Comparison of DNA adducts from exposure to complex mixtures in various human tissues and experimental systems

DNA adducts derived from complex mixtures of polycyclic aromatic compounds emitted from tobacco smoke are compared to industrial pollution sources (e.g., coke ovens and aluminum smelters), smoky coal burning, and urban air pollution. Exposures to coke oven emissions and smoky coal, both potent rodent skin tumor initiators and lung carcinogens in humans, result in high levels of DNA adducts compared to tobacco smoke in the in vitro calf thymus DNA model system, in cultured lymphocytes, and in the mouse skin assay. Using tobacco smoke as a model in human studies, we have compared relative DNA adduct levels detected in blood lymphocytes, placental tissue, bronchoalveolar lung lavage cells, sperm, and autopsy tissues of smokers and nonsmokers. Adduct levels in DNA isolated from smokers were highest in human heart and lung tissue with smaller but detectable differences in placental tissue and lung lavage cells. Comparison of the DNA adduct levels resulting from human exposure to different complex mixtures shows that emissions from coke ovens, aluminum smelters, and smoky coal result in higher DNA adduct levels than tobacco smoke exposure. These studies suggest that humans exposed to complex combustion mixtures will have higher DNA adduct levels in target cells (e.g., lung) as compared to nontarget cells (e.g., lymphocytes) and that the adduct levels will be dependent on the genotoxic and DNA adduct-forming potency of the mixture

Molecular mechanisms involved in T cell activation. I. Evidence for independent signal-transducing pathways in lymphokine production vs proliferation in cloned cytotoxic T lymphocytes

It is well-established that activated T cells proliferate in response to interleukin 2 (IL 2) and produce various soluble lymphokines such as macrophage-activating factor (MAF) in response to antigen. Prior to investigating the molecular events involved in signaling the initiation of these responses in cloned murine cytotoxic T lymphocytes (CTL), we determined whether these responses could occur independently, and we established for each response the time during which signal transducing mechanisms may function. It was found that this cloned CTL population was in a resting state (G1 phase of cell cycle) 7 days after stimulation with antigen plus IL 2. At this time, the incubation of these resting CTL with IL 2 for 4 to 6 hr resulted in a maximal proliferative response that was not accompanied by the production of MAF. Conversely, the incubation of resting CTL with antigen or lectin (in the absence of IL 2) for at least 8 hr resulted in the maximal production of MAF at 24 hr without inducing a proliferative response. In addition, antigen or lectin, but not IL 2, triggered an immediate (less than 1 min) and sustained (at least 8 hr) mobilization of intracellular calcium. The kinetics of this calcium response paralleled the minimum time (8 hr) that was required for resting CTL to interact with either antigen or lectin in order to produce maximal titers of MAF. These results indicate that proliferation and lymphokine (MAF) production in cloned murine CTL are independent events. In these resting CTL, the signal mechanisms that mediate the production of lymphokines are most likely restricted to the initial 8 hr of stimulation by antigen or lectin and involve the rapid and prolonged mobilization of cytoplasmic calcium. Proliferative signals, however, are probably complete within 4 to 6 hr after stimulation by IL 2 and do not involve readily demonstrable fluxes of cytoplasmic calcium, as determined by the fluorescent calcium probe Quin 2

Mechanism of cyclosporin A-induced immunosuppression. Cyclosporin A inhibits receptor-mediated and non-receptor-mediated lymphokine production as well as interleukin-2-induced proliferation in cloned T lymphocytes

The effects of cyclosporin A (CyA) on the activation processes of cloned murine cytotoxic T lymphocytes (CTL) have been examined. With the use of Day 7 resting cloned CTL it was possible to separate the functions of lymphokine production (macrophage-activating factor, MAF) and interleukin 2 (IL-2)-induced proliferation of these cells. The effect of CyA on each of these activities was analyzed independently. CyA was found to inhibit both receptor-mediated MAF production in response to stimulation with antigen and lectin and MAF production in response to non-receptor-mediated stimulation (by anti-Thy-1 antibodies, ionophore, and phorbol ester). Further, CyA was observed to inhibit the re-entry of these resting CTL into the cell cycle upon stimulation with IL-2. The effect of CyA on MAF production did not appear to be due to inhibition of the signal-transducing mechanism involved in this process (i.e., inositol lipid hydrolysis, calcium mobilization, and protein phosphorylation). The action of CyA on the IL-2-induced proliferation was not due to inhibition of IL-2 receptor expression or the binding of IL-2 to its receptor. Thus, CyA appeared to mediate its suppressive effects on MAF production and IL-2-induced proliferation through an action on some later step(s) in the signal pathways of these activities

Molecular mechanisms involved in T cell activation. II. The phosphatidylinositol signal-transducing mechanism mediates antigen-induced lymphokine production but not interleukin 2-induced proliferation in cloned cytotoxic T lymphocytes

