A connecting hinge represses the activity of endothelial nitric oxide synthase

149

150

In the vasculature, nitric oxide (NO) is generated by endothelial NO synthase (eNOS) in a calcium/calmodulin-dependent reaction. With oxidative stress, the critical cofactor BH 4 is depleted, and NADPH oxidation is uncoupled from NO generation, leading to production of (O 2 . . generation from the enzyme at low Ca 2؉ concentrations, and PKC␣-mediated phosphorylation alters the sensitivity of the enzyme to other negative regulatory signals. Nitric-oxide synthase (NOS)2 is a critical enzyme that converts L-arginine (L-Arg) to L-citrulline and nitric oxide (NO) with the consumption of NADPH. NO is a signaling molecule that promotes vascular smooth muscle relaxation and functions as an endogenous mediator of a wide range of effects in different tissues (1, 2). After oxidant stress, as occurs in postischemic tissues, production of O 2. and its derived oxidants, including peroxynitrite (ONOO Ϫ ), hydrogen peroxide (H 2 O 2 ), and hydroxyl radical (⅐OH), induce NOS dysfunction with uncoupling of the enzyme leading to the production of NOSderived O 2. instead of NO (3, 4). It has been reported that an imbalance between NO and O 2 . can contribute to the onset of a variety of cardiovascular diseases, including hypertension, atherosclerosis, and heart failure (5). Therefore, tight coupling of the enzyme is important for normal cardiovascular function and prevention of disease. The catalytic domains of NOS include a flavin-containing NADPH binding reductase and a heme-binding oxygenase that also contains the binding sites for the redox labile cofactor tetrahydrobiopterin (BH 4 ) and the substrate L-Arg. In the presence of Ca 2ϩ and calmodulin (CaM), electrons flow from NADPH through the reductase domain to the oxygenase domain resulting in the activation of oxygen at the heme center followed by substrate monooxygenation. This process requires the presence of the fully reduced BH 4 . Our laboratory and several others have demonstrated that besides synthesizing NO, all three isoforms of NOS can also generate O 2 . , depending on substrate and cofactor availability (3, 6 -9). One of the primary mechanisms implicated in the oxidant-induced switch of NOS from the production of NO to the generation of O 2 . is the oxidation of the enzyme bound BH 4 (10, 11). Various extracellular signals, including shear stress and additional stimuli such as vascular endothelial growth factor (VEGF), estrogen, sphingosine 1-phosphate, bradykinin, and aldosterone, modulate eNOS NO generation through several signal transduction pathways (12)(13)(14)(15)(16). Cellular studies have demonstrated that phosphorylation of eNOS at specific amino acids regulates enzyme-mediated NO production (17). The majority of previous work has focused on two residues, serine 1177 and threonine 495. It has been shown that Akt specifically induces phosphorylation of Ser-1177 (18, 19) and that PKC specifically phosphorylates . Although phosphorylation of Ser-1177 has been shown to increase NO production * This work was supported, in whole or in part, by National Institu...

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Phosphorylation of Endothelial Nitric-oxide Synthase Regulates Superoxide Generation from the Enzyme

Chen

Druhan

Varadharaj

et al. 2008

149

150

“…In fact, the 42 residue-long eNOS C-terminal tail most likely contributes to eNOS having the weakest activity among three NOSs. One other factor contributing to the slow activity of eNOS has been shown to be the linker between the two flavin domains (61).…”

Section: The Structure Of the Inos Reductase Domain In The Closed Andmentioning

confidence: 99%

Regulation of Interdomain Interactions by Calmodulin in Inducible Nitric-oxide Synthase

