succimer and oxophenylarsine

An early event in the toxic effects of organic arsenic compounds, such as phenylarsine oxide (PAO), is an inhibition of glucose uptake. Glucose uptake involving the glucose transporter, GLUT4 is inhibited by PAO indicating an importance of vicinal sulfhydryls in insulin-stimulated glucose uptake. However, the data on effects of PAO on GLUT1 are conflicting. This study investigated the effects of PAO on glucose uptake in L929 fibroblast cells, cells, which express only GLUT1. The data presented here reveal a dual effect of PAO. At low concentrations or short exposure times PAO stimulated glucose uptake reaching a peak activation of about 400% at 3 microM. At higher concentrations (40 microM), PAO clearly inhibited glucose uptake. At intermediate concentrations (10 microM), PAO had no effect under basal conditions but completely inhibited activation of glucose uptake by glucose deprivation and partially inhibited methylene blue-stimulated glucose uptake. PAO increased the specific binding of cytochalasin B to GLUT1 suggesting a direct interaction with the transporter. These data are most consistent with PAO interacting with multiple proteins that regulate the activity of this transporter, one of which may be GLUT1 itself. The identity of these proteins will require further investigation.

Topics: Animals; Arsenicals; Biological Transport; Cell Line; Cytochalasin B; Enzyme Inhibitors; Fibroblasts; Glucose; Glucose Transporter Type 1; Mice; Succimer

It has been shown that oxophenylarsine (PhAsO) inhibits glucose uptake in MDCK cells. In addition to the known impairment of cellular energy metabolism, this inhibition may contribute to the acute toxicity of trivalent organic arsenicals. We have investigated the effect of BAL, DMPS, DMSA, and other sulfur compounds on cellular incorporation of [U-14C]PhAsO and their efficacy to revert PhAsO-induced inhibition of glucose uptake. In the presence of [U-14C]PhAsO (2 microM), the radiolabel was steadily accumulated by the cells over 150 min without any signs of severe cell damage (e.g., altered morphology, increased LDH release). A notable decrease of cellular ATP was only observed at 150 min, whereas within 30 min uptake of D-[6-(14)C]glucose was reduced to 40% of controls. When BAL, DMPS, or DMSA was added after 30 min, the inhibition of glucose uptake was reversed, accompanied by a decrease in cell-associated radiolabel from [U-14C]-PhAsO. Water-soluble DMPS and DMSA required longer times than BAL for comparable effects. 2,3-Bis(acetylthio)propanesulfonamide, a thioester derivative, and dithiothreitol, a 1,4-dithiol, were effective only with the highest concentration tested (200 microM). 2-Mercaptoethanol neither reversed inhibition of glucose uptake nor influenced [U-14C]PhAsO incorporation. Our results show that inhibition of glucose uptake is a very early event in PhAsO cytotoxicity which occurs before any decrease of cellular energy metabolism and/or full cellular loading with arsenic comes into effect. The more rapid onset of action of lipophilic BAL compared to PhAsO action.

Topics: Adenosine Triphosphate; Animals; Antidotes; Arsenic Poisoning; Arsenicals; Biological Transport; Cell Line; Dimercaprol; Dithiothreitol; Dogs; Enzyme Inhibitors; Glucose; L-Lactate Dehydrogenase; Mercaptoethanol; Succimer; Sulfonamides; Unithiol