The protective capacities of fractionated immune thoracic duct lymphocytes against Nippostrongylus brasiliensis

Thoracic duct lymphocytes (TDL) obtained from rats either on the tenth day of a primary infection (Day 10 TDL) or 1 or 5 weeks after a tertiary infection (hyperimmune TDL) with Nippostrongylus brasiliensis were fractionated into cells lacking (sIg^?) or bearing (sIg⁺) surface immunoglobulin by a rosetting procedure. The abilities of unfractionated TDL, of the two subpopulations, and of the reconstituted cells to confer protection against the parasite were examined. The effector cells which cause worm expulsion were found only in (sIg^?) cells from Day 10 TDL and also predominantly in (sIg^?) cells from hyperimmune TDL. However, a small but significant degree of protection was conferred by (sIg⁺) cells from hyperimmune TDL. These results suggest that the mechanisms involved in worm expulsion are regulated by (sIg^?) cells but that (sIg⁺) cells from hyperimmune rats can also contribute to the mechanisms of worm expulsion.     

Fate of H2-activated T lymphocytes in syngeneic hosts. III. Differentiation into long-lived recirculating memory cells.

Memory to H2 determinants was studied with an adoptive transfer system using a population of H2-activated blast T cells (T.TDL) obtained from thoracic duct lymph of irradiated F₁ hybrid mice injected with parental strain T cells. CBA T.TDL activated either to DBA/2 or C57BL determinants were transferred to syngeneic “B” mice. Thoracic duct lymphocytes (TDL) were obtained from the recipients 4–6 weeks later and tested for their capacity to produce (a) a graft-versus-host (GVH) reaction, (b) a mixed lymphocyte reaction (MLR) (measured by an in vivo technique) and (c) allograft rejection (suppression of the growth of allogeneic tumour cells in vivo). Control experiments involved testing the function of TDL obtained from “B” mice preinjected with TDL or no cells.TDL from “B” mice injected with TDL (passaged TDL) gave strong MLR and GVH reactions to both DBA/2 and C57BL determinants. Passaged T.TDL activated to C57BL antigens gave intermediate MLR and GVH reactions to the specific (C57BL) determinants but only very low responses to third-party (DBA/2) determinants; reciprocal results were obtained with passaged T.TDL activated to DBA/2 determinants. TDL from “B” mice given no cells failed to respond to either set of determinants.Since the responses by the passaged T.TDL did not exceed those by passaged TDL there was no evidence that adoptive transfer of T.TDL had conferred to the recipients a state of memory to either MLR or GVH determinants. Adoptive transfer did, however, lead to qualitative changes in the properties of T.TDL since, before transfer, they were unable to evoke GVH reactions or produce an MLR of normal kinetics.Passaged T.TDL were far superior to passaged TDL at suppressing the growth of allogeneic tumour cells. The protection was specific since protection against DBA/2 tumour cells was, cell for cell, 5–10 fold more effective with passaged T.TDL activated to DBA/2 determinants than with cells activated to C57BL determinants. No protection was observed with cells treated with anti-θ serum. The protective cells appeared to be precursors of effector cells rather than effector cells per se since they failed to lyse the tumour cells in vitro. These data suggest therefore that the descendants of T.TDL which survived after transfer to “B” mice were highly enriched in long-lived recirculating T lymphocytes reactive to determinants expressed by specific tumour allografts.     

Nippostrongylus brasiliensis: intestinal goblet-cell response in adoptively immunized rats.

Goblet-cell differentiation was studied in the intestinal epithelium of rats infected with the nematode Nippostrongylus brasiliensis. An increase in the proportion of goblet cells occurred at the time of worm expulsion in rats infected with 1000 or 4000 third stage larvae. Adoptive immunization of infected rats with immune-thoracic duct lymphocytes (TDL) induced extensive goblet-cell differentiation whereas the transfer of immune-TDL into normal rats had no effect. The extent of goblet-cell differentiation in adoptively immunized infected rats was proportional to the number of cells transferred. A goblet-cell response also occurred in adoptively immunized rats harboring implanted “normal” and “damaged” worms but recipients of normal worms which were not given cells were unable either to expel their worm burden or to induce a goblet-cell response. Experiments in which the parasites were expelled with an anthelmintic drug suggested that the goblet-cell increase was not simply a repair process associated with the expulsion of the parasites. In all situations where immune expulsion of the parasites occurred, there was a concomitant rise in the proportion of goblet cells. These experiments suggest that thoracic duct lymphocytes either directly or indirectly regulate the differentiation of intestinal goblet cells.     

