Human cytotoxic lymphocytes. IV. Frequency and clonal specificity of CD8+CD16-(Leu2+Leu11-) and CD16+CD3-(Leu11+Leu4-) cytotoxic lymphocyte precursors activated by alloantigen or K562 stimulator cells

Cell sorter-purified CD8+CD16- (Leu2+Leu11-) cytotoxic T cell precursors and CD16+CD3-(Leu11+Leu4-) natural killer (NK) cells were cultured under limiting dilution (LD) conditions with allogeneic stimulator cells or with K562 tumor cells in the presence of exogenous interleukin 2. One out of 100-200 alloantigen-stimulated Leu2+ T cells clonally developed into an alloantigen-specific cytotoxic T cell, but only 1 out of 500-3400 of these cells lysed NK-susceptible K562 target cells. In contrast, 1 out of 2-35 alloantigen-stimulated Leu11+ precursor cells developed into an effector cell that lysed K562, but less than 1 out of 500 of these cells lysed allogeneic Con A blast targets. However, clonal activation of Leu11+ precursor cells under LD conditions did not require alloantigenic stimulator cells. Comparable high frequencies (f = 1/3 to 1/28) of anti-K562 cytotoxic lymphocyte precursors were thus measured when Leu11+ precursor cells were cultured on autologous or K562 feeder cells. As shown by a split culture approach, the vast majority of alloantigen-activated Leu2+ effector cells were highly specific for the stimulating alloantigen (i.e., they did not lyse K562), while the majority of Leu11+ microcultures lysed K562 tumor cells but neither autologous nor allogeneic Con A blast targets. On a quantitative basis, these data show that CD8+CD16- T cells and CD16+CD3-NK cells are two mutually exclusive lymphocyte populations which clonally develop into cytotoxic effector cells specific for alloantigen or K562 target cells, respectively.     

Antigen-presenting T cells. I. Class I alloantigen (bm1)-bearing T lymphoblasts efficiently stimulate a primary clonal response of Lyt-2+ cytotoxic lymphocyte precursors of B6 origin

The cytotoxic response of splenic Lyt-2+ T cells to class I H-2 alloantigen-bearing stimulator cells was analyzed under limiting dilution conditions. One of 50 to one of 200 nylon wool-nonadherent (FACS-purified), small Lyt-2+ spleen cells of B6 origin gave rise in vitro to a cytotoxic T lymphocyte clone that specifically lysed targets bearing bm1 alloantigen. This population of alloantigen-specific cytotoxic lymphocyte precursors (CLP) was activated by different types of bm1 stimulator cells with different efficiency: 2 X 10(5) nonfractionated spleen cells, 5000 normal peritoneal cells, 400 to 10(4) L3T4+ helper T blasts, or 2000 to 10(4) Lyt-2+ T blasts induced clonal growth of this CLP pool. Irradiated or mitomycin-treated small (L3T4+ or Lyt-2+) bm1-derived T cells were inefficient stimulator cells for this response. Supplementation of culture medium with (recombinant) interleukin 2 was necessary and sufficient to support clonal development of alloantigen-triggered CLP in the presence of allogeneic T blasts. Under these limiting dilution conditions, we observed comparable cloning efficiencies for (wild-type) Kb-allospecific splenic Lyt-2+ CLP from bm1 mice generated in response to either irradiated B6 spleen cells or inactivated B6-derived T cell lines (EL4 and RBL-5 lymphoma cells). The data indicate that normal T lymphoblasts as well as tumor T cell lines stimulate clonal development in vitro of class I H-2-allospecific cytotoxic T lymphocytes in the presence of interleukin 2.     

