Characterization of a human T cell-specific chimeric antibody (CD7) with human constant and mouse variable regions

A chimeric human-mouse anti-T lymphocyte mAb (CHT2; SDZ 214-380) has been constructed by cloning the variable region exons of both the L and H chains from the murine hybridoma RFT2 which have CD7 specificity and reactivity with a 40-kDa Ag. The variable L chain exon was joined to the human C kappa, and the variable H chain exon was joined to the human IgG1 region exon encoding the human allotype nGlm(z), nGlm(a). The gene constructs were introduced by electroporation into SP2/0, a non-Ig-producing murine myeloma. The identical tissue reactivity of the newly made CHT2 and the original murine RFT2 mAb (CD7) was confirmed by blocking experiments as well as by immunohistology and flow cytometry. Because this new mAb may have clinical use, the CD7 Ag expression of T lineage cells has also been quantitated in double and triple immunofluorescence assays in combinations with mAb to restricted forms of leukocyte common Ag that designate unprimed (CD45R+) and primed T lymphocyte populations (UCHL1+). CHT2 shows very strong reactivity with large thymic blast cells and cortical thymocytes from which T-ALL originates. Strong staining is seen on CD45R+ unprimed "virgin" T lymphocytes, whereas the expression on UCHL1+ primed "memory" cell types is weaker unless these cells are reactivated by mitogens or Ag. Thus CHT2 may spare a substantial population of resting memory T cells which is relevant to its potential therapeutic use. In addition the chimeric antibody had a greater in vitro antibody dependent cytotoxicity and a prolonged half-life (4.2 to 5.0 days) in Rhesus monkeys.     

Flow cytometric analysis of human bone marrow. IV. Differential quantitative expression of T-200 common leukocyte antigen during normal hemopoiesis

We have correlated the intensity of expression of CD45 Ag (T200 common leukocyte Ag) with mAb reactive with various lineages of hemopoietic cells in normal human bone marrow by using two-color immunofluorescence on a flow cytometer. Mature T lymphocytes (CD3+) and NK cells (CD16+ or CD11b+) expressed CD45 at the highest intensity. B lymphoid cells (CD19+) had three distinct levels of CD45 Ag expression. The bright CD45(3+) cells were mature B cells (CD19+, CD20+), whereas the less intense CD45(2+) cells were less mature B lymphoid cells (CD19+, CD10+). The dim CD45+ cells were very early, B lymphoid precursor cells (CD19+, CD10(2+), CD34+). The intensity of CD45 expression increased as cells matured in the monocytic lineage (CD14+, CD11b+). Among marrow granulocytic cells, CD45 intensity did not change on cells during maturation. Within the erythroid lineage, the most immature cells were CD45+ dim, and CD45 expression decreased during erythroid maturation to become undetectable on mature E. Hemopoietic progenitor cells (CD34+) expressed low levels of CD45 Ag. Expression of CD45R on marrow cells also showed intensity differences on different lineages. All NK cells (CD16+) were positive for CD45R, whereas only about one-half of the T lymphocytes (CD3+) were positive for CD45R. Almost all the cells in the erythroid and myelomonocytic lineages were CD45R-. Quantitative differences in expression of CD45R were observed on marrow B lymphoid cells which were correlated with the expression of CD45. The results show that quantitative changes in CD45 Ag expression accompany the differentiation and maturation of cells in the bone marrow. Comparisons with CD45R showed that this Ag was not always correlated with CD45. Since these Ag are the products of the same gene, these data indicate that the regulation of expression of the T200 molecules during normal hemopoietic development must be both quantitative and qualitative.     

The DTH-initiating Thy-1+ cell is double-negative (CD4-, CD8-) and CD3-, and expresses IL-3 receptors, but no IL-2 receptors

