Sheep red blood cell-specific helper activity in rat thoracic duct lymphocyte populations positively selected for reactivity to specific strong histocompatibility alloantigens

Anti H-2Dd alloreactivity mediated by herpes-simplex-virus specific cytotoxic H-2k T lymphocytes is associated with H-2Dk

Herpes-simplex-virus (HSV) specific, H-2k-restricted, immune cytotoxic T lymphocytes also lyse noninfected H-2d target cells. Genetic mapping studies revealed that HSV-specific Dk-restricted CTL cross-react with allogeneic targets expressing Dd alloantigens. Cold target inhibition experiments indicate that only a minority of HSV-specific CTL mediate cross-reactive cytolysis. The data give an example of where the phenomenon of H-2-restricted versus nonrestricted responsiveness is not due to distinct subsets of T cells but solely depends on the antigenic determinants recognized.

In vivo responses of alloreactive lymphocytes stimulated in vitro. Helper-cell activity of MLR-primed lymphocytes

Populations of mouse lymphocytes enriched in specific alloreactive cells by priming in a mixed lymphocyte response (MLR) include cells which, when injected into congenic nude mice, enable them to make alloantibody after immunization. Helper cells for the priming H-2 alloantigens (H-2b or H-2k) were enriched relative to helper cells for the other H-2 type. Furthermore, the alloantibody responses of nude mice reconstituted with lymphocytes primed twice in vitro were virtually monospecific for the priming alloantigens. These studies suggest that lymphocytes that proliferate in MLR include lymphocytes capable of giving specific help for H-2 antigens in vivo. Nude mice reconstituted with MLR-primed lymphocytes made less antibody to bacteriophage T4 and phix than mice reconstituted with unprimed cells, and fewer mice responded. Priming of cells a second time in MLR further depleted the population of phage helper cells. Similar results were sometimes, but not always, obtained when testing reconstituted nude mice for their ability to make anti-sheep erythrocyte (SRBC) responses. These results suggest that lymphocytes primed against H-2b or H-2k alloantigens do not have specificity for antigens of T4 or phix. These alloreactive cells may also lack specificity for SRBC. However, the results do not allow a definitive conclusion to be drawn.

The IE allogeneic response of T cells from C57Bl/6 mice is associated with genes in the TCRa locus

It has been demonstrated that induction of immune responses, infectious diseases and autoimmune manifestations can be associated with at least four gene loci: the major histocompatibility complex (MHC) locus; the immunoglobulin (Ig) heavy chain (Hc) locus; and the T-cell receptor (TCR) TCR-alpha or TCR-beta chain loci. In the present study, we have analysed whether T-cell responses of IE-negative C57Bl/6 (B6) mice to IE alloantigen (IE alpha transgenic B6 mice = B6.E alpha 16) or to trinitrophenylated (TNP) syngeneic spleen cells were influenced by changes in the Ig-Hc locus or the TCRa locus. Whereas the fine specificity of T-cell responses to IE alloantigen was the same in B6 mice and in Ig-Hc congenic B6.26a or TCRa congenic B6.10TCa mice, the latter strain of mice demonstrated much higher IE-specific T-cell responses against B6.E alpha 16 spleen cells than B6 or B6.26a mice. This high responsiveness was a dominant feature and associated with the TCRa locus. In addition, the TCRV alpha or V beta repertoire of the congenic strains of mice was polyclonal and very similar. The TNP-specific T-cell responses of B6 and B6.10TCa mice showed the same restricted TCRV alpha and V beta repertoire. It is concluded that in both an oligoclonal T-cell response (anti-TNP) and a polyclonal T-cell response (anti-IE), exchange of Ig-Hc or TCRa loci does not significantly influence the TCRV alpha or V beta repertoire in IE-negative C57Bl/6 mice.

Involvement of I-J epitopes in the self- and allo-recognition sites of T cells: blocking of syngeneic and allogeneic mixed lymphocyte reaction-responder cells by monoclonal anti-I-J antibodies

Monoclonal anti-I-Jk antibodies (mAbs) were found to inhibit syngeneic and allogeneic mixed lymphocyte reactions by blocking the responder T cells but not the stimulator cells. Only the responses of H-2k and H-2a strains were inhibited. Three different anti-I-Jk mAbs (1G8, 4B11, and KN34) showed different inhibitory patterns in allogeneic mixed lymphocyte reactions of individual H-2k strains, depending on the H-2 and immunoglobulin heavy chain variable region (IgVH) genes possessed by the stimulator strains. The results indicated that I-J epitopes are involved in the self- and allo-recognition sites of T cells, which are clonally distributed and used to recognize Ia plus IgVH-linked products.

