Changes in heat shock protein synthesis and heat sensitivity during mouse thymocyte development

Heat shock protein synthesis was examined in mouse thymocytes at three stages of development: early embryonic thymocytes, which are CD4^?CD8^?, adult thymocytes, which are primarily CD4⁺CD8⁺, and mature spleen T cells, which are CD4⁺CD8^? or CD4^?CD8⁺. After either a 41°C or 42°C heat shock, the synthesis of the maior heat-inducible protein (hsp68) was elevated during the first hour of recovery but then decreased abruptly in thymocytes from adult mice. In contrast, the synthesis of hsp68 continued for up to 4 h after heating embryonic mouse thymocytes or mature spleen T cells. The more rapid termination ofthe heat shock response in the adult thymocytes was not the result of eitherless heat damage or more rapid repair since the recovery of general protein synthesis was more severely delayed in these cells. As well, the double positive CD4⁺CD8⁺ cells were more sensitive to hyperthermia than either the double negative CD4^?CD8^? or single positive CD4⁺CD8^? or CD4^?CD8⁺ cells. Exposure of fetal thymus organ cultures to elevated temperature revealed that the double negative thymocytes were able to survive and differentiate normally following a heat shock treatment that was lethal for the double positive thymocytes. Exposure of thymocytes from adult mice to elevated temperatures induced apoptotic cell death. This was evident by the cleavage of DNA into oligonucleosome-sized fragments. Quantitation of the extent of DNA fragmentation and the number of apoptotic cells by flow cytometry demonstrated that the extent of apoptotic cell death was related to the severity of the heat stress. Double positive (CD4+CD8+) thymocytes are selected on the basis of their T-cell antigen receptor (TCR). Most of these cells are negatively selected and die within the thymus by an active process of cell deletion known as apoptosis. Restricting hsp synthesis in response to stress might be essential during developmental processes in which cell maturation is likely to result in death rather than functional differentiation. © 1993Wiley-Liss, Inc.     

Antigenic relationship between medullary thymocytes and a subpopulation of peripheral T cells in the rat: description of a masked antigen.

Using differentially absorbed rabbit antisera to rat thoracic duct cells, an antigen is described which normally is expressed on the surface of T cells in thoracic duct lymph and lymph node, but which exists in a masked form on medullary thymocytes and apparently not at all on cortical thymocytes. This antigen is termed the rat masked thymocyte antigen (RMTA). RMTA on medullary thymocytes can be unmasked mechanically by sectioning in a cryostat or enzymatically by treating with neuraminidase. Trypsin destroys or removes RMTA. Nearly all the T cells in thoracic duct lymph and lymph node are RMTA⁺, whereas only 58–66% of T cells in spleen are RMTA⁺. RMTA⁺ T cells, which are cortisone resistant, reside in the paracortex and periarteriolar sheath regions of lymph node and spleen. RMTA^? T cells, which are cortisone sensitive, appear to reside in the red pulp of spleen. The results suggest that (i) two antigenically distinct populations of T cells exist in the rat, RMTA⁺ and RMTA^? T cells, (ii) medullary thymocytes are the immediate precursors of RMTA⁺ T cells, and (iii) cortical thymocytes may be the immediate precursors of RMTA^? cells.     

T-lymphocyte heterogeneity in the rat: Separation of distinct rat T-lymphocyte populations which respond in syngeneic and allogeneic mixed lymphocyte reactions

