Antitumor effects of interleukin 2 liposomes and anti-CD3-stimulated T-cells against murine MCA-38 hepatic metastasis.

The stimulation of murine splenocytes with the monoclonal antibody anti-CD3 and interleukin 2 (IL-2) results in the propagation of large numbers of cells (T-activated killer; T-AK) which demonstrate high therapeutic efficacy when infused with IL-2 into mice bearing pulmonary metastases. Interleukin 2 infusions are required to maintain the function of the adoptively transferred cells. Recent data demonstrate that the therapeutic efficacy can be enhanced by encapsulating IL-2 in liposomes. The present work tested the combination of T-AK cells with IL-2 liposomes in an immunotherapy model utilizing the MCA-38 murine colon adenocarcinoma. Expansion of murine splenocytes was achieved with anti-CD3 monoclonal antibody plus IL-2 and was consistently greater than 50-fold during a 9-day culture period. Cytolytic activity of the murine T-AK cells was mediated primarily by Lyt-2+ cells. In vivo results demonstrate synergistic therapeutic efficacy of the combination of IL-2 liposomes and T-AK cells. Evaluation of the in vivo distribution of these T-AK cells utilizing congenic mice demonstrates that Lyt-2+ cells from these in vitro cultures infiltrate hepatic metastases in vivo. The activation of lymphocytes with anti-CD3 monoclonal antibody and IL-2 appears to be a reproducible and convenient method of producing cells capable of producing antitumor effects in models of adoptive immunotherapy.

Characterization of OKT3-initiated lymphokine-activated effectors expanded with interleukin 2 and tumor necrosis factor alpha.

Synergistic and cooperative effects in vitro of OKT3, interleukin 2 (IL-2), and tumor necrosis factor alpha (TNF) as stimuli in generating effectors with lymphokine-activated killer activity were studied. Activation of human peripheral blood mononuclear cells with OKT3 (10 ng/ml) for 48 h, followed by culture in low concentrations of IL-2 (10 units/ml) and TNF (250 units/ml) resulted in higher cell recovery (50- to 3300-fold) compared to the number of cells in the initial culture and enhanced lytic activity against both Raji and fresh lung tumor targets (mean 100-fold) by day 30 compared to those expanded with higher concentrations of IL-2 (100 units/ml) alone. Immunofluorescence analysis of peripheral blood mononuclear cells initiated with OKT3 and expanded with IL-2 plus TNF revealed a selective increase in CD8+ cells and a decrease in CD4+ by day 28; the opposite effect was observed when cells were incubated with 100 units/ml of IL-2 alone, resulting in a greater proportion of CD4+ cells. Almost all cells were CD3+. Studies of cytokine receptor expression indicated that OKT3 plus IL-2 plus TNF caused an earlier up-regulation of the IL-2 receptor beta chain (Tac) and higher TNF receptor expression by day 6 compared to 100 units/ml IL-2 alone. Significant TNF levels (greater than 17 units/ml) were measured in culture supernatants from peripheral blood mononuclear cells initiated with OKT3 alone. Collectively, our data demonstrate that induction of lymphokine-activated killer activity with OKT3, followed by culture in low concentrations of IL-2 plus TNF is an alternative to the use of high-dose IL-2 alone and suggest that this combination may provide potential advantages in long-term generation of cytolytic cells.

Study on the E-rosette-blocking effects of E receptors.

Lymphocytes were purified from 10 samples of normal peripheral blood. E receptors were detached by heating to +45 degrees C. The sheep red blood cells (SRBC) and 2-aminoethylisothiouronium bromide (AET)-treated SRBC (AET-SRBC) were incubated at +4 degrees C for 2 h, with E receptors. E receptors detached by heating blocked E-rosette formation with SRBC, but not with AET-SRBC. The results suggest that E receptors may exhibit different conformational structures or different molecules which are responsible for E-rosette formation and E-AET-rosette formation, respectively.

