Ultrastructural studies of the killing of schistosomula of Schistosoma mansoni by activated macrophages in vitro

Immunologically activated murine macrophages have been shown elsewhere to kill skin stage schistosomula of Schistosoma mansoni in vitro, in a manner analogous to the extracellular killing of tumour cell targets. In this study, the kinetics of the interaction between activated macrophages and larval targets and the resultant ultrastructural changes in parasite morphology that culminated in death have been analysed in detail. Unlike granulocyte-mediated schistosomular killing, macrophage-mediated cytotoxicity did not appear to be directed against the surface tissues of the parasite. Macrophages adhered only transiently following initiation of the cultures, yet changes in the subtegumental mitochondria and muscle cells of the larva were detected within the first hour of incubation. Progressive internal disorganisation followed rapidly, but the tegument and tegumental outer membrane remained intact, to form a 'shell' that maintained the general shape of the parasite. Such changes were recognised irrespective of whether the effector cell population comprised peritoneal macrophages activated by lymphokine treatment in vitro, or by infection with Mycobacterium bovis (strain BCG), or S. mansoni in vivo. That macrophages rather than contaminating granulocytes or lymphocytes, had mediated the observed damage was demonstrated by the use of a lymphokine treated macrophage cell line, IC-21. The observation that macrophage cytotoxicity is directed against internal organelles rather than the tegumental outer membrane of this multicellular target, may help to elucidate the general mechanism of extracellular killing by these cells.     

Suppressor T cells in the specific control of the carrier response to schistosomula in mice infected with Schistosoma mansoni

The carrier effect, using TNP-labelled schistosomula was used to measure the helper T-cell activity against the schistosomula surface in CBA mice exposed to 30 cercariae of Schistosoma mansoni. After infection the helper T-cell activity reached a peak in 8--10 days, but by 6 weeks it had declined to background levels. Five x 10(7) spleen cells from chronically (12-week) infected mice when injected into 9-day infected mice caused a specific suppression of the helper T-cell response to schistosomula. Subsequent fractionation of the spleen cell population using a nylon wool column and specific depletion of T cells from the spleen cell population with anti-Thy 1.2 antisera and complement, showed that the suppressive activity was due to T cells. We conclude that during infection of mice with S. mansoni a population of suppressor T cells is generated which partially regulates antibody production against schistosome surface antigens.     

Morphological studies on the killing of schistosomula of Schistosoma mansoni by human eosinophil and neutrophil cationic proteins in vitro

Purified eosinophil and neutrophil cationic proteins isolated from the lysosomal secretion granules of human granulocytes, evoke characteristic, dose-dependent morphological changes in young schistosomula of S. mansoni. The first sign of damage is seen within 15–30 min of incubation and involves the formation of surface microvilli and blebs. Subsequently, tegumental evaginations of varying size are developed, but these appear to explode with rapidity, so that lengths of expanded tegumental outer membrane are deposited over the severely damaged surface of the parasite. Both types of granulocyte proteins are able to effect comparable damage at equimolar concentration. Other cationic proteins such as protamine and poly-L-arginine also damage the parasite surface but the pathological changes differ from those induced by the granulocyte proteins and they take longer to develop. In contrast, lysozyme-treated parasites are virtually similar to control schistosomula incubated in medium alone. These findings are discussed in relation to published data concerning the interaction of intact granulocytes with young schistosomula both in vitro and in viva.     

Human neutrophil-mediated killing of schistosomula of Schistosoma mansoni: augmentation by schistosomal binding of eosinophil peroxidase

Eosinophil peroxidase (EPO) is a major component of the large cytoplasmic granules of eosinophils, and is released onto the surface of schistosomula when eosinophils adhere to antibody and complement coated organisms. EPO is a strongly cationic protein, which can bind to the surface of schistosomula with retention of peroxidatic activity. The binding per se was not toxic to the organisms under our conditions, but EPO-coated schistosomula were rapidly killed when H2O2 and halide were added, under conditions in which uncoated schistosomula were unaffected. The toxicity of the surface-bound EPO system was not significantly inhibited by albumin (20 mg/ml), in contrast to the complete inhibition by this concentration of protein when the EPO was free in solution. Purified polymorphonuclear leukocytes (PMNs) from normal donors were toxic to uncoated schistosomula in medium containing antischistosomal antibody and complement, and this toxicity was significantly increased when EPO was bound to the surface of the organisms. The toxicity of PMNs to EPO-coated schistosomula was inhibited but not abolished by the hemeprotein inhibitor azide. This is compatible with the involvement of surface-bound EPO in an enzymatic attack on the organism, utilizing H2O2 generated by PMNs stimulated by adherence to antibody and complement-coated schistosomula. PMN adherence to schistosomula is increased by surface-bound EPO, and this also may contribute to the enhancement of neutrophil-mediated toxicity by EPO. These findings indicate a mechanism by which two inflammatory cells, the eosinophil and neutrophil, may interact to enhance the destruction of a target organism.     

