Differences in Three Kinetic Parameters Underpin the Unique Catalytic Profiles of Nitric-oxide Synthases I, II, and III

Santolini, Jérôme; Meade, Abigail L.; Stuehr, Dennis J.

doi:10.1074/jbc.m108666200

Cited by 115 publications

(175 citation statements)

References 58 publications

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“…6. The slower k off values have typically been derived from equilibrium NO titration experiments (25,26,40), in ligand displacement studies (16,25,26) or in single turnover catalytic studies (13,14,22,25,26) that directly follow NO dissociation from the ferric heme as we have done here in Figs. 3-5.…”

Section: Discussionmentioning

confidence: 99%

“…1). In the three mammalian NOS, the rates of Fe III NO dissociation and reduction are set so that much of the NO can escape from the enzyme before the Fe III NO product complex is reduced to ferrous, which then dooms it to an oxidative reaction that forms a higher oxide of nitrogen in place of NO (15,16). The Fe III NO dissociation rates of mammalian NOS enzymes are within a range that is typical for other ferric heme proteins, whereas in bsNOS this rate is near the lower end of the range (Table V).…”

Section: Discussionmentioning

confidence: 99%

“…1). Interestingly, there is only a modest variation in Fe III NO dissociation rates among the three mammalian NOS isoforms, which range from 2 to 5 s Ϫ1 when measured in NOHA single turnover reactions at 10°C (16).…”

mentioning

confidence: 99%

“…Because dissociation of the Fe III NO product complex is required for NO to escape from the enzyme, it is an essential step for the biologic functions of animal NOSs. In fact, this dissociation rate is one of three key kinetic parameters that together determine the overall catalytic behavior of a given NOS (15,16). Slower rates of NO dissociation dispose the Fe III NO product complex toward its reduction during catalysis, which then places the ferrous heme-NO enzyme species into a futile cycle that does not release NO (Fig.…”

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A Conserved Val to Ile Switch near the Heme Pocket of Animal and Bacterial Nitric-oxide Synthases Helps Determine Their Distinct Catalytic Profiles

Wang

Wei

Sharma

et al. 2004

Journal of Biological Chemistry

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The rate of each transition was increased relative to wild-type bsNOS, with Fe III NO dissociation being 3.6 times faster. In V346I iNOSoxy we consecutively observed the beginning ferrous, Fe II O 2 , a mixture of Fe III NO and ferric heme species, and ending ferric enzyme. The rate of each transition was decreased relative to wild-type iNOSoxy, with the Fe III NO dissociation being 3 times slower. An independent measure of NO binding kinetics confirmed that V346I iNOSoxy has slower NO binding and dissociation than wild-type. Citrulline production by both mutants was only slightly lower than wild-type enzymes, indicating good coupling. Our data suggest that a greater shielding of the heme pocket caused by the Val/Ile switch slows down NO synthesis and NO release in NOS, and thus identifies a structural basis for regulating these kinetic variables.Nitric oxide synthases (NOSs) 1 are flavoheme enzymes that generate nitric oxide (NO) from L-arginine (Arg) (1, 2). The overall reaction consumes 1.5 NADPH and 2 O 2 and involves two steps, the first being Arg hydroxylation to form N-hydroxy-L-Arg (NOHA), and the second being NOHA oxidation to form citrulline and NO (see Scheme 1).The NOS heme is located in a catalytic "oxygenase" domain that also contains the binding sites for Arg and the essential redox cofactor (6R)-tetrahydrobiopterin (H 4 B) (3, 4). The heme is ligated to a cysteine thiolate (5-7) and catalyzes a reductive activation of molecular oxygen in conjunction with H 4 B in each of the two steps of NO synthesis (8 -11). The NOS heme also binds self-generated NO as an intrinsic feature of catalysis (12)(13)(14). Each molecule of NO generated by NOS has a high probability of binding to the heme before it is released from the enzyme. The resulting ferric heme-NO product complex (Fe III NO) has been observed to build up as a transient species during NOHA oxidation reactions catalyzed by NOS oxygenase domains (NOSoxy) when run in a stopped-flow spectrophotometer under single turnover conditions (9,13,14). These experiments also provided spectral and kinetic information regarding the formation of an initial ferrous heme-dioxy species (Fe II O 2 ), whose disappearance then coincides with k cat and formation of the transient Fe III NO product complex (see Scheme 2). Because dissociation of the Fe III NO product complex is required for NO to escape from the enzyme, it is an essential step for the biologic functions of animal NOSs. In fact, this dissociation rate is one of three key kinetic parameters that together determine the overall catalytic behavior of a given NOS (15,16). Slower rates of NO dissociation dispose the Fe III NO product complex toward its reduction during catalysis, which then places the ferrous heme-NO enzyme species into a futile cycle that does not release NO (Fig. 1). Interestingly, there is only a modest variation in Fe III NO dissociation rates among the three mammalian NOS isoforms, which range from 2 to 5 s Ϫ1 when measured in NOHA single turnover reactions at 10°C (16).Given the above, we...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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A Conserved Val to Ile Switch near the Heme Pocket of Animal and Bacterial Nitric-oxide Synthases Helps Determine Their Distinct Catalytic Profiles

