Pei Tsai

The role of tetrahydrobiopterin in the regulation of neuronal nitric-oxide synthase-generated superoxide.

Tetrahydrobiopterin (H4B) is a critical element in the nitric-oxide synthase (NOS) metabolism ofl-arginine to l-citrulline and NO⋅. It has been hypothesized that in the absence of or under nonsaturating levels of l-arginine where O2 reduction is the primary outcome of NOS activation, H4B promotes the generation of H2O2 at the expense of O 2 ⨪ . The experiments were designed to test this hypothesis. To test this theory, two different enzyme preparations, H4B-bound NOS I and H4B-free NOS I, were used. Initial rates of NADPH turnover and O2 utilization were found to be considerably greater in the H4B-bound NOS I preparation than in the H4B-free NOS I preparation. In contrast, the initial generation of O 2 ⨪ from the H4B-free NOS I preparation was found to be substantially greater than that measured using the H4B-bound NOS I preparation. Finally, by spin trapping nearly all of the NOS I produced O 2 ⨪ , we found that the initial rate of H2O2 production by H4B-bound NOS I was considerably greater than that for H4B-free NOS I.

Spin trapping of nitric oxide by ferro-chelates: kinetic and in vivo pharmacokinetic studies

Biologically generated nitric oxide appears to play a pivotal role in the control of a diverse series of physiologic functions. Iron-chelates and low-frequency EPR spectroscopy have been used to verify in vivo production of nitric oxide. The interpretation of in vivo identification of nitric oxide localized at the site of evolution in real time is complicated by the varied kinetics of secretion. The quantitative efficiency of the spectroscopic measurement, so important in understanding the physiology of nitric oxide, remains elusive. The development of a more stable iron-chelate will help better define nitric oxide physiology. In this report, we present data comparing the commonly used ferro-di(N-methyl-D-glucamine-dithiocarbamate) (Fe2+(MGD)2) and the novel chelate ferro-di(N-(dithiocarboxy)sarcosine) (Fe2+(DTCS)2) quantifying the in vitro and in vivo stability of the corresponding spin trapped adducts, NO-Fe(MGD)2 and NO-Fe(DTCS)2. Finally, very low frequency EPR spectroscopy has been used to evaluate the pharmacokinetics of NO-Fe(MGD)2 and NO-Fe(DTCS)2 in mice in real time.

Importance of Nitric Oxide Synthase in the Control of Infection by Bacillus anthracis

ABSTRACT The spore-forming, gram-positive bacterium Bacillus anthracis, the causative agent of anthrax, has achieved notoriety due to its use as a bioterror agent. In the environment, B. anthracis exists as a dormant endospore. Upon infection, germination of endospores occurs during their internalization within the phagocyte, and the ability to survive exposure to antibacterial killing mechanisms, such as O2·−, NO·, and H2O2, is a key initial event in the infective process. Macrophages generate NO· from the oxidative metabolism of l-arginine, using an isoform of nitric oxide synthase (NOS 2). Exposure of murine macrophages (RAW264.7 cells) to B. anthracis endospores up-regulated the expression of NOS 2 12 h after exposure, and production of NO· was comparable to that achieved following other bacterial infections. Spore-killing assays demonstrated a NO·-dependent bactericidal response that was significantly decreased in the presence of the NOS 2 inhibitor l-N6-(1-iminoethyl)lysine and in l-arginine-depleted media. Interestingly, we also found that B. anthracis bacilli and endospores exhibited arginase activity, possibly competing with host NOS 2 for its substrate, l-arginine. As macrophage-generated NO· is an important pathway in microbial killing, the ability of endospores of B. anthracis to regulate production of this free radical has important implications in the control of B. anthracis-mediated infection.

The generation of free radicals by nitric oxide synthase.

