Immune response to Toxoplasma gondii--analysis of suppressor T cells in a patient with symptomatic acute toxoplasmosis

Unresponsiveness of antigen-dependent (Toxoplasma-specific and purified protein derivative of tuberculin [PPD]-specific) T-cell proliferative responses of peripheral blood leukocytes (PBL) was observed in a patient with symptomatic acute toxoplasmosis. The immunosuppression of T-cell responses was mediated by Leu 1+, Leu 2a+, and Leu 3a- suppressor T cells that were induced by Toxoplasma gondii antigen and suppressed both Toxoplasma-specific and PPD-specific PBL T-cell responses from a patient with chronic toxoplasmosis when PBL of these patients were mixed and cocultured in vitro. Participation of class II molecules of HLA in Toxoplasma-specific proliferative T-cell responses and activation of suppressor T cells was examined by using monoclonal antibodies specific for HLA-DR and HLA-DQ molecules. Anti-HLA-DQ monoclonal antibody released the suppressive activity, while anti-HLA-DR monoclonal antibody inhibited Toxoplasma-specific T-cell responses. Thus, the suppressive effect of PBL from a patient with acute toxoplasmosis on antigen-dependent PBL T-cell responses from a patient with chronic toxoplasmosis was mediated by HLA-DQ molecules. By contrast, Toxoplasma-specific T-cell responses were activated by HLA-DR molecules (presumably present on antigen-presenting cells).     

Frequency analysis of CD4+CD8+ T cells cloned with IL-4

The coexpression of both CD4 and CD8 molecules on T cells occurs in the peripheral blood at a low frequency and can be generated transiently on CD4+ peripheral blood T cells by treatment with lectin which induces CD8 biosynthesis and cell surface expression. We have cloned T cells in a nonselective fashion from normal subjects in the presence of either IL-2, rIL-4 and IL-2, or rIL-4 and have examined the phenotypic expression of CD4 and CD8. The addition of excess rIL-4 increased the expression of CD8 on the surface of CD4+ T cell clones but did not increase CD4 expression on CD8+ T cell clones. There were three patterns of CD4 and CD8 expression observed: high density CD8 with no CD4 expression; high density CD4 with low CD8 expression; or high density CD4 with higher cell surface CD8 expression which was regulated by the presence of rIL-4. CD4+ T cell clones originally cultured in IL-2 and rIL-4 and subsequently grown in IL-2 alone exhibited decreased expression of the CD8 molecule. The increased expression of CD8 did not correlate with NK activity or lectin-dependent cytotoxicity in an antigen independent system. In addition, rIL-4 alone or in combination with IL-2 appeared to accelerate the growth curve of T cell clones as compared to IL-2 alone. These results show that IL-4 can upregulate CD8 expression on CD4+ T cell clones while not effecting CD4 expression on CD8+ T cell clones. As class I MHC is the ligand for the CD8 molecule, expression of CD8 induced by IL-4 on CD4+ T cells may allow for increased nonspecific cell to cell contact during the course of an inflammatory response.     

Functional heterogeneity among herpes simplex virus-specific human CD4+ T cells.

One hundred thirteen HSV-specific CD4+ T cell clones were established from the PBL of a healthy person and their functional heterogeneity was investigated. All clones proliferated in response to stimulation with HSV in the presence of autologous APC. Among those, 48 clones showed cytotoxic activity to HSV-infected autologous EBV-transformed lymphoblastoid cell line, but not to HSV-infected autologous fibroblasts, HSV-infected allogeneic cells, or K562 cells (group 1). Five clones showed cytotoxicity against HSV-infected autologous cells as well as HSV-infected allogeneic cells and K562 cells (group 2). The cytotoxicity of these clones was found to be mediated by the direct killing but not by the "innocent bystander" killing of target cells. Sixty clones showed no cytotoxic activity, however, among these, 23 revealed HLA-unrestricted and nonspecific cytotoxicity in the presence of PHA in culture (group 3), and the remaining 37 did not show any cytotoxic activity even in the presence of PHA (group 4). The cytotoxic patterns of these clones did not change in activated and resting phases, suggesting that the difference in cytotoxic ability does not depend on cell cycles. The cytotoxic activity of group 1 was inhibited by addition of anti-HLA-DR or anti-CD3 mAb to the culture, whereas these mAb had no effect on the cytotoxicity of group 2. All four groups of clones had helper activity for anti-HSV antibody production by autologous B cells. Moreover it was found that all groups of clones simultaneously produced IL-2, IL-4, and IFN-gamma after culture with APC followed by HSV Ag stimulation. The surface phenotype of all clones was uniformly CD2+, CD3+, CD4+, CD8-, CD29+, CD45RA-, but expression of Leu 8 was varied. These data therefore indicate that HSV-specific human CD4+ T cells are classified into at least four groups according to the presence and specificity of cytotoxicity, i.e., Th cells with HSV-specific and HLA-class II-restricted cytotoxicity, Th cells with HLA-unrestricted and nonspecific cytotoxicity, Th cells with lectin-dependent cytotoxicity, and Th cells without cytotoxic activity. The present finding of functional heterogeneity among virus-specific human CD4+ T cells might shed light on the pathogenesis of CD4+ T cell immunodeficiency, such as human retrovirus infections.     

