Analysis of clones derived from human CD7+CD4-CD8-CD3- thymocytes.

The differentiation of human thymocyte precursors was studied by analysis of clonal progeny of CD4-CD8-CD3- (triple negative or TN) thymocytes. Using a culture system of phytohemagglutinin, IL-2, and irradiated allogeneic lymphoid feeder cells, we found that 48% of clones (104 total) derived from TN thymocyte suspensions were TCR gamma delta cells, 12% of clones were TCR alpha beta cells, and 34% were CD16+CD3- cells. Importantly, 6% of clones were novel subsets of CD4+CD8-CD3- or CD4-CD8+CD3- thymocytes. The majority of TCR alpha beta, TCR gamma delta, and CD16+CD3- clones expressed low levels of CD4. Molecular analysis of freshly isolated TN- thymocytes prior to in vitro culture demonstrated that up to 40% of cells had TCR gamma, delta, and beta gene rearrangements, but were negative in indirect immunofluorescence assays for cytoplasmic TCR delta and beta. These data provide evidence at the clonal level for the presence of precursors of the TCR alpha beta and TCR gamma delta lineages in the human TN thymocyte pool. Moreover, a substantial proportion of freshly isolated human TN thymocytes had already undergone TCR gene rearrangement prior to in vitro culture. Whether these precursors of the TCR alpha beta and TCR gamma delta lineages mature from cells already containing TCR gene rearrangements into sTCR+ cells or differentiate in vitro from cells with TCR genes in germline configuration remains to be determined. Nonetheless, these data demonstrate that the predominant clone types that grow out of human TN thymocytes in vitro are TCR gamma delta and NK cells.     

Delineation of chicken thymocytes by CD3-TCR complex, CD4 and CD8 antigen expression reveals phylogenically conserved and novel thymocyte subsets.

To further define the relationship between thymocyte subsets and their developmental sequence, multi-parameter flow cytometry was used to determine the distribution of the CD3-TCR complex and the accessory molecules CD4 and CD8 on chicken thymocytes. As in mammals, adult thymocytes could be subdivided into CD3-, CD3lo, and CD3hi staining populations. CD4 and CD8 distribution on such populations revealed the presence of CD3-CD4+CD8- and CD3-CD4-CD8+ thymocytes, putative precursors to CD4+CD8+ cells, detectable in the adult and at high frequency during ontogeny. Of particular interest was the existence of CD3lo expression on CD4+CD8- and CD4-CD8+, and in some instances, on CD4-CD8- thymocytes. Such phenotypes are not easily detectable in the mammalian thymus but were readily observed in both adult and embryonic chicken thymus from 16 days of embryogenesis. Further analysis of the TCR lineage of these CD3lo cells revealed that they were essentially all of the alpha beta TCR type. Mature CD3hi thymocytes were found within the CD4+CD8+ and CD4+CD8- and CD4-CD8+ subsets. Both alpha beta and gamma delta TCR lineage thymocytes were detected within all CD4- and CD8-defined subsets, thus identifying novel thymocyte subsets in the chicken thymus, namely alpha beta TCR+CD4-CD8- and gamma delta TCR+ CD4+CD8- cells. Hence, this analysis of chicken thymocytes, while confirming the phylogenically conserved nature of the thymus, has revealed novel T cell subsets, providing further insight into the complexity of mainstream thymocyte maturation pathways.     

Interleukin 7 preferentially supports the growth of gamma delta T cell receptor-bearing T cells from fetal thymocytes in vitro.

Murine fetal thymus cells were cultured with various interleukins (IL-1, 2, 3, 4, 5, 6, and 7) in the absence or presence of phorbol 12-myristate 13-acetate (PMA), and it was found that only IL-4 and IL-7 induced a prominent proliferative response in the presence of PMA. A large proportion of cells grown in the cultures of fetal thymus cells (days 15 and 17 of gestation) stimulated with PMA plus IL-4 or with PMA plus IL-2 remained CD4-CD8-. In marked contrast, nearly 70% of the cells generated in the cultures of the same fetal thymocytes stimulated with PMA plus IL-7 expressed CD8 on their surface. Approximately 30% of these cells expressed TCR gamma, delta, whereas TCR alpha beta+ cells were virtually undetectable. The cells grown in cultures stimulated with PMA plus IL-7 comprised three populations: CD4-Lyt-2-3-, CD4-Lyt-2 + Lyt-3- and CD4-Lyt-2 + Lyt-3+, and that TCR gamma delta+ T cells were found in all three populations. It was also found that the addition of IL-7 in the culture of adult CD4-CD8- thymocytes on the monolayer of a thymic stromal cell line, which selectively promotes the generation of alpha beta T cells, resulted in the generation of gamma delta T cells. These results strongly suggest that IL-7 plays an important role in the development of gamma delta T cells.     