Strongyloides ratti: Dissociation of the rat's protective immunity into systemic and intestinal components

Analysis of the early stages of a challenge infection with Strongyloides ratti has shown that protection is expressed against the developing third-stage larval worms (L₃) and prevents the maturation to adulthood of most larvae. Challenge after an immunizing infection that was restricted to the parenteral L₃ migratory phase showed that some 10–40% of overall protection could be ascribed to systemic antilarval immunity. Some larvae were trapped in the skin at the site of injection whereas others failed to migrate to the head and lung of immune rats. Larvae arriving in the intestine at Days 3, 4, and 5 did not persist beyond Day 7 and 8. Studies using [⁷⁵Se]methionine-labeled L₃ showed a significant increase in fecal label in rats immunized by a complete infection. This loss did not occur to the same extent in rats immunized only with parenteral larvae. Significant rejection of worms transplanted to the intestine also indicated intestinal protection. The possible existence of large numbers of worms in a state of “arrested development” was excluded by their failure to appear after cortisone treatment and the absence of worm accumulation in radiolabeling studies. It is concluded that at least two responses operate against larval S. ratti, one is systemic and the other operates in the intestine against larvae in a manner that resembles the “rapid expulsion” rejection of Trichinella spiralis in immune rats.     

Hymenolepis diminuta: The origin of protective antigens

Mice were infected orally with 1,6, or 30 cysticercoids of Hymenolepis diminuta. These were allowed to develop for different periods of time before elimination with anthelminthic, thus exposing the hosts to antigens from the prestrobilate, early strobilate, or fully strobilate worms. Other groups of mice were immunized by intraperitoneal (ip) implantation of a live strobilate worm or by ip implantation of live worms from cysticercoids excysted in vitro. Strong protection against challenge with a surgically transplanted strobilate worm was achieved by prior infection with 6 or 30 worms eliminated as early as Day 3 of infection. By this time these worms would not have strobilated. Conversely, a single worm, strobilating extensively over 16 days, stimulated only weak protection. Parenteral implantation of excysted worms protected mice but parenteral implantation of a strobilate worm had no effect. It is suggested that (i) the tapeworm protective antigens are primarily related to the scolex and/or the germinative region; (ii) the number of worms and the duration of antigenic stimulation in an immunizing infection determine the magnitude of a protective secondary response.     

Adoptive transfer of the intestinal mast cell response in rats infected with Nippostrongylus brasiliensis.

The intestinal mast cells (IMC) were examined in normal and adoptively immunized rats infected with Nippostrongylus brasiliensis. An increase in the numbers of IMC was observed in infected recipients of thoracic duct lymphocytes (TDL) obtained from donor rats which had themselves been infected 10 days previously (Day 10 TDL). The increase in the number of IMC in the mucosa was related to the number of Day 10 TDL transferred into infected recipients. When TDL were fractionated into populations of cells either bearing (sIg⁺) or lacking (sIg^?) surface immunoglobulin, only sIg^? cells were able to confer the IMC response. Antigenic stimulation was necessary for the differentiation of intestinal mast cells. There was a marked difference between different strains of rats with regard to worm burden and intestinal mast cell kinetics although the increase in intestinal mast cells was always closely related to the final stage of the rapid phase of worm expulsion. These results are compatible with the concept that intestinal mast cells are derived from T cells and suggest that sIg⁺ cells do not influence IMC differentiation. Alternatively, the possibility that the transferred TDL regulate the differentiation of cells of host origin into IMC cannot be excluded.     

The role of the spleen in protective immunity against Angiostrongylus cantonensis in rats: Splenectomy and passive spleen cell transfers

Splenectonuzed rats infected with Angiostrongylus cantonensis had more and longer worms and lower anti-A. cantonensis antibody titres compared to intact and sham operated rats. Splenectomy, however, had no effect on the capacity of rats to mount a cell-mediated immune response, as assessed by the in vitro uptake of tritiated thymidine by peripheral blood lymphocytes following stimulation by PHA and adult worm antigen. Adoptive protection and antibody production against A. cantonensis could be transferred with immune spleen cells. This protection was strongly dose and time dependent. Protection was adoptively conferred with 3 × 10⁹ spleen cells transferred 7 days before infection.     

