NK-like cytotoxicity of allospecific gamma delta TCR+ T cell clones]

We recently generated a series of human alloantigen-specific, CD3+, gamma delta- TCR+ clones by stimulating CD3+, CD4-, CD8- T cells from normal individuals with allogeneic lymphoblastoid cell lines (LCL). These clones display cytotoxic activity against their specific stimulators but not against irrelevant LCL. Most but not all of these clones express the NK cell associated marker, CD57, and kill NK-sensitive targets such as the K562 and Molt 4 lines, but not NK-resistant line, Raji. Gamma delta clones which lacked expression of CD57 had no detectable NK activity. The allospecific cytotoxicity of CD57+ and CD57- clones was inhibited by mAb to CD3 or the TCR delta- chain. In contrast, the NK-like activity of the CD57+ clones was enhanced by these antibodies over a wide range of antibody concentration. An HLA class I framework-specific mAb had no effect on NK-like cytolysis but did inhibit allospecific killing, suggesting that the target structures on the surface of allospecific and NK-sensitive cells are distinct. The receptors utilized by the gamma delta- TCR+ clones to recognize NK-sensitive and allospecific targets are also distinct, since killing of NK-sensitive targets was blocked by the presence of cold (unlabeled) NK-sensitive cells but not by cold allospecific targets, whereas allospecific cytolysis was inhibited by cold allospecific targets but not by NK-sensitive cells. We conclude that some CD3+, TCR- gamma delta+ clones exhibit NK-like as well as allospecific killing and that these two activities are mediated by distinct receptor-ligand interactions.     

Alloantigen-specific cytotoxic clones bearing the alpha,beta T cell antigen receptor but not CD4 or CD8 molecules

The vast majority of circulating lymphocytes that express the alpha,beta TCR in association with CD3 also express either CD4 or CD8 molecules, which are thought to act as important accessory structures in HLA class II- and I-restricted T cell functions, respectively. In the current study alpha,beta TCR+ clones devoid of detectable CD4 or CD8 were generated by repeated stimulation of fresh CD3+,CD4-,CD8- cells with an allogeneic lymphoblastoid cell line in the presence of conditioned medium containing IL-2. Except for the absence of CD4 and CD8, which was associated with undetectable levels of CD4 and CD8 mRNA, the clones were phenotypically indistinguishable from classical CD3+,alpha,beta TCR+ cells. Furthermore, they mediated potent cytolysis of their specific stimulator line but did not kill irrelevant LCL or NK-sensitive targets. mAb to CD3 and the alpha,beta TCR inhibited cytolysis, suggesting that the clones use the TCR/CD3 complex to recognize and respond to their targets. mAbs to CD2 and CD11a also inhibited cytolysis, indicating that the clones use these accessory molecules to interact with their targets. Finally, cytolysis was inhibited by an HLA-A,B,C framework-specific mAb (W6/32) as well as a mAb (MA2.1) specific for an HLA-A2 epitope. These results demonstrate that CD3+,alpha,beta TCR+,CD4-,CD8- cytotoxic clones can be generated from the peripheral blood of healthy adults, and use their TCR/CD3 complexes to function in an HLA class I-restricted manner.     

Differences in surface phenotype and mechanism of action between alloantigen-specific CD8+ cytotoxic and suppressor T cell clones

