Human T cells targeted with anti-T3 cross-linked to antitumor antibody prevent tumor growth in nude mice

Human peripheral blood T cells were tested for the ability to prevent tumor growth in nude mice when targeted with anti-T3 cross-linked to antitumor antibodies. LS174T human colon adenocarcinoma cells were mixed with human PBL coated either with anti-T3 (Fab) cross-linked to 315F6 (Fab) (an antitumor monoclonal antibody) or with no antibody, and were injected subcutaneously into nude mice. Tumor growth was totally inhibited at effector to target (E:T) ratios of 7.0:1 and 2.1:1, and was partially inhibited at 0.7:1 with antibody-coated PBL, but was not inhibited by uncoated PBL. T cell-mediated protection against tumor growth occurred when an antitumor was physically cross-linked to anti-T3. Neither a mixture of unlinked anti-T3 and antitumor antibodies nor anti-human MHC class I cross-linked to antitumor antibody prevented tumor growth. Whereas in vitro cytotoxicity was mediated exclusively by T8+ cells and was augmented by brief exposure of effector cells to IL 2, tumor neutralization in vivo was mediated by both T4+ and T8+ cells and was not significantly stimulated by prior exposure of the cells to IL 2. We conclude that human T cells, when targeted with appropriate antibody heteroaggregates, can specifically inhibit tumor growth at low E:T ratios, and that cells mediating tumor neutralization in vivo may differ from those mediating cytotoxicity in vitro.     

Human K/natural killer cells targeted with hetero-cross-linked antibodies specifically lyse tumor cells in vitro and prevent tumor growth in vivo

We have induced fresh peripheral blood K/natural killer cells to lyse a variety of target cells by coating them with anti-Fc gamma receptor (anti-Fc gamma R) (CD16) antibody hetero-cross-linked with anti-target cell antibody. The cytotoxic cell mediating this activity is different, as judged by depletion studies, from the CD3+, CD8+ T cell which is targeted by anti-CD3 cross-linked to anti-target cell antibody. Targeted K cell activity from some donors is enhanced by exposure to interleukin 2 but not interferon-gamma; other donors exhibit high amounts of this activity without stimulation. Specificity of lysis mediated by targeted K cells is dictated by the specificity of the anti-target cell antibody within the heteroconjugate, and bystander cells are not lysed by targeted K cells. Hetero-cross-linked antibodies containing anti-histocompatibility leukocyte antigen class I instead of anti-Fc gamma R (CD16) do not promote lysis, suggesting that the bridging of the target cell to Fc gamma R on the K cell is required to activate the lytic process. Lysis mediated by targeted K cells is much less inhibitable by polymerized IgG than is classical antibody-dependent cellular cytotoxicity. Fresh human melanoma cells are lysed specifically by K cells coated with anti-Fc gamma R (CD16) cross-linked to the 96.5 anti-melanoma antibody. In vivo, targeted K cells prevent tumor growth at low effector to target ratios in Winn-type tumor neutralization assays. Targeted K cells may therefore provide a new immunotherapeutic approach for the destruction of detrimental cells, such as tumor and virally infected cells.     

Human T cells can be directed to lyse tumor targets through the alternative activation/T11-E rosette receptor pathway