These experiments were designed to determine if separate subpopulations of T cells were involved in the syngeneic and allogeneic mixed lymphocyte reaction. Rat lymph node T cells were separated into W3/25⁺ and W3/25^? subpopulations by panning with the monoclonal antibody W3/25 and tested for their ability to proliferate in both syngeneic (SMLR) and allogeneic (MLR) mixed lymphocyte responses, as well as to develop cytotoxicity against allogeneic, syngeneic, and trinitrophenol (TNP)-modified syngeneic targets. The W3/25⁺ T cells reacted strongly in the SMLR and the MLR whereas the W3/25^? fraction proliferated only in response to allogeneic stimulation and with a kinetic pattern distinct from W3/25⁺. Furthermore, addition of W3/25 monoclonal antibody directly to the cultures was shown only to inhibit the proliferation of the W3/25⁺ T-cell fraction. The W3/25^? subpopulation contained cytotoxic T cells (CTLs) against both allogeneic determinants and TNP-modified self. However the requirements for the activation of allospecific CTLs were distinct from those for CTLs for TNP-self in that W3/25^? allospecific CTLs required no detectable help from W3/25⁺ T cells but generation of the CTL response against TNP-self required the presence of W3/25⁺ helper T cells (Th). These data suggest that in the rat, there exist subsets of T cells recognized by their cell surface phenotype that distinguish between self and nonself determinants and the requirements for activation are different for each of these populations.     

Use of positively selected Lyt-2+ mouse splenocytes to examine interleukin-2 secretion in responses to alloantigens and to TNP-modified syngeneic cells

Current models for T-cell interactions in the generation of cytotoxic T lymphocytes have encountered a technical problem, since it has until recently been impossible to purify the peripheral Lyt-1⁺2⁺ subset from the Lyt-1⁺2^? helper cell set. Reports that the helper factor Interleukin-2 (IL-2) can be synthesized by Lyt-2⁺ spleen cells have suggested that the peripheral Lyt-2⁺ set, unlike Lyt-2⁺ thymocytes, might not depend on help from Lyt-1⁺2^? cells. To clarify this question, we have produced spleen Lyt-2⁺ cells, and the complementary Lyt-2^? set, by a positive selection method. The Lyt-2⁺ cells were able to produce high levels of anti-hapten CTL only if supplemented with either Lyt-2^? cells or with semi-purified IL-2. Although IL-2 synthesis from Lyt-2⁺ cells, or from unseparated T cells, could be induced by H-2I region-disparate stimuli, Lyt-2⁺ cells produced very little IL-2 in response to H-2I or to H-2K region-disparate cells. IL-2 synthesis in hapten-stimulated cultures was found not to depend on the presence of the hapten per se, and probably represents a response to components of the fetal calf serum supplementation. Lyt-2⁺ cells were also much less able to generate IL-2 than Lyt-2^? cells in response to these stimuli. Cell mixing experiments provided no evidence that Lyt-2⁺ cells could suppress IL-2 secretion by Lyt-2^? cells. We conclude that generation of CTL from splenic Lyt-2⁺ cells requires IL-2 produced by Lyt-2^? cells, because Lyt-2⁺ cells do not produce high levels of IL-2 themselves, even when stimulated across an H-2K difference alone.     

Defective T helper activity in the spleen of BALB/c mice immune to a syngeneic fibrosarcoma

Summary BALB/c mice were immunized with the syngeneic 3-methylcholanthrene-induced fibrosarcoma CA-2 by the growth and excision method. When lymphoid cells from different organs of these tumor-free mice were tested in a direct ⁵¹Cr-release assay, peritoneal exudate cells but not spleen cells displayed specific cytotoxicity against the syngeneic tumor target. A cytotoxic response could be obtained by tumor-immune spleen cells when cultured in a mixed lymphocyte tumor cell culture (MLTC) at high but not low density although at the same effector/stimulator ratio. Lack of cytotoxic activity in low density MLTC was not due to an impairment of cytotoxic precursors since cytotoxicity was rescued by adding exogenous interleukin-2 in experimental conditions in which no lymphokine-activated killer cells could develop relevant anti-CA-2 lysis. When low density MLTC were supplemented with either 800 R-irradiated cells or nonirradiated, negatively selected Lyt 1⁺ cells from the same immune mice, induction of a cytotoxic response against CA-2 occurred and interleukin-2 production became detectable. Additional studies indicated that spleen cells of CA-2-immune mice were also impaired in their ability to provide help to syngeneic thymocytes for the generation of cytotoxic T lymphocytes against C57BL/6J alloantigens. Dilution effect of helper cells due to immunization procedures was excluded since spleen cells of mice immunized against another BALB/c tumor, the YC8 lymphoma, or against DBA/2 minor histocompatibility antigens provided good help to thymocytes against the same alloantigens. These results indicate that tumor-immune animals may also have selective T helper defects in an important lymphoid organ like spleen.     

