The cell-mediated immune response to ectromelia virus infection. I. Kinetics and characteristics of the primary effector T cell response in vivo.

The cell-mediated immune (CMI) response to ectromelia virus infection in mice was studied. Virus doses from 4 × 10² up to 5 × 10⁴ PFU of an attenuated strain inoculated intravenously (iv) all induced cytotoxic T cell responses in the spleen as measured in a ⁵¹Cr release assay using virus-infected target cells. Higher virus doses gave larger responses. There was little variation between individual animals, and mice ranging in age from 4–22 weeks gave similar responses. Following iv infection, virus grew logarithmically in spleen for 2 days, then titers declined to undetectable levels by day 5. The peak of the virus-specific cytotoxic T cell response occurred at 5–6 days post-infection, as determined by calculation of effector units based on a linear log-log relationship between killer cells added and targets lysed. T cells responsible for virus clearance in vivo gave similar kinetics, suggesting the possibility that both functions are mediated by the same T cell subset. Two other categories of cytotoxic activity were also generated at low levels in the spleen during ectromelia infection or during infection with a bacterium, Listeria monocytogenes. These activities were significantly sensitive to anti-δ and complement treatment, suggesting T cell dependence, but participation of other mechanisms has not been rigorously excluded. One category lysed allogenic target cells and reached a peak at 4 days post-infection. The other lysed H-2-compatible cells, syngeneic embryo cells, and some syngeneic tumor cells but not syngeneic macrophages, and was present at similar low levels through days 1–4. These different kinetics and evidence from “cold” target competition experiments suggested that the total cytotoxic activity of immune spleen cell populations was a composite of the activities of separate cellular subsets (probably mainly T cells), killing of any one target cell type being the responsibility of a subset with receptors at least partly specific for antigens on that target cell.     

Mutations in H-2K b influence the specificity of alloreactive effector cells included in the repertoire of H-2D b -restricted cytotoxic T lymphocytes against Moloney leukemia virus

Moloney leukemia virus-specific cytotoxic T lymphocytes (CTL), generated by secondary in vitro stimulation of spleen cells with syngeneic virus-infected cells, frequently lysed not only syngeneic virus-infected cells, but also noninfected allogeneic target cells. This phenomenon was studied with B6(H-2 ^b ) responder cells and a series of H-2K ^b -mutant responder cells. Thus, B6 Moloney-specific CTL lysed noninfected K ^b -mutant cells, but not B6 cells, whereas K ^b -mutant Moloney-specific CTL lysed noninfected B6 cells and not noninfected cells of the same mutant. Cold-target-inhibition studies showed that the CTL reactions against different allogeneic cells were mediated by different subpopulations of virus-specific CTL: lysis of allogeneic target cells was fully inhibited only by the same allogeneic and by syngeneic virus-infected cells, but not by another allogeneic cell, also lysed by the same effector-cell population. Lysis of syngeneic virus-infected cells could not be inhibited by allogeneic target cells. These data imply that a minority of virus-specific CTL shows cross-reactivity with a given allogeneic target cell. It is concluded that limited amino acid substitutions in the K^b molecule alter the repertoire of Moloney virus-specific CTL, as reflected in alloreactive CTL populations, even though the virus-specific CTL response. of B6 and all K ^b mutants is mainly D^b-restricted. Thus, the development of tolerance to self class-I major histocompatibility complex (MHC) molecules affects the repertoire of self-restricted cytotoxic T cells.     

