The Lyt phenotype of a long-term allospecific T cell line. Both helper and killer activities to IA are mediated by Ly-1 cells

CD4+ Cytotoxic T cells - Phenotype, Function and Transcriptional Networks Controlling Their Differentiation Pathways

The two major subsets of peripheral T cells are classically divided into the CD4⁺ T helper cells and the cytotoxic CD8⁺ T cell lineage. However, the appearance of some effector CD4⁺ T cell populations displaying cytotoxic activity, in particular during viral infections, has been observed, thus breaking the functional dichotomy of CD4⁺ and CD8⁺ T lymphocytes. The strong association of the appearance of CD4⁺ cytotoxic T lymphocytes (CD4 CTLs) with viral infections suggests an important role of this subset in antiviral immunity by controlling viral replication and infection. Moreover, CD4 CTLs have been linked with anti-tumor activity and might also cause immunopathology in autoimmune diseases. This raises interest into the molecular mechanisms regulating CD4 CTL differentiation, which are poorly understood in comparison to differentiation pathways of other Th subsets. In this review, we provide a brief overview about key features of CD4 CTLs, including their role in viral infections and cancer immunity, and about the link between CD4 CTLs and immune-mediated diseases. Subsequently, we will discuss the current knowledge about transcriptional and epigenetic networks controlling CD4 CTL differentiation and highlight recent data suggesting a role for histone deacetylases in the generation of CD4 CTLs.

Cytotoxic CD4 T Cells-Friend or Foe during Viral Infection?

CD4 T cells with cytotoxic function were once thought to be an artifact due to long-term in vitro cultures but have in more recent years become accepted and reported in the literature in response to a number of viral infections. In this review, we focus on cytotoxic CD4 T cells in the context of human viral infections and in some infections that affect mice and non-human primates. We examine the effector mechanisms used by cytotoxic CD4 cells, the phenotypes that describe this population, and the transcription factors and pathways that lead to their induction following infection. We further consider the cells that are the predominant targets of this effector subset and describe the viral infections in which CD4 cytotoxic T lymphocytes have been shown to play a protective or pathologic role. Cytotoxic CD4 T cells are detected in the circulation at much higher levels than previously realized and are now recognized to have an important role in the immune response to viral infections.

The Differentiation and Protective Function of Cytolytic CD4 T Cells in Influenza Infection

CD4 T cells that recognize peptide antigen in the context of class II MHC can differentiate into various subsets that are characterized by their helper functions. However, increasing evidence indicates that CD4 cells with direct cytolytic activity (CD4 CTL) play a role in chronic as well as acute infections, such as influenza A virus (IAV) infection. In the last couple of decades, techniques to measure the frequency and activity of these cytolytic cells has demonstrated their abundance in infections, such as human immunodeficiency virus, mouse pox, murine gamma herpes virus, cytomegalovirus, Epstein-Barr virus, and influenza among others. We now appreciate a greater role for CD4 CTL as direct effectors in viral infections and antitumor immunity through their ability to acquire perforin-mediated cytolytic activity and contribution to lysis of virally infected targets or tumors. As early as the 1980s, CD4 T cell clones with cytolytic potential were identified after influenza virus infection, yet much of this early work was dependent on in vitro culture and little was known about the physiological relevance of CD4 CTL. Here, we discuss the direct role CD4 CTL play in protection against lethal IAV infection and the factors that drive the generation of perforin-mediated lytic activity in CD4 cells in vivo during IAV infection. While focusing on CD4 CTL generated during IAV infection, we pull comparisons from the literature in other antiviral and antitumor systems. Further, we highlight what is currently known about CD4 CTL secondary and memory responses, as well as vaccination strategies to induce these potent killer cells that provide an extra layer of cell-mediated immune protection against heterosubtypic IAV infection.

Molecular and cellular mechanisms regulating T and B cell apoptosis through Fas/FasL interaction

Fas (CD95) and Fas ligand (FasL) are a receptor/ligand pair critically involved in lymphocyte homeostasis and peripheral tolerance such that genetic defect in either Fas or FasL results in an autoimmune lymphoproliferative syndrome. Fas is a type I transmembrane protein and a member of the tumor necrosis factor receptor (TNFR) family whereas FasL is a type II transmembrane protein and a member of TNF family. Binding of Fas by FasL induces apoptosis of the Fas-expressing cells. In the past few years, Fas/FasL interaction has been connected to a series of important phenomena previously viewed as independent immune processes. The activation-induced T cell death (AICD) and the FasL-mediated cytotoxicity by activated T cells are two critical mechanisms that can account for most of these phenomena. It is in the context of the two mechanisms that we discuss in this review the molecular and cellular events that occur during T/T and T/B interactions that account for the down-regulation of the immune response. We have also discussed recent advances in the areas of FasL gene regulation, lymphokine regulation of AICD, and regulation of B cell susceptibility to FasL. Investigation in these areas should help elucidate the role of Fas/FasL in the complex network of regulatory mechanisms that control immune response and autoimmunity.

