Induction of mitochondrial fusion by cysteine-alkylators ethacrynic acid and N-ethylmaleimide

Mitochondrial fusion and fission are important aspects of eukaryotic cell function that permit the adoption of varied mitochondrial morphologies depending upon cellular physiology. We previously observed that ethacrynic acid (EA) induced mitochondrial fusion in cultured BSC-1 and CHO/wt cells. However, the mechanism responsible for it was not clear since EA has a number of known cellular effects including glutathione (GSH) depletion and alkylation of cysteine residues. To gain insight, we have tested the effects of a variety of compounds on EA induced cellular toxicity and mitochondrial fusion. N-acetyl cysteine (NAC), a GSH precursor, was found to abrogate both the toxic and fusion-inductive effects, whereas diethylmaleate (dEM), a GSH depletor, potentiated both these effects in a dose-dependent manner. However, treatment with dEM alone, which depleted GSH to the same degree as EA, did not induce mitochondrial fusion. These results indicate that although detoxification of EA via formation of GSH conjugates is dependant upon GSH levels, the depletion of GSH by EA is not responsible for its effect on mitochondrial fusion. Dihydro-EA (DH-EA), a saturated EA analogue, lacked EA's toxicity and effect on fusion, indicating that the alpha,beta-unsaturated ketone is central to its observed effects. N-ethylmaleimide (NEM), another well-known cysteine-alkylator, also induced mitochondrial fusion at near toxic concentrations. These data suggests that cysteine-alkylation is the causative factor for fusion and toxicity. In live BSC-1 cells, EA induced fusion of mitochondria occurred very rapidly (<20 min), which suggests that it is inducing fusion by modifying certain critical cysteine residue(s) in proteins involved in the process.     

Interaction of ethacrynic acid and cysteine with renal medullary adenylate cyclase

Results of the present study indicate that (1) ethacrynic acid, dihydroethacrynic acid, and the cysteine adduct of ethacrynic acid inhibit plasma membrane-bound adenylate cyclase from canine renal medulla; (2) reaction with a sulfhydryl group is not essential for inhibition by ethacrynic acid and its derivatives, but may contribute quantitatively to the inhibition; and (3) cysteine enhances the activity of renal medullary adenylate cyclase in the presence of a vasopressin analog or sodium fluoride.Observations support the view that ethacrynic acid and its cysteine adduct interfere with the action of vasopressin on the distal nephron at the site of renal medullary adenylate cyclase.     

Effects of ethacrynic acid on intraocular pressure of anesthetized rats

Ethacrynic acid (ECA) lowers intraocular pressure (i.o.p.) by an effect usually ascribed to increased drainage of aqueous humor by the trabecular meshwork. Here, we describe the effects of a continuous 2-hr intracameral infusion of balanced salt solution (BSS), with or without 2 mM ECA (sodium salt), on IOP of pentobarbital anesthetized rats. The infusion was divided into a constant (0.05 microliter/min) and a periodic (0.25 microliter/min) component that cycled 4 min on then 4 min off. This permitted the calculation of dynamic changes in resistive (trabecular and uveoslceral drainage) and nonresistive (aqueous synthesis, episcleral venous pressure) components of IOP by fitting a second-order transfer function to the responses. ECA markedly blunted the BSS-induced rise in IOP (P < 0.01). The rise in resistive mechanisms (ocular impedance) was transiently blunted by ECA (P < 0.05) during the third and fourth 8-min cycles, and nonresistive mechanisms were reduced by ECA from cycles 3-10 (P < 0.05). Then, at the end of the infusion, the control and ECA dynamic values were similar (P < 0.05), although IOP of ECA-treated rats was still slightly reduced (P < 0.05). The most likely explanation is a summation of small changes in both resistive and nonresistive components of IOP dynamics. Systemic blood pressure was unchanged within either group. The well-known effects of ECA on the trabecular meshwork, alone, are insufficient to explain the dynamic changes in IOP observed in this model.     

Effect of furosemide and ethacrynic acid on sodium transport and potassium secretion]

Ethacrinic acid (0.5 mg/ml), similarly to strophanthin K, increased sodium content and decreased potassium content in the tissue of the frog urinary bladder. Furocemide (0.1 mg/ml) failed to change the ionic content of this tissue. These data indicated a difference in the intracellular action of furosemide and ethacrynic acid.     

Effect of ethacrynic acid on the course of cytotoxic glomerulonephritis]

Ethacrynic acid (10 mg/kg subcutaneously 15 days) significantly facilitated the experimental glomerulonephritis in rats. The efficacy of diuretic was confirmed by the improvement of the functional characteristics (the degree of proteinuria, the plasma contents of protein and urea, the creatinine excretion), and by the results of the histological investigation, especially at the second phase of the pathological process.     

Solution-phase parallel synthesis and screening of anti-tumor activities from fenbufen and ethacrynic acid libraries

The derivatives with fenbufen and ethacrynic acid core compounds was synthesized through a facial preparation of 1-amino-4-azidobutane. The subsequent coupling with 102 members of carboxylic acids afforded amide products. The in situ screening using colorimetric assay with 3-(4.5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide showed that fenbufen but not ethacrynic acid butyl amide members displayed the cytotoxicities to tumor cells substantially, including two human cell lines (MCF7 and A549) and two murine cell lines (C26 and TRAMP-C1). Three fenbufen analogs were found to have a good anti-tumor activity comparable to cisplatin.