Decreases in alpha beta T cell receptor negative T cells and CD8 cells, and an increase in CD4+ CD8+ cells in active Hashimoto''s disease and subacute thyroiditis.

We examined peripheral lymphocyte subsets in patients with autoimmune thyroid disease, or subacute thyroiditis, in the active stage when possible. During destructive thyrotoxicosis arising from alpha beta T cell receptor (TCR) negative T (WT31-CD3+) cells and CD8 (CD4-CD8+) cells decreased and those of CD4+CD8+ cells increased slightly, resulting in proportional increases in CD4 (CD4+CD8-) cells, non-T, non-B (CD5-CD19-) cells, and the CD4/CD8 cell ratio. Changes were similar in active subacute thyroiditis. During stimulative thyrotoxicosis in active Graves' disease, the numbers of such T lymphocyte subsets were not changed, but only the number of CD5+ B (CD5+CD19+) cells increased markedly, resulting in proportional decreases in total T (CD3+) cells, alpha beta+ TCR T (WT31+CD3+) cells, CD8 cells, and non-T, non-B cells. A serial study of some of the patients showed opposite changes in alpha beta TCR- T cells, the CD4/CD8 cell ratio, and CD5+ B cells between the active stages of Graves' and Hashimoto's diseases. alpha beta TCR- T cells were mostly gamma delta TCR+ T (IIF2+ CD3+) cells in these patients. These data suggest that alpha beta TCR-T (gamma delta TCR+ T), CD8, and CD4+ CD8+ cells are important in thyroid destruction in Hashimoto's disease and subacute thyroiditis, and that CD5+ B cells are important in thyroid stimulation in Graves' disease.     

Human double-negative (CD4-CD8-) T cells bearing alpha beta T cell receptor possess both helper and cytotoxic activities.

Expression of CD4 or CD8 on the cell surface is an important guide for discriminating the immunological functions of T cells. However, a minor T cell subset, which lacks both CD4 and CD8 molecules but bears the usual form of T cell receptor (TCR) alpha beta (CD4-CD8-TCR alpha beta+ T cells), has recently been found not only in mice but also in humans, and its role in immune response is now of considerable interest. In order to clarify the characteristics of this newly defined T cell subpopulation, we established five IL-2-dependent CD4-CD8-TCR alpha beta+ T cell clones from the peripheral blood of a healthy individual, and examined their various biological functions. It was found that all clones not only helped B cells in immunoglobulin production, but also exerted major histocompatibility complex-unrestricted cytotoxicity. Although their CD3/TCR complexes were functionally competent, the cytotoxicity seemed to be mediated via unknown molecules other than the CD3/TCR complex, as evidenced by the failure of CD3 MoAb to inhibit the cytotoxic activity. Our present findings showed that CD4-CD8-TCR alpha beta+ T cells possess potential bifunction, i.e. helper and cytotoxic activities. Their roles in the pathogenesis of immunodeficiency are discussed.     

Definition of unique traits of human CD4-CD8- alpha beta T cells.

We have studied the nature of human CD4-CD8- (double negative) alpha beta T cells to determine whether they possess unique characteristics which could further differentiate them from conventional CD4+ or CD8+ (single positive) T cells. We observed that double negative TCR alpha beta+ T cells differ from single positive T cells in the following respects: (i) their T cell receptor (TCR) repertoire is different, as revealed by the analysis of 47 clones derived from three individuals and by analysis of peripheral blood lymphocytes (PBL) prior to in vitro manipulation; (ii) their in vivo CD3:TCR expression is lower before in vitro manipulation and expansion; (iii) their direct proliferative response to IL-3, which is not mediated by secondary release of other T cell growth factors. These characteristics have also been recently ascribed to murine double negative alpha beta T cells, which develop extrathymically and are considered to be a distinct T cell lineage. Our data suggest that, like their murine counterparts, human double negative alpha beta T cells may represent a distinct T cell lineage which might develop extrathymically.     