Virus-specific proliferative T-cell responses: Parameters and specificity

The genetic requirements for inducing virus-specific T-cell proliferation were investigated by taking spleen cells from animals primed with vaccinia virus in vivo, then culturing the cells in vitro with vaccinia virus-infected syngeneic peritoneal macrophages, and finally restimulating these cells a second time in vitro with vaccinia virus-infected macrophages from several strains of mice. Under these conditions, T cells proliferated in the tertiary response to virus-specific stimulation, whereas background proliferation caused by allogeneic differences between stimulator and responder cells was minimal. Compatibility between T cells and infected stimulator cells at the K or I regions alone or at I-A or I-A + I-B regions of the major histocompatibility complex (MHC) produced strong proliferative responses, whereas compatibility at D alone often resulted in somewhat weaker responses. However, these responses were rarely as great as in combinations of completely syngeneic stimulator and responder cells. Homology between responding and virus-infected stimulating cells in more than one of the H-2K, D, or I regions resulted in an additive, but not potentiating, effect. Genes coded outside the H-2 region did not seem to play a role in this system. In some rare cases, a weak response occurred across allogeneic barriers, but in general, virus-specific T-cell proliferation was strongly H-2 restricted.     

Immunologic recognition of influenza virus-infected cells. I. Generation of a virus-strain specific and a cross-reactive subpopulation of cytotoxic T cells in the response to type A influenza viruses of different subtypes.

Parenteral immunization of mice with a given strain of type A influenza virus generates two subpopulations of cytotoxic T cells in the in vivo primary response. One subpopulation is specific for the immunizing virus; the other subpopulation cross-reacts with target cells infected with type A influenza virus of a different subtype. Both subpopulations are specific for target cells infected with type A influenza virus and optimally lyse only infected targets which are syngeneic at the H-2 gene locus. In vitro stimulation of previously primed spleen cells with cells infected with homologous virus generates both subpopulations in the secondary cytotoxic response. However, in vitro stimulation of primed cells with cells infected with heterologous type A virus of a different subtype specifically selects for the cross-reactive T-cell population. These results are discussed in terms of current models for T-cell recognition of virus-infected cells and possible mechanisms for cross-reaction between type A influenza viruses of different subtypes at the level of cytotoxic T cells.     

Stimulatory cells in the generation of T-cell-mediated cytotoxicity: Potent stimulating activity of a small radioresistant spleen cell population (RSCs)

The combined effects of irradiation followed by cultivation on a total spleen cell population in order to study the evolution of the stimulating potential in the in vitro generation of allogeneic cytotoxic T lymphocytes (CTLs) were tested. Results revealed that, after 3 days and up to at least 7 days of cultivating irradiated (1000 rad) spleen cells, the remaining living cells (radioresistant spleen cells or RSC) have the same potential to generate CTLs as irradiated noncultivated spleen cells. RSC can resist a 5000-rad irradiation and induce a primary cytotoxic response pattern similar to that of total spleen cells; they act in primary as well as in secondary cultures with optimal responder to RSC ratios of about 100, but are still stimulatory at MLC ratios up to 1000 or 5000. They are lysed by specific allogeneic CTLs and readily inhibit the specific lysis of H-2-identical labeled targets by CTLs. RSCs do not express unusual levels of H-2 or Ia antigens and do stimulate purified T cells. Alloantisera anti-H-2 are able to completely block the RSC-induced generation of CTL. This RSC population may prove to be a good model to study non-H-2- or H-2-associated, nonserologically detectable determinants interacting in the generation of T-cell-mediated cytotoxicity.     

The cytotoxic T-cell response to H-1 minor histocompatibility antigen differences

H-1-specific cytotoxic T cells were generated in in vitro secondary cultures. Effectors were assayed on H-2 compatible, peritoneal exudate cell targets in a ⁵¹Cr release assay. Target-cell lysis appeared to be specific for the H-1 type of the stimulator cells. Effector cells were T cells since they expressed Thy 1.2 alloantigen and required H-2 compatibility between donors of the stimulator cells, responder cells, and target cells for efficient lysis. Peritoneal exudate cells were found to be efficient specific competitors in the cytotoxicity assay. There appeared to be no strict correlation between in vitro cytotoxic T-cell activity and mean skin graft rejection times for a number of minor H and H-2D differences.     