Activation of nonspecific killer cells by interleukin 2-containing supernatants

In the absence of specific antigen stimulation, nonspecific killer cells were induced by culturing C57BL/6 lymph node or spleen cells with interleukin 2-containing supernatants. These supernatants were obtained from stimulation of either rat spleen cells with concanavalin A or a variant of the T cell lymphoma, EL4 (H-2b) with phorbol myristic acetate. The ability of the EL4 supernatant to induce nonspecific killer cells was abrogated by absorption with an interleukin 2-dependent T cell line or by concanavalin A-stimulated spleen cell blasts, but not by lipopolysaccharide-stimulated spleen cell blasts or by a non-interleukin 2-producing EL4 line. Partially purified interleukin 2 from EL4 supernatants could also support nonspecific killer cell induction. The induction of cytolytic cells by interleukin 2 is sensitive to gamma-irradiation and has a D omicron of 120 rad. The nonspecific killer cells induced are likely cytotoxic T lymphocytes; the majority of the precursor and effector cells bear the Thy-1 alloantigen marker. These nonspecific killer cells killed a broad spectrum of target cells, including concanavalin A- and lipopolysaccharide-induced splenic blasts of syngeneic or allogeneic mice, a syngeneic tumor, and a cloned allogeneic cytotoxic T cell line. The frequency of precursors for nonspecific killer cells in C57BL/6 lymph node and spleen cells are 1/7000 and 1/12,000, respectively. Clonal analyses revealed that these nonspecific killers exhibit heterogeneity with respect to their target cell specificities. The induction of nonspecific killers by interleukin 2-containing supernatants is partially dependent on nylon wool-adherent cells; in antigen-stimulated cultures the most specific killer cells were obtained from cultures in which nylon wool-nonadherent lymph node responder cells were stimulated with nylon wool-nonadherent allogeneic splenic stimulator cells that were treated with anti-Thy-1 antibody and complement. The relevance of these findings with respect to the frequencies and fine specificities of cytotoxic T lymphocytes generated in interleukin 2-supplemented cultures is discussed.     

Cell-mediated lympholysis of trinitrophenyl-derivatized autologous human cells: in vitro triggering by nonspecific signals.

This report describes the primary in vitro generation of human CTL that lyse TNP-derivatized autologous cells. Although in the majority of these studies, a direct cytotoxic response to the TNP-modified autologous stimulators was not achieved, in all experiments the addition of either allogeneic cells or soluble antigen triggered the generation of killer cells which destroy TNP-modified, but not unaltered, autologous targets. Fractionation of responder lymphocyte populations demonstrated that the cytotoxic activity was mediated by T cells. Killer cell specificity was tested by assaying for cytotoxicity to a variety of targets, and by blocking the cytolysis of TNP-altered autologous targets with various populations of nonradiolabeled cells. Results indicated that these CTL were cytotoxic for TNP-modified autologous cells but not unaltered autologous or TNP-modified allogeneic targets. The capacity of soluble antigen and alloantigens to facilitate the in vitro generation of altered-self reactive human CTL is not an isolated phenomenon. This "helper" effect has now been observed for the cytotoxic response to chemically modified autologous cells and MHC identical human leukemic blasts. It is possible that in vivo, similar responses to nonspecific antigenic stimuli may play a role in the maintenance of immune surveillance.     

Cultured Lyt-2- L3T4- T lymphocytes from normal thymus or lpr mice express a broad spectrum of cytolytic activity

T lymphocytes expressing the surface phenotype Lyt-2- L3T4- represent a minor population of immature thymocytes that appear to be the precursors of mature T cells. Cells with the same apparent surface phenotype also accumulate in vast numbers in the lymphoid tissues of the autoimmune lpr mouse. Lyt-2- L3T4- T lymphocytes from lpr lymph node (LN) or normal thymus express low to undetectable levels, respectively, of surface antigen receptor. In addition, they produce reduced amounts of lymphokines compared with normal T cells and lack precursors of alloantigen-specific cytolytic T lymphocytes. We previously showed that after culture with phorbol esters and interleukin 2, lpr Lyt-2- L3T4- T lymphocytes proliferate and differentiate, acquiring increased levels of surface antigen receptor by most cells, as well as Lyt-2 by a portion. We now show that cultured Lyt-2- L3T4- T cells from lpr LN or normal thymus are very efficiently cytolytic toward not only allogeneic tumor targets, but also natural killer (NK)-susceptible targets and syngeneic targets. Such killing was not inhibited by antibodies to H-2 or Lyt-2. In contrast, cultured mature Lyt-2+ L3T4- T cells from normal LN, thymus, or lpr LN were cytolytic only toward allogeneic targets and were dependent on Lyt-2 expression and H-2 recognition. The similarities of cultured Lyt-2- L3T4- T cells to NK and lymphokine-activated killer cells are discussed.     