We have previously demonstrated that fresh CD8+ T cells proliferate in response to autologous, alloantigen-primed CD4+ T cells, and differentiate into Ts cells, which inhibit the response of fresh T cells to the primary allogeneic stimulator cell but not irrelevant stimulators. Although such Ts do not have discernible cytolytic activity, like classical cytotoxic T cells (Tc) they express CD3 and CD8 on their surface and function in a class I MHC-restricted manner. Our study was an attempt to compare the surface phenotype and mechanism of action of Ts and Tc clones derived from the same individual. Ts clones were generated from donor JK by repeated stimulation of CD8+ T cells with an autologous CD4+ T inducer line specific for an allogeneic lymphoblastoid cell line (LCL). These clones were noncytolytic for either the inducer line or the allogeneic stimulator LCL. Tc clones, generated by direct stimulation of JK CD8+ T cells with the same allogeneic LCL, mediated potent, alloantigen-specific cytolysis. All Tc clones were alpha, beta TCR+, CD3+, CD4-, CD8+, CD11b-, and CD28+. Ts clones were also alpha, beta TCR+, CD3+, and CD8+, but in contrast to Tc clones, Ts clones were CD11b+ and CD28-. When added to MLR both Ts and Tc clones inhibited the response of fresh JK CD4+ T cells to the original but not irrelevant allogeneic LCL. However, Ts inhibited the response of only those CD4+ T cells that shared class I)MHC determinants with the Ts donor, whereas Tc inhibited the response of CD4+ T cells from all responders, regardless of HLA type. Pretreatment of Ts clones with mAb to CD2, CD3, or CD8 blocked suppression, whereas similar pretreatment of Tc clones blocked cytotoxicity in 4-h 51Cr release assays but had no effect on Tc-mediated suppression of the MLR. These results suggest that both Ts and Tc clones can inhibit the MLR but they do so through different mechanisms. Moreover, the maintenance of distinct surface phenotypes on these long term clones suggests that Ts may be a distinct sublineage of CD8+ T cells rather than a variant of CD8+ Tc.     

Functional and phenotypic differences between CD4+ and CD4- T cell receptor-gamma delta clones from peripheral blood.

CD4+ TCR-gamma delta+ T cells comprise a very small subset of TCR-gamma delta+ T cells. CD4+ TCR gamma delta+ T cell clones were established to study the phenotypical and functional characteristics of these cells. Thirty-four CD4+ TCR-gamma delta+ T cell clones were established after sorting CD4+ T cells from a pre-expanded TCR-gamma delta+ T cell population. These clones as well as the CD4- TCR-gamma delta+ T cells from the same donor used V gamma 2 and V delta 2. In a second cloning experiment CD4+ TCR-gamma delta+ T cells were cloned directly from freshly isolated TCR-gamma delta+ T cells using a cloning device coupled to a FACS sorter. Forty-three clones were obtained, which all expressed CD4 and TCR-gamma delta. Eleven of these clones used V delta 1 and three of them coexpressed V gamma 2. The other CD4+ TCR-gamma delta+ T cell clones used both V delta 2 and V gamma 2. CD4+ TCR-gamma delta+ T cell clones expressed CD28 irrespective of the V gamma or V delta usage, and were CD11b negative. Three CD4-CD8+ TCR-gamma delta+ clones expressed CD8 alpha but not CD8 beta and were CD11b positive. CD28 expression among CD4-CD8+ and CD4-CD8- was variable but lower than on CD4+ T cell clones. CD4- TCR-gamma delta+ T cell clones using V gamma 2 and V delta 2 specifically lyse the Burkitt lymphoma cell line Daudi and secrete low levels of IFN-gamma and granulocyte-macrophage-CSF upon stimulation with Daudi. In contrast, most CD4+ T cell clones that use V gamma 2 and V delta 2 had a very low lytic activity against Daudi cells and secrete high levels of IFN-gamma and granulocyte-macrophage-CSF after stimulation with Daudi cells. The NK-sensitive cell line K562 was killed efficiently by the CD4- TCR-gamma delta+ T cell clones, but not by CD4+ TCR-gamma delta+ T cell clones, and could not induce cytokine secretion in CD4+ or CD4- T cell clones. CD4+ TCR-gamma delta+ T cell clones, but not the CD4- clones, could provide bystander cognate T cell help for production of IgG, IgM, and IgA in the presence of IL-2 and IgE in the presence of IL-4. Thus, CD4+ TCR-gamma delta+ T cells are similar to CD4+ TCR-alpha beta+ T cells in their abilities to secrete high levels of cytokines and to provide T cell help in antibody production.(ABSTRACT TRUNCATED AT 400 WORDS)     

Bacterial activation of human natural killer cells. Characteristics of the activation process and identification of the effector cell

