Electron Transfer and Catalytic Activity of Nitric Oxide Synthases

Nishida, Clinton R.; Montellano, Paul R. Ortiz de

doi:10.1074/jbc.273.10.5566

Cited by 94 publications

(66 citation statements)

References 47 publications

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“…These differences in electron transfer activity with and without CaM can be observed when the nNOS heme and reductase domains are independently expressed (16,17). Furthermore, the elements that control the CaM dependence and relatively low rate of electron transfer to the heme domain in eNOS appear to be localized entirely within the reductase domain because NOS chimeras with the eNOS oxygenase domain fused to the iNOS or nNOS reductase domain exhibit high activities (18). Conversely, chimeras in which the eNOS reductase domain is fused to the iNOS or nNOS oxygenase domain have low, eNOS-like activities (18).…”

Section: And References Therein)mentioning

confidence: 99%

Nitric-oxide Synthase (NOS) Reductase Domain Models Suggest a New Control Element in Endothelial NOS That Attenuates Calmodulin-dependent Activity

Knudsen

Nishida

Mooney

et al. 2003

Journal of Biological Chemistry

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Inducible (iNOS) and constitutive (eNOS, nNOS) nitric-oxide synthases differ in their Ca2؉ -calmodulin (CaM) dependence. iNOS binds CaM irreversibly but eNOS and nNOS, which bind CaM reversibly, have inserts in their reductase domains that regulate electron transfer. These include the 43-45-amino acid autoinhibitory element (AI) that attenuates electron transfer in the absence of CaM, and the C-terminal 20 -40-amino acid tail that attenuates electron transfer in a CaMindependent manner. We constructed models of the reductase domains of the three NOS isoforms to predict the structural basis for CaM-dependent regulation. We have identified and characterized a loop (CD2A) within the NOS connecting domain that is highly conserved by isoform and that, like the AI element, is within direct interaction distance of the CaM binding region. The eNOS CD2A loop (eCD2A) has the sequence 834 KGSPG-GPPPG 843 , and is truncated to 809 ESGSY 813 (iCD2A) in iNOS. The eCD2A contributes to the Ca 2؉ dependence of CaM-bound activity to a level similar to that of the AI element. The eCD2A plays an autoinhibitory role in the control of NO, and CaM-dependent and -independent reductase activity, but this autoinhibitory function is masked by the dominant AI element. Finally, the iCD2A is involved in determining the salt dependence of NO activity at a post-flavin reduction level. Electrostatic interactions between the CD2A loop and the CaM-binding region, and CaM itself, provide a structural means for the CD2A to mediate CaM regulation of intra-subunit electron transfer within the active NOS complex.Nitric-oxide synthase (NOS), 1 a modular protein, consists of an N-terminal heme domain that catalyzes P450-like oxidations and a C-terminal two-flavin domain homologous to that of cytochrome P450 reductase (CPR) (1, 2). The NOS oxygenase and reductase domains are linked by a calmodulin (CaM) binding helix. The NOS oxygenase domain is completely different from a P450, however, in that it has no sequence identity with that family of enzymes and has an ␣,␤-fold structure distinct from the highly ␣-helical structure of the P450 enzymes (3-6). Furthermore, the two-stage mechanism for the oxidation of L-arginine to L-citrulline and nitric oxide (NO) by NOS is more complex than that of a P450 enzyme, as it requires tetrahydrobiopterin (H 4 B) as a transient electron donor (7). In contrast, the NOS reductase domain exhibits considerable sequence identity with CPR, and the electrons, as in P450/CPR, flow from NADPH to the FAD, then to the FMN, and finally, upon substrate binding, to the heme (2, 8).In the cytochrome P450 system, the principal control on inter-protein electron transfer is the requirement for association of the P450 with CPR. The NOS complex also requires interactions between independently transcribed proteins because it is a homodimer in which the reductase domain of one subunit provides electrons to the oxygenase domain of the other (9, 10). However, inter-domain electron transfer in NOS also requires the binding of CaM, and the Ca 2ϩ...

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Section: And References Therein)mentioning

confidence: 99%

Nitric-oxide Synthase (NOS) Reductase Domain Models Suggest a New Control Element in Endothelial NOS That Attenuates Calmodulin-dependent Activity

Knudsen

Nishida

Mooney

et al. 2003

Journal of Biological Chemistry

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“…Conceivably, slow heme reduction in eNOS could involve structural elements in both its reductase and oxygenase domains. However, poor Fe(CN) 6 and cytochrome c reduction by the CaM-bound reductase domain (11), along with the fact that a NOS chimera comprised of an nNOS reductase and eNOS oxygenase domain had faster NO synthesis than native eNOS (30), suggest that structural elements responsible for slow heme reduction reside in the reductase domain. From our present work we conclude that slow heme reduction is not because of slow flavin reduction in eNOS, which is actually quite fast in the presence of CaM.…”

Section: Fig 8 Spectra Of Enos During Steady-state Catalysis the Smentioning

confidence: 99%

“…Because NO synthesis is actually the result of many steps, it is imperative to identify which steps limit the activity of a particular NOS isoform. Work with NOS chimeras containing swapped reductase domains has suggested heme reduction could be responsible for the low activity of eNOS (30). However, it seems that NOS catalysis is comprised of two parts (15,16): an active component that includes all steps involved in NO generation and an inactive component that includes NO binding to the NOS heme and subsequent dissociation or oxidation of the heme-NO complex to regenerate active enzyme.…”

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confidence: 99%

Electron Transfer, Oxygen Binding, and Nitric Oxide Feedback Inhibition in Endothelial Nitric-oxide Synthase