The elicitation of delayed-type hypersensitivity (DTH) requires an early-acting Thy-1+ cell that produces an Ag-specific, non-MHC-restricted factor that initiates DTH by sensitizing the local tissue for release of the vasoactive amine serotonin. We characterized the phenotype of this DTH-initiating cell by treating cells from sensitized mice with different antibodies and then either with rabbit C or anti-Ig panning or bead separation to deplete various subpopulations. We then transferred these cells i.v. into naive recipients that were challenged to elicit DTH. Our findings indicate that the early DTH-initiating cell is Thy-1+, Lyt-1+, CD4-, CD8- and CD3-, whereas the classical, late DTH effector T cell is Thy-1+, Lyt-1+, CD4+, CD8-, and CD3+. We hypothesize that DTH-initiating cells are primitive T cells with Ag receptors that can bind Ag without MHC-restriction. This hypothesis was supported by the finding that two different antibodies, that both bind T cell-derived Ag-binding molecules, eliminated the DTH-initiating, cell but did not affect the late component, MHC-restricted CD4+, CD3+ T cell. Additional experiments with antibodies against restricted determinants of the T-200 glycoprotein family (CD45R) showed that the early but not the late cell is positive for B220, which is usually present on B cells, and on some activated T cells. Also, the DTH-initiating cell is Il-2R-, but Il-3R+; whereas the late component DTH T cell is IL-2R+ and IL-3-. Our findings suggest that DTH-initiating cells may be Ag-specific lymphoid precursor cells that arise before final differentiation along the pathway leading to mature T or B cells. Our results indicate that antigen-specific Thy-1+, CD3-, CD4-, CD8- cells function in vivo to initiate DTH reactions.     

Biochemical nature and topographic localization of epitopes defining four distinct CD45 antigen specificities. Conventional CD45, CD45R, 180 kDa (UCHL1) and 220/205/190 kDa

The biochemical nature and relative topographic localization of Ag determinants recognized on CD45 molecular complex by mAb defining four distinct Ag specificities (conventional CD45, CD45R, 180 kDa and 220/205/190 kDa) have been investigated. These Ag specificities display a differential biochemical, cellular, and histochemical distributions and are important in the definition of CD4-positive complementary functional T cell subsets and/or distinct stages of thymic maturation. Protease treatment of either CD45-positive cells or purified CD45 molecules revealed that both conventional CD45 and 180-kDa (UCHL1 epitope) Ag specificities are defined by epitopes present on a protease-resistant domain which is internal to the protease-sensitive epitopes defining both CD45R and 220/205/190-kDa Ag specificities. In addition, it is shown that carbohydrate moieties are contributing to the epitopes recognized by both the anti-180-kDa UCHL1 and the anti-220/205/190-kDa mAb. Neuraminidase treatment, which cleaves sialic acids either from N- or O-linked oligosaccharides, abrogated the reactivity of both mAb. However, N-glycanase treatment, which selectively cleaves N-linked sugars, did not affect the recognition of these two epitopes. Thus, these results demonstrate that the Ag determinants recognized by the UCHL1 and the anti-220/205/190-kDa mAb, which are topographically unrelated, are associated with sialic acids from O-linked-type oligosaccharides, emphasizing the contribution of carbohydrates to the Ag heterogeneity of CD45 molecular complex.     

Differential activation requirements for virgin and memory T cells

Most studies of the activation requirements for T cells have used either T cell lines or populations of normal T cells that consist of a mixture of virgin and Ag-primed T cells. These two subpopulations of T cells can now be distinguished in humans by their reactivity with mAb. The anti-CD45R antibody HB10 identifies virgin T cells (T degrees) that are non-reactive to recall Ag and relatively poor at providing help for B cell differentiation. Conversely, memory T cells (T') that can react to recall Ag and enhance Ig production are non-reactive with anti-CD45R, but can be identified with the UCHL1 antibody. We have used these antibodies to separate the T degrees and T' populations and examine their activation requirements. On activation CD45R+ cells rapidly began to lose the CD45R Ag and express the UCHL1 Ag in increased amounts, whereas the UCHL1+ cells retained this phenotype. Both populations responded to PHA in the presence of monocytes, but when triggered by an antibody to CD3 only the T' cells were induced to express IL-2R, produce IL-2, and to proliferate. The T degrees population of cells remained relatively quiescent by all of these parameters. However, anti-CD3 stimulation conditioned the T degrees cells for IL-2 responsiveness, inasmuch as the addition of rIL-2 resulted in significant IL-2R expression and proliferation. When the CD4+ T degrees and CD4+ T' subpopulations were isolated and examined in the same assays similar results were obtained. The data indicate that fundamental differences exist in the triggering requirements for T degrees and T' cells.     