We showed previously that contact of human peripheral blood lymphocytes with glutaraldehyde-fixed Salmonella bacteria augmented their cytotoxic capacity against NK-sensitive targets. We have now analyzed the characteristics of the activation and also identified the subsets of lymphocytes responding to bacterial contact. Blocking of protein synthesis with cyclohexamide totally abrogated bacterial induction of activated killing (AK), whereas inhibition of DNA synthesis with mitomycin C did not significantly affect the capacity of lymphocytes to respond to bacterial contact. Both the induction and the effector phase of AK were radioresistant. The AK cells exhibited efficient lytic activity, comparable to that induced by recombinant IL 2 (rIL 2), against NK-resistant targets (including both hematopoietic and solid tumor cell lines). All inducible cytotoxic activity was contained within the subset of lymphocytes expressing Leu-19 (NKH-1) antigen. Leu-19- lymphocytes exhibited no significant NK activity and could not be further stimulated by bacterial contact, rIL 2, or IFN-alpha. Within the Leu-19+ lymphocyte subset, two distinct cell types were present; CD3-, Leu-19+ NK cells and CD3+. Leu-19+ T cells. The CD3+, Leu-19+, T cells mediated low levels of non-MHC-restricted cytotoxicity against K562, but did not respond to bacterial contact, even though rIL 2 could augment their lytic activity slightly. However, the cytotoxic activity of CD3-, Leu-19+ NK cells was significantly augmented by bacterial contact. Within the CD3-, Leu-19+ NK cell population both CD16+ and CD16- cells responded to bacterial activation. The CD3-, CD16-, Leu-19+ cells constituted 1 to 4% of the Percoll-fractionated low buoyant density lymphocytes and accounted for the activation seen within the CD16- lymphocyte population. Thus bacterial stimulation of NK activity seems to be mediated for the most part via CD16+, Leu-19+ cells, and a minor overall contribution is mediated via CD3-, CD16-, Leu-19+ cells. No apparent involvement of T cells was seen in the lytic response of lymphocytes to bacterial contact.     

The expression of T cell receptor-associated proteins during T cell ontogeny in man

The expression of TCR-associated molecules was examined in human fetal and postnatal tissues. From gestational wk 7 onward in the fetal liver, putative prothymocytes have been identified with cytoplasmic CD3 positivity (cCD3+). These immature cells are TdT- and do not express membrane CD3 (mCD3-) or TCR beta identified by beta F1, but show CD7 and CD45 positivity without CD1, CD2, CD5, CD4, CD8, CD10, and class II Ag. Their high proliferative activity is indicated by greater than 85% Ki67 positivity. After the 10th wk, beta F1+, mCD3+ cells also appear in the liver and these are mostly Ki67- but no TCR gamma delta-bearing cells can be identified at such an early stage of extrathymic development. In the mCD3- TdT-fetal thymus (10 1/2 to 18th wk) cCD3+, mCD3- CD1-blasts proliferate (Ki67+) and lack TCR-beta or TCR-gamma delta. The TdT-, CD1+ cortical thymocytes develop into TCR-beta + and WT31-positive (TCR-alpha beta +) cells. Subsequently TdT-positive thymocytes become detectable around 19 to 20 wk, and in such glands the peak of proliferative activity is seen among TdT+, cCD3+ cells which appear to acquire, in a regular sequence, cytoplasmic beta F1 (TCR-beta), mCD3, and TCR-alpha beta (WT31 positivity) together with the loss of TdT and Ki67 positivity. A newly described transitional population of cells is TdT-, beta F1+ but exhibits no detectable WT31 positivity. These cells correspond to the CD1+, mCD3+ thymocytes and are probably the targets of thymic selection. The cells of the TCR-gamma delta lineage, detected by mAb TCR-delta-1 and delta TCS1, are rare (0.02 to 0.5%) among thymocytes from gestational wk 10 1/2 onward through the whole span of thymic development, but these cells include a proportion (18 to 59%) of cells expressing CD1 Ag, suggesting that these TCR-gamma delta cells differentiate in the thymus. Among the CD1+, TCR-gamma delta + thymocytes, no TdT positivity can be detected.     

Specific triggering of gamma, delta T cells by K562 activates the gamma, delta T cell receptor and may regulate natural killer-like function.