Xia

Misra

Iyanagi

et al. 2009

179

The freely diffusible and moderately reactive free radical, nitric oxide (NO), 2 is a biological signal molecule in numerous physiological and pathophysiological processes (for reviews, see Refs. 1-4). Nitric-oxide synthases (NOSs) catalyze the NADPH-dependent conversion of L-arginine to NO and L-citrulline (for reviews, see Refs. 5-7). In mammals, three different isoforms have been identified. Neuronal NOS (nNOS) and endothelial NOS (eNOS) are constitutively expressed, and their activities are Ca 2ϩ /CaM-dependent, whereas the inducible NOS (iNOS) is independent of intracellular Ca 2ϩ concentration. These isoforms share ϳ55% sequence identity yet differ in their size, tissue distribution, and regulation. The 165-kDa nNOS is located in neurons in the brain and neuromuscular junctions and is involved in neurotransmission. eNOS has a molecular mass of 133 kDa, is located in vascular endothelial cells, and is involved in vascular homeostasis. iNOS can be found in macrophages and many other tissues, has a molecular mass of 130 kDa, and is expressed only in response to endotoxins or inflammatory cytokines.All three isoforms of NOS are modular, homodimeric hemoflavoproteins. The N-terminal half of each NOS isozyme is similar to the cytochrome P450 enzyme family and contains iron protoporphyrin IX (heme). It is referred to as the heme domain or the oxygenase domain. This latter domain also contains tetrahydrobiopterin-and arginine-binding sites. The C-terminal half of each isozyme is the flavin-binding domain (or reductase domain) and contains FAD-, FMN-, and NADPH-binding sites, much the same as in NADPH-cytochrome P450 oxidoreductase (CYPOR). These two domains are linked by a CaM-binding region (8). The constitutive isoforms (nNOS and eNOS) are Ca 2ϩ -dependent due to their reversible binding of CaM, providing a mechanism for rapid response in a signaling cascade. On the other hand, iNOS has tightly bound Ca 2ϩ /CaM and is virtually independent of Ca 2ϩ concentration (9). In contrast to the other NOS isozymes, it is regulated at the transcriptional level. As in the case of the P450 (CYP)-CYPOR system, the FAD in the reductase domain accepts a pair of electrons in the form of a hydride ion from NADPH and transfers them one at a time to FMN. FMN, in turn, transfers the electrons again one by one to the heme of the other monomer in the NOS dimer (10 -12). However, the mechanisms of electron transfer and regulation of the FMN domain interactions with its electron acceptor (the heme domain) in NOS and related enzymes, including CYPOR and methionine synthase reductase, are largely unknown. Only recently, studies on this subject have been emerging (13)(14)(15)(16).CaM regulates a wide range of cellular functions through its reversible Ca 2ϩ -dependent binding to target proteins, including NOS. CaM regulates NOS activity by controlling the rates of electron transfer between the two flavin cofactors and between * This work was supported, in whole or in part, by National Institutes of Health Grant GM52682 (to J. J. K.

“…tase activity than nNOS (15,16). The basis for these differences is unclear, but it appears to involve slower electron transfer by eNOSr.…”

mentioning

confidence: 93%

“…Previous studies have investigated structural elements that appear to regulate NOS activity. These include an autoinhibitory element in the FMN binding subdomain (a 40 -50-amino acid loop) (17)(18)(19), a connecting hinge domain between the FMN and FAD binding subdomains (23-25-amino acid residues) (15,20), and the C-terminal tail (21-42-amino acid extension) (16,21,22). It has also been shown that an FAD stacking residue (Phe-1160 in bovine eNOS and Phe-1395 in rat nNOS) and site-specific phosphorylation (Ser-1179 in bovine eNOS and Ser-1412 in rat nNOS) are involved in the catalytic regulation of NOS enzymes (21,(23)(24)(25).…”

mentioning

confidence: 99%

Differences in a Conformational Equilibrium Distinguish Catalysis by the Endothelial and Neuronal Nitric-oxide Synthase Flavoproteins

Ilagan

Tiso

Konas

et al. 2008

Self Cite

153

Nitric oxide (NO) is a physiological mediator synthesized by NO synthases (NOS).Despite their structural similarity, endothelial NOS (eNOS) has a 6-fold lower NO synthesis activity and 6 -16-fold lower cytochrome c reductase activity than neuronal NOS (nNOS), implying significantly different electron transfer capacities. We utilized purified reductase domain constructs of either enzyme (bovine eNOSr and rat nNOSr) to investigate the following three mechanisms that may control their electron transfer: (i) the set point and control of a two-state conformational equilibrium of their FMN subdomains; (ii) the flavin midpoint reduction potentials; and (iii) the kinetics of NOSr-NADP ؉ interactions. Although eNOSr and nNOSr differed in their NADP(H) interaction and flavin thermodynamics, the differences were minor and unlikely to explain their distinct electron transfer activities. In contrast, calmodulin (CaM)-free eNOSr favored the FMN-shielded (electron-accepting) conformation over the FMN-deshielded (electron-donating) conformation to a much greater extent than did CaM-free nNOSr when the bound FMN cofactor was poised in each of its three possible oxidation states. NADPH binding only stabilized the FMN-shielded conformation of nNOSr, whereas CaM shifted both enzymes toward the FMN-deshielded conformation. Analysis of cytochrome c reduction rates measured within the first catalytic turnover revealed that the rate of conformational change to the FMN-deshielded state differed between eNOSr and nNOSr and was rate-limiting for either CaM-free enzyme. We conclude that the set point and regulation of the FMN conformational equilibrium differ markedly in eNOSr and nNOSr and can explain the lower electron transfer activity of eNOSr.