环孢素A体外抗AF18标记的曼氏血吸虫童虫的作用

目的探讨环孢素A抗曼氏血吸虫童虫的作用机制。方法制备童虫,环孢素A体外作用,AF18标记,荧光显微镜观察;定量童虫荧光素的分布以及测定光漂洗后童虫荧光素的复原率。结果童虫损伤或死亡,虫体逐渐从绿色变成黄色,虫体表面损伤;随着环孢素A剂量加大,童虫荧光素定量增加;童虫光漂洗后荧光素的复原率大幅度降低。结论环孢素A增加童虫AF18的含量,降低童虫荧光素的复原率,减低童虫表膜流动性;提示,表膜是药物作用的靶标。     

Enhancement of eosinophil-mediated cytotoxicity to schistosomula of Schistosoma mansoni by autologous mononuclear cells from patients

Adherent mononuclear cells (monolayer), when co-cultured with autologous peripheral blood eosinophils isolated from patients treated for Schistosoma mansoni infections, enhanced the eosinophil-mediated killing of antibody coated schistosomula. The monolayer increased the activity of the eosinophils by 225%, and was observed in 80% of the patients studied. Heat labile factors other than complement, present in immune serum, further enhanced the ability of eosinophils to kill schistosomula in the presence of the monolayer. On their own the adherent cells did not mediate obvious damage to the parasite. Eosinophils that had been pre-incubated with the monolayer (100 mins) and tested separately, killed equal numbers of schistosomula as in the co-culture assay; this excludes the possibility of concurrent schistosomula cytotoxicity by the two cell populations. The ability of the monolayer to activate eosinophils was not altered by inhibitors of protein synthesis. The monolayer was largely consistent of monocytes as demonstrated by an over 96% positive staining for non-specific esterases.     

Therapy with bone marrow cells reduces liver alterations in mice chronically infected by Schistosoma mansoni

AIM： To investigate the potential of bone marrow mononuclear cells （BM-MCs） in the regeneration of hepatic lesions induced by Schistosoma mansoni （S.mansoni） chronic infection. METHODS： Female mice chronically infected with S.rnansoni were treated with BM-MCs obtained from male green fluorescent protein （GFP） transgenic mice by intravenous or intralobular injections. Control mice received injections of saline in similar conditions, Enzyme-linked immunosorbent assay （ELISA） assay for transforming growth factor-beta （TGF-β）, polymerase chain reaction （PCR） for GFP DNA, immunofluorescence and morphometric studies were performed. RESULTS： Transplanted GFP^＋ cells migrated to granuloma areas and reduced the percentage of liver fibrosis. The presence of donor-derived cells was confirmed by Fluorescence in situ hybridization （FISH） analysis for detection of cells bearing Y chromosome and by PCR analysis for detection of GFP DNA. The levels of TGF-β, a cytokine associated with fibrosis deposition, in liver fragments of mice submitted to therapy were reduced. The number of oval cells in liver sections of S.mansoni-infected mice increased 3-4 fold after transplantation. A partial recovery in albumin expression, which is decreased upon infection with S.mansoni, was found in livers of infected mice after cellular therapy. CONCLUSION： In conclusion, transplanted BMCs migrate to and reduce the damage of chronic fibrotic liver lesions caused by S.mansoni.     

Fractionated sera from Schistosoma mansoni infected patients confers passive protection in mice

Sera from humans with chronic Schistosoma mansoni infections (CHS) were chromatographed with CNBr-activated Sepharose 4 B conjugated with NP-40 extracts obtained from live 3 hr schistosomula. Both unbound (CHSUB) and bound (CHSB) fractions which contained IgG and IgM isotypes were characterized by ELISA, immunofluorescence, and complement-mediated in vitro killing assays. ELISA data showed that the CHSB fraction recognized schistosomula NP-40 extracts, whereas the CHSUB fraction did not. However, both CHSUB and CHSB fractions recognized 8 M urea adult worm extracts and 8 M urea egg extracts. By indirect immunofluorescence assay, the CHSB fraction recognized epitopes on the surface of live schistosomula 3 hr-29 days of age, whereas the CHSUB fraction showed surface fluorescence only on 24- and 29-day-old worms. The CHSB fraction mediated 95% killing of schistosomula in a complement dependent in vitro assay, the CHSUB fraction and the unfractionated CHS did not exhibit killing ability. The CHSUB fraction was able to titrate out the killing ability of the CHSB fraction in in vitro cytotoxic assays when mixed with the CHSB fraction at increasing concentrations. In passive immunization experiments, the CHSB fraction provided approximately 30% passive protection in mice when injected 1 day or 6 days after challenge and 20% protection when injected at 15 days, but failed to provide protection when administered greater than or equal to 24 days after challenge. Unfractionated CHS failed to mediate passive protection.     