The role of Ia antigens and Fc receptor-bearing T-cells in the inhibition of macrophage receptors for cytophilic antibody induced by soluble immune complexes

Soluble antigen-antibody complexes composed of 3 M KCl-extracted L1210 antigens and alloantibody to L1210 given to C3H mice caused immunosuppression in the mice. This was reflected in part by the inhibition of cytophilic antibody receptors on macrophages which could be used as a measure of the suppression. Thymocytes or splenic T cells from mice treated with immune complexes could adoptively transfer the suppression to normal syngeneic mice. These cells, which we have termed suppressor inducers, were found to be Ia positive: specifically, I-A⁺, I-J^?. Thus, treatment of the inducers with anti-la or anti-I-A antibodies and complement in vitro abrogated their ability to transfer the suppression to normal mice. In contrast treatment with anti-I-J serum and complement had no effect. Through a similar approach, the cooperating (acceptor) T cells were found to be I-A⁺, I-J^?. Pretreatment of mice with anti-Ia or anti-I-A serum before the administration of antigen-antibody complexes prevented the inhibition of macrophages. This was due at least in part to steric hindrance of adjacent Fc receptors on the FcR⁺ T cells with which the complexes interacted. Early interaction of immune complexes with FcR⁺ T cells was in fact demonstrated directly by the inability of the complexes to induce suppression when FcR⁺ T cells were depleted. The thymocytes or splenic T cells from anti-Ia-pretreated mice failed to transfer the suppression to recipient mice. In contrast, treatment with either anti-Ia or anti-I-A after the immune complexes did not abrogate the generation of suppressor inducers. Treatment of normal recipient mice with anti-Ia serum in vivo before they received the suppressor inducer cells did not prevent cooperation between the two types of cells. By the same token, blocking of Ia antigens of the inducers in vitro with anti-Ia serum (without complement) also did not impair the cooperative interaction. These results indicate that antigen-antibody complexes generate I-A-positive, I-J-negative T-suppressor inducer cells from FcR⁺ naive T cells. These in turn interact with Ia-positive (I-A⁺ and I-J^?) normal thymocytes or spleen T cells. This interaction most likely generates the ultimate suppressor T cells that suppress cytophilic antibody receptors on macrophages in vivo. However, the I-region determined antigens did not appear to be directly involved in the T-T interaction of suppressor inducer and acceptor cells.     

Immunological properties of Fc receptor on lymphocytes. 2. Differentiation from FcR- to FcR+ cells and their functional differences in in vitro antibody response.

In in vitro plaque-forming cell (PFC) response to particulate as well as to soluble antigen, the functional difference between Fc receptor-bearing (FcR⁺) and nonbearing (FcR^?) murine splenic lymphocytes was analyzed using the EA rosetting method. In the secondary anti-horse red blood cell (HRBC) response of C3H mice, FcR^? cells showed higher IgM and IgG responses than did FcR⁺ cells. When nylon wool (NW)-purified T cells primed with keyhole limpet hemocyanin (KLH) were fractionated into FcR^? and FcR⁺ T cells, helper activity was proven in the former subset in the cooperation with syngeneic spleen cells primed with dinitrophenylated ascaris extract (DNP-Asc). FcR⁺ T cells showed essentially no helper activity. When FcR^? cells were cultured, neogenesis of FcR⁺ cells was observed on Days 3 to 5. The conversion from FcR^? to FcR⁺ cells was prominent in B cells (40 to 50%), whereas NW-purified nonadherent FcR^? T cells converted poorly (15 to 20%). The converting process was accelerated slightly by mitogens, but was least affected by antigens. To examine the possible contribution of neogeneic FcR⁺ T cells in the helper activity, KLH-primed FcR^? T cells were precultured for 7 days with homologous antigen. The specific helper activity of the cultured T cells proved to be unaffected by the depletion of neogeneic FcR⁺ T cells by EA rosetting. The neogeneic FcR⁺ T cells had no helper activity. It was thus suggested that helper T cells remain in the FcR^? cell fraction and do not convert to the FcR⁺ state during the cooperating process.     