Transplantation antigen expression on murine trophoblast detection by induction of specific alloimmunity

Cell-mediated immune responses to murine embryonic trophoblast cells were investigated using lymphocyte trophoblast cultures (LTC) and cell-mediated lympholysis (CML). Spleen cells from CBA (H-2^k) or C57BL/6 (H-2^b) mice hyperimmunized with 3.5-day-old Balb/c (H-2^d) blastocysts did not undergo DNA synthesis after in vitro exposure to Balb/c blastocyst outgrowths nor were cytotoxic lymphocytes (CTL) generated against H-2^d alloantigens. Splenocytes from Balb/c mice presensitized with semiallogeneic (Balb/c female × C57BL/6 male) trophoblast cells derived from 17- to 20-day placental tissue expressed a weak proliferative response in the presence of semiallogeneic placental trophoblast and produced a moderate number of CTL against H-2^b (paternal strain) alloantigens when compared to mixed lymphocyte cultures (MLC) between Balb/c responder and semiallogeneic (stimulator) spleen cells. CTL were also generated in vitro after splenocytes from Balb/c mice hyperimmunized with semiallogeneic spleen cells were restimulated in vitro with placental trophoblast cells. These studies showing that early-stage trophoblast cells fail to evoke transplantation immunity and placental trophoblast is capable of generating alloimmunity only after combined in vivo hyperimmunization with in vitro restimulation suggest that these trophoblast cells are poorly immunogenic due in part to the relatively weak functional expression of major transplantation antigens.     

The cell-mediated immune response to ectromelia virus infection. Secondary response in vitro: specificity, nature of effector and responder cells and requirements for induction of antigenic changes in stimulator cells.

An in vitro culture method was used to study secondary cell-mediated responses to ectromelia virus infection in mice. Infected, syngeneic spleen cells or peritoneal cells were efficient "stimulator" cells when cultured with "responder" cells obtained from mice infected with ectromelia 4-6 weeks previously. The kinetics of generation of cytotoxic cells in cultures were determined; a peak occurred on days 4-5. A separation procedure performed on the cytotoxic cells showed that activity was associated mainly with the Ig-negative subpopulation (T cell-rich) and that H-2 compatibility between cytotoxic cells and target cells was required. The secondary response was virus-specific, at the level of both induction and target cell lysis, at least so far as ectromelia and lymphocytic choriomeningitis (LCM) viruses are concerned. Seperation of responder cells prior to culture showed that a potent secondary response was generated with the Ig-negative (T cell-rich) subpopulation and only a weak response was observed when the responder cells were Ig-positive (rich in B cells). Infected stimulator cells did not appear to secrete significant amounts of soluble antigen into the medium over 4 days of culture. Thus, antigenic patterns effective in memory T cell stimulation may be largely associated with the surfaces of infected cells.Pretreatment of ectromelia virus with UV- or gamma-irradiation did not impair its ability to induce antigenic changes in stimulator cells. Stimulator cells treated with UV-or gamma-irradiated virus for 1 h and then immediately with pactamycin to inhibit further viral protein synthesis and replication were efficient stimulators, thus indicating that antigenic changes are induced very rapidly on the surface of stimulator cells after uptake of virus. These treatments are being used to further characterize the cellular requirements in the stimulator population.     

Specificity or affinity of cytotoxic T cells for self H-2K determinants apparently does not change between primary and secondary responses to ectromelia virus infection.