We investigated the ability of human T cells to be directed to lyse murine and human tumor targets by antibodies (Ab) to the T11-E rosette (CD2) receptor. We found that the human cytotoxic T lymphocyte clone TBI-6, which is specific for the Epstein-Barr virus-transformed cell line, CM-EBV, could be directed to lyse the Fc receptor-positive murine tumor P388D1, by the combination of anti-T11(2) plus anti-T11(3) Ab. This activation and lysis was demonstrable only with an Fc receptor expressing tumor target and only with those Ab or with anti-T3 (CD3) Ab but not with other anti-T11 Ab or other Ab directed against surface structures on the clone. We therefore constructed heterodimeric Ab consisting of anti-T11(2) or anti-T11(3) Ab and the J5 anti-common acute lymphoblastic leukemic antigen (anti-CALLA) Ab. The purity and retained functional properties of the dimers were demonstrated by sodium dodecyl sulfate-polyacrylamide gels, fluorescence-activated cell sorter analysis on relevant cells, and by the ability of these conjugates to activate human peripheral blood lymphocytes to proliferate. These heterodimeric Ab conjugates were shown to be able to direct the lysis of CALLA+ targets by TBI-6. The specificity of this lysis was demonstrated by the inability of these heterodimers to direct the lysis of CALLA- targets by the cytotoxic T lymphocyte clone, and by the ability of excess free J5, but not an irrelevant Ab of the same isotype, to block this type of lysis. The potential clinical significance of these reagents is discussed.     

Activation of human cytolytic cells through CD2/T11. Comparison of the requirements for the induction and direction of lysis of tumor targets by T cells and NK cells

We studied the mechanisms whereby human T cells and NK cells are activated and directed to lyse tumor targets through the CD2 (T11/E-rosette) Ag. Using two cloned NK lines, we showed that these cells, as had previously been shown for T cells, could be directed to lyse an "NK-resistant" tumor target in the presence of antibody heterodimers. These heterodimers consisted of a (mAb) to CD2 (anti-T11(2) or anti-T11(3] linked to a mAb recognizing the tumor cell (J5, anti-CALLA). However, distinct differences between NK cells and T cells were observed with regard to the requirements for such directed lysis: first, only one epitope of CD2 on NK cells (either T11(2) or T11(3] needed to be recognized by the antibody heterodimer in order for directed lysis to occur, whereas for T cells both T11(2) and T11(3) epitopes had to be recognized. Second, in confirmation of previous data with monomeric anti-T11(2) or anti-T11(3) antibody, heterodimers constructed with these reagents enhanced conjugate formation between NK cells and tumor targets, whereas no such enhancement was seen with T cells. All types of heterodimer directed lysis were dependent on the adhesion molecule LFA-1, as an anti-LFA-1 antibody-blocked lysis. Third, whereas in T cells lysis mediated through CD2 appeared to be regulated by CD3 but not vice versa, all types of lysis by NK cells appeared to be regulated through CD2. Finally we showed that F(ab')2 fragments of the anti-T11(2) and anti-T11(3) antibodies could activate NK cells, but were unable to activate T cells either as cloned cytolytic lines, or in populations of PBL. The implications of our findings with regard to the role of CD2 in the activation of cytolytic cells is discussed.     

Growth inhibition of human T cells by antibodies recognizing the T cell antigen receptor complex

Monoclonal antibodies that bind to the T cell MHC-antigen recognition complex (anti-T3 or anti-Ti) are known to either mimic ligand binding and activate T cells or block ligand binding, leading to an inhibition of T cell activation. In the present experiments, we demonstrate a direct inhibitory effect on the growth of human T cells by anti-T3 or anti-Ti antibodies. The proliferation of human peripheral blood T cells preactivated by exposure to PHA was inhibited in a specific manner by anti-T3. Colony formation in soft agar by REX cells, a leukemic cell line of early T cell phenotype, was completely inhibited by anti-T3 or anti-Ti antibodies, whereas isotype-matched antibodies to a variety of other T cell markers had no effect. Growth of REX cells in suspension culture was not affected by anti-T3 or anti-Ti. A cell line, T3.N1, was established from an agar colony of anti-T3-resistant REX cells. T3.N1 was phenotypically identical to REX except for failure to express any detectable T3 or Ti surface antigen. T3.N1 colony formation in soft agar was not inhibited by anti-T3 or anti-Ti. There was no rise in [Ca2+]i of T3.N1 cells after anti-T3 or anti-Ti exposure. These results indicate that in addition to the well-known positive regulatory effects of ligand binding to the T3/Ti complex, T3/Ti binding can also result in a down-regulatory signal for human T cell growth.     