Generation of CD8 (T8) cytotoxic cells has a preferential requirement for CD4+2H4- inducer cells

CD8 (T8) cells are capable of both suppression and cytotoxicity. However, we have found that the activation of CD8 cytotoxic cells has a preferential requirement for a different CD4 (T4) subset from that previously reported for the activation of CD8 suppressor cells. We have recently characterized two monoclonal antibodies which subdivide CD4 cells into inducers of help for antibody production (CD4+ 4B4+) and inducers of CD8 mediated suppression (CD4+2H4+). We now report that CD4+4B4+2H4- cells also preferentially induce CD8-mediated cytotoxicity. Human peripheral blood T cells were fractionated into CD8, CD4, CD4+2H4+, and CD4+2H4- populations by both the adherence to antibody-coated plates and the fluorescence-activated cell sorter. The cells were cultured 6 days with irradiated allogeneic non-T cells and a cytotoxicity assay was then performed using cryopreserved non-T cells as targets. It was found that the combination of CD4+2H4- cells and CD8 cells resulted in greater cytotoxicity than either CD4 + CD8, or CD4+2H4+ + CD8. The combination of CD4+2H4+ cells with CD8 cells resulted in minimal cytotoxicity, which was similar to that generated by CD8 cells alone. These results were confirmed using anti-4B4 to positively select the reciprocal CD4 subset. Furthermore, the cytotoxicity induced by CD4+2H4- cells was alloantigen specific and Class I major histocompatibility complex restricted. As both CD4+2H4+ and CD4+2H4- cells proliferate equally well to alloantigen and produce similar levels of interleukin 2 (IL-2), it is likely that the generation of CD8 cytotoxic cells requires a signal in addition to IL-2.     

Composite response of naive T cells to stimulation with the autologous lymphoblastoid cell line is mediated by CD4 cytotoxic T cell clones and includes an Epstein-Barr virus-specific component.

We have approached the challenge of generating a primary T cell response to Epstein-Barr virus (EBV) in vitro by stimulating naive T cells with the autologous EBV-transformed lymphoblastoid cell line (LCL), a rich source of EBV-associated cytotoxic T lymphocyte (CTL) epitopes. Responsive T cells from three EBV-seronegative donors were cloned in agarose, phenotyped for T cell markers by flow cytometry, and their cytotoxic properties analyzed in the 51Cr release assay. Most clones (greater than 95%) expressed the CD4 phenotype and 59% of these clones showed cytotoxic properties. The dominant CTL response was specific for FCS-associated epitopes presented by FCS-grown autologous LCL target cells and was restricted by class II HLA antigens. Other clonal components included: (i) an EBV-specific response by HLA-restricted CD4 CTL clones that did not discriminate between A- and B-type EBV transformants; (ii) an EBV-specific response by an HLA-restricted CD4 CTL clone that discriminated between A- and B-type transformants, and (iii) a nonspecific cytotoxic response by CD3+,4+,8-, CD3+,4-,8-, and CD3-,4-,8- clones that were broadly allotypic or restricted to the lysis of K562 target cells. The EBV-specific CTL clones did not lyse the autologous EBV-negative B or T cell blasts and their specificity patterns of lysis were supported by the cold target competition data. These studies highlight the role of CD4 CTL in the establishment in vitro of a primary immune response to a human virus.     