Lysis of virus-infected target cells by virus-specific cytotoxic T cells occurs where donors of T cells and targets share either H-2K or H-2D genes. The effect of four H-2K mutations on virus-induced antigens recognized by cytotoxic T cells from in vitro secondary response to infection was studied. B10.A(5R) cytotoxic T cells (which share the K end of H-2 with the mutant strains, except for the mutated gene(s)) efficiently killed virus-infected macrophage targets from mutant strains B6-H-2bg1 and B6-H-2bg2, were less effective against B6-H-2bh and did not appear to be cytotoxic for B6.C-H-2ba target cells. Conversely, B6-H-Ibg1 and B6-H-2bg2 cytotoxic T cells were more effective in killing virus-infected B10.A(5R) macrophages than B6-H-2bh and B6.C-H-2ba cytotoxic cells respectively. In addition, B6-H-2bg1 and B6-H-2bg2 cells appeared to be only slightly different from wild-type with respect to the interaction between virus-infected cells and T cells. The data obtained suggested that virus-induced antigenic patterns on infected B6.C-H-2ba (mutant) cells are more different antigenically from those on wild-type cells than are those on infected cells from the other mutants, B6-H-2bh, B6-H-2bg1 and B6-H-2bh2. This agrees with previous data using primary cytotoxic T cells and thus suggests that no detectable change in the affinity or specificity of cytotoxic T cell receptors occurs between primary and secondary responses to infection. These findings are also discussed in relation to the exclusion of T cells with receptors for H-2K determinants that are common to the mutants and wild-type, from the response to virus-infected self cells.     

The requirement of Ia-positive accessory cells for the induction of tumor-specific cytotoxic T lymphocytes in vitro

The mechanism for the induction of cytotoxic T cells specific for tumor-associated antigens was studied by using fractionated responder T cells, tumor cells, and accessory cells in vitro. The tumor-specific cytotoxic T cells were induced by culturing immunized spleen cells with the tumor cells in vitro for 5 days. Nylon-column-purified T cells alone did not induce cytotoxic T cells upon culture with tumor cells, but the addition of normal spleen cells as accessory cells did successfully induce the cytotoxic T cells, suggesting that the presence of accessory cells is required for the activation of tumor-specific cytotoxic T cells in vitro. The accessory function was associated with spleen cell populations adhering to a plastic dish, a Sephadex G-10 column or a nylon wool column, and was sensitive to anti-Ia serum and C treatment, but was resistant to anti-Ig serum or anti-Thy 1 serum and C treatment, suggesting that the accessory cells are Ia-positive macrophages. Not only syngeneic but also allogeneic macrophages had the accessory function and the allogeneic macrophages were also Ia positive. These results suggest that Ia-positive macrophages play a crucial role in the induction of tumor-specific cytotoxic T cells in vitro. The possible role of Ia-positive accessory cells in the induction of tumor-specific cytotoxic T cells is discussed from the standpoint of cellular interactions.     

H-2-associated specificity of virus-immune cytotoxic T cells fromH-2 mutant and wild-type mice: M523 (H-2K ka ) and M505(H-2K bd ) do,M504 (H-2D da ) and M506(H-2K fa ) do not crossreact with wild-typeH-2K orH-2D

B10.A(3R) (H-2K ^b ) mice infected with lymphocytic choriomeningitis virus (LCMV) or vaccinia virus generate cytotoxic T cells capable of specifically lysing virus-infected macrophage target cells fromH-2K ^b mutant mice M505 (H-2K ^bd ), and vice versa. Similarly, virus-immune B10.A(4R) (H-2K ^k ) T cells specifically lyse infected targets from M523 (H-2K ^ka ), and vice versa. In contrast, virus-specific cytotoxic T cells from neither M504 (H-2D ^da ) and B10.A(5R) (H-2D ^d ) nor M506 (H-2K ^fa ) and B10.M(11R) (H-2K ^f ) mutually crossreact at the cytotoxic effector-cell level. As far as tested, the crossreactivity patterns between wild-type and mutantK orD specificities are identical for LCMV- and vaccinia virus-immune spleen cells. Although this finding is no proof for either the altered self nor the dual recognition concept of T-cell recognition, it may be compatible with the latter model.     

