In vitro induction of immunological tolerance

IL-2 was previously shown to induce cytotoxic effectors with a broad spectrum of target specificities in thymus and spleen cell cultures. This study was designed to show whether T cells activated by H-2 allogeneic cells in MLC or by syngeneic tumor cells in MLTC are also potential targets for these cytotoxic effectors. We found that thymocytes activated in vitro for 5 days by rIL-2 were capable of killing tumor cells as well as activated T cells. Thymocytes activated by IL-2 were accordingly utilized as a means of effecting clonal deletion of T cells activated by H-2 allogeneic target cells in MLC. To establish whether the unresponsiveness is specific. IL-2-activated thymocytes were added as third party cells to MLC and MLTC. The results showed that both T cells, proliferating in response to H-2 allogeneic cells, and CTL, reactive against syngeneic tumors or H-2 allogeneic cells, are eliminated from the T cell pool. Only alloreactive T cells are specifically eliminated in MLC by IL-2-activated thymocytes, as the remaining T cells are capable of proliferating and generating CTL in response to antigenically unrelated third party allogeneic cells. The possibility that unresponsiveness might be due to soluble factors was ruled out by studies performed with a diffusable "chamber insert" culture system. The results provide evidence that IL-2-activated thymocytes induce in vitro T cell tolerance.     

T cell antigen receptor expression by subsets of Ly-2-L3T4- (CD8-CD4-) thymocytes

The V beta 8-specific mAb F23.1 and KJ16 were used as fluorescent stains to test for TCR expression on the surface of subpopulations of early, CD4-CD8- (L3T4-Ly-2-) thymocytes from adult CBA mice. A surprisingly high proportion (27%) of Ly-2-L3T4- thymocytes were strongly F23.1 and KJ16 positive. No positive cells were detected among Ly-2-L3T4- thymocytes from V beta 8-negative SJL mice. In contrast to the adult thymus, Ly-2-L3T4- cells from embryonic CBA thymus lacked F23.1-positive cells. Subsets of adult CBA Ly-2-L3T4- thymocytes were separated to determine which expressed V beta 8. The major subset, Ly-1 low B2A2-M1/69+Thy-1+Pgp-1-, representing a phenotype similar to embryonic Ly-2-L3T4- thymocytes and the phenotype commonly isolated from adult thymocytes as Ly-1 "dull," lacked cells strongly positive for F23.1. In contrast, a series of subsets of adult CBA Ly-2-L3T4- thymocytes which were B2A2-M1/69- and Pgp-1+ all included strongly F23.1-positive cells. A minor subset, negative for most markers except Pgp-1 and presumed on the basis of this phenotype and some reconstitution studies to include the earliest intrathymic precursors, contained 28% F23.1-positive cells. However, no F.23.1-positive cells were detected in equivalent "prethymic" populations from bone marrow or from athymic mouse spleen. The subsets of Ly-2-L3T4- thymocytes which were Ly-1 high, B2A2-M1/69-, and Pgp-1+ all contained about 70% F23.1-positive cells, indicating a V beta 8 usage much higher than the mature T cell average. These results indicate that a series of distinct developmental events have occurred within these CD4-CD8- thymocytes previously considered as a single group of early precursor cells, and that some aspects of repertoire selection may be occurring amongst thymocytes which lack CD4 or CD8.     

Two roles for CD4 cells in the control of the generation of cytotoxic T lymphocytes.