Freshly isolated and resting gamma/delta T cell lines, although capable of lysing a variety of MHC-unrestricted targets, fail to lyse K562. Yet, the killing of K562 can be specifically induced by antibodies to CD3 or delta-chains. Although this phenomenon may be caused by redirected lysis, it also raised the possibility that K562 may possess ligands capable of specifically interacting with the gamma/delta receptor. We found that K562 specifically induced both CD3 and delta modulation as well as IL-2R expression and IL-2 production by gamma/delta cells, supporting the idea that the TCR-gamma/delta is specifically triggered by K562 cells. Moreover, although the gamma/delta cell clones lysed other target cells (e.g., Molt 4, U937, Jurkat etc.), these latter targets did not induce delta modulation or IL-2R expression. In addition, F(ab)2 anti-CD3 antibodies inhibited activated gamma/delta T cells from killing K562 but did not inhibit the lysis of the other targets. Taken together, these results suggest that gamma/delta cells lyse some targets by utilizing receptors (perhaps NK-like) distinct from the gamma/delta receptor. We also found that triggering of the gamma/delta receptor by K562 inhibited the capacity of resting gamma/delta to lyse Molt 4 cells under conditions in which the K562 cells were not lysed. These findings suggest that the gamma/delta receptor maybe directly involved in the lysis of certain targets (i.e., K562) and, importantly, may potentially regulate the function of NK-like receptors that are involved in the lysis of other targets.     

The relationship of CD16 (Leu-11) and Leu-19 (NKH-1) antigen expression on human peripheral blood NK cells and cytotoxic T lymphocytes

We examined the antigenic and functional characteristics of human peripheral blood lymphocytes that differentially express the CD16 (Leu-11) and Leu-19 (NKH-1) antigens. Leu-19 is a approximately 220,000 daltons protein expressed on approximately 15% of freshly isolated peripheral blood lymphocytes. Within the Leu-19+ subset, three distinct populations were identified: CD3-,CD16+,Leu-19+ cells; CD3+,CD16-,Leu-19+ cells; and CD3-,CD16-,Leu-19bright+ cells. Both the CD3+,CD16-,Leu-19+ and CD3-,CD16+,Leu-19+ populations mediated non-major histocompatibility complex (MHC)-restricted cytotoxicity against the NK-sensitive tumor cell K562 and were large granular lymphocytes. CD3-,CD16+,Leu-19+ NK cells were the most abundant (comprising approximately 10% of peripheral blood lymphocytes) and the most efficient cytotoxic effectors. The finding that CD3+,Leu 19+ lymphocytes mediated cytotoxicity against K562 unequivocally demonstrates that a unique subset of non-MHC-restricted cytotoxic CD3+ T lymphocytes are present in the peripheral blood of unprimed, normal individuals. However, CD3+,CD16-,Leu-19+ cells comprised less than 5% of peripheral blood lymphocytes, and the cytotoxic activity of this subset was significantly less than CD3-,CD16+,Leu-19+ NK cells. Most CD3+,Leu-19+ T cells co-expressed the CD2, CD8, and CD5 differentiation antigens. The antigenic and functional phenotype of peripheral blood CD3+,Leu-19+ cytotoxic T lymphocytes corresponds to the interleukin 2-dependent CD3+ cell lines that mediate non-MHC-restricted cytotoxicity against NK-sensitive tumor cell targets. A small population of Leu-19bright+ lymphocytes lacking both CD3 and CD16 was also observed. This population (comprising less than 2% of peripheral blood lymphocytes) contained both large agranular lymphocytes and large granular lymphocytes. CD3-,CD16-,Leu-19bright+ lymphocytes also mediate non-MHC-restricted cytotoxicity. The relationship of these CD3-CD16-,Leu-19bright+ lymphocytes to CD3+ T cells or CD16+ NK cells is unknown.     