HLA-DR-4-associated alloreactivity of an HLA-DR-3-restricted human tetanus toxoid-specific T cell clone: inhibition of both reactivities by an alloantiserum

We present here the first report of a human helper/inducer T cell clone (F6) that specifically recognizes tetanus toxoid (TT) in the context of self-major histocompatibility complex (MHC) determinant(s) (HLA-DR3), and in addition recognizes a specific but unrelated MHC determinant(s) in the absence of conventional antigen. Extensive subcloning insured that the cells were progeny of a single cell. Furthermore, removal of the cells proliferating to the alloantigen with bromodeoxyuridine and light removed cells responding to both TT plus self-MHC and to the stimulating alloantigen, again indicating that F6 was the progeny of a single cell. The alloantigen recognized by this TT-specific clone appears to be closely linked to HLA-DR4 since cells from 13 of 14 HLA-DR4+ donors stimulated F6. An antiserum which recognizes HLA-DR4, when added to cultures, blocked the alloreactivity of F6, and in addition blocked its proliferation to TT plus HLA-DR3. Absorption of this antiserum with HLA-DR4+ cells or with TT-pulsed HLA-DR3+ cells removed its capacity to inhibit the proliferation of F6. These results suggest that the antigen recognition unit on F6 is stimulated both by allodeterminants expressed on HLA-DR4 cells and by TT plus HLA-DR3. These moieties cross-react at the T cell recognition level as well as at the antibody level.

Functional characterization of human alloreactive T cell clones

We have investigated the functional activity of alloreactive T cell clones, generated by limiting dilutions of MLC blasts. Clones displaying helper, suppressor, or cytotoxic functions (against Class I or Class II HLA antigens) were identified, using proliferative, 51Cr-release, and hemolytique-plaque induction assays. To determine whether functionally distinct clones share determinants that trigger the AMLC reaction we have tested the capacity of selected clones to cross-stimulate each other in secondary AMLC. Our data suggest that AMLC stimulatory determinants are related to common structure antigens of the T cell receptor for alloantigen, since helper clones, for example, (TLC #19) can induce memory responses to suppressor (TLC #209) as well as cytotoxic (TLC #207) clones and vice versa. The AMLC system seems well suited for studying network regulations within the T cell compartment.

Specificity of T cell clones for antigen and autologous major histocompatibility complex products determines specificity for foreign major histocompatibility complex products

We have analyzed a panel of T cell clones that corecognize defined epitopes of the insulin molecule in association with Ia for their patterns of recognition of alloantigens. A striking correlation is observed between recognition of the I-Ab gene product and cow insulin alpha loop and recognition of I-Eu of the PL/J haplotype. These results are consistent with the notion that reactions to foreign major histocompatibility complex (MHC) products reflect molecular mimicry by foreign class II antigens of 'physiologic' complexes formed by autologous class II MHC molecules and antigen.

Mutations in H-2Kb influence the specificity of alloreactive effector cells included in the repertoire of H-2Db-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-2b) responder cells and a series of H-2Kb-mutant responder cells. Thus, B6 Moloney-specific CTL lysed noninfected Kb-mutant cells, but not B6 cells, whereas Kb-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 Kb 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 Kb mutants is mainly Db-restricted. Thus, the development of tolerance to self class-I major histocompatibility complex (MHC) molecules affects the repertoire of self-restricted cytotoxic T cells.

Interactions between MHC-encoded products and cloned T-cells. I. Fine specificity of induction of proliferation and lysis

To study the interactions between T cells and class I MHC products, we developed in vitro a T-cell line reactive to H-2Kb stimulating cells and derived T-cell clones from it. Although the T-cell line could proliferate in the absence of exogeneous T-cell growth factors when stimulated with H-2Kb spleen cells, each of the derived T-cell clones required both H-2Kb stimulating cells and an external source of T-cell growth factor for its propagation. Each of the T-cell clones was also cytolytic for H-2Kb target cells. Such T-cell clones allowed the comparison of the antigenic requirements for proliferation and cytolysis. By using H-2Kb mutant mice, we found that while the original anti-H-2Kb T-cell line reacted with each of the six mutants tested, the individual T-cell clones could be distinguished in terms of their reactivity pattern. Similar fine specificity patterns were found when H-2Kb mutant cells were used as stimulating or target cells for any given T-cell clone. Each of the three monoclonal H-2Kb-specific antibodies reacting with different epitopes of the H-2Kb molecule totally inhibited H-2Kb-induced proliferation and lysis by the T-cell clones. Further blocking studies involved use of Fab antibody fragments and definition of their reactivity on cells from the H-2Kb mutants. We concluded that: (1) blocking with a monoclonal antibody does not prove identity of alloantigens recognized by the T-cells and the antibody; (2) a monoclonal antibody could either block or not block H-2Kb-CTL interactions depending on structural variations of the H-2Kb molecule not affecting the CTL-H-2Kb functional interaction; (3) blocking one type of H-2Kb-T-cell interaction (induction of proliferation) always affects the other type (cytolysis).