Loss of CD45R (Lp220) represents a post-thymic T cell differentiation event

CD45R+ and CDw29+ CD4+ T cells are widely regarded as separate functionally defined T cell lineages. The work described here indicates that they represent maturation stages within the same differentiation pathway. Purified populations of CD4+ or CD8+ T cells, after stimulation with PHA, lose cell surface expression of CD45R (Lp220) and gain an increased surface density of CDw29 (4B4). Clonal analysis demonstrated that individual CD4+ CD45R+ T cells lost CD45R and acquired CDw29 with time in culture. This effect was selective for the high Mr 220-kDa form of the T200 (CD45) complex because the density of CD45, detected by an antibody to common determinants, did not decrease. This strongly indicates that CD45R+ cells are an immature stage in a lineage that culminates in CDw29 expression. To further define the expression of CD45R and CDw29, we analyzed infant thymus cells. Thymocytes include only 4 to 6% CD45R+ cells, but 95% express CDw29 in moderate density. The CD45R+ set appears to include mainly single CD4+ or CD8+, CD3 "bright" medullary cells, although only 15 to 25% of thymocytes with medullary phenotype express CD45R. In vitro culture of thymocytes with Con A and T cell growth factor induces expression of CD45R but these cells differ from the peripheral CD45R+ set by virtue of their co-expression of a high density of CDw29 (4B4) Ag. We postulate that post-thymically CD45R (Lp200) and CDw29 (4B4) comprise a functional assembly on the surface of T cells that changes in composition after stimulation with Ag or mitogen. This may result in enhanced ability of an Ag-experienced T cell to respond effectively to Ag due perhaps to a more efficient signaling complex.     

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.     

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.     

Immunoregulatory T lymphocytes in man. Soluble antigen-specific suppressor-inducer T lymphocytes are derived from the CD4+CD45R-p80+ subpopulation

Regulation of the immune response in man is largely dependent on interactions between cells of the cluster designation 4+ (CD4+) helper/inducer sublineage and the CD8+ suppressor/cytotoxic sublineage. When cultured with autologous antigen-primed CD4+ lymphocytes, CD8+ cells differentiate into suppressor T cells (Ts) that specifically inhibit the response of fresh autologous CD4+ cells to the priming antigen only. The current study was undertaken to analyze the roles in this suppressor circuit of subpopulations of the CD4+ sublineage distinguished from one another on the basis of their binding (or lack of binding) to monoclonal antibodies against molecules p80 (Leu8) and CD45R (p220/Leu18/2H4). When examined for the proliferative responses to alloantigenic stimuli, each of the four: CD4+p80+, CD4+p80-, CD4+CD45R+, and CD4+CD45R- populations proliferated vigorously, synthesized interleukin 2 (IL-2) and interferon and released soluble IL-2 receptors. However, the responses to soluble antigens such as Candida and diphtheria toxoid were exhibited by CD4+CD45R-, CD4+p80+, and CD4+p80- cells, but not by CD4+CD45R+ cells. When examined for their ability to induced CD8+ Ts in the Candida-driven suppressor-induction culture system, only CD4+p80+ and CD4+CD45R- cells induced strong suppression. Further, when CD4+CD45R- cells were separated into CD4+CD45R-p80+ and CD4+CD45R-p80- subpopulations, despite the ability of both subpopulations to respond to Candida, only CD4+CD45R-p80+ cells induced autologous CD8+ Ts. Activated CD8+ Ts suppressed not only proliferation but also the release of soluble IL-2 receptors by autologous antigen-activated CD4+ cells. Thus, the antigen-specific suppressor-inducer T cells appear to be derived from the CD4+CD45R-p80+ (Leu3+, Leu8+, 2H4-) subpopulation of the CD4+ sublineage.     

An antigen-specific DTH-initiating cell clone. Functional, phenotypical, and partial molecular characterization

