A novel serine esterase expressed by cytotoxic T lymphocytes

Cytotoxic T (Tc) lymphocytes recognize and lyse target cells and are thought to serve as an important defence against viral infections and possibly against neoplasms. The nature of the receptors responsible for antigen recognition by these cells is becoming clearer, but the molecular mechanisms responsible for their cytolytic activity remain largely unknown. The possibility that proteases are involved in this process has been suggested by the effects of certain inhibitors. Here we demonstrate that clones of murine Tc cells possess considerable trypsin-like esterase activity when assayed by a sensitive colorimetric assay. This activity was blocked completely by two serine esterase inhibitors, diisopropylfluorophosphoridate (DFP) and phenylmethylsulphonyl fluoride (PMSF), but not by N alpha-tosyl lysyl chloromethyl ketone (TLCK). The use of 3H-DFP as an affinity-labelling reagent demonstrated that the esterase activity resides in a protein of relative molecular mass (Mr) 28,000 (28K). A wide variety of other lymphocytes, including those from thymus, spleen and lymph node, established lines of B cells and noncytotoxic T cells, and clones of T helper cells, had about 300-fold less esterase activity than the Tc-cell clones and far smaller amounts of the DFP-reactive 28K protein. However, in thymocytes the esterase activity increased 20-50-fold and the 28K protein became more prominent 4 days after these cells had been stimulated in vitro to generate Tc cells.     

Homology of perforin to the ninth component of complement (C9)

Perforin is one of the cytolytic factors present in the cytoplasmic granules of mouse cytotoxic T lymphocytes and natural killer cells. We have determined the sequence of the N-terminal amino acids of perforin purified from a mouse natural killer cell line, and, by using oligonucleotide probes corresponding to the amino acid residues, we have identified a complementary DNA encoding perforin from the cDNA library of a mouse cytotoxic T lymphocyte clone. As predicted from the functional similarities between perforin and the ninth component of the serum cytolytic system, complement (C9) (refs 4-8), the deduced primary structure of perforin has homology with C9 at their respective functionally conserved regions. We find that perforin is only expressed in killer cell lines, and not in helper T lymphocytes or other tumour cells tested. Thus we have provided direct molecular evidence that a killer-cell-specific protein evolutionally linked to C9 is involved in cell-mediated cytolysis.     

Cytotoxic T lymphocyte mediated lysis without release of serine esterase

Cloned cytotoxic T lymphocytes (CTL) can lyse target cells in a Ca2+-dependent or Ca2+-independent fashion, depending on the target cell used. We have used these Ca2+-free assay conditions to determine whether there is serine esterase release in the absence of extracellular Ca2+. We find that under conditions where there is significant target cell killing in the absence of Ca2+, there is no detectable serine esterase release. To the extent that serine esterase and perforin-like molecules reside in the same granules, these results also suggest that target cell killing may occur in the absence of degranulation. Our results provide an example of target cell killing without serine esterase release, and the first indication that lysis and degranulation can be functionally dissociated.     

Phosphorylcholine acts as a Ca2+-dependent receptor molecule for lymphocyte perforin

Large granular lymphocytes and cytolytic T-lymphocytes (CTL) contain numerous cytoplasmic granules thought to be responsible, at least in part, for the cytolytic activity of these effector cells. Isolated granules are lytic for a variety of target cells and the granule proteins are specifically released upon target-cell interaction. Major proteins in mouse CTL granules are a family of seven serine proteases designated granzymes A to G, and a pore-forming protein called perforin (cytolysin). Purified perforin is cytolytic in the presence of Ca2+ and shows ultrastructural, immunological and amino-acid sequence similarities to complement component C9. Despite these similarities, perforin and C9 are clearly distinct in their mode of target-cell recognition. Whereas C9 insertion is absolutely dependent on a receptor moiety assembled from the complement proteins C5b, C6, C7, and C8 on the target-cell membrane, no requirement for a receptor molecule has been reported for perforin. Here, we demonstrate that phosphorylcholine acts as a specific, Ca2+-dependent receptor molecule for perforin.     

