Thiols and Neuronal Nitric Oxide Synthase: Complex Formation, Competitive Inhibition, and Enzyme Stabilization

Abstract

To elucidate how thiols affect neuronal nitric oxide synthase (nNOS) we studied the binding of thiols to tetrahydrobiopterin (BH₄)-free nNOS. Dithiothreitol (DTT), 2-mercaptoethanol, and l- and d-cysteine all bound to the heme with K_d values varying from 0.16 mM for DTT to 41 mM for l-cysteine. DTT, 2-mercaptoethanol, and l-cysteine yielded absorbance spectra with maxima at about 378 and 456 nm, indicative of bisthiolate complexes; the maximum at 426 nm with d-cysteine suggests binding of the neutral thiol. From the results with 2-mercaptoethanol we deduced that in 2-mercaptoethanol-free, BH₄-free nNOS the sixth heme ligand is not a thiolate. DTT binding to nNOS containing one BH₄ per dimer was biphasic. Apparently, the BH₄-free subunit bound DTT with the same affinity as the BH₄-free enzyme, whereas the BH₄-containing subunit exhibited a >100-fold lower affinity, indicative of competition between DTT and BH₄ binding. Binding of DTT to the BH₄-containing subunit was suppressed by l-arginine, whereas high-affinity binding was not affected, suggesting that l-arginine binds only to the BH₄-containing subunit. DTT competitively inhibited l-citrulline production by nNOS containing one BH₄ per dimer (K_i ≈ 11 mM). Comparison of DTT binding and inhibition suggests that the heme of the BH₄-free subunit is not involved in catalysis. Thermostability of nNOS was studied by preincubating the enzyme at various temperatures prior to activity determination. At nanomolar concentrations, nNOS was stable at 20 °C but rapidly deactivated at higher temperatures (t_1/2 ≈ 6 min at 37 °C). At micromolar concentrations, inactivation was 10 times slower. Absorbance and fluorescence measurements demonstrate that inactivation was not accompanied by major structural changes. The stabilization of nNOS by thiols was illustrated by the fact that omission of 2-mercaptoethanol during preincubation for 10 min at 30 °C led to an activity decrease of up to 90%.