Strongyloides ratti: Structural and functional characteristics of normal and immune-damaged worms

Adult Strongyloides ratti recovered at Day 6 of a primary infection in the rat appear normal in terms of ultrastructural morphology; the occurrence of membranous material within the gut lumen of the nematode indicates that such specimens are feeding. As the infection progresses, degenerate changes occur in the worm tissues. Lipid droplets and dense granules accumulate in intestinal cells. The contents of the gut lumen indicate that worms continue to feed until at least Day 20, but thereafter, as they migrate from the anterior to the posterior half of the intestine, feeding ceases. This is associated with the development of oral plugs, which contain host immunoglobulins, and may represent antigen-antibody complexes. Damaged worms are considerably smaller than 6-day normal worms, but this stunting is not reflected by a change in the thickness of the cuticle. Worms recovered 7 days after a challenge infection do not differ significantly from specimens recovered at the end of a primary infection. A seemingly unique feature of S. ratti is the existence of a “margination membrane” which delimits the brush border glycocalyx. This membrane shows unilaminar or multilaminar configurations, unlike a true lipid bilayer; possibly it is secreted by the parasite.     

Strongyloides ratti: reversibility of immune damage to adult worms

Transplantation experiments were conducted to assess the reversibility or irreversibility of the damage sustained by Strongyloides ratti during infections in the rat host. Worms of different ages from primary and secondary infections were recovered from their original hosts and transplanted surgically into naive rats. The size and fecundity of normal (Days 6–11 postinfection) worms were maintained after transfer. Damaged worms from primary infection (Days 22–26) showed complete recovery of size and fecundity within 10 days of transfer; damaged worms from a secondary infection (Days 6–7) also showed functional recovery but to a lesser extent. The ultrastructural changes observed mainly in the intestine of damaged worms from primary infections, prior to their transfer, were, however, only partially ameliorated following transplantation into new naive hosts; there was no complete return to structural normality. On the other hand, second infection worms did show almost complete ultrastructural recovery. The course of a transplanted infection established with either damaged or normal worms was similar to infections established percutaneously. Increase in the size of transplanted infections from 100 to 250 worms per recipient did not alter the dynamics of the host/parasite relationship. There was no evidence of adaptation in S. ratti and damaged worms, when transplanted into naive rats, were as successful as normal worms in protecting the host against a subcutaneous larval infection. The implications of this work on the present understanding of the phenomenon of autoinfection in experimental rodent strongyloidiasis are discussed.     

Schistosoma mansoni: reduction in clinical manifestations and in worm burdens conferred by serum and transfer factor from immune or normal rhesus monkeys.

Although delayed hypersensitivity to Schistosoma mansoni was conferred on rhesus monkeys (Macaca mulatta) by means of dialyzable transfer factor prepared from peripheral leukocytes or lymph node cells of infected immune donors, when such animals were challenged with 1000 cercariae of S. mansoni they developed worm burdens similar to those of nontreated controls. However, recipients of transfer factor that, in addition, received hyperimmune serum showed minimal clinical symptoms and significantly reduced worm burdens after subsequent infection with S. mansoni irrespective of whether the donors used for the transfer factor were immune or uninfected. A significant but lower degree of protection was conferred by combinations of either S. mansoni transfer factor or normal transfer factor and normal serum. Neither transfer factor nor hyperimmune serum alone conferred protection to recipients. Susceptibility to infection was assessed by observing the signs of the disease, determining the worm burdens by perfusion 10 weeks after exposure, and by observing the appearance of the intestine at autopsy. The animals which received transfer factor and immune serum were protected against clinical disease. Good correlation between worm burdens and severity of disease was observed.     