Xenogeneic serum-induced murine cytotoxic cells. I. The generation of effector components specific for self and allogeneic target cells.

Spleen cells from unimmunized mice cultured in vitro without the intentional addition of exogenous antigen generated cytotoxic effector cells which lysed tumor and mitogen-stimulated blast target cells in a 5-hr chromium release assay. Effectors were generated in fetal bovine serum but not in adult horse serum, although both serum sources supported the generation of allogeneic cytotoxic cells. No correlation was observed between the ability of a serum source to support and generate serum-induced effectors and its ability to support an allogeneic cytotoxic response. The effectors lysed targets which were H-2 matched and those which were not H-2 matched with the cultured spleen cells, although the H-2 matched targets were consistently lysed more efficiently. “Cold” target cell inhibition studies indicated that multiple clones of cytotoxic cells were generated—including effector cells with specificity for self-structures, and particular alloantigens. Possible roles for the xenogeneic serum in the generation of this response are considered, including (a) the provision of essential stimulating and target antigens; (b) the induction of the expression of neoself-determinants; and (c) the possession of mitogenic properties.     

Analysis of cellular immune response to EBV by using cloned T cell lines

Eight cloned T cell lines specific for Epstein Barr virus-transformed B lymphocytes were derived. In the presence of the autologous virus-infected B cells, the T cell lines show HLA-restricted cytotoxic activity and also secrete alpha-interferon in sufficient amounts to inhibit infection and transformation. Four of these clones showed restriction to a single HLA locus (two for A3, and two for B7) and three showed exquisite self-restriction lysing only autologous targets. These seven clones expressed the classical cell surface phenotype of cytotoxic T cells being T3, 8, 11, and la-positive and T4-negative. An eighth clone that lacked the T8 surface marker appeared to recognize both B7 and BW51. HLA restriction was confirmed: 1) by the ability of a monoclonal antibody against an HLA-A,B,C framework antigen (W6-32) to block the cytotoxicity; 2) the failure of the clones to lyse Daudi, an EBV-positive, HLA-A,B, C-negative cell line; and 3) successful competition of the cytotoxicity by autologous but not allogeneic cold targets. The cloned T cells do not kill EBV-negative targets such as autologous pokeweed mitogen blasts and cell lines including CEM and the natural killer cell target K562. The results suggest T cell clones may be generated against an EBV-associated membrane antigen on transformed B cells, perhaps equivalent to the lymphocyte-determined membrane antigen, and that the recognition is restricted by a single HLA determinant. We propose that single T cells can play multiple roles in controlling EBV infection in vitro and in vivo including the elimination of transformed cells by cytotoxicity and the prevention by secreted interferon of further re-infection and transformation.     

Alteration of allospecific t-cell receptors after differentiation from prethymic precursor cells in semiallogeneic environments

Murine bone marrow cells (strain A) have been allowed to differentiate in vivo in syngeneic (A) or semiallogeneic hosts (A × B) to produce mature splenic T lymphocytes. After stimulation of these cells with irradiated allogeneic (C) spleen cells in tissue cultures, the cytotoxic T-cell blasts (CTL) were purified by velocity sedimentation and used to immunize (A × C) F₁ hybrid mice, to produce antisera recognizing the receptor structure (for C) on the relevant A cytotoxic cells (and their precursors). Using these sera we have been able to show that the T-cell receptor for alloantigen C on strain A cytotoxic precursor lymphocytes (CTLp) seems to differ according to the host environment in which those T cells differentiate from immature bone marrow precursors.     

