Margaret Loftus scite author profile

Murine inducible nitric oxide (NO) synthase (iNOS) is catalytically active only in dimeric form. Assembly of its purified subunits into a dimer requires H4B. To understand the structure-activity relationships of human iNOS, we constitutively expressed recombinant human iNOS in NIH 3T3 cells by using a retroviral vector. These cells are deficient in de novo H4B biosynthesis and the role of H4B in the expression and assembly of active iNOS in an intact cell system could be studied. In the absence of added H4B, NO synthesis by the cells was minimal, whereas cells grown with supplemental H4B or the H4B precursor sepiapterin generated NO (74.1 and 63.3 nmol of nitrite per 106 cells per 24 h, respectively). NO synthesis correlated with an increase in intracellular HAB but no increase in iNOS protein. Instead, an increased percentage of dimeric iNOS was observed, rising from 20% in cytosols from unsupplemented cells to 66% in H4B-supplemented cell cytosols. In all cases, only dimeric iNOS displayed catalytic activity. Cytosols prepared from H4B-deficient cells exhibited little iNOS activity but acquired activity during a 60-to 120-min incubation with H4B, reaching final activities of 60-72 pmol of citrulline per mg of protein per min. Reconstitution of cytosolic NO synthesis activity was associated with conversion of monomers into dimeric iNOS during the incubation. Thus, human iNOS subunits dimerize to form an active enzyme, and H4B plays a critical role in promoting dimerization in intact cells. This reveals a posttranslational mechanism by which intracellular H4B can regulate iNOS expression.H4B is synthesized from GTP and was first shown to function as an essential cofactor for the aromatic amino acid hydroxylases (1-3). Subsequent reports of H4B synthesis in cells lacking these enzymes (4) and of increased H4B production during immunostimulation (5) suggested that other H4B-requiring enzymes must exist. This was confirmed when the nitric oxide synthases (NOSs) were found to require H4B for maximum activity (6-10). Three NOS isoforms have been purified and cloned from several sources. All appear to be homodimeric enzymes that convert L-arginine to nitric oxide (NO) and L-citrulline (for reviews, see refs. 11 and 12 (21), studies have been unable to detect redox cycling of H4B in NOS (19,22).In contrast to its elusive redox function, a role for H4B in forming and maintaining NOS structure seems well established. H4B enables L-arginine to bind to NOS (15), stabilizes the axial ligand geometry of the NOS heme iron (23), and induces purified iNOS subunits to associate into an active dimeric enzyme (24). Subunit association in this system also required L-arginine and heme and may be functionally important in that iNOS subunits lack catalytic activity prior to dimerization (24).Although the work with purified subunits is compelling, a role for H4B in iNOS subunit dimerization in intact cells has yet to be established. This is experimentally difficult because many cells either contain sufficient H4B to promote di...

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Subunit Dissociation and Unfolding of Macrophage NO Synthase: Relationship between Enzyme Structure, Prosthetic Group Binding, and Catalytic Function

Abu-Soûd

1995

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Macrophage NO synthase is a homodimer of 130 kDa subunits. Each subunit contains an oxygenase domain that binds iron protoporphyrin IX (heme) and tetrahydrobiopterin (H4biopterin) and a reductase domain that binds FAD, FMN, and calmodulin (CaM) [Ghosh & Stuehr (1995) Biochemistry 34, 801-807]. We have studied the dissociation and unfolding reactions of dimeric iNOS in urea to learn how enzyme structure relates to catalysis and prosthetic group binding. The iNOS dimer dissociated between 0 and 2.5 M urea, and the subunits partially unfolded at 2.5 M urea and above. Dimer dissociation was accompanied by loss of NO synthesis activity and release of bound H4biopterin from the protein. However, the dissociated subunits maintained their cytochrome c and ferricyanide reductase activities and retained near stoichiometric quantities of bound heme. The subunit unfolding transition was accompanied by loss of reductase activities and partial loss of bound heme but retention of bound flavins and CaM. The heme iron in the dissociated subunits remained coordinated through axial cysteine thiolate ligation. Kinetic analysis of dimer dissociation showed that loss of NO synthesis correlated with a loss of heme Soret absorbance at 398 nm and an appearance of absorbance bands at 377 and 460 nm, which were attributed to DTT coordination to the sixth position of the heme iron to form a mixed bisthiolate complex. Subunits could reassociate into a dimer when incubated with L-arginine and H4biopterin. Dimer formation correlated with proportional recoveries of NO synthesis and heme Soret absorbance at 398 nm. Thus, dimeric iNOS undergoes separate dissociation and unfolding transitions in urea, and each transition is accompanied by a loss of a specific catalytic function.(ABSTRACT TRUNCATED AT 250 WORDS)

