Role of Oxidative Stress in Mediating Elevated Atrial Fibrillation by Tumor Necrosis Factor-alpha

Mirkhani, S. Moniba

21 March 2012

Atrial fibrillation (AF), the most common arrhythmia encountered in clinical practice, is a major source of morbidity and mortality, and is highly associated with inflammation and oxidative stress. In the present study, we show that acute exposure of mice atrial tissue to tumor necrosis factor-α (TNF-α) increases susceptibility to AF. We further show that acute exposure to TNF-α led to increased spontaneous sarcoplasmic reticulum (SR) calcium release and generated triggered activities in isolated mice atrial myocytes. This increase in spontaneous SR calcium activity was found to be due to elevated reactive oxygen species production from mitochondria and NADPH oxidase sources triggered by TNF-α. Hence we concluded that acute exposure to TNF-α leads to elevated oxidative stress that increases spontaneous SR Ca2+ release and triggered activity through which it can lead to AF induction and maintenance

Atrial Fibrillation

Oxidative Stress

Reactive Oxygen Species (ROS)

Inflammation

TNF-alpha

Calcium Sparks

Triggered Activity

Mitochondria

NADPH Oxidase

0719

Effects of Rotenone and 6-OHDA on Dopaminergic Neurons of the Substantia Nigra Studied In Vitro

Freestone, Peter Stuart

January 2009

This study investigated the neurotoxic effects of rotenone and 6-hyroxydopamine (6 OHDA), two compounds which have been implicated in Parkinson’s disease (PD). PD is a neurodegenerative disorder that results in the impairment of movement. During the disease process, a group of dopamine-containing cells in the brain region called the Substantia Nigra pars compacta (SNc), degenerate. Whilst genetic factors contribute to approximately 5% of PD cases, the causes of the remaining 95% are unknown. What does seem clear is the pivotal role of mitochondrial dysfunction as observed in post-mortem human tissue. Mitochondrial dysfunction leads to energy depletion and the generation of harmful reactive oxygen species (ROS). However, despite the fact that the involvement of mitochondria in the disease process has been well established, the cellular events that lead to, and result from, mitochondrial dysfunction remain poorly understood. Rotenone and 6 OHDA have been implicated in PD for two reasons: (1) both toxins can relatively selectively kill SNc neurons in animal models of PD, and (2) there is evidence for both compounds having a potential causative role in the etiology of the disease in humans. When 6 OHDA is injected into the brain, or rotenone applied systemically, both toxins cause degeneration of SNc neurons. This ability makes them excellent tools for studying mechanisms of PD in animal models. In addition, both toxins inhibit mitochondrial function. Despite extensive use in models of PD, the mechanisms by which each toxin cause cell damage remains elusive. The first part of this study investigated the acute responses of dopaminergic SNc neurons to rotenone exposure (5 nM – 1 µM). The experiments were conducted on brain slices obtained from rats. Electrophysiological recordings (whole-cell patch-clamp technique) were used to detect activation of specific membrane channels as well as cell firing and changes to the membrane potential. In addition, imaging of several fluorescent dyes sensitive to specific cellular events was carried out. In voltage-clamp experiments, acute rotenone (200 nM – 1 µM) application evoked a concentration-dependent outward current which was mediated by tolbutamide-sensitive KATP channels. The current was associated with a drop in cell input resistance (Rm) and, in current-clamp, membrane hyperpolarization and inhibition of spontaneous action potentials. The mechanisms by which rotenone activates KATP channels is controversial, with some studies suggesting activation by ATP depletion and others by elevated reactive oxygen species (ROS). To address this issue, experiments were conducted with high levels of ATP in the pipette solution. Since the rotenone-induced outward current was unaffected by high ATP levels, it was concluded that KATP channel activation was due to oxidative stress. Indeed, the antioxidant Trolox significantly attenuated the current response. Confirmation of elevated ROS production was obtained by recording increased mitochondrial superoxide production, using the fluorescent dye MitoSOX. In addition, rotenone evoked depolarization of mitochondrial membrane potential (ΔΨm). Measurements of intracellular Ca2+ and Na+ were performed using the fluorescent dyes Fura 2 and SBFI, respectively. Rotenone evoked increases to both [Ca2+]i and [Na+]i in a concentration-dependent manner. The rotenone-induced [Ca2+]i rise was unaffected by blocking KATP channels with Cs+. The elevation of [Ca2+]i is particularly important in relation to cell death, since [Ca2+]i overload is known to activate pathways leading to necrosis and apoptosis. There has been growing interest in the synergistic action of rotenone with other toxins/conditions which also enhance [Ca2+]i. This concept was explored in the present study by testing the relationship between the baseline [Ca2+]i level and the rotenone-induced [Ca2+]i increase. Two approaches were taken. Firstly, baseline [Ca2+]i was deliberately raised by activation of voltage-gated calcium channels. When rotenone was applied in the presence of this raised baseline calcium level, the rotenone-induced [Ca2+]i rise was significantly greater. The second approach involved post-hoc analysis of the relationship between the normal cellular variation in baseline [Ca2+]i and the rotenone-induced [Ca2+]i elevation. This analysis also revealed a dependency of the rotenone-induced [Ca2+]i elevation on the baseline calcium level. From this finding, as well as the observation that rotenone evoked ROS production, Transient Receptor Protein subtype M2 (TRPM2) channels were proposed as the likely underlying mechanism. The potentiation of the rotenone-induced [Ca2+]i rise by an elevation in baseline calcium level can be attributed to the calcium-dependence of ROS-sensitive TRPM2 channels, known to respond with increased channel opening to increased [Ca2+]i. Recent findings from our laboratory have confirmed TRPM2 involvement in rotenone toxicity, since blockade of these channels with ACA