Simultaneous expression of H-2-restricted and alloreactive recognition by a cloned line of influenza virus-specific cytotoxic T lymphocytes

Based on theoretical considerations and several types of experimental evidence with heterogeneous cell populations it has been proposed that alloreactive T cells and major histocompatibility complex (MHC)-restricted T cells directed to foreign non-NHC antigens represent overlapping subsets. In this report we provide direct evidence for this hypothesis at the clonal level. We have isolated a cloned continuous influenza virus-specific cytotoxic T cell (CTL) line derived from a single (H-2b X H-2d)F1 CTL precursor which simultaneously exhibits H-2-restricted cytotoxicity of influenza A/Japan/305/57 virus in association with H-2Kd and alloreactive cytotoxicity for H-2Kk alloantigen. Cold target inhibition data demonstrate that both MHC-restricted and alloreactive recognition is mediated by the same cell population. In addition to cross-reactivity at the target cell level, we shown that this cloned CTL line can be specifically stimulated to proliferate either by A/Japan/305/57 virus-infected cells expressing H-2Kd or by uninfected cells of the H-2Kk haplotype.

Antigen-inducible, H-2-restricted, interleukin-2-producing T cell hybridomas. Lack of independent antigen and H-2 recognition

We developed a method for production of antigen-specific, H-2-restricted T cell hybrids. The tumor cell partner in the fusions was itself a T cell hybrid, FS6-14.13.AG2 (or its derivatives), which could be induced to produce the growth factor, interleukin-2 (IL-2), in response to a challenge with concanavalin A, but had no known antigen specificity. The normal T cell partner in the fusions was a population of lymph node T cell blasts that had been highly enriched in antigen-specific, H-2-restricted T cells by in vivo immunization, followed by in vitro challenge with antigen and clonal expansion in IL-2-containing medium. These fusions produced hybrids that grew constitutively in culture. A sizable proportion of the hybrids demonstrated the ability to produce IL-2 in response to a challenge with specific antigen presented by irradiated spleen cells of the appropriate H-2 type. Four cloned antigen/H-2-specific hybrid lines were produced. AO-40.10 responded to chicken ovalbumin (OVA) when presented by I-A(k)-bearing cells. DC1.18.3 responded to the apo form of beef cytochrome c when presented with I-A(d). AODK-10.4 responded to keyhole limpet hemocyanin (KLH) presented with I-A (d). AODK-1.16 also responded to KLH presented by a product of the I region of H-2(d), but the data were consistent with either a product of the I-J-I-E(d) region or a combinatorial molecule with elements from both I-A(d) and I-E(d)/I-C(d). Coincidentally, AO-40.10 was shown to have an unexpected alloreactivity with a product of H-2(b) mapping to the K-I-A region. These hybrids should prove invaluable as sources of monoclonal material for the study of the receptor(s) on T cells with H-2-restricted antigen specificities. We also generated T cell hybrids with two antigen/H-2 specificities by fusing an azaguanine-resistant clone of AO-40.10 to normal T cells with a different antigen/H-2 specificity. Many of the hybrids retained reactivity to OVA plus H-2(a) and to the second antigen/H-2 combination. None reacted to either OVA plus the second H-2 type or to the second antigen plus H-2(a). One of these hybrids was successfully cloned to produce the line AOFK- 11.11.1. It retained the ability to recognize OVA plus I-A(k) inherited from one parent, and KLH plus IA(f) inherited from the other. It did not recognize OVA plus IA(f) or KLH plus I-A(k). These results have some bearing on models describing the nature of T cell receptors for antigen recognized in association with H-2 products. They do not support models in which antigen and H-2 are recognized separately by two independent T cell receptors.