In vitro T-lymphocyte proliferative response to mouse thyroglobulin in experimental autoimmune thyroiditis

The in vitro lymphocyte proliferative response to mouse thyroglobulin (MTg) was studied in good and poor responder mice in relationship to in vivo antibody formation and thyroid infiltration. CBA(H-2^k) and BALB/c(H-2^d) mice were immunized in the hind footpads with MTg incorporated into complete Freund's adjuvant (CFA). At weekly intervals up to 28 days, groups of mice were sacrificed. Their popliteal lymph nodes were cultured in vitro for proliferative response to MTg and their antibody levels and thyroid involvement determined. In good responder CBA mice, the proliferative responses to MTg were strongest on Days 8 to 14, where they were 9- to 14-fold over control levels, depending on the day of harvest. The response declined to 2- to 4-fold over background on Days 21 to 28, although high antibody levels were present throughout this period. The proliferative response was abrogated by anti-Thy-1 treatment, indicating its dependence on T cells. In poor responder BALB/c mice, no significant proliferative responses to MTg were observed at any time, although the animals displayed moderate levels of MTg antibody. The responses to PPD, in contrast, were similar in both strains, usually being 4- to 7-fold above background. Thyroid infiltration, like the proliferative response to MTg, was observed only in CBA mice. Thus lymphocyte proliferation at 8 to 14 days represents a reliable, early in vitro correlate of autoimmune thyroiditis induced with CFA as adjuvant.     

H-2-linked genes determine the level of the primary in vitro anti-Mls response

The level of cell proliferation and interleukin-2 (IL-2) production observed in an anti-Mls mixed lymphocyte reaction between spleen cells from H-2 compatible, Mls incompatible mouse strains is determined by the H-2 haplotype of the mouse combination. Thus, while AKR (H-2 ^k) spleen cells stimulated strong M1s^a responses in H-2^k responder cells, AKR H-2b spleen cells stimulated no or negligible M1s^a responses in responder cells from H-2 ^bmouse strains. This effect was observed at the levels of IL-2 production and cell proliferation. The magnitude of the response observed using F₁ (H-2 ^k/H-2 ^b) responder cells was found to be a function of stimulator rather than responder cells. The poor stimulatory capacity of AKRH-2 ^bspleen cells was also shown not to be due to the loss of the stimulatory Mls ^aallele during the construction of the congenic strain from AKR and C57BL/6 parental strains. Using stimulator cells from a second series of congenic mice, we found H-2 ^b(strain DLLP) again to represent a poorly Mls^a stimulatory H-2 haplotype. In addition, H-2^q (DBA/1) cells displayed very poor Mls^a stimulatory potential while H-2^d (D1.C) cells were efficient Mls^a stimulators. Again the effect was shown to be at the level of the stimulator cells. In toto, our findings indicate that the H-2 ^kand H-2 ^dhaplotypes encode strong Mls^a stimulatory potential while the H-2 ^band H-2 ^qhaplotypes determine poor Mls^a stimulatory potential in primary in vitro responses, measured as cell proliferation and IL-2 production.Abbreviations used in this paper: CTL cytotoxic T lymphocyte - IL-1 interleukin-1 - IL-2 interleukin-2 - MLR mixed lymphocyte reaction - NMS normal mouse serum     

Murine T-cell hybridomas that produce lymphokine with macrophage-activating factor activity as a constitutive product

Responder spleen cells primed to alloantigens in vivo could generate high degree of cytotoxicity against low- or nonimmunogenic stimulators such as thymocytes or uv light-treated spleen cells in vitro. However, a removal of adherent cells from primed responder cells remarkably reduced the cytotoxicity after stimulation with such low-immunogenic stimulators. Adding a small number of peritoneal adherent cells (PACs) also suppressed the cytotoxic activity of unseparated responders against low-immunogenic stimulators. These suppressive effects by PACs were blocked by indomethacin. By adding prostaglandin E₂, cytotoxic T lymphocyte (CTL) generation of primed unseparated responders against low-immunogenic stimulators was suppressed; however, cytotoxic activity against mitomycin C-treated stimulators was not suppressed. These results suggested that prostaglandins released from PACs selectively inhibited the function of splenic adherent cells that were required for CTL generation of primed responder spleen cells against low-immunogenic stimulators in vitro.     

