emergence of schistosomes. Moreover, such significant differences between the hybrids and their parents in the times of cercarial emission may be of value in the epidemiological research and characterization of naturally occurring hybrids.     

Effect of artemether against Schistosoma haematobium in experimentally infected hamsters

The drug, artemether, has been shown to be active against the juvenile stages of Schistosoma japonicum and Schistosoma mansoni in experimentally infected animals, while it is less effective on adult worms. These findings have been confirmed in randomised controlled trials in humans. Consequently, it could be expected that artemether is also active against Schistosoma haematobium. We present here the first results from experiments assessing the effect of artemether on S. haematobium. Hamsters with a single infection received intra-gastrically an initial dose of 300 mg/kg artemether on day 14, 21 or 28, followed by further doses at varying treatment regimens. In all the treatment groups, the total and female worm reduction rates were highly significant, and ranged from 78 to 100% in hamsters harbouring juvenile schistosomes. Hamsters infected three times with S. haematobium, on days 0, 4 and 9, and repeatedly treated with artemether at the same dose as above, showed highly significant total and female worm reduction rates of between 94 and 99%. Artemether was also active against 77-day-old adult S. haematobium, since its administration on two consecutive days resulted in highly significant total and female worm reduction rates of 76-89%. Our findings confirm that artemether is also active against S. haematobium, especially the schistosomules. These results provide a basis for clinical trials in humans, for further assessment of the potential of artemether for schistosomiasis control.