The two-phase recognition process of allografts in a Brazilian strain of Biomphalaria glabrata

Comparative studies of the defense mechanism against Schistosoma japonicum of schistosome-susceptible and -resistant Oncomelania nosophora

The amphibious snail Oncomelania nosophora is an intermediate host of Schistosoma japonicum. Previously we reported that there are two strains of the snail, one resistant and one susceptible to a Mindoro, the Philippines, strain of S. japonicum. The resistant snails were collected from Nirasaki and susceptible snails from Kisarazu, Japan. To determine early cellular responses in the two snail strains, we examined histologic alterations in the snails for up to 18 h after the initial exposure to miracidia. In both strains, the penetrating miracidia were distributed in the foot, mantle, gills, heart, stomach, and kidney, and the mean number of penetrating miracidia was similar in both strains. After penetration, snail hemocytes migrated toward the larvae, and by 12 h after exposure, substantial numbers of penetrated larvae were surrounded and encapsulated by hemocytes. The percentage of larvae encapsulated by hemocytes during 12-18 h after the exposure was significantly higher in the resistant Nirasaki strain (60.9+/-19.8%) than in the susceptible Kisarazu strain (42.3+/-15.0%). In a few snails of the Nirasaki strain, all the larvae found were encapsulated by hemocytes. The differences in hemocyte responses between the two strains may explain the susceptibility of the snails to schistosome larvae.

Leech responses to tissue transplantation

The aim of the present work is to describe histologically, histochemically and immunocytochemically, the sequence of events that lead to first and second set rejection of allo- or xenograft in leeches. Graft responses of leeches are comparable and are described following specific steps: inflammatory phase, rejection phase and granulation tissue formation (including re-epithelialisation, angiogenesis and fibroplasia).The responses to first and second graft in first set graft rejection as well as to the first transplant in second set graft experiments are identical and in the time span of a week all grafts are destroyed and disappear. In the second set graft rejection experiments the responses against the second transplant are markedly accelerated. The second graft shows massive structural alterations and it is rapidly rejected, within 3-4 days.Our results permit to highlight that in leeches there is a specific responsiveness of immune system similar to those described in highly divergent phyla.

Comparison of several types of allografts in Biomphalaria glabrata (Mollusca: Pulmonata)

Interpretation of prior studies on molluscan allografts is complicated by the variety of experimental methods used and recurring reports of acute rejection of digestive gland implants. In this study, allografts of adult digestive gland, saccular kidney, mantle, albumin gland, brain, ovotestis, heart, or amoebocyte-producing organ (APO) were implanted into the hemocoel of Biomphalaria glabrata snails, and their histological condition at 60 days post implantation (DPI) was compared with that of preimplantation tissues. Also, digestive gland tissue, still surrounded by body wall, was implanted from immature donors and examined at 120 DPI. All 60-day allografts maintained some degree of normal cell and tissue structure, and most displayed additional evidence of viability, i.e., contraction (heart), hyperplasia (APO), gametogenesis (ovotestis), secretion (albumin gland, digestive gland, and kidney), shell deposition (mantle), or neuroma formation (brain). Recipient hemocytic reaction was minimal or absent, except that in three of six ovotestis implants and five of seven digestive gland implants, variable numbers of acini were undergoing phagocytosis by hemocytes or had been reduced to granulomas. Among seven implants examined at 120 DPI, digestive gland acini were found in five (with one instance of hemocytic encapsulation). Thus, in this study, acute rejection of allografts did not occur. Although the observed hemocytic reactions could be viewed as evidence of chronic graft rejection, the inconsistent and protracted nature of these responses suggests instead that they represent resorption of degenerating tissue damaged by nonimmunological effects, e.g., mechanical trauma, heterotopic location, or autolysis.

Allogeneic and xenogeneic grafts in pulmonate gastropod molluscs: fates of neural transplants

Neural intracerebral allo- and xenografts in pulmonate gastropods demonstrated a variation in the tolerance of neural xenogeneic grafts that was dependent on the phylogenetic distance between the donor and the host. Like allografts, neural congeneric xenografts (Hp/Haa and H1/Haa) of cerebral ganglia (CG) were tolerated and restored growth in juvenile mesocerebrum-deprived (Haa) snails. However, CG neural xenografts between different genera of stylommatophorans (Achatina fulica/Haa) or between genera of different orders (Lymnaea stagnalis: Basommatophora/Haa: Stylommatophora) revealed an interspecific histoincompatibility. These results, compared with those described by other authors, suggest that gastropods possess mechanisms for the recognition of non-self that depend on the organ considered and the phylogenetic distance separating host and donor. Research should now attempt to identify the factors responsible for graft destruction.

Brain grafts of cerebral ganglia have effectiveness in growth restoration of damaged Helix aspersa mesocerebrum

The microsurgical extirpation of the mesocerebrum from the brain of fast-growing juvenile snails (Helix aspersa aspersa: H.a.a.) stops their growth. This suggests that neurosecretory cells of the mesocerebrum secrete a growth hormone. Neural grafting has been used as a tool to restore the impaired growth function after mesocerebrum removal in juvenile H.a.a snails. The transplantation of desheathed cerebral ganglia (CG) (i.e. CG with their glioconjunctive outer covering removed), into the place where the mesocerebrum had been re-established growth which depended on the age of the donors. For the grafts of H.a.a CG into H.a.a, it was CG from the youngest donors that restored growth best. However, the CG of adult snails still conserved a slight growth-stimulating activity. Transplantation of the CG from the large, fast-growing sub-species H. aspersa maxima (H.a.m), into the brain of H.a.a with mesocerebrum removed induced faster growth than the H.a.a CG probably because of a more abundant secretion of growth hormone. Our results show that intracerebral CG grafts are well tolerated in snails and that labeling of the neurones of the transplanted CG with a vital fluorescent stain (Fast blue), allowed the observation, over several months, of their integration into the lesion zone of the host brain.

Dynamics of the leukocytic response of Biomphalaria glabrata during the larval development of Schistosoma mansoni and Echinostoma liei

The daily evolution of the number of hemocytes in Biomphalaria glabrata was ascertained under three conditions: uninfected snails, snails infected with Schistosoma mansoni, and snails infected with Echinostoma liei. The Results show differences between the three experiments as well as in the average hemocyte density over the whole experimental period, as in the temporal dynamics of circulating hemocyte number. Specifically, it appears that the development of E. liei in B. glabrata induces a density of circulating hemocytes greater than that in uninfected B. glabrata or in snails infected with S. mansoni. The hemocyte dynamics observed in both experimental groups might best be interpreted by taking into account differences in the immunogenic stimulating capacity of the two trematodes and different physiological functions of the hemocytes brought into play during the infection: wound repair, nutrient digestion and transport, and excretion.