Activation of cytolytic T lymphocyte and natural killer cell function through the T11 sheep erythrocyte binding protein

The T11 sheep erythrocyte binding glycoprotein [relative molecular mass (Mr)50,000(50K)] is expressed throughout human T-lymphocyte ontogeny and appears to play an important physiological role in T-cell activation. Thus, the treatment of T cells with certain monoclonal anti-T11 antibodies results in antigen-independent polyclonal T-cell activation as assessed by proliferation and lymphokine secretion. In addition, the majority of thymocytes that have not yet acquired the T3-Ti antigen/major histocompatibility complex (MHC) receptor can be activated to express interleukin-2 (IL-2) receptors through this T11 structure. We show here that the triggering of cytolytic T (Tc) cells via T11 causes an antigen-independent activation of the cytolytic mechanism as evidenced by the induction of nonspecific cytolytic activity. Furthermore, T11+T3-Ti- natural killer (NK) cell clones can also be induced to lyse NK-cell-resistant targets by treatment with anti-T11 monoclonal antibodies directed at defined T11 epitopes. These results indicate that T11 triggering can activate cytotoxic lymphocytes to express their functional programmes in the absence of specific antigen recognition via the T3-Ti complex and provide further evidence for the notion that certain NK cells and T lymphocytes are related.     

Rapid on/off cycling of cytokine production by virus-specific CD8+ T cells.

CD8-positive T cells protect the body against viral pathogens by two important mechanisms: production of antiviral cytokines and lysis of infected cells. Cytokine production can have both local and systemic consequences, whereas cytolytic activity is limited to infected cells that are in direct contact with T cells. Here we analyse activated CD8-positive T cells from mice infected with lymphocytic choriomeningitis virus and find that cytokines are not produced ex vivo in the absence of peptide stimulation, but that they are rapidly generated after T cells encounter viral peptides bound to the major histocompatibility complex. Remarkably, cytokine production ceases immediately upon dissociation of the T cells from their targets and resumes when antigenic contact is restored. In contrast to the 'on/off/on' cycling of cytokines, the pore-forming cytotoxic protein perforin is constitutively maintained. Our results indicate that there is differential expression of effector molecules according to whether the antiviral product is secreted (like cytokines) or stored inside the cell (like perforin). The ability to turn cytokines on and off while maintaining intracellular stores of perforin shows the versatility of the cellular immune response and provides a mechanism for maintaining effective immune surveillance while reducing systemic immunopathology.     

The structural basis for membrane binding and pore formation by lymphocyte perforin

Natural killer cells and cytotoxic T lymphocytes accomplish the critically important function of killing virus-infected and neoplastic cells. They do this by releasing the pore-forming protein perforin and granzyme proteases from cytoplasmic granules into the cleft formed between the abutting killer and target cell membranes. Perforin, a 67-kilodalton multidomain protein, oligomerizes to form pores that deliver the pro-apoptopic granzymes into the cytosol of the target cell. The importance of perforin is highlighted by the fatal consequences of congenital perforin deficiency, with more than 50 different perforin mutations linked to familial haemophagocytic lymphohistiocytosis (type 2 FHL). Here we elucidate the mechanism of perforin pore formation by determining the X-ray crystal structure of monomeric murine perforin, together with a cryo-electron microscopy reconstruction of the entire perforin pore. Perforin is a thin 'key-shaped' molecule, comprising an amino-terminal membrane attack complex perforin-like (MACPF)/cholesterol dependent cytolysin (CDC) domain followed by an epidermal growth factor (EGF) domain that, together with the extreme carboxy-terminal sequence, forms a central shelf-like structure. A C-terminal C2 domain mediates initial, Ca(2+)-dependent membrane binding. Most unexpectedly, however, electron microscopy reveals that the orientation of the perforin MACPF domain in the pore is inside-out relative to the subunit arrangement in CDCs. These data reveal remarkable flexibility in the mechanism of action of the conserved MACPF/CDC fold and provide new insights into how related immune defence molecules such as complement proteins assemble into pores.     

Herpesvirus-transformed cytotoxic T-cell lines

Investigations of cellular cytotoxicity of the immune system are hampered by the lack of continuously growing, transformed cell lines which express a cytotoxic potential. Here we describe cytotoxic cell lines from the cotton-topped marmoset monkey, transformed by Herpesvirus Ateles (HVA) or Herpesvirus Saimiri (HVS), which can kill certain target cells in a short-term in vitro test. HVA/HVS-transformed cells have earlier been classified as belonging to the T-cell lineage in contrast to Epstein-Barr virus (EBV)-transformed cells derived from B lymphocytes. We suggest that the HVA/HVS-transformed killer cell lines described here represent an effector population resembling, or corresponding to, marmoset natural killer (NK) cells and that they may be used to define the cytolytic mechanism involved in cellular cytotoxicity and possibly also effector cell receptors and target cell antigens, as well as regulatory mechanisms of general biological interest.     

