Development of a cell culture/ELISA assay to detect anticoagulant rodenticides and its application to analysis of rodenticide treated grain.

This study describes a generic biological screening assay designed to detect anticoagulant rodenticides based on their inhibitory action on the vitamin K epoxide reductase protein complex, resulting in an accumulation of under-carboxylated prothrombin or proteins induced by vitamin K antagonism (PIVKA-II). A combined cell culture/ELISA assay was optimized to measure PIVKA-II production by the human hepatoma HepG2 cell line cultured in the presence of anticoagulant rodenticides. The specificity and sensitivity of the assay was validated using 41 grain extracts containing representative concentrations of rodenticide or appropriate nonrodenticide control compounds. In all cases, PIVKA-II produced by HepG2 cells in response to grain extracts spiked with rodenticides was detected by ELISA, while PIVKA-II was not detected in supernatants collected from cells exposed to nonrodenticide controls. This represents a novel, class-specific biological assay for the detection of anticoagulant rodenticides present in contaminated grain.

Beta2-adrenoceptor regulation of the K+ channel iKCa1 in human mast cells.

Human mast cells express the intermediate conductance Ca2+-activated K+ channel iKCa1, which opens following IgE-dependent activation. This results in cell membrane hyperpolarization and potentiation of both Ca2+ influx and degranulation. Mast cell activation is attenuated following exposure to beta2-adrenoceptor agonists such as salbutamol, an effect postulated to operate via intracellular cyclic AMP. In this study, we show that salbutamol closes iKCa1 in mast cells derived from human lung and peripheral blood. Salbutamol (1-10 microM) inhibited iKCa1 currents following activation with both anti-IgE and the iKCa1 opener 1-EBIO, and was reversed by removing salbutamol or by the addition of the selective beta2-adrenoceptor antagonist and inverse agonist ICI 118551. Interestingly, ICI 118551 consistently opened iKCa1 in quiescent cells, suggesting that constitutive beta2-receptor signaling suppresses channel activity. Manipulation of intracellular cAMP, Galphai, and Galphas demonstrates that the beta2-adrenergic effects are consistent with a membrane-delimited mechanism involving Galphas. This is the first demonstration that gating of the iKCa1 channel is regulated by a G protein-coupled receptor and provides a clearly defined mechanism for the mast cell "stabilizing" effect of beta2-agonists. Furthermore, the degree of constitutive beta2-receptor "tone" may control the threshold for human mast cell activation through the regulation of iKCa1.

Inhibition of human mast cell proliferation and survival by tamoxifen in association with ion channel modulation.

BACKGROUND: Human lung mast cells (HLMCs) and the human mast cell line HMC-1 express a strongly outwardly rectifying Cl- current characteristic of that carried by the voltage-dependent Cl- channel ClC-5. A similar but distinct current has been implicated in the control of cell proliferation in astrocytes. OBJECTIVE: In this study, we have examined the effects of the Cl- channel blocker tamoxifen on ion channel activity and cell proliferation in both HMC-1 and HLMCs. METHODS: We used the whole-cell patch-clamp technique to characterize macroscopic ion currents in mast cells before and after addition of tamoxifen. HMC-1 proliferation was assessed by incorporation of tritiated thymidine, HLMC proliferation was determined by counting cells in long-term culture, and cell viability was assessed by annexin V binding and propidium iodide uptake. RESULTS: In HMC-1, tamoxifen reduced the outward Cl- current at +130 mV by 73% +/- 9% at a concentration of 3 micromol/L and simultaneously opened a novel inwardly rectifying nonselective cation current with a mean inward current of 153 +/- 18 pA at -130 mV. Tamoxifen produced a dose-dependent inhibition of HMC-1 proliferation (90.3% +/- 4.0% inhibition at 30 micromol/L) without altering cell viability. Tamoxifen inhibited the outward ClC-5-like current in HLMCs, did not open an inward current, and produced a dose-dependent inhibition of HLMC proliferation in long-term culture. CONCLUSION: Tamoxifen inhibits HMC proliferation, possibly through ion channel modulation. This suggests that tamoxifen might be useful in the treatment of mast-cell-mediated diseases, including mastocytosis, asthma, and pulmonary fibrosis.