Regulation on murine T cell responses to autologous antigens by alpha-fetoprotein

Murine α-fetoprotein (AFP), a major component of fetal and newborn sera, was shown to exert potent immunosuppressive effects on autologous mixed lymphocyte reactions (AMLR) in vitro. Thus, the relatively vigorous proliferative response of newborn CBA/J thymocytes reacting in mixed cultures against adult syngeneic spleen cells was almost totally abrogated by 200 and 100 μg/ml AFP over the 6-day time course studied, with significant suppression still evident in the presence of 10 μg/ml AFP. In contrast, the maximum achievable suppression of parellel allogeneic MLRs was only 40 to 60%. The newborn thymocyte anti-adult syngeneic spleen AMLR was shown to be mediated by an Lyt 1⁺23^? T-cell subset reacting against Ia⁺ adult non-T stimulator cells. Newborn and adult AMLRs resulting from autochthonous T responder/non-T stimulator cell mixtures from individual animals were also found to be highly sensitive to AFP-mediated suppression. The fact that fetal-derived AFP could be shown to efficiently inhibit neonatal thymocyte responses to autologous antigens when tested in vitro in amounts 20 to 50 times lower than the levels present in fetal and newborn sera suggests a potentially important role for endogenous AFP in the regulation of autosensitization during ontogeny.     

Induction of interleukin 3 but not interleukin 2 or interferon production in the syngeneic mixed lymphocyte reaction

The syngeneic mixed lymphocyte reaction (SMLR) was assayed in the medium containing syngeneic normal mouse serum (NMS), by using nylon-adherent stimulator cells and nonadherent responder T cells, which were prepared from murine spleens in the absence of fetal calf serum (FCS) to avoid any sensitization to xenogeneic protein antigens. The responder cells in this SMLR, without definite background proliferation, generated specific proliferative response to the syngeneic stimulator cells in a dose-related fashion. The SMLR was accompanied by production of interleukin 3 (IL 3) but not interleukin 2 (IL 2) or interferon (IFN). No cytotoxicity against the syngeneic or allogeneic target cells was induced. Correlating with no production of IL 2 or IFN, no natural killer (NK) activity was detected. The proliferation was not inhibited by addition of specific antiserum for IFN-gamma. In contrast, proliferation in the responder cells when incubated with allogeneic stimulator cells was inhibited by anti-IFN-gamma serum and accompanied by production of IL 2 and IFN as well as IL 3, and by augmentation of NK activity and generation of cytotoxic T cells. Cell surface analysis revealed that the cells producing IL 3 in this SMLR system were Thy-1+ Lyt-1+2- helper T cells. Cells responding to the SMLR culture fluids with DNA replication were Thy-1-Lyt-1-2- asialo GM1- no-marker cells, which were the same as a population responsible for partially purified IL 3. On the other hand, when the responder cells were exposed to FCS before culture and assayed for SMLR in the FCS-free NMS medium, variable levels of IL 2 production were induced in response to the stimulator cells. The responder cells generated a high background DNA replication in the absence of syngeneic stimulators, suggesting that this IL 2 production may result from the stimulation of T cells by FCS as a foreign antigen. Overall, these results suggest that the SMLR may be a cellular interaction, in which non-T cells stimulate Lyt-1+2- helper T cells to produce IL 3 but not IL 2 or IFN. This IL 3 can, in turn, induce proliferation of IL 3 responding cells, which appear to be early precursors in lymphocyte differentiation, but no proliferative response or activation of IL 2- and IFN-dependent mature T cells or NK cells.     

