Depletion of mast cell ATP inhibits complement-dependent cytotoxic histamine release

Calcium and GTP-gamma-S as single effectors of secretion from permeabilized rat mast cells: requirements for ATP

Treatment with metabolic inhibitors and addition of exogenous MgATP exerted different effects on secretion from streptolysin-O-permeabilized mast cells, responding to calcium and GTP-gamma-S as single effectors (i.e., independently of each other). These effects were also strongly dependent on the experimental conditions. Thus cells, triggered by Ca2+ at the time of permeabilization, did not require MgATP, but after metabolic inhibition rapidly became absolutely dependent on its provision, requiring high (> mM) concentrations. AMP-PNP was not effective. After longer treatment with metabolic inhibitors, the absolute dependence on MgATP was also exhibited by cells responding to dual effectors (i.e., Ca2+ and GTP-gamma-S applied together). In contrast, calcium independent secretion due to GTP-gamma-S was more resistant to metabolic inhibition, exhibiting no absolute requirements for MgATP. Once the responsiveness to GTP-gamma-S had been lost, it could not be restored by addition of MgATP. MgATP, in fact, inhibited the response of permeabilized cells to GTP-gamma-S. This effect could be mimicked by AMP-PNP. When permeabilized cells were washed before triggering, MgATP (0.1-1 mM concentration range) was no longer inhibitory but stimulatory. These differences between Ca(2+)- and GTP-gamma-S-induced responses indicate that ATP utilization is essential to the calcium, but not to the guanine nucleotide, pathway to secretion. The rate of the response to calcium/MgATP was much slower in the absence than in the presence of GTP-gamma-S. The onset of secretion occurred after an initial delay. This lag phase was abolished by addition of GTP-gamma-S, suggesting that a GTP-binding protein may control a reaction which constitutes a rate-limiting step in the secretory process.

Essential synergy between Ca2+ and guanine nucleotides in exocytotic secretion from permeabilized rat mast cells

Rat mast cells, pretreated with metabolic inhibitors and permeabilized by streptolysin-O, secrete histamine when provided with Ca2+ (buffered in the micromolar range) and nucleoside triphosphates. We have surveyed the ability of various exogenous nucleotides to support or inhibit secretion. The preferred rank order in support of secretion is ITP greater than XTP greater than GTP much greater than ATP. Pyrimidine nucleotides (UTP and CTP) are without effect. Nucleoside diphosphates included alongside Ca2+ plus ITP inhibit secretion in the order 2'-deoxyGDP greater than GDP greater than o-GDP greater than ADP approximately equal to 2'deoxyADP approximately equal to IDP. Secretion from the metabolically inhibited and permeabilized cells can also be induced by stable analogues of GTP (GTP-gamma-S greater than GppNHp greater than GppCH2p) which synergize with Ca2+ to trigger secretion in the absence of phosphorylating nucleotides. ATP enhances the effective affinity for Ca2+ and GTP analogues in the exocytotic process but does not alter the maximum extent of secretion. The results suggest that the presence of Ca2+ combined with activation of events controlled by a GTP regulatory protein provide a sufficient stimulus to exocytotic secretion from mast cells.

T-Lymphocyte-mediated cytolysis as an excitatory process of the target. I. Evidence that the target cell may be the site of Ca2+ action

Delivery of the lethal hit signal to target cells (TC) by cytolytic T lymphocyte (CTL) has traditionally been considered strictly dependent upon the presence of external Ca2+ [( Ca2+]ext) in the medium, but neither the role of Ca2+ nor its site of action (effector or target) have been known. We have observed that in different CTL/TC systems the requirement for [Ca2+]ext varies, depending on the target. Some TC, like leukemia L1210, are strictly dependent on [Ca2+]ext for lysis while others, like EL4 (and P815), are not. It is therefore suggested that, where required, [Ca2+]ext exerts its effect(s) on the TC and not the CTL. In support of this conclusion are experiments showing that effector cells cytolytic to certain TC in the absence of [Ca2+]ext, require [Ca2+]ext when used themselves as TC of other effectors. Verapamil, a Ca2+-channel blocker, inhibits the lysis of L1210 but not of EL4 cells, suggesting involvement of Ca2+ flux into L1210 target cells and, if at all involved, Ca2+ mobilization from internal stores in EL4. The different lytic susceptibility of the two TC to the Ca2+ ionophore A23187, in the presence and absence of [Ca2+]ext, correlated with their responses to CTL. It suggests Ca2+ influx into both types of TC in the presence of [Ca2+]ext and its release from internal stores in the lysis of EL4 but not L1210 in the absence of [Ca2+]ext. In view of these results indicating that the target is the site of Ca2+ action, we propose that CTL induce a Ca2+-regulated activation of the TC leading to its lysis.

The molecular basis for cytolytic T lymphocyte function: analysis with blocking monoclonal antibodies

During the past decade the mechanism of CTL-mediated killing has been resolved into 3 steps, and its cation requirements, and general nature have been well defined. However, biochemical understanding of the CTL-target interaction has made little progress. Recently, we have developed a monoclonal antibody (MAb) which blocks killing by binding to a previously undescribed molecule on the CTL membrane, a molecule which we therefore have termed lymphocyte function-associated antigen one (LFA-1). LFA-1 and Lyt-2,3 are the only presently identified sites for such blocking; antibodies to over a dozen other molecules expressed on the CTL do not block killing. Present evidence suggests that LFA-1 is crucial in the adhesive interaction of T cells with other cells (e.g., targets, macrophages, perhaps B cells) The continuing search for blocking MAbs provides a systematic way to link specific molecules with CTL function.

Inhibition of mast cell histamine secretion by N-substituteed derivatives of phosphatidylserine

The structural basis for the highly specific action of phosphatidylserine in enhancing mast cell histamine secretion induced by concanavalin A was investigated by studying the activities of three N-substituted derivatives: N-acetyl phosphatidylserine, N-1-dimethylaminonaphthalene-5-sulfonly phosphatidylserine, and N-4-nitrobenzo-2-oxa-1,3-diazole phosphatidylserine. None of the derivatives was capable of activating concanavalin A-induced histamine secretion at concentrations two to three times that required for maximal activation by phosphatidylserine. Instead, the derivatives were found to inhibit the secretory response of mast cells to the calcium ionophore A23187 as well as to concanavalin A. The inhibition was noncytotoxic, partially reversible by washing, and associated with binding of N-substituted phosphatidylserine to the mast cell.