Cross-linking of human T cell receptor proteins: association between the T cell idiotype beta subunit and the T3 glycoprotein heavy subunit

Bifunctional cross-linking reagents DSP, DSS, and BSOCOES were used to cross-link 125I-surface-labeled viable T lymphocytes. The cross-linked cells were solubilized in Nonidet-P40, immunoprecipitated with anti-Ti (monoclonal antibody T40/25) or anti-T3 (monoclonal antibodies UCHT-1 or OKT3), and analyzed by SDS-PAGE. With all three cross-linkers, the intact cross-linked products obtained with monoclonal antibody T40/25 from HPB-ALL cells were 20-30 kd heavier than the Ti dimer (Mr 80,000). When the DSP cross-linked product was isolated using either anti-Ti or anti-T3 monoclonal antibodies and then cleaved, bands having molecular weights identical with both the Ti and T3 subunits were obtained. The two-dimensional SDS-PAGE analysis (nonreducing followed by reducing conditions) of the DSS and BSOCOES cross-linked products revealed the specifically cross-linked bands to have Mr 40,000 and Mr 28,000. These data indicate that the Ti molecule and the T3 molecule are spatially associated on the cell surface and suggest the predominant association is between the Ti beta subunit (Mr 40,000) and the T3 heavy subunit (Mr 28,000).     

The T3/T cell receptor complex: antigenic distinction between the two 20-kd T3 (T3-delta and T3-epsilon) subunits.

Clonally distributed (clonotypic) antigen receptors on human T lymphocytes (alpha and beta chains) are associated with three invariable T3 polypeptide chains (T3 gamma, delta and epsilon), together forming the T3/T cell receptor complex. Monoclonal antibodies prepared against the two 20-kd T3 polypeptide chains demonstrated that T3-delta and T3-epsilon are distinct polypeptide chains. Only one monoclonal antibody (anti-T3-delta chain) reacted with the T cell surface as judged by indirect immunofluorescence, and by its mitogenicity for quiescent peripheral blood lymphocytes. Immunohistological staining and immunoprecipitation experiments showed that both the T3-delta and T3-epsilon chains are T cell-specific. As seen with the anti-alpha/beta chain reagent WT-31, anti-T3-delta chain monoclonal antibodies stained medullary thymocytes more intensely than cortical thymocytes, whereas the difference between the staining of cortical and medullary thymocytes was generally not apparent with anti-T3-epsilon chain antibodies. Because of this specificity and their ability to react with both the denatured and the native forms of each polypeptide chain, these new monoclonal reagents will be useful tools in studies of the biosynthesis and cell surface expression of the T3/T cell receptor complex during normal and malignant thymic differentiation.     

Monoclonal antibodies against T cell differentiation antigens initiate stimulation of monocyte/macrophage oxidative metabolism

Within the first minute after incubation with the mouse anti-human T cell orthoclone monoclonal antibodies OKT3, OKT4, and OKT8, and in the absence of complement, human monocytes generate a burst of highly reactive oxygen metabolites as detected by a luminol-dependent photometric chemiluminescence (CL) assay. The kinetics of the CL responses to these antibodies are identical to that induced by OKM1, the monoclonal antibody to human monocytes and granulocytes. With regard to CL response intensities, OKM1 induces the maximal response and those of OKT3, OKT4, and OKT8 closely reflect the proportion of T cell subsets recognized by these antibodies in peripheral blood. This reaction is also observed when monoclonal antibodies against mouse Lyt surface determinants (Lyt-1 and Lyt-2) and Thy-1 antigen are tested against murine spleen cells. This murine model was further used to investigate the specificity and the mechanism of this reaction. It was demonstrated that the CL response is Lyt antigen specific, occurs upon addition of monoclonal IgG but not IgM antibodies, requires the concomitant presence of CL-producing cells (CLPC) (promonocytes, monocytes, macrophages, and/or granulocytes) and of fully differentiated T cells, and lastly, is mediated via a T cell opsonization process. Selective blockade of bone marrow cell Fc receptors (FcR II) with monoclonal anti-mouse FcR II antibody inhibits the CL response to IgG2b anti-T cell antibody-coated thymocytes and thus strongly suggests that the stimulation of CLPC oxidative metabolism in this model results from the binding of opsonized T cells to plasma membrane Fc receptors. These observations lend additional support to increasing evidence that the initiation of effector functions by monoclonal anti-T cell antibodies may be strictly dependent upon the presence of monocytes and/or macrophages.     