Nitric oxide synthase (NOS) is an example of a family of heme-containing monooxygenases that, under the restricted control of a specific substrate, can generate free radicals. While the generation of nitric oxide (NO*) depends solely on the binding of L-arginine, NOS produces superoxide (O(2)*(-)) and hydrogen peroxide (H(2)O(2)) when the concentration of the substrate is low. Not surprisingly, effort has been put forth to understand the pathway by which NOS generates NO*, O(2)*(-) and H(2)O(2), including the role of substrate binding in determining the pathways by which free radicals are generated. By binding within the distal heme pocket near the sixth coordination position of the NOS heme iron, L-arginine alters the coordination properties of the heme iron that promotes formation of the perferryl complex NOS-[Fe(5+)=O](3+). This reactive iron intermediate has been shown to abstract a hydrogen atom from a carbon alpha to a heteroatom and generate carbon-centered free radicals. The ability of NOS to produce free radicals during enzymic cycling demonstrates that NOS-[Fe(5+)=O](3+) behaves like an analogous iron-oxo complex of cytochrome P-450 during aliphatic hydroxylation. The present review discusses the mechanism(s) by which NOS generates secondary free radicals that may initiate pathological events, along with the cell signaling properties of NO*, O(2)*(-) and H(2)O(2).

Protective Role of Bacillus anthracis Exosporium in Macrophage-Mediated Killing by Nitric Oxide

ABSTRACT The ability of the endospore-forming, gram-positive bacterium Bacillus anthracis to survive in activated macrophages is key to its germination and survival. In a previous publication, we discovered that exposure of primary murine macrophages to B. anthracis endospores upregulated NOS 2 concomitant with an ·NO-dependent bactericidal response. Since NOS 2 also generates O2·−, experiments were designed to determine whether NOS 2 formed peroxynitrite (ONOO−) from the reaction of ·NO with O2·− and if so, was ONOO− microbicidal toward B. anthracis. Our findings suggest that ONOO− was formed upon macrophage infection by B. anthracis endospores; however, ONOO− does not appear to exhibit microbicidal activity toward this bacterium. In contrast, the exosporium of B. anthracis, which exhibits arginase activity, protected B. anthracis from macrophage-mediated killing by decreasing ·NO levels in the macrophage. Thus, the ability of B. anthracis to subvert ·NO production has important implications in the control of B. anthracis-induced infection.

2H,15N–Substituted Nitroxides as Sensitive Probes for Electron Paramagnetic Resonance Imaging

Electron paramagnetic resonance imaging (EPRI) using nitroxides is an emergent imaging method for studying in vivo physiology, including O(2) distribution in various tissues. Such imaging capabilities would allow O(2) mapping in tumors and in different brain regions following hypoxia or drug abuse. We have recently demonstrated that the anion of 3-carboxy-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl (2) can be entrapped in brain tissue to quantitate O(2) concentration in vivo. To increase the sensitivity of O(2) measurement by EPR imaging, we synthesized 3-carboxy-2,2,5,5-tetra((2)H(3))methyl-1-(3,4,4-(2)H(3),1-(15)N)pyrrolidinyloxyl (7). EPR spectroscopic measurements demonstrate that this fully isotopically substituted nitroxide markedly improves signal-to-noise ratio and, therefore, the sensitivity of EPR imaging. The new isotopically substituted nitroxide shows increased sensitivity to changes in O(2) concentration, which will enable more accurate O(2) measurement in tissues using EPRI.

Spin trapping nitric oxide from neuronal nitric oxide synthase : A look at several iron-dithiocarbamate complexes

The free radical, nitric oxide (√NO), is responsible for a myriad of physiological functions. The ability to verify and study √NO in vivo is required to provide insight into the events taking place upon its generation and in particular the flux of √NO at relevant cellular sites. With this in mind, several iron-chelates (Fe2+(L)2) have been developed, which have provided a useful tool for the study and identification of √NO through spin-trapping and electron paramagnetic resonance (EPR) spectroscopy. However, the effectiveness of √NO detection is dependent on the Fe2+(L)2 complex. The development of more efficient and stable Fe2+(L)2 chelates may help to better understand the role of √NO in vivo. In this paper, we present data comparing several proline derived iron–dithiocarbamate complexes with the more commonly used spin traps for √NO, Fe2+-di(N-methyl-D-glutamine-dithiocarbamate) (Fe2+(MGD)2) and Fe2+-di(N-(dithiocarboxy)sarcosine) (Fe2+(DTCS)2). We evaluate the apparent rate constant (kapp) for the reaction of √NO with these Fe2+(L)2 complexes and the stability of the corresponding Fe2+(NO)(L)2 in presence of NOS I.

