Phenotype and distribution of T lymphocytes in Peyer's patches of athymic mice

The distribution and phenotype of T (Thy-1.2+) cells was examined in Peyer's patches of 8 and 16 week old athymic mice by peroxidase and two-color-fluorescence immunohistochemistry. Despite the generally recognized T cell deficiency of nude mice, some T cells consistently occurred in Peyer's patch domes in all mice. However, many Thy-1.2+ lymphocytes lacked cell surface markers for either helper T cells (L3T4) or cytotoxic/suppressor T cells (Lyt-2), indicating that these cells may be an immature subset of T cells. These cells may represent a population of resident T cell precursors delayed in maturation or T cells newly immigrated to Peyer's patches.     

Phenotype and distribution of T lymphocytes in Peyer's patches of athymic mice

Summary The distribution and phenotype of T (Thy-1.2^–) cells was examined in Peyer's patches of 8 and 16 week old athymic mice by peroxidase and two-color-fluorescence immunohistochemistry. Despite the generally recognized T cell deficiency of nude mice, some T cells consistently occurred in Peyer's patch domes in all mice. However, many Thy-1.2⁺ lymphocytes lacked cell surface markers for either helper T cells (L3T4) or cytotoxic/suppressor T cells (Lyt-2), indicating that these cells may be an immature subset of T cells. These cells may represent a population of resident T cell precursors delayed in maturation or T cells newly immigrated to Peyer's patches.     

T lymphocytes that express CD4 and the alpha beta-T cell receptor but lack Thy-1. Preferential localization in Peyer's patches

Thy-1- T cells expressing CD4 and the alpha beta-TCR have been identified in murine lymphoid tissues. These cells are particularly prevalent in Peyer's patches (PP), representing 17 +/- 3% of PP CD4 T cells, whereas they are much less prevalent in spleen, lymph nodes, lamina propria, or peritoneum. Phenotypic studies of fresh-isolated PP T cells demonstrate that all PP CD4 T cells (both Thy-1- and Thy-1+) express CD3, alpha beta-TCR, and CD5 (Lyt-1), whereas none coexpress CD8 (Lyt-2). Thy-1- and Thy-1+ CD4 T cell lines generated from PP also coexpress CD3 and alpha beta-TCR, but are heterogeneous in expression of CD5 and again do not coexpress CD8. Further studies revealed that Thy-1- CD4+ T cells were not present in nude mice. Short term stimulation of Thy-1+ CD4+ PP T cells with anti-CD3 resulted in loss of Thy-1 in a substantial fraction of these cells. Functional studies of Thy-1- and Thy-1+ CD4+ PP T cells indicate that fresh-isolated Thy-1- CD4+ cells do not proliferate in response to insoluble anti-CD3 but do proliferate when stimulated with soluble anti-CD3 in the presence of feeder cells. In contrast, Thy-1+ CD4+ cells proliferate well to both stimuli. However, Thy-1- CD4+ PP T cells adapted to in vitro culture exhibit vigorous proliferative responses when stimulated with either form of anti-CD3. Evaluation of lymphokine secretion by fresh-isolated Thy-1- and Thy-1+ CD4+ PP T cells revealed that both make substantial amounts of IL-2; however, Thy-1- T cells made less IL-4 than their Thy-1+ counterparts. Neither population made IL-5 or IFN-gamma. Similarly, Thy-1- and Thy-1+ CD4 T cell lines made similar amounts of IL-2; again Thy-1- T cells made less IL-4; and in this case Thy-1- T cells made IL-5 albeit significantly less than the Thy-1+ cells. Finally, immunohistochemical studies suggested that many of the CD4+ T cells in PP germinal centers were Thy-1-, indicating that Thy-1- and Thy-1+ CD4 T cells differ in their distribution within the PP. These studies thus define a phenotypically and functionally distinct T cell population which is most prevalent in murine Peyer's patches.     