The generation of CTL against Qa-1 Ag in C57BL/6 (B6) (Qa-1b) and B6.Tlaa (Qa-1a) congenic strains requires in vivo priming with the Qa-1 alloantigen together with a helper Ag, such as H-Y. The primed precursors obtained from these female mice generate Qa-1-specific CTL activity upon culture in vitro. Although the presence of the H-Y helper Ag is not required for the in vitro sensitization, no response occurs in the absence of CD4 cells. Addition of unprimed B6.Tlaa CD4 cells from Qa-1 incompatible radiation bone marrow chimeras (B6.Tlaa----B6), that are presumably tolerant to Qa-1b, provide helper activity for Qa-1b-specific CTL. This indicates that although CD4 cells are obligatory for the Qa-1 response, they need not be specific for alloantigens on the APC to generate helper activity in in vitro cultures. Addition of unirradiated B6 CD8-depleted spleen cells to CD4-depleted B6.Tlaa anti-B6 cultures in the presence of either B6.Tlaa CD4 cells or rIL-2 prevents the generation of Qa-1 specific CTL. This inhibition is not due to an anti-idiotypic Ts cell since B6.Tlaa----B6 chimeric cells do not suppress an anti-Qa-1b response. Rather, this finding is consistent with that of a veto cell mechanism. To determine whether CD4 cells themselves exhibit veto activity, highly purified CD4 populations were tested for their ability to inhibit the generation of Qa-1-specific CTL. CD4 cells precultured for 2 to 3 days with Con A and rIL-2 specifically inhibit CTL activity whereas resting cells do not, similar to that noted for CD8 veto cells. The relative efficiency of activated CD4 cells is greater than that of resting NK cells but is less than that of activated CD8 or NK cells. Thus, CD4 cells not only provide helper activity for CTL precursors, but also act as veto cells to prevent the generation of CTL activity.     

Correlation of Qa-1 determinants defined by antisera and by cytotoxic T lymphocytes

Cytotoxic T lymphocytes (CTL) activated in H-2 identical, Qa-1 disparate mixed leukocyte cultures recognize H-2-nonrestricted target antigens indistinguishable by strain or tissue distribution from serologically defined Qa-1 antigens. Cloned Qa-l-specific CTL define determinants encoded by four Qa-1 genotypes; we used anti-Qa-1 sera in antibody blocking experiments to determine if these determinants reside on molecules recognized by Qa-1-specific antibodies. Antisera containing Qa-1.1-specific and TL-specific antibodies blocked recognition of two CTL-defined determinants associated with Qa-1 ^a . Although both Qa-1 and TL molecules are expressed on activated T cells from appropriate strains, our studies indicated that the CTL recognized Qa-1, not TL. In addition, anti-Qa-1.2 serum inhibited CTL recognition of Qa-1^b- and Qa-1^c-encoded determinants. Qa-1 ^d target cells are unique in that they express determinants recognized by anti-Qa-1^a CTL and by anti-Qa-1^b CTL. Killing of Qa-1 ^d targets by anti-Qa-1^a CTL was not inhibited by anti-Qa-1.1 serum, but was partially inhibited by anti-Qa-1.2 serum. Cytotoxicity of Qa-1 ^d cells by one anti-Qa-1^b CTL clone was inhibited by both anti-Qa-1.2 and anti-Qa-1.1 sera, indicating close association of both serological determinants with the determinants recognized by the CTL. Thus, all of the CTL-defined Qa-1 determinants resided on molecules recognized by Qa-1-specific antibodies, but anti-Qa-1^a CTL and Qa-1.1-specific antibodies did not have identical specificities.Abbreviations used in this paper B6 C57BL/6J - CAB concanavalin A stimulated lymphoblasts - CML cell-mediated lympholysis - CTL cytotoxic T lymphocyte - NMS normal mouse serum - MHC major histocompatibility complex - MLC mixed leukocyte culture - MR maximum release - SMDM supplemented Mishell-Dutton medium - SR spontaneous release     

Mouse CD94 participates in Qa-1-mediated self recognition by NK cells and delivers inhibitory signals independent of Ly-49

Inhibitory receptors expressed on NK cells recognize MHC class I molecules and transduce negative signals to prevent the lysis of healthy autologous cells. The lectin-like CD94/NKG2 heterodimer has been studied extensively as a human inhibitory receptor. In contrast, in mice, another lectin-like receptor, Ly-49, was the only known inhibitory receptor until the recent discovery of CD94/NKG2 homologues in mice. Here we describe the expression and function of mouse CD94 analyzed by a newly established mAb. CD94 was detected on essentially all NK and NK T cells as well as small fractions of T cells in all mouse strains tested. Two distinct populations were identified among NK and NK T cells, CD94(bright) and CD94(dull) cells, independent of Ly-49 expression. The anti-CD94 mAb completely abrogated the inhibition of target killing mediated by NK recognition of Qa-1/Qdm peptide on target cells. Importantly, CD94(bright) but not CD94(dull) cells were found to be functional in the Qa-1/Qdm-mediated inhibition. In the presence of the mAb, activated NK cells showed substantial cytotoxicity against autologous target cells as well as enhanced cytotoxicity against allogeneic and "missing self" target cells. These results suggest that mouse CD94 participates in the protection of self cells from NK cytotoxicity through the Qa-1 recognition, independent of inhibitory receptors for classical MHC class I such as Ly-49.     