Specific T-cell-mediated killing of autologous lung tumour cells

The phenomenon that strong syngeneic T-cell-mediated cytotoxicity is observed if killer, stimulator, and target cells share H-2 histocompatibility antigens is called H-2 restriction. Here a syngeneic model system making use of hapten-coupled stimulator and target cells is used to explore whether H-2 restriction is absolute or not. Using TNP-coupled spleen or tumor cells as stimulator or target cells in syngeneic and allogeneic situations, it is shown that neither the induction step nor the effector step of TNP-dependent killing is H-2 restricted. By varying the experimental assay conditions more or less H-2-restricted, TNP-dependent killing can be observed. For instance, suboptimal coupling of TNP to targets may result in H-2-restricted killing. Similarly, the use of spleen cell targets as opposed to spleen blast cells or tumor cells may result in H-2-restricted lysis. In contrast optimal coupling of TNP to sensitive target cells and coupling of TNP to cells with certain H-2 haplotypes may lead to significant TNP-dependent killing which is not H-2 restricted. Since hapten-coupled cells lacking H-2 are neither stimulators nor targets these results suggest that the T-cell receptor recognizes TNP-modified H-2 antigens simply as nonself-H-2. Thus hapten coupling of syngeneic cells appears to lead to a histocompatibility antigen change similar to the situation in an allogeneic cytotoxic reaction. Experiments are presented which support this view showing that TNP-coupled and uncoupled syngeneic or allogeneic stimulator and target cells cross-react. For instance allogeneic sensitization may lead to killing on TNP-coupled targets syngeneic to the effector cells and TNP-coupled stimulator cells syngeneic to the effector cells may induce killing on uncoupled syngeneic targets. TNP-dependent cytotoxicity can therefore be envisaged as a kind of allogeneic reactivity due to modification of H-2 antigens by the TNP coupling. This conclusion may have bearing on other model systems in which syngeneic killing appears to be H-2 restricted. In support of this possibility it is shown that allogeneic sensitization may lead to priming of memory cells able to respond to minor histocompatibility antigens.     

Alloreactive cytotoxicity of interferon-triggered human lymphocytes detected with tumor biopsy targets

Interferon activation of lymphocytes produces lytic potential against allogeneic but not against autologous biopsy-derived tumor cells. This effect was seen when targets isolated from solid tumors were used directly without cultivation in vitro. The hypothesis that the lytic effect was due to activation of alloreactive cells was tested in the cold target competition assay. The results substantiated our assumption because they showed that in a given lymphocyte population separate sets act on allogeneic tumor cells derived from different individuals. In addition PHA blasts from the target-cell donor but not from unrelated individuals also inhibited the lysis. The system we use is operationally an NK assay in which antigen (MHC)-recognizing lymphocytes seem to function. Since antigen recognition is a property of the T subset, the conceptual dualism in the classification of NK and CTL effects should be modified.     

Human cytotoxic lymphocytes. V. Frequency and specificity of gamma delta+ cytotoxic lymphocyte precursors activated by allogeneic or autologous stimulator cells

We have investigated the frequency and specificity of gamma delta+ cytotoxic lymphocyte precursors (CLP) under limiting dilution culture conditions. E rosette separated total T cells and CD3+CD4-CD8-TCR alpha beta- double-negative (DN) T cells were cocultured with allogeneic or autologous PBMC stimulator cells, and frequencies of alloreactive and autoreactive CLP were determined after 12 to 14 days against Con A blast target cells. Freshly isolated DN cells consisting of 82.3 +/- 8.2% gamma delta+ T cells did not exert cytolytic activity against K562 or anti-TCR gamma delta mAb-producing hybridoma cells. In striking contrast to E+ cells, the vast majority of alloantigen-stimulated clonally developing DN CLP did not show specificity for stimulator-derived target cells. Thus, frequencies of alloreactive and autoreactive CLP after alloantigenic stimulation were in the range of 1/100 to 1/4800 and 1/450 to 1/5000, respectively. After coculture with autologous stimulator cells, frequencies of autoreactive and alloreactive DN CLP were 1/700 to 1/2700 and 1/1360 to 1/4500, respectively. Split culture analysis revealed that most proliferating DN colonies selected for high probability of clonality simultaneously killed both autologous and HLA-mismatched allogeneic targets. The majority of the DN cells expressed the CD3+/TCR gamma delta+ phenotype after culture, and thus were not CD2+CD3- NK cells. Taken together, our results show that 1) freshly isolated peripheral blood gamma delta+ T cells lack cytotoxic activity, and 2) most cytotoxic gamma delta+ T cells activated by autologous or allogeneic stimulator cells under limiting dilution conditions do not discriminate between autologous and allogeneic targets.     