The T11 (CD2) molecule is functionally linked to the T3/Ti T cell receptor in the majority of T cells

Most mature human T lymphocytes express both the multichain T3 (CD3)/Ti T cell receptor for antigen (TCR), and the biochemically distinct 55-kDa T11 (CD2) glycoprotein. Stimulating the T11 molecule causes profound T cell proliferation and functional activation in vitro, but the relationship of T11-mediated activation to antigenic stimulation of T lymphocytes in vivo remains unknown. We now present evidence that T11 function is directly linked to TCR components in T3/Ti+ T11+ human T cells. First, we found that stimulating peripheral blood T cells with the mitogenic combination of anti-T11(2) cells with the mitogenic combination of anti-T11(2) plus anti-T11(3) monoclonal antibodies caused the phosphorylation of TCR T3 chains. The predominance of T3-gamma-phosphorylation that occurred in anti-T11(2) plus anti-T11(3)-treated T cells is similar to the pattern previously observed in antigen-stimulated T cell clones. Second, T11 function depended upon concurrent cell-surface expression of the TCR. Thus, when peripheral blood T cells were deprived of cell surface T3/Ti by anti-T3 modulation, anti-T11(2) plus anti-T11(3)-induced mitogenesis and transmembrane signal generation in the form of calcium mobilization were inhibited. The mechanism of TCR-T11 interdependence was investigated in a series of TCR-deficient variants of a T cell lymphoblastoid cell line. T3/Ti negative variants expressed cell surface T11, but anti-T11(2) plus anti-T11(3) failed to cause detectable calcium mobilization. The TCR-deficient variants also failed to express T11(3) activation epitopes after incubation with anti-T11(2) antibodies, suggesting that T11(3) expression is an essential and TCR-dependent intermediate in the T11 activation mechanism in these cells. Taken together, our results suggest that T11 function depends upon cell-surface expression of TCR in many T3/Ti+ T11+ T lymphocytes, and T11-mediated activation is intimately interconnected with TCR activation mechanisms. A model in which stimulating signals delivered via T11 may be a part of antigenic activation of T lymphocytes is presented.     

T cell unresponsiveness to the mitogenic activity of OKT3 antibody results from a deficiency of monocyte Fc gamma receptors for murine IgG2a and inability to cross-link the T3-Ti complex

We recently identified defective monocyte accessory function as the cause of T cell unresponsiveness to the mitogenic activity of OKT3 antibody in cultures of peripheral blood mononuclear cells (PBMC) from five healthy subjects, members of one family. We now report that the underlying abnormality in nonresponders is at the level of monocyte Fc gamma receptors for murine IgG2a. T cell unresponsiveness was not restricted to the signal provided by OKT3 but occurred also for two other anti-T3 antibodies of the IgG2a subclass, in contrast to a normal proliferative response to IgG1 anti-T3 antibodies in one of the OKT3 nonresponders. By using cytofluorography, we found that monocytes from responders but not from nonresponders bound OKT3-FITC to their membrane. The binding could be blocked by mouse IgG2a and by human IgG, but not by mouse IgG1 nor by serum albumin. The data suggest that, through specific Fc gamma receptors for murine IgG2a, monocytes bind the Fc portion of OKT3 during T cell activation. The function of this Fc gamma receptor binding was further studied by culturing PBMC from nonresponders on plates coated with affinity-purified goat anti-mouse IgG antibodies as a substitute for monocyte Fc gamma receptors. The addition of OKT3 to nonresponder PBMC, cultured on such plates, resulted in T cell activation, as evidenced by thymidine incorporation, IL 2 production, and expression of IL 2 receptors. Soluble anti-mouse IgG was not able to substitute for monocyte Fc gamma receptors. The results demonstrate the existence of polymorphism in monocyte Fc gamma receptors for murine IgG2a. They also substantiate that an essential helper function of monocytes in T cell activation by anti-T3 is to provide a matrix for multimeric binding of the Fc portion of the anti-T3 antibodies in order to cross-link T3 molecules.     

