Correlations between worm burden and markers of Th1 and Th2 cell subset induction in an inbred strain of mouse infected with Trichuris muris

Helper T cell subset induction was examined within a single inbred strain of mouse (B10.D2/n) where individuals varied in their ability to expel the nematode parasite Trichuris muris. In this mouse strain approximately half of infected individuals resist infection whilst half are unable to expel the parasite and harbour chronic mature adult worm infections. We here assess various T cell and serological parameters in individual B10.D2/n mice infected with T. muris in relation to the number of parasites harboured. Worm burdens showed very significant negative correlations with five different parameters indicative of the selective expansion within the host of helper T cells of the Th2 subset. Thus, in vitro IL-5 and IL-9 production by restimulated mesenteric lymph node cells, total IgE levels, the early parasite-specific IgG1 response (all P < 0.01) and intestinal eosinophilia (P < 0.05), were all significantly negatively correlated with worm burden. In addition, levels of IL-3 were significantly greater in mice resistant to infection (P < 0.01). In contrast there was a significant positive correlation between worm burden and parasite-specific IgG2a levels (P < 0.05), IgG2a production being under the tight control of the Th1-specific cytokine IFN-gamma and thus a reliable marker for in vivo Th1 cell activation. The data demonstrates that an individual infected with T. muris is capable of mounting either a protective Th2-type response or an inappropriate Th1-type response.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunological relationships during primary infection with Heligmosomoides polygyrus (Nematospiroides dubius): downregulation of specific cytokine secretion (IL-9 and IL-10) correlates with poor mastocytosis and chronic survival of adult worms

Mice were infected either with Trichinella spiralis (day 0), Heligmosomoides polygyrus (day-14) or concurrently with both species and were killed in groups, together with naïve control mice, on 2 occasions (day 8 and 15 post infection with T. spiralis, corresponding to days 22 and 29 p.i. with H. polygyrus). The expulsion of T. spiralis was slowed significantly in concurrently infected mice and this was associated with a reduced mastocytosis and lower serum mucosal mast cell protease levels. Mesenteric lymph node (MLN) lymphocytes from all three experimental groups secreted IL-3 and IL-4 in copious amounts when stimulated in vitro by Concanavalin A (Con-A), but the secretion of high levels of IL-9 and IL-10 was essentially confined to mice infected with T. spiralis alone. It is suggested that adult H. polygyrus selectively modulate cytokine secretion by Th2 cells within the MLN during infection and that this is brought about as a direct consequence of the mechanism employed by H. polygyrus to depress mucosal inflammatory responses in order to facilitate its own survival.

Cytokine production in BALB/c mice immunized with radiation attenuated third stage larvae of the filarial nematode, Brugia pahangi

BALB/c mice immunized with radiation attenuated third stage larvae of the filarial nematode Brugia pahangi are strongly immune to challenge infection. Investigation of the profile of cytokines secreted by spleen cells from immune mice stimulated in vitro with either parasite Ag or with Con A revealed high levels of IL-5 and IL-9 and moderate levels of IL-4. In contrast, secretion of IFN-gamma by spleen cells from immune animals was negligible. Spleen cells from control mice secreted low levels of all cytokines assayed. Levels of parasite-specific IgE were significantly elevated in immune animals and a peripheral blood eosinophilia was observed, which exhibited a biphasic distribution. Our results are consistent with the preferential expansion of Th2 cells in immune animals and provide the basis for dissecting the means by which radiation attenuated larvae of filarial nematodes stimulate immunity.

Cytokine production in BALB/c mice immunized with radiation attenuated third stage larvae of the filarial nematode, Brugia pahangi

BALB/c mice immunized with radiation attenuated third stage larvae of the filarial nematode Brugia pahangi are strongly immune to challenge infection. Investigation of the profile of cytokines secreted by spleen cells from immune mice stimulated in vitro with either parasite Ag or with Con A revealed high levels of IL-5 and IL-9 and moderate levels of IL-4. In contrast, secretion of IFN-gamma by spleen cells from immune animals was negligible. Spleen cells from control mice secreted low levels of all cytokines assayed. Levels of parasite-specific IgE were significantly elevated in immune animals and a peripheral blood eosinophilia was observed, which exhibited a biphasic distribution. Our results are consistent with the preferential expansion of Th2 cells in immune animals and provide the basis for dissecting the means by which radiation attenuated larvae of filarial nematodes stimulate immunity.