Evidence of extensive lymphocyte death in sheep Peyer's patches. II. The number and fate of newly-formed lymphocytes that emigrate from Peyer's patches

The emigration of newly produced lymphocytes from Peyer's patches (PP) of lambs was studied. Mesenteric lymph nodes (MLN) were excised from most animals a few weeks after birth, and then at 8 to 10 wk of age, the dividing cells in 3 to 4 m of the small intestine were labeled in situ with [3H]thymidine. An extracorporeal perfusion system was used to restrict the 15-min period of labeling to the perfused lengths of intestine, which included either the large continuous ileal PP or a number of smaller jejunal PP. One or 3 days later, the number of labeled cells in the perfused tissue and in other lymphoid organs was studied by autoradiography. In the perfused tissues, labeled lymphocytes accounted for 63.7% of ileal PP cells by 1 day and for 86.7% by 3 days compared with only 9.6% of lymphocytes in the perfused MLN. Labeled lymphoid cells in the perfused PP were nearly all in the follicles. Labeled lymphocytes that must have been produced in the segments of ileum or jejunum at the time of the perfusion, subsequently emigrated via the lymphatics, and were identified in the spleen, MLN, other lymph nodes, blood, jejunal PP, and at a lower frequency in the thymus, nonperfused ileal PP, and bone marrow. In lymph nodes, spleen, and nonperfused PP, more than 80% of the immigrant newly formed PP-derived cells were small- and medium-sized lymphocytes, and about 15% were large lymphocytes. The nature of the labeled cells in the lamina propria of the nonperfused small intestine was quite different in that approximately 50% were plasma cells as early as 24 hr after the cells were born in the perfused gut. It is proposed that terminal B cell differentiation was most likely initiated within the PP in response to the entry of antigen. It was estimated that at both 1 and 3 days after perfusion there were about 100 times more labeled cells in the perfused ileal PP than could be accounted for by emigration to other organs. It was concluded that these results provide additional support for the view that PP in lambs produce a tremendous number of lymphocytes, but relatively few leave their site of production; most apparently die in situ.     

Heat shock enhances the expression of cytotoxic granule proteins and augments the activities of tumor-associated antigen-specific cytotoxic T lymphocytes

Focal inflammation causes systemic fever. Cancer hyperthermia therapy results in shrinkage of tumors by various mechanisms, including induction of adaptive immune response. However, the physiological meaning of systemic fever and mechanisms of tumor shrinkage by hyperthermia have not been completely understood. In this study, we investigated how heat shock influences the adaptive immune system. We established a cytotoxic T lymphocyte (CTL) clone (#IM29) specific for survivin, one of the tumor-associated antigens (TAAs), from survivin peptide-immunized cancer patients’ peripheral blood, and the CTL activities were investigated in several temperature conditions (37–41 °C). Cytotoxicity and IFN-γ secretion of CTL were greatest under 39 °C condition, whereas they were minimum under 41 °C. To address the molecular mechanisms of this phenomenon, we investigated the apoptosis status of CTLs, expression of CD3, CD8, and TCRαβ by flow cytometry, and expression of perforin, granzyme B, and Fas ligand by western blot analysis. The expression of perforin and granzyme B were upregulated under temperature conditions of 39 and 41 °C. On the other hand, CTL cell death was induced under 41 °C condition with highest Caspase-3 activity. Therefore, the greatest cytotoxicity activity at 39 °C might depend on upregulation of cytotoxic granule proteins including perforin and granzyme B. These results suggest that heat shock enhances effector phase of the adaptive immune system and promotes eradication of microbe and tumor cells.

Electronic supplementary material

The online version of this article (doi:10.1007/s12192-012-0348-0) contains supplementary material, which is available to authorized users.     

Regulation of the activation of cytotoxic T lymphocytes by prostaglandins and antigens

The present study demonstrated the presence of two suppressor circuits in the regulation of the in vitro activation and differentiation of cytotoxic T lymphocytes (CTL); these suppressor circuits were mediated by prostaglandins (PG) and antigens, respectively. In intrinsic suppression, the activation of cytotoxic precursor cells was regulated by the host endogenous production of PG. When the regulation by PG was removed (e.g., using indomethacin), lymphokine-induced cytotoxic cells (LICC) were generated. This activation process can be induced in the absence of antigen or mitogen stimulation. In extrinsic suppression, the presence of antigen induced the generation of antigen-nonspecific suppressor T cells to restrict the expansion of antigen-unrelated cytotoxic lymphocyte clones, whereas the antigen-specific CTL clones were spared. The generation of antigen-specific helper cells further augmented the antigen-specific CTL response. These findings indicate that both antigen specific suppressor T cells and antigen nonspecific suppressor T cells are involved in the regulation of CTL responses. These suppressor circuits not only play an active role in monitoring the activation of CTL clones, they also help to determine the specificity and magnitude of the CTL response.     

