Electron Transfer by Neuronal Nitric-oxide Synthase Is Regulated by Concerted Interaction of Calmodulin and Two Intrinsic Regulatory Elements

Background: NOS enzymes are large, dimeric complexes essential in mammalian physiology. Results: EM structural analysis and three-dimensional models reveal nNOS reductase-oxygenase arrangements and a CaMdependent rotation of the FMN domain. Conclusion: Coordinated conformational changes act to reposition the FMN domain for electron transfer. Significance: This work captures structural states of the NOS holoenzyme that drive the NO synthesis cycle.

Section: Discussionmentioning

confidence: 99%

Architecture of the Nitric-oxide Synthase Holoenzyme Reveals Large Conformational Changes and a Calmodulin-driven Release of the FMN Domain

Yokom¹,

Morishima²,

Lau³

et al. 2014

“…Regarding NOS flavin-to-heme electron transfer, a variety of data (35)(36)(37)(38)(39)(40) suggest the FMN module undergoes a relatively large-scale movement to contact-shuttle between the NADPH-FAD module (to receive electrons) and the oxygenase domain (to donate electrons) during catalysis (Fig. 7).…”

Section: Discussionmentioning

confidence: 99%

Catalytic Reduction of a Tetrahydrobiopterin Radical within Nitric-oxide Synthase

Wei

Wang

Tejero

et al. 2008

Nitric-oxide synthases (NOS) are catalytically self-sufficient flavo-heme enzymes that generate NO from arginine (Arg) and display a novel utilization of their tetrahydrobiopterin (H 4 B) cofactor. During Arg hydroxylation, H 4 B acts as a one-electron donor and is then presumed to redox cycle (i.e. be reduced back to H 4 B) within NOS before further catalysis can proceed. Whereas H 4 B radical formation is well characterized, the subsequent presumed radical reduction has not been demonstrated, and its potential mechanisms are unknown. We investigated radical reduction during a single turnover Arg hydroxylation reaction catalyzed by neuronal NOS to document the process, determine its kinetics, and test for involvement of the NOS flavoprotein domain. We utilized a freeze-quench instrument, the biopterin analog 5-methyl-H 4 B, and a method that could separately quantify the flavin and pterin radicals that formed in NOS during the reaction. Our results establish that the NOS flavoprotein domain catalyzes reduction of the biopterin radical following Arg hydroxylation. The reduction is calmodulin-dependent and occurs at a rate that is similar to heme reduction and fast enough to explain H 4 B redox cycling in NOS. These results, in light of existing NOS crystal structures, suggest a "throughheme" mechanism may operate for H 4 B radical reduction in NOS.

“…The CT, AI, and charge pairing interactions all stabilize the FMN-shielded state of equilibrium A in the CaM-free NOS. CaM binding changes equilibrium A by disabling the influence of the CT and perhaps also the AI control element (27), but the molecular details of the various actions of CaM remain a matter of conjecture (10,25).…”

mentioning

confidence: 99%

A Bridging Interaction Allows Calmodulin to Activate NO Synthase through a Bi-modal Mechanism

Tejero¹,

Haque²,

Durra

et al. 2010

Calmodulin (CaM) activates the nitric-oxide synthases (NOS) by a mechanism that is not completely understood. A recent crystal structure showed that bound CaM engages in a bridging interaction with the NOS FMN subdomain. We investigated its importance in neuronal NOS (nNOS) by mutating the two residues that primarily create the bridging interaction (Arg 752 in the FMN subdomain and Glu 47 in CaM). Mutations designed to completely destroy the bridging interaction prevented bound CaM from increasing electron flux through the FMN subdomain and diminished the FMN-to-heme electron transfer by 90%, whereas mutations that partly preserve the interaction had intermediate effects. The bridging interaction appeared to control FMN subdomain interactions with both its electron donor (NADPH-FAD subdomain) and electron acceptor (heme domain) partner subdomains in nNOS. We conclude that the Arg 752 -Glu 47 bridging interaction is the main feature that enables CaM to activate nNOS. The mechanism is bi-modal and links a single structural aspect of CaM binding to specific changes in nNOS protein conformational and electron transfer properties that are essential for catalysis. Nitric oxide (NO)4 is an essential signal and effector molecule in biology (1). NO is produced in animals from L-Arg by the NO synthases (NOS, EC 1.14.13.39) (2). Three types of NOS are expressed in mammals: inducible NOS (iNOS), endothelial NOS (eNOS), and neuronal NOS (nNOS) (3-5). The three NOS are structurally homologous and are active as homodimers (6, 7). Each NOS monomer is comprised of two domains: an N-terminal oxygenase domain (NOSoxy) that contains cofactors protoporphyrin IX (heme) and (6R)-5,6,7,8-tetrahydro-L-biopterin (H 4 B) and binds the substrate L-Arg, and a C-terminal reductase domain that contains FAD, FMN, and binds NADPH. The NOS reductase domain is homologous to cytochrome P-450 reductase and related dual-flavin enzymes (5, 8), but also contains up to three regulatory inserts that are unique to the NOS enzymes (3, 5). Significantly, a calmodulin (CaM) binding site is located in the connecting sequence between the NOSoxy and reductase domains (3-5). CaM binding to this site activates NO synthesis by triggering electron transfer to the heme in NOS enzymes (9). The ability of CaM to activate a redox enzyme like NOS is novel and the mechanism is a topic of current interest.Much of the actions of CaM impinge on the NOS FMN subdomain, which is thought to undergo large conformational motions to transfer electrons during catalysis (10 -17). This may be a common feature in the dual-flavin reductase enzyme family (18 -20). Fig. 1 illustrates a model for FMN conformational switching during electron transfer between the FMN and heme within a NOS homodimer. The FMN subdomain must first interact with the NADPH-FAD subdomain (FNR) in a "FMN-shielded" conformation to receive electrons, according to equilibrium A. Once the FMN hydroquinone forms (FMNH 2 ), it must swing away to a "FMN-deshielded" conformation, and then must interact with the NOSoxy do...