Therapeutic induction of regulatory, cytotoxic CD8+ T cells in multiple sclerosis

In the setting of autoimmunity, one of the goals of successful therapeutic immune modulation is the induction of peripheral tolerance, a large part of which is mediated by regulatory/suppressor T cells. In this report, we demonstrate a novel immunomodulatory mechanism by an FDA-approved, exogenous peptide-based therapy that incites an HLA class I-restricted, cytotoxic suppressor CD8+ T cell response. We have shown previously that treatment of multiple sclerosis (MS) with glatiramer acetate (GA; Copaxone) induces differential up-regulation of GA-reactive CD8+ T cell responses. We now show that these GA-induced CD8+ T cells are regulatory/suppressor in nature. Untreated patients show overall deficit in CD8+ T cell-mediated suppression, compared with healthy subjects. GA therapy significantly enhances this suppressive ability, which is mediated by cell contact-dependent mechanisms. CD8+ T cells from GA-treated patients and healthy subjects, but not those from untreated patients with MS, exhibit potent, HLA class I-restricted, GA-specific cytotoxicity. We further show that these GA-induced cytotoxic CD8+ T cells can directly kill CD4+ T cells in a GA-specific manner. Killing is enhanced by preactivation of target CD4+ T cells and may depend on presentation of GA through HLA-E. Thus, we demonstrate that GA therapy induces a suppressor/cytotoxic CD8+ T cell response, which is capable of modulating in vivo immune responses during ongoing therapy. These studies not only explain several prior observations relating to the mechanism of this drug but also provide important insights into the natural immune interplay underlying this human immune-mediated disease.     

The human MHC-restricted cellular response to herpes simplex virus type 1 is mediated by CD4+, CD8- T cells and is restricted to the DR region of the MHC complex

The nature of the in vitro human cytotoxic T-cell responder population to HSV type 1 (HSV-1) was studied. In 5-day HSV-1-stimulated cultures that contained MHC-restricted activity, two phenotypically distinct populations of cells were present that were capable of lysing HSV-1-infected B cell lines in a 5-h 51Cr-release assay. The first was CD4+, CD8-, CD16- cell typical of class II-restricted T cells, whereas the other population bore a CD4-, CD8-, CD16+ NK-cell phenotype. Elimination of the NK cell fraction from bulk cultures by using anti-CD16 plus C frequently resulted in cell populations that killed in an Ag-specific, HLA-DR-restricted fashion. In some cases the anti-CD16-pretreated cultures retained a killing population that was unrestricted to MHC products. In no instance were any cytotoxic T cells that were restricted to class I Ag in evidence. Limiting dilution analysis of precursor frequency indicated that about 1 in 4000 to 1 in 8000 cells from peripheral blood are specific for HSV-1 in seropositive individuals. Comparisons of HLA class I-matched and HLA class II-matched targets with the autologous target by using limiting dilution analysis yielded results entirely consistent with those obtained in the bulk culture assay system.     

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.     

A previously unrecognized large fraction of cytotoxic lymphocyte precursors is present in CD4+ human peripheral blood T cells

We describe a limiting dilution (LD) culture system in which cell sorter-purified CD4+ (and CD8+) peripheral blood T cells are cocultured with irradiated, anti-CD3 mab-producing OKT3 hybridoma cells. Under these conditions, one out of 2-3 CD4+ (and CD8+) T cells is induced to clonal proliferation. In striking contrast to previously described LD culture systems, every growing CD4+ cell clone displayed cytotoxic activity when tested in a lectin-facilitated 51Cr release assay against P815 target cells. This contrasts with the development of cytotoxic CD4+ T cells in alloantigen-stimulated LD cultures, where only one out of 15-20 proliferating CD4+ cells killed P815 in the presence of PHA, and one out of 300-500 proliferating CD4+ cells displayed alloantigen-specific cytotoxic activity. Furthermore, we have established antigen-specific proliferating CD4+ T cell clones which do not exert antigen-specific cytotoxicity but can be cytotoxic when crosslinked to target cells via lectin or monoclonal antibody (anti-CD3, anti-TCR). Our results show that a previously unrecognized large fraction (at least 30-50%) of all peripheral blood CD4+ T cells can give rise to cytotoxic effector cells. The mode of CD4+ T cell activation (OKT3 hybridoma versus alloantigen) thus determines whether the intrinsic cytotoxic capacity of CD4+ T cells is functionally activated or not.     