The immunomodulatory role of CD4-positive cytotoxic T-lymphocytes in health and disease

Among the CD4-positive (CD4+) T-lymphocytes a population exists which expresses cytolytic activity. These 'killer' cells belong to the T helper type 1 (Th1) subset and if activated, express Fas-ligand (FasL) which induces apoptosis in Fas-positive target cells. The major targets of these CD4+ cytotoxic T-lymphocytes (CTL) are cells of the immune system, such as T, B cells and macrophages which express Fas upon activation. Thus, CD4+ CTL play a major immunoregulatory part through the elimination of activated myeloid and lymphoid cells during and upon completion of an immune response. In certain diseases, such as in HIV-infection and some autoimmune disorders, the functional activity of CD4+ CTL is disturbed preferentially at the level of FasL-Fas interaction, further emphasizing their important immunoregulatory role. Furthermore, Fas-ligand expressing tumors can evade the attack of Fas-positive CD4+ CTL and other effector cells, thereby giving them an opportunity to expand.

Mechanism and biological significance of CD4-mediated cytotoxicity

It is now well established that CD4+ T cells can express cytotoxic activity. This type of cell-mediated cytotoxicity is associated with the Th1-, but not with the Th2-phenotype. While the activation of CD4+ CTL is MHC class II-restricted, the effector phase, i.e. the target cell killing is unrestricted and antigen non-specific. In analogy to CD8+ CTL, CD4-mediated target cell death is by DNA fragmentation. However, the molecular mechanism of killing differs from CD8-mediated lysis. Thus, CD4+ CTL preferentially lyse their targets via Fas-Fas ligand interaction, whereas the major cytotoxic effect of CD8+ CTL is by granule exocytosis, i.e. perforin and granzymes. Although CD8+ CTL can also express the FasL, their lytic activity through interaction with Fas is of less importance. Likewise, some CD4+ CTL may also kill by perforin/granzymes activity, but this pathway is of minor significance. The aims of CD8- or CD4-mediated lysis are also different. Thus, the major task of CD8+ CTL which recognize and kill their targets in the context of MHC class I molecules, is the lysis of virally infected cells and battling against tumor cells. CD4+ CTL, on the other hand, have an immunomodulatory role. Thus, they preferentially eliminate activated MHC class II-positive cells, i.e. APC, be they monocytes/macrophages, B cells or T cells. They may lyse these cells in order to prevent an overreaction of the ongoing immune response or in order to remove potentially hazardous cells upon completion of the immune response. The Fas-FasL pathway is particularly suitable for this task as myeloid or lymphoid cells express Fas only if activated, while FasL is preferentially expressed on activated CD4+ Th1 cells. Moreover, activated T cells eliminate themselves by the Fas-mediated pathway. Whether this happens by fratricide only, or also by suicide or both is open. Moreover, CD4+ CTL are particularly suitable for killing tumor cells as well, as they are efficient effectors in bystander lysis in contrast to CD8+ CTL. On the other hand, the non-specific killing via Fas-FasL interaction, which is an important reason for the bystander lysis, may have unwanted effects in that cells which should not be eliminated could be killed. Such reactions affecting various organs and cells, e.g. the liver, thyroid or islet cells of the pancreas could be an explanation for certain autoimmune diseases.

Cytolytic T lymphocytes: an overview of their characteristics

Cloned T cells have been useful for assessing the lytic potential of distinct T cell subsets and for determining the relative contribution of different effector mechanism involved in the lytic process. Alloreactive CD8+ murine T cell clones and cloned murine CD4+ TH1 and TH2 T cells reactive with nominal antigen (ovalbumin) lysed nucleated target cells bearing antigen or coated with anti-CD3 monoclonal antibody in a short term 51Cr-release assay. These clones were also evaluated for their ability to lyse efficiently sheep erythrocyte (SRBC) target cells coated with anti-CD3 mAb by a mechanism (presumably involving membrane damage) that does not involve nuclear degradation. Three patterns of lysis were observed: CD8+ and some CD4+ TH2 effector cells lysed efficiently nucleated target cells and anucleated SRBC coated with anti-CD3 mAb. However, CD4+ TH1 (and a few TH2) T cells which lysed nucleated target cells bearing antigen or coated with anti-CD3 mAb did not lyse efficiently the SRBC coated with anti-CD3 mAb. One CD4 bearing TH2 cell failed to lyse efficiently either nucleated target cells or anucleated SRBC coated with anti-CD3 mAb. These results indicate that both TH1 and TH2 clones have lytic capabilities. Furthermore, they suggest that some but not all TH2 murine T cell clones have lytic characteristics similar to those of conventional CD8+ CTL. However, it is not certain how these patterns of lysis of target cells in vitro relates to the capacity of CTL to lyse such target cells in vivo.