Cytotoxic effects in vitro of human monocytes and macrophages on schistosomula of Schistosoma mansoni

Human peripheral blood monocytes from normal donors were isolated by differential centrifugation and cultured in vitro in hydrophobic Teflon-coated tissue culture bags. Cells were harvested between 0 and 10 days and tested for their ability to kill schistosomula of Schistosoma mansoni in an in-vitro cytotoxicity assay. Freshly isolated, unstimulated monocytes demonstrated minimal cytotoxic capability. However, this was increased if the cells were pretreated with human recombinant gamma interferon (IFN-gamma), or with specific anti-S. mansoni antiserum. As the monocytes matured in vitro there were marked increases in the levels of antibody-independent killing of schistosomula. Monocytes grown in vitro with IFN-gamma (10(4) u/ml) took 2-3 days to develop almost maximal cytotoxicity (mean 94% kill of schistosomula). In contrast, unstimulated monocytes (no IFN-gamma) took between 5 and 7 days to achieve comparable cytotoxicity (mean 99% kill). Killing of the schistosomula was dependent upon a high effector to target ratio, and was a relatively slow phenomenon in vitro, parasite attrition occurring between 17 and 36 h. Supernatants from cytotoxic macrophages were ineffective in mediating cytotoxicity of the parasite.     

In-vitro antibody-dependent killing of schistosomula of Schistosoma haematobium by human eosinophils

Schistosomula of S. haematobium have been shown to be susceptible to in vitro killing by eosinophils in the presence of serum from an infected individual. The highest level of killing was found after 48 h in culture. Killing was related to the eosinophil to schistosomula ratio, being highest at 5000: 1. Killing was also related to serum concentration, being highest at a 1/10 final dilution, falling to background levels at a 1/120 final dilution. At a cell: target ratio of 2000: 1 and at a serum dilution of 1/10 eosinophils from subjects with high peripheral blood eosinophil counts were, cell for cell, more active in killing S. haematobium schistosomula than were eosinophils from subjects with lower counts. Sera taken from adults resident in an endemic area gave higher levels of killing in the presence of eosinophils than did sera taken from adults with no history of exposure.     

Temporal variation in the carbohydrate and peptide surface epitopes in antibody-dependent, eosinophil-mediated killing of Schistosoma mansoni schistosomula

Changes in the surface antigenicity and susceptibility to eosinophil-dependent killing during in vitro development of schistosomula of Schistosoma mansoni, were examined using sera from rabbits and mice immunized with antigens that are shed from the schistosomulum in vitro (shed antigen), a carbohydrate extract of shed antigen (SAg/CHO) or a periodate-insensitive fraction of shed antigen (SAg/PEP). Anti-SAg/CHO antisera recognised mainly carbohydrate epitopes on the parasite surface, whilst anti-SAg/PEP antisera bound to periodate-insensitive, putative peptide, surface epitopes. Anti-SAg/PEP antibodies failed to recognise the surface of newly transformed schistosomula unless the parasite was first treated with sodium periodate, suggesting that these epitopes may be masked by periodate sensitive (i.e., carbohydrate) epitopes. There was an increase in anti-SAg/PEP antibody binding to the larval surface with age of the parasite in vitro; five-day-old lung schistosomula were also recognised by anti-SAg/PEP antisera. In contrast, anti-SAg/CHO antibody binding declined with parasite age, and failed totally to recognise lung schistosomula. This change in epitope expression was reflected in eosinophil-dependent cytotoxicity assays, with anti-SAg/CHO antisera killing young larvae and anti-SAg/PEP antisera only killing older larvae. Lung worms were not killed by either antisera. The difference in epitopes recognised by the antisera was also reflected in the antigens identified by immunoprecipitation and SDS-PAGE.     