Patterns of membrane TcR alpha beta and TcR gamma delta chain expression by normal blood CD4+CD8-, CD4-CD8+, CD4-CD8dim+ and CD4-CD8- lymphocytes.

Enriched CD4+CD8-/CD4-CD8-, CD4-CD8+/CD4-CD8- and CD4-CD8- cell suspensions were prepared from normal peripheral blood by selective immunomagnetic depletion of monoclonal antibody-defined lymphocyte populations. Subsequent examination of these modified cell fractions by two-colour flow cytometry provided a means of determining the expression of membrane T-cell receptor (TcR)alpha beta and TcR gamma delta chains by both major (CD4+ and CD8+) and minor (CD3+CD4-CD8dim+ and CD3+CD4-CD8-) lymphocyte subpopulations. Normal CD4+CD8- lymphocytes were almost invariably (greater than 99%) TcR alpha beta+, whereas lymphocytes expressing membrane CD8, which could be further subdivided according to differences in fluorescent staining intensity into CD3+CD4-CD8+, CD3+CD4-CD8dim+ and CD3-CD4-CD8dim+ components, were characterized by distinct differences in patterns of TcR chain expression. In contrast to CD3+CD4-CD8+ cells, which were predominantly (99%) TcR alpha beta+, CD3+CD4-CD8dim+ lymphocytes showed a significant proportion (33%) of TcR gamma delta+ cells (natural killer-associated CD3-CD4-CD8dim+ cells were uniformly TcR-). The highest proportion (62%) of TcR gamma delta+ cells was associated with the CD3+CD4-CD8- fraction, but these studies also revealed that a significant minority of this population was TcR alpha beta+. Despite some evidence for normal inter-individual variation, further analysis of membrane CD8 fluorescent intensities confirmed clear differential relationships for TcR alpha beta and TcR gamma delta chain expression.     

Clonally expanded CD3+, CD4-, CD8- cells bearing the alpha/beta or the gamma/delta T-cell receptor in patients with the lymphoproliferative disease of granular lymphocytes.

Among 60 retrospectively assessed patients with the lymphoproliferative disease of granular lymphocytes (LDGL), lymphocytes from only 2 patients had the CD3+, CD4-, CD8- phenotype, rarely observed in normal peripheral blood lymphocytes (about 3%). In this paper we report a detailed study of lymphocytes isolated from these two patients. The cells from patients 1 had the CD3+, CD4-, CD8-, WT31-, beta F1-, TCR delta 1+, Ti gamma A-, BB3+, CD7+, CD16-, CD57+ phenotype, while cells from patient 2 had a phenotype even more rarely observed on normal lymphocytes: CD3+, CD4-, CD8-, WT31+, beta F1+, TCR delta 1-, CD7+, CD16-, CD57+. Thus, in only the first case the cells expressed the gamma/delta T-cell receptor (TCR) on the membrane, while the cells from the second case had the alpha/beta TCR. Genetic studies showed that in case 1 the TCR gamma gene was rearranged and the beta chain gene configuration was germline; the TCR mRNA was of normal size for the gamma chain, while that of the beta chain was truncated. Case 2 had the beta and the gamma genes of the TCR rearranged, but only the alpha and beta mRNA were expressed. In agreement with these findings, the delta chain gene of the TCR was rearranged in case 1 and was deleted in case 2. Cytotoxic activity was absent in cells from case 1 and low in case 2; in the latter, the lytic activity could be up-regulated following incubation with IL-2 or an anti-CD3 monoclonal antibody. Our study indicates that CD3+, CD4-, CD8- lymphocytes are rarely expanded in patients with LDGL. The detection of a lymphoproliferative disease of a CD3+, CD4-, CD8-, alpha/beta + cell may contribute to a better characterization of this novel lymphocytic subpopulation.     