The acquisition and maintenance of cytolytic activity by CD4+ murine T-lymphocyte clones

The class II MHC antigen-specific CTL clones described in this report lose lytic activity when grown in exogenous rIL-2, but regain lytic activity when rIL-2 is removed from the culture medium. Using this cell model, we have investigated the metabolic activities (i.e., DNA, RNA, and protein synthesis) required for CTL to acquire or down-regulate lytic activity. DNA synthesis inhibitors (hydroxyurea and cytosine-arabinoside) and irradiation did not prevent CTL from gaining lytic activity. However, when protein or RNA synthesis was inhibited, these CTL could no longer acquire lytic activity. Furthermore, evidence showed that continuous RNA and protein syntheses were essential for CTL to exert their lytic function. Studies on cell surface antigen expression of CD3, CD4, Thy-1, and LFA-1 revealed no significant difference of antigen expression between a cloned CTL in its lytic and nonlytic states. Our data suggested that the synthesis of certain proteins and their encoded mRNA are essential for CTL to exert its lytic function and these proteins are not the cell surface antigens involved in CTL-target recognition or binding. Data also indicated that a granule enzyme, serine-esterase, was not involved in the expression of lytic activity in these CTL clones.

Evidence for an involvement of T4+ cytotoxic T cells in tumor immunity

Cell-mediated immunity against cancer cells primarily involves class I major histocompatibility complex (MHC)-restricted cytotoxic T cells and natural killer (NK) cells. To investigate whether T4+ cytotoxic T cells also have a role in tumor-specific immunity, mice were immunized with a B cell lymphoma. T cell hybridomas were constructed from the immune spleen cells and analyzed for their cytotoxic ability against the immunizing lymphoma. A T4+, Lyt-1+ hybridoma cell line was developed (103L2) which specifically killed the immunizing tumor cells but not normal B cells or a range of other tumor cells of B or non-B origin. This cytotoxic hybridoma cell line differed from Lyt-2+ cytotoxic T lymphocyte cells and NK cells, commonly identified with cytotoxicity, in a number of important ways. First, the cells were class II MHC restricted; second, interleukin-2 was released from activated effector cells; and finally but most importantly, innocent nonparticipating bystander cells were also killed. The significance of this observation was that normal cells were protected, although a broad range of tumor cell types, including tumor antigen-negative mutants, were killed. It is therefore conceivable that T4+ cytotoxic T cells might play an important role in tumor immunity through the direct recognition and lysis of tumor cells while any tumor variants, arising due to antigen loss, would remain susceptible through the bystander killing effect and normal cells would remain unaffected. These results strongly suggest that tumor-reactive T4+ cytotoxic T cells belong to a new category of effector cells with an important role in tumor-specific immunity.

A comparison of the cytolytic properties of murine primary CD8+ cytotoxic T lymphocytes and cloned cytotoxic T cell lines

Lysates of many highly cytolytic murine primary CD8+ cytotoxic T lymphocytes (CTLs) have no detectable hemolytic activity and only traces of serine esterase activity, indicating a striking paucity or absence of the perforin-rich secretory granules that are abundant in the cytoplasm of murine cloned CTL cell lines. Nevertheless, the primary CTLs are almost as resistant to granule-mediated lysis as CTL cell lines. Moreover, target cells that are lysed by all CTLs so far tested, whether primary or cell lines, show similar rapid and marked increases in intracellular calcium and breakdown of DNA into nucleosome-sized fragments. A parsimonious explanation for all of these findings is that primary CTLs, like the CTL cell lines, exercise their cytolytic activity by means of perforin, but the amounts needed are extremely small and below the level of detection by the current relatively insensitive hemolytic assays.

Class II antigen-specific murine cytolytic T lymphocytes (CTL). I. Analysis of bulk populations and establishment of Lyt-2+L3T4- and Lyt-2-L3T4+ bulk CTL lines

Murine allogeneic cytolytic T lymphocytes (CTLs), including long-term bulk CTL lines, were induced in I-region-incompatible combinations of strains in vitro in order to study the phenotypes of class II major histocompatibility complex (MHC) antigen-specific CTLs, as well as the possible functional involvement of accessory cell interaction molecules such as Lyt-2 and L3T4. This report shows that class II-specific allogeneic CTL populations consist of two types of T cells. Lyt-2+L3T4- (2+4-) and Lyt-2-L3T4+ (2-4+), in variable proportions depending on the strain combination, that in vitro bulk CTL lines with each of these phenotypes can be established, that the killing function of 2-4+ CTL is sensitive to the blocking effect of anti-L3T4 antibodies, suggesting functional involvement of this molecule in the CTL-target interaction, that anti-Lyt-2 antibodies fail to block killing by 2+4- cells, suggesting that such CTLs do not utilize this molecule in their killing function, and that while I-A-specific CTLs of both phenotypes are detectable, 2-4+ cells could not be detected among I-E-specific CTL populations.

The influence of HLA-A,B and -DR matching on leucocyte infiltration in renal allografts

The influence of donor and recipient HLA-A,B and -DR matching on the cellular infiltration in renal allografts was examined in 78 transplant recipients who received either cyclosporin (Cy) or azathioprine and low-dose prednisolone (AP) immunosuppression. Transplant biopsies (n = 161) were routinely obtained up to 40 days after transplantation, and biopsy material was therefore available from both rejecting grafts and grafts with stable function. Tissue sections were labelled with a panel of monoclonal antibodies and stained using an indirect immunoperoxidase technique. Cellular infiltration was assessed using a morphometric point counting technique. In AP-treated patients with well-functioning grafts, poor HLA-AB and HLA-DR matching was associated with increased leucocyte infiltration, while in patients receiving Cy therapy the effect of matching on cellular infiltration was seen only during rejection in grafts poorly matched for HLA-AB antigens. In addition, where an effect of HLA-AB matching on cellular infiltration was found, CD8+, but not CD4+ cells, were significantly increased in number, while when an HLA-DR matching effect was seen, a significant increase was observed in the CD4+ and not the CD8+ infiltration. Thus, HLA matching may influence the magnitude of the cellular response in renal allografts and the phenotype of the infiltrating cells.

