The in vitro inhibition of growth of intracellular Listeria monocytogenes by lymphocyte products

The listeria-inhibiting activity of culture supernatants from listeria-immune and nonimmune lymphocytes was assessed on listeria-infected macrophage cultures. It was found that supernatant from listeria-immune lymphocyte cultures stimulated in vitro with antigen was markedly inhibitory to the multiplication of intracellular listeria. Some inhibitory activity was also evident in supernatant from antigen-stimulated non-immune lymphocyte cultures. Supernatant from listeria-immune lymphocytes stimulated in vivo with antigen was capable of inhibiting listeria. Some inhibitory activity was still evident upon dilution of active supernatant at 1:100.     

Induction of protective immunity to Listeria monocytogenes in neonates

Neonates suffer unduly from infections and also respond suboptimally to most commonly used vaccines. However, a CD8 T cell response can be elicited in neonates if the Ag is introduced into the cytoplasm of APCs. Listeria monocytogenes (Lm) targets the cytoplasm of APC and is a strong CD8 and CD4 Th1-promoting vaccine vehicle in adult mice. We hypothesized that an attenuated strain of Lm would be safe and induce long-lasting protective immunity, even in neonates. We found that neonatal mice immunized only once with the attenuated strain DeltaactA-Lm developed robust primary and secondary CD8 and CD4 Th1 responses and were fully protected from lethal challenge with virulent wild-type Lm without the need for a booster immunization. Furthermore, DeltaactA-Lm expressing a heterologous recombinant Ag induced a strong CD8 and Th1 memory response to that Ag. Based on these data, we propose that DeltaactA-Lm or derivatives thereof might serve as a vaccine vehicle for neonatal immunization.     

Adoptive transfer of immunity against Nippostrongylus brasiliensis in mice. In vitro restimulation of immune cells before their transfer

When mesenteric lymph node cells from infected mice were stimulated during an in vitro culture with exoantigens or with a purified protective antigen of Nippostrongylus brasiliensis, a drop was noted in the number of cells required to transfer protection to new mice. A maximal effect was already obtained after 4 hrs. of culture, but irradiated cells or cells from another mouse strain were unable to mediate this transfer. T cells were more effective than B cells in transferring the protection.     

Impairment of T cell-mediated immunity to Listeria monocytogenes in pregnant mice

In order to study pregnancy-induced changes in cell-mediated immunity to Listeria monocytogenes, acquired resistance and T cell functions in pregnant mice were compared with those in nonpregnant mice after immunization with viable listerial cells. Impaired generation of acquired resistance was evident in pregnant mice from the impaired elimination of bacteria and poor survival after secondary challenge. Delayed footpad reactivity to listerial antigen was also lower in the pregnant mice. When immune spleen cells were examined for their ability to produce macrophage activating factor in vitro, culture supernatants from pregnant-mouse spleen cells with listerial antigen showed far less ability to render macrophages cytostatic for P815 mastocytoma cells. To elucidate further the impairment of listeria-immune T cell generation in pregnant mice, a local transfer experiment was carried out. When a given number of immune spleen cells was transferred locally into the footpads of naive mice, both delayed footpad reaction and local protection were much lower in the pregnant mice. This local transferability of the reactions was abrogated after treatment of cells with anti-Thy 1 antibody plus complement. These findings indicate that pregnancy impairs the generation of specific T cells capable of contributing to acquired resistance to L. monocytogenes. Possible mechanisms for this impairment and the relationship to macrophage functions are discussed.     

Metabolic requirements for macrophage presentation of Listeria monocytogenes to immune CD8 cells.