Antigenic, functional, and molecular genetic studies of human natural killer cells and cytotoxic T lymphocytes not restricted by the major histocompatibility complex

Cytotoxicity not restricted by the major histocompatibility complex (MHC) is mediated by two distinct types of lymphocyte: natural killer (NK) cells and non-MHC-restricted cytotoxic T lymphocytes (CTL). These two types of cytotoxic lymphocytes can be distinguished by antigenic phenotype, function, and molecular genetic studies. In human peripheral blood, NK cells are identified by expression of the Leu-19 and/or CD16 cell surface antigens, and lack of CD3/T cell antigen receptor (Ti) complex expression (i.e., CD3-,Leu-19+). Peripheral blood non-MHC-restricted CTL express both CD3 and Leu-19 (i.e., CD3+, Leu-19+, referred to as Leu-19+ T cells). Both Leu-19+ T cells and NK cells lyse "NK-sensitive" hematopoietic tumor cell targets, such as K562, without deliberate immunization of the host. However, most "NK activity" in peripheral blood is mediated by NK cells, because they are usually more abundant and more efficient cytotoxic effectors than Leu-19+ T cells. The cytolytic activity of both NK cells and Leu-19+ T cells against hematopoietic targets was enhanced by recombinant interleukin 2 (rIL 2). NK cells, but not peripheral blood Leu-19+ T cells, were also capable of lysing solid tumor cell targets after short-term culture in rIL 2. Southern blot analysis of NK cells revealed that both the T cell antigen receptor beta-chain genes and the T cell-associated gamma genes were not rearranged, but were in germ-line configuration. These findings indicate that NK cells are distinct in lineage from T lymphocytes and do not use the T cell antigen receptor genes for target recognition.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two distinct human cloned T cell lines that exhibit natural killer-like and anti-human effector activities

Cloned T cell lines from mixed lymphocyte cultures stimulated with autologous Epstein Barr virus- (EBV) transformed lymphoblastoid cell line (LCL) cells were established using a limiting dilution technique in the presence of T cell growth factor (TCGF). The T cell lines included two distinct clones of cytotoxic T cells (Tc) in addition to EBV-specific Tc. A cytotoxic profile of one cloned line was similar to that of endogenous NK cells in peripheral blood. The other cloned Tc line showed an anti-human cytotoxicity. The susceptible targets for this latter Tc line were various human cells, including autologous LCL and peripheral blood lymphocytes (PBL), stimulated with pokeweed mitogen, along with NK-sensitive and NK-resistant cell lines. Weak cytotoxic activity was detected against various xenogeneic cell lines. Furthermore, autologous and allogeneic cloned T cell lines were resistant to killing by the anti-human effector clone. These t wo distinct cloned Tc lines expressed the Leu-1 and Leu-2a antigens, which are markers of suppressor/cytotoxic T cells.     

Phenotypic and functional analysis of murine CD3+,CD4-,CD8- TCR-gamma delta-expressing peripheral T cells

Murine CD3+,CD4-,CD8- peripheral T cells, which express various forms of the TCR-gamma delta on their cell surface, have been characterized in terms of their cell-surface phenotype, proliferative and lytic potential, and lymphokine-producing capabilities. Three-color flow cytofluorometric analysis demonstrated that freshly isolated CD3+,CD4-, CD8- TCR-gamma delta lymph node cells were predominantly Thy-1+,CD5dull,IL-2R-,HSA-,B220-, and approximately 70% Ly-6C+ and 70% Pgp-1+. After CD3+,CD4-,CD8-splenocytes were expanded for 7 days in vitro with anti-CD3-epsilon mAb (145-2C11) and IL-2, the majority of the TCR-gamma delta cells expressed B220 and IL-2R, and 10 to 20% were CD8+. In comparison to CD8+ TCR-alpha beta T cells, the population of CD8+ TCR-gamma delta-bearing T cells exhibited reduced levels of CD8, and about 70% of the CD8+ TCR-gamma delta cells did not express Lyt-3 on the cell surface. Functional studies demonstrated that splenic TCR-gamma delta cells proliferated when stimulated with mAb directed against CD3-epsilon, Thy-1, and Ly-6C, but not when incubated with an anti-TCR V beta 8 mAb, consistent with the lack of TCR-alpha beta expression. In addition, activated CD3+,CD4-,CD8- peripheral murine TCR-gamma delta cells were capable of lysing syngeneic FcR-bearing targets in the presence of anti-CD3-epsilon mAb and the NK-sensitive cell line, YAC-1, in the absence of anti-CD3-epsilon mAb. Finally, activated CD3+, CD4-,CD8-,TCR-gamma delta+ splenocytes were also capable of producing IL-2, IL-3, IFN-gamma, and TNF when stimulated in vitro with anti-CD3-epsilon mAb.     