Inhibition of T cell responses to alloantigens and polyclonal mitogens by Ly-5 antisera

The effects of Ly-5 alloantisera on the generation of cytotoxic T cells (CTL), on the effector phase of CTL killing, and on polyclonal mitogenesis were studied. Ly-5 antisera added at the beginning of mixed lymphocyte culture (MLC) suppressed the production of CTL in an allele-specific manner. Neither Ly-5.1 nor Ly-5.2 antisera inhibited the generation of cytotoxic effectors by Ly-5.1/Ly-5.2 heterozygous spleen cells; however, a combination of Ly-5.1 and Ly-5.2 antisera markedly suppressed the appearance of Ly-5 heterozygous CTL. Similarly, Ly-5 antisera inhibited the effector phase of CTL killing in an allele-specific manner. In addition, Ly-5 alloantisera specifically blocked concanavalin A and oxidative mitogenesis of splenocytes carrying the appropriate Ly-5 alloantigen. The results are discussed in light of a possible functional role of Ly-5 molecules in immune processes.     

T lymphocyte responses to non-H-2 histocompatibility antigens. I. Role of Ly-1+2+ T cells as cytotoxic effectors and requirement for Ly-1+2+ T cells for optimal generation of cytotoxic effectors

Cytotoxic effector T cells specific for non-H-2 histocompatibility (H) antigens were examined for phenotypic expression of lymphocyte differentiation (Ly) antigens. Virtually all H-Y-specific cytotoxic effectors generated in mixed lymphocyte culture were Ly-1+2+ T cells. H-3-specific effectors comprised both Ly-1+2+ and Ly-1-2+ T cells. However, cytotoxic effectors specific for multiple non-H-2 H antigens were predominantly Ly-1-2+ T cells. The optimal generation of H-Y- and H-3-specific effectors required Ly-1+2+ T cells; optimal generation of multiple non-H-2 H antigen-specific effectors required an interaction between Ly-1+2- and Ly-1-2+ T cells. These observations suggest that the identity of the target H antigen in part determines the Ly type of responsive T cells. Our observations suggest that 2 alternative pathways of T cell response exist for non-H-2 H antigens. The first pathway involves an interaction between Ly-1+2- helper T cells and Ly-1-2+ cytotoxic effector precursors. The 2nd pathway simply involves the response of Ly-1+2+ T cells proliferating and generating H antigen-specific cytotoxic effectors.     

Regulation of the cytotoxic T lymphocyte response against Qa-1 alloantigens

Spleen cells from B6.Tlaa (Qa-1a) mice primed against C57BL/6 (Qa-1b) splenocytes in vivo generate Qa-1-specific CTL when rechallenged with Qa-1b Ag in vitro. The addition of unirradiated Qa-1b splenocytes to these cultures inhibits the generation of Qa-1-specific CTL. By using highly purified cell populations, we demonstrate that the only cell population in resting spleen capable of causing this inhibition is NK1.1+. Although resting CD8 cells lack inhibitory activity, purified CD8 cells precultured with Con A and IL-2 inhibit anti-Qa-1 CTL. This inhibition is specific for the Qa-1b Ag expressed on the inhibitor cells, is not due to cold target competition, and is thus similar to that ascribed to veto cells. Although NK cells from resting spleen inhibit the generation of Qa-1-specific CTL, NK cells precultured in the presence of Con A and IL-2 show an approximate 30-fold increase in veto activity. Thus, NK cells represent the most likely cell population for down-regulating anti-self class I-reactive CTL.     