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

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

Human cytotoxic T lymphocytes (CTL) against Epstein-Barr virus (EBV) infected cells: EBV specificity and involvement of major histocompatibility complex determinants in the lysis exerted by anti-EBV CTL toward HLA-compatible and allogeneic target cells

Human peripheral blood lymphocytes (PBL), from anti-Epstein-Barr virus (EBV)-seropositive donors, were stimulated by EBV and were shown to be cytotoxic toward autologous, HLA-compatible, and fully allogeneic EBV-transformed target cells. The lysis was not due to natural killer (NK) cells since the target cells used were resistant to lysis by fresh PBL and by virus-stimulated PBL-depleted of AET-SRBC-rosetting T cells (the latter being still fully cytotoxic on K562 NK-susceptible target cells). Conversely only E-rosette-purified (T) lymphocytes killed EBV-transformed HLA-compatible and allogeneic target cells. Moreover, anti-MHC antibodies inhibited the cytotoxicity exerted by EBV-induced cytotoxic T lymphocytes (CTL) on both autologous and allogeneic target cells. Finally the lysis was EBV specific since PHA blasts were not killed and since only EBV-transformed cells could compete for lysis with the EBV-positive target cells. Efficient competition was achieved by EBV-transformed cells autologous or allogeneic to the targets, even when effector and target cells were fully allogeneic. All together, the data suggest that human anti-EBV CTL may recognize nonpolymorphic HLA determinants on the target cells in association with the virus-induced antigens.     

Alloantigens placed into the anterior chamber of the eye induce specific suppression of delayed-type hypersensitivity but normal cytotoxic T lymphocyte and helper T lymphocyte responses

Intracameral inoculation of allogeneic B16F10 melanoma cells (C57BL/6) into LP/J mice resulted in progressively growing intraocular tumors and impaired delayed-type hypersensitivity (DTH) reactivity. Additional experiments showed that DTH responses were specifically down-regulated by splenic T suppressor cells. By contrast, subcutaneous inoculation of B16F10 melanoma cells induced significant DTH responses to the alloantigens expressed on the tumor cells and stimulated brisk rejection of the subcutaneously injected tumor cells. In spite of the T suppressor cell inhibition of DTH reactivity, significant cytotoxic T lymphocyte activity could be demonstrated in lymphoid cell suspensions from hosts harboring allogeneic intraocular tumors. The demonstrated cytotoxic T lymphocyte activity is particularly noteworthy because it occurs in the face of severely suppressed DTH responsiveness and thus implies that the intracameral presentation of alloantigens evokes a precise immunoregulatory process that selectively and concomitantly modulates specific cellular immune components; one immune process (cytotoxic T lymphocyte function) is stimulated whereas the other (DTH responsiveness) is down-regulated.     

Human mesenchymal stem cells suppress induction of cytotoxic response to alloantigens

Mesenchymal stem cells (MSC) fail to induce allogeneic responses in mixed lymphocyte reaction assays. Because MSC express HLA class I molecules, here we investigated whether they could be recognized as allogeneic targets by cytolytic T lymphocytes (CTL). With this aim, CTL precursor (CTLp) frequencies were measured following stimulation of T cells with either allogeneic mononuclear cells (MNC) or MSC originated from the same human bone marrow donor. Lysis of MSC was measured at day 10 of culture in standard chromium release assays. In addition, allogeneic PHA blast T cells or B-EBV lymphoblastoid cell lines (LCLs) generated from the same donor were used as positive controls of lysis. Our results showed that when allogeneic MNC were used to stimulate T cells, a high CTLp frequency was detected towards MSC targets. However, when MSC were used as stimulators, CTLp frequencies were markedly altered whatever the targets used, i.e.: MSC, PHA blast T cells or EBV-B LCLs. Moreover, when graded concentrations of MSC were added together with MNC upon stimulation of alloreactive T cells, we observed a dose-dependent decrease in CTLp frequencies towards MSC targets. This inhibition of MSC lysis was partially overcome by adding exogenous rh-IL-2 from the beginning of cultures. In addition, this suppressive effect was totally reproduced when, instead of MSC, supernatant harvested from MSC cultures was added to allogeneic MNC, upon stimulation of alloreactive T cells. In conclusion, our results demonstrate that MSC which can be recognized as targets by pre-activated alloreactive CTLs, may be able to suppress differentiation of CTL precursors into CTL effectors through secretion of suppressive factors.     