Lysis of tumor cells by CD3+4-8-16+ T cell receptor alpha beta- clones, regulated via CD3 and CD16 activation sites, recombinant interleukin 2, and interferon beta 1

A small subpopulation (about 2%) of normal CD3+ human T lymphocytes lacks both CD4 and CD8 antigens. We have cloned these cells from peripheral blood lymphocytes (PBL) obtained from healthy individuals and from a patient with severe combined immunodeficiency. Six out of seven CD3+4-8-clones exert strong cytolytic activity against a variety of so-called NK-susceptible and -nonsusceptible tumor target cells. Their target cell specificity spectrum can virtually be as wide as that of CD3-NK cell-derived clones, with strong lytic capacity. Some of these clones also exert antibody-dependent cellular cytotoxicity (ADCC), a characteristic of NK cell-derived clones but not of CD3+4+ or CD8+ mature T cell-derived clones. Such CD3+ T cell clones do not express the CD16 (IgG Fc receptor) antigen, but as we demonstrate here, the CD16 antigen can be identified on CD3+4-8-clones. Both ADCC activity and CD16 antigen expression are lower in CD3+4-8- than in CD3- NK cell clones. Lytic activity of mature CD3+4+ or CD8+ and CD3- NK cell clones can be augmented, respectively, by anti-CD3 or anti-CD16 monoclonal antibodies (MAb), but that of CD3+4-8- clones are augmented by both MAb. Lytic activity of CD3+4+ or CD8+ clones is considerably enhanced after 3 hr of incubation with recombinant IL 2, as found for CD3- NK cells. Enhancement of lytic activity of allospecific CD3+4+ or CD8+ clones requires 18 hr of incubation. Thus, CD3+4-8-16+ cells share several features with CD3- NK cells. However, they express the CD3 antigen, which is characteristic for CD4+ or CD8+ mature T cells. Our results also indicate that although CD3+4-8- clones react with five preparations of anti-CD3 MAb tested, these clones do not express a classical CD3+/Ti alpha, beta antigen receptor complex. This is suggested by the finding that the CD3+4-8- clones do virtually not express the common epitope of the T cell receptor alpha, beta-chains as identified by the WT31 MAb. These CD3+4-8- lymphocytes may represent functionally mature lymphocytes of a distinct T cell subpopulation having a particular immune function.     

Establishment and functional characterization of human herpesvirus 6-specific CD4+ human T-cell clones.

In order to clarify the protective immune responses against a newly identified herpesvirus, human herpesvirus 6 (HHV-6), we established HHV-6-specific human T-cell clones and examined their functional properties. Five CD3+CD4+CD8- T-cell clones, which proliferated in response to stimulation with two different strains of HHV-6 in the presence of autologous antigen-presenting cells but not with herpes simplex virus type 1 or human cytomegalovirus, were established from peripheral blood lymphocytes of a healthy individual. The proliferative response of all T-cell clones to HHV-6 antigen was inhibited by addition of anti-HLA-DR monoclonal antibody, indicating that these clones were human leukocyte antigen (HLA) class II DR restricted. Of the five clones, two lysed HHV-6-infected autologous lymphoblasts, but not HHV-6-infected allogeneic cells or natural killer-sensitive K562 cells (group 1); one showed cytotoxicity against HHV-6-infected autologous lymphoblasts as well as HHV-6-infected allogeneic cells and K562 cells (group 2); and the remaining two showed no cytotoxic activity (group 3). The cytotoxic activity of group 1 was inhibited by addition of anti-HLA-DR monoclonal antibody to the culture, whereas this monoclonal antibody had no effect on the cytotoxicity of group 2 and did not induce the cytotoxicity of group 3. Perforin, which is one of the mediators of cytotoxicity, was abundantly expressed in group 1 and 2 clones. Moreover, all groups of clones produced gamma interferon after culture with antigen-presenting cells followed by HHV-6 antigen stimulation. These results suggest that HHV-6-specific CD4+ T cells have heterogeneous functions.     