The Ly-10 antigen is a marker of mouse-activated T lymphocytes

Ly-10.1 is a lymphocyte surface antigen controlled by a gene linked to the Ly-1.1 locus and expressed on activated T helper, T suppressor (Ts), and cytotoxic T lymphocytes (CTL). In this report, we describe the following:

Interaction between MHC-encoded products and cloned T cells

The interaction between class I major histocompatibility complex (MHC) products and T cells was studied using H-2K^b-specific alloreactive T-cell lines and clones obtained by repeated in vitro stimulation with allogeneic cells. Induction of proliferation of these T cells appeared to involve two signals: the H-2K^b alloantigen and interleukins. Immunopurified liposome-inserted H-2K^b, which stimulates specific secondary in vitro cytotoxic T lymphocyte (CTL) responses, could not replace cell-associated H-2K^b in the stimulation of these T-cell lines, even in the presence of feeder cells and interleukins. When T-cell lines were initiated in vitro and repeatedly stimulated with H-2K^b liposomes and feeder cells, it was possible to obtain T cells that could proliferate in response to H-2K^b liposomes in the presence of feeder cells and interleukin-2-containing supernatants or on H-2K ^b -expressing cells. Only stimulation with cells permitted maintenance of these T cells in culture for more than 12 weeks. Analyses of cell surface markers and of patterns of inhibition of proliferation by monoclonal antibodies (mAb) of T-cell lines induced in vitro with cell- or liposome-associated H-2K^b indicated that T-cell stimulation by class I antigen can occur in at least two ways. In the first, the H-2K^b-induced proliferation of Lyt-1^- Lyt-2⁺ T4^- T cells is inhibited by H-2K^b- and by Lyt-2-specific mAb, but not by Ia or T4-specific mAb. In the second, both Lyt-2⁺ and T4⁺ T cells are involved and the H-2K^b-induced proliferation is inhibited by H-2K^b- and Lyt-2-specific mAb and by Ia- and T4-specific mAb.Abbreviations used in this paper Ab antibody - mAb monoclonal antibody - C complement - i.p. intraperitoneally - PBS phosphate-buffered saline - PBS-B-N PBS containing bovine serum albumin and NaN₃ - CTL cytotoxic T lymphocyte - Th T helper cell - MHC major histocompatibility complex - PMA 4-phorbol 12-myristate 13-acetate - SCA concanavalin A-stimulated rat spleen cell supernatant - SC16 EL4 clone 16 supernatant - IL-1 interleukin-1 - IL-2 interleukin-2 (T-cell growth factor) - FCS fetal calf serum - H-2K^b-lip. H-2K^b inserted in liposomes - C. E. cell equivalents     

Role of lymphokine-activated killer cells as mediators of veto and natural suppression

Fresh bone marrow cells have veto activity but little if any NK activity. By contrast, lymphokine-activated bone marrow cells have potent natural suppressor as well as veto activity, and also have cytolytic activity characteristic of lymphokine-activated killer cells. Veto activity of fresh bone marrow cells is eliminated by 9 Gy irradiation and by depletion of cells expressing Qa-2, but is unaffected by removal of cells expressing Thy-1, Qa-5, Ly-5, or asialo GM1. By contrast, the veto and NS activities of lymphokine-activated bone marrow cells are both abrogated by C lysis depletion of cells expressing Qa-2, Qa-5, Thy-1, asialo GM1, NK1, and Ly-11, but are unaffected by depletion of cells expressing Ly-2. Bone marrow cells depleted of Qa2+ cells fail to generate veto or natural suppressor activity when cultured in Con A-conditioned medium, unlike bone marrow cells depleted of mature NK1.1+ NK cells. Cloned NK cell line F8 is able to mediate both natural suppression and veto. These findings indicate that bone marrow veto and natural suppression are not mediated by T or NK cells present de novo in the bone marrow, but are dependent on proliferating cells that phenotypically resemble pre-NK cells. The progeny of these cells have the phenotype and functional activity of lymphokine-activated killer cells, and are capable of directly mediating both veto and natural suppression.     

Characterization of T cell proliferative responses induced by anti-Qa-2 monoclonal antibodies.