The elicitation of delayed-type hypersensitivity (DTH) reactions in mice is due to the sequential action of two different Ag-specific Thy-1+ cells. An early-acting DTH-initiating cell in the lymphoid organs produces a circulating, Ag-specific factor that is functionally analogous to IgE antibody and initiates DTH by sensitizing the local tissue for release of the vasoactive amine serotonin. In picryl chloride (PC1) or oxazolone (OX) contact sensitivity, this DTH-initiating factor is called PC1-F and OX-F respectively, and is Ag-specific, but MHC-unrestricted. The phenotype of polyclonal DTH-initiating cells was recently shown to be unusual for an Ag-specific cell. The phenotype was: Thy-1+, Lyt-1+ (CD5), triple negative (CD4-, CD8-, and CD3-), B220+ (Ly-5, CD45RA), positive for IL-3 receptors, but not IL-2 receptors, and positive for antibodies that react with a putative constant or framework portion of DTH-initiating factors such as anti-PC1-F antibodies and 14-30 mAb. We report here the generation of an Ag-specific DTH-initiating cell clone from nude mice that were immunized and boosted by contact sensitization with OX. By flow microfluorometry analysis, this clone has a similar unique surface phenotype, and by in vivo assay has the same functional abilities, as polyclonal DTH-initiating cells. The clone produces Ag-specific OX-F that acts in an Ag-specific manner to initiate DTH. Moreover, specific cDNA probes and Northern blot analysis of the clone demonstrated that the Ag-specific DTH-initiating cells are Thy-1+, CD3-, and IL-3R+. Thus, DTH initiation is due to an Ag-specific lymphoid cell, that produces an Ag-specific factor, and that has a unique surface phenotype for Ag-specific cells; namely, Thy-1+, CD5+, sIg-, CD4-, CD8-, CD3-, CD45RA+, IL-2R-, and IL-3R+.     

Comparative biochemical and tissue distribution study of four distinct CD45 antigen specificities

Studies on the antigenic structure of the human CD45 glycoproteins using mAb have revealed the existence of four reactivity patterns defined specifically by distinct biochemical, cellular, and histochemical distributions. In addition to the two well characterized Ag specificities, CD45 and CD45R, present on the four glycoproteins (220, 205, 190, and 180 kDa) and on the 220-kDa member, respectively, we have identified two novel specificities. These have been defined by two different mAb, UCHL1 and PD7/26/16, that recognize an epitope exclusively expressed on the 180-kDa lowest molecular sized polypeptide and an epitope shared by the three higher molecular sized polypeptides (220, 205, 190 kDa) of the complex, respectively. It has been demonstrated that they are also part of the CD45 complex by immunoprecipitation, immunoblotting, and binding assays with purified CD45 molecules. Comparative analysis by flow cytometry and immunoperoxidase techniques also showed a distinct pattern of cell distribution for each specificity. The 180-kDa specificity is present on a subset of T cells but absent on B lymphocytes, whereas the 220-kDa specificity is mainly expressed by B cells and a subpopulation of T lymphocytes. On the other hand, the cell distribution of the epitope common to the three higher members is slightly different to the conventional pan-leukocyte CD45 specificity. Thus, certain CD45+ cell types such as cutaneous Langerhans' cells, sinusoidal lymph node macrophages, and a small subset of T cells in both lymph node and tonsil did not express the 220/205/190-kDa specificity. These results further support that CD45 glycoproteins constitute a very heterogeneous molecular complex with epitopes that are selectively expressed by different cell types and by T cells at different stages of maturation.     

1F7, a novel cell surface molecule, involved in helper function of CD4 cells

We have developed a monoclonal antibody, anti-1F7, that inhibits soluble Ag-driven T cell proliferation as well as PWM-driven IgG synthesis. Anti-1F7 antibody reacts with approximately 57% of unfractionated T cells, 62% of CD4+ cells, and 54% of CD8+ cells. Although the 1F7 Ag is widely distributed among lymphoid cells, this Ag on CD4+ cells is preferentially expressed on the CDw29(4B4+) helper population. Moreover, anti-1F7 antibody further subdivides the CD4+CDw29+ cell subset into CDw29+1F7+ and CDw29+1F7- populations. The CD4+CDw29+1F7+ population of cells maximally proliferates to recall Ag such as tetanus toxoid, whereas helper function for PWM-driven IgG synthesis by B cells belongs to both the CD4+CDw29+1F7+ and CD4+CDw29+1F7- population of cells. The most prominent structure defined by this antibody is a 110-kDa molecule that is different from the 135-kDa, 160-kDa, and 185-kDa glycoproteins identified by anti-CDw29 antibody and the 180-kDa glycoprotein identified by UCHL-1 antibody. It is, however, related to the molecule recognized by anti-Ta1, an activation Ag on T cells. Furthermore, although the Ta1 molecule is recognized by anti-1F7 mAb, the 1F7 family of structures also includes molecules distinct from Ta1.     