Selective protection of murine thymic helper T cells from glucocorticosteroid inhibition by macrophage-derived mediators

We investigated the in vitro effects of dexamethasone (DEX) on the functional capacities of virgin murine T cells cultured in the absence and presence of adjuvant-stimulated macrophages or factors derived from them. Immunologically mature thymocytes, isolated on the basis of their inability to bind peanut agglutinin (PNA^? thymocytes), were used as virgin T cells. Treatment of PNA^? thymocytes with DEX for 24 hr in vitro eliminated their subsequent capacity to function as helper cells for primary humoral responses, to proliferate when stimulated by plant mitogens or allogeneic cells, or to generate T-cell-mediated cytotoxic responses. However, when PNA^? thymocytes were pretreated with DEX in combination with either adjuvant-activated macrophages or their culture supernatants, which contained Interleukin 1, the capacity of the T cells to subsequently express helper activity was preserved. The macrophage products, however, did not prevent DEX from inhibiting the capacities of PNA^? thymocytes to proliferate in response to plant mitogens or alloantigens or to generate cytotoxic effector cells; thus, protection was selective. The data indicate that, prior to activation, helper T cells are distinguished by their capacity to become steroid resistant in response to macrophage products. Although T-cell proliferative and cytotoxic responses have been reported to be protected from DEX inhibition by Interleukin 2, our results suggest that macrophages prevent steroid effects on virgin helper T cells by Interleukin-1-dependent mechanisms that do not involve Interleukin 2. While we have not delineated the biochemical pathways of protection, we show that the acquisition of DEX resistance by helper T cells cannot be attributed to the polyclonal induction of helper activity by macrophage factors.     

Thymic lymphocytes: II. Phenotypic modifications of thymocytes after concanavalin A stimulation in the presence of interleukin 2: Early modifications of Lyt 1+2+ subset and later proliferation of cells with more mature phenotypes

Cortical thymocytes are devoid of any immune function, as tested by presently available techniques. The ability of this subpopulation to respond to mitogens or antigens in the presence of interleukin 2 (IL-2) produced by activated mature T lymphocytes has been claimed but is still questioned. In an attempt to study the participation of the different thymocyte subsets and especially that of the cortical type, phenotypic modifications were examined during concanavalin A activation in the presence of IL-2. An immunofluorescent double labeling technique with anti-Lyt 1 and anti-Lyt 2 antibodies was used which led to the determination of four different phenotypes: Lyt 1⁺2⁺, Lyt 1⁺2^?, Lyt 1^?2⁺, and Lyt 1^?2^?. Careful analysis of cell viability in culture and expression of the results in absolute numbers of living cells per culture allowed us to follow modifications of small cellular subsets. Cultures of total thymocytes and PNA-agglutinated (enriched in Lyt 1⁺2⁺ cells) and non-PNA-agglutinated cells (enriched in Lyt 1⁺2^?, Lyt 1^?2⁺, and Lyt 1^?2^? cells) were studied. It was shown that thymocyte activation began by early phenotypic modifications which took place within the first 2 hr of culture but only when Con A plus IL-2 were used. These modifications imply the reduction of the Lyt 1⁺2⁺ pool and a compensatory enhancement of Lyt 1^?2⁺ and Lyt 1^?2^? cells, without modification of the total cell number or [³H]thymidine incorporation. These early phenotypic changes are interpreted as the modulation of antigens on the surface of Lyt 1⁺2⁺ cells. The second phase of thymocyte activation implies cell death (essentially Lyt 1⁺2⁺ cells) and cell proliferation. The cells which specifically proliferate in the presence of Con A and IL-2 are Lyt 1⁺2^? and Lyt 1^?2⁺, the latter always being present in greater number. Cell survival and absolute number of Lyt 1⁺2^? and Lyt 1^?2⁺ cells in the activated PNA^?-enriched population are always higher than in total thymocyte and PNA⁺ cells cultures. Thus, if Lyt 1⁺2⁺ cortical thymocytes do not proliferate by themselves, they seem to intervene by providing Lyt 1^?2⁺ cells which proliferate secondarily.     