Though ingested Ag are readily degraded into peptides within endocytic vesicles, APC usually cannot present these fragments to CD8 cells. Despite this generalization, some exceptions have been noted. For example, murine macrophage targets readily process heat-killed Listeria monocytogenes (HKLM) into a form recognizable by immune CD8 CTL. Using an assay of Listeria-specific, CD8-mediated cytotoxicity to quantitate Ag presentation by C57Bl/6 macrophage targets, we have examined some of the cellular requirements for this form of Ag processing. To assess whether the physical form of the Ag is an important determinant of processing, we compared the ability of macrophages to present intact HKLM, fractionated L. monocytogenes (LM) membranes, and octyl-beta-d-thioglucopyranoside-solubilized extracts of LM membranes. Macrophages presented each Ag form in a similar manner indicating that processing is not critically dependent on the presence of intact bacteria or even on the introduction of Ag in a particulate form. To gain insight into the metabolic requirements for Ag processing, we examined the effects of several inhibitors. As might be expected, listerial Ag presentation was blocked by brefeldin, a known inhibitor of the endogenous pathway of Ag processing. LM Ag presentation, however, was also blocked by inhibitors of endosomal acidification (chloroquine, ammonium chloride, and monensin) and by the acid protease inhibitor pepstatin A, suggesting that endocytic processing may play an essential role in CD8 recognition of this Ag. To formally establish that this pattern of exogenous Ag processing requires the presence of a class I MHC product, we demonstrated that beta-2 microglobulin-deficient macrophages, which lack class I MHC product expression, cannot present HKLM to CD8 cells. However, we could not block Ag presentation by incubating macrophages with monoclonal anti-H-2K or H-2D antibodies, suggesting that LM Ag presentation may be mediated by some other class I MHC product. Additional characterization of this pathway of Ag presentation is warranted in view of its possible role in initiating CD8-mediated immunity against microbial Ag.     

Anti-bacterial immunity to Listeria monocytogenes in allogeneic bone marrow chimera in mice

Protection and delayed-type hypersensitivity (DTH) to the facultative intracellular bacterium Listeria monocytogenes (L.m.) were studied in allogeneic and syngeneic bone marrow chimeras. Lethally irradiated AKR (H-2k) mice were successfully reconstituted with marrow cells from C57BL/10 (B10) (H-2b), B10 H-2-recombinant strains or syngeneic mice. Irradiated AKR mice reconstituted with marrow cells from H-2-compatible B10.BR mice, [BR----AKR], as well as syngeneic marrow cells, [AKR----AKR], showed a normal level of responsiveness to the challenge stimulation with the listeria antigens when DTH was evaluated by footpad reactions. These mice also showed vigorous activities in acquired resistance to the L.m. By contrast, chimeric mice that had total or partial histoincompatibility at the H-2 determinants between donor and recipient, [B10----AKR], [B10.AQR----AKR], [B10.A(4R)----AKR], or [B10.A(5R)----AKR], were almost completely unresponsive in DTH and antibacterial immunity. However, when [B10----AKR] H-2-incompatible chimeras had been immunized with killed L.m. before challenge with live L.m., these mice manifested considerable DTH and resistance to L.m. These observations suggest that compatibility at the entire MHC between donor and recipient is required for bone marrow chimeras to be able to manifest DTH and protection against L.m. after a short-term immunization schedule. However, this requirement is overcome by a preceding or more prolonged period of immunization with L.m. antigens. These antigens, together with marrow-derived antigen-presenting cells, can then stimulate and expand cell populations that are restricted to the MHC (H-2) products of the donor type.     

The host resistance locus sst1 controls innate immunity to Listeria monocytogenes infection in immunodeficient mice

Epidemiological, clinical, and experimental approaches have convincingly demonstrated that host resistance to infection with intracellular pathogens is significantly influenced by genetic polymorphisms. Using a mouse model of infection with virulent Mycobacterium tuberculosis (MTB), we have previously identified the sst1 locus as a genetic determinant of host resistance to tuberculosis. In this study we demonstrate that susceptibility to another intracellular pathogen, Listeria monocytogenes, is also influenced by the sst1 locus. The contribution of sst1 to anti-listerial immunity is much greater in immunodeficient scid mice, indicating that this locus controls innate immunity and becomes particularly important when adaptive immunity is significantly depressed. Similar to our previous observations using infection with MTB, the resistant allele of sst1 prevents formation of necrotic infectious lesions in vivo. We have shown that macrophages obtained from sst1-resistant congenic mice possess superior ability to kill L. monocytogenes in vitro. The bactericidal effect of sst1 is dependent on IFN-gamma activation and reactive oxygen radical production by activated macrophages after infection, but is independent of NO production. It is possible that there is a single gene that controls common IFN-dependent macrophage function, which is important in the pathogenesis of infections caused by both MTB and L. monocytogenes. However, host resistance to the two pathogens may be controlled by two different polymorphic genes encoded within the sst1 locus. The polymorphic gene(s) encoded within the sst1 locus that controls macrophage interactions with the two intracellular pathogens remains to be elucidated.     