The MHC class I Qa-2 Ag are attached to the cell surface by a glycanphosphatidylinositol (GPI) anchor. Crosslinking of Qa-2 and several other cell surface Ag attached by the GPI linkage has been shown to lead to cell activation. We have developed 10 new anti-Qa-2 mAb and characterized their capacity to induce proliferation of spleen cells. In the absence of anti-Ig-mediated crosslinking, none of the mAbs alone could induce activation. However, mAb 23.1 which reacts with the alpha 3 domain of Qa-2, when combined with most of the other mAbs (alpha 1, alpha 2 domain reactive), activated cells in the absence of anti-Ig crosslinking. The mAb pair 23.1 plus 24.16 was the most proficient and induced proliferation in the absence of any exogenous second signals. Responses were greatly enhanced and equivalent to those seen with anti-CD3 by the addition of phorbol myristate acetate (PMA). Ionomycin, rIL-2, or rIL-4 also potentiated anti-Qa-2 responses but less efficiently than PMA. Significant strain variation in the magnitude Qa-2-mediated proliferative responses was observed correlating with the levels of Qa-2 expressed on the cell surface. Crosslinking of Qa-2 molecules by the mAb combinations was required because monovalent Fab fragments failed to activate cells. F(ab')2 fragments of mAb 23.1 plus 24.16 induced vigorous proliferation indicating that accessory cell presentation of the mAb via Fc receptors was not required. Immobilized (plate bound) anti-Qa-2 mAb induced proliferation suggesting that the Qa-2 pathway may be distinct from that of other GPI molecules such as Thy-1 and Ly-6. Populations enriched for T cells (approximately 95%) responded as well as whole spleen cells, whereas B lymphocytes failed to proliferate to anti-Qa-2. Both CD4+ and CD8+ cells were activated following crosslinking of Qa-2. Finally, T cell activation mediated by Qa-2 induced elevation of [Ca2+]i, IL-2R expression, and the release of IL-2. These data demonstrate that crosslinking of Qa-2 on T lymphocytes represents a potent pathway for inducing cell activation.     

Analysis of the HLA-Cw3-specific cytotoxic T lymphocyte response of HLA-B7 X human beta 2m double transgenic mice

The cytolytic responses of either normal (non transgenic), HLA-B7 (single transgenic) or HLA-B7 x human beta 2 microglobulin (double transgenic) DBA/2 mice induced by transfected HLA-Cw3 P815 (H-2d) mouse mastocytoma cells were compared, to evaluate whether the expression of an HLA class I molecule in responder mice would favor the emergence of HLA-specific, H-2-unrestricted CTL. Only 8 of 300 HLA-Cw3-specific CTL clones tested could selectively lyse HLA-Cw3-transfected cells in an H-2-unrestricted manner, all having been isolated after hyperimmunization of double transgenic mice. These clones also lysed HLA-Cw3+ human cells. Unexpectedly, the lysis of the human but not that of the murine HLA-Cw3 cells was inhibited by Ly-2,3-specific mAb. Despite significant expression of HLA-B7 class I molecules on transgenic lymphoid cells, including thymic cells, limiting dilution analysis and comparative study of TCR-alpha and -beta gene rearrangements of the eight isolated clones (which suggested that they all derived from the same CTL precursor) indicated that the frequency of HLA-Cw3-specific H-2 unrestricted cytotoxic T lymphocytes remained low (even in HLA-B7 x human beta 2-microglobulin double transgenic mice). This suggests that coexpression of HLA class I H and L chain in transgenic mice is not the only requirement for significant positive selection of HLA class I-restricted cytotoxic mouse T lymphocytes.     

Studies of the mouse Ly-6 alloantigen system

Three monoclonal antibodies were produced by fusing mouse myeloma cell line NS-1 with spleen cells from C3H/An mice hyperimmunized with B6-H-2^k spleen cells. These antibodies recognized an alloantigen displaying a similar strain distribution pattern to the Ly-6.2 and Ala-1.2 alloantigens. Analysis of C×B and B×H recombinant inbred mice revealed close linkage of genes controlling Ly-m6 and Ly-6. The monoclonal antibodies lysed 70 percent of cells in lymph nodes and 60 percent in spleen in direct cytotoxicity assays, but did not lyse significant numbers of cells of thymus and bone marrow. Separated T and B cells were reactive with the antibodies, but T cells were more sensitive to the antibody and complement than B cells. Virtually all cells in cultures of cells activated in the mixed lymphocyte reaction or by Concanavalin A were reactive with the monoclonal antibodies. Direct plaque-forming cells were completely eliminated by the monoclonal antibody and complement. By absorption tests, cells from all organs tested so far (thymus, lymph node, spleen, bone marrow, brain, kidney and liver) were shown to express the Ly-m6 determinant. Tumor cell lines with T, B or stem cell characteristics were reactive with the monoclonal antibody by direct cytotoxicity and absorption assays.     