Detection of double target binders at the single cell level: an evaluation of the specificity of NK and MLC-induced NK-like cells

MLC-generated cells were tested on 7 consecutive days in the single cell cytotoxicity assay to determine the kinetics of natural and allospecific killing. Maximum cytotoxicity to the NK-sensitive target, K562, was found on Day 3 of MLC with an increase at that time in both the number of cells binding and the number of cells killing K562. The maximum allospecific response was found on Days 6 and 7 with an increase in cells able to bind and kill the alloantigen-bearing target. To determine whether the anti-K562 and allospecific killing were mediated by the same effector cells or different cell populations, both targets were tested simultaneously in the single cell assay. At no time during the 7 days were cells detected capable of simultaneously binding both K562 and allospecific targets. These data indicate that there are two different cell populations responsible for allospecific cytotoxicity and MLC-induced NK-like cytotoxicity. The cytotoxic specificity of unstimulated and MLC-generated NK-like cells was also investigated. When two different NK-sensitive targets (e.g., K562 and MOLT-4) were tested together in the single cell assay, there was no concurrent binding of targets by either fresh PBL prior to MLC stimulation or Day 3 MLC-generated cells. When unstimulated effector cells were enriched for NK activity by Percoll density gradient centrifugation, only a small number of effector cells simultaneously binding two different NK-sensitive targets was detected in the single cell assay. These results imply that the NK cell population is heterogeneous and composed of subpopulations recognizing diverse target specificities.     

Cytotoxic T lymphocyte triggering via CD16 is regulated by CD3 and CD8 antigens. Studies with T cell receptor (TCR)-alpha beta+/CD3+16+ and TCR-gamma delta+/CD3+16+ granular lymphocytes

The role of CD3 and CD8 Ag in CD16-mediated CTL triggering was studied in TCR-alpha beta+ and TCR-gamma delta+ granular lymphocytes (GL). In TCR-alpha beta+/CD3+4-8+16+ GL obtained from patients with GL-proliferative disorders, antibody-dependent cellular cytotoxicity was inhibited by anti-CD3 and anti-CD8 mAb. Anti-CD3 mAb also inhibited antibody-dependent cellular cytotoxicity activity of TCR-gamma delta+/CD3+4-8-16+ GL from a patient and that of TCR-gamma delta+/CD3+4-8+/-16+ T cell clones established from patients with proliferating TCR-gamma delta+ GL. In TCR-gamma delta+ T cell clones, cytotoxicity against Fc gamma R+ targets was induced by stimulation of CD16 Ag with anti-CD16 mAb, and such cytotoxicity was also inhibited by anti-CD3 mAb. These results indicate that CD3 and CD8 molecules play a regulatory role in CD16-mediated CTL triggering.     

Human V gamma 9-V delta 2 T cell receptor-gamma delta lymphocytes show specificity to Daudi Burkitt's lymphoma cells