Enhancement by interferon of natural killer cell activity in mice.

Injection of mice with several interferon inducers, Newcastle Disease virus, polyinosinic-polycytidylic acid and tilorone resulted in an increase in spleen cell cytotoxicity for ⁵¹chromium-labeled mouse YAC tumor target cells in 4-hr in vitro assays. This increase in spleen cell cytotoxicity was abrogated by injection of mice with potent anti-mouse interferon globulin. Inoculation of mice with mouse interferon (but not human leucocyte or mock interferon preparations) also resulted in a marked enhancement of spleen cell cytotoxicity. The extent of enhancement of spleen cell cytotoxicity was directly proportional to the amount of interferon injected and a significant increase was observed after inoculation of as little as 10³ to 10⁴ units of interferon. An effect could be detected as soon as 1 hr after injection of interferon. The increase of spleen cell cytotoxicity after inoculation of an interferon inducer was not due to a localization and accumulation of cytotoxic cells in the spleen but reflected a general increase in cytotoxic cell activity in various lymphoid tissues (except the thymus). The splenic cytotoxic cells from interferon or interferon-inducer-injected mice had the characteristics of natural killer (NK) cells since (i) interferon enhanced spleen cell cytotoxicity in athymic (nu/nu) nude mice, (ii) classical spleen cell fractionation procedures by nylon wool columns, anti-Thy 1.2 serum plus complement, anti-Ig columns, and depletion of FcR+ rosette-forming cells, failed to remove the effector cells generated in vivo or in vitro. Therefore like NK cells, interferon-induced cytotoxic cells lack the surface markers of mature T and B lymphocytes, are not adherent, and are devoid of avid Fc receptors. Furthermore like NK cells, the spleen cells from interferon-treated mice lysed various target cells (known for their sensitivity to NK cells) without H-2 or species restriction. Incubation in vitro of normal spleen cells with interferon also resulted in an increase in cytotoxicity for YAC tumor cells. We conclude that interferon acts directly on NK cells and enhances the inherent cytotoxic activity of these cells.     

Role of the H-2I region in the generation of an antiviral cytotoxic T-cell response in vitro

The participation of H-2I gene products in generating virus-specific proliferative and/or cytotoxic T-lymphocyte (CTL) responses was investigated. Spleen cells from mice infected with vaccinia virus were restimulated secondarily in vitro with syngeneic virus-infected peritoneal exudate cells (PEC) and then restimulated in tertiary cultures with virus-infected PEC from syngeneic and partially histoincompatible strains of mice. Based on the finding that comparable proliferative responses resulted when stimulating the responding cells were histocompatible at the H-2K, I, or D region of the major histocompatibility complex (MHC), the additively enhanced, but not potentiated, proliferation caused by identity at two or three H-2 regions was analyzed. Enhancement of proliferation followed when the H-2K/D components plus virus and the H-2I components plus virus were either on the same, or alternatively on two, stimulating cells. This suggests that H-2K, D, and I plus virus trigger distinct T-cell subsets. A virus-specific CTL response was generated in vitro when spleen cells from virus-primed mice and even unprimed mice were stimulated with cells sharing only H-2K and/or H-2D of the MHC. Identity at the H-2I region did not stimulate a CTL response, nor did it influence the magnitude of the $\text{K}\text{D}$ restricted response. Nevertheless, the presence of anti-Ia antiserum in cultures of syngeneic stimulators and responders inhibited the cytotoxic response to a great extent. Therefore, H-2I region products seem to participate in the generation of virus-specific CTL in vitro.     