Structural/functional similarity between proteins involved in complement- and cytotoxic T-lymphocyte-mediated cytolysis

Cytolysis mediated by complement or cytolytic lymphocytes results in the formation of morphology similar lesions in the target membrane. These lesions, formed by the polymerization of C9 or perforin respectively, contribute the major killing action by causing osmotic lysis of the target cell. Following the suggestion of Mayer that the mechanisms of humoral and cell-mediated cytotoxicity might be related, studies into the morphology of the membrane lesions formed, and the proteins responsible for causing the lesions, have shown several similarities. While the lesion caused by natural and T-killer cells is a little larger than that caused by complement, its overall shape is similar and in both cases the cylindrical pore is formed by polymerization of a monomeric subunit, C9 (relative molecular mass, Mr = 71,000) for complement, and perforin (Mr = 66,000) for cell-mediated cytotoxicity. C9 has an absolute requirement for a receptor in the target membrane formed by the earlier membrane attack complex components, C5b, C6, C7 and C8 (ref. 8). For perforin, polymerization in a target membrane requires no receptor, specificity being derived from the specific recognition between killer and target cell. Both proteins can be made to polymerize in vitro by the addition of divalent cations (Zn2+ for C9 (ref. 16) and Ca2+ for perforin) and the resultant complexes closely resemble their physiological counterparts. Antibodies raised against lymphocyte-killed targets have also been shown to cross-react with complement proteins, but the antigenically related proteins were not determined in these studies. We show here using purified proteins that perforin, C9 and complexes involving C7 and C8 share a common antigenic determinant which is probably involved in polymerization.     

Selective activation of Lyt 2+ precursor T cells by ligation of the antigen receptor

Resting T lymphocytes may be activated either physiologically, by the specific recognition of antigen in association with molecules encoded by the major histocompatibility complex (MHC), or non-physiologically using mitogens such as concanavalin A (Con A). The former activation process is difficult to analyse because resting precursor T cells specific for a particular antigen-MHC combination can only be isolated in the presence of a large excess of bystander cells of irrelevant specificity; clonal populations of uniform specificity are not useful for studying the activation of naive T cells because there is no reason to believe that such cloned cells ever return to the state of resting precursors. Mitogens may activate a large fraction of resting T cells, but analysis is again complicated because the target molecule(s) of most mitogens is unknown and the relationship of this kind of activation to physiological induction by antigen plus MHC molecules remains unclear. By using a monoclonal antibody specific for the antigen receptors on approximately 25% of all T cells of both Lyt 2+ and Lyt 2- subsets, we have studied the induction of lymphokine responsiveness in resting normal T cells. This antibody, immobilized on Sepharose beads, is sufficient to activate Lyt 2+ T cells, but not Lyt 2- T cells, to clonal expansion in the presence of a mixture of lymphokines (10% rat spleen Con A supernatant). We report here that clonal growth of the T cells obeys single-hit kinetics in limiting-dilution microcultures, suggesting that a single cell type is limiting. We conclude that cytotoxic T-lymphocyte (Tc) precursors require only ligation of the antigen receptor before they become responsive to lymphokines, whereas helper T-lymphocyte (Th) precursors require additional signals.     

Abolition of specific immune response defect by immunization with dendritic cells

Murine cytotoxic T (Tc)-cell responses to various antigens are controlled by immune response (Ir) genes mapping in the major histocompatibility complex (H-2). The genes responsible are those encoding the class I and class II H-2 antigens. The H-2 I-Ab mutant mouse strain bm12 differs from its strain of origin, C57BL/6 (H-2b), only in three amino acids in the I-A beta bm12 class II H-2 molecule. As a consequence, female bm12 mice are Tc-cell nonresponders to the male antigen H-Y and do not reject H-Y disparate skin grafts. We now report that bm12 mice generate strong H-Y-specific Tc cells following priming in vivo and restimulation in vitro with male bm12 dendritic cells (DC). Female bm12 mice primed with male DC also reject male skin grafts. Furthermore, we demonstrate that only responder cell populations containing a mixture of L3T4+ (T-helper (Th) phenotype) and Lyt 2+ (Tc phenotype) T lymphocytes generate H-Y-specific Tc cells. These data imply an essential role for Th cells, activated by DC as antigen-presenting cells (APC), in changing H-Y-nonresponder bm12 mice into H-Y responders. Priming and restimulation with DC allows the triggering of a T-cell repertoire not demonstrable by the usual modes of immunization. This principle might be used to overcome other specific immune response defects.     