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

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

Fusion as a mediator of cytolysis in mixtures of uninfected CD4+ lymphocytes and cells infected by human immunodeficiency virus

We describe an unusual type of cytopathology in which uninfected CD4+ (helper/inducer) cells (cells expressing the human leukocyte antigen CD4) interact with cells persistently infected with the human immunodeficiency virus (HIV). Prior antigenic stimulation was not required, since CD4+ cells taken either from healthy persons without anti-HIV antibodies or from individuals with anti-HIV antibodies were capable of inducing cytolysis. Neither CD8+ (suppressor/cytotoxic) nor CD16+ (natural killer) cells mediated the reaction. Light microscopic and autoradiographic studies revealed that, prior to cytolysis, multinucleated giant cells were formed from fusions between HIV-infected cells and large numbers of uninfected CD4+ lymphocytes. These data may explain the paradox that exists in vivo in which a dramatic depletion of CD4+ lymphocytes occurs in the presence of a small number of HIV-infected CD4+ cells. These new insights into the pathogenesis of acquired immunodeficiency syndrome (AIDS) may lead to future therapeutic strategies.

Inducer T-cell-mediated killing of antigen-presenting cells

L3T4+ inducer/helper T-cell clones, once activated by antigen-presenting cells (APC) expressing the appropriate Ia allele and antigen, autonomously kill their target APC. All 13 L3T4+ inducer T-cell clones tested demonstrated this cytolytic activity. In addition, 11 different target cells representing the three major APC types, namely, macrophages, B cells, and dendritic cells, were all sensitive to this cytolytic activity. Moreover, normal macrophages which were treated with interferon-gamma to increase Ia expression were also killed. These observations convincingly demonstrate that the cytolytic activity of L3T4+ inducer T-cell clones is a general phenomenon. In contrast to other reports, lysis of target APC could not be detected following 4-6 hr of incubation. Marginal lysis was observed after 9 hr and a 20-hr incubation period was required to achieve maximal killing. The kinetics of killing paralleled other parameters of T-cell activation such as IL-2 release and cell proliferation. Activation of T cells for cytolysis of APC requires the interaction of T-cell receptors with Ia and antigen. Monoclonal antibody to Ia, L3T4 and the T-cell receptor inhibited the cytolysis of APC. The ability to mediate nonspecific bystander killing was variable depending on both the T-cell clone and the target. The implications of these findings to immune regulation and autoimmunity are discussed.

Role of L3T4 antigen in the activation of various functions of Lyt-1+2- T cells against vaccinia virus

The present study defines assay systems for vaccinia virus-reactive Lyt-1+2- T cells mediating various functions and investigates the positivity of L3T4 antigen on these Lyt-1+2- T cells as well as the role of L3T4 antigen in the activation of these T cells with respect to their functions. C3H/He mice were immunized against vaccinia virus by inoculating viable virus intraperitoneally (i.p.). Anti-vaccinia virus reactivity in lymphoid cells from these immunized mice was assessed by proliferative response, helper T cell activities involved in cytotoxic T lymphocyte (CTL) and B cell (antibody) responses, delayed type-hypersensitivity (DTH) response, and production of lymphokines such as interleukin 2 (IL2) and macrophage-activating factor (MAF). The results demonstrate that all of the above anti-vaccinia virus responses were mediated by Lyt-1+2- T cells and that these Lyt-1+2- T cells expressed L3T4 antigens on their cell surfaces. Moreover, such anti-vaccinia Lyt-1+2- T cell responses were inhibited in the presence of anti-L3T4 antigen antibody. These results indicate that there is a reciprocal relationship between Lyt-2 and L3T4 markers, and that L3T4 antigen is closely related to the activation of various functions of anti-vaccinia virus Lyt-1+2- T cells.

Cloning of a cDNA for a T cell-specific serine protease from a cytotoxic T lymphocyte

A new serine protease was encoded by a clone isolated from a murine cytotoxic T-lymphocyte complementary DNA library by an RNA-hybridization competition protocol. Complementary transcripts were detected in cytotoxic T lymphocytes, spleen cells from nude mice, a rat natural killer cell leukemia, and in two of eight T-helper clones (both cytotoxic), but not in normal mouse kidney, liver, spleen, or thymus, nor in several tested T- and B-cell tumors. T-cell activation with concanavalin A plus interleukin-2 induced spleen cells to express this gene with kinetics correlating with the acquisition of cytolytic capacity. The nucleotide sequence of this gene encoded an amino acid sequence of approximately 25,700 daltons, with 25 to 35 percent identity to members of the serine protease family. The active site "charge-relay" residues (His57, Asp102, and Ser195 of the chymotrypsin numbering system) are conserved, as well as the trypsin-specific Asp (position 189 in trypsin). A Southern blot analysis indicated that this gene is conserved in humans, mouse, and chicken. This serine protease may have a role in lymphocyte lysis and a "lytic cascade."

