Uma Siddhanta scite author profile

The nitric oxide synthases (NOS) are the only heme-containing enzymes that require tetrahydrobiopterin (BH4) as a cofactor. Previous studies indicate that only the fully reduced (i.e., tetrahydro) form of BH4 can support NO synthesis. Here, we characterize pterin-free inducible NOS (iNOS) and iNOS reconstituted with eight different tetrahydro- or dihydropterins to elucidate how changes in pterin side-chain structure and ring oxidation state regulate iNOS. Seven different enzyme properties that are important for catalysis and are thought to involve pterin were studied. Only two properties were found to depend on pterin oxidation state (i.e., they required fully reduced tetrahydropterins) and were independent of side chain structure: NO synthesis and the ability to increase heme-dependent NADPH oxidation in response to substrates. In contrast, five properties were exclusively dependent on pterin side-chain structure or stereochemistry and were independent of pterin oxidation state: pterin binding affinity, and its ability to shift the heme iron to its high-spin state, stabilize the ferrous heme iron coordination structure, support heme iron reduction, and promote iNOS subunit assembly into a dimer. These results clarify how structural versus redox properties of the pterin impact on its multifaceted role in iNOS function. In addition, the data reveal that during NO synthesis all pterin-dependent steps up to and including heme iron reduction can take place independent of the pterin ring oxidation state, indicating that the requirement for fully reduced pterin occurs at a point in catalysis beyond heme iron reduction.

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Distinct Roles for the p110α and hVPS34 Phosphatidylinositol 3′-Kinases in Vesicular Trafficking, Regulation of the Actin Cytoskeleton, and Mitogenesis

Siddhanta

et al. 1998

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We have examined the roles of the p85/ p110α and hVPS34 phosphatidylinositol (PI) 3′-kinases in cellular signaling using inhibitory isoform-specific antibodies. We raised anti-hVPS34 and anti-p110α antibodies that specifically inhibit recombinant hVPS34 and p110α, respectively, in vitro. We used the antibodies to study cellular processes that are sensitive to low-dose wortmannin. The antibodies had distinct effects on the actin cytoskeleton; microinjection of anti-p110α antibodies blocked insulin-stimulated ruffling, whereas anti-hVPS34 antibodies had no effect. The antibodies also had different effects on vesicular trafficking. Microinjection of inhibitory anti-hVPS34 antibodies, but not anti-p110α antibodies, blocked the transit of internalized PDGF receptors to a perinuclear compartment, and disrupted the localization of the early endosomal protein EEA1. Microinjection of anti-p110α antibodies, and to a lesser extent anti-hVPS34 antibodies, reduced the rate of transferrin recycling in CHO cells. Surprisingly, both antibodies inhibited insulin-stimulated DNA synthesis by 80%. Injection of cells with antisense oligonucleotides derived from the hVPS34 sequence also blocked insulin-stimulated DNA synthesis, whereas scrambled oligonucleotides had no effect. Interestingly, the requirement for p110α and hVPS34 occurred at different times during the G1–S transition. Our data suggest that different PI 3′-kinases play distinct regulatory roles in the cell, and document an unexpected role for hVPS34 during insulin-stimulated mitogenesis.

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Domain Swapping in Inducible Nitric-oxide Synthase