Specific targeting of cytotoxic T cells by anti-T3 linked to anti-target cell antibody

The specificity of cytotoxic T lymphocytes (Tc) cells is conferred by an antigen-specific receptor, Ti, which in humans is physically associated with an invariant cell-surface glycoprotein, T3. Monoclonal antibodies specific for either T3 and Ti are able to elicit a variety of T-cell responses such as lymphokine production, mitogenesis and cytotoxicity. For example, human Tc cells lyse anti-T3-expressing hybridoma cells, but not cells of other specificity, presumably because anti-T3 on the hybridoma cells binds to T3 on the Tc cells and triggers lysis. Here, we have adapted approaches used in a different cytotoxic effector system, antibody-dependent cellular cytotoxicity (ADCC), to alter the specificity of Tc cell. Studies of ADCC showed that heteroaggregates containing anti-Fc receptor (Fc gamma R) antibody cross-linked to a second antibody bind to Fc gamma R on ADCC effectors and cause them to kill target cells bearing antigen recognized by the second antibody. The present studies use anti-T3-containing heteroaggregates to re-target human Tc cells to cells for which we have appropriate antibodies, including xenogeneic tumour cells and chicken erythrocytes. These results extend previous observations on the role of T3 in triggering cytotoxicity and suggest that effector cell re-targeting could be used for in vivo treatment of neoplasms and other pathogens that express distinctive surface antigens.     

Human gamma-chain genes are rearranged in leukaemic T cells and map to the short arm of chromosome 7

Three gene families that rearrange during the somatic development of T cells have been identified in the murine genome. Two of these gene families (alpha and beta) encode subunits of the antigen-specific T-cell receptor and are also present in the human genome. The third gene family, designated here as the gamma-chain gene family, is rearranged in murine cytolytic T cells but not in most helper T cells. Here we present evidence that the human genome also contains gamma-chain genes that undergo somatic rearrangement in leukaemia-derived T cells. Murine gamma-chain genes appear to be encoded in gene segments that are analogous to the immunoglobulin gene variable, constant and joining segments. There are two closely related constant-region gene segments in the human genome. One of the constant-region genes is deleted in all three T-cell leukaemias that we have studied. The two constant-region gamma-chain genes reside on the short arm of chromosome 7 (7p15); this region is involved in chromosomal rearrangements identified in T cells from individuals with the immunodeficiency syndrome ataxia telangiectasia and observed only rarely in routine cytogenetic analyses of normal individuals. This region is also a secondary site of beta-chain gene hybridization.     

Characterization of murine cytolytic-helper hybrid T cell clones

L3T4, Lyt-2 and the T-cell receptor for antigen are cell-surface molecules involved in antigen specific T cell activation. We have constructed functional murine cytolytic-helper T-cell hybrid clones to study the link between expression of cell-surface molecules and specific cell function. Three of the clones express two antigen receptors and both Lyt-2 and L3T4, normally expressed on mutually exclusive subsets of mature T lymphocytes. The pattern of lymphokines produced by the hybrid cells in response to antigen was not controlled by the specific antigen receptor; both T-cell growth factor, produced only by the helper T-cell partner, and gamma-interferon, produced only by the cytolytic T-cell partner, were secreted when either antigen receptor was stimulated. However, cytolytic activity appeared to be restricted to the recognition of antigen by the T-cell receptor of the cytolytic partner. Thus cytolysis appears to be rightly linked to the antigen receptor of the cytolytic parent but lymphokine release is not tightly linked.     

Effect of MTECl on the functional expression of TCRαβ~ + 3G11~- 6C10~-CD4~+CD8~- thymocyte subset

A murine CD4+ thymocyte subset with phenotype of TCRαβ + 3G11- 6C10- CD4 + CD8- CD69 +/- HSAmed/locontains the cells in relatively functional matured status. The functional property of the cells in this subset is characterized by the unique pattern of cytokine production at transitional stage from Th0 to Th2 type with the latter being the dominant type. After being co-cultured with murine thymic medullary epithelial cell line (MTEC1) cells, a murine thymic medullary type epithelial cell line, the TCRαβ(T 3G11 6C10-CD4 + CD8- CD69+/- HSAmed/l? thy-mocytes, has exhibited significantly higher levels of proliferation capability and IL-6 production, whereas the production of IL-4 and IL-10 is suppressed after co-culturing with MTECl. By contrast, MTECl could not induce thymocytes to secrete Th1 type of cytokines. The results suggest that MTECl can regulate functional status of this thymocyte subset and induce them to develop into a specialized Th2 subset.     