The role of T cells in anti-herpes simplex virus immunity. I. Induction of antigen-specific cytotoxic T lymphocytes.

Mice infected with herpes simplex virus develop little or no cytotoxic T lymphocyte (CTL) response. However, in lymph nodes (LN's) draining a local site infected with HSV, antigen-specific CTL precursors are sensitized, which upon transfer to in vitro culture conditions develop within 72 hr into effective CTL. The in vivo blockade of CTL differentiation can be overcome by cyclophosphamide, suggesting that a cyclophosphamide-sensitive mechanism blocks the in vivo generation of HSV-immune CTL. The cytolytic activity of HSV-immune CTL is H-2 restricted and antigen specific. Thus CTL sensitized toward HSV type 1 discriminate between syngeneic targets infected with either the immunologic HSV variant type 1 or type 2 (and vice versa). H-2-matched target cells exposed for 30 min to infectious HSV are lysed within 60 min of contact with CTL. Since HSV replication is believed to require more than 4 to 5 hr, the data suggest that either the expression of HSV-dependent "early proteins" takes place within 30 to 90 min or cell membrane-integrated HSV virion represents the target antigen of CTL.     

Expression and function of asialo GM1 in alloreactive cytotoxic T lymphocytes

In the present study we examined asialo GM1 (AsGM1) expression and its function in alloreactive cytotoxic T lymphocytes (CTL). We consistently found that the cytotoxic activity of bulk culture-derived allo-CTL was susceptible to the treatment of anti-AsGM1 (alpha AsGM1) plus complement. To further determine whether the expression of AsGM1 was maintained in CTL, we examined cloned T cells. The expression of AsGM1 in the T cell clones was assessed by their susceptibility to lysis by alpha AsGM1 plus complement and the reduction or abrogation of their cytotoxic activity by this treatment. It was found that, with one exception, all Lyt-2+, Thy-1+ CTL clones were AsGM1+ (seven out of eight), independent of their class specificity (class I or class II). In contrast, all Thy-1+, L3T4+ CTL (2) or helper T cell (4) clones AsGM1-. These findings suggested that there was a close association between the expression of AsGM1 and the expression of Lyt-2. The cytotoxic reaction of the anti-class I MHC CTL clones that expressed AsGM1 was blocked by alpha AsGM1 or alpha Lyt-2 antibody. The Lyt-2+, AsGM1+ anti-class II MHC CTL clone-mediated lysis was inhibited by alpha AsGM1. Addition of AsGM1 in micelle form (AsGM1-M) alone also blocked the cytotoxic reactions. Addition of other structurally similar but antigenically different glycolipids or other non-AsGM1-containing liposome preparations did not affect CTL-mediated cytotoxicity. Furthermore, adding both alpha AsGM1 and AsGM1-M together at proper doses inhibited the blocking effect (deblocking) of either alone, and other structurally similar glycolipids did not inhibit the blocking. The deblocking was specific, since AsGM1-M did not affect the blocking by alpha Lyt-2. These findings indicate that not only is AsGM1 expressed in a majority of Lyt-2+ CTL clones, but it may also be involved in the CTL- target interaction to mediate lytic reaction.     

Cellular localization of perforin 1 in murine cloned cytotoxic T lymphocytes

The localization of perforin 1 (P1) in cytotoxic cells was studied by immuno-electron microscopy by using a monospecific rabbit antiserum against highly purified mouse P1 and protein A gold as a second ligand. P1 was found in specific granules of cloned cytotoxic T lymphocytes (CTL). Within the granules, P1 antigen was localized in the fine granular matrix, whereas the vesicular compartment remained free of gold particles. The amount of P1 antigen detectable by immuno-electron microscopy varied between different CTL clones. CTL with NK-like activity had the highest level of P1 antigen. A cytotoxicity loss CTL mutant had no detectable P1 antigen, suggesting an important role of P1 during cell-mediated cytolysis. P1 antigen was undetectable also in bone marrow macrophages, indicating a different cytolytic mechanism of these cells.     

