ROLE OF REACTIVE OXYGEN SPECIES PEROXYNITRITE IN TRAUMATIC SPINAL CORD INJURY

Xiong, Yiqin

01 January 2008

Peroxynitrite (PN, ONOO-), formed by nitric oxide radical (•NO) and superoxide radical (O2•-), plays an important role in post-traumatic oxidative damage. In the early work, we determined the temporal characteristics of PN-derived oxidative damage in a rat spinal cord injury (SCI) model. Our results showed 3-nitrotyrosine (3-NT), a specific marker for PN, rapidly accumulated at early time points (1 hr, 3 hrs), after when it plateaued and the high level was sustained to 1 week post injury. The co-localization of 3-NT and lipid peroxidation derived-4-HNE observed in immunohistochemistry indicates PN is involved in lipid peroxidative as well as protein nitrative damage. PN-oxidative damage exacerbates intracellular Ca2+ overload, which activates Ca2+ dependent calpain-mediated cytoskeletal protein (α-spectrin) degradation. The 145 kD fragments of α-spectrin (SBDP 145), which are specifically generated by calpain, increased dramatically as early as 1 hr after injury although the peak increase did not occur until 72 hrs post injury. The high level waned back toward sham level at one week post injury. We then carried out experiments to evaluate the beneficial effects of tempol, a scavenger of PN-derived radicals, following SCI. Three pathological events including PN-induced oxidative damage, mitochondrial dysfunction and cytoskeletal degradation were investigated. Immunoblotting and immunohistochemical studies indicated PN-mediated oxidative damage including protein nitration, protein oxidation and lipid peroxidation, were all reduced by a single dose of tempol (300mg/kg, i.p) after SCI. Spinal cord (SC) mitochondrial dysfunction in terms of the respiratory control ratio (RCR) significantly improved by both 150 mg/kg and 300 mg/kg tempol treatments. Moreover, calpain-mediated proteolysis was significantly decreased by tempol, with greater effects on calpain-specific SBDP 145 observed. Direct PN-scavenging effect of tempol was confirmed in vitro. Exposure of healthy SC mitochondria to SIN-1, a PN donor in vitro, impaired mitochondrial respiration in a dose-dependent manner. Tempol was able to protect mitochondria against SIN-1-induced damage by improving mitochondrial function and decreasing mitochondrial 3-NT formation. These findings strongly support the concept that PN is a crucial player in the secondary damage following SCI. And tempol, by scavenging PN-induced free radicals, provides a promising pharmocotherapeutic strategy for treating acute SCI.

Reactive Oxygen Species

Peroxynitrite

Tempol

Oxidative Damage

Spinal Cord Injury

Anatomy

Medical Neurobiology

Atividade antioxidante de extratos vegetais da flora brasileira: estudo com ressonância paramagnética eletrônica (RPE) e teoria do funcional da densidade (TFD) / Antioxidant Activity of Plant Extracts from Brazilian Flora: Study of Electron Paramagnetic Resonance (EPR) and Density Functional Theory (DFT).