Selected populations of alloreactive T cells contain helper T cells but lack ThId, an antigen-specific helper T cell required for dominant production of the T15 idiotype

Isolated, alloreactive T cell populations were primed with protein carriers in vivo and tested for their ability to provide help for an anti-phosphorylcholine (PC) antibody response and for production of the T15 idiotype. It was found that alloreactive T cell populations would support anti-PC antibody response but did not selectively activate B cells capable of producing the T15 idiotype that normally dominates such responses. This failure to help for the production of the T15 idiotype was shown to be due to the absence of an antigen-specific helper T cell that is required for dominant idiotype production (ThId). These studies suggest that ThId cells have recognition structures for antigen and for self idiotype, but lack recognition structures for major histocompatibility complex-encoded antigens.

Quantitative studies on T cell diversity. I. Determination of the precursor frequencies for two types of streptococcus A-specific helper cells in nonimmune, polyclonally activated splenic T cells

A limiting-dilution system is described that makes use of T cell growth factor T cell expansion and allows the determination of precursor frequencies for various regulatory and effector T cells in nonimmune, polyclonally, or specifically activated T cell populations. Two different sets, a frequent and a rare set, of T helper cell precursors with specificity for trinitrophenyl-group A streptococcal vaccine, could be identified: the frequent set is of the Lyt-123 phenotype, and is present at frequencies of from 1/1,000 to 1/6,000 splenic T cells. It is only active at low cell numbers, whereas it is completely inactivated at greater cell numbers, presumably by suppressor T cells of lower frequency but greater potency. The rare set is of the Lyt-1 phenotype, is present at frequencies of from 1/10,000 to 1/70,000, and is not sensitive to suppressor cells present within the tested cell numbers. We suggest that the frequent set contains primiary helper cell precursors, whereas the rare set contains helper T memory cells preselected by previous exposure to other antigens. The results are discussed with respect to other reports on the involvement of more than one set of helper cells in antibody production.

Idiotypes, T-cell receptors, and T-B cooperation

T cells are responsible for virtually all the characteristics of the mammalian immune system except the production of serum antibody, in which they play a vital regulatory role. As such, they are central to our understanding of the immune system. T cells recognize cell-bound antigens with great precision, in association with self MHC antigens. They do this by means of antigen-specific receptors, whose antigen-combining sites are encoded in conventional VH genes. There is evidence that T cells carry at least two kinds of specific receptors, one for MHC antigens and one for non-MHC antigens. Both of these would bear VH-encoded and distinct idiotypic determinants. The process by which antigens associate with MHC-gene products on cell surfaces is poorly understood at present, and so is the process by which the two types of receptors communicate with each other. T cells are divisible into a number of subpopulations playing unique functional roles in the regulation of antibody responses. If one examines them further for other functions, even greater complexity emerges. Thus, all T cells may not have the same kind of receptor, which would not be surprising given the wide variety of functions they perform. Future work will undoubtedly focus on these important questions.

The receptor specificity of alloreactive T cells. Distinction between stimulator K, I, and D region products and degeneracy of third-party H-2 recognition by low-affinity T cells

The specificity of binding of stimulator-derived H-2 antigens by mixed lymphocyte culture (MLC)-activated T blasts was investigated under conditions of antigen excess. We have shown that the detectable proportion of alloantigen-binding blasts from primary MLC is a function of antigen concentration, and can represent up to more than 90 percent of total blasts, when the antigen is presented in the appropriate form (on mitomycin-treated viable stimulator cells, or membrane vesicles prepared from lipopolysaccharide blasts), and at nonlimiting concentration. Thus stimulator alloantigen-binding directly parallels the proliferative response and is not restricted to a subpopulation of T blasts. However, the marked dependence of the binding on antigen concentration indicates that cells with a wide range of receptor affinities for the stimulating determinants are involved. In view of this possibility, the specificity of binding by these cells was studied. We have demonstrated that stimulator K, I, and D region products are bound by nonoverlapping subpopulations of blasts, the sum of which may represent 93 percent of total blasts. Thus, specific distinction by these cells between different H-2 region products is not affected by the putative heterogeneity in terms of receptor affinities. However, specificity with respect to unrelated H-2 haplotypes is strictly dependent on antigen concentration. A preferential binding of stimulator membrane vesicles occurs at limiting concentrations; whereas the majority of blasts bind stimulator and third- party vesicles equally well at high vesicle concentrations. The binding of both vesicle types is specific in that it can be inhibited with the relevant anti-H-2 sera. Furthermore, stimulator and third-party vesicles seem to compete for binding sites on the same cells, as shown by cold antigen inhibition. From these results, we propose that there is an imperfect distinction between stimulator and third-party H-2 antigens by the majority of primary MLC blasts. In contrast, highly selected long-term MLC blasts do not bind third-party H-2 antigens at any concentration, and seem to have high affinity for the stimulating antigens. We conclude that large numbers of clones with low-affinity (cross- reactive) receptors are generated in primary MLC, most of which become eliminated during long-term selection. This implies that the frequency of cells strictly specific for nonshared stimulating determinants must be minute.