Immunity against trichostrongylus colubriformis infection in guinea-pigs and sheep: Some comparisons with Nippostrongylus brasiliensis infection in the rat

In Nippostrongylus brasiliensis infection in rats there is evidence that antibodies ‘damage’ the worms rendering them susceptible to other components of the host immune response. Some of the experiments from which this evidence was obtained were repeated in Trichostrongylus colubri-formis infections in guinea-pigs and sheep.Lesions similar to those described in ‘damaged’ N. brasiliensis were present in T. colubriformis, but unlike damaged N. brasiliensis, damaged T. colubriformis were not rapidly expelled from the intestine of either normal or adoptively immunized hosts. Other differences between the two infections included the failure of serum from T. colubriformis-immune donors either to regularly transfer immunity against infection to non-immune recipients or to endow additional immunity on recipients of lymphoid cells from immune donors.It is suggested that the results might reflect differences between the manner in which guinea-pigs and rats achieve immune expulsion of gastro-intestinal nematode parasites.     

In vivo and in vitro analysis of the resistance against viral haemorrhagic septicaemia virus in Japanese flounder (Paralichthys olivaceus) precedingly infected with aquabirnavirus

The resistance of Japanese flounder (Paralichthys olivaceus Temminck et Schlegel) against a viral haemorrhagic septicaemia virus (VHSV) challenge induced by a preceding non-lethal aquabirnavirus (ABV) challenge was investigated through experimental dual-infections with different intervals between the two challenges. The non-specific protection conferred by the primary ABV infection against the secondary VHSV infection commenced at Day 3 and persisted up to Day 14 but vanished at Day 21 post-ABV challenge. The in vitro assay using HINAE (hirame natural embryo) cells demonstrated anti-VHSV activity in the serum of ABV-challenged flounder from Day 1 to Day 14 but not at Day 21 post-ABV challenge. A high expression of a Mx gene, a molecular marker of type I interferon(s) (IFN) occurred in the head kidneys of ABV-challenged flounder from Day 1 to Day 7. These results suggest that the non-specific protection against the secondary VHSV infection in flounder was due to IFN(s) induced by the primary ABV infection.     

Trichinella spiralis: mediation of the intestinal component of protective immunity in the rat by multiple, phase-specific, antiparasitic responses.

Rats infected orally with Trichinella spiralis developed an immunity that was induced by and expressed against separate phases of the parasite's enteral life cycle. Infectious muscle larvae generated an immune response (rapid expulsion) that was directed against the very early intestinal infection and resulted in the expulsion of worms within 24 hr. This response eliminated more than 95% of worms in an oral challenge inoculum. Developing larvae (preadults) also induced an immune response that was expressed against adult worms. The effect on adults was dependent upon continuous exposure of worms to the immune environment throughout their enteral larval development. Immunity induced by preadult T. spiralis was not expressed against adult worms transferred from nonimmune rats. While adult worms were resistant to the immunity engendered by preadults they induced an efficient immunity that was autospecific. Both “preadult” and “adult” immunities were expressed in depression of worm fecundity as well as in the expulsion of adults from the gut. However, the two reactions differed in respect to their kinetics and their efficiency against various worm burdens. Preadult immunity was directed mainly against fecundity whereas adult immunity favored worm expulsion. All responses (rapid expulsion, preadult and adult immunity, and antifecundity) acted synergistically to produce sterile immunity against challenge infections of up to 5000 muscle larvae. These findings indicate that the host protective response to T. spiralis is a complex, multifactorial process that operates sequentially and synergistically to protect the host against reinfection.     

Dipetalonema viteae: Response of spleen cells in experimental mouse filariasis to mitogens and antigens

Balb/c mice were infected by transplanting 3, 5, 10, or 20 female adult Dipetalonema viteae under the dorsal skin. The microfilaremias resulting from infections with 3 or 5 adult worms were of lesser magnitude and of shorter duration than those produced in infections with 10 or 20 worms. Spleen cells taken from these mice at various intervals after infection were assayed in vitro for their ability to respond to phytohemagglutinin (PHA) or lipopolysaccharide (LPS). There was no depression in the response to LPS or to PHA in mice given infections of 3 or 5 D. viteae adult worms. In contrast, the response to PHA was significantly depressed in groups receiving 10 or 20 adult female worms 12 days after infection and by Day 25, the depression was severe. Thereafter the PHA responsiveness recovered gradually to reach control values on Day 60. In mice transplanted with 10 or 20 D. viteae adult worms there was no significant depression in the response to LPS at any time during the infection, but the response was increased slightly sporadically during infection. These results indicate that in mice, this infection causes an initial suppression in the function of PHA-sensitive T cells but has little effect on the B cells which respond to LPS. A factor present in serum taken on Day 25 from mice infected with 10 or 20 adult worms inhibited the proliferative response to PHA by spleen cells from normal mice. The recovery of PHA responsiveness in mice given the heavier infections coincided with death of the adult worms, but mitogen reactivity and microfilaremia were unrelated. Antigens from male or female worms induced cell division in spleen cells taken from infected mice after microfilaremia had ceased whether they were implanted with 3 or 10 adult worms.     