In vivo effects of GK1.5 (anti-L3T4a) monoclonal antibody on induction and expression of delayed-type hypersensitivity

The in vivo effects of monoclonal GK1.5 antibody, directed against the L3T4a determinant expressed on Class II-restricted T cells, on the induction and expression of murine delayed-type hypersensitivity (DTH) responses were examined. Development and expression of both hapten (2,4-dinitrofluorobenzene and 2,4,6-trinitrochlorobenzene)- and protein antigen poly(Glu60Ala30Tyr10)-specific DTH are significantly inhibited by injection of monoclonal anti-L3T4a antibody. The inhibitory effects of anti-L3T4a were most pronounced when administered during the afferent (induction) phase of the DTH response, leading to the functional inhibition of the generation of both polyclonal lymph node T-proliferative cells (Tprlf) and DTH effector cells (TDH). The in vivo inhibitory effect is apparently unrelated to preferential induction of suppressor T cells as GK1.5 inhibited DTH induction in cyclophosphamide-treated as well as normal recipients. L3T4a expression on the various T-cell subsets involved in DTH induction and elicitation was also examined. The data show that three functionally distinct, antigen-specific T-cell subsets, Tprlf, TDH, and Th cells involved in DTH induction, bear the Lyt 1+2-, L3T4+ phenotype. Possible mechanisms where in vivo injection of anti-L3T4a inhibits Class II-restricted T-cell subsets involved in DTH induction and expression, including immune depletion and inhibition of T-cell-receptor/ligand interactions, are discussed.

Cloned helper T cells can kill B lymphoma cells in the presence of specific antigen: Ia restriction and cognate vs. noncognate interactions in cytolysis

Cloned, Lyt-1+,2-, antigen-specific, Ia-restricted T cell lines can inhibit the growth of Ia-bearing B lymphoma cells in the presence of specific antigen. This effect is due to cytolysis of the B lymphoma cells in an antigen-specific, Ia-restricted manner by the cloned T cell lines. These cloned T cell lines can also kill lipopolysaccharide-activated normal B cells, while they activate resting B cells to divide and secrete immunoglobulin and are thus helper T cells as well as cytolytic T cells. The mechanism of cytolysis was examined in detail. Killing was mediated by a nonspecific mechanism after specific stimulation of the T cells with antigen presented in the context of the appropriate Ia glycoprotein complex, possibly implying a role for a soluble mediator. This simple system involving two clonal populations allows a detailed analysis of T-B interactions. Our studies are consistent with the view that both cognate and noncognate interactions of Ia-restricted T cells with B cells are mediated by nonspecific factors. Thus, the difference between interactions that appear to be cognate and those that appear to be noncognate may be quantitative rather than qualitative. That two cloned populations of cells can show either pattern of interaction depending on T-B ratio provides strong support for this view. Finally, that cloned helper T cells can kill activated B cells in an antigen-specific fashion may provide a new mechanism of immune regulation that would be especially important in responses to self antigens in vivo.

Cell surface structures involved in T cell activation

We have discussed four specific models which provide different kinds of information about the requirements for T cell activation. The first utilized a CTL clone designated L3, which is reactive specifically with Ld alloantigen, to study the involvement of the associative recognition structure Lyt-2 in cytolysis. The apparent requirements for activation of this CTL clone differ depending on whether the target cells bear specific alloantigen or are hybridoma cells which express on their cell surface a clonotypic antibody which reacts specifically with the L3 T cell receptor for antigen. When the antigen receptor reacts with alloantigen on the allogeneic target cell, cytolysis is inhibited by anti-Lyt-2 antibody. However, when the clonotypic antibody of the target cell reacts with the antigen receptor of the T cell, cytolysis is much less inhibited by anti-Lyt-2 antibody. The antigen receptor seems to be responsible for the specificity of both these interactions but the avidity of the interaction between CTL and target cell seems to differ in the two situations. Evidence that participation of the L3T4 associative recognition structure on HTL is less important for cloned T cells which have higher affinity antigen receptors was provided by the second model system which used cloned HTL selected for optimal responses to different concentrations of nominal antigen. Proliferative responses of those clones which responded to lower antigen concentrations were less readily inhibited by anti-L3T4 mAb. Evidence provided by these two model systems is consistent with the concept that associative recognition structures are of lesser importance for T cell activation for those T cells which have higher affinity antigen receptors. In the third model system, we have identified several monoclonal antibodies which augment proliferative response of cloned T cells to sub-optimal amounts of IL-2, probably by reacting with the antigen receptor or with the associated Leu-4/T3 structure. The reactivity patterns of these antibodies indicate that several different epitopes are being recognized. Some appear to be clonotypic although they do not block functional activity of the clone with which they react. Others react with all T clones which we have tested. Several of these react with a cell surface antigen which is expressed at about the same level as the clonotypic structures: these antibodies may react with the murine equivalent of the human Leu-4/T3 molecular complex. One of the "pan-T cell" antibodies which augments IL-2-induced T cell proliferation appears to react with Thy-1; this antibody is similar to one described recently by Gunter et al. (1984).(ABSTRACT TRUNCATED AT 400 WORDS)