Peripheral blood TCR-gamma delta cells with different functional V gamma or V delta gene rearrangements represent two nonoverlapping subsets. The major subset uses the V gamma 9 and the V delta 2 gene segments and the minor subset the V delta 1 gene segments in its functional TCR rearrangement. Upon in vitro activation, these TCR-gamma delta lymphocytes display MHC-unrestricted lytic activity, against a wide variety of tumor cells of distinct histologic origin. Here we show that fresh TCR-gamma delta lymphocytes that express a V gamma 9-V delta 2 encoded TCR display a specific proliferative response to Daudi, Burkitt's lymphoma cells. Moreover, cloned V gamma 9-V delta 2 lymphocytes show the capacity to lyse Daudi cells, whereas none of the cloned V gamma 1 TCR-gamma delta lymphocytes shows such specificity. Nucleotide diversity at the V-D-J junction of the TCR-V delta 2 gene did not contribute to this Daudi cell specificity. Comparison of the MHC-unrestricted cytolytic capacities of the V gamma 9-V delta 2 and the V delta 1 clones using a panel of distinct types of tumor target cells showed that on average, the level of MHC unrestricted lysis of V gamma 9-V delta 2 clones against these tumor cells exceeded that of V delta 1 clones. However, in contrast to all these tumor cell lines, only the Daudi cells showed such an absolute distinction in susceptibility to lysis by V gamma 9-V delta 2 and V delta 1 clones. V gamma 9-V delta 2 clones that were generated with a stimulator cell other than Daudi did not lyse their stimulator cells but nevertheless showed specific cytolysis of Daudi cells. The specific proliferation to and cytolysis of Daudi cells of the entire V gamma 9-V delta 2 subpopulation of TCR-gamma delta lymphocytes is reminiscent of a superantigen response.     

Functional heterogeneity in allospecific cytotoxic T lymphocyte clones. II. Development of syngeneic cytotoxicity in the absence of specific antigenic stimulation

Two out of four long-term murine allospecific cytotoxic T lymphocyte (CTL) clones tested could develop high levels of cytotoxicity against syngeneic target cells when cultured under appropriate conditions. All CTL clones maintained strict allospecificity so long as they were cultured with both appropriate allogeneic stimulator cells and growth factor (supernatant from secondary mixed lymphocyte cultures). In two of the clones, syngeneic reactivity rapidly developed when the allogeneic stimulator cells were replaced with syngeneic or third party stimulator cells, and when the supernatant from EL4 thymoma cells stimulated with phorbol ester was used as growth factor. In addition to killing the appropriate allogeneic target, clones with syngeneic reactivity could kill both syngeneic C57BL/6 targets and H-2-congenic BALB.B targets but not third party unrelated targets, suggesting that the self structure recognized was coded for within the major histocompatibility complex. Such clones did not kill the natural killer (NK) target YAC. The results obtained from cold target inhibition and from subcloning at limiting dilution of clones with syngeneic reactivity suggested that both allogeneic and syngeneic reactivity could be expressed by the same individual cell in the CTL clone. The specificity for syngeneic H-2 as opposed to third party H-2 and NK-sensitive target cells, and the observation that both allospecific and syngeneic killing could be partially blocked by anti-Lyt-2 antibody treatment of the CTL, strongly suggested that different recognition structures are involved in CTL-mediated syngeneic cytotoxicity and NK cytotoxicity.     

IL-2-dependent expansion of CD3+ large granular lymphocytes expressing T cell receptor-gamma delta. Evidence for a functional receptor by anti-CD3 activation of cytolysis

The nature and function of the TCR on PBL of a patient with a chronic CD3+ large granular (LGL) proliferation was studied. Fresh peripheral blood from this individual was comprised of 80% lymphocytes, 65 to 75% of which were CD3+, CD8+, Leu-7+ LGL. Of these LGL, 72% initially expressed the TCR-alpha beta heterodimer, whereas 21% did not. Cytotoxicity directed against MHC-unrestricted targets was minimal. After several days of exposure to rIL-2, cytotoxic activity was greatly enhanced, correlating with a disappearance of CD3+ cells expressing the alpha beta heterodimer. Twelve days after rIL-2 exposure, the LGL expressed only TCR-gamma delta heterodimer in association with CD3 and alpha beta heterodimer expression could no longer be detected. The TCR/CD3 complex on these cells was demonstrated to be functional as anti-CD3 elicited an increase in cytoplasmic free calcium concentration, stimulated cytolytic activity, and stimulated granule enzyme secretion from the LGL.     