Induction and blocking of cytolysis in CD2+, CD3- NK and CD2+, CD3+ cytotoxic T lymphocytes via CD2 50 KD sheep erythrocyte receptor

The 50 KD sheep red blood cell antigen receptor CD2 is the earliest T cell differentiation marker and is present on all blood-derived T cells, including natural killer (NK) cells. The CD2 antigen is also known to serve as an important activation site regulating various T cell functions. We report that anti-CD2 monoclonal antibodies (MAb) block MHC-restricted class I- and class II-specific cytolysis by CD2+, CD3+ clones of the relevant target cells, irrespective of whether lysis by these clones is blocked by anti-CD3 or anti-CD8 MAb. Moreover, anti-CD2 MAb (but not anti-CD3 MAb) are able to reduce MHC-nonrestricted, nonspecific cytolysis: a) by CD2+, CD3+ clones of K562 target cells; and b) by CD2+, CD3 NK clones of K562 as well as Daudi cells. Different preparations of anti-CD2 MAb vary in their capacity to inhibit cytolysis. For cloned effector cells, the percent inhibition of lysis by CLB-T11 greater than Lyt-3 MAb, whereas with "fresh" NK cells, the lysis inhibitory ability of Lyt-3 greater than CLB-T11. The antibody-dependent cellular cytotoxicity by "fresh" and cloned NK cells is not inhibited by anti-CD2 MAb. Anti-CD2 MAb also prevent the induction of lysis by cross-linked anti-CD3 MAb, e.g., by CD2+, CD3+ cloned cloned cells against (IgG-FcR+) Daudi cells. Anti-CD2 MAb can also induce cytolysis in some, but not all, CD2+, CD3- NK clones against xenogeneic P815 mouse mastocytoma cells. Anti-CD2 MAb, in combination with lectins (PHA or Con A: pretreatment of effector cells), can also induce cytolytic activity by CD2+, CD3+ clones against Daudi cells. Our data therefore support the concept that the CD2 antigen is an important activation site regulating a wide variety of T cell functions including cytolysis. Whether ligand interaction with the CD2 antigens results in augmentation or inhibition of T cell functions may very well depend on the type of CD2 antigen-ligand interaction, e.g., cross-linked ligand-receptor interaction may, in general, enhance the various T cell functions, whereas noncross-linked ligand-receptor interactions may inhibit such functions, as we and other investigators demonstrated earlier for the CD3/Ti antigen-receptor complex activation site.     

CD103 is a marker for alloantigen-induced regulatory CD8+ T cells

The alphaEbeta7 integrin CD103 may direct lymphocytes to its ligand E-cadherin. CD103 is expressed on T cells in lung and gut and on allograft-infiltrating T cells. Moreover, recent studies have documented expression of CD103 on CD4+ regulatory T cells. Approximately 4% of circulating CD8+ T cells bear the CD103 molecule. In this study, we show that the absence or presence of CD103 was a stable trait when purified CD103- and CD103+ CD8+ T cell subsets were stimulated with a combination of CD3 and CD28 mAbs. In contrast, allostimulation induced CD103 expression on approximately 25% of purified CD103- CD8+ T cells. Expression of CD103 on alloreactive cells was found to be augmented by IL-4, IL-10, or TGF-beta and decreased by addition of IL-12 to MLCs. The alloantigen-induced CD103+ CD8+ T cell population appeared to be polyclonal and retained CD103 expression after restimulation. Markedly, in vitro-expanded CD103+ CD8+ T cells had low proliferative and cytotoxic capacity, yet produced considerable amounts of IL-10. Strikingly, they potently suppressed T cell proliferation in MLC via a cell-cell contact-dependent mechanism. Thus, human alloantigen-induced CD103+ CD8+ T cells possess functional features of regulatory T cells.     