The phenotype of antigen-specific suppressor T cells generated in human mixed leucocyte culture depends on the nature of the major histocompatibility regions recognized

Following secondary stimulation of mixed leucocyte culture (MLC) populations with a class I plus II HLA difference, antigen-specific suppressor-effector cells of the OKT8+4- phenotype are generated. On the other hand, stimulation with a class II HLA genetic difference only gave rise to OKT4+ suppressor T cells. These effector cell populations which were maintained as "lines" by the addition of exogenous T cell growth factor (TCGF) and feeder cells, mediated antigen-specific suppression over a 6-8 week period during which they were assayed. The data reported here demonstrate that the phenotype of suppressor cells, generated in allogenic MLC, depends on the nature of the class of HLA antigen recognized as disparities in the suppressor-generating MLC. Moreover, both OKT8+4- and OKT4+ suppressors, obtained following stimulation with class I plus II or class II genetic disparities, respectively, appear to be specific for DR (or related class II product) antigens.

Surface markers of cytotoxic T lymphocyte clones

Several class II major histocompatibility complex antigen-specific murine cytolytic T cell clones express Lyt-2 but not MT4 surface antigens.

HLA class-II-specific T-lymphocyte clones with dual alloreactive functions

The relationship between T lymphocytes that proliferate in response to HLA class II antigens and those that mediate the cytotoxic response toward HLA class II target antigens was investigated. Alloreactive T-cell clones were derived under conditions in which the likelihood of clonality was high. Three populations of HLA class-II-specific T cells were identified. Two of these populations exhibited only HLA class-II-directed cytotoxicity or HLA class-II-induced proliferation. The third population of T cells exhibited both of these responses.

Possible involvement of the T4 molecule in T cell recognition of class II HLA antigens. Evidence from studies of CTL-target cell binding

The present study examines the potential role of the T4 molecule in functional cell-cell interactions between target cells and human cytotoxic T lymphocyte (CTL) clones that are specific for HLA class II alloantigens encoded by the SB locus. There were marked differences (greater than 30-fold) between the seven SB-specific clones studied with respect to their susceptibility to inhibition by anti-T4 as well as anti-T3 antibodies. We wished to test the hypothesis that such variation among the clones would be due to differences in clonal "affinity" for antigen. To quantitate differences among the CTL clones in the tightness with which they bind target cells, the clones were analyzed using a previously published assay of susceptibility of CTL-target cell conjugates to dissociation in the presence of unlabeled targets. The results revealed that the clones that were most susceptible to inhibition by anti-T4 and anti-T3 were the weakest target cell binders, and vice versa. Anti-T4 antibody could partially induce dissociation of functional CTL-target cell conjugates in the absence of any added cold targets. For the "highest affinity" clone such anti-T4 antibody-induced dissociation could be observed at 4 degrees C but not 23 degrees C. These results indicate that the T4 molecule is functionally involved in target cell binding by CTL, and raise the possibility that although it is easiest to demonstrate the function of the T4 molecule in "low affinity" clones, that function may also be operative in the "high affinity" clones.

Distinct epitopes on the T8 molecule are differentially involved in cytotoxic T cell function

The present report attempts to determine if there are distinct epitopes on the T8 molecule that are involved in class I-restricted cytotoxic T lymphocyte (CTL) function. A panel of 9 monoclonal antibodies (OKT8A,B,C,E,F,G,H,I, and OKT5) was produced and all antibodies were shown to bind to the T8 molecule. This panel of antibodies was employed to characterize the distribution of distinct epitopes on the T8 molecule and to block the activity of class I-specific influenza virus-immune and allo-immune CTL effector function. Significant differences in the ability of the anti-T8 antibodies to block CTL function were observed: OKT8C and T8F blocked best (49 and 55% respectively); OKT8A,E,G,H,I, and OKT5 blocked less well (24-31%); and OKT8B blocked marginally (11%). There was no correlation between the capacity of the antibodies to block CTL function and their heavy chain isotype. Competitive binding of the different OKT8 antibodies to the cell surface and differential trypsin sensitivity of the epitopes recognized by the antibodies indicated that OKT8C and T8F were located on topographically distinct regions of the T8 molecule. These results indicate that specific epitopes on the T8 molecule are involved in CTL function, and that there could be more than one functional site on the molecule.

Monoclonal anti-Lyt-2.2 antibody blocks lectin-dependent cellular cytotoxicity of H-2-negative target cells

The hypothesis that blocking of cytotoxic T lymphocyte (CTL)-mediated cytolysis with anti-Lyt-2 antibodies acts at the level of inhibiting the interaction of the Lyt-2-bearing structure with H-2 class I molecules was tested. In agreement with the findings of others, purified anti-Lyt-2.2 inhibited both antigen-specific lysis and lectin-dependent cellular cytotoxicity (LDCC). LDCC of H-2-positive and H-2-negative target cells was similarly inhibited by this antibody. As expected, this effect was specific for CTL expressing the Lyt-2.2 allele, in contrast to blocking with a rat monoclonal antibody to the murine LFA-1 antigen. The implications of this finding for the function of the Lyt-2 antigen in CTL-target cell interaction are discussed.