Immunity to coccidiosis: genetic influences on lymphocyte and cytokine responses to infection with Eimeria vermiformis in inbred mice

Cellular and cytokine responses to infection with Eimeria vermiformis were compared in BALB/c (resistant) and C57BL/6 (B6-susceptible) inbred mice. Cellular responses in the mesenteric lymph node (MLN) occurred sooner after primary infection in the resistant BALB/c strain. In contrast, proliferative responses occurred earlier after challenge in B6 mice. Resting levels of CD4 + ve and CD8 + ve T-lymphocytes in the MLN differed between the two strains but the relative numbers of each subset remained relatively constant throughout primary infection. MLN cells taken at intervals after infection were assayed for release of the cytokines IFN-gamma, IL-5 and IL-10 after culture in vitro with the mitogen Concanavalin A (Con-A) or with parasite antigen. With either stimulus cells from resistant BALB/c mice released IFN-gamma and IL-5 earlier after infection than did B6 cells. The strains had a comparable absolute ability to produce IFN-gamma but BALB/c cells released more IL-5 than did B6, levels declining, rather than increasing, during primary infection in the latter. Only cells from BALB/c mice released IL-10 during infection. Cells taken after a secondary infection released relatively little cytokine after pulsing in vitro. These data suggest that the difference in response phenotype between the two strains when infected with E. vermiformis reflect a kinetic, rather than a qualitative, difference in ability to mount protective T-helper (Th) cell subset responses. No evidence was found for a Th2-mediated interference with ability to release IFN-gamma, the cytokine most closely associated with protective immunity.

The in vivo role of stem cell factor (c-kit ligand) on mastocytosis and host protective immunity to the intestinal nematode Trichinella spiralis in mice

The role of stem cell factor (SCF) in the generation of intestinal mast cell hyperplasia and host protective immunity following helminth infection was investigated using the Trichinella spiralis/mouse model. In vivo administration of a monoclonal antibody specific for the receptor for SCF (c-kit) was found to completely prevent the generation of intestinal mastocytosis normally observed following T. spiralis infection. This was reflected by markedly reduced intestinal mast cell protease (IMCP) levels in both tissue and serum. Moreover, animals treated with anti-c-kit antibody failed to show any evidence of worm expulsion from the gut. The data demonstrate for the first time, a critical role for the SCF in the generation of mucosal mastocytosis and host protective immunity following an intestinal helminth infection.

Genetic influences upon eosinophilia and resistance in mice infected with Trichinella spiralis

Genetic influences upon host variation in eosinophilia and resistance to helminth infection, and the relationship between these parameters, were investigated in 7 inbred and 1 hybrid strains of mice infected with Trichinella spiralis. Clear strain-dependent variations were observed in the maximum peripheral blood, bone marrow and spleen eosinophilia attained in infected animals. SWR, NIH and SJL strains of mice all gave high responses to infection; four congenic strains sharing the B10 background (C57BL10 [B10], B10.S, B10.G and B10.BR) were low responders. Some of the genes for high responsiveness appeared to be dominant, as F1 hybrids from high- and low-response phenotype parental strains showed intermediate to high responses to infection. Intestinal eosinophilia showed no correlation with either peripheral blood or bone marrow responses (NIH and B10 strains having similar levels of eosinophil response in gut tissue) and was unrelated to the level of resistance to infection. Whereas NIH were highly resistant, with adult worm burdens at 13 days post-infection and muscle larval burdens at 35 days post-infection significantly lower than all other strains, B10 were quite susceptible, retaining substantial worm burdens at day 13 and harbouring large numbers of muscle larvae. Measurements of the level of the eosinophilopoietic cytokine IL-5 in sera during infection showed that the two strains differed in the kinetics of release but not in their absolute capacity to produce this cytokine. NIH mice released high levels during a primary infection, B10 released high levels during a secondary infection.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of cytokine production and response phenotypes in murine trichuriasis