Santos, Adevailton Bernardo dos

03 July 2006

Há, no Brasil, uma enorme diversidade de espécies vegetais, e um conhecimento popular de várias propriedades medicinais das mesmas. Dentre os estudos realizados com extratos de plantas, há um interesse especial na atividade antioxidante. Este trabalho, focado em atividade antioxidante, é dividido em duas partes: a primeira, utiliza a técnica de RPE para estudar a ação dos antioxidantes neutralizando os radicais livres, enquanto que a segunda utiliza a TFD para, em simulação computacional, ajudar a entender os resultados obtidos na primeira parte. Foram analisados 10 extratos vegetais: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (casca de raiz), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (folhas e sementes), Didymopanax vinosum. O estudo da atividade antioxidante com RPE utiliza dois métodos diferentes: o primeiro método mede a atividade antioxidante por meio do controle da quantidade de radicais livres, TEMPOL e DPPH, em contato com o extrato vegetal, enquanto que o segundo método utiliza o spin trap DMPO em conjunto com a reação de Fenton (Fe2+ + H2O2 => Fe3+ + HO- + HO) para analisar a ação dos extratos vegetais contra o radical hidroxila (OH?). A simulação computacional dos compostos TEMPOL, DPPH e DMPO é realizada em um método de primeiros princípios na Teoria do Funcional da Densidade, com uso de pseudopotenciais. O código utilizado é o SIESTA. As conclusões indicam que o extrato de Iryanthera juruensis, tanto de folhas quanto de sementes, exibe atividades antioxidantes bastante acentuadas, em todos os métodos utilizados. A simulação computacional aponta o TEMPOL menos reativo que o DPPH, devido a menor energia liberada em sua reação de redução. Sabendo que algumas destas espécies já são usadas popularmente por propriedades medicinais, estudos futuros para a correta identificação do agente antioxidante e seu possível uso, tanto na indústria alimentícia quanto na farmacêutica, deverão ser realizados. / There is, in Brazil, a great diversity of vegetable species, and a popular knowledge of several medicinal properties of the some of them. In studies carried out with plants? extracts, there is special interest in antioxidant activities. This work, focused in antioxidant activity, is divided in two parts: the first uses EPR technique to study the antioxidant activities neutralizing free radicals, while the second one uses DFT, in computational simulation, to understand the results obtained from the first part. Ten vegetable extracts were analyzed: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (bark root extracts), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (leaves and seeds), Didymopanax vinosum. The study with EPR uses two different methods: the first method measures the antioxidant activity by monitoring the amount of free radicals, DPPH and TEMPOL, that are in contact with the plant extract, the second method uses spin trap DMPO with Fenton reaction (Fe2+ + H2O2 => Fe3+ + HO- + HO) for the study of the plant extract antioxidant activity against the hydroxyl radical (OH?). The computational simulation of TEMPOL, DPPH and DMPO is carried out using a method of first principles within the Density Functional Theory and pseudopotentials. The code is SIESTA. The conclusions indicate that the Iryanthera juruensis extract, as of leaves as of seeds, exhibits accentuated antioxidants activities, in all of the used methods. The computational simulation indicated that the TEMPOL is less reactive than the DPPH, because the lower energy in its reduction reaction. As some of these species are already used popularly by medicinal properties, future studies for correct identification of the antioxidant compounds and its possible use, as in the food industry as in the pharmaceutical industry, should be realized.

antioxidant

antioxidante

Density Functional Theory (DFT).

DMPO

DMPO

DPPH

DPPH

Electron Paramagnetic Resonance (EPR)

extrato vegetal

Fenton reaction

free-radicals

radicais livres

reação de Fenton

TEMPOL

TEMPOL

Teoria do Funcional da Densidade (TFD).

vegetal extract

Atividade antioxidante de extratos vegetais da flora brasileira: estudo com ressonância paramagnética eletrônica (RPE) e teoria do funcional da densidade (TFD) / Antioxidant Activity of Plant Extracts from Brazilian Flora: Study of Electron Paramagnetic Resonance (EPR) and Density Functional Theory (DFT).

Adevailton Bernardo dos Santos

03 July 2006

Há, no Brasil, uma enorme diversidade de espécies vegetais, e um conhecimento popular de várias propriedades medicinais das mesmas. Dentre os estudos realizados com extratos de plantas, há um interesse especial na atividade antioxidante. Este trabalho, focado em atividade antioxidante, é dividido em duas partes: a primeira, utiliza a técnica de RPE para estudar a ação dos antioxidantes neutralizando os radicais livres, enquanto que a segunda utiliza a TFD para, em simulação computacional, ajudar a entender os resultados obtidos na primeira parte. Foram analisados 10 extratos vegetais: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (casca de raiz), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (folhas e sementes), Didymopanax vinosum. O estudo da atividade antioxidante com RPE utiliza dois métodos diferentes: o primeiro método mede a atividade antioxidante por meio do controle da quantidade de radicais livres, TEMPOL e DPPH, em contato com o extrato vegetal, enquanto que o segundo método utiliza o spin trap DMPO em conjunto com a reação de Fenton (Fe2+ + H2O2 => Fe3+ + HO- + HO) para analisar a ação dos extratos vegetais contra o radical hidroxila (OH?). A simulação computacional dos compostos TEMPOL, DPPH e DMPO é realizada em um método de primeiros princípios na Teoria do Funcional da Densidade, com uso de pseudopotenciais. O código utilizado é o SIESTA. As conclusões indicam que o extrato de Iryanthera juruensis, tanto de folhas quanto de sementes, exibe atividades antioxidantes bastante acentuadas, em todos os métodos utilizados. A simulação computacional aponta o TEMPOL menos reativo que o DPPH, devido a menor energia liberada em sua reação de redução. Sabendo que algumas destas espécies já são usadas popularmente por propriedades medicinais, estudos futuros para a correta identificação do agente antioxidante e seu possível uso, tanto na indústria alimentícia quanto na farmacêutica, deverão ser realizados. / There is, in Brazil, a great diversity of vegetable species, and a popular knowledge of several medicinal properties of the some of them. In studies carried out with plants? extracts, there is special interest in antioxidant activities. This work, focused in antioxidant activity, is divided in two parts: the first uses EPR technique to study the antioxidant activities neutralizing free radicals, while the second one uses DFT, in computational simulation, to understand the results obtained from the first part. Ten vegetable extracts were analyzed: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (bark root extracts), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (leaves and seeds), Didymopanax vinosum. The study with EPR uses two different methods: the first method measures the antioxidant activity by monitoring the amount of free radicals, DPPH and TEMPOL, that are in contact with the plant extract, the second method uses spin trap DMPO with Fenton reaction (Fe2+ + H2O2 => Fe3+ + HO- + HO) for the study of the plant extract antioxidant activity against the hydroxyl radical (OH?). The computational simulation of TEMPOL, DPPH and DMPO is carried out using a method of first principles within the Density Functional Theory and pseudopotentials. The code is SIESTA. The conclusions indicate that the Iryanthera juruensis extract, as of leaves as of seeds, exhibits accentuated antioxidants activities, in all of the used methods. The computational simulation indicated that the TEMPOL is less reactive than the DPPH, because the lower energy in its reduction reaction. As some of these species are already used popularly by medicinal properties, future studies for correct identification of the antioxidant compounds and its possible use, as in the food industry as in the pharmaceutical industry, should be realized.

