Neutralizing a Surface Charge on the FMN Subdomain Increases the Activity of Neuronal Nitric-oxide Synthase by Enhancing the Oxygen Reactivity of the Enzyme Heme-Nitric Oxide Complex

Nitric-oxide synthases (NOSs) are calmodulin-dependent flavoheme enzymes that oxidize l-Arg to nitric oxide (NO) and l-citrulline. Their catalytic behaviors are complex and are determined by their rates of heme reduction (k_r), ferric heme-NO dissociation (k_d), and ferrous heme-NO oxidation (k_ox). We found that point mutation (E762N) of a conserved residue on the enzyme''s FMN subdomain caused the NO synthesis activity to double compared with wild type nNOS. However, in the absence of l-Arg, NADPH oxidation rates suggested that electron flux through the heme was slower in E762N nNOS, and this correlated with the mutant having a 60% slower k_r. During NO synthesis, little heme-NO complex accumulated in the mutant, compared with ∼50–70% of the wild-type nNOS accumulating as this complex. This suggested that the E762N nNOS is hyperactive because it minimizes buildup of an inactive ferrous heme-NO complex during NO synthesis. Indeed, we found that k_ox was 2 times faster in the E762N mutant than in wild-type nNOS. The mutational effect on k_ox was independent of calmodulin. Computer simulation and experimental measures both indicated that the slower k_r and faster k_ox of E762N nNOS combine to lower its apparent K_m,O2 for NO synthesis by at least 5-fold, which in turn increases its V/K_m value and enables it to be hyperactive in steady-state NO synthesis. Our work underscores how sensitive nNOS activity is to changes in the k_ox and reveals a novel means for the FMN module or protein-protein interactions to alter nNOS activity.Nitric oxide (NO)² is a biological mediator that is produced in animals by three NO synthase isozymes (NOS, EC 1.14.13.39): inducible NOS (iNOS), neuronal NOS (nNOS), and endothelial NOS (eNOS) (1, 2). The NOS are modular enzymes composed of an N-terminal oxygenase domain and a C-terminal flavoprotein domain, with a calmodulin (CaM)-binding site connecting the two domains (3). During NO synthesis, the flavoprotein domain transfers NADPH-derived electrons through its FAD and FMN cofactors to a heme located in the oxygenase domain. The FMN-to-heme electron transfer enables heme-dependent oxygen activation and a stepwise conversion of l-Arg to NO and citrulline (4, 5). Heme reduction also requires that CaM be bound to NOS and is rate-limiting for NO biosynthesis (6–9).NOS enzymes operate under the constraint of having their newly made NO bind to the ferric heme before it can exit the enzyme (10). How this intrinsic heme-NO binding event impacts NOS catalytic cycling is shown in Fig. 1 and has previously been discussed in detail (10–13). The l-Arg to NO biosynthetic reaction (Fe^III to Fe^IIINO in Fig. 1) is limited by the rate of ferric heme reduction (k_r), because all biosynthetic steps downstream are faster than k_r. However, once the ferric heme-NO complex forms at the end of each catalytic cycle, it can either dissociate to release NO into the medium (at a rate k_d as shown in Fig. 1) or become reduced by the flavoprotein domain (at a rate k′_r in Fig. 1; equal to k_r) to form the enzyme ferrous heme-NO species (Fe^IINO), which releases NO very slowly (11, 12). Consequently, two cycles compete during steady-state NO synthesis (Fig. 1); NO dissociation from the ferric heme (k_d) is part of a “productive cycle” that releases NO and is essential for NOS bioactivity, whereas reduction of the ferric heme-NO complex (k_r′) channels the enzyme into a “futile cycle” that actually represents a NO dioxygenase activity. The rate of futile cycling is also determined by the rate of O₂ reaction with the ferrous heme-NO complex (at a rate k_ox in Fig. 1), which regenerates the ferric enzyme. Surprisingly, NOS enzymes have evolved to have a broad range of k_r (varies 40×), k_ox (varies 15×), and k_d (varies 30×) values (Table S1) (12). This causes each NOS to distribute quite differently during steady-state NO synthesis and gives each NOS a unique catalytic profile (12).Open in a separate windowFIGURE 1.Global kinetic model for NOS catalysis. Ferric enzyme reduction (k_r) is rate-limiting for the biosynthetic reactions (central linear portion). k_cat1 and k_cat2 are the conversion rates of the enzyme Fe^IIO₂ species to products in the l-Arg and N^ω-hydroxy-l-arginine (NOHA) reactions, respectively. The ferric heme-NO product complex (Fe^IIINO) can either release NO (k_d) or become reduced (k′_r) to a ferrous heme-NO complex (Fe^IINO), which reacts with O₂ (k_ox) to regenerate ferric enzyme. Enzyme partitioning and NO release are determined by the relative rates of k_r, k_ox, and k_d. This figure is adapted from Ref. 12.The enzyme physical and electronic factors that may set and regulate each of the three kinetic parameters (k_r, k_ox, and k_d) in NOS enzymes remain to be fully described. At present, the composition of the NOS flavoprotein domain and CaM appear to be primarily responsible for determining the k_r (14–17), whereas the composition of the NOS oxygenase domain is presumed to determine the k_d and k_ox (18, 19). Indeed, our recent point mutagenesis study identified a patch of electronegative residues on the FMN subdomain that are required to maintain a normal k_r and NO synthesis activity in nNOS, suggesting that subdomain electrostatic interactions are important in the process (20). We found particularly large effects when the negative charge at Glu⁷⁶² was neutralized via mutation to Asn. Remarkably, the NO synthesis activity of E762N nNOS was double that of wild-type nNOS, despite the mutant displaying a slow k_r that was half of wild type. In the current report, we show that the E762N mutation has an additional, unsuspected effect on the k_ox kinetic parameter of nNOS. How this effect alters distribution of the nNOS enzyme during steady-state catalysis, impacts the apparent K_m,O2, and leads to hyperactive NO synthesis is described. Our finding that the nNOS flavoprotein domain can tune a key kinetic parameter that defines the rate of a heme-based reaction in the nNOS oxygenase domain is unusual and suggests a means by which protein-protein interactions could regulate the catalytic behavior of nNOS.     

