A Tale of Two Controversies

Brennan, Marie Luise; Wu, Weijia; Fu, Xiaoming; Shen, Zhongzhu; Song, Wei; Frost, Heather N.; Vadseth, Caryn; Narine, Laura; Lenkiewicz, Elizabeth; Borchers, Michael T.; Lusis, Aldons J.; Lee, James J.; Lee, Nancy A.; Abu-Soûd, Husam M.; Ischiropoulos, Harry; Hazen, Stanley L.

doi:10.1074/jbc.m112400200

Cited by 455 publications

(143 citation statements)

References 61 publications

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“…In some models, MPO and EPO played a dominant role, accounting for the majority of nitrotyrosine formed. However, in other leukocyte-rich acute inflammatory models, neither MPO nor EPO contributed to nitrotyrosine formation, implying the existence of alternative nitration pathways (18).…”

Section: Ookinete-invaded Cells Undergomentioning

confidence: 99%

“…NO formation resulted in nitrite accumulation, which was proposed to serve as a substrate for a myeloperoxidase (MPO)-mediated tyrosine nitration reaction (17). Experiments using multiple distinct models of acute inflammation with eosinophil peroxidase (EPO)-and MPO knock-out mice indicate that leukocyte peroxidases participate in nitrotyrosine formation in vivo (18). In some models, MPO and EPO played a dominant role, accounting for the majority of nitrotyrosine formed.…”

Section: Ookinete-invaded Cells Undergomentioning

confidence: 99%

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Inducible Peroxidases Mediate Nitration of Anopheles Midgut Cells Undergoing Apoptosis in Response to Plasmodium Invasion

Kumar

Gupta

Han

et al. 2004

Journal of Biological Chemistry

119

134

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Plasmodium berghei invasion of Anopheles stephensi midgut cells causes severe damage, induces expression of nitric-oxide synthase, and leads to apoptosis. The present study indicates that invasion results in tyrosine nitration, catalyzed as a two-step reaction in which nitric-oxide synthase induction is followed by increased peroxidase activity. Ookinete invasion induced localized expression of peroxidase enzymes, which catalyzed protein nitration in vitro in the presence of nitrite and H 2 O 2 . Histochemical stainings revealed that when a parasite migrates laterally and invades more than one cell, the pattern of induced peroxidase activity is similar to that observed for tyrosine nitration. In Anopheles gambiae, ookinete invasion elicited similar responses; it induced expression of 5 of the 16 peroxidase genes predicted by the genome sequence and decreased mRNA levels of one of them. One of these inducible peroxidases has a C-terminal oxidase domain homologous to the catalytic moiety of phagocyte NADPH oxidase and could provide high local levels of superoxide anion (O 2 . ), that when dismutated would generate the local increase in H 2 O 2 required for nitration. Chemically induced apoptosis of midgut cells also activated expression of four ookinete-induced peroxidase genes, suggesting their involvement in general apoptotic responses. The two-step nitration reaction provides a mechanism to precisely localize and circumscribe the toxic products generated by defense reactions involving nitration. The present study furthers our understanding of the biochemistry of midgut defense reactions to parasite invasion and how these may influence the efficiency of malaria transmission by anopheline mosquitoes.Anopheline mosquitoes are the natural vectors of human malaria worldwide. When a female mosquito takes a blood meal from a malaria-infected host, the ingested Plasmodium gametocytes complete their differentiation into mature gametes in the midgut lumen. Following fertilization, zygotes mature into motile ookinetes, which traverse the midgut epithelium and form oocysts in the space between the epithelial cells and the basal lamina. Oocysts grow, mature, and eventually rupture, releasing a large number of sporozoites into the hemolymph. The sporozoites invade the salivary glands and are injected into a new vertebrate host when an infected female takes a second blood meal.In Anopheles stephensi, midgut invasion of Plasmodium berghei ookinetes takes place around 24 h after blood feeding and induces the expression of nitric-oxide synthase (NOS) 1 as revealed by immunofluorescence (1) and increased NADPHdependent nitroblue tetrazolium reduction activity (2). NOS catalyzes the formation of nitric oxide (NO), a highly reactive and toxic molecule (3-5). NO is unstable and reacts readily with other molecules, generating multiple reactive nitrogen intermediates. Peroxynitrite is formed by a rapid reaction between NO and a superoxide anion and readily nitrates proteins in vitro (6, 7). peroxynitrite has also been proposed to be t...