BALB/K mice are usually resistant to infection with the intestinal nematode parasite Trichuris muris and exhibit a Th2 dominated (IL-5, IL-9) response. Conversely in B10.BR mice, which are unable to expel T. muris, Th1 type (IFN-gamma producing) cells predominate. We have manipulated the course of infection in these two strains of mice such that the period of host-parasite contact is extended in the former and curtailed in the latter. Extension of host-parasite contact in BALB/K mice beyond normal (day 21) resulted in the modulation of cytokines produced by in vitro concanavalin A (Con-A) stimulated MLNC away from IL-5 and IL-9 (Th2-type cytokines) in favour of the Th1-type cytokine IFN-gamma. Curtailment of host parasite contact in B10.BR mice to less than 21 days resulted in elevated production of IL-5 and IL-9 by MLNC in the absence of elevated IFN-gamma levels. Thus modulation of expulsion phenotype also modulates cytokine production by T-cells in the MLN draining the site of infection, with a Th2 response being associated with resistance and a Th1 type response with the inability to expel the parasite. Mechanisms by which the modulated cytokine profiles arise are discussed.

T lymphocyte dependent enteropathy in murine Trichinella spiralis infection

Mice infected with Trichinella spiralis developed significant enteropathy, comprising villus atrophy, crypt hyperplasia, goblet cell hyperplasia and a decrease in intra-epithelial lymphocyte numbers by 10 days post-infection, when most of the parasites had been expelled from the gut. However, worm expulsion was prevented by treatment with cyclosporin A and, despite a continued parasite burden, cyclosporin A treated animals had no villus atrophy or changes in inflammatory cell numbers. These results confirm that the expulsion of T. spiralis from the mouse gut is accompanied by a significant intestinal lesion and that both of these phenomena are T-cell mediated.

Cellular immune responses to the murine nematode parasite Trichuris muris. II. Differential induction of TH-cell subsets in resistant versus susceptible mice

We have analysed the production of a wide variety of cytokines by in vitro concanavalin A (Con A) stimulated mesenteric lymph node cells (MLNC) from strains of mice experiencing chronic (B10.BR, AKR) versus acute (BALB/K) infection with the nematode parasite Trichuris muris. MLNC from infected BALB/K mice produced elevated levels of the Th2-specific cytokines interleukin-5 (IL-5) and IL-9. IL-3 and IL-4 remained at or just above normal. Interferon-gamma (IFN-gamma) (a Th1-type cytokine) was secreted only in small amounts. MLNC from infected susceptible B10.BR and AKR mice produced large amounts of IFN-gamma in the relative absence of IL-4 and IL-9. IL-5 levels failed to rise significantly above normal in B10.BR mice whilst in AKR mice high levels of IL-5 were detected early post-infection (p.i.) but levels decreased dramatically as the infection proceeded to reach normal levels by Day 34. IL-3 levels were depressed below normal. Our results are consistent with the polarization of the Th-cell response during T. muris infection to give predominantly IFN-gamma-secreting Th1 cells in strains of mice unable to expel the parasite and mainly IL-4, IL-5 and IL-9 producing Th2-type cells in resistant strains.

Host protective immunity to Trichinella spiralis in mice: activation of Th cell subsets and lymphokine secretion in mice expressing different response phenotypes

Host protective immunity to the intestinal dwelling nematode Trichinella spiralis is mediated by CD4+ mesenteric lymph node (MLN) cells during the course of intestinal infection. The present study has examined the cytokine production by T cells within the MLN of two H-2-compatible strains of mice infected with T. spiralis which differ in the speed at which they expel the parasite from the gut. For both strains of mice, in vitro stimulation of MLN cells with a protective worm antigen preparation resulted in secretion of elevated levels of interleukin-3 (IL-3), IL-4, IL-5 and IL-9 compared to controls. Negligible levels of interferon-gamma (IFN-gamma) were secreted. Furthermore, a similar pattern of cytokine secretion was observed from MLN cells taken from infected mice after in vitro stimulation by T-cell mitogens. No evidence was found for a relationship between quantity of cytokine secreted and the differences in speed of parasite expulsion in the two strains of mice studied. The results support the hypothesis that protective immunity to T. spiralis infection is associated with the activation of Th2-type cells within the MLN in the relative absence of Th1-type cells.