Recognition of antigens by T lymphocytes

The present review briefly summarizes our knowledge of antigen-specific B and T lymphocyte receptors. Antigen-specific receptors on mammalian B lymphocytes are mainly monomeric IgM and IgD consisting of conventional immunoglobulin heavy and light chains. The nature of the T lymphocyte receptor which can specifically recognize antigens is not yet fully defined. However, it seems that conventional light chains do not participate in the build up of this receptor, and that the receptor is made up of heavy chains of a new immunoglobulin class which has to be further characterized and which we call Tau-chain. The variable region of the T lymphocyte receptors share idiotypic determinants with the corresponding B lymphocyte receptors. The possible linkage between the T cell idiotypes present on the Tau-chains and molecules which are under the control of genes of the Major Histocompatibility Complex of the species are discussed. In the last part of the review two methods for the induction of specific transplantation tolerance in adult animals are described. These methods are based on the concept that T lymphocytes reactive against alloantigens bear idiotypic determinants against which a specific auto-immune response can be initiated.

The primary immune response of patients with different stages of squamous-cell bronchial carcinoma

Using the indirect ELISA technique, the IgM, IgG, and IgA antibody response to the primary test immunogen Helix pomatia haemocyanin (HPH) was studied in 30 patients with various clinical stages of primary squamous-cell bronchial carcinoma and compared with values obtained in 15 controls matched for sex, age, smoking habit, and presence of chronic bronchitis. Patients with disseminated disease (stage III) showed a significant decrease in IgG and IgA antibody response (P less than 0.001), but IgM antibodies were relatively high and not different from the controls. Although normal IgG and IgA antibody titres were found at the peak response two weeks after immunisation in patients with localised disease (stage I), these antibody titres showed a significantly more rapid decline after serial investigations at eight and 14 weeks after immunisation compared with the controls (P less than 0.001) despite total removal of the tumour burden at c four weeks after immunisation. In-vitro HPH-induced lymphocyte transformation was considerably decreased in state I patients (P less than 0.01) as well as in stage III patients (P less than 0.001). The results suggest that patients with squamous-cell bronchial carcinoma develop impaired T-cell function, which gives rise to a defective antibody response and in-vitro lymphocyte reactivity to the T-cell dependent primary immunogen HPH.

T cells specific for hapten-modified self are precommitted for self major histocompatibility complex antigens before encounter with the hapten

The technique of antigen-driven, 5-bromo-deoxyuridine and light suicide has been adapted to eliminate the precursors of cytotoxic effector cells both for alloantigen and for 2,4,6-trinitrophenyl(TNP)-modified stimulator and target cells. Using this technique, the following observations have been made. Precursors of killer cells specific for alloantigen can be suicided independently of precursors of killer cells specific for TNP-modified self cells. The loss of activity during this procedure is not due to either specific or nonspecific suppressor cells, as judged by mixing experiments. With responder cells from F1 animals, it has been possible to show that precursors specific for TNP-modified cells from one parent are suicided independently of precursors specific for TNP-modified cells of the other parent, but only if the parental strains differ in the K and D regions of the H-2 complex. Cells of F1 mice derived from K and D identical, I region different, parental strains were specifically suicided by TNP-modified stimulator cells from either parent. However, the cross-reactive killing of TNP-self targets induced by stimulation with allogeneic cells is not eliminated by first suiciding with TNP-parental cells, suggesting that the precursors of these two types of TNP-self killer cells are different. This is compatible with reported differences in their specificity, as confirmed in this report. Finally, deletion of alloreactive cells by this technique reveals little or no reactivity specific for TNP-modified allogeneic stimulator cells. In summary, these results strongly suggest that recognition of self MHC antigens is preprogrammed in peripheral T cells of normal animals, and is not acquired during the immunization process. They also suggest that cells specific for modified alloantigen are relatively rare in the strains of mice studied.