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Development of automated brightfield double In Situ hybridization (BDISH) application for HER2 gene and chromosome 17 centromere (CEN 17) for breast carcinomas and an assay performance comparison to manual dual color HER2 fluorescence In Situ hybridization (FISH)

et al. 2008

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Background: Human epidermal growth factor receptor 2 (HER2) fluorescence in situ hybridization (FISH) is a quantitative assay for selecting breast cancer patients for trastuzumab therapy. However, current HER2 FISH procedures are labor intensive, manual methods that require skilled technologists and specialized fluorescence microscopy. Furthermore, FISH slides cannot be archived for long term storage and review. Our objective was to develop an automated brightfield double in situ hybridization (BDISH) application for HER2 gene and chromosome 17 centromere (CEN 17) and test the assay performance with dual color HER2 FISH evaluated breast carcinomas.

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Silver In Situ Hybridization (SISH) For Determination of HER2 Gene Status in Breast Carcinoma

Papouchado

Myles

Lloyd

et al. 2010

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The importance of HER2 status in breast cancer management has focused attention on the ability of clinical assays to correctly assign HER2 amplification status. There is no consensus as to the best method for assessing HER2 status. Disadvantages of fluorescence in situ hybridization (FISH) testing include longer time required for staining and scoring slides, requirements for specialized training and fluorescence microscopy, and loss of the signal due to quenching of the fluorescent dye. Silver-enhanced in situ hybridization (SISH) is a rapid fully automated assay providing permanently stained slides that are interpreted by conventional bright field microscopy which enables pathologists to evaluate slides within the context of tissue morphology. This study evaluates the concordance between SISH and FISH assays in determining the status of HER2 gene amplification in a cohort of 298 primary invasive breast carcinomas. Furthermore, we assessed in detail the variables contributing to interobserver interpretive reproducibility of HER2 SISH among 10 pathologists. HER2 was quantified using the ratio of HER2 to CHR17 signals using the conventional historical interpretation scale and also by the American Society of Clinical Oncology/College of American Pathologists reporting scheme. For SISH status determined by consensus among 10 pathologists, overall concordance between SISH and FISH was identified in 288 of 298 cases (96.6%) using the conventional Food and Drug Administration approved criteria. Overall agreement was observed in 282 of 285 cases (98.9%) using the American Society of Clinical Oncology/College of American Pathologists result reporting scheme (with equivocal cases removed). In conclusion, SISH represents a novel approach for the determination of HER2 status in breast cancer. The overall concordance between SISH and FISH is excellent, and the interpretation of SISH results by pathologists is most reproducible using the HER2/CHR17 ratio.

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Margaret Loftus

Expression of human inducible nitric oxide synthase in a tetrahydrobiopterin (H4B)-deficient cell line: H4B promotes assembly of enzyme subunits into an active dimer.

Subunit Dissociation and Unfolding of Macrophage NO Synthase: Relationship between Enzyme Structure, Prosthetic Group Binding, and Catalytic Function

Development of automated brightfield double In Situ hybridization (BDISH) application for HER2 gene and chromosome 17 centromere (CEN 17) for breast carcinomas and an assay performance comparison to manual dual color HER2 fluorescence In Situ hybridization (FISH)

Silver In Situ Hybridization (SISH) For Determination of HER2 Gene Status in Breast Carcinoma

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