Dual immunofluorescence studies of cortisone-induced thymic involution: evidence for a major cortical component to cortisone-resistant thymocytes

Cortisone-resistant thymocytes (CRT) have been used as the experimental equivalent of medullary thymocytes for the past 15 yr. Studies with CRT have provided evidence that the medullary population is similar to mature T cells in phenotype and function and may therefore be the major source of thymus emigrants. However, we have recently demonstrated that CRT differ from medullary thymocytes in their expression of the homing receptor molecule recognized by the monoclonal antibody MEL-14. Thus, many CRT express high levels of the MEL-14-defined homing receptor, whereas medullary thymocytes are MEL-14- to MEL-14lo. In normal adult mice, only 1 to 3% of thymocytes are MEL-14hi; these cells are located exclusively in the cortex and many are phenotypically and functionally mature. In this study we have used dual immunofluorescence techniques to further characterize those thymocytes resistant to cortisone treatment. Aside from being of mature phenotype with respect to expression of peanut agglutinin binding sites and the cell surface molecules H-2K, Ly-1, Lyt-2, and L3T4, CRT can be divided into MEL-14lo and MEL-14hi subpopulations, suggesting that they may actually be derived from both the medullary and the MEL-14hi cortical thymocyte subsets.     

Detection of allogeneic Qa/TL and Ly specificities on murine tumor cells with IgD in tumor-regressor serum

Summary Serum from C3H/He mice, which show regression of MM2 tumor cells after transplantation and removal (regressor serum, RS) contains non-gammaglobulin components that cross-react with various tumor cells of mice [22, 23]. In addition to tumor cells, various allogeneic lymphocytes are also susceptible to an RS-dependent lymphocyte-mediated cytotoxic reaction. To identify tumor cell surface antigens that cause the cross-reactive host response, the serum components were analyzed by absorption of RS with allogeneic lymphocytes. RS components were found to recognize allogeneic lymphocyte antigens including Qa-2 and Ly6.2. Specificity for the Qa-2 antigen was further tested using Qa-2-congenic mice. The expression of Qa-2 antigen was detected on the surfaces of MM2 and other tumor cells derived from H-2^k mice (seven among nine cell lines tested) by a membrane immunofluorescence method using a Qa-2-specific mAb. Physical characteristics of the Qa-2-specific component in RS were determined and found to differ from those of regular IgGs but to be similar to those of IgDs. Using an enzyme-linked immunosorbent assay with an IgD-specific mAb and Qa-2-lacZ fusion protein, the existence of IgD in RS with specificity for Qa-2 was confirmed. These results suggest that the RS component with Qa-2 specificity is an IgD, the specificity and physiological role of which are unknown.     

Membrane structures involved in auto-tumor recognition

Tumor patients' blood lymphocytes have the capacity to recognize autologous tumor cells in vitro. A consequence of this recognition is the proliferation of small-size, high-density, resting T cells. Both helper (CD4+) and cytotoxic/suppressor (CD8+) T lymphocytes proliferate in the mixed lymphocyte-tumor cell cultures. In contrast to the autologous mixed lymphocyte cultures, both the auto-erythrocyte rosetting and non-rosetting (AE+ and AE-) T cells participate in the auto-tumor response. In contrast to stimulation by virus-infected or hapten-modified cells, DR antigen expression is not essential for stimulation by autologous tumor cells. In a proportion of cancer patients, blood lymphocytes have the capacity to lyse the patients' own tumor cells in vitro. There are two populations of lymphocytes with auto-tumor cytotoxic function. The first is characterized by low buoyant density and by non-adaptive cytotoxicity. In contrast to the recognition of hapten-modified or virus-infected target cells by the CTL, recognition of autologous tumor cells by the cytotoxic LD cells occurs even when the MHC class I antigens are blocked by mAb. The CD3 complex is also not involved in LD-mediated lysis. The other population with auto-tumor cytotoxic function comprises high-density, resting T cells. Recognition of autologous tumor cells by cytotoxic HD lymphocytes shares the characteristics of CTLs, i.e., their function is abrogated by pretreatment of the effectors with mAbs directed to the T3 receptor complex and by preincubation of the targets with mAb to the MHC class I antigens. Cytotoxicity of HD cells is restricted to the autologous tumor cells. This selectivity and the characteristics shared with CTL suggest that the auto-tumor reactivity of HD lymphocytes reflects an immune response against the autologous tumor.     