Post lung-stage schistosomula of Schistosoma mansoni exhibit transient susceptibility to macrophage-mediated cytotoxicity in vitro that may relate to late phase killing in vivo

Studies of protective immunity against Schistosoma mansoni in immunized mice suggest that a proportion of challenge parasites may be eliminated after they have passed through the lungs of the host several days after infection; however, no potential immune effector mechanism of resistance against this stage of the parasite has yet been identified, since schistosomes have been shown to rapidly become resistant to antibody-dependent killing mechanisms. In this study, different development stages of S. mansoni were examined for their susceptibility to in vitro cytotoxicity by lymphokine-activated macrophages. As previously shown, newly transformed larvae were readily killed by lymphokine-treated peritoneal macrophages or the macrophage cell line IC-21 (80% mortality over 48 h in vitro), whereas 7 and 10 day old lung-stage parasites had become refractory to macrophage effects. However, after 2 to 2 1/2 weeks of development in vivo, juvenile parasites recovered from the liver were again susceptible to activated macrophage-mediated cytotoxicity (25-65% mortality). Ultrastructural studies of 2 1/2 week old parasites co-cultured with activated IC-21 cells revealed that damage was largely restricted to the areas beneath the parasite surface and gut syncitia; surface membrane disruption was not evident. This late stage of susceptibility was transient and by 4 to 6 weeks liver-stage worms had again become refractory to macrophage killing. The interaction of post lung-stage parasites with activated macrophages was antibody independent. Furthermore, schistosomes isolated from the portal circulation 2 1/2 weeks after infection showed no evidence of surface-bound immunoglobulin in a quantitative immunofluorescence assay, nor did antisera from chronically infected mice (CIS) or mice vaccinated with irradiated cercariae (VS) react with the surface of these parasites in vitro, making the possibility of direct antibody-dependent killing mechanisms unlikely. However, both CIS and VS did recognize excretory/secretory proteins synthesized by 2 1/2 week old liver-stage schistosomes, including a major antigen of approximate Mr (X 10(-3] 220 (220K). It is therefore possible that such antigens might participate in protective immunity, for example via immune complex formation or activation of sensitized T cells. These observations support the role of macrophages as immune effector cells in mice immunized against Schistosoma mansoni, and provide the first physiologically relevant mechanism whereby the immune system might recognize and kill post-lung stage schistosomes.     

Protection of mice against Schistosoma mansoni infection by passive transfer of sera from infected rabbits

Sera from rabbits infected with unattenuated Schistosoma mansoni cercariae conferred significant levels of protection against S. mansoni challenge ( P  < 0.001) after passive transfer to mice. Infected rabbit sera were only effective in conferring protection when transferred during the first week of infection, and were not effective when administered against liver-stage worms. Immunoglobulins isolated from the infected rabbit sera with Protein A-Sepharose were shown to be responsible for the transfer of protection to mice. Immunofluorescence studies demonstrated that the sera were more reactive against the surface of three hour-old mechanically transformed schistosomula than against the surfaces of lung-stage schistosomula. The sera from infected rabbits reacted polyspecifically against antigens in cercaria, schistosomula, and the worm and egg stages of the S. mansoni life-cycle. The host parasite relationship of S. mansoni in the rabbit is discussed.     

Chemiluminescence response of peritoneal exudate cells from mice infected with virulent and avirulent strains of Toxoplasma gondii

The zymosan-triggered chemiluminescence response of peritoneal exudate cells from mice infected with relatively virulent or avirulent Toxoplasma gondii strains was examined at various intervals after infection. Toxoplasma infections increased the background chemiluminescence compared with controls, but higher values were attained earlier in virulent than avirulent infection. A phase of transient unresponsiveness to zymosan was observed with both types of toxoplasma strains. Chemiluminescence continued to decline even after the addition of zymosan on day 3 of infection with the virulent strain but only on day 10 with the avirulent strain. Generation of chemiluminescence was enhanced in mice which had been infected with either strain for 1 month.     

Neutrophil-mediated cytotoxicity to schistosomula of Schistosoma mansoni in vitro: studies on the kinetics of complement and/or antibody-dependent adherence and killing

The capacity of rat peritoneal neutrophils to adhere to and kill schistosomula of Schistosoma mansoni in vitro has been investigated. Neutrophils adhere readily to schistosomula in the presence of antibody plus complement (C) (fresh immune rat serum), antibody alone (heat-inactivated immune rat serum) and C alone (fresh normal rat serum), but not with heat-inactivated normal rat serum. However, schistosomular killing is only achieved with neutrophils and fIRS or MRS. In the presence of hiIRS the cells detach after 6 h without producing a significant level of parasite death. The system involving neutrophils plus fIRS is the most efficient in terms of serum dilution and the rate of schistosomular killing. The complement-dependent antibody involved in this system belongs to the class IgG and occurs in rat serum at peak titres, 6–8 wk after a primary schistosome infection. Neutrophil adherence in the presence of MRS depends upon the generation of C3b molecules at the parasite surface via the alternative pathway of C activation. Studies on the antibody alone system indicate that the lack of significant schistosomular killing might result from the absence of factors which stimulate cell migration, since if a chemokinetic agent is introduced into the assay a 30% increase in mortality is recorded. The possible participation of neutrophils in the destruction of a primary and/or challenge infection in vivo is discussed.