The virus-specific and allospecific cytotoxic T-lymphocyte response to lymphocytic choriomeningitis virus is modified in a subpopulation of CD8(+) T cells coexpressing the inhibitory major histocompatibility complex class I receptor Ly49G2

The role of negatively signaling NK cell receptors of the Ly49 family on the specificity of the acute CD8(+) cytotoxic T-lymphocyte (CTL) response was investigated in lymphocytic choriomeningitis virus (LCMV)-infected C57BL/6 mice. Activated CD8(+) T cells coexpressing Ly49G2 expanded during LCMV infection, and T-cell receptor analyses by flow cytometry and CDR3 spectratyping revealed a unique polyclonal T-cell population in the Ly49G2(+) fraction. These cells lysed syngeneic targets infected with LCMV or coated with two of three LCMV immunodominant peptides examined. Transfection of these sensitive targets with H2D(d), a ligand for Ly49G2, inhibited lysis. This was reversed by antibody to Ly49G2, indicating effective negative signaling. LCMV characteristically induces an anti-H2(d) allospecific T-cell response that includes T-cell clones cross-reactive between allogeneic and LCMV-infected syngeneic targets. The CD8(+) Ly49G2(+) population mediated no allospecific killing, nor was any NK-like killing observed against YAC-1 cells. This study shows that CD8(+) Ly49G2(+) cells participate in the virus-induced CTL response but lyse a more restricted range of targets than the rest of the virus-induced CTL population.     

Expression of Leu-19 (NKH-1) antigen on IL 2-dependent cytotoxic and non-cytotoxic T cell lines

The Leu-19 (NKH-1) antigen is expressed on human peripheral blood NK cells and a subset of peripheral blood cytotoxic T lymphocytes that kill "NK-sensitive" tumor cell targets without major histocompatibility complex restriction. In the present study, we demonstrate that the Leu-19 (NKH-1) antigen is also expressed on most interleukin 2 (IL 2) dependent T cell lines and clones that have been maintained in long term culture. The Leu-19 (NKH-1) antigen expressed on an antigen-specific, class I directed cytotoxic T lymphocyte cell line was an approximately 200,000 to 220,000 dalton protein, similar to Leu-19 (NKH-1) protein expressed on natural killer cells and KG1a, an immature stem cell leukemia cell line. Furthermore, Leu-19 (NKH-1) was expressed on both CD4+ and CD8+ IL 2 dependent T cell clones, and was present on both cytotoxic and non-cytotoxic T cell clones. Thus expression of Leu-19 (NKH-1) antigen on cultured cell lines does not directly correlate with cytotoxic function, antigenic specificity, or cell lineage.     

Cytotoxic activity and lymphokine production of T cell receptor (TCR)-alpha beta+ and TCR-gamma delta+ cytotoxic T lymphocyte (CTL) clones recognizing HLA-A2 and HLA-A2 mutants. Recognition of TCR-gamma delta+ CTL clones is affected by mutations at positions 152 and 156

TCR-gamma delta+ CTL clones were generated from CD4-CD8- T cells that were stimulated twice with the cell line JY. Either IL-2 or IL-4 was used as growth factor. A number of TCR-gamma delta+ clones were found to lyse the stimulator cell line JY. Two of these clones secreted N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester serine esterase activity after stimulation with JY cells. The cytotoxic activity of these two clones was blocked by a mAb specific for HLA-A2. Moreover, these two TCR-gamma delta+ clones selectively lysed human fibroblast line M1 and murine P815 cells transfected with DNA fragments encoding HLA-A2 but not those transfected with HLA-B7 encoding DNA, indicating that these clones recognize HLA-A2. Analysis of the recognition of HLA-A2 by using target cells transfected with mutated HLA-A2 encoding genes revealed that the nature of the amino acid at position 152 of the molecule is critical for recognition of the TCR-alpha beta+ as well as the TCR-gamma delta+ CTL clones since replacement of Val for Ala at that position resulted in abrogation of recognition of one TCR-gamma delta+ and one TCR-alpha beta+ clone and substitution of Val for Glu affected recognition of all clones. Substitution of Leu for Trp at position 156 abrogated recognition by one TCR-gamma delta+ and one TCR-alpha beta+ T cell clone, but recognition by the other clones was not changed. All clones were able to secrete IL-2, IFN-gamma, and GM-CSF but not IL-4 after activation.