Structural biology: Paper alert

A selection of interesting papers that were published in the two months before our press date in major journals most likely to report significant results in structural biology.     

Altered bleomycin-induced lung fibrosis in osteopontin-deficient mice

Osteopontin is a multifunctional matricellular protein abundantly expressed during inflammation and repair. Osteopontin deficiency is associated with abnormal wound repair characterized by aberrant collagen fibrillogenesis in the heart and skin. Recent gene microarray studies found that osteopontin is abundantly expressed in both human and mouse lung fibrosis. Macrophages and T cells are known to be major sources of osteopontin. During lung fibrosis, however, osteopontin expression continues to increase when inflammation has receded, suggesting alternative sources of ostepontin during this response. In this study, we demonstrate immunoreactivity for osteopontin in lung epithelial and inflammatory cells in human usual interstitial pneumonitis and murine bleomycin-induced lung fibrosis. After treatment with bleomycin, osteopontin-null mice develop lung fibrosis characterized by dilated distal air spaces and reduced type I collagen expression compared with wild-type controls. There is also a significant decrease in levels of active transforming growth factor-beta(1) and matrix metalloproteinase-2 in osteopontin null mice. Type III collagen expression and total collagenase activity are similar in both groups. These results demonstrate that osteopontin expression is associated with important fibrogenic signals in the lung and that the epithelium may be an important source of osteopontin during lung fibrosis.     

Adult emergence phenology in checkerspot butterflies: the effects of macroclimate,topoclimate, and population history

The prediction of adult emergence times in insect populations can be greatly complicated by microclimatic gradients, especially in circumstances where distributions of juveniles along those gradients vary from year to year. To investigate adult emergence patterns in topographically heterogeneous habitats, we built a model of postdiapause development of the Bay checkerspot butterfly, Euphydryas editha bayensis. The model uses slope-specific insolation as the rate-controlling variable, and accounts for both solar exposure of the habitat and cloud cover. Instar-specific larval mass gains per unit of insolation were determined from mark-recapture experiments. A small correction for daily low temperatures was used to calibrate the model to five years of field data on larval mass. The model predicted mean mass of 90% of larval samples within 4 clear days over a 70–120 day growing season. The magnitude of spatial variation in emergence times across habitat slopes is greater than annual variation in emergence times due to yearly weather conditions. Historical variation (yearly shifts in larval distributions across slopes) is an important determinant of mean population emergence dates. All of these factors need to be considered in understanding adult emergence phenology in this butterfly and in other insects inhabiting heterogeneous thermal environments. Such an understanding can be useful in managing insect populations for both pest control and conservation.     

The Fate of Linear DNA in Saccharomyces cerevisiae and Candida glabrata: The Role of Homologous and Non-Homologous End Joining

In vivo assembly of plasmids has become an increasingly used process, as high throughput studies in molecular biology seek to examine gene function. In this study, we investigated the plasmid construction technique called gap repair cloning (GRC) in two closely related species of yeast – Saccharomyces cerevisiae and Candida glabrata. GRC utilizes homologous recombination (HR) activity to join a linear vector and a linear piece of DNA that contains base pair homology. We demonstrate that a minimum of 20 bp of homology on each side of the linear DNA is required for GRC to occur with at least 10% efficiency. Between the two species, we determine that S. cerevisiae is slightly more efficient at performing GRC. GRC is less efficient in rad52 deletion mutants, which are defective in HR in both species. In dnl4 deletion mutants, which perform less non-homologous end joining (NHEJ), the frequency of GRC increases in C. glabrata, whereas GRC frequency only minimally increases in S. cerevisiae, suggesting that NHEJ is more prevalent in C. glabrata. Our studies allow for a model of the fate of linear DNA when transformed into yeast cells. This model is not the same for both species. Most significantly, during GRC, C. glabrata performs NHEJ activity at a detectable rate (>5%), while S. cerevisiae does not. Our model suggests that S. cerevisiae is more efficient at HR because NHEJ is less prevalent than in C. glabrata. This work demonstrates the determinants for GRC and that while C. glabrata has a lower efficiency of GRC, this species still provides a viable option for GRC.