The phospholipid metabolism of cloned murine cytotoxic T lymphocytes (CTL) was examined under conditions in which the induction of proliferation by interleukin 2 (IL 2) and the stimulated production of lymphokine (macrophage-activating factor (MAF] by concanavalin A (Con A) and specific antigen occurred independently of each other. Activation of the CTL by either of the latter two stimuli resulted in changes in the metabolism of phosphatidylinositol (PI) that were early (less than 2.5 min), specific, and prolonged (6 to 8 hr). These changes were primarily characterized by an increase in phosphatidic acid (PA) and PI, with a decrease in phosphatidylinositol-4,5-bisphosphate. The duration of these phospholipid responses, particularly PA and PI, approximated the minimum time of CTL-stimulus interaction required to produce maximal titers of MAF. No changes were observed in other major classes of phospholipids during 8 hr of continuous stimulation. Stimulation with an irrelevant antigen had no effect on CTL phospholipid metabolism. In contrast to specific antigen or Con A, the T cell growth factor IL 2 failed to elicit specific and early biosynthetic responses from PA and PI. Instead, there were nonspecific biosynthetic responses from all major phospholipid classes (including phosphatidylcholine and phosphatidylethanolamine, as well as PA and PI) which occurred between 1 and 6 hr after IL 2 stimulation. Both 1,2-diacylglycerol (DAG) and inositol phosphates (IP), the hydrolytic products of PI turnover, were produced in response to MAF-inducing stimuli, but neither were detected in response to the proliferative stimulus IL 2. Together, these results indicate that the hydrolysis of PI and the concomitant production of the putative second messengers DAG and IP are involved in signaling the production of lymphokines (MAF) by CTL. On the other hand, the failure of IL 2 to elicit a full-spectrum PI response suggests that signals mediating CTL proliferation may utilize an alternate and still undefined pathway

Transmembrane signalling via the T11-dependent pathway of human T cell activation. Evidence for the involvement of 1,2-diacylglycerol and inositol phosphates

It has previously been shown that some anti-T11 monoclonal antibodies, when used in combination, can activate the human T cell line Jurkat to produce interleukin 2. In this study, we investigate the mechanism by which perturbation of different epitopes of T11 molecules induces activation in Jurkat cells. We show that this activation is initiated by a T11-mediated increase in the concentration of free cytoplasmic calcium ions ([Ca2+]i). The initial increment in [Ca2+]i can occur when extracellular Ca2+ is depleted by EGTA, indicating that Ca2+ from intracellular stores is mobilized. As an early response to extracellular signals provokes a rapid breakdown of a class of lipid known collectively as the phosphoinositides, we measured the levels of phosphatidylinositol bisphosphate (PIP2) which is hydrolyzed to generate inositol triphosphates (IP3), the putative mobilizer of Ca2+ from internal stores and 1,2-diacylglycerol (DAG), the physiological activator of protein kinase C. Monoclonal antibodies directed either against different epitopes of T11 molecules or the T3-Ti antigen receptor complex provoke a rapid breakdown of PIP2, the parental product from which IP3 and DAG derive. In addition antibodies to either the T11 molecules or T3-Ti antigen receptor complex induce marked elevations in IP3, other inositol phosphate compounds and DAG. Taken together, these data indicate that, during T cell activation, due to the perturbation of T11 molecules or T3-Ti antigen receptor complex, membrane phosphoinositides are specifically hydrolyzed. This hydrolysis of phosphoinositides generates two putative second messengers such as IP3 and DAG, which mobilizes Ca2+ from intracellular stores and stimulates protein phosphorylation, respectively

Molecular mechanisms involved in T cell activation. III. The role of extracellular calcium in antigen-induced lymphokine production and interleukin 2-induced proliferation of cloned cytotoxic T lymphocytes

The role that extracellular calcium plays in activating resting cloned cytotoxic T lymphocytes (CTL) to proliferate and to produce lymphokines was examined. In these cells, stimulation with interleukin 2 (IL-2) induced a proliferative response without a concomitant production of macrophage-activating factor (MAF), whereas stimulation with antigen or lectin (in the absence of IL-2) induced MAF production but not proliferation. In the case of IL-2-induced proliferation, extracellular calcium was required to initiate proliferation as well as to prevent cellular arrest later in the G2 + M phase of the cell cycle. In MAF production extracellular calcium was required both to activate the phosphatidylinositol signal-transducing mechanism and to mobilize intracellular calcium in antigen- or lectin-stimulated cytotoxic T lymphocytes. Further, extracellular calcium was required for only 8 of the 18 hr of stimulation time which was needed to achieve maximal MAF production, indicating that both calcium-dependent and -independent events exist in the signal pathway. Additional experiments with calcium ionophores and activators of protein kinase C indicated that although both intracellular calcium mobilization and de novo protein phosphorylation are involved in MAF production, an optimal increase in the level of intracellular calcium by itself is insufficient to induce the production of this lymphokine