Molecular mechanisms involved in T cell activation. I. Evidence for independent signal-transducing pathways in lymphokine production vs proliferation in cloned cytotoxic T lymphocytes

It is well-established that activated T cells proliferate in response to interleukin 2 (IL 2) and produce various soluble lymphokines such as macrophage-activating factor (MAF) in response to antigen. Prior to investigating the molecular events involved in signaling the initiation of these responses in cloned murine cytotoxic T lymphocytes (CTL), we determined whether these responses could occur independently, and we established for each response the time during which signal transducing mechanisms may function. It was found that this cloned CTL population was in a resting state (G1 phase of cell cycle) 7 days after stimulation with antigen plus IL 2. At this time, the incubation of these resting CTL with IL 2 for 4 to 6 hr resulted in a maximal proliferative response that was not accompanied by the production of MAF. Conversely, the incubation of resting CTL with antigen or lectin (in the absence of IL 2) for at least 8 hr resulted in the maximal production of MAF at 24 hr without inducing a proliferative response. In addition, antigen or lectin, but not IL 2, triggered an immediate (less than 1 min) and sustained (at least 8 hr) mobilization of intracellular calcium. The kinetics of this calcium response paralleled the minimum time (8 hr) that was required for resting CTL to interact with either antigen or lectin in order to produce maximal titers of MAF. These results indicate that proliferation and lymphokine (MAF) production in cloned murine CTL are independent events. In these resting CTL, the signal mechanisms that mediate the production of lymphokines are most likely restricted to the initial 8 hr of stimulation by antigen or lectin and involve the rapid and prolonged mobilization of cytoplasmic calcium. Proliferative signals, however, are probably complete within 4 to 6 hr after stimulation by IL 2 and do not involve readily demonstrable fluxes of cytoplasmic calcium, as determined by the fluorescent calcium probe Quin 2.     

Natural cytotoxic T cells (NCTC) that differ from natural killer (NK) and natural cytotoxic (NC) cells are present in Peyer's patches of mice

We have examined noninduced cytotoxicity of mouse gut associated and peripheral lymphoid tissues for a wide variety of syngeneic as well as allogeneic cell lines and lymphoblasts. Lymphoid cells from Peyer's patches were found to lyse these targets in a 3-hr chromium release assay whereas lymphoid cells from intestinal mucosa, mesenteric or peripheral lymph nodes, spleen, and thymus did not. The variety of targets toward which Peyer's patch cells were cytotoxic established the latter as nonspecific and H-2 unrestricted. The cell responsible for the lytic event was identified as possessing Thy 1.2 and Ia surface antigens. This naturally cytotoxic T cell (NCTC) was found to be adherent to nylon-wool but not to plastic plates. Although both natural killer cell (NK) and non-NK targets served as targets for the NCTC, the latter were further differentiable from NK cells by lack of asialo GM1 surface marker, which is present on NK cells. In addition, NCTC remained fully functional in mice given either of the drugs cyclophosphamide or cortisone. Each of these drugs, in the doses used, markedly reduced poly(I:C)-induced NK activity. Thus, NCTC differs from NK on the basis of the spectrum of targets against which it is functional, phenotypic surface markers, insusceptibility to stimulation with poly(I:C), and insensitivity to diminution by the immunosuppressive drugs cyclophosphamide and hydrocortisone. Since NCTC is a Thy 1.2 antigen-bearing cell and is detectable in a 3-hr cytotoxic assay, it also differs from the natural cytotoxic (NC) cell. NC lacks the Thy 1.2 marker and becomes detectable only in an 18-hr cytotoxic assay. Thus, NCTC is neither an NK nor an NC cell. We have discussed the possibility that the three naturally occurring cells may be related by being dedifferentiated descendants of an antigen-specific cytotoxic T lymphocyte (CTL). Alternatively, since NCTC is confined to an anatomical site prone to ample antigenic exposure and is still identifiable as a T cell, it may be in linear transition from the CTL to the NK or NC stages.     

Multipotential acceptance of Peyer's patches in the intestine for both thymus-derived T cells and extrathymic T cells in mice

Peyer's patches (PP) are important inductive sites for the mucosal immune response. It is well known that lymphocytes that migrate into PP are mainly of T-cell lineage from thymus-derived cells (i.e. alphabetaTCR(high) cells). In this study, we further characterized the properties of PP lymphocytes in mice using a mouse model of colitis induced by dextran sulphate sodium (DSS). Although the major site of the inflammation induced by DSS is known to be the large intestine, the small intestine was also damaged. When mice developed DSS-induced colitis, CD3+CD8+B220+ gammadelta T cells increased in PP in the small intestine. These gammadelta T cells, which are not seen in the PP of normal mice, resembled intraepithelial lymphocytes (IEL) in the small intestine in terms of their expression of CD5, CD103 and Thy1.2. In addition, the Vgamma/delta repertoire of these gammadelta T cells was similar to that of gammadelta IEL. When DSS-treated mice were injected with IEL isolated from normal mice, IEL including gammadelta T cells preferentially migrated to PP, raising the possibility that B220+ T cells seen in PP of diseased mice may derive from IEL in the small intestine. Our present study suggests that PP might be able to accept T-cell lineages from intestinal IEL as well as from thymus-derived T cells.     