Inhibition of lymphocyte proliferation by a monoclonal antibody (RFT2) against CD7.

The effect of the monoclonal antibody RFT2, directed against CD7, on T cell proliferation in unseparated peripheral blood mononuclear cell populations induced by various stimulants was investigated. The addition of RFT2 to cell cultures inhibited the T cell proliferation induced by tuberculin PPD and OKT3 but not by phytohaemagglutinin, concanavalin A or phorbol myristic acid; RFT2 had to be present during the first 24 h of culture in order to elicit inhibition; inhibition of proliferation was not due to down regulation of interleukin-2 receptor on the surface of T cells; and suppressive effects could be transferred by mononuclear cells pre-treated with RFT2. These results are of particular relevance in view of the known in vivo suppressive effect of RFT2 in humans.

Interleukin 4 and interferon gamma production in restimulated CD4+ and CD8+ cells indicates memory type responsiveness.

Interleukin 4 (IL-4) and interferon gamma (IFN-gamma) production was analysed in murine spleen cells during primary and secondary mitogen stimulation in vitro. The kinetics, frequency and phenotype of single lymphokine-producing cells were studied by combining intracytoplasmatic immunofluorescence and surface staining. Both IL-4 and IFN-gamma was produced by CD4+ as well as CD8+ cells, however 75-80% of IL-4 producers were CD4+ and 90% of IFN-gamma+ cells were CD8+. In primary stimulations, concanavalin A (Con A) activation or anti-CD3 antibody together with phorbol 12-myristate 13-acetate (PMA) induced different patterns of lymphokine production. Approximately the same frequency of IFN-gamma+ cells was induced by both stimulation procedures but the kinetics was different with a peak at 30 h using Con A and at 52 h using anti-CD3 and PMA. IL-4 production peaked at 52 h, but the frequency of IL-4+ cells was 8-10 times higher after stimulation by anti-CD3 and PMA than after Con A stimulation. During restimulation of the mitogen activated cells, lymphokines were rapidly produced; both IL-4 and IFN-gamma production peaked at 8-11 h. Only a small increase in the frequency of IL-4+ cells was seen, at most two to three times. No evidence for a major shift of lymphokines produced between primary and secondary stimulations could be found. Instead, the pattern of lymphokine production induced by the primary stimulus was dominant also in secondary cultures irrespective of stimulation condition.

A novel surface molecule expressed by long-term cultured T and natural killer cells is involved in cell activation.

Two monoclonal antibodies (mAb), termed ED6 and LD6, were obtained by immunizing mice with cytotoxic T cell lines expressing the T cell receptor (TcR) gamma/delta. These mAb were selected according to their ability to trigger the cytolytic program of the immunizing cell lines in a redirected killing assay. Both mAb recognized molecule(s) expressed on the surface of most long-term cultured TcR gamma/delta +, TcR alpha/beta + and CD3-CD16+ lymphocytes, while it was absent on resting peripheral blood lymphocytes. In addition both mAb reacted with neoplastic B cell lines, Epstein-Barr virus-transformed B cell lines, small cell lung cancer and glioma cell lines, while no surface reactivity was detected on ovarian, breast, colon and non-small cell lung cancer lines. The functional activity of these mAb was studied by two cytolytic assays. Both mAb were able to trigger the cytolytic program of CD3+TcR gamma/delta + polyclonal cell lines and of a CD3-CD16+ NK cell clone against the murine mastocytoma target cell line P815 (Fc receptor+) in a 4-h 51Cr-release assay. In addition, ED6 and LD6 hybridomas were lysed by TcR gamma/delta + effector cells while other hybridomas (obtained from the same fusion) were not lysed. ED6 and LD6 mAb (in the presence of submitogenic doses of the phorbol 12-myristate 13-acetate) also induced the secretion of interleukin 2 by ED6/LD6+ T cell clones expressing TcR gamma/delta or alpha/beta. mAb-induced surface antigen modulation experiments showed that the antigenic determinant recognized by ED6 and LD6 co-modulated, thus indicating that the two mAb probably recognize the same or closely associated molecules. The molecular characteristics of the antigen recognized by the mAb were investigated by Western blot analysis. The LD6 mAb recognized a major band of approximately 65 kDa, both under nonreducing and reducing conditions. These data indicate that ED6 and LD6 mAb recognize a novel non-lineage-specific activation antigen which is involved in the induction of the functional program of long-term cultured T or natural killer cells.