IL-2 and IL-7 differentially induce CD4-CD8- alpha beta TCR+NK1.1+ large granular lymphocytes and IL-4-producing cells from CD4-CD8- alpha beta TCR+NK1.1- cells: implications for the regulation of Th1- and Th2- type responses

Effector functions of CD4-CD8- double negative (DN) alpha beta TCR+ cells were examined. Among mouse DN alpha beta TCR+ thymocytes, NK1.1+ cells expressing a canonical V alpha 14/J alpha 281 TCR but not NK1.1- cells produce IL-4 upon TCR cross-linking and IFN-gamma upon cross- linking of NK1.1 as well as TCR. Production of IL-4 but not IFN-gamma from DN alpha beta TCR+NK1.1+ cells was markedly suppressed by IL-2. Whereas V alpha 14/J alpha 281 TCR+ cells express NK1.1+, these cells are not the precursor of DN alpha beta TCR+NK1.1+CD16+B220+ large granular lymphocytes (LGL). IL-2 induces rapid proliferation and generation of NK1.1+ LGL from DN alpha beta TCR+NK1.1- but not from DN alpha beta TCR+NK1.1+ cells. LGL cells exhibit NK activity and produce IFN-gamma but not IL-4 upon cross-linking of surface TCR or NK1.1 molecules. In contrast to IL-2, IL-7 does not induce LGL cells or NK activity from DN alpha beta TCR+NK1.1- cells but induces the ability to produce high levels of IL-4 upon TCR cross-linking. Our results show that DN alpha beta TCR+ T cells have several distinct subpopulations, and that IL-2 and IL-7 differentially regulate the functions of DN alpha beta TCR+ T cells by inducing different types of effector cells.      

Interleukin-4 induces expression of the CD45RA antigen on human thymocyte subpopulations

Interleukin-4 (IL-4) is a multifunctional lymphokine which promotes the growth and/or maturation of multiple cell types. We have examined the ability of IL-4 to promote the phenotypic maturation of subsets of human thymocytes. When cultured in serum-free medium supplemented with recombinant IL-4, a subset of immature CD3-CD45RA- human thymocytes ceased to express the CD1 common thymocyte antigen and acquired phenotypic features characteristic of relatively mature thymocytes, such as high-density expression of the CD3 antigen and de novo expression of the CD45RA isoform of the common leukocyte antigen family. These changes, which were not seen in cells cultured in medium alone, occurred over an 8-9 day period and were accompanied by a significant increase in cell size. The CD45RA+ cells that derived from these immature CD3-CD45RA- precursors were mainly CD4-CD8- or CD8+ cells, and a significant proportion of these cells expressed the T cell receptor delta chain. IL-4 also increased expression of the CD45RA antigen on the more mature CD3+ thymocyte population. However, the CD45RA+ cells derived from IL-4 stimulated CD3+ thymocyte precursors expressed either the CD4 or the CD8 antigen, and virtually all expressed alpha/beta TCR chains. Studies of cell viability and cell growth indicated that these findings were due to direct changes in the phenotype of responsive cells rather than the growth or selective survival of a small number of mature thymocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Delineation of human thymocytes with or without functional potential by CD1-specific antibodies

Hematopoietic precursors lacking T cell antigen receptors (TCR-CD3-) and CD4 and CD8 surface markers (i.e. double-negative thymocytes) give rise to functionally mature T lymphocytes. Yet their major progeny are immunologically unresponsive thymocytes in spite of having acquired TCR-CD3 and CD4-CD8. Because only mature thymocytes migrate to peripheral lymphoid organs and most thymocytes die in situ, the knowledge of the events associated with functional maturation in the double-negative thymocyte progeny is a fundamental question in T cell development. We reasoned that a clue to trace the fate of early human thymocytes may perhaps come from the study of the developmental acquisition of CD1 antigen, currently used to define better the functionally inert CD4+8+ (double-positive) stage and absent in mature, medullary thymocytes and peripheral T cells. By using antibodies specific for CD1 (HTA 1/T6) we show here that a large fraction of double-negative thymocytes also express CD1. CD1+3-, CD1+3+, CD1-3+, and CD1-3- subsets all exist. The CD1+3- subset generates CD1+3-4-8+ precursors of CD1+ double-positive cells. A large portion of the CD1+3+ subset bears TCR gamma delta-CD3 complexes. The CD1- subsets are responsive in assays of function, in which they can be stimulated to use the interleukin 2 pathway of proliferation and to mediate cytotoxicity. In contrast, all CD1+ thymocytes behave as functionally inert cells. Thus, the CD1 surface marker delineates human thymocyte precursors and their products which lack, or possess, functional potential in vitro, on both alpha beta and gamma delta lineages.     

Intrathyroidal lymphocyte subsets, including unusual CD4+ CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells, in autoimmune thyroid disease.