Heterogeneity of human T4+ inducer T cells defined by a monoclonal antibody that delineates two functional subpopulations

A monoclonal antibody termed anti-T4 that detected approximately 60% of peripheral blood T lymphocytes was shown to define the human inducer population. In the present study, we characterized three additional monoclonal antibodies, anti-T4A, anti-T4B, and anti-TQ1, that were reactive with a similar percentage of T lymphocytes. Anti-T4A, anti-T4B, and anti-T4 delineated identical cell populations, while those defined by anti-TQ1 differed in several respects: 1) Anti-TQ1 stained a minority (less than 7%) of thymocytes, whereas the other antibodies stained a majority (80%); 2) Anti-TQ1 reacted with 70 to 85% of T4+ lymphocytes, but also stained 50% of T cells within the T4- (T8+) cytotoxic/suppressor subset; 3) The antigen defined by anti-TQ1 was not restricted in its expression to T cells; it defined a fraction of normal B and null lymphocytes as well as non-T cell lines. In vitro studies indicated that the subpopulations of T4+ T lymphocytes delineated by anti-TQ1 were functionally distinct. Although T4+TQ1+ and T4+TQ1- T cells proliferated in an equal fashion to soluble antigen and alloantigen, only the T4+TQ1+ subset was responsible for maximal proliferation in autologous MLR. This T4+TQ1+ subset contained a population of lymphocytes reactive with the previously defined JRA autoantibody. In contrast, the T4+TQ1-, but not the T4+TQ1+, subset provided the majority of T cell help for B cell immunoglobulin production in a pokeweed-driven system. We conclude that the subpopulation of T4+ inducer cells responsible for maximal helper activity in T-B interactions is restricted to a minor subpopulation of T4+ lymphocytes.     

Comparative biodistribution and antibody-dependent cellular cytotoxicity of native and heavy chain chimeric antibody.

We have recently chimerized the heavy chain of the pan-carcinoma monoclonal antibody (mAb) B72.3. Studies were undertaken to compare the IgG1 chimeric antibody, B72.3-1-3 with native murine B72.3 (nB72.3). Using fluorescence-activated cell sorting analysis, B72.3-1-3 demonstrated specific binding to fresh LS174T tumor cells. Biodistribution of 131I B72.3-1-3 was similar to 131I nB72.3 in nude mice bearing LS174T xenografts. Peak radiolocalization indices were noted on day 6 for B72.3-1-3 and day 8 for nB72.3. Both antibodies were capable of imaging LS174T tumors by radioimmunoscintigraphy. Antibody-dependent cellular cytotoxicity of LS174T by human peripheral blood lymphocytes was tested in 8h 51Cr release assays. With either no antibody or nB72.3, lymphocytes were not capable of killing LS174T cells. However, B72.3-1-3 at a concentration of 5 and 50 micrograms/ml mediated significant lysis of tumor cells by human lymphocytes. These results suggest that chimeric antibodies retain their binding properties to tumor cells and display biodistribution patterns similar to their unmodified counterparts. Such modifications may reduce the deleterious human antimouse antibody response to murine mAbs as well as augment antibody-dependent cellular cytotoxicity of tumor cells by human effectors.     