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Section: Ookinete-invaded Cells Undergomentioning

confidence: 99%

Section: Ookinete-invaded Cells Undergomentioning

confidence: 99%

Inducible Peroxidases Mediate Nitration of Anopheles Midgut Cells Undergoing Apoptosis in Response to Plasmodium Invasion

Kumar

Gupta

Han

et al. 2004

Journal of Biological Chemistry

119

134

View full text Add to dashboard Cite

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“…Quantification of Total Nitrotyrosine and Tyrosine-The snap-frozen samples were thawed and analyzed by stable isotope dilution high pressure liquid chromatography-tandem mass spectrometry, as described previously in detail, using 300 g of protein per analysis (28).…”

Section: Figmentioning

confidence: 99%

Rapid and Selective Oxygen-regulated Protein Tyrosine Denitration and Nitration in Mitochondria

Koeck

Hazen

et al. 2004

Journal of Biological Chemistry

Self Cite

167

133

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Growing evidence connects a cumulative formation of 3-nitrotyrosyl adducts in proteins as a marker for oxidative damage with the pathogenesis of various diseases and pathological conditions associated with oxidative stress. A physiological signaling role for protein nitration has also been suggested. Controlled "denitration" would be essential for such a contribution of protein nitration to cellular regulatory processes. Thus, we further characterized such a potentially controlled, reversible tyrosine nitration that occurs in respiring mitochondria during oxygen deprivation followed by reoxygenation, which we recently discovered. Mitochondria constitute cellular centers of protein nitration and are leading candidates for a "nitrative" regulation. Mitochondria are capable of completely eliminating 3-nitrotyrosyl adducts during 20 min of hypoxia-anoxia and undergoing a selective partial reduction after only 5 min. This denitration is independent of protein degradation but depends on the oxygen tension. Reoxygenation re-establishes protein tyrosine nitration patterns that are almost identical to the pattern that occurs before hypoxia-anoxia, with nitration levels that depend on the duration of hypoxia-anoxia. The identified mitochondrial targets of this process are critical for energy and antioxidant homeostasis and, therefore, cell and tissue viability. This cycle of protein nitration and denitration shows analogies to protein phosphorylation, and we demonstrate that the cycle meets most of the criteria for a cellular signaling mechanism. Taken together, our data reveal that protein tyrosine nitration in mitochondria can be controlled, is target-selective and rapid, and is dynamic enough to serve as a nitrative regulatory signaling process that likely affects cellular energy, redox homeostasis, and pathological conditions when these features become disturbed.

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“…1 -5 NO-Tyr per 10 4 Tyr residues [175]. Values from 6-80 μmol/mol (Tyr/NO-Tyr) were reported in reference [176], and ~ 10 ng NO-Tyr/mg protein in plasma and tissue up to 170 ng/mg in actin-enreched fractions of tissue proteins have been reported in reference [177]. It has been demonstrated recently that N-terminal-blocked tryptophan moieties can effectively be nitrosated by N 2 O 3 [138,139], outlining the pivotal role of high nitrogen oxides in aromatic nitrosation.…”

Section: Aromatic Nitrosation 3-nitrotyrosine and N-nitrosotryptophamentioning

confidence: 99%

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

Boudko

2007

Journal of Chromatography B

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This review briefly summarizes recent progress in fundamental understanding and analytical profiling of the L-arginine/nitric oxide (NO) pathway. It focuses on key analytical references of NO actions and on the experimental acquisition of these references in vivo, with capillary electrophoresis (CE) and high-performance capillary electrophoresis (HPCE) comprising one of the most flexible and technologically promising analytical platform for comprehensive high-resolution profiling of NO-related metabolites. Second aim of this review is to express demands and bridge efforts of experimental biologists, medical professionals and chemical analysis-oriented scientists who strive to understand evolution and physiological roles of NO and to develop analytical methods for use in biology and medicine.

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A Tale of Two Controversies

Cited by 455 publications

References 61 publications

Inducible Peroxidases Mediate Nitration of Anopheles Midgut Cells Undergoing Apoptosis in Response to Plasmodium Invasion

Inducible Peroxidases Mediate Nitration of Anopheles Midgut Cells Undergoing Apoptosis in Response to Plasmodium Invasion

Rapid and Selective Oxygen-regulated Protein Tyrosine Denitration and Nitration in Mitochondria

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

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