Formation of Nitric Oxide–Derived Oxidants by Myeloperoxidase in Monocytes

Hazen, Stanley L.; Zhang, Renliang; Shen, Zhongzhou; Wu, Weijia; Podrez, Eugene A.; MacPherson, Jennifer C.; Schmitt, David; Mitra, Sophie; Mukhopadhyay, Chaitali; Chen, Yonghong; Cohen, Peter A.; Hoff, Hans; Abu-Soûd, Husam M.

doi:10.1161/01.res.85.10.950

Cited by 211 publications

(81 citation statements)

References 55 publications

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“…This nTyr increase, which is not observed in tPA -/-mice (Fig. 1A,B), although usually attributed to ONOO -, is not completely specific for it, since the nitrite-hemeperoxidase pathway can also result in tyrosine nitration (Chao et al, 1992;Hazen et al, 1999). Scavenging ONOO -by FeTMPyP attenuates the neurotoxic properties of KA and reduces the levels of oxidation (Fig.…”

Section: Discussionmentioning

confidence: 89%

Nitric oxide mediates neurodegeneration and breakdown of the blood-brain barrier in tPA-dependent excitotoxic injury in mice

Parathath

Tsirka

2006

Journal of Cell Science

101

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Stroke and many neurodegenerative diseases culminate in neuronal death through a mechanism known as excitotoxicity. Excitotoxicity proceeds through a complex signaling pathway that includes the participation of the serine protease tissue plasminogen activator (tPA). tPA mediates neurotoxic effects on resident central nervous system cells as well alters blood-brain barrier (BBB) permeability, which further promotes neurodegeneration. Another signaling molecule that promotes neurodegeneration and BBB dysfunction is nitric oxide (NO), although its precise role in pathological progression remains unclear. We examine here the potentially interrelated roles of tPA, NO and peroxynitrite (ONOO–), which is the toxic metabolite of NO, in BBB breakdown and neurodegeneration following intrahippocampal injection of the glutamate analog kainite (KA). We find that NO and ONOO– production are linked to tPA-mediated excitotoxic injury, and demonstrate that NO provision suffices to restore the toxic effects of KA in tPA-deficient mice that are normally resistant to excitotoxicity. NO also promotes BBB breakdown and excitotoxicity. Interestingly, BBB breakdown in itself does not suffice to elicit neurodegeneration; a subsequent ONOO–-mediated event is required. In conclusion, NO and ONOO– function as downstream effectors of tPA-mediated excitotoxicity.

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Section: Discussionmentioning

confidence: 89%

Nitric oxide mediates neurodegeneration and breakdown of the blood-brain barrier in tPA-dependent excitotoxic injury in mice

Parathath

Tsirka

2006

Journal of Cell Science

101

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“…Certainly the T cells induced by immunizing with peroxynitrite HEL or peptides also reacted with the activated APC. However, products derived from iNOS and myeloperoxidase show nitrating activity (24,25,46,47). A final point is that modifications are not taking place in a single vesicular compartment; they took place in both HEL, which is processed in a late vesicular compartment, and the 48-62 peptide, processed in a recycling early vesicle (48).…”

Section: Discussionmentioning

confidence: 99%

Activated antigen-presenting cells select and present chemically modified peptides recognized by unique CD4 T cells

Herzog

Maekawa

Cirrito

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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CD4 T cells recognized posttranslationally modified peptides of the protein hen egg-white lysozyme (HEL), consisting of nitration of tyrosines and modifications of tryptophans in the T cell contact residues of the peptides. T cells were directed against modifications of a chemically dominant HEL peptide as well as a minor HEL peptide, bound to the class II histocompatibility molecule I-A k . The modified peptides were generated in vivo after immunization with native HEL molecules or were generated ex vivo by peroxynitrite treatment of HEL. Moreover, antigen-presenting cells (APC), either macrophages or dendritic cells activated in culture or in vivo, generated the modified HEL epitopes that stimulated the T cells. In transgenic mice expressing HEL, the T cells to the modified epitopes escaped negative selection and were found, albeit fewer in number than in normal mice. Infection with Listeria monocytogenes of the transgenic HEL mice generated APC containing the modifications. T cells to modified epitopes induced by activation of APC may be a component of antimicrobial immunity and autoimmune reactions.histocompatability molecules ͉ nitrotyrosine ͉ posttranslational modification P eptides bound to either class I or class II MHC molecules suffer posttranslational modifications of potential importance in the context of inducing unique T cell reactivities. A number of posttranslational changes were identified on peptides isolated from class I MHC proteins (1, 2), including phosphorylation of tyrosine residues (3). Unique T cell reactivities were ascribed to changes in the peptides bound to class II MHC molecules (reviewed in ref. 4). These included phosphorylations (5), conversions of asparagine or aspartic acid to isoaspartic acid (6, 7), glutamine to glutamic acid (8, 9), nitration of tyrosine (10), and addition of saccharide residues to a peptide (11-15). These results are reminiscent of early ones showing T cell reactions to proteins containing small reactive chemical groups, i.e., with ''haptens,'' first reported by Jones and Leskowitz (16) in delayed sensitivity reactions to arsanilic acid. Their observations were extended by others (17), including by using dinitrophenyl to derivatize class II molecules on cells (18). Clearly, T cells are highly discriminatory of large or small changes in the residues to which their receptor [T cell receptor (TCR)] establishes contact. Antibodies directed to posttranslationally modified proteins have also been identified (19,20).Activation of macrophages and dendritic cells (DC) takes place after their interactions with IFN-␥ together with cytokines like TNF or IL-1, or microbial products like LPS from Gram-negative bacteria. The activation includes the production of nitric oxide (NO) and reactive oxygen species with the formation of strong oxidizing molecules such as peroxynitrite (21-23) or other derivatives (24,25). These molecules induce a number of amino acid changes, including nitration of tyrosines (21, 22) and modification of tryptophans (26). The present study report...

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“…However, after polymorphonuclear cell degranulation, MPO can be taken up by nonphagocytic cells, and a strong codistribution of MPO and 3-nitrotyrosine is observed in different inflammatory processes (63). Excess • NO can also modulate the hemeperoxidase-mediated nitration; indeed, • NO readily reacts with resting state MPO as well as with compounds I and II, and therefore peroxidases may serve as catalytic sinks of • NO and influence nitration yields (64).…”

Section: The Limited Efficiency Of the Nitration Reactions In Biologymentioning

confidence: 99%

Nitric oxide, oxidants, and protein tyrosine nitration

Radí

2004

Proc. Natl. Acad. Sci. U.S.A.

1,345

1,066

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Formation of Nitric Oxide–Derived Oxidants by Myeloperoxidase in Monocytes

Cited by 211 publications

References 55 publications

Nitric oxide mediates neurodegeneration and breakdown of the blood-brain barrier in tPA-dependent excitotoxic injury in mice

Nitric oxide mediates neurodegeneration and breakdown of the blood-brain barrier in tPA-dependent excitotoxic injury in mice

Activated antigen-presenting cells select and present chemically modified peptides recognized by unique CD4 T cells

Nitric oxide, oxidants, and protein tyrosine nitration

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