Use of tetrameric antibody complexes to stain cells for flow cytometry

Bifunctional tetrameric complexes of monoclonal antibodies were used to stain cells for flow cytometry. These complexes consist of two different mouse monoclonal IgG1 antibodies (one with specificity for a cell surface antigen, the other with specificity for a fluorochrome) cross-linked by two molecules of a monoclonal rat anti-mouse IgG1. The use of this immunological approach to cross-link fluorochromes to cell surface antigens was studied with tetrameric complexes containing Leu-3a or Leu-2a antibodies and monoclonal antibodies specific for the fluorochromes B- and R-phycoerythrin. The ability of such cyclic immune complexes to stain T-cell subset antigens on human peripheral blood lymphocytes was demonstrated in single and double-staining experiments. The results demonstrate that tetrameric antibody complexes provide a simple and efficient alternative to covalently labeled antibodies for the flow cytofluorimetric analysis of cell-surface antigens.     

The anti-tumor efficacy of lymphokine-activated killer cells and recombinant interleukin 2 in vivo: direct correlation between reduction of established metastases and cytolytic activity of lymphokine-activated killer cells

Our previous studies demonstrated that the incubation of human peripheral blood lymphocytes or murine splenocytes in recombinant interleukin 2 (RIL 2) resulted in the generation of lymphokine-activated killer (LAK) cells capable of lysing a broad spectrum of fresh tumors in short-term chromium-release assays. Moreover, injections of LAK cells plus RIL 2 were highly effective in eliminating established 3 day metastases in the lung and liver (1-3). We have examined several parameters to define whether or not the cytolytic activity of LAK cells as measured in vitro correlated directly with the in vivo anti-tumor efficacy of adoptively transferred LAK cells. LAK cells plus RIL 2 could mediate marked reductions of established pulmonary metastases in mice rendered T cell deficient by adult thymectomy and lethal, total body irradiation followed by reconstitution with T cell-depleted bone marrow and spleen cells. Thus there was no requirement for additional T lymphocytes of host origin for successful therapy with adoptively transferred LAK cells plus RIL 2. Fresh splenocytes depleted of T cells by anti-Thy-1.2 monoclonal antibody plus complement generated LAK cells that were as highly lytic to fresh tumor in vitro and were as effective in reducing established pulmonary metastases as those generated from untreated or complement-treated splenocytes. Thus the precursor to LAK cells with anti-tumor activity in vitro and in vivo did not express the Thy-1 antigenic marker. In contrast, treatment of LAK effector cells (those generated from a 3-day incubation of fresh, normal splenocytes in RIL 2) with anti-Thy-1.2 antibody plus complement reduced or abolished their in vitro cytolytic activity. However, when combined with the systemic administration of RIL 2, these T cell-depleted, non-lytic LAK cells remained as effective in reducing the number of established pulmonary metastases upon adoptive transfer as untreated or complement-treated lytic LAK cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

The T4 molecule differentially regulating the activation of subpopulations of T4+ cells

It has been demonstrated that the T4+2H4+ subset functioned as a suppressor inducer cell, whereas the reciprocal T4+2H4- subset provided help for B cell Ig production. In the present studies, a series of monoclonal antibodies to cell surface structures expressed on these subsets of cells were examined for their effects on the proliferative and immunoregulatory functions generated in AMLR. We demonstrated that anti-T4 antibody preferentially inhibited the proliferative response of the T4+2H4+ but not T4+2H4- cells against self-MHC antigens. In contrast, anti-T3 and anti-Ia antibodies inhibited the response of both subsets of cells. This subset preference of anti-T4 antibody was not attributable to either the isolation procedures used or a shift in the kinetics of proliferation to autologous self-MHC antigens. Moreover, both IL 2 production and the immunoregulatory function of the T4+2H4+ subset was profoundly inhibited by anti-T4 antibody, whereas the T4+2H4- subset was minimally influenced. In the absence of Ia molecules, T4+2H4+ but not T4+2H4- cell proliferation was inhibited with anti-T4 antibody. Together, these results suggest that the T4 molecule plays a distinct functional role in the differential triggering of subsets of T4+ cells.     