Characterization of cellular and molecular immune effectors against Trichinella spiralis newborn larvae in vivo.

The cellular and molecular immune effectors that participated in host immunity against Trichinella spiralis newborn larvae were characterized in vivo using AO rats. Donor rats were immunized with 2,000 muscle larvae orally or 11,400 newborn larvae i.v. Immune serum and cells from spleen, peripheral lymph nodes, mesenteric lymph node, thoracic duct lymph and the peritoneal cavity were obtained from donor rats 10-21 days after infection and transferred into normal recipient rats. The control recipients received either no cells and serum or normal cells and normal serum obtained from normal donors. Newborn larvae (20,000-50,000) were injected either i.v. or ip into these recipients and immunity against newborn larvae was measured either by muscle larvae burden of the recipients three weeks later or by direct recovery of newborn larvae from the peritoneal cavity of the recipients. The experiments demonstrated that immune lymphocytes conferred no protection in the recipients but that immune serum and immune peritoneal cells were protective and these effects were synergistic. Cell adherence to the cuticle and killing of newborn larvae were observed in the peritoneal cavity of immune rats. Positive fluorescence was observed on newborn larvae incubated with fractionated IgM and IgG(E) antibody isotypes. Massive deposition of antibody molecules on newborn larvae was demonstrated by scanning electron microscopy. Studies using transmission electron microscopy revealed that the larval adherent cells were stimulated macrophages, neutrophils and eosinophils.     

Migration of recently divided B and T lymphocytes to peritoneum and lung

It is recognized that a population of newly divided (or young) cells migrate preferentially to inflamed foci. It has been shown that a large proportion of lymphocytes residing in the bronchoalveolar airspaces of rat are recently divided cells and that blood may be an important source of these cells. To further delineate how blood may contribute to lymphocyte subpopulations in inflamed peritoneum and lung, a comparison of the capacity of recently divided T and B cells to migrate from blood to inflamed peritoneum and lung was made. To label young lymphocytes, DA strain donor rats were given Initiated thymidine by vein in vivo for 7 days. After thoracic duct drainage, the following labeled cell populations were adoptively transferred by vein into syngeneic recipients: (i) unseparated thoracic duct lymphocytes (TDL), (ii) enriched T cells (>90%) or B cells (>80%) recovered after passage of TDL through nylon columns, and (iii) thoracic duct lymphocytes (> 99% B cells) obtained from “B rats” that were prepared by X irradiation, thymectomy, and bone marrow reconstitution. T and B cells were identified by specific heterologous antisera. The percentage recovery of labeled lymphocytes in the recipients with inflamed peritoneum or lung aspirates was determined from cell counts and autoradiographs. The studies indicated that (a) both labeled T and B cells migrated to inflamed peritoneum and lung; (b) labeled B cells migrated to peritoneum and lung better than did labeled TDL or T cells; and (c) labeled lymphocytes did not migrate to unstimulated peritoneum. The enhanced migration of newly divided B lymphocytes to inflamed peritoneum and normal lung (a site that is likely under chronic antigenic stimulation) was unexpected, but may provide additional information on the relative contribution of these subpopulations in the immune inflammatory response.     

Influence of serum donor and recipient mouse genotype on the passive transfer of protective immunity with serum against Nematospiroides dubius