Suppressive Effect by Cooperation of Splenic and Peritoneal Adherent Cells on Generation of Cytotoxic T Lymphocytes

When spleen cells primed in vivo against allogeneic lymphoid cells were used as responder cells in secondary mixed lymphocyte cultures, a high degree of cytotoxicity was generated even in the absence of splenic adherent cells. However, removal of adherent cells from such primed responder spleen cells reduced the cytotoxicity to some extent. On the other hand, when these responder cells were transferred into the peritoneal cavity of irradiated syngeneic mice together with antigenic cells, unseparated responder cells generated a lower degree of cytotoxicity than did adherent cell-depleted responder cells. In an in vitro system, peritoneal adherent cells also suppressed the generation of cytotoxic T lymphocytes by unseparated responders; however they augmented the cytotoxic T lymphocyte generation by adherent cell-depleted responders. These adherent cell populations with augmenting activity became inhibitory when they coexisted. The mechanism of this inhibitory action remains unclear.     

Functional significance of the Fc receptor on mixed lymphocyte culture-activated T blasts.

Fc receptor (FcR)-carrying blast cells were separated from nonFcR blast cells after priming in primary mixed lymphocyte culture (MLC) by erythrocyte-antibody rosetting and by 1-g velocity sedimentation. Both types of blast cells were cytotoxic to relevant allogeneic target cells in vitro. The FcR-positive and FcR-negative blasts were then plated on a feeder layer syngeneic to the primary MLC responder cells. After feeder layer culture both types of cells reverted into secondary small lymphocytes. When restimulated with the original stimulator cells, both types of secondary lymphocytes produced the relevant secondary cell-mediated lysis responses. Thus no functionally dissimilar subclasses of secondary T lymphocytes can be distinguished in the MLC-stimulated T-cell population on the basis of the FcR.     

Cytotoxic T-cell responses to H-Y:Ir genes and associative antigens map inH-2

The secondary cytotoxic responses to the male-specific antigen (H-Y) in mice showH-2 restriction so that the cytotoxic female cell must share the K- and/or D-end antigen with the male target cells. The association with the K and/or D end varies with differentH-2 haplotypes,e.g., H-2 ^b cytotoxic cells require the H-2D^b antigen(s) on the target cells, while cytotoxic cells fromH-2 ^b/H-2 ^d F₁ mice sensitized toH-2 ^d male cells kill only male targets having H-2K^d antigen(s). This association of H-Y with appropriate K/D antigens seems to be needed also in the induction of the cytotoxic response. Of the independent haplotypes, onlyH-2 ^b strains are capable of making secondary anti-H-Y responses and this trait seems to be dominant,i.e., the F₁ strains with oneH-2 ^b parent are able to produce anti-H-Y cytotoxic cells against both theH-2 ^b parent and the nonresponder parent. The mating of the two nonresponder strains may produce F₁ mice which are responders, thus suggestingIr gene complementation. Mapping data indicates that at least one of these complementary genes is located in theI-C region fork/s complementation.     

Trypanosoma cruzi: Responses by cells from infected mice to alloantigens

In unidirectional mixed lymphocyte cultures containing (as responders, stimulators, or regulators) spleen cells from mice infected with Trypanosoma cruzi, alloantigen responses were less than in cultures containing normal spleen cells only. Depletion of plastic adherent cells from infected spleen cells (stimulators or regulators) reversed their inhibitory effect on normal spleen cells (responders); removal of adherent responder cells and/or B lymphocytes did not alter the low alloantigen responses of normal spleen cells (stimulated by infected spleen cells) or infected spleen cells (stimulated by normal spleen cells). Infected spleen cells were effective in regulating mixed lymphocyte cultures only when added at the initiation of the culture. Serum from infected mice suppressed mixed lymphocyte cultures containing responder spleen cells syngeneic to the serum donor if added up to 24 hr after initiation of cultures, whereas the “suppressor serum” had to be present at the initiation of cultures when responder cells were allogeneic to the serum donor. Cultures of infected spleen cells (whole or macrophage enriched) produced a factor which was suppressive when added to mixed lymphocyte cultures containing syngeneic responder cells at initiation. It is proposed that the serum suppressor substance regulates cell-mediated immune responses directly by suppressing the response-potential of cells and indirectly by triggering the release of a factor from adherent splenic cells which induces a hyporesponsive state in T lymphocytes.