Activation of human thymocytes via the 50KD T11 sheep erythrocyte binding protein induces the expression of interleukin 2 receptors on both T3+ and T3- populations

Recent studies have demonstrated that the 50KD T11 molecule is a surface component of a macrophage-independent alternative pathway of human T cell activation that is unrelated to the T3/Ti antigen-MHC receptor complex. Given the expression of T11 on all human thymocytes, it was of interest to determine whether they could be activated via this pathway. The triggering of T11 by monoclonal antibodies anti-T112 and anti-T113, directed at two unique epitopes on the molecule, induced IL 2 receptor expression on both T3+ and T3- thymocytes but did not induce IL 2 production. Consequently, in contrast to peripheral blood T cells, thymocytes did not proliferate in response to anti-T112 and anti-T113 in the absence of exogenous IL 2. These studies suggest that IL 2 receptor gene activation precedes IL 2 gene activation in T cell development. The ability of the alternative pathway of T cell activation to induce IL 2 receptor expression on T3- thymocytes implies that the T11 molecule may have an important role in early thymocyte ontogeny.     

Murine lymphokine-activated killer (LAK) cells: phenotypic characterization of the precursor and effector cells

Murine and human lymphocytes incubated in recombinant interleukin 2 (RIL 2) generate a population of cytotoxic cells (lymphokine-activated killer cells [LAK]), which are able to lyse a wide array of fresh tumor cells but do not lyse fresh normal cells. Intravenous administration of these cells with the concomitant administration of RIL 2 can eliminate established pulmonary and hepatic metastases in mice. To characterize the cell that has in vitro LAK activity, we subdivided murine lymphocytes by lysing select subpopulations with the use of complement and antibodies against lymphocyte surface markers or by fluorescence-activated cell sorting. Thy-1.2-negative splenocytes were found to generate near normal amounts of LAK activity after RIL 2 incubation. Small and inconsistent LAK cell activity was generated from Thy-1.2-positive splenocytes. Ia-positive and surface immunoglobulin-positive splenocytes had little or no LAK precursor capability and did not appear to be necessary for LAK activation. Treatment of splenocytes with anti-asialo GM1 (anti-ASGM1) heterosera and complement markedly decreased their ability to generate LAK activity. At the effector stage, cytotoxic cells were of the Thy-1.2-positive, Ia-negative phenotype. Ia-depleted cells were separated into subpopulations bearing or not bearing the gamma Fc receptor (gamma FcR). The majority of cytotoxicity resided in gamma FcR-positive cells. Thus the precursors of murine LAK cells are "null" lymphocytes bearing neither T nor B cell surface markers but develop the Thy-1.2 cell surface marker in vitro, in association with the development of lytic activity for fresh tumor cells after stimulation by RIL 2.     