Functional interaction between human T-cell protein CD4 and the major histocompatibility complex HLA-DR antigen

Mature T cells segregate phenotypically into one of two classes: those that express the surface glycoprotein CD4, and those that express the glycoprotein CD8. The CD4 molecule is expressed primarily on helper T cells whereas CD8 is found on cytotoxic and suppressor cells. A more stringent association exists, however, between these T-cell subsets and the major histocompatibility complex (MHC) gene products recognized by their T-cell receptors (TCRs). CD8+ lymphocytes interact with targets expressing class I MHC gene products, whereas CD4+ cells interact with class II MHC-bearing targets. To explain this association, it has been proposed that these 'accessory' molecules bind to monomorphic regions of the MHC proteins on the target cell, CD4 to class II and CD8 to class I products. This binding could hold the T cell and its target together, thus improving the probability of the formation of the trimolecular antigen: MHC: TCR complex. Because the TCR on CD4+ cells binds antigen in association with class II MHC, it has been difficult to design experiments to detect the association of CD4 with a class II molecule. To address this issue, we devised a xenogeneic system in which human CD4 complementary DNA was transfected into the murine CD4-, CD8- T-cell hybridoma 3DT-52.5.8, the TCR of which recognizes the murine class I molecule H-2Dd. The murine H-2Dd-bearing target cell line, P815, was cotransfected with human class II HLA-DR alpha, beta and invariant chain cDNAs. Co-culture of the parental T-cell and P815 lines, or of one parental and one transfected line resulted in a low baseline response. In contrast, a substantial increase in response was observed when CD4+ 3DT-52.5.8 cells were co-cultured with HLA-DR+ P815 cells. This result strongly indicates that CD4:HLA-DR binding occurs in this system and that this interaction augments T-cell activation.     

Expression and function of CD4 in a murine T-cell hybridoma

The CD4 (T4) antigen was originally described as a phenotypic marker specific for helper T cells, and has recently been shown to be the receptor for the human immunodeficiency virus (HIV). Functional studies using monoclonal antibodies directed at CD4 and major histocompatibility complex (MHC) class II molecules led to the suggestion that CD4 binds to the MHC class II molecules expressed on stimulator cells, enhancing T-cell responsiveness by increasing the avidity of T cell-stimulator cell interaction and/or by transmitting a positive intracellular signal. But recent evidence that antibodies to CD4 inhibit T-cell responsiveness in the absence of any putative ligand for CD4 has been interpreted as suggesting that antibody-mediated inhibition may involve the transmission of a negative signal via the CD4 molecule instead. We have infected a murine T-cell hybridoma that produces interleukin 2 (IL-2) in response to human class II HLA-DR antigens with a retroviral vector containing CD4 cDNA. The resulting CD4-expressing hybridoma cell lines produce 6- to 20-fold more IL-2 in response to HLA-DR antigens than control cell lines. Furthermore, when antigen levels are suboptimal, the response of the cell lines is entirely CD4-dependent. The data presented here clearly demonstrate that CD4 can enhance T-cell responsiveness and may be crucial in the response to suboptimal levels of antigen.     

Failure of wild-type or a mutant form of protein kinase C-alpha to transform fibroblasts

A mutant form of the alpha-isoform of protein kinase C (PKC) was recently isolated from an ultraviolet radiation-induced murine fibrosarcoma cell line and reported to transform mouse BALB/c 3T3 fibroblasts on transfection. Four point mutations in the regulatory domain were assumed to be responsible for its oncogenicity and unusual preference for membrane localization. Here, we report that overexpression of the reported mutant PKC alpha complementary DNA in three fibroblast cell lines, including BALB/c 3T3, does not enable these cells to grow in soft agar or nude mice. In addition, this mutant PKC alpha form seems to be indistinguishable from the wild-type PKC alpha with respect to its dependence on cofactors, phorbol ester binding, subcellular distribution and its effects on growth and morphology. These results fail to confirm the previous study and indicate that overexpression of either the wild-type or the reported mutant form of PKC alpha does not transform rodent fibroblasts.