Accumulation of major histocompatibility complex class II+CD11c− non‐lymphoid cells in the spleen during infection with Plasmodium yoelii is lymphocyte‐dependent

The spleen is the main organ for immune defense during infection with Plasmodium parasites and splenomegaly is one of the major symptoms of such infections. Using a rodent model of Plasmodium yoelii infection, MHC class II⁺CD11c^? non‐T, non‐B cells in the spleen were characterized. Although the proportion of conventional dendritic cells was reduced, that of MHC II⁺CD11c^? non‐T, non‐B cells increased during the course of infection. The increase in this subpopulation was dependent on the presence of lymphocytes. Experiments using Rag‐2^?/? mice with adoptively transferred normal spleen cells indicated that these cells were non‐lymphoid cells; however, their accumulation in the spleen during infection with P. yoelii depended on lymphocytes. Functionally, these MHC II⁺CD11c^? non‐T, non‐B cells were able to produce the proinflammatory cytokines alpha tumor necrosis factor and interleukin‐6 in response to infected red blood cells, but had only a limited ability to activate antigen‐specific CD4⁺ T cells. This study revealed a novel interaction between MHC II⁺CD11c^? non‐lymphoid cells and lymphoid cells in the accumulations of these non‐lymphoid cells in the spleen during infection with P. yoelii.

     

Identification of a novel isoform of ZAP-70, truncated ZAP kinase

We identified a novel cDNA encoding truncated ZAP-70, which lacked the SH2 domain and a part of interdomain B, and named it truncated ZAP kinase (TZK). TZK was expressed in the thymus, spleen, and lymph nodes with ZAP-70. TZK was expressed in CD44⁺CD25⁻ thymocytes up to mature T cells, but ZAP-70 was not expressed in CD44⁺CD25⁻ or CD44⁺CD25⁺ thymocytes. ZAP-70 or TZK was transfected into P116 cells derived from a Jurkat T-cell line deficient in ZAP-70. The P116 cells with ZAP-70 induced the T-cell receptor-mediated signal transduction, but the cells expressing TZK did not. While ZAP-70 was accumulated at the immune synapse, TZK was not. Meanwhile, impaired phosphorylation of SLP-76, one of the substrates of ZAP-70, in P116 cells upon pervanadate stimulation was rescued in the cells expressing TZK. These findings show that TZK is a novel isoform of ZAP-70, which is expressed in pre-T-cell receptor-minus thymocytes and functions as a kinase not associated with T-cell receptor.     

Analysis of Ly-6.2-bearing murine lymphocyte subpopulations in relation to the T-lymphocyte markers,Thy-1, Lyt-1, and Lyt-2

Using immunofluorescence with a monoclonal anti-Ly-6.2 antibody and FACS analysis we have confirmed that the Ly-6.2 antigen is present on approximately 70% of mature T cells and B cells but on few immature lymphocytes. There is a wide range of antigen density among the Ly-6.2⁺ populations, with the mean density higher on T cells than B cells. Following Con A activation of splenocytes there was a sixfold increase in Ly-6.2 antigen density though approximately 20% of the activated lymphocytes were Ly-6.2^?. The increase in Ly-6.2 density was specific since similar density increases did not occur for the closely linked antigens ThB and H $\text{9}\text{25}$. By panning a predominantly T-cell population for Lyt-2-bearing cells, it was found that Lyt-2⁺ lymphocytes were either negative or dully staining for Ly-6.2. However, activated cells bearing the Lyt-2 antigen were all Ly-6.2 positive. Double-staining experiments showed that T cells which had high Ly-6.2 antigen densities also had high Thy-1 antigen densities. Corticosteroid-resistant thymocytes were highly enriched for Ly-6.2-bearing cells compared to untreated thymocytes and had staining profiles for Ly-6.2 which were similar to peripheral T cells, supporting the idea that steroid treatment selects for a phenotypically mature thymic population.     