Specificity of helper T cells for different antigens

BALB/c nude mice have been injected with 10(6) congenic thymus cells, a number which allows some, but not all mice to respond to any particular T-dependent antigen. These mice have been tested for their ability to respond to three bacteriophages, T4, T7 and phiX, sheep and horse erythrocytes, and alloantigens of C3H and C57BL/6 mice. The number of mice able to respond to each of these antigens was of the same order of magnitude. Sheep and horse erythrocytes showed cross-reactivity at the T cell level, i.e. the responses to these two antigens were not independent. The same was observed for C3H and C57BL/6. Otherwise, the responses were independent showing that the antigens are recognize by different populations of specific helper T cells.

Failure of T cells specific for strong histocompatibility antigens to cooperate with B cells for a humoral response

Thymus-derived lymphocytes (T cells) selected for reactivity to strong histocompatibility antigens over a period of one to twelve months in vitro were tested for their ability to cooperate with bone marrow-derived lymphocytes (B cells) for a humoral response. If cultured with normal syngeneic or allogeneic spleen cells and sheep erythrocytes (SRBC) as immunogen, inhibition of the anti-SRBC response was observed. Similarly, in T cell-free spleen cells the alloreactive T cells did not stimulate a humoral response, indicating that they cannot exert cooperative activity on B cells. Since it was possible that the alloreactive T cells may cooperate with B cells in a humoral response to immunogens carrying histocompatibility antigens, hapten-coupled tumor cells were also used as immunogen. Though it is demonstrated that the alloreactive T cells do recognize the tumor cell immunogen, no stimulation of the B cells for a humoral response against the tumor cell is observed. This result, as well as the finding that the antigenic requirements for T helper cell priming and cell proliferation of the alloreactive T cells are different, suggests that these alloreactive T cells and helper T cells belong to different T cell subsets.

Killer cells reactive to altered-self antigens can also be alloreactive

Murine cytotoxic thymus-derived lymphocytes immunized against cells bearing foreign minor histocompatibility antigens are specific for the immunizing minor antigens and for their own major H-2 antigens; they do not lyse target cells that bear the correct minor antigens plus a different H-2 haplotype. These are referred to as "altered-self" or "self-plus-X" killer cells. Alloreactive killer cells are those which respond to allogeneic cells expressing a foreign (non-self) H-2 haplotype. In this study, cytotoxic lymphocytes were immunized against minor histocompatibility differences in vivo and in vitro. These effector cells killed the immunizing altered-self target very well and showed about 1% cross-reactive lysis of an allogeneic target differing from themselves only at H-2. These cross-reactive clones were then selected for by repeated in vitro stimulation with the cells bearing foreign H-2 such that an effector population was obtained which lysed both the altered-self and the alloreactive target with the same efficiency. Cold target competition experiments established that the same killer cell could lyse either target; however, it was not determined if a killer cell uses the same receptor to respond to altered-self antigens as it does respond to foreign H-2 antigens.

Functional specificity of thymus- dependent lymphocytes

Thymus-dependent lymphocytes display a restricted range of specificity when compared to thymus-independent (B) lymphocytes. They react particularly to thymus-dependent protein and cell surface antigens and to products of genes encoded in the MHC. In addition, T lymphocytes have important functions in regulating the immune response and in discriminating of self from nonself. Recent work indicates that individual T lymphocytes possess receptors that interact with both thymus-dependent antigens and MHC gene products, either independently or as associated structures. We attempt to relate this complex specificity pattern to the regulatory and surveillance functions of T lymphocytes.

Regulation by the H-2 gene complex of macrophage-lymphoid cell interactions in secondary antibody responses in vitro

The ability of antigen-bearing syngeneic and allogeneic peptone-induced peritoneal exudate macrophages to support development of primary and secondary antibody responses by murine lymphoid or spleen cells in vitro has been investigated. The antigen used was the terpolymer of L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT). Syngeneic and allogeneic macrophages supported development of comparable primary antibody responses to GAT, indicating that genetic restrictions do not limit efficient macrophage-lymphocyte interactions in primary responses. By contrast, immunized spleen or lymphoid cells developed secondary antibody responses preferentially when stimulated in vitro with GAT on macrophages syngeneic to the macrophages used to present GAT during in vivo immunization. Thus, genetic restrictions regulate efficient macrophage-lymphocyte interactions in secondary antibody responses. These restrictions have been demonstrated from 2 to 8 wk after a single immunization with limiting quantities of GAT and are controlled by the H-2 gene complex. The implications that immune lymphocytes selectively recognize and respond to antigen presented in the context of the macrophage membrane-antigen complex which sensitized the lymphocytes initially are considered.