At the concentrations tested (5–25 μM), ABA inhibited state-3 res

At the concentrations tested (5–25 μM), ABA inhibited state-3 respiration of mitochondria in a concentration-dependent manner. This effect was observed when mitochondria were energized with either glutamate plus malate, the respiratory chain site I substrates (Fig. 2A), or succinate, a respiratory chain site II substrate (Fig. 2B). A maximum effect was observed at a concentration of 15 μM. ABA also inhibited

state-3 respiration of TMPD plus ascorbate-energized mitochondria in a concentration-dependent manner (data not shown). The compound did not stimulate state-4 respiration, indicating that it does not act as an uncoupler (data not shown). Subsequent experiments with carbonyl cyanide m-chlorophenyl hydrazone (CCCP)-stimulated mitochondrial respiration were performed to test selleckchem the inhibitor effect of the compound on the respiratory chain or on ATP synthase. ABA did not inhibit CCCP-uncoupled respiration, indicating that only oxidative phosphorylation was inhibited (Fig. 3). The same behavior was observed with oligomycin (ATPase inhibitor) and carboxyatractyloside

(ANT inhibitor). Figure 4 shows the effect of ABA on the Δψ of glutamate + malate-energized rat liver mitochondria. ABA (25 μM) did not dissipate Δψ. The same behavior was observed for oligomycin and carboxyatractyloside. At the end of the experiment, 1 μM CCCP (uncoupler) or 2.5 μM rotenone (complex I inhibitor) was added as a positive control, and the mitochondrial membrane electrical potential dissipated. The effect of ABA on SAHA HDAC nmr mitochondrial ATP levels was evaluated using the respiratory assay conditions 15 min after mitochondria were incubated with the compound (Fig. 5). In agreement with the mitochondrial respiration results, ABA caused a significant concentration-dependent

decrease in mitochondrial ATP levels, reaching a maximum effect at 15 μM. The effects of SB-3CT ABA on FoF1-ATPase activity were measured in intact-uncoupled mitochondria in the presence of CCCP, and in freeze–thawing-disrupted mitochondria, as shown in Fig. 6A and B, respectively. The ATPase activity of uncoupled mitochondria was increased in a concentration-dependent manner by ABA (Fig. 6A). In disrupted mitochondria, the effects were less dramatic and similar across all concentrations tested (Fig. 6B). The effect of ABA on NADH and succinate dehydrogenase activity was measured in freeze–thawing-disrupted mitochondria. As expected, ABA at concentrations from 5 to 25 μM did not cause significant changes in enzyme activity (data not shown). The purpose of this assay was to determine whether ABA inhibits ADP-induced depolarization of Δψ by interference with ANT. Carboxyatractyloside was used as a positive control for direct ANT inhibition. ABA caused significant, concentration-dependent inhibition of ADP-stimulated depolarization of Δψ (Fig. 7).

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