Subpopulation of T Cells Sensitive to Natural Thymocytotoxic Autoantibody (NTA) of New Zealand Mice: I. Distinct Cytotoxic Sensitivity of Functional T Cell Subsets to NTA and Anti-Thy-1 Antibodies

NZB mice produce a natural thymocytotoxic autoantibody (NTA) capable of specifically injuring thymocytes and T cells. NTA-reactive antigen (NTA-A) shows a different density distribution among T cells, and partial killing with NTA and complement can eliminate T cells bearing NTA-A in high density. Thy-1 antigen is similar to NTA-A in this respect. To determine the effects of NTA and anti-Thy-1 on distinct functional subsets of T cells, Con A-induced suppressor T cell (Con A-Ts) activity against the allogeneic mixed lymphocyte reaction (MLR), responding T cell (T_MLR) activity in the allogeneic MLR, and Con A-induced cytotoxic T cell (Con A-Tc) activity were examined simultaneously in BALB/c spleen cells before and after partial elimination of NTA- and anti-Thy-1-sensitive T cells. Treatment with NTA and complement resulted in a marked reduction in Con A-Ts activity, a significant increase in T_MLR activity and a slight and inconstant decrease in Con A-Tc activity. Since Con A-generated Ts were much less sensitive to NTA, the NTA-sensitive T cells involved in Con A-Ts activity appear to be precursors or promoters of the Con A-Ts. In contrast, the precursors of Con A-Tc seem to be relatively resistant to NTA. The increase in T_MLR activity caused by NTA suggests the possibility that NTA is less cytotoxic for T_MLR and cytotoxic for some suppressor T cells in allogeneic MLR. The monoclonal anti-Thy-1 antibody showed no such preferential cytotoxic effects on the three T cell functions. The NTA-sensitive T cells, in contrast to anti-Thy-1-sensitive T cells, were reduced gradually during Con A stimulation. All these findings indicate that NTA-A not only differs from Thy-1 antigen but that it appears to be a unique T cell antigen.     

In vitro selective effect of melphalan on human T-cell populations

Summary In vitro treatment with 2 g/2×10⁶ cells melphalan (l-PAM: l-phenylalanine mustard) significantly decreased the total number of T lymphocytes from peripheral blood (PBL) of healthy human donors and of the OKT₄ population (precursor suppressor/helper/inducer) T cells as defined by monoclonal antibodies OKT₃ and OKT₄, respectively. No changes in the OKT ₈ ⁺ lymphocyte population (cytotoxic/mature suppressor cells) were observed following the same treatment. Preincubation of PBL with l-PAM at concentrations that do not affect the rate of DNA synthesis in PHA-stimulated lymphocytes inhibited the generation of T suppressor lymphocytes by ConA, as shown by their effect on PHA stimulation. Treatment of allogeneic PBL with l-PAM had no effect on mature suppressor T cells already induced by Con A, as shown by incubation of PBL with l-PAM after incubation with ConA.     

Detection and characterization of cytotoxic T lymphocyte precursors in the murine intestinal intraepithelial leukocyte population