Cellular interactions in lymphocyte proliferation: effect of syngeneic and xenogeneic macrophages.

Secondary cell-mediated responses to ectromelia virus infection were studied using an in vitro system. Lymphoid “responder” cells from mice which had recovered from intravenous primary infection at various times prior to sacrifice, were cultured with syngeneic, virus-infected macrophages or spleen cells as “stimulator” cells at 39 °C, a temperature which prevented the virus from exerting cytopathic effects against responder cells. This restrictive temperature and medium with 2-mercaptoethanol at 10^?4M often gave viable cell yields of more than 100% of the original responder cells over 4 days of culture. Preliminary experiments showed that spleen cells from primed mice, cultured with syngeneic, infected spleen cells from normal mice gave the most powerful secondary cytotoxic cell responses as measured by ⁵¹Cr release from virusinfected H-2-compatible target cells. The cytotoxic cells were sensitive to anti-θ and complement treatment and lysed H-2-compatible, virus-infected target cells much more efficiently than infected, allogeneic target cells, thus indicating that they were T cells. Some activity against uninfected H-2-compatible target cells was also generated, but this was largely independent of the presence of virus-induced antigen, (i.e. infected stimulator cells were unnecessary) and therefore seemed to be a consequence of the cultural conditions. Cold target competition showed that this activity was the responsibility of a T cell subset separate from the virus-specific cytotoxic T cells. The peak of cytotoxic activity against virus-infected targets occurred at 4 days of culture and DNA synthesis was maximal on day 3. The concentration of cytotoxic T cells at the peak was eight-fold higher than at the peak of the splenic primary response in vivo, Memory T cells (precursors of secondary cytotoxic T cells) appeared in spleen within 12–14 days of primary infection in vivo, reached a plateau at 5–6 weeks and persisted for at least 16 months. Spleen cells appeared partly refractory to secondary stimulation in vitro at 8–10 days post-priming. This did not seem to be due to cellular migration from spleen to lymph nodes or peritoneal cavity, but its cause was not determined. Primary responses in vitro were not detectable under conditions optimal for secondary responses, thus suggesting a major quantitative, or qualitative difference between virgin and memory T cells.     

Regulation of cytotoxic responses to alloantigens by Ia+ cells

Pretreatment of responder spleen cells with anti-Ia plus complement led to an enhancement of cytotoxic responses to alloantigens as well as to TNP-modified self antigens. This observation confirms previous reports that cytotoxic T lymphocytes (CTL) and their precursors (CLP) are Ia^?. Furthermore, it suggests that the CTL responses to alloantigens or TNP-modified self-antigens are regulated by an Ia⁺ suppressor cell. Absorption studies and studies with anti-Ia sera specific for either the entire I region or the I-E/C subregions suggest that the regulatory cell certainly expresses I-E/C-coded determinants although the possibility that it also expresses I-A/B/J-coded determinats cannot be ruled out. Cell-mixing studies suggest that the regulatory cell is Thy-1^? and requires cell division before it can suppress. A clonal assay for CLP was used to show that the enhancement of the CTL response to alloantigens cannot be accounted for on the basis of an increase in the number of CLP in the anti-Ia + C-treated group.     

Immunological properties of Fc receptor on lymphocytes. 1. Functional differences between Fc receptor-positive and negative lymphocytes in humoral immune responses.