Abu-Soûd

Ichimori

Presta

et al. 2000

Journal of Biological Chemistry

115

118

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We studied steps that make up the initial and steadystate phases of nitric oxide (NO) synthesis to understand how activity of bovine endothelial NO synthase (eNOS) is regulated. Stopped-flow analysis of NADPH-dependent flavin reduction showed the rate increased from 0.13 to 86 s ؊1 upon calmodulin binding, but this supported slow heme reduction in the presence of either Arg or N -hydroxy-L-arginine (0.005 and 0.014 s ؊1 , respectively, at 10°C). O 2 binding to ferrous eNOS generated a transient ferrous dioxy species (Soret peak at 427 nm) whose formation and decay kinetics indicate it can participate in NO synthesis. The kinetics of heme-NO complex formation were characterized under anaerobic conditions and during the initial phase of NO synthesis. During catalysis heme-NO complex formation required buildup of relatively high solution NO concentrations (>50 nM), which were easily achieved with N -hydroxy-L-arginine but not with Arg as substrate. Heme-NO complex formation caused eNOS NADPH oxidation and citrulline synthesis to decrease 3-fold and the apparent K m for O 2 to increase 6-fold. Our main conclusions are: 1) The slow steady-state rate of NO synthesis by eNOS is primarily because of slow electron transfer from its reductase domain to the heme, rather than heme-NO complex formation or other aspects of catalysis. 2) eNOS forms relatively little heme-NO complex during NO synthesis from Arg, implying NO feedback inhibition has a minimal role. These properties distinguish eNOS from the other NOS isoforms and provide a foundation to better understand its role in physiology and pathology. Nitric-oxide synthases (NOSs)1 catalyze a stepwise oxidation of L-arginine (Arg) to citrulline and nitric oxide (NO) (1-3). In mammals, three NOSs are expressed that differ in their primary sequence, post-translational modifications, cellular location, and tissue expression (4 -6), consistent with their participating in a range of physiologic and pathologic systems. Two NOSs (neuronal, nNOS or NOS-I; and endothelial, eNOS or NOS-III) are constitutively expressed and participate in signal cascades by synthesizing NO in response to Ca 2ϩ -dependent CaM binding. A third NOS (cytokine-inducible, iNOS or NOS-II) is primarily regulated by transcriptional mechanisms, binds CaM irrespective of the Ca 2ϩ concentration to be always active, and functions as both a regulator and effector of the immune response.Although NO synthesis activities of the NOS isoforms differ considerably, how and why this occurs is unclear. A comparison of published steady-state rates shows that eNOS is about four to eight times slower than either nNOS or iNOS (7-14). Because NO synthesis is actually the result of many steps, it is imperative to identify which steps limit the activity of a particular NOS isoform. Work with NOS chimeras containing swapped reductase domains has suggested heme reduction could be responsible for the low activity of eNOS (30). However, it seems that NOS catalysis is comprised of two parts (15, 16): an active component that includes...

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“…Because the proximal electron donor and acceptor are on the same polypeptide chain in the NOSs, and thus each potential acceptor is linked to its donor, unlike CYPOR and the cytochromes P450, regulation of electron transfer by the reductase domain is reasonable. In fact, the rate of electron transfer from the reductase to the heme domain determines the turnover rates of NO production in the various NOSs (30), and thus alterations, such as truncations or insertions in the reductase domain, might confer the ability to regulate electron transfer through this domain. The remarkable sequence identity (58%) between the C-terminal 641 amino acids of neuronal NOS and the entire sequence of CYPOR was reported by Bredt et al (31).…”

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confidence: 99%

Recruitment of governing elements for electron transfer in the nitric oxide synthase family

Jáchymová

Martásek

Panda

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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At least three building blocks are responsible for the molecular basis of the modulation of electron transfer in nitric oxide synthase (NOS) isoforms: the calmodulin-binding sequence, the C-terminal extension, and the autoregulatory loop in the reductase domain. We have attempted to impart the control conferred by the C termini of NOS to cytochrome P450 oxidoreductase (CYPOR), which contains none of these regulatory elements. The effect of these C termini on the properties of CYPOR sheds light on the possible evolutionary origin of NOS and addresses the recruitment of new peptides on the development of new functions for CYPOR. The C termini of NOSs modulate flavoprotein-mediated electron transfer to various electron acceptors. The reduction of the artificial electron acceptors cytochrome c, 2,6-dichlorophenolindophenol, and ferricyanide was inhibited by the addition of any of these C termini to CYPOR, whereas the reduction of molecular O 2 was increased. This suggests a shift in the rate-limiting step, indicating that the NOS C termini interrupt electron flux between flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) and͞or the electron acceptors. The modulation of CYPOR by the addition of the NOS C termini is also supported by flavin reoxidation and fluorescence-quenching studies and antibody recognition of the C-terminal extension. These experiments support the origin of the NOS enzymes from modules consisting of a heme domain and CYPOR or ferredoxin-NADP ؉ reductase-and flavodoxin-like subdomains that constitute CYPOR, followed by further recruitment of smaller modulating elements into the flavin-binding domains.flavoprotein ͉ NADPH-cytochrome P450 reductase ͉ protein evolution

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Electron Transfer and Catalytic Activity of Nitric Oxide Synthases

Cited by 94 publications

References 47 publications

Nitric-oxide Synthase (NOS) Reductase Domain Models Suggest a New Control Element in Endothelial NOS That Attenuates Calmodulin-dependent Activity

Nitric-oxide Synthase (NOS) Reductase Domain Models Suggest a New Control Element in Endothelial NOS That Attenuates Calmodulin-dependent Activity

Electron Transfer, Oxygen Binding, and Nitric Oxide Feedback Inhibition in Endothelial Nitric-oxide Synthase

Recruitment of governing elements for electron transfer in the nitric oxide synthase family

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