diamide and monochlorobimane

A method for the quantitative determination of the antioxidant form of glutathione (GSH) in red blood cells (RBCs) is described that does not require separation of the analyte of interest from the complex cellular matrix. The measurement portion of the analysis is performed using fluorescence spectrophotometry after monochlorobimane (a recognized probe for GSH) is added to a mixture containing RBCs and glutathione transferase (GST). This method was employed to determine the GSH concentration (0.042 +/- 0.002 mM) in a solution of 1% RBCs obtained from rabbits (n = 6). When spiked with authentic GSH (0.50 micromol), 99.8% of the GSH was recovered. Addition of GST to the sample mixture enabled most measurements to be made after 5-10 min of reaction time. Importantly, a decrease in GSH was measured upon the addition of a recognized oxidant (diamide) to the RBC sample followed by a subsequent return to normal levels of GSH. The ability of the GSH to recover from the oxidant attack occurred in a dose-dependent manner, requiring 30 and 90 min to recover from oxidant insults of 20 and 40 microM diamide, respectively. The antioxidant capabilities of the GSH were able to be monitored in real time, thus providing a method to dynamically monitor the ability of the RBC to maintain homeostasis in a complex matrix.

Topics: Animals; Antioxidants; Diamide; Erythrocytes; Fluorescent Dyes; Glutathione; Glutathione Transferase; Homeostasis; Oxidants; Pyrazoles; Rabbits; Sensitivity and Specificity; Spectrometry, Fluorescence; Time Factors

The probability that a cell will undergo apoptosis is in part dictated by the cellular redox potential, which is mainly determined by the reduction and oxidation of thiol residues on glutathione and proteins. We and others have recently shown that mitochondria play a critical role in the apoptotic cascade. Here, we address the question as to whether thiol modification regulates apoptosis and in which cellular compartment apoptosis-regulatory thiols are localized. To resolve this problem, we employed the divalent thiol-reactive agent diamide, which causes thiol cross-linking and thus mimics disulfide bridge formation, and a panel of monovalent thiol-reactive compounds (which impede disulfide bridge formation due to thiol oxidation), one of which is specifically targeted to the mitochondrial matrix. Our data indicate that thymocyte apoptosis induced by diamide mimics natural apoptosis in the sense that mitochondrial transmembrane potential (delta psi(m)) disruption precedes nuclear chromatin degradation; that monovalent thiol-reactive compounds inhibit apoptosis induced by diamide, glucocorticoids, irradiation, and topoisomerase inhibition; that the critical thiols determining cell fate after exposure to diamide, glucocorticoids, or DNA damage are likely to be located in the mitochondrial matrix; and that thiol oxidation and reduction are critical for apoptosis induction by some stimuli (glucocorticoids, DNA damage), but not by Fas/CD95 cross-linking. Taken together, these findings suggest that, at least in some pathways of apoptosis, mitochondrial thiols constitute a critical sensor of the cellular redox potential.

Topics: Animals; Apoptosis; Cells, Cultured; Dexamethasone; Diamide; Disulfides; DNA Fragmentation; fas Receptor; Female; Fluorescent Dyes; Intracellular Membranes; Membrane Potentials; Mice; Mice, Inbred BALB C; Mitochondria; Mitochondrial Swelling; Oxidation-Reduction; Permeability; Pyrazoles; Signal Transduction; Sulfhydryl Compounds; Sulfhydryl Reagents; Thymus Gland