Abstract
Site-specific suppressors of superoxide production (named S1QELs) in the quinone-reaction site in mitochondrial respiratory complex I during reverse electron transfer have been previously reported; however, their mechanism of action remains elusive. Using bovine heart submitochondrial particles, we herein investigated the effects of S1QELs on complex I functions. We found that the inhibitory effects of S1QELs on complex I are distinctly different from those of other known quinone-site inhibitors. For example, the inhibitory potencies of S1QELs significantly varied depending on the direction of electron transfer (forward or reverse). S1QELs marginally suppressed the specific chemical modification of Asp160 in the 49-kDa subunit, located deep in the quinone-binding pocket, by the tosyl chemistry reagent AL1. S1QELs also failed to suppress the binding of a photoreactive quinazoline-type inhibitor ([125I]AzQ) to the 49-kDa subunit. Moreover, a photoaffinity labeling experiment with photoreactive S1QEL derivatives indicated that they bind to a segment in the ND1 subunit that is not considered to make up the binding pocket for quinone or inhibitors. These results indicate that unlike known quinone-site inhibitors, S1QELs do not occupy the quinone- or inhibitor-binding pocket; rather, they may indirectly modulate the quinone-redox reactions by inducing structural changes of the pocket through binding to ND1. We conclude that this indirect effect may be a prerequisite for S1QELs' direction-dependent modulation of electron transfer. This, in turn, may be responsible for the suppression of superoxide production during reverse electron transfer without significantly interfering with forward electron transfer.
Highlights
The order of the suppressive efficiencies of the four S1QELs against ROS production from site IQ, in terms of the IC50 values, was S1QEL1.1 Ͼ S1QEL2.1 Ͼ S1QEL2.3 Ͼ S1QEL1.5 [24]. This order is identical to that of the inhibitory potencies (EC50) against the reverse electron transfer determined in the present study (Table 1), complex I samples differ between the two studies
S1QELs exhibited no inhibition against mitochondrial enzymes and transporters presiding over ATP production via oxidative phosphorylation at 10 M or 20 ϫ IC50
The present study was conducted to address the question of how each S1QEL selectively modulates reverse electron transfer but not forward electron transfer in complex I at a definite concentration range, even though both take place inside a common reaction pocket
Summary
As for forward electron transfer, each test compound was incubated with SMPs for 4 min before the reverse reaction started by the addition of ATP (final concentration: 1.0 mM). The inhibitory effects of S1QEL1.5 and S1QEL1.5_D1 on the reverse electron transfer gradually disappeared during incubation with SMPs (Fig. 3B), as observed with forward electron transfer.
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