Highly purified preparations of intraepithelial leukocytes (IEL) were obtained from the small intestinal mucosa. Leukocytes from the lamina propria (LPL) were isolated and phenotypically compared with IEL to verify that IEL were minimally contaminated by LPL. Because approximately 80% of IEL expressed the Lyt-2 antigen usually associated with cytotoxic/suppressor T lymphocytes, we wished to determine if precursors for cytotoxic T cells were present in this population. In order to generate cytotoxic cells, IEL and spleen cells from CBA/J mice (H-2k) were co-cultured with irradiated allogeneic spleen cells (H-2d or H-2b) in a one-way mixed leukocyte reaction (MLR). Four to six days later, the cultured cells were assayed against 51Cr-labeled H-2d or H-2b tumor or Con A-stimulated lymphoblast target cells, and the specificity of alloantigen-stimulated IEL and spleen cells was compared. The cytotoxic cells derived from both tissues displayed antigen-specific lysis of the allogeneic targets. Treatment of effector cells, generated from intraepithelial or splenic precursors, with monoclonal antibodies against Thy-1.2, Lyt-1.1, or Lyt-2.1 antigens plus complement, decreased cytotoxicity 85 to 100%, even though only 20 to 50% of the cells were lysed. The alloantigen specificity and surface antigen phenotype of the cultured IEL cells were identical to those of spleen cells and allowed us to conclude that IEL contained a cytotoxic T lymphocyte precursor (CTLp). Further characterization showed that, like spleen, the intraepithelial CTLp was Thy-1+ and Lyt-1+ and their sedimentation velocity was the same but differed from intraepithelial natural killer cells. Although 80% of IEL were Lyt-2+, the frequency of CTLp in the IEL population was estimated to be threefold to fivefold lower than in spleen, and the Lyt-2+ cells were shown not to be an enriched source of CTLp. Thus, the function of the majority of the IEL is still not known. However, there exists within this population CTLp, which may be capable of being stimulated with luminal antigens.     

Frequency of herpes simplex virus-specific murine cytotoxic T lymphocyte precursors in mitogen- and antigen-driven primary in vitro T cell responses

The aim of this study was to assess and to compare the frequencies and specificities of herpes simplex virus (HSV)-specific cytotoxic T lymphocyte precursors (CTL-p) in mitogen (concanavalin A)-activated splenic T cells, as well as in antigen-activated splenic T cells of normal nonimmunized mice. In the mitogen-driven system one of 130 T cell blasts developed clonal progenies able to lyse specifically HSV-infected syngeneic targets. In the antigen-driven system HSV-specific CTL-p could be detected in normal lymphocytes provided the stimulator cells used were enriched for dendritic cells and pulsed with high concentrations of heat-inactivated HSV. Depending on the mouse strain used, the frequencies of HSV-specific CTL-p ranged from 1/500 to 1/10,000 in normal mice. Upon antigen priming within local lymph node cells, an increase of frequencies from 1/500 to 1/170 was observed in CBA/Ca mice.     

IL-21-treated naive CD45RA<Superscript>+</Superscript> CD8<Superscript>+</Superscript> T cells represent a reliable source for producing leukemia-reactive cytotoxic T lymphocytes with high proliferative potential and early differentiation phenotype

Clinical tumor remissions after adoptive T-cell therapy are frequently not durable due to limited survival and homing of transfused tumor-reactive T cells, what can be mainly attributed to the long-term culture necessary for in vitro expansion. Here, we introduce an approach allowing the reliable in vitro generation of leukemia-reactive cytotoxic T lymphocytes (CTLs) from naive CD8⁺ T cells of healthy donors, leading to high cell numbers within a relatively short culture period. The protocol includes the stimulation of purified CD45RA⁺ CD8⁺ T cells with primary acute myeloid leukemia blasts of patient origin in HLA-class I-matched allogeneic mixed lymphocyte-leukemia cultures. The procedure allowed the isolation of a large diversity of HLA-A/-B/-C-restricted leukemia-reactive CTL clones and oligoclonal lines. CTLs showed reactivity to either leukemia blasts exclusively, or to leukemia blasts as well as patient-derived B lymphoblastoid-cell lines (LCLs). In contrast, LCLs of donor origin were not lysed. This reactivity pattern suggested that CTLs recognized leukemia-associated antigens or hematopoietic minor histocompatibility antigens. Consistent with this hypothesis, most CTLs did not react with patient-derived fibroblasts. The efficiency of the protocol could be further increased by addition of interleukin-21 during primary in vitro stimulation. Most importantly, leukemia-reactive CTLs retained the expression of early T-cell differentiation markers CD27, CD28, CD62L and CD127 for several weeks during culture. The effective in vitro expansion of leukemia-reactive CD8⁺ CTLs from naive CD45RA⁺ precursors of healthy donors can accelerate the molecular definition of candidate leukemia antigens and might be of potential use for the development of adoptive CTL therapy in leukemia.