Role of a thymic stromal cell clone in inducing the stage-specific differentiation of various subpopulations of double negative thymocytes

The monolayer of a thymic stromal cell clone termed MRL104.8a induced the differentiation of adult double negative (DN) thymocytes (CD3-4-8-) through a CD3-4-8+ intermediate into CD3- (or dull) 4+8+ stages. DN thymocytes were separated into three subpopulations depending on their cell-surface expression of Pgp-1 and IL-2R, namely, Pgp-1+IL-2R-, Pgp-1-IL-2R+, and Pgp-1-IL-2R-. The present study investigated the requirements of the MRL104.8a monolayer for inducing the differentiation of these DN thymocyte subpopulations. The following were revealed: i) the MRL104.8a monolayer failed to induce the differentiation of a Pgp-1+IL-2R- subpopulation; ii) whereas a Pgp-1-IL-2R+ subpopulation did not express either CD4 or CD8 Ag when cultured in medium, culturing this subpopulation on the thymic stromal cell monolayers resulted in the expression of CD8 but not CD4 Ag; and iii) a Pgp-1-IL-2R- DN subpopulation obtained through less extensive treatments with anti-CD4 and anti-CD8 antibodies in the presence of C before sorting procedures spontaneously differentiated into double positive cells in medium. In contrast, most of DN cells with the same phenotype obtained through extensive anti-CD4 and -CD8 treatments before sorting failed to express CD4 and/or CD8 Ag in medium but could differentiate through a CD3-4-8+ into more mature stages only when they were cultured on the thymic stromal monolayer. These results indicate differential requirements of thymic stromal cells for the differentiation of various DN subpopulations with qualitatively distinct phenotypes and different magnitudes (very low vs almost zero levels) of CD4/CD8 expression.     

Production of lymphokine mRNA by CD45R+ and CD45R- helper T cells from human peripheral blood and by human CD4+ T cell clones

The expression of lymphokine mRNA by human CD4+CD45R+ and CD4+CD45R- Th cells was assessed after mitogen stimulation. These Ag have previously been shown to relate closely to virgin and primed T cells, respectively. CD4+CD45R+ (virgin) and CD4+CD45R- (primed) cell fractions were isolated by sorting double-labeled cells with a fluorescence-activated cell sorter. CD4+CD45R+ cells produced high levels of IL-2 mRNA when stimulated with either PMA together with calcium ionophore, or with PHA, but they expressed only trace quantities of mRNA for IL-4 or IFN-gamma. In contrast, CD4+CD45R- cells produced high levels of mRNA for IL-2, IL-4, and IFN-gamma. After 14 days of continuous culture, CD4+CD45R+ Th cells lost expression of the CD45R Ag, but gained high level expression of CDw29, such that they were indistinguishable from the cell population which originally expressed this Ag. At the same time, they acquired the ability to synthesize IL-4 mRNA. It seemed likely that the broad lymphokine profile of primed Th cells might mask clonal heterogeneity. Analysis of 122 CD4+ T cell clones showed that all of them synthesized IL-2 mRNA. One clone failed to express IL-4 mRNA, but did produce those for IL-2 and IFN-gamma. A total of 34 of the clones was investigated to determine expression of IFN-gamma mRNA; two of these clones were negative for IFN-gamma mRNA, and both expressed IL-2 and IL-4 message. These data suggest that while fresh virgin and primed peripheral blood T cells show a clear resolution of lymphokine production, a simple subdivision of human CD4+ T cell clones on the basis of their lymphokine production (such as that reported for mouse Th cell clones) is not possible.     

Expression and function of a 90-kilodalton homodimeric molecule (10D1 antigen) on human thymocytes

The 10D1 Ag is a 90-kDa homodimeric molecule specifically expressed on a subpopulation of human T cells, and is involved in an alternative pathway of T cell activation. In the present study, we have examined the expression and function of the 10D1 Ag on human thymocytes. Three-color FMF analysis showed that the 10D1 Ag was highly expressed on minor but distinct subpopulations of double-negative and CD4 single-positive thymocytes, and weakly on a part of double-positive thymocytes, but not on CD8 single-positive thymocytes. In double-negative thymocytes, the vast majority of 10D1+ cells were immature thymocytes of CD7+2+3- phenotype. Interestingly, 10D1 mAb could induce the proliferation of CD4 single-positive thymocytes in the presence of goat anti-mouse Ig to cross-link the 10D1 Ag. The treatment of thymocytes with OKT4 mAb plus C but not with OKT8 mAb plus C totally abrogated the proliferative response induced by 10D1 mAb, indicating that the 10D1-responsible thymocytes were of CD4+8- phenotype. This 10D1 mAb-induced thymocyte proliferation was perfectly dependent on the endogenous IL-2/IL-2R system since a complete inhibition was observed with anti-IL-2 and anti-IL-2R mAb. The proliferating CD4 single positive thymocytes predominantly expressed the IL-2R alpha (p55) but not a detectable level of the IL-2R beta (p75). These results indicate that, although the 10D1 Ag can be detected on the CD7+2+3-4-8- thymocytes, its functional expression is restricted to a minor more mature CD4+ thymocyte population as well as in peripheral blood T cells, and the implications of these findings are discussed.     