The antitumor effect of tumor-draining lymph node cells activated by both anti-CD3 monoclonal antibody and activated B cells as costimulatory-signal-providing cells

To establish an efficient cell-culture system for adoptive immunotherapy, we attempted to use lipopolysacharide (LPS)-activated B cells (LPS blasts) as costimulatory-signal-providing cells in the in vitro induction of antitumor effector cells. Both normal and tumor-draining lymph node cells were efficiently activated by both anti-CD3 monoclonal antibody (mAb) and LPS blasts, and subsequently expanded by a low dose of interleukin-2 (IL-2; anti-CD3 mAb and LPS blasts/IL-2). The expanded cells were predominantly CD8⁺ T cells and showed a low level of tumor-specific cytotoxic T lymphocyte (CTL) activity. The adoptive transfer of B16-melanoma-draining lymph node cells expanded by anti-CD3 mAb and LPS blasts/IL-2 showed significant antitumor effect against the established metastases of B16 in combination with intraperitoneal injections of IL-2. This treatment cured all B16-bearing mice. In addition, these mice also showed tumorspecific protective immunity against B16 at the rechallenge. Considering that activated B cells express several kinds of costimulatory molecules, these findings thus indicate an efficacy of costimulation that is derived from activated B cells for the in vitro induction of tumor-specific CTL, in co-operation with anti-CD3 mAb. The culture system presented here may thus be therapeutically useful, providing potent effectors for adoptive immunotherapy against various types of cancer.     

Phenotype and localization of thymocytes expressing the homing receptor-associated antigen MEL-14: arguments for the view that most mature thymocytes are located in the medulla

The monoclonal antibody MEL-14 recognizes a lymphocyte surface structure (the MEL-14 antigen) involved in migration of lymphocytes into lymph nodes. Its use as a maturation marker for T cells within the thymus led to the view that a small population (1 to 2%) of MEL-14high thymocytes located in the inner cortex represented fully mature cells about to exit as thymus emigrants. The medulla, in this view, contained only the phenotypically mature but MEL-14low cells, and was not the source of thymus emigrants. The data we present, derived from flow-cytometric analysis of suspension-stained CBA mouse thymocytes, is not in accordance with this view. A high proportion (approximately 20%) of thymocytes express relatively high levels of MEL-14; these include some immature Ly-2- L3T4- and nonmature Ly-2+ L3T4+ thymocytes. Among the 12 to 14% thymocytes of mature phenotype (PNAlow or H-2Khigh or Ly-2+ L3T4- and Ly-2- L3T4+), more than half express relatively high levels of MEL-14. The mature phenotype and MEL-14moderate-to-high cells (8% of thymocytes) appear too numerous to account for the few percent MEL-14high cells seen in the cortex in frozen sections, and the mature phenotype but MEL-14low cells (2 to 3% of thymocytes) too few to fill the medulla; however, both together account numerically for the medullary population. By section staining, the medulla contains Ly-2- L3T4+ and Ly-2+ L3T4- cells in a characteristic 2:1 ratio; by suspension staining this ratio agrees with that of the total mature phenotype population, but not with that of the MEL-14low subset previously claimed to represent medullary cells. Another paradox is apparent when suspension staining and section staining are compared: suspension staining reveals that many mature phenotype cells coexpress high levels of both MEL-14 and H-2K, yet section staining reveals H-2Khigh cells in the medulla but not in the inner cortex, and reveals scattered MEL-14high cells throughout the cortex but not in the medulla. We suggest that section staining for MEL-14 fails to locate the mature cells that stain for MEL-14 in suspension; the few MEL-14high cells localized in both the inner and the outer cortex on section staining are predominantly immature Ly-2- L3T4- and nonmature Ly-2+ L3T4+ thymocytes; the majority of thymocytes of mature phenotype, whether MEL-14high or MEL-14low on suspension staining, are of medullary location; the medulla is the most likely immediate source of thymic emigrants.