a(CHEBI:peroxynitrite)

Entity

Name

peroxynitrite

Namespace

chebi

Namespace Version

20180906

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https://raw.githubusercontent.com/pharmacome/terminology/b46b65c3da259b6e86026514dfececab7c22a11b/external/chebi-names.belns

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

During Abeta-associated inflammation, reactive nitrogen and oxygen species are generated that can cause neuronal dysfunction and death (34-37). Prevalent among these species is peroxynitrite (ONOO-) PubMed:16566606

It is noteworthy that IL-1 beta and IL-18 can activate various cell types, par- ticularly astrocytes and microglia to induce additional cytokine release involving IL-1 beta , IL-6, and IL-18, and also nitric oxide (NO) synthase that can stimulate production of free radical NO, leading to the forma- tion of peroxynitrite that denatures DNA and impairs cellular energy pathways [48, 49]. PubMed:27314526

In primary neuronal cells, exposure to Aβ25-35 peptide increase NF-κB mediated transactivation of manganese superoxide dismutase (Mn-SOD), suppress peroxinitrite production and inhibit membrane depolarization, thereby preventing apoptosis induced by oxidative stress PubMed:25652642

The small increase in heme degradation in the absence of SOD1 may, however, be attributed to low levels of heme degradation products produced either by the increased levels of superoxide [17] or perhaps the peroxynitrite that forms due to the rapid reaction of superoxide with any NO present. PubMed:23215741

GPx removes both H2O2 and organic hydroperoxides [8,31] whereas PRDX2 removes H2O2 [2], organic hydroperoxides, lipid hydroperoxides, [32,33] peroxynitrite [34] and protein hydroperoxides [35]. PubMed:23215741

PN-treated wild-type tau and 5XY→F tau consistently displayed lysine formylation throughout tau in a non-sequence specific distribution. Lysine formylation likely results from reactive free radical exposure caused by PN treatment. PubMed:21210655

Select nitration of residues Tyr18, Tyr29, Tyr197, and Tyr394, events known to stabilize the pathological Alz-50 conformation inhibits the ability of monomeric tau to promote tubulin assembly, effect specific for the 3-NT modification, as mutant tau proteins pseudophosphorylated at each Tyr residue are fully competent to stabilize MTs, suggesting that ONOO(-)-mediated modifications stabilize tau filaments via 3,3'-DT bonding and destabilize MTs by site-selective nitration of tau monomers. PubMed:16566606

Previously, we showed that peroxynitrite (ONOO-) induces the oxidative 3,3¢- dityrosine (3,3¢-DT) cross-linking and site-selective nitration of tau monomers [Reynolds et al. (2005) PubMed:16566606

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

In the present study we injected bilaterally 3-morpholino-sydnonimine (SIN-1), a recognized and widely used peroxynitrite donor (25–30), into rat hippocampus, and investigated whether or not peroxynitrite could induce simultaneously nitration and hyperphosphorylation of tau and the underlying mechanisms in vivo. The level of nitrated and hyperphosphorylated tau was markedly increased in rat hippocampus 24 h, and prevented by preinjection of uric acid, a natural scavenger of peroxynitrite. GSK-3beta and p38 MAPKs, including p38alpha, p38beta, and p38delta activity was increased, but no change in the activity of p38gamma, ERK, and c-Jun amino-terminal kinase (JNK). Both nitrated tau and hyperphosphorylated tau were aggregated in the hippocampus, with activity of 20S proteasome significantly arrested in SIN-1-injected rats. Hyperphosphorylated tau was degraded as efficiently as normal tau by 20S proteasome, but the nitrated tau with an unorderly secondary structure became more resistant to the proteolysis, providing evidence that peroxynitrite simultaneously induces tau hyperphosphorylation, nitration, and accumulation, and that activation of GSK-3beta, p38alpha, p38beta, p38delta isoforms and the inhibition of proteasome activity are respectively responsible for the peroxynitrite-induced tau hyperphosphorylation and accumulation. PubMed:16816118

Select nitration of residues Tyr18, Tyr29, Tyr197, and Tyr394, events known to stabilize the pathological Alz-50 conformation inhibits the ability of monomeric tau to promote tubulin assembly, effect specific for the 3-NT modification, as mutant tau proteins pseudophosphorylated at each Tyr residue are fully competent to stabilize MTs, suggesting that ONOO(-)-mediated modifications stabilize tau filaments via 3,3'-DT bonding and destabilize MTs by site-selective nitration of tau monomers. PubMed:16566606

Select nitration of residues Tyr18, Tyr29, Tyr197, and Tyr394, events known to stabilize the pathological Alz-50 conformation inhibits the ability of monomeric tau to promote tubulin assembly, effect specific for the 3-NT modification, as mutant tau proteins pseudophosphorylated at each Tyr residue are fully competent to stabilize MTs, suggesting that ONOO(-)-mediated modifications stabilize tau filaments via 3,3'-DT bonding and destabilize MTs by site-selective nitration of tau monomers. PubMed:16566606

Select nitration of residues Tyr18, Tyr29, Tyr197, and Tyr394, events known to stabilize the pathological Alz-50 conformation inhibits the ability of monomeric tau to promote tubulin assembly, effect specific for the 3-NT modification, as mutant tau proteins pseudophosphorylated at each Tyr residue are fully competent to stabilize MTs, suggesting that ONOO(-)-mediated modifications stabilize tau filaments via 3,3'-DT bonding and destabilize MTs by site-selective nitration of tau monomers. PubMed:16566606

It is noteworthy that IL-1 beta and IL-18 can activate various cell types, par- ticularly astrocytes and microglia to induce additional cytokine release involving IL-1 beta , IL-6, and IL-18, and also nitric oxide (NO) synthase that can stimulate production of free radical NO, leading to the forma- tion of peroxynitrite that denatures DNA and impairs cellular energy pathways [48, 49]. PubMed:27314526

It is noteworthy that IL-1 beta and IL-18 can activate various cell types, par- ticularly astrocytes and microglia to induce additional cytokine release involving IL-1 beta , IL-6, and IL-18, and also nitric oxide (NO) synthase that can stimulate production of free radical NO, leading to the forma- tion of peroxynitrite that denatures DNA and impairs cellular energy pathways [48, 49]. PubMed:27314526

NF-κB activation also protects hippocampal neurons from oxidative stress-induced apoptosis by inducing manganese superoxide dismutase (MnSOD) expression and mitigating peroxynitrite-induced protein nitration PubMed:28745240

The small increase in heme degradation in the absence of SOD1 may, however, be attributed to low levels of heme degradation products produced either by the increased levels of superoxide [17] or perhaps the peroxynitrite that forms due to the rapid reaction of superoxide with any NO present. PubMed:23215741

GPx removes both H2O2 and organic hydroperoxides [8,31] whereas PRDX2 removes H2O2 [2], organic hydroperoxides, lipid hydroperoxides, [32,33] peroxynitrite [34] and protein hydroperoxides [35]. PubMed:23215741