Dendritic cells induce MUC1 expression and polarization on human T cells by an IL-7-dependent mechanism

The MUC1 transmembrane mucin is expressed on the surface of activated human T cells; however, the physiologic signals responsible for the regulation of MUC1 in T cells are not known. The present studies demonstrate that IL-7, but not IL-2 or IL-4, markedly induces MUC1 expression on CD3+ T cells. MUC1 was also up-regulated by IL-15, but to a lesser extent than that found with IL-7. The results show that IL-7 up-regulates MUC1 on CD4+, CD8+, CD25+, CD69+, naive CD45RA+, and memory CD45RO+ T cells. In concert with induction of MUC1 expression by IL-7, activated dendritic cells (DC) that produce IL-7 up-regulate MUC1 on allogeneic CD3+ T cells. DC also induce MUC1 expression on autologous CD3+ T cells in the presence of recall Ag. Moreover, DC-induced MUC1 expression on T cells is blocked by a neutralizing anti-IL-7 Ab. The results also demonstrate that DC induce polarization of MUC1 on T cells at sites opposing the DC-T cell synapse. These findings indicate that DC-mediated activation of Ag-specific T cells is associated with induction and polarization of MUC1 expression by an IL-7-dependent mechanism.     

Rapid response to Con A by CD4+CD45R- rat memory lymphocytes as compared to CD4+CD45R+ lymphocytes

Functionally distinct subpopulations within the CD4+ subset of T lymphocytes have been described in man, rat, and mouse. In the rat different functions have been assigned to CD45R+ and CD45R- T helper cells. The CD45R+ in contrast to the CD45R- T helper cells have been reported to produce IL-2 and to proliferate well in response both to Con A and in MLR. In the present investigation the kinetics of the response to Con A by the CD45R+ and CD45R- rat T helper subsets have been analyzed. We confirm a strong proliferative response to Con A by CD4+CD45R+ rat T lymphocytes and also that they are the best IL-2 producers. We further demonstrate that CD4+CD45R- cells also produce IL-2, although in order to appreciate this production quantitatively by assays of the culture supernatants it was necessary to block IL-2 absorption by IL-2 receptor (IL-2R) antibodies. This blockage was of importance also in comparisons of the two subsets, since they showed different kinetics of IL-2R appearance. It is demonstrated that the CD4+CD45R- cells respond more rapidly to Con A than the CD4+CD45R+ cells as reflected by phenotypic conversion, IL-2 production, and proliferation. The fast response of the CD4+CD45R- T subset shown in the present study of rat cells and analogous studies of human cells suggests that the memory compartment of T cells besides other characteristics also has the capacity for a more rapid response than naive lymphocytes.     

T cell regulation of human B cell proliferation and differentiation. Regulatory influences of CD45R+ and CD45R- T4 cell subsets