Siddhanta¹,

Presta²,

Fan³

et al. 1998

Journal of Biological Chemistry

184

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Cytokine-inducible nitric-oxide (NO) synthase (iNOS)contains an oxygenase domain that binds heme, tetrahydrobiopterin, and L-arginine, and a reductase domain that binds FAD, FMN, calmodulin, and NADPH. Dimerization of two oxygenase domains allows electrons to transfer from the flavins to the heme irons, which enables O 2 binding and NO synthesis from L-arginine. In an iNOS heterodimer comprised of one full-length subunit and an oxygenase domain partner, the single reductase domain transfers electrons to only one of two hemes (Siddhanta, U., Wu, C., Abu-Soud, H. M., Zhang, J., Ghosh, D. K., and Stuehr, D. J. (1996) J. Biol. Chem. 271, 7309 -7312). Here, we characterize a pair of heterodimers that contain an L-Arg binding mutation (E371A) in either the full-length or oxygenase domain subunit to identify which heme iron becomes reduced. The E371A mutation prevented L-Arg binding to one oxygenase domain in each heterodimer but did not affect the L-Arg affinity of its oxygenase domain partner and did not prevent heme iron reduction in any case. The mutation prevented NO synthesis when it was located in the oxygenase domain of the adjacent subunit but had no effect when in the oxygenase domain in the same subunit as the reductase domain. Resonance Raman characterization of the heme-L-Arg interaction confirmed that E371A only prevents L-Arg binding in the mutated oxygenase domain. Thus, flavin-to-heme electron transfer proceeds exclusively between adjacent subunits in the heterodimer. This implies that domain swapping occurs in an iNOS dimer to properly align reductase and oxygenase domains for NO synthesis. Nitric oxide (NO)1 acts as a signal and cytotoxic molecule in biology (1-3) and is synthesized from L-arginine (L-Arg) by enzymes termed NO synthases (NOS). The NOS exhibit a bidomain structure in which a N-terminal oxygenase domain that contains binding sites for iron protoporphyrin IX (heme), tetrahydrobiopterin (H 4 B), and L-Arg is fused to a C-terminal reductase domain that contains binding sites for calmodulin (CaM), FMN, FAD, and NADPH (4, 5). To synthesize NO, NADPH-derived electrons must transfer from the reductase domain flavins to the oxygenase domain heme irons, which are bound to the protein via cysteine thiolate axial ligation as in the cytochromes P450 (6 -10). The flavin-to-heme electron transfer is thought to be critical for catalysis because it enables each heme iron to bind and activate oxygen at two steps in the reaction sequence, resulting in oxygen insertion into L-Arg to form N -hydroxy-L-Arg, and subsequent oxygenation to generate NO and citrulline as products (11-13).The NOS are only active as homodimers (4, 14), and understanding how dimerization relates to NOS catalysis is a topic of current interest. Studies with the cytokine-inducible NOS (iNOS) indicate its dimer assembly occurs with stable incorporation of one heme and one H 4 B into each subunit (15, 16). The dimeric interaction only requires the oxygenase domains of each subunit with the reductase domains apparently not interacting ...

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Heme Iron Reduction and Catalysis by a Nitric Oxide Synthase Heterodimer Containing One Reductase and Two Oxygenase Domains

Siddhanta

Abu-Soûd

et al. 1996

Journal of Biological Chemistry

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Inducible nitric oxide (NO) synthase (iNOS) is com-prised of an oxygenase domain containing heme, tetrahydrobiopterin, the substrate binding site, and a reductase domain containing FAD, FMN, calmodulin, and the NADPH binding site. Enzyme activity requires a dimeric interaction between two oxygenase domains with the reductase domains attached as monomeric extensions. To understand how dimerization activates iNOS, we synthesized an iNOS heterodimer comprised of one fulllength subunit and one histidine-tagged subunit that was missing its reductase domain. The heterodimer was purified using nickel-Sepharose and 2,5-ADP affinity chromatography. The heterodimer catalyzed NADPHdependent NO synthesis from L-arginine at a rate of 52 ؎ 6 nmol of NO/min/nmol of heme, which is half the rate of purified iNOS homodimer. Heterodimer NO synthesis was associated with reduction of only half of its heme iron by NADPH, in contrast with near complete heme iron reduction in an iNOS homodimer. Full-length iNOS monomer preparations could not synthesize NO nor catalyze NADPH-dependent heme iron reduction. Thus, dimerization activates NO synthesis by enabling electrons to transfer between the reductase and oxygenase domains. Although a single reductase domain can reduce only one of two hemes in a dimer, this supports NO synthesis from L-arginine.

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Identification of a biochemical link between energy intake and energy expenditure

Obici¹,

Wang²,

Chowdury³

et al. 2002

J. Clin. Invest.

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Uma Siddhanta

Comparative Functioning of Dihydro- and Tetrahydropterins in Supporting Electron Transfer, Catalysis, and Subunit Dimerization in Inducible Nitric Oxide Synthase

Distinct Roles for the p110α and hVPS34 Phosphatidylinositol 3′-Kinases in Vesicular Trafficking, Regulation of the Actin Cytoskeleton, and Mitogenesis

Domain Swapping in Inducible Nitric-oxide Synthase

Heme Iron Reduction and Catalysis by a Nitric Oxide Synthase Heterodimer Containing One Reductase and Two Oxygenase Domains

Identification of a biochemical link between energy intake and energy expenditure

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