Extracts of Larix Leptolepis effectively augments the generation of tumor antigen-specific cytotoxic T lymphocytes via activation of dendritic cells in TLR-2 and TLR-4-dependent manner

Type-1 immunity plays a crucial role in host defense against various tumors and infectious diseases. Here, we first demonstrated that extract of Larix Leptolepis (ELL), one of the most popular timbers at Hokkaido area in Japan, strongly activated Type-1 immunity. ELL induced production of Type-1 cytokines such as IL-12 and TNF-α from bone marrow-derived dendritic cells (BMDCs) in TLR2- and TLR4-dependent manner and remarkably up-regulated the expression of MHC and co-stimulatory molecules. In addition, antigen-specific CTLs were significantly augmented by the combined administration of ELL, antigen and BMDCs. Finally, we revealed that combination therapy using ELL, antigen and BMDCs significantly inhibited the growth of established tumor in mouse model. Thus, these findings suggested that ELL would be a novel adjuvant for inducing an activation of Type-1-dependent immunity including activation of BMDCs and induction of tumor-specific CTLs, which is applicable to the therapy of cancer and infectious diseases.     

Cloned protein antigen-specific, Ia-restricted T cells with both helper and cytolytic activities: mechanisms of activation and killing

Myoglobin-specific, Iad-restricted cloned helper T cells and T hybridomas were found to directly kill Iad-bearing, myoglobin-pulsed B lymphoma targets and could also kill bystander targets, but only in the presence of antigen-pulsed antigen presenting cells (APC). The induction of the killing requires recognition of processed antigen in the context of class II major histocompatibility complex (MHC) molecules. Despite the specificity of induction, the bystander killing suggests a nonspecific lytic mechanism. The direct killing can be inhibited only by cold specific targets, whereas the bystander killing can be blocked by both specific and nonspecific targets. The cold target inhibition seems to be due to interference with effector-to-target contact or proximity rather than due to high-dose suppression of T-cell activation. Experiments using T-cell supernatants or cyclosporin A suggested that the helper T cells kill targets by synthesizing short-range soluble factor(s) with nonspecific killing activity de novo during the effector phase, but only while antigen-specific signal transduction is occurring. The mechanism of cold target inhibition appears to be absorption or consumption of a short-acting cytotoxic lymphokine by cells which must be able to interact closely with the effector cell. Normal spleen B cells, despite their capability for activating the helper T cells, cannot inhibit specific killing or be killed by helper T cells, even after lipopolysaccharide stimulation. Thus, although killing by helper T cells may play a negative feedback role in the normal immune response, our data raise the possibility that the helper T-cell-mediated killing may contribute to the immune surveillance against malignancy by virtue of the preferential killing of tumor cells either directly or indirectly.     

The role of Ca2+ in activation of mature cytotoxic T lymphocytes for lysis

We carried out a detailed analysis of the requirement for Ca2+ in the lysis of target cells by cloned cytotoxic T lymphocytes (CTL). In direct, antigen-specific lysis we always observed an influx of Ca2+ into the CTL concomitant with target cell binding. However, we never observed an increase in CTL Ca2+ content during lectin-mediated lysis, or nonspecific lysis by phorbol myristate acetate-induced CTL. We found that in all three types of lysis (direct, lectin-mediated lysis, C or phorbol myristate acetate-induced) the requirement for Ca2+ in lysis was dictated by the target cell used; the same CTL can kill one target cell in the absence of detectable Ca2+, and absolutely require Ca2+ for the lysis of another target cell. Target cell killing, when it occurred in the absence of Ca2+, was accompanied by microtubule organizing center reorientation in the CTL, showing that this function is not uniformly Ca2+ dependent. These results provide further evidence that Ca2+ is not always required for activation of the lytic pathway in CTL, although Ca2+ may be absolutely required for other CTL functions such as interleukin production or expression of the interleukin 2 receptor.