Enhancement of interleukin 2 production in human and Gibbon T cells after in vitro treatment with lithium.

The effect of trace elements lithium, selenium, and zinc on interleukin 2 (IL-2) production by peripheral blood mononuclear cells (PBMC), MLA144, and Jurkat cell lines has been studied. Lithium markedly enhanced IL-2 production by MLA144 and PBMC, but not by Jurkat. Selenium could only enhance IL-2 production by MLA144, whereas in none of these three systems was IL-2 production altered by zinc. The enhancing effect of lithium on IL-2 production showed some differences from that of tetradecanoylphorbol acetate (TPA) in the following aspects: (i) TPA could reverse the inhibitory effect of anti-CD2 monoclonal antibody on IL-2 production, whereas lithium could not; and (ii) lithium was unable to synergistically induce IL-2 production with anti-CD3 monoclonal antibody as TPA did. The effect of lithium on IL-2 production was in the early phase of lymphocyte activation. The addition of cholera toxin or theophylline to phytohemagglutinin-stimulated PBMC culture suppressed IL-2 production. However, IL-2 production could be restored by lithium. There was a corresponding increase in cAMP in cholera toxin or theophylline-treated PBMC, which could be reversed by lithium. Therefore, lithium restores IL-2 production via a decrease in cAMP.

Regulation of human B cell responsiveness by CD8+ T cells: differential effects of stimulation with monoclonal antibodies to CD3 and pokeweed mitogen.

Previous studies have shown that human CD8-positive T cells activated by immobilized mAb to the CD3 complex have the capacity to support the generation of Ig secreting cells (ISC). The experiments reported here were undertaken to examine the nature of CD8+ T cell helper function in greater detail. CD8+ T cells that had been treated with mitomycin C (CD8+ mito) and stimulated by immobilized mAb to CD3 (64.1) provided help for the generation of ISC from resting B cells. By contrast, CD8+ mito did not support the generation of ISC in cultures stimulated by pokeweed mitogen (PWM). This could not be explained by differences in the production of IL2, since PWM and anti-CD3 induced comparable amounts of IL2 from CD8+ mito. In anti-CD3-stimulated cultures, CD8+ mito supported the generation of larger numbers of ISC when B cells were also activated with Staphylococcus aureus (SA). By contrast, in PWM-stimulated cultures, CD8+ mito did not provide help for SA-activated B cells. Rather, PWM-stimulated CD8+ mito appeared to suppress the generation of ISC induced by PWM-activated CD4+ mito or by SA + IL2, whereas anti-CD3-stimulated CD8+ mito did not. Only control CD8+ T cells, which were able to proliferate, exerted suppressive effects in anti-CD3-stimulated cultures. Examination of the functional capacities of a battery of CD8+ T cell clones indicated that the same clonal population of CD8+ cells could provide help or suppress responses when stimulated with anti-CD3 or PWM, respectively. The functional activities of CD8+ clones differed from those of fresh CD8+ cells. Thus, anti-CD3-stimulated CD8+ clones provided help for B cells regardless of whether they were treated with mitomycin C. Moreover, PWM stimulated suppression by CD8+ clones was abrogated by treating the clones with radiation or mitomycin C. These results indicate that helper T cell function is not limited to the CD4+ T cell population, but that help can also be provided by appropriately stimulated CD8+ T cells. Taken together, these results indicate that CD8+ T cells are not limited in their capacity to regulate B cell responses, but rather can provide positive or negative influences depending on the nature of the activating stimulus.