Adoptive transfer of protective immunity in experimental schistosomiasis in the mouse

Passive transfer of immune serum alone did not confer protection to recipient mice irrespective of the routes of serum transfer or cercarial challenge of Schistosoma mansoni. Mice that received both sensitized cells and immune serum were protected against challenge by subcutaneous injection of cercariae but not by percutaneous exposure. The immune serum could be transferred as late as 8 days after subcutaneous challenge, suggesting that the protection was afforded in part by a late parasite killing mechanism which functions after the schistosomula have migrated through the lungs.     

Restriction in adoptive transfer of resistance to Listeria monocytogenes. I. Influence of non-H-2 loci

In vivo adoptive transfer of T-cell-mediated immunity to the facultative intracellular bacterium Listeria monocytogenes is restricted, not only by the H-2 haplotype of the mice, but also by incompatibilities at non-H-2 loci. Thus, transfer between H-2 identical strains of mice with different background genes was reproducibly and significantly less efficient than transfer between completely syngeneic mice, although the restriction was less marked than that across the H-2 barrier. Restriction also occurred when parental cells were injected into semisyngeneic F1 hybrids and when cells from F1 hybrids were injected into parental strains. Using congenic strains of mice differing only at defined minor histocompatibility antigens, it was found that, of those loci available for study, antigens arising from the H-4 and H-8 loci strongly restricted transfer, whereas those specified by H-1, H-3, and H-7 did not.     

Gender effect on in vitro lymphocyte subset levels of healthy individuals

Differences in gender immune response have resulted in differences in immune protection and susceptibility to inflammatory diseases. Cultured peripheral blood mononuclear cells (PBMC) are widely used in immunomodulation studies, yet the influence of gender is usually not considered. We examined the effect of in vitro culture and phytohaemagglutinin (PHA) stimulation on PBMC lymphocyte subsets using flowcytometry. Full blood counts of whole blood showed higher levels of lymphocyte in male subjects. Lymphocyte subsets enumeration revealed higher NK cell counts in males and higher B cells in females. Cultured PBMC resulted in significant increases in B and total T cell percentages among females and NK cells among males. PHA stimulated significantly increased percentages of NK and total T cells in males and total activated T cells (CD69+) in females. Our results showed significant gender differences in lymphocyte subsets in cultured conditions. This may affect experimental outcome.     

Structural requirements of phosphatidyl choline in arresting lymphocyte stimulation

We reported previously that lymphocyte stimulation mediated by mitogenic lectin may be arrested by the presence of egg lecithin. The inhibitory effect was further investigated using other natural phospholipids including phosphatidyl ethanolamine, phosphatidyl serine, sphingomyelin of bovine brain and phosphatidyl cholines extracted from egg, brain, liver and soybeans. We also tested the effects of a variety of synthetic phosphatidyl cholines having different acyl side chains. We found that all the natural phospholipids having a phosphoglycerol head group effectively inhibit lymphocyte stimulation while sphingomyelin was not inhibitory. The synthetic phosphatidyl cholines were not inhibitory unless when they were added to the lymphocyte cultures as mixtures. The results indicated that (1) a phosphoglycerol head group appears essential to arrest lymphocyte stimulation; and (2) inhibition requires a mixture of phosphotidyl choline having different acyl side chains.     

Adoptive cell transfer studies to examine the role of T lymphocytes in immunity to Trypanosoma musculi

Previous studies in this laboratory utilizing monoclonal antibody-induced immunosuppression have demonstrated that the T-helper lymphocyte is primarily responsible for the T lymphocyte dependency of Trypanosoma musculi elimination from the bloodstream of mice, and that T-cytotoxic lymphocytes play a minimal role in this response. In the current study, these findings were extended by examining the effects of adoptive cell transfers on the course of infection with T. musculi using immune splenocytes enriched for T lymphocyte subpopulations. These studies demonstrated that adoptive transfer of immune splenic T lymphocytes resulted in a specific, dose-related enhancement of kinetics of trypanosome elimination. This effect was found to be due to the presence of L3T4+ T-helper cells in the immune splenocyte population. Adoptive transfer of Lyt-2+ T-cytotoxic cells or lymphokine-activated killer (LAK) cells was ineffective in altering the course of infection. In addition, it was found that immune B lymphocytes were equally capable of adoptively transferring immunity to T. musculi, suggesting that the primary role of the T-helper lymphocyte is to provide help in the induction of parasite-specific antibodies.