Abstract
Mitochondrial and cytosolic aconitases have been indicated as major targets of .NO- and O2-.-mediated toxicity in cells due to the oxidant-mediated disruption of the [4Fe-4S] prosthetic group. However, under circumstances in which both .NO and O2-. are generated, their almost diffusion-controlled combination reaction (k = 6.7 x 10(9) M-1 s-1), leading to the formation of peroxynitrite anion (ONOO-), can out-compete the direct reactions of .NO and O2-. with aconitase and even the enzymatic dismutation of O2-. by superoxide dismutase. In this work, we report that ONOO- reacts with isolated pig heart mitochondrial aconitase at 1.4 x 10(5) M-1 s-1, resulting in a significant loss of enzymatic activity. Aconitase activity was totally recovered after postincubation with thiols and ferrous iron, indicating that ONOO- reactions with the enzyme involve the perturbation of the labile Fe alpha to yield the inactive [3Fe-4S] cluster, which is also evident by spectral changes. On the other hand, anaerobic exposure of isolated aconitase to high concentrations of .NO (> 100 microM) led to a moderate inhibition of the enzyme, which could be fully overcome by .NO displacement under an argon-saturated atmosphere, in agreement with the formation of a reversible inhibitory complex between .NO and the active site of aconitase. Superoxide inactivated mitochondrial aconitase at (3.5 +/- 2) x 10(6) M-1 s-1, a reaction rate 3 orders of magnitude slower than its reaction rate with .NO. O2-. could represent the main mechanism of inactivation of the enzyme in systems in which it is formed without significant concomitant production of .NO. Our results imply that the mechanisms by which .NO and O2-. inactivate aconitase in cell systems may not be simple due to their direct reactions with the iron-sulfur cluster, but may rely on the formation of ONOO-.
Highlights
Mitochondrial and cytosolic aconitases have been in- Several oxidants includinghydrogen peroxide, ferricyanide, dicated as major targets of ‘Nitric oxide (NO)- and 0;-mediated toxicity in cells due to the oxidant-mediateddisruption of the [4Fe-4S] prosthetic groupH. owever, under circumstances in which both ‘NO and 0; are generated, their and persulfate can inactivate the enzyme because of the oxidant-mediated lost of the labile iron from the cluster, giving a paramagnetic [3Fe-4SI1+cluster [4,5]
We report that ONOO- reacts with isolated pig heart mitochondrial aconitase at 1.4 x lo5M - ~s-’, resulting in a Nitric oxide (‘NO) is anendogenous free radical formed in a diverse variety of cell types by the enzymatic oxidation of L
We have studied thereactivity of 'NO, O;, and 7.6, containedin sealed rubber-capped tubes and incubaftoerd5 min at ONOO- toward isolated pig heart mitochondrial aconitase to determine whether previously ascribed effects of 'NO are solely due t o direct reactions with theenzyme or may rely on the formation of more oxidizing 'NO-derived intermediates
Summary
Materials-Porcine heart aconitase (essentially mitochondrial), citrictehvealsutautdeidebdycoam5p-omunind anaerobic before the preincubatiofnthe active enzyme addition of peroxynitrite. Forthe synthesisof 'NO, a series of three Cys, 10mM GSH, or 1m0 ~ DTT) under an argon-saturated atmosphere flasks plusa gas-sampling tube were sequentially connected using pfroers5- min, and activity was measuredA.ctive anaerobic aconitase sure-resistantTeflon tubing and gas-tight fittings. In bariseofl,ution of was exposed toauthenticnitric oxide (0-200 PM) orS-nitrosothiols 1M ferrous sulfate in 1M.5H,SO, in thefirst flask wasslowly mixed by (5-10 mM GSNO and 1-2 mM SNAP) in 100 mM Tris-HC1, pH 7.8, for a n argon stream witha solution of 1M sodium nitrite contained in the 25-30 min at 25 "C. No significant differences in aconitase activity weroebserved a t a higher iron or thiol concentration or longer incubation times
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