Production of alpha-lymphotoxin by human T-cell subsets

Human T cells were isolated from peripheral blood lymphocytes (PBL) and sensitized to allogeneic PBL in a one-way mixed-lymphocyte culture. These sensitized T cells were fractionated on the basis of their possession of Fc receptors for IgG (TG+) or IgM (TM+), or the absence of both IgG and IgM receptors (TG-M-). When restimulated with alloantigen of the same derivation, TG+, TM+, and TG-M- cells yielded almost equal amounts of cytotoxin. Anti-alpha-lymphotoxin serum neutralized most of this cytotoxic activity indicating that alpha-lymphotoxin (alpha-LT) constituted most of this activity. Although TG-M- cells function as effectors in allogeneic cytotoxicity, TG+ cells lyse IgG-coated targets in an antibody-dependent cell-mediated cytotoxic (ADCC) reaction, which has been shown to be mediated in part by alpha-LT. Whether TM+ cells can be cytotoxic is not clear. In addition, freshly isolated human T-cell subsets were stimulated with phytohemagglutinin-P (PHA-P). After PHA stimulation, TG+, TM+, and TG-M- cells produced similar amounts of soluble cytotoxin, which was largely neutralized by anti-alpha-LT. The TG+ cells incorporated less thymidine than the TM+ or TG-M- cells. Likewise, OKT4+ and OKT8+ subsets, isolated with the aid of monoclonal OKT8 or OKT4 antibody and complement, yielded lymphotoxin after stimulation with PHA. It is shown that all T-cell subsets, as defined here, can produce lymphotoxin. Furthermore, depending on the assay system, cytotoxicity can be clearly demonstrated in all of these subsets, except in TM+ cells, where positive and negative results have been reported.

Cloned LYT-2+ cytolytic T lymphocytes destroy allogeneic tissue in vivo

The long-accepted notion that alloimmune cytolytic T cells (CTL) mediate transplantation immunity has recently been called into question. In order to ascertain directly whether alloimmune CTL can mediate destruction of foreign tissue, we tested the ability of mouse CTL expanded as cloned populations in vitro to destroy allogeneic skin in vivo. The results of these studies prove unequivocally that cloned Lyt-2+ CTL can perform this task in an immunologically specific, H-2-restricted, and dose-dependent fashion.

Relationship between human T cell functional heterogeneity and human T cell surface molecules

Our knowledge of human T cell differentiation and function has expotentially increased during recent years. With this growth in knowledge there has been an increase in our appreciation of the complexity of the T-T interactions which initiate and control immune responses. A great deal remains to be learned concerning the mechanisms of these complex cellular interactions. In particular, it will be important to precisely understand the clear heterogeneity of functions within isolated subsets of OKT4+ and OKT8+ T cells. Perhaps, as importantly, it will be necessary to define more clearly the functions of the T4 and T8 molecules as well as the precise function of the other defined glycoproteins on the T cell surface. The evidence is clearly emerging that many of those molecules are not solely markers of unique functional subsets and are intimately involved in the functions of T cells.

The human T cell receptor: analysis with cytotoxic T cell clones

Employing human T lymphocyte clones and monoclonal antibodies to their surface glycoproteins, the antigen receptors on these cells have been defined. Based on functional and biochemical data, it is shown that each T cell displays two major recognition units on its surface. One structure consists of the antigen-binding region (Tin-T3) which views antigen X in the context of a polymorphic region of an MHC molecule. A second (T8 or T4) serves as an associative recognition structure for a constant region of the class I or class II molecule. The antigen-binding structure is a heterodimer of disulfide linked 49KD and 43KD subunits, which contains clonally unique variable regions. These are non-covalently associated with the 20/25KD monomorphic T3 molecule expressed on all mature human T lymphocytes. The associative-recognition element on an individual clone is either T8 or T4, depending on its subset derivation. It is likely that these glycoproteins bind to constant regions of class I or class II molecules, respectively, and are independent of the Tin-T3 complex complex.

T cell subsets and the recognition of MHC class

We have presented and/or briefly reviewed data which indicates that there are two T cell subsets which interact respectively with the two Classes (1 and 2) of MHC antigen and which can be identified by the Ly (mouse) or Leu (human) molecules that they express. This correlation, and the large body of (largely) circumstantial but still quite convincing data, suggests that these Ly and Leu molecules play a very important role in T cell responses by actually interacting with monomorphic MHC class specific determinants. We suggest that this interaction facilitates and possibly helps direct the binding of the T cell receptor to polymorphic MHC determinants and antigen. In this model T cell "recognition" of MHC and antigen consists of several independent but connected interactions of T cell surface structure with MHC molecules and antigen on antigen-presenting cells or targets.