Involvement of the perferryl complex of nitric oxide synthase in the catalysis of secondary free radical formation

Neuronal nitric oxide synthase (NOS I) has been shown to generate nitric oxide (NO*) and superoxide (O(2)* during enzymatic cycling, and the ratio of each free radical is dependent upon the concentration of L-arginine. Using spin trapping and electron paramagnetic resonance spectroscopy, we detected alpha-hydroxyethyl radical (CH(3)*CHOH), produced during the NOS I metabolism of ethanol (EtOH). The generation of CH(3)*CHOH by NOS I was found to be Ca(2+)/calmodulin dependent. Superoxide dismutase prevented CH(3)*CHOH formation in the absence of L-arginine. However, in the presence of L-arginine, the production of CH(3)*CHOH was independent of O(2)* but dependent upon the concentration of L-arginine. Formation of CH(3)*CHOH was inhibited by substituting D-arginine for L-arginine, or inclusion of the NOS inhibitors N(G)-nitro-L-arginine methyl ester, N(G)-monomethyl-L-arginine and the heme blocker, sodium cyanide. The addition of potassium hydrogen persulfate to NOS I, generating the perferryl complex (NOS-[Fe(5+)=O](3+)) in the absence of oxygen and Ca(2+)/calmodulin, and EtOH resulted in the formation of CH(3)*CHOH. NOS I was found to produce the corresponding alpha-hydroxyalkyl radical from 1-propanol and 2-propanol, but not from 2-methyl-2-propanol. Data demonstrated that the perferryl complex of NOS I in the presence of L-arginine was responsible for catalyses of these secondary reactions.

The effect of structure on nitroxide EPR spectral linewidth.

Nitroxides with narrow linewidths are essential for low-frequency EPR spectroscopy and in vivo EPR imaging. In developing a framework for designing narrow-line nitroxides, we sought to understand the unexpectedly narrow line width of 4-oxo-2,2,6,6-tetramethyl-1-piperidinyloxyl (5). Computational modeling revealed that the carbonyl double bond in the 4-position allows conformational diversity that results in the observed narrowing of the EPR spectral line. In view of this finding, we synthesized two new nitroxides bearing an exocyclic double bond: 4-methoxycarbonylmethylidene-2,2,6,6-tetramethyl-1-piperidinyloxyl (7) and 4-acetoxymethoxycarbonylmethylidene-2,2,6,6-tetramethyl-1-piperidinyloxyl (9). These nitroxides, like nitroxide 5, exhibited narrow linewidths-consistent with the results of modeling. Nitroxide 8 (4-carboxymethylidene-2,2,6,6-tetramethyl-1-piperidinyloxyl), as a prototype, allows for a variety of structural diversity, such as nitroxide 9,that can, for instance, target tissue compartments for in vivo EPR imaging.

Spin labelling of Bacillus anthracis endospores : A model for in vivo tracking by EPR imaging

Anthrax is caused by the gram-negative bacterium, Bacillus anthracis. Infection by this microbe results from delivery of the endospore form of the bacillus through direct contact, either topical or inhalation. With regard to the latter route of administration, it is proposed that endospores of B. anthracis enter the lungs and are phagocytized by host alveolar macrophages. Thereafter, it is unclear as to how endospores travel to distal loci and what tissues are the targets. Herein, this study describes the spin labelling of endospores through two different approaches with various aminoxyls. Indeed, after exposure to RAW 264.7 cells, these aminoxyl-containing endospores were phagocytized, as demonstrated by EPR spectroscopy of the infected macrophage, thus providing a potential tool for EPR imaging in animals.