Cellular immune responses to the murine nematode parasite Trichuris muris. I. Differential cytokine production during acute or chronic infection

A variety of T-cell parameters have been analysed in two H-2 compatible strains of mice, B10.BR and BALB/K, which differ in an absolute fashion in their ability to resist infection with the parasitic nematode Trichuris muris: BALB/K mice expel T. muris relatively rapidly, whereas B10.BR mice are unable to expel the parasite before the infection reaches patency. Analysis of Th1- and Th2-specific cytokines (IFN-gamma and IL-5, respectively) produced by in vitro Con A-stimulated mesenteric lymph node cells (MLNC) from infected and normal mice demonstrated that MLNC from resistant BALB/K mice produced high levels of IL-5 and low levels of IFN-gamma whilst B10.BR MLNC secreted large amounts of IFN-gamma in the relative absence of IL-5. As an in vivo correlate of in vitro IL-5 production, peripheral and tissue eosinophilia were quantified during the course of infection in the two strains of mice. No peripheral eosinophilia was observed in BALB/K or B10.BR individuals. However, a considerable intestinal eosinophilia was seen in the high IL-5-producing BALB/K mice compared to normal levels. Differences observed in cytokine profiles were not due to differential changes in the numbers of T cells within the MLN. Indeed, FACS analysis revealed a decrease in the relative percentage of CD4+ and CD8+ T cells in both strains of mice post-infection. Our results suggest that resistance to T. muris involves the preferential induction of Th cells which secrete IL-5, whilst cells of a different Th subset (IFN-gamma producing) predominate in chronically infected mice. As such, this represents the first description of a correlation between the reciprocal activation of Th cell subsets in relation to acute or chronic intestinal infection with the same parasite in the same host species.

Trichuris muris: antigen recognition and transfer of immunity in mice by IgA monoclonal antibodies

Mesenteric node lymphocytes from mice that had been infected with the nematode Trichuris muris, and then boosted with adult worm excretory-secretory antigens were fused with myeloma cells to produce a panel of 9 monoclonal antibodies (MoAbs). Five of the MoAbs were of the IgA isotype. The antigen recognition profiles of these MoAbs were studied using SDS-PAGE and immunoblotting; three major profile patterns were identified. Five MoAbs recognized a major band in the MW range 43-48 kD; all recognized a range of antigens. Three MoAbs were used to localize antigens in the bodies of adult worms. Granules within the anterior stichocytes were recognized strongly, as was material within the eggs and pseudocoelom. Two MoAbs stained the cuticle. Although the phosphorylcholine (PC) determinant was widely distributed within worm tissues none of the MoAbs tested recognized PC. Passive transfer of immunity was achieved using two of the IgA monoclonals; no immunity was transferred by the IgM and IgG MoAbs used. The limited recognition profiles of these IgA MoAbs, and the ability to stain stichocyte granules, suggest that their protective activity results from an interaction with ES antigens.

Genetic control of mast cell development in bone marrow cultures. Strain-dependent variation in cultures from inbred mice

A comparison was made of the capacity of bone marrow cells (BM) from genetically distinct strains of mice to develop into mast cells under defined conditions of in vitro culture. In the presence of conditioned media derived from ConA treated spleen cells from normal or Trichinella spiralis-infected mice, mast cell development occurred readily. After 21 days of culture mast cells comprised more than 90% of the total cell population. BM taken from certain strains of mice (SWR and NIH) produced large numbers of mast cells, total cell numbers increasing between 2 and 5 fold; other strains (C57BL/10 [B10] B10 congenics) produced relatively few mast cells, total cell numbers not increasing above the starting concentration or declining during culture. The genetic factors determining the strain-response phenotype (no. of mast cells in culture) were predominantly associated with the background genome. No significant differences in response were noted between the B10 congenic strains B10 [H-2b], B10.G [H-2q] or B10.BR [H-2k], which differ only at the MHC, whereas major differences were seen between B10.G and the other H-2q strains [SWR and NIH]. Response phenotype was not inherited as a simple dominant trait; F1 progeny of high x low responder strains were intermediate between the parental values. The expression of genetic influences upon mast cell response phenotype appears to be at both the level of mast cell precursor cells, as determined from limiting dilution assays of BM from high, low and F1 (high x low) strains, and at the level of mast cell proliferation, as determined by repeated sub-culture of mast cells from these strains.