Characterization of the murine antigenic determinant, designated L3T4a, recognized by monoclonal antibody GK1.5: expression of L3T4a by functional T cell clones appears to correlate primarily with class II MHC antigen-reactivity

We describe here the properties of mAb GK1.5, which recognizes a cell surface molecule designated L3T4; the determinant on L3T4 recognized by mAb GK1.5 is designated L3T4a. We present evidence here that: i) the expression of L3T4a by murine T cell clones correlates primarily with class II MHC antigen-reactivity; ii) mAb GK1.5 blocks all class II MHC antigen-specific functions (cytolysis, proliferation, release of lymphokines) by murine class II MHC antigen-reactive T cell clones, although there appears to be clonal heterogeneity in the degree to which these functions are blocked by mAb GK1.5; iii) mAb GK1.5 blocks class II MHC antigen-specific release of IL-2 from cloned T cell hybridomas by blocking class II MHC antigen-specific binding; and iv) L3T4 is very similar to the human Leu3/T4 antigen. The properties of mAb GK1.5 (complement fixation, reactivity with all mouse strains tested, profound blocking of all class II MHC antigen-specific functions by murine T cells, usefulness for FACS analyses, and usefulness for immuno-precipitation/SDS-PAGE analyses) make it suitable for investigating both the role of class II MHC antigen-reactive T cells in various immunological phenomena and the mechanistic basis, at the molecular level, of class II MHC antigen-reactivity by murine T cells.

Human T cell clones allospecific for HLA-DR5 antigen with the OKT8 phenotype

Human allospecific T-lymphocyte clones reactive in the primed lymphocyte (PLT) and/or the CML assays were established and grown using T cell growth factor and weekly stimulation with a pool of allogeneic feeder cells. Specificity of selected clones was determined by their reactivity with a panel of HLA-typed lymphocytes. The phenotype of the clones was identified by monoclonal antibodies and complement lysis. Two weakly cytolytic clones, which specifically proliferated in response to DR5 bearing lymphocytes in PLT, possessed the OKT8 marker, suggesting that this determinant is not exclusively involved in the recognition of class I antigens.

Lyt-phenotype conversion of cytotoxic T lymphocytes specific for the A and E class II major histocompatibility complex molecules

The Lyt-1+ (high) Lyt-2+/- (low) primary cytotoxic T lymphocytes (CTL) specific for A(A alpha A beta) molecules and the Lyt-1+Lyt-2+ primary E(E alpha E beta)-specific CTL are both shown to become Lyt-1 Lyt-2+ effector cells after secondary in vitro stimulation. Thus CTL specific for class II major histocompatibility complex molecules exhibit the same Lyt-phenotype shift as class-I-specific CTL do. The data suggest that either both class-I-specific and class-II-specific CTL follow the same differentiation pathway or regulatory cellular interactions allow only Lyt-1-Lyt-2+ cells to differentiate to secondary CTL.

Expression of passively transferred immunity against an established tumor depends on generation of cytolytic T cells in recipient. Inhibition by suppressor T cells

The results of this study with the P815 mastocytoma confirm the results of previous studies that showed that the passive transfer of tumor-sensitized T cells from immunized donors can cause the regression of tumors growing in T cell-deficient (TXB) recipients, but not in normal recipients. The key additional finding was that the expression of adoptive immunity against tumors growing in TXB recipients is immediately preceded by a substantial production of cytolytic T cells in the recipients' draining lymph node. On the other hand, failure of adoptive immunity to be expressed against tumors growing in normal recipients was associated with a cytolytic T cell response of much lower magnitude, and a similar low magnitude response was generated in TXB recipients infused with normal spleen cells and in tumor-bearing control mice. Because the passively transferred sensitized T cells possessed no cytolytic activity of their own, the results indicate that the 6-8-d delay before adoptive immunity is expressed represents the time needed for passively transferred helper or memory T cells to give rise to a cytolytic T cell response of sufficient magnitude to destroy the recipient's tumor. In support of this interpretation was the additional finding that inhibition of the expression of adoptive immunity by the passive transfer of suppressor T cells from tumor-bearing donors was associated with a substantially reduced cytolytic T cell response in the recipient's draining lymph node. The results serve to illustrate that interpretation of the results of adoptive immunization experiments requires a knowledge of the events that take place in the adoptively immunized recipient. They support the interpretation that suppressor T cells function in this model to "down-regulate" the production of cytolytic effector T cells.

Alloreactive T-cell clones. Ly phenotypes predict both function and specificity for major histocompatibility complex products

We have studied the association of Ly phenotype with function and specificity for major histocompatibility complex (MHC) products by examining the properties of 21 T-cell clones derived from B10 anti-B10.D2 and B10.A anti-B10.D2 mixed lymphocyte cultures (MLC). T cells were selected after MLC solely on the basis of Ly phenotype, cloned by limiting dilution, and tested for stability of Ly phenotype, function and specificity for class I or class II MHC products. Sixteen Ly-1+2- and five Ly-1-2+ T-cell clones were tested. The clones selected for the Ly-1+2- phenotype maintained this phenotype, expressed helper but not lytic function, and recognized class II MHC products (I-Ad or I-Ed). All Ly-1-2+ clones maintained this phenotype, possessed cytolytic but not helper activity, and recognized class I MHC products (Dd and Ld). Our data therefore confirm at the clonal level the original observations of a remarkably consistent correlation between Ly markers, MHC specificity, and function. They suggest that the expression of Ly antigens on T-cell clones forms part of a genetic program for each of these specialized cells that also determines their function and MHC specificity.