Intrathyroidal lymphocyte subsets were analysed in 13 euthyroid patients with autoimmune thyroid disease by two-colour flow cytometry and compared with subsets in peripheral blood. In both Graves' and Hashimoto's diseases, proportions of intrathyroidal CD5- B cells were higher than in peripheral blood. The numbers of such cells were correlated with serum levels of anti-thyroid microsomal antibodies. Proportions of T cells bearing alpha beta chains of T cell receptors (TCR alpha beta+ T; T alpha beta) and CD16+CD57+ natural killer (NK) cells were lower in the thyroid, but proportions of CD3hiTCR alpha beta-TCR gamma delta+ (T gamma delta) cells were not different. Proportions of CD4+Leu-8- helper T cells and CD4+CD57+ germinal centre T cells were higher and proportions of CD4+Leu-8+ suppressor-inducer T cells and CD8+CD57+ or CD8+CD11b+ suppressor T cells were lower than in the blood in both diseases. Proportions of CD5+ B cells were high in Graves' disease, and proportions of CD8+CD11b- cytotoxic T cells were high in Hashimoto's disease. Unexpectedly, CD4+CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells were present in thyroid tissues of both diseases. These findings suggest that: (i) an imbalance in the numbers of regulatory T cells and of NK cells that had appeared in the thyroid resulted in the proliferation of CD5- B cells, which were related to thyroid autoantibody production; (ii) CD5+ B cells and cytotoxic T cells are important for the different pathological features in Graves' and Hashimoto's diseases, respectively; and (iii) intrathyroidal CD4+CD8+ cells and CD3loTCR alpha beta lo/-CD4-CD8- cells may be related to the pathogenesis of autoimmune thyroid disease.     

Identification of αβ and γδ T Cell Receptor-Positive Cells

Two lineages of T lymphocytes bearing the CD3 antigen can be defined on the basis of the nature of the heterodimeric receptor chain (alpha beta or gamma delta T cell receptor (TCR) expressed. Precise identification of alpha beta and gamma delta TCR+ cells is essential when studying the tissue distribution and function of these different T cells. In immunofluorescence studies gamma delta TCR+ cells have been identified as CD3+WT-31- or CD3+CD4-CD8- cells. However, this may not be the optimal procedure because gamma delta TCR+ cells are weakly WT-31+, and some are CD8+. The aim of this study was to evaluate a panel of monoclonal antibodies (MoAb) directed against different chains of the TCR-T3 complex for a more precise identification of alpha beta+ and gamma delta TCR+ cells in flow cytometric studies. We found that the MoAb anti-Ti-gamma A and delta-TCS-1, recognizing the TCR-gamma and the TCR-delta chain respectively, only reacted with a subpopulation of gamma delta TCR+ cells, whereas another TCR-delta chain recognizing MoAb anti-TCR-delta 1 reacted with all gamma delta TCR+ cells. All MoAb reported to belong to the CD3 group reacted with both alpha beta TCR+ and gamma delta TCR+ cells as expected. Our results indicate that all gamma delta TCR+ cells can be identified with the MoAb anti-TCR-delta 1. Because no MoAb recognizing the TCR-alpha or TCR-beta chains at the cell surface of intact cells are yet available, we suggest that alpha beta TCR+ cells could be identified as CD3+ anti-TCR-delta 1-cells.     

Gamma delta T cells expressing CD8 or CD4low appear early in murine foetal thymus development.

Three-colour flow cytometry was used to study the distribution of TCR gamma delta+ cells among CD4+CD8-, CD4-CD8+, CD4+CD8+, and CD4-CD8- cell populations during thymic development. Thymocytes were obtained either directly from embryos at different stages of gestation (ex vivo) or from organ cultures maintained in vitro. In both cases, TCR gamma delta+ cells were found predominantly among the double negative (CD4-CD8-) and CD8 single positive subsets. These cells were actively dividing as demonstrated by 7 amino actinomycin D (7AAD) labelling. A small population of TCR gamma delta+ cells expressing low levels of CD4 was identified early and transiently (days 15-18) during development, but this subset was rare in the adult thymus. In newborn mice, adult mice, and late during organ culture, TCR gamma delta+ cells were found mainly within the CD4-CD8- compartment of thymocytes, although a minor population of CD8+ cells (5-10%) bearing gamma delta receptor was routinely observed. In contrast, few gamma delta cells were contained among the CD4+CD8+ subset at any timepoint studied. These data highlight differences between the ontogeny of alpha beta and gamma delta cells in the thymus, and suggest that a CD4+CD8+ intermediate may not be a requisite for the intrathymic differentiation of murine gamma delta T cells.     

Characterization of normal human CD3+ CD5- and gamma delta T cell receptor positive T lymphocytes.

The functional and phenotypic properties of normal human CD3+CD5- T cells which have a higher frequency of cytotoxic cells than CD3+CD5+ T lymphocytes have been described. Using three- and four-colour immunofluorescence flow cytometric cell sorting, the CD3+CD5- and CD3+CD5+ populations were subdivided into alpha beta or gamma delta T cell receptor positive cells. The four subsets were examined for the in vitro cytotoxic activity and were also stimulated with mitogens in limiting-dilution assays to measure the frequencies of proliferating and interleukin-2 (IL-2) producing cells. CD3+CD5- alpha beta +, CD3+CD5- gamma delta + and CD3+CD5+ gamma delta + cells had lower frequencies of proliferating and IL-2-producing cells than did CD3+CD5+ alpha beta + cells. However, the cytotoxic activity of the different phenotypes was higher in the CD3+CD5- subsets, especially when these cells were gamma delta +. Expression of gamma delta or lack of expression of CD5 appeared to be associated with the acquisition of cytolytic potentials. CD8 was expressed on 20% of fresh CD3+ gamma delta + cells. Cultured gamma delta + cells retained the expression of gamma delta, but quickly lost that of CD8 and with time modulated the expression of CD5. The expression of CD5 was found to be higher on sorted CD3+CD5+ gamma delta - than on CD3+CD5+ gamma delta + cells. These observations indicate that gamma delta is preferentially expressed on CD5-negative or weakly positive T lymphocytes and that CD3+CD5- gamma delta + cells appear to constitute a discrete small subset of mature T lymphocytes which are cytotoxic in nature. However, the exact immunological function of these cells and their place in T cell ontogeny are yet to be elucidated.     

Resting porcine T lymphocytes expressing class II major histocompatibility antigen.

The immune system of swine is unique in that the expression of CD4 and CD8 antigens defines four subpopulations of resting, extrathymic (CD1-) T lymphocytes in the circulation as well as in lymphoid tissue. Here it is documented that the specialty of the porcine T lymphocyte compartment extends to the expression of class II MHC (SLA) antigens. While the TCR gamma/delta CD4-CD8- as well as the TCR alpha/beta CD4+CD8- subpopulation both lack MHC II, the TCR alpha/beta CD4-CD8+ and the CD4+CD8+ subpopulation, the latter of which is private to swine, both do express MHC II. As opposed to human T lymphocytes, expression of porcine MHC II is not transient and restricted to lymphoblasts but is imminent in small, resting T lymphocytes of the two CD8-expressing subsets, even though also in swine activation can induce MHC II. Activation-induced extrathymic acquisition of MHC II without reversal can be discussed as one possible way of how MHC II+ T lymphocytes are generated. Alternatively, MHC II antigens should already be expressed by thymic progenitors. Remarkably, all CD1+CD4-CD8+ and most CD1+CD4+CD8+ thymocytes lack MHC II, yet, a minor subset with the phenotype CD4hiCD8hi expresses MHC II. One may speculate that these cells do not undergo thymic selection and represent the progenitors of the unusual, swine-typic MHC II+CD4+CD8+ extrathymic T lymphocytes.     

Maturation of CD4-8- alpha/beta TCR+ T cells induced by CD2-stimulation in vivo and in vitro.

Newly generated ('virgin') rat thymocytes of the immature CD4+8+ double positive (DP) subset were treated in suspension culture for 2 days with the stimulatory pair of anti-CD2 monoclonal antibodies OX-54 and OX-55. Approximately 50% of the recovered cells had downregulated CD4 and CD8 and upregulated the T cell antigen receptor (TCR). CD2-stimulated, but not control thymocytes proliferated in response to TCR plus IL-2 stimulation. In vivo, postnatal injection of OX-54/55 led to a dramatic and selective increase in functionally mature CD4-CD8- double negative (DN) alpha/beta--TCR(high) thymocytes and peripheral T cells. These findings show that CD2 stimulation can promote T cell differentiation and suggest that DN TCR(high) thymocytes can be generated from DP thymocytes via alternative pathways of T cell maturation.     

TCR-mediated target cell lysis by CD4+NK1+ liver T lymphocytes

In the liver, an unusual T lymphocyte population exists with the intriguing phenotype CD4+NK1+ TCR alpha beta int. Thus far, functions of these lymphocytes remained elusive. Recently, however, CD4+NK1+ liver T lymphocytes have been shown to produce cytokines. Here we show that sorted CD4+NK1+ liver lymphocytes from naive mice lyse target cells after TCR alpha beta or CD3, but not TCR gamma delta, engagement. Liver lymphocytes from beta 2-microglobulin-deficient gene disruption mutant mice failed to express such cytolytic activities and in vivo treatment with anti-NK1.1 mAb or anti-CD4 mAb, but not anti-CD8 mAb, markedly reduced target cell lysis. In vivo administration or rIL-12 impaired TCR alpha beta-mediated target cell lysis by liver lymphocytes. A similar down-regulation of cytolytic activities was observed with liver lymphocytes from mice infected with Listeria monocytogenes or Mycobacterium bovis BCG, which are potent IL-12 inducers. We anticipate (i) that cytolytic CD4+NK1+ T lymphocytes contribute to immunosurveillance of inflammatory processes in the liver and (ii) that they are influenced by IL-12.      

Phenotypical and Functional Characterization of Double-Negative (CD4-CD8-) αβ T-Cell Receptor Positive Cells from an Immunodeficient Patient

We have characterized CD4-CD8- double-negative (DN) alpha beta TCR+ T cells from a patient with immunodeficiency, lymphocytosis, lymphadenopathy, and hepatosplenomegaly. The majority of peripheral blood lymphocytes were DN alpha beta TCR+ T cells as evaluated by FACS and biochemical analysis. The DN T cells showed the following phenotype: alpha beta TCR+, gamma delta TCR-, CD2+, CD3+, CD4-, CD5+, CD7-, CD8-, CD16-, CD25-, CD26-, CD28+, CD45RO-, CD45RA+, CD57+, and HLA-DR+. Both southern blot analysis of TCR genes and FACS analysis applying a panel of V beta and V alpha monoclonal antibodies (MoAbs) indicated a polyclonal T-cell expansion. Thymic biopsy showed normal histology, whereas lymph node biopsy samples showed altered histological and immunohistological patterns with markedly expanded paracortical areas containing the DN T cells of the same phenotype as found in peripheral blood T cells. In functional studies, the DN T cells showed a profoundly reduced proliferative response upon stimulation with mitogens as well as MoAbs against the TCR/CD3 complex, CD2, and CD28, respectively. Addition of exogenous interleukin-2 (IL-2) only minimally augmented the proliferative response. In contrast, the addition of a combination of Ca2+ ionophore and phorbol 12-myristate 13-acetate (PMA) restored the proliferative response of the DN T cells to almost normal levels. This observation strongly suggests that the protein kinase C activity of the DN T cells was intact, but that the normal mechanism for transmembrane signal transduction was impaired in these unusual DN T cells.     

IL-4 is able to reverse the CD2-mediated negative apoptotic signal to CD4-CD8- alpha beta and/or gamma delta T lymphocytes.

Activation of immature thymocytes or transformed T lymphocytes via T-cell receptor (TCR)/CD3 signalling can induce programmed cell death (apoptosis). Recent data indicate that anti-CD3/TCR monoclonal antibodies (mAb) also trigger apoptosis in activated (but not resting) mature peripheral blood T lymphocytes. Here we report that triggering of resting CD4-CD8-TCR alpha beta+ and/or TCR gamma delta+ via the alternative CD2-dependent activation pathway is able to induce programmed cell death. A pair of mitogenic anti-CD2 mAb provoked a dramatic rise in [Ca2+]i that was almost entirely sustained by extracellular fluxes, and the inhibition of membrane [Ca2+/Mg2+] ATPase. The resulting endonuclease activation was able to induce DNA fragmentation, as revealed by propidium iodide staining and gel electrophoresis. Induction of apoptosis was prevented by the presence of interleukin-4 (IL-4) as well as by endonuclease inactivation with 100 microM ZnCl2, but enhanced by the contemporary block of protein kinase C. Thus it seems that in resting T lymphocytes the strong calcium signal delivered by the alternative CD2 activation pathway may act as a negative apoptotic signal in both alpha beta and gamma delta T cells with low (non-major histocompatibility complex restricted) antigenic affinity, so limiting the extension of polyclonal T-cell growth.