antioxidante

DMPO

DPPH

extrato vegetal

radicais livres

reação de Fenton

TEMPOL

Teoria do Funcional da Densidade (TFD).

antioxidant

Density Functional Theory (DFT).

DMPO

DPPH

Electron Paramagnetic Resonance (EPR)

Fenton reaction

free-radicals

TEMPOL

vegetal extract

ROLE OF THE REACTIVE OXYGEN SPECIES PEROXYNITRITE IN TRAUMATIC BRAIN INJURY

Deng, Ying

01 January 2008

Reactive oxygen species (ROS) is cytotoxic to the cell and is known to contribute to secondary cell death following primary traumatic brain injury (TBI). We described in our study that PN is the main mediator for both lipid peroxidation and protein nitration, and occurred almost immediately after injury. As a downstream factor to oxidative damage, the peak of Ca2+-dependent, calpainmediated cytoskeletal proteolysis preceded that of neurodegeneration, suggesting that calpain-mediated proteolysis is the common pathway leading to neuronal cell death. The time course study clearly elucidated the interrelationship of these cellular changes following TBI, provided window of opportunity for pharmacological intervention. Furthermore, we conducted a pharmacological study to solidify our hypothesis. First of all, we tested the potency of a membrane permeable, catalytic scavenger of PN-derived free radicals, tempol for its ability to antagonize PN-induced oxidative damage. Tempol successfully inhibited PNinduced protein nitration at dosages of 30, 100 and 300mg/kg. Moreover, early single dose of 300mg/kg was administered and isolated mitochondria were examined for respiratory function and oxidative damage level. Our data showed that tempol reduced mitochondrial oxidative damage, and maintained mitochondrial function within normal limits, which suggested that tempol is efficiently permeable to mitochondrial membrane and mitochondrial oxidative damage is essential to mitochondrial dysfunction. Next, we found that calpainmediated proteolysis is reduced at early treatment with a single dose of tempol. However, the effect of tempol on calpain is short-lived possibly due to systematic elimination. In our multiple dose study, tempol showed a significant inhibitory effect on SBDPs. Consequently, we measured neuordegeneration with the de Olmos aminocupric silver staining method at 7 days post-injury and detected a significant decrease of neuronal cell death. Together, the time course study and pharmacological study strongly support the hypothesis that PN is the upstream mediator in secondary cell death in the CCI TBI mouse model. Moreover, inhibition of PN-mediated oxidative damage with the antioxidant, tempol, is able to attenuate multiple downstream injury mechanisms. However, targeting PN alone may be clinically impractical due to its limited therapeutic window. This limitation may be overcome in future studies by a combination of multiple therapeutic strategies.

Traumatic brain injury

Peroxynitrite

Tempol

Mitochondrial dysfunction

Calpain-Mediated Proteolysis

Medical Anatomy

Medical Neurobiology

Medicine and Health Sciences