Human monocytes and U937 cells bear two distinct Fc receptors for IgG

Several convergent lines of evidence have led us to propose that human monocytes and the related cell line U937 possess a second class of IgG Fc receptor (FcR) in addition to the 72-Kd high affinity FcR previously described. IgG affinity purification from detergent lysates of surface radiolabeled U937 cells has yielded both a 40-Kd IgG-binding membrane protein (p40) and the 72-Kd FcR protein. By the same procedure, only the p40 was isolated from the erythroblast cell line K562 and from the B cell lines, Daudi and Raji. Serologic cross-reactivity between the 40-Kd FcR on U937 and Daudi cells was demonstrated using a goat anti-FcR antiserum. A murine (m) monoclonal antibody, raised against the FcR of K562 cells, precipitated the 40-Kd FcR from lysates of U937 and K562 cells but not from Daudi or Raji cells. This antibody, referred to as anti-p40 (IV.3), selectively inhibited the binding of murine IgG1-coated erythrocytes to U937 cells, whereas monomeric human IgG selectively inhibited binding of human anti-Rh(D)-coated erythrocytes to U937 cells. Both Daudi and U937 cells mediated mIgG1 anti-T3 (Leu-4)-induced stimulation of T lymphocytes. In contrast, mIgG2a anti-T3 (OKT3)-induced stimulation was supported effectively by U937 cells but only modestly by Daudi cells. Intact IgG or Fab fragments of anti-p40 (IV.3) blocked mIgG1 anti-T3 (Leu-4) stimulation but not mIgG2a anti-T3 (OKT3) stimulation of T cells; monomeric human IgG blocked only OKT3-induced stimulation. The simplest interpretation of these results is that human monocytes and U937 cells bear two classes of IgG FcR, one of 72 Kd and the other, as described above, of 40 Kd. We propose that the 72-Kd FcR mediates rosette formation with red cells coated by human anti-Rh IgG as well as T cell stimulation by mIgG2a anti-T3 (OKT3) and that the 40-Kd FcR mediates rosette formation with erythrocytes bearing mIgG1 as well as T cell stimulation by mIgG1 anti-T3 (Leu-4). Furthermore, we suggest that these two FcR are the human homologues of the murine macrophage FcRI (binding mIgG2a) and FcRII (binding mIgG2b/1).     

Regulation of the alternative pathway of T cell activation by anti-T3 monoclonal antibody

T cell activation may be triggered either through the T3-Ti antigen receptor complex or via an alternative macrophage-independent pathway involving the 50KD T11 sheep erythrocyte-binding glycoprotein. Monoclonal antibodies anti-T11(2) and anti-T11(3), directed at distinct epitopes of the T11 molecule, trigger mature T cells to proliferate and express their functional programs, and induce expression of IL 2 receptors on both T3+ and T3- thymocytes. We now show that a non-mitogenic anti-T3 antibody blocks activation via the T11 pathway of not only peripheral blood T cells, but also T3+ thymocytes. Anti-T3 does not affect surface expression of T11 or the rapid augmentation of T11(3) expression after incubation of cells with anti-T11(2). However, anti-T3 inhibits generation of IL 2 receptors and production of IL 2 by T lineage cells cultured with anti-T11(2) plus anti-T11(3). In contrast, modulation of the T11 molecule by a non-mitogenic anti-T11 antibody does not inhibit activation of T cells by a mitogenic anti-T3 antibody. The ability of anti-T3 to block expression of IL 2 receptors on both thymocytes and mature T cells activated by the T11 pathway suggests that a regulatory interaction may be important during T cell ontogeny to provide a mechanism for inhibiting expansion of autoreactive clones.     

Binding of human lymphocyte-specific monoclonal antibodies to common marmoset lymphoid cells

Commercially available monoclonal antibodies which bind to human lymphocyte subsets were screened for their ability to bind to lymphoid cells from the common marmoset Callithrix jacchus. Anti-Leu-5 and T11 were the only pan T-cell antibodies which reacted strongly. None of the antibodies which bind human lymphocytes of the helper/inducer subpopulation reacted with C. jacchus cells and only one antibody, T8, specific for the cytotoxic/suppressor subset, bound to the marmoset cells. The two antibodies tested which bind human B cells, B1 and anti-HLA-DR, were also reactive with marmoset cells. The cellular specificity of the T11, T8, and B1 antibodies was determined by dual binding studies on the fluorescence-activated cell sorter. The B1 antibody bound only Ig+ cells and all Ig+ cells were B1+. The T11 and T8 antibodies bound only to Ig- marmoset lymphoid cells and, as in the human, all T8+ marmoset cells were also T11+. Thus, using these monoclonal antibodies in the common marmoset one can identify three populations of lymphoid cells: (1) T11+, T8+ cells; (2) T11+, T8- cells; (3) B1+ cells.