Mediation of immunity to Eimeria vermiformis in mice by L3T4+ T cells

Immunity to infection with Eimeria vermiformis was transferred in NIH mice by both the nylon wool-adherent (B-cell-enriched) and nonadherent (T-cell-enriched) fractions of lymphocytes (spleen and mesenteric lymph node) taken from infected donors. Transfer was more variable with the adherent fraction, and when contaminating T cells were removed by treatment with anti-Thy1 monoclonal antibody (MAb) and complement, this fraction lost all protective activity. The protective effect of T-cell-enriched populations of mesenteric lymphocytes was abrogated by treatment with anti-L3T4 MAb and complement in vitro before transfer or by opsonization with this MAb in vitro before intravenous inoculation into recipients. Similar treatments of cells with anti-Lyt2 MAb did not have this effect, confirming that Thy1+ L3T4+ cells mediate the adoptive transfer of immunity to E. vermiformis. Thy1+ L3T4+ cells were also shown to limit the replication of E. vermiformis in primary infections: mice depleted of this subset (by thymectomy followed by intravenous injection of anti-L3T4 MAb) passed greater numbers of oocysts over a longer period of time than did mice similarly depleted of Lyt2+ cells.

Release of leukotrienes during rapid expulsion of Trichinella spiralis from immune rats

Rapid expulsion of the nematode Trichinella spiralis from immune rats is associated with an increase in volume of intestinal exudate and the presence of large numbers of tissue mucosal mast cells (MMC) and eosinophils. We have measured the concentrations of leukotrienes (LT) C4 (LTC4) and B4 (LTB4) in gut perfusates and mucosal homogenates at 30 min, 1, 3, 6 and 20 hr after challenge with larvae. Leukotrienes were identified by radioimmunoassay (RIA) combined with reverse-phase high-pressure liquid chromatography (RP-HPLC). There were significant elevations at 30 min and 1 hr in the concentrations of LTC4 in the perfusates from the gut of challenged immune rats compared to controls (infected unchallenged and uninfected naive rats). Similar increases in immunoreactive LTC4 and LTB4 were observed in mucosal homogenates from the gut of immune challenged animals. A second peak of LTB4 was also observed at 20 hr in both immune and naive challenged rats. There were also elevations in serum concentration of the MMC-associated specific serine protease, rat mast cell protease II (RMCPII). Since LTC4 causes smooth muscle contraction, increased vascular permeability and stimulation of mucus hypersecretion, and LTB4 recruits and activates inflammatory cells, leukotrienes may participate in the process of rapid expulsion of T. spiralis.

Lymphokine production by T cells generated during infection with Trichinella spiralis

Lymphokine production by mesenteric lymph node cells (MLNC) taken from mice during infection with the intestinal nematode parasite Trichinella spiralis was investigated. Upon stimulation in vitro with a protective crude antigen preparation of the infective L1 larvae, MLNC proliferated in a specific manner, and were observed to release the T-cell lymphokines IL-2, IL-3 and interferon. IL-2 and IL-3 release by MLNC was greatest when taken during the early intestinal phases of infection. Interferon was also released by cells taken from infected mice, with highest levels observed shortly after expulsion of the parasite from the gut. MLNC taken during the early intestinal phases of infection were also able to respond and proliferate to an exogenous source of IL-2, suggesting clonal expansion of T cells within the node. Lymphokine release from T. spiralis specific T-cell lines was also examined.

Immunization of mice with surface antigens from the muscle larvae of Trichinella spiralis

Surface antigens of muscle larvae of Trichinella spiralis were stripped from the cuticle of live worms by the cationic detergent cetyltrimethylammonium bromide (CTAB). Such antigen preparations were shown to contain surface antigens of approximate molecular weights 100,000, 90,000, 69,000, 55,000, 46,000 and 35,000. Immunoprecipitation experiments confirmed that the surface of muscle larvae share antigenic epitopes with antigens contained within and secreted by the stichosome. CTAB antigen preparations were shown to be protective in NIH mice against a challenge infection as assessed by reduction in intestinal worm burden, worm fecundity, worm length and muscle larvae burden. The role of surface antigens in protective immunity to T. spiralis is discussed.