Tumor-selective cytolysis is executed exclusively by CD45R+ CTL whereas allo-specific cytotoxicity can be executed also by CD45R- CTL

Naive and memory CD4+ T helper cells can be distinguished on the basis of expression of the CD45R molecule. Whether this dichotomy applies also to CD8+ T cells has not yet been established. In the present investigation the cytolytic activity of peritoneal CD8+CD45R+ and CD8+CD45R- T cells from tumor- and allo-immunized rats has been studied. More than 90% of the CD8+ peripheral blood T lymphocytes expressed the CD45R molecule, whereas in the peritoneal cavity about 60% of the CD8+ T cells displayed the CD45R+ phenotype. Analysis of cytotoxicity of sorted peritoneal cells of W439 tumor-immunized donors demonstrated selective cytolytic activity of the CD5+CD4-CD8+CD45R+ subpopulation to W439 lymphoma target cells but no effect of CD5+CD4-CD8+CD45R- lymphocytes. None of these lymphocyte populations exhibited cytolytic activity to the NK-sensitive cell line YAC-1, whereas the CD5-CD45R+ population showed strong cytotoxicity to YAC-1 cells. In allo-immunized rats both CD5+CD4- CD8+CD45R+ and CD5+CD4-CD8+CD45R- peritoneal cells exhibited strong allo-specific cytolytic activity, but no activity to YAC-1 cells. Both CD5+CD4-CD8+CD45R+ and CD5+CD4-CD8+CD45R- cells from tumor-immunized rats proliferated in response to Con A and rIL-2. This is the first study demonstrating that tumor-selective cytolytic CD8+ T cells express the CD45R molecule and that allo-specific cytolytic CD8+ T cells are found in both the CD45R+ and CD45R- populations.     

Helper activity in antigen-specific antibody production mediated by CD4+ human cytotoxic T cell clones directed against herpes simplex virus

Three HSV type 1 (HSV-1) and HSV type 2 (HSV-2) common ("HSV-type common") and three HSV-1 specific CTL clones, which were CD3+, CD4+, CD8-, 4B4+, and 2H4-, were established. These clones proliferated in response to stimulation with HSV in the presence of autologous APC. The HSV type specificity of the proliferative response was identical with that of the cytotoxic activity of the clones. The cytotoxic activity and the proliferative response were both inhibited by addition of anti-HLA-DR mAb to the culture. After culture of these CTL clones with autologous B cells and macrophages followed by HSV Ag stimulation, anti-HSV antibody was detected in the culture supernatant. The HSV type specificity of the helper function for antibody production was identical with that of the cytotoxicity, i.e., HSV-type common clones, upon stimulation with either HSV-1, or HSV-2, and HSV-1-specific clones, upon stimulation with HSV-1 but not with HSV-2, showed helper activity for anti-HSV antibody production by autologous B cells. Moreover, it was found that these clones produced humoral factors which help autologous B cells to produce antibody. The helper factors were produced by T cell clones in an HSV-type-specific manner. These data suggest that some CD4+ T cells can simultaneously manifest both specific cytotoxicity and helper activity for Ag-specific antibody production by B cells, and that these multifunctional T cells might play an important role in protection against viral infection.     

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.     

Hyperstimulatory CD1a+CD1b+CD36+ Langerhans cells are responsible for increased autologous T lymphocyte reactivity to lesional epidermal cells of patients with atopic dermatitis.

We studied whether abnormalities in epidermal APC could be responsible for intracutaneous T cell activation in atopic dermatitis (AD). In the absence of added Ag, patients' peripheral blood T cells demonstrated significantly increased proliferation to their autologous lesional epidermal cells (mean +/- SEM = 19,726 +/- 9,754 cpm [3H]TdR uptake) relative to epidermal cells from uninvolved AD skin (2179 +/- 697 cpm) (n = 10) (p = 0.0001, log transformed data). AD T cell proliferative responses to autologous epidermal cells were dependent upon cells expressing HLA-DR, CD1a, and CD36, and not upon keratinocytes or their cytokines. Ultrastructurally, these cells ranged from typical Langerhans cells to indeterminate cells with irregular nuclear contours. Enriched populations of lesional AD Langerhans cells were highly stimulatory for autologous T cells, whereas equal numbers of Langerhans cells from non atopic epidermis were poor stimulators, even at high concentrations. The dermal perivascular dendritic cell markers CD36 and CD1b, not usually present on normal epidermal APC, were expressed by 40 and 60% of lesional AD CD1a+ epidermal Langerhans cells, respectively. Addition of anti-CD1b to cocultures of AD epidermal cells and autologous T lymphocytes augmented T cell activation, suggesting that the expression of CD1b by AD Langerhans cells may represent over expression of a molecule functionally linked to the enhanced T cell stimulatory capacity of these cells. Thus, stimulatory signals for T cells contained within AD epidermis are carried by cells in an abnormal differentiation state as indicated by expression of phenotypic characteristics of both epidermal and dermal antigen presenting cells (HLA-DR+, CD1a+, CD1b+, CD36+). We propose that activation of autologous T cells by an altered cutaneous APC population may represent a mechanism for the hyperactive and disordered cell-mediated immune response that characterizes the dermatitic lesions of AD.     