Dobson C., Brindley P. J. and Sitepu P. 1982. Influence of serum donor and recipient mouse genotype on the passive transfer of protective immunity with serum against Nematospiroides dubius. International Journal for Parasitology12: 567–572. Different strains of serum donor mice showed variations in innate immunity to primary infections with Nematospiroides dubius. Different levels of anti-N, dubius antibodies were detected in sera from these mouse strains; there was no correlation between antibody titre and numbers of worms recovered. Serum from donor wild and six laboratory strains of mice protected female Quackenbush (Q) recipients against N. dubius infections; donor mouse strain influenced the degree of protection conferred and donor serum antibody titre related to the degree of stunting of worm growth in recipient mice. Five laboratory strains of mice developed different levels of protective immunity following multiple experimental infections with N. dubius. Antibody titres in these mice were strongly correlated with the percentage protection observed after 1–4 infections: Q and CBA mice produced more anti-N. dubius antibody and were better protected than DBA/2, BALB/c and C3H mice. However BALB/c, C3H and CBA mice attained similar anti-N. dubius antibody titres after a single infection with N. dubius but serum from BALB/c gave better protection when transferred to female Q recipients than that from the other two strains. This suggested qualitative differences in the protective antibodies in sera between mouse strains. Five mouse strains were passively immunized with a uniform dose of serum from female Q donors: DBA/2 female recipients showed the least, BALB/c and C3H females were intermediate, and Q and CBA female mice attained the greatest level of passive protection against N. dubius. A close positive correlation existed between the degree of actively acquired and the level of passively acquired protection between the five strains of mice.     

Detection of the precursor and effector cells of experimental allergic encephalomyelitis in the thoracic duct of the rat

Despite strong evidence pointing to the fundamental role of the T cell in the pathogenesis of experimental allergic encephalomyelitis (EAE), little has been known about the normal traffic of the precursor (unprimed) and effector (primed) cells of EAE. We have demonstrated the recirculation of the precursor cells in that B rats regained their susceptibility to EAE following reconstitution with thoracic duct lymphocytes (TDL) passed through an irradiated intermediate host as well as following reconstitution with normal thymocytes or normal TDL. The effector cells were shown to be present in TDL in that TDL from donors immunized 11 or 12 days prior to transfer could passively transfer EAE to naive recipients.     

Brugia pahangi in nude mice: protective immunity to infective larvae is Thy 1.2+ cell dependent and cyclosporin A resistant

Mechanisms of protective immunity to larvae of Brugia pahangi were studied in congenitally athymic nude C3H/HeN mice and their syngeneic heterozygous littermates. An average 11% of subcutaneous larval inocula was recovered from control nudes 28 days after inoculation. No worms were recovered from nude recipients of viable splenic Thy 1.2+ T lymphocytes from heterozygotes which had killed a priming dose of B. pahangi larvae. Primed T lymphocytes, depleted of either Lyt 1.1+ or Lyt 2.1+ cells or incubated with anti-Thy 1.2 monoclonal antibody and complement, failed to protect nude mice against a larval challenge. Nor were primed B lymphocytes depleted by Thy 1.2+ T cell contaminants protective. Treatment with cyclosporin A (CsA) did not increase the numbers of worms recovered from heterozygotes nor did CsA treatment of heterozygous cell donors abolish the ability of primed Thy 1.2+ T lymphocytes to transfer protection to nude mice. IgG but not IgM antibody titres to B. pahangi antigens were depressed in all CsA-treated mice. CsA treatment of nude mice had no direct effect upon development of B. pahangi larvae. These results show that protective immunity to larvae of B. pahangi in mice depends upon small numbers of Thy 1.2+ T cells which are CsA-resistant.     

Fate of H2-activated T lymphocytes in syngeneic hosts: II. Residence in recirculating lymphocyte pool and capacity to migrate to allografts

T.TDL—a purified population of lymph-borne H2-activated T lymphocytes—were transferred to syngeneic mice to examine their capacity to remain in the recirculating lymphocyte pool (RLP). Experiments with cells labelled with ³H-thymidine (³HTdR) or ⁵¹Chromium showed that although a considerable proportion of T.TDL joined the RLP (i.e., were mobilizable through a thoracic duct fistula) for several days after transfer, most of the cells soon left the pool. This applied whether the cells were transferred to normal mice or to “B” mice. Normal thoracic duct lymphocytes, by contrast, joined the RLP for long periods post-transfer.Studies with ³HTdR-labelled T.TDL showed that a small number of heavily labelled cells remained in the RLP for at least 3 months. Experiments with the θ-antigen as a cell marker suggested that a further small proportion of cells underwent division at some stage after transfer and then rejoined the RLP in expanded numbers.T.TDL showed a tendency to home to specific allografts of either skin, tumor cells or lymphoid cells. Although homing was specific it was very limited in extent.