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    Probing the dynamics and conformational landscape of neuronal nitric oxide synthase.

    Sobolewska-Stawiarz, Anna

    [Thesis]. Manchester, UK: The University of Manchester; 2014.

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    Abstract

    Rat neuronal nitric oxide synthase (nNOS) is a flavo-hemoprotein that catalyses the NADPH and O2-dependent conversion of L-arginine (L-arg) to L-citrulline and nitric oxide (NO) via the intermediate N-hydroxyarginine. nNOS is a homodimer, where the subunits are modular and are comprised of an N-terminal oxygenase domain (nNOSoxy) that binds iron protoporphyrin IX (heme), (6R)-5,6,7,8-tetrahydro-biopterin (H4B) and L-arg, and a C-terminal flavoprotein or reductase domain (nNOSred) that binds NADPH, FAD and FMN. Regulation of NO biosynthesis by nNOS is primarily through control of interdomain electron transfer processes in NOS catalysis. The interdomain electrons transferred from the FMN to the heme domain are essential in the delivery of electrons required for O2 activation (which occurs in the heme domain) and the subsequent NO synthesis by NOS. Both spectroscopic and kinetic approaches have been used in studying the nature and control of interdomain electron transfer, reaction mechanism and structural changes during catalysis in WT and R1400E nNOS in both full length (FL) and nNOSred. Cytochrome c reduction activity of nNOS was used to determine kinetic parameters for NADPH for FL and nNOSred, WT and R1400E nNOS in the presence and absence of calmodulin (CaM). FL nNOS, where both domains (nNOSred and nNOSoxy) were present, was proven to be more stable and more catalytically efficient than nNOSred by itself. Additionally it was observed that R1400E is still promoting electron transfer despite being thought to lower the affinity of the enzyme to the substrate (NADPH); R1400E also showed lower catalytic efficiency and lower dependence on CaM/Ca2+ compared to the WT. The structure of the functional output state has not yet been determined. In the absence of crystallographic structural data for the NOS holoenzyme, it was important to experimentally determine conformational changes and distances between domains in nNOS. A pulsed EPR spectroscopy (PELDOR) approach has been utilised to gain important and unique information about the conformational energy landscape changes in nNOS. In the presence of CaM, PELDOR results for FL WT nNOS shows a complex energy landscape with multiple conformational states, while in the absence of CaM the interflavin distance distribution matches that exhibited by nNOSred CaM- in the presence of NADP+, suggesting that CaM binding affects some major large-scale conformational changes which are involved in internal electron transfer control in nNOS. A high-pressure stopped-flow technique was also used to perturb an equilibrium distribution of conformational states, to observe the effect of the pressure on the internal electron transfer and to study the kinetics of NADPH oxidation, flavin reduction by NADPH and NO formation. It was shown that high pressure is forcing major changes in the conformational energy landscape of the protein, affecting internal electron transfer. NO formation studies under pressure show that the R1400E mutation in FL nNOS may be affecting protein/NADPH affinity and flavin reduction, but it has no effect on the heme reduction step.

    Bibliographic metadata

    Type of resource:
    Content type:
    Form of thesis:
    Type of submission:
    Degree type:
    Doctor of Philosophy
    Degree programme:
    PhD Biomolecular Science
    Publication date:
    Location:
    Manchester, UK
    Total pages:
    272
    Abstract:
    Rat neuronal nitric oxide synthase (nNOS) is a flavo-hemoprotein that catalyses the NADPH and O2-dependent conversion of L-arginine (L-arg) to L-citrulline and nitric oxide (NO) via the intermediate N-hydroxyarginine. nNOS is a homodimer, where the subunits are modular and are comprised of an N-terminal oxygenase domain (nNOSoxy) that binds iron protoporphyrin IX (heme), (6R)-5,6,7,8-tetrahydro-biopterin (H4B) and L-arg, and a C-terminal flavoprotein or reductase domain (nNOSred) that binds NADPH, FAD and FMN. Regulation of NO biosynthesis by nNOS is primarily through control of interdomain electron transfer processes in NOS catalysis. The interdomain electrons transferred from the FMN to the heme domain are essential in the delivery of electrons required for O2 activation (which occurs in the heme domain) and the subsequent NO synthesis by NOS. Both spectroscopic and kinetic approaches have been used in studying the nature and control of interdomain electron transfer, reaction mechanism and structural changes during catalysis in WT and R1400E nNOS in both full length (FL) and nNOSred. Cytochrome c reduction activity of nNOS was used to determine kinetic parameters for NADPH for FL and nNOSred, WT and R1400E nNOS in the presence and absence of calmodulin (CaM). FL nNOS, where both domains (nNOSred and nNOSoxy) were present, was proven to be more stable and more catalytically efficient than nNOSred by itself. Additionally it was observed that R1400E is still promoting electron transfer despite being thought to lower the affinity of the enzyme to the substrate (NADPH); R1400E also showed lower catalytic efficiency and lower dependence on CaM/Ca2+ compared to the WT. The structure of the functional output state has not yet been determined. In the absence of crystallographic structural data for the NOS holoenzyme, it was important to experimentally determine conformational changes and distances between domains in nNOS. A pulsed EPR spectroscopy (PELDOR) approach has been utilised to gain important and unique information about the conformational energy landscape changes in nNOS. In the presence of CaM, PELDOR results for FL WT nNOS shows a complex energy landscape with multiple conformational states, while in the absence of CaM the interflavin distance distribution matches that exhibited by nNOSred CaM- in the presence of NADP+, suggesting that CaM binding affects some major large-scale conformational changes which are involved in internal electron transfer control in nNOS. A high-pressure stopped-flow technique was also used to perturb an equilibrium distribution of conformational states, to observe the effect of the pressure on the internal electron transfer and to study the kinetics of NADPH oxidation, flavin reduction by NADPH and NO formation. It was shown that high pressure is forcing major changes in the conformational energy landscape of the protein, affecting internal electron transfer. NO formation studies under pressure show that the R1400E mutation in FL nNOS may be affecting protein/NADPH affinity and flavin reduction, but it has no effect on the heme reduction step.
    Thesis main supervisor(s):
    Thesis co-supervisor(s):
    Thesis advisor(s):
    Language:
    en

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    Record metadata

    Manchester eScholar ID:
    uk-ac-man-scw:218062
    Created by:
    Sobolewska-Stawiarz, Anna
    Created:
    24th January, 2014, 22:32:20
    Last modified by:
    Sobolewska-Stawiarz, Anna
    Last modified:
    9th January, 2019, 09:50:28

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