Immunity to tapeworms: intraspecific cross-protective interactions between Hymenolepis citelli, H. diminuta and H. microstoma in mice

Interactions between tapeworm species in a single host offer intriguing opportunities for immunological studies that attempt to identify the mechanism(s) underlying protection against cestode infections. Mice that are immunized against Hymenolepis citelli infections were shown to be refractory to subsequent H. diminuta challenge infections. The reciprocity of the response was also demonstrated, although the protection recorded for H. diminuta when mice are sensitized with H. citelli is weaker than that observed when mice are primed with H. diminuta against H. citelli challenge. H. citelli was also shown to be expelled simultaneously during the rejection phase of H. diminuta in concurrent infections, indicating the susceptibility of the former tapeworm to the rejection mechanism initiated by the latter. H. microstoma-immunized mice were shown to be strongly protected against heterologous H. citelli challenge. However, mice primed against H. citelli were not as strongly protected against H. microstoma challenge infections: a statistically significant protection was obtained only after a 12-cysticercoid H. citelli primary infection, although a 6-cyst infection did stunt the growth of H. microstoma challenge worms. It is presently suggested that the cross-protective responses observed in the study between H. citelli, H. diminuta and H. microstoma may have emanated from a specific immunological cross-reactivity due to the sharing of similar immunogens.

Antigen-specific T-cell lines transfer protective immunity against Trichinella spiralis in vivo

T-cell lines specific for infective muscle larvae antigens of the intestinal nematode Trichinella spiralis have been generated in vitro. These antigen-specific T-cell lines express the L3T4+ Ly2- phenotype and secrete the lymphokines IL-2, IL-3 and gamma-IFN. They are stable in culture for up to 15 weeks and are protective when adoptively transferred into naive recipients. As few as 2 x 10(5) T. spiralis-specific tract. In addition, intestinal mastocytosis and peripheral blood eosinophilia were accelerated after adoptive transfer of T. spiralis-specific T-cell lines.

Genetic control of immunity to Trichinella spiralis in mice. Response of rapid- and slow-responder strains to immunization with parasite antigens

Slow-responder C57BL/10 (B10) mice responded poorly to immunization with muscle larval antigen of Trichinella spiralis showing no accelerated loss of worms from a subsequent challenge infection. In contrast, rapid-responder NIH mice and (B10 X NIH) F1 mice developed high levels of immunity after immunization. Lymphocyte proliferation studies showed that immunized B10 mice did respond to in vitro restimulation with antigen, though less well than NIH mice. Failure of B10 mice to respond to immunization did not therefore reflect a failure to recognize larval antigen, a view confirmed by the fact that immunization was achieved using abbreviated enteral infections and, to a smaller extent, by parenterally administered muscle larvae.

L3T4-positive T lymphoblasts are responsible for transfer of immunity to Trichinella spiralis in mice

The characteristics of lymphocyte subpopulations involved in mediating immunity to the intestinal nematode Trichinella spiralis in vivo have been examined using adoptive transfer in conjunction with accurate cell-sorting and cell-depletion techniques. Positive selection of cell subsets, using FACS sorting and velocity sedimentation at unit gravity, confirm that rapidly dividing T blasts are the major population that mediates expulsion of the worm from the gut. Furthermore, cell-depletion studies demonstrated that the T-cell subset involved is of the L3T4 + ve Lyt 2-ve phenotype. This phenotype suggests class II MHC restriction in recognition of T. spiralis antigens by T cells in vivo. The roles that such T cells play in immunity to T. spiralis are discussed in terms of lymphokine release.

Genetic control of immunity to Trichinella spiralis in mice: capacity of cells from slow responder mice to transfer immunity in syngeneic and F1 hybrid recipients

Mice of the C57BL/10 (B10) strain are slow responders to infection with T. spiralis in terms of ability to expel worms from the intestine. Compared with rapid-responder NIH mice, infection stimulates a slower and reduced blast cell response in the draining mesenteric lymph node (MLN). Transfer of immune cells from the MLN (MLNC) does not accelerate worm expulsion from naive B10 recipient mice, even though MLNC from this strain effectively transfer immunity to (B10 X NIH) F1 recipients. In common with other B10 background mice C57BL/10 show an infection-dose related suppression of immunity to T. spiralis. Such suppression does not appear to determine the response to MLNC, as adoptive transfer into B10 recipients was not enhanced by reducing the level of challenge infection given, and transfer into F1 recipients was unaffected by simultaneous transfer of lymphocyte populations from donors infected at a level which would induce suppression. A hypothesis is proposed which relates slow response status to (i) the inherent capacity of the intestinal inflammatory component of worm expulsion, and (ii) the outcome of infection-dose related stimulatory and suppressive influences acting on the two interacting lymphocyte components of expulsion. The relevance of H-2-linked and non-H-2 genes to the control of the response is discussed.