Wang

Wei

Sharma

et al. 2004

Journal of Biological Chemistry

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“…[31]). It includes transcriptional [32], translational and posttranslational [33][34][35] regulations of NO-synthesis mechanisms, negative feedback regulation of NOS by NO [36][37][38][39], membrane transport of substrates [40][41][42][43], intracellular metabolic recycling of substrates [43][44][45][46][47][48][49][50][51], availability of molecular oxygen and cell respiration [52][53][54][55][56][57], and intracellular redox state [58][59][60].…”

Section: No Productionmentioning

confidence: 99%

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

Boudko

2007

Journal of Chromatography B

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This review briefly summarizes recent progress in fundamental understanding and analytical profiling of the L-arginine/nitric oxide (NO) pathway. It focuses on key analytical references of NO actions and on the experimental acquisition of these references in vivo, with capillary electrophoresis (CE) and high-performance capillary electrophoresis (HPCE) comprising one of the most flexible and technologically promising analytical platform for comprehensive high-resolution profiling of NO-related metabolites. Second aim of this review is to express demands and bridge efforts of experimental biologists, medical professionals and chemical analysis-oriented scientists who strive to understand evolution and physiological roles of NO and to develop analytical methods for use in biology and medicine.

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NO and NO Donors

Cai

Wang

Holder

2005

Nitric Oxide Donors

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Nitric oxide (NO), a magic free radical gas molecule, has been shown to be involved in numerous physiological and pathophysiological processes. Among its diverse functions, NO has been implicated in the relaxation of vascular smooth muscle, the inhibition of platelet aggregation, neurotransmission (Viagra reverses impotence by enhancing an NO-stimulated pathway), and immune regulation [1]. It was named the molecule of the year in 1992 by Science and was the subject of the Nobel Prize in 1998. NO has limited solubility in water (2-3 mM), and it is unstable in the presence of various oxidants. This makes it difficult to introduce as such into biological systems in a controlled or specific fashion. Consequently, the development of chemical agents that release NO is important if we are to target its bioeffector roles to specific cell types for biological and pharmacological applications. Based on our comprehensive review of NO donors [2], this chapter focuses on recent progress and current trends in NO donor development and novel applications which are not covered by the following chapters.

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Differences in Three Kinetic Parameters Underpin the Unique Catalytic Profiles of Nitric-oxide Synthases I, II, and III

Cited by 115 publications

References 58 publications

A Conserved Val to Ile Switch near the Heme Pocket of Animal and Bacterial Nitric-oxide Synthases Helps Determine Their Distinct Catalytic Profiles

A Conserved Val to Ile Switch near the Heme Pocket of Animal and Bacterial Nitric-oxide Synthases Helps Determine Their Distinct Catalytic Profiles

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

NO and NO Donors

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