Using an EA rosetting system, it was observed that Fc receptors (FcR) were present on the surface of T cells as well as B cells, and that functional differences existed between FcR-positive (FcR⁺) and FcR-negative (FcR^?) cells in both T and B cells in in vivo humoral immune responses. Approximately 15% of splenic T cells obtained by nylon wool passage are FcR⁺. The number of surface immunoglobulinbearing cells as detected by immunofluorescent staining accounted for less than 10% of these FcR⁺ cells. FcR⁺ and FcR^? T+B-cell populations obtained from spleens contain 60 and 20% of surface immunoglobulin-positive cells, respectively. In the adoptive primary response in which horse RBC and dinitrophenyl-conjugated dextran (DNP-DE) were used as T-dependent and T-independent antigens, respectively, the majority of precursor B cells were FcR^?. In the secondary response using hapten-primed B cells and carrier-primed T cells, the majority of memory B cells for a haptenic determinant were also FcR^?. Furthermore, the majority of functional cells exerting helper activity in the same hapten-carrier system are FcR^? cells, and FcR⁺ T cells collaborate much less effectively with either memory B cells or helper FcR^? T cells.     

Thy.1lowCD3− Cells Sorted from Nylon Wool-Passed Bone Marrow Cells Can Augment the H-2 Identical but Not Non-Identical Cytotoxic T Lymphocyte Precursors in Mixed Lymphocyte Cultures

Thy. 1^lowCD3^– cells obtained from nylon wool-passed murine bone marrow (NW-BM) cells by cell sorting did not express CD4, CD8, or T cell receptor-α/β and -γ/δ on their cell surfaces. An extremely limited number of B10.BR (H-2^k) responder lymph node (LN) cells were stimulated with B10. D2 (H-2^d) stimulator spleen cells in cultures containing the minimum required dose of rat T cell growth factor (TCGF). In these cultures, the generation of cytotoxic T lymphocytes (CTL) was very low. B10.BR Thy.1^lowCD3^– NW-BM cells, added to these cultures, could augment the CTL generation vigorously, but neither B10 (H-2^b) nor B10.D2 cells could. When B10 LN cells were used as responder cells in these cultures, B10 Thy. 1^lowCD3^– NW-BM cells could augment the CTL generation, but neither B10.BR nor B10.D2 cells could. Similar findings were obtained when Lyt-2⁺ cells or Thy.1⁺ L3T4^– (CTL precursor) cells sorted from spleen cells were used as responder cells. Both elements, rat-TCGF and Thy.1^low CD3^– NW-BM cells, were essential for this augmentation of the CTL generation in this culture system because neither one alone could augment generation, and rat-TCGF could be replaced by Thy.1⁺ Lyt-2^– helper T (Th) cells sorted from spleen cells. These findings showed that NW-BM cells could augment CTL precursors in a self-major histocompatibility complex (self-MHC)-antigen restricted manner, and further that both NW-BM cells and Th cells had different and independent functions to induce CTL.     

Immunological properties of Fc receptor on lymphocytes. 5. Suppressive regulation of humoral immune response by Fc receptor bearing B lymphocytes.

High anti-DNP PFC responses to DNP-DE or DNP-KLH were obtained by transferring normal or primed FcR^? B cell fractions into irradiated syngeneic recipients. On the other hand, the FcR⁺ B cell fraction showed a low precursor activity. Trypsinization of the FcR⁺ B cells, to eliminate remaining antigen-antibody complexes on the surface, failed to augment the response in comparison with that of trypsin-untreated FcR⁺ B cells. Therefore, the weak precursor activity of FcR⁺ B cells seemed to be inherent. No synergistic interaction between the FcR⁺ B and precursor FcR^? B cells, to give rise to the maximum PFC response, was observed. On the contrary, the FcR⁺ B cells significantly suppressed the PFC responses of FcR^? B cells. This kind of suppression could be mediated by a factor released from the FcR⁺ B cell, but not from the FcR^? B or original-unrosetted spleen cell fraction. The factor was not attributable to macrophages, because the FcR⁺ B cells isolated from normal spleen cells, of which macrophages were depleted by Sephadex G-10 columns, could produce the factor with the same activity. Stimulation by specific antigen is not necessary for the induction of the factor(s) as well as of the suppressing FcR⁺ B cells. It seems to be necessary to stimulate FcR by antigen-antibody complexes to produce or release this factor.