Function of the CD4 and CD8 molecules on human cytotoxic T lymphocytes: regulation of T cell triggering

The function of the T cell differentiation antigens CD4 (Leu-3/T4) and CD8 (Leu-2/T8) on human cytotoxic T lymphocytes (CTL) is presently seen only in conjugate formation between CTL and target cell via class II or class I MHC antigens rather than in the later killing steps. In this study, human CD4+ and CD8+ CTL clones were used to investigate the effects of monoclonal antibodies against these differentiation antigens on nonspecific triggering of cytotoxicity. Cytotoxicity was induced either by antibodies against the CD3 (T3) antigen or by the lectins Con A and PHA. Anti-CD4 or anti-CD8 antibodies specifically inhibited all types of cytotoxicity of CD4+ or CD8+ CTL, respectively, regardless of the specificity of the CTL for class I or class II HLA antigens and regardless of whether target cells expressed class I or class II antigens. These results are incompatible with an exclusive role of the CD4 and CD8 molecules in MHC class recognition and are discussed with respect to a function as negative signal receptors for these molecules on CTL.     

Interleukin-2- and mitogen-activated NK-like killer cells from highly purified human peripheral blood T cell (CD3+ N901-) cultures

In this study, highly purified (HP) CD3-positive N901-negative T lymphocytes could be induced to become natural killer (NK)-like in culture in the presence of recombinant interleukin-2 (rIL-2) and phytohemagglutinin (PHA). Thus, purified CD3+ N901- T cells from fresh human peripheral blood were obtained by negative selection using an indirect panning technique. To ensure that T lymphocyte fractions were completely devoid of any detectable NK cells, two additional purification procedures were employed: incubation of post-pan T cells with the NK-cytotoxic lysomotropic agent L-leucinemethylester, and complement-mediated lysis using the NK cell specific NKH1a monoclonal antibody. Purity of CD3+ N901- cells could be confirmed by surface marker analysis, whereby two NK-associated antigens, N901 and H-25, were undetectable, while 94 +/- 1% of cells expressed the CD3 (Leu-4) antigen. On functional analysis, fresh HP CD3+ N901- cells exhibited no cytotoxic activity against the standard NK target K562. When HP NK-depleted T lymphocytes were cultured for 7 days in the presence of rIL-2 (100 U/ml), neither surface antigen expression nor cytotoxic activity against K562 changed significantly. However, significant cytotoxicity against K562 [18 +/- 5% specific lysis at 25:1 effector:target (E/T) ratio] could be induced when HP CD3+ N901- cells were grown for 7 days in the presence of rIL-2 and PHA (0.5% v/v). Concomitantly, antigens N901 and H-25 were found to be coexpressed on a minor proportion (22 +/- 16 and 22 +/- 6%, respectively) of CD3+ (88 +/- 2% on day 7) cells. Four-week long-term culture of HP NK-depleted T cells in the presence of rIL-2 and PHA yielded a continuous increase in cytotoxicity against K562 cells (0 up to 46% specific lysis at 25:1 E/T ratio). Of particular interest was the emergence of cytotoxicity against the NK-resistant Daudi cell target (15 +/- 8% specific lysis at 25:1 E/T ratio on day 21). Expression of antigens N901 and H-25 as well as CD3 remained essentially unchanged in long-term culture. In sorting experiments, the H-25+ cell fraction was significantly enriched for cytotoxicity against K562, when compared to both H-25- and unseparated cell fractions. In summary, our results suggest that a proportion of HP CD3+ N901- T lymphocytes may give rise to cells that exhibit NK-like functional and phenotypic properties.