Eva Pitters scite author profile

The oxygenase domain of inducible NO synthase (residues 1-498, iNOSox) is the enzyme's catalytic center. Its active form is a homodimer that contains heme and tetrahydrobiopterin (H4biopterin) and binds l-arginine [Ghosh, D. K., & Stuehr, D. J. (1995) Biochemistry 34, 801]. To help identify protein residues involved in prosthetic group and dimeric interaction, we expressed H4biopterin-free iNOSox in Escherichia coli. The iNOSox was 80% dimeric but contained a low-spin heme iron that bound DTT as a sixth ligand. The iNOSox bound H4biopterin or L-arginine with high affinity, which displaced DTT from the heme and caused spectral changes consistent with a closing up of the heme pocket. The H4biopterin-replete iNOSox could catalyze conversion of Nomega-hydroxyarginine to citrulline and NO in a H2O2-supported reaction. Limited trypsinolysis of the H4biopterin-free iNOSox dimer cut the protein at a single site in its N-terminal region (K117). H4biopterin protected against the cleavage whereas l-arginine did not. The resulting 40 kDa protein contained thiol-ligated low-spin heme, was monomeric, catalytically inactive, showed no capacity to bind H4biopterin or l-arginine, and did not dimerize when provided with these molecules, indicating that residues 1-117 were important for iNOSox dimerization and H4biopterin/l-arginine interaction. A deletion mutant missing residues 1-114 was partially dimeric but otherwise identical to the 40 kDa protein regarding its spectral and catalytic properties and inability to respond to l-arginine and H4biopterin, whereas a deletion mutant missing residues 1-65 was equivalent to wild-type iNOSox, narrowing the region of importance to amino acids 66-114. Mutation of a conserved cysteine in this region (C109A) decreased H4biopterin affinity without compromising iNOSox dimeric structure, L-arginine binding, or catalytic function. These results suggest that residues 66-114 of iNOSox are involved in productive H4biopterin interaction and subunit dimerization. H4biopterin binding appears to stabilize the protein structure in this region, and through doing so activates iNOS for NO synthesis.

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Tetrahydrobiopterin-Free Neuronal Nitric Oxide Synthase: Evidence for Two Identical Highly Anticooperative Pteridine Binding Sites

Gorren

et al. 1996

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The properties of neuronal nitric oxide synthase containing one tetrahydrobiopterin (BH4) per dimer [nNOS(BH4+)] were compared to those of the BH4-free enzyme [nNOS(BH4-)]. The stimulation by BH4 of the formation of L-citrulline at the expense of H2O2 production unambiguously demonstrated that BH4 is essential in coupling reductive oxygen activation to Arg oxidation. The clear difference between the Stokes radii of nNOS(BH4-) and nNOS(BH4+) indicates that the introduction of one BH4 per dimer significantly changes the enzyme structure. Whereas the heme in nNOS(BH4+) was primarily high-spin, nNOS(BH4-) contained mainly low-spin heme. This was slowly converted into the high-spin form with Arg and/or BH4, with a rate that was independent of the concentration of either compound. Dithiothreitol inhibited the Arg/BH4-induced spin conversion by stabilizing low-spin heme. Formation of high-spin heme, with rates varying from 0.04 to 0.4 min-1, always correlated to an equally fast increase in activity. Radioligand binding studies showed the rapid association (within 20 s) of BH4 to nNOS(BH4-), but not to nNOS(BH4+), after preincubation with Arg. Complete and monophasic dissociation of radioligand occurred in the presence of excess unlabeled BH4, demonstrating the exchangeability of high-affinity bound BH4. Studies of the association of NG-nitro-L-arginine (L-NNA) to nNOS(BH4+) revealed that excess BH4 increased the amount of bound L-NNA 2-fold. Most of the binding data are explained by a model in which nNOS dimers accommodate two identical BH4- and Arg/L-NNA-binding sites, with cooperativity between Arg- and BH4-binding and anticooperativity between the BH4-binding sites.

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Eva Pitters

Characterization of the Inducible Nitric Oxide Synthase Oxygenase Domain Identifies a 49 Amino Acid Segment Required for Subunit Dimerization and Tetrahydrobiopterin Interaction

Tetrahydrobiopterin-Free Neuronal Nitric Oxide Synthase: Evidence for Two Identical Highly Anticooperative Pteridine Binding Sites

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