The immunoregulatory functions of human T4 cell subpopulations defined by mAb to the CD45R molecule (2H4) were examined. Both CD45R- and CD45R+ T4 cells that had been treated with mitomycin C (CD45R- and CD45R+ T4-mito) provided help for the generation of Ig-secreting cells (ISC) in cultures stimulated by PWM or by immobilized mAb to CD3 (64.1). IL-2 enhanced the generation of ISC in PWM-stimulated cultures and in anti-CD3-stimulated cultures containing CD45R+ T4-mito. The generation of ISC was maximal in cultures containing anti-CD3-activated CD45R- T4-mito and was not increased by IL-2. By contrast, CD45R+ T4 cells that had not been treated with mitomycin C suppressed B cell responses in cultures stimulated with PWM or anti-CD3, whereas CD45R- T4 cells suppressed the generation of ISC only in cultures stimulated with anti-CD3. IL-2 enhanced suppression by anti-CD3, but not PWM, activated CD45R- T4 cells. Suppression by CD45R+ T4 cells was maximal and not increased by IL-2. CD45R+ T4-mito were more effective suppressor-inducers in PWM-stimulated cultures, promoting the differentiation of suppressor-effector cells from CD8+ T cells. However, both CD45R+ and CD45R- T4-mito exerted comparable suppressor-inducer function in anti-CD3-stimulated cultures. Moreover, in anti-CD3-stimulated cultures, T8 cells could function as both suppressor-effector cells and suppressor-inducer cells. One of the functions of suppressor-inducer cells in this system appeared to involve the production of IL-2. Thus, the addition of IL-2 facilitated the induction of suppressor-effector T8 cells by CD45R- T4-mito in PWM-stimulated cultures. Although IL-2 production by the T cell subsets varied widely depending on the nature of the stimulus, these differences could not entirely explain their capacity to function as helper cells, suppressor-effector cells or suppressor-inducer cells. These results indicate that both CD45R+ and CD45R- T4 cells can help or suppress B cell responses, as well as induce suppressor-effector T8 cells. Moreover, suppressor-inducer function of T cells is not limited to the T4 cell population, but rather can also be accomplished by T8 cells. The results indicate that both T4 cell subsets and T8 cells exert multiple regulatory effects on human B cell function, with the nature of the activating stimulus playing a major role in determining the functional capacity of various T cell subsets.     

Human IL-7: a novel T cell growth factor

IL-7 is a hemopoietic growth factor that induces the proliferation of early B lineage cells. In the course of studies to determine its effect on human bone marrow cells, we noted a marked outgrowth of mature T cells. When T cells from the circulation were cultured with IL-7, a dose-dependent proliferative response was observed. The target cells included both the CD4+ and CD8+ subpopulations of T cells, but the memory T cells (CD45R-) were better responders than unprimed T cells (CD45R+). IL-7 induced the expression of receptors for IL-2 and transferrin and higher levels of the 4F2 activation Ag. Although T cell responses to suboptimal concentrations of IL-7 were enhanced by the addition of IL-2, the proliferative response to IL-7 was not inhibited by neutralizing antibody to the IL-2R (Tac), nor was IL-2 secretion detected in this response. This response pattern of mature T cells suggests an important role for IL-7 in normal T cell physiology in humans.     

In situ localization of CD45 isoforms in the human thymus indicates a medullary location for the thymic generative lineage.

Previous work has suggested that the generative lineage within the human thymus can be defined by the selective expression of CD45 isoforms and is CD45RO- and predominantly CD45RA+. In order to physically localize these cells we have stained frozen sections of human thymus with antibodies to CD45RO (p180), and CD45RA (p205/P220), as well as with CD1 and HLA class I to define cortical and medullary areas, respectively. In the cortex, 70 to 90% of thymocytes were CD45RO+, whereas only 0.5% expressed CD45RA. Medullary cells were 30% CD45RO+, 29% CD45RA+; approximately 40% did not express detectable levels of either isoform but did express CD45 common determinants. To assess the degree of proliferation of cells expressing CD45 isoforms, we stained adjacent sections, or used double staining, with Ki67, an antibody that detects a nuclear Ag on proliferating cells. We found that CD45RA+ thymocytes are predominantly a resting medullary population with a small component in cell cycle, consistent with our analysis of human thymocytes by immunofluorescence, and with data in murine systems defining the generative lineage. To confirm that the CD1- or low, CD45RO-CD45RA+ thymocytes defined by immunofluorescence analysis were likely to have a medullary location, we analyzed the CD4/CD8 subset distribution of CD1-cells. From 80 to 90% of CD1-thymocytes are CD4+ or CD8+ single positives or CD-8- double negatives. CD1-thymocytes also include 12 to 14% CD4+8+ cells with a probable medullary location. A similar analysis of lymphocytes expressing a high density of HLA class I, which have a medullary location, confirmed the existence of CD4+8+ thymocytes in the medulla. Purified CD3-4-8- cells, previously shown to be CD1-CD45RA+, were also shown to bear a high density of HLA class I, indicating a medullary location. Correlative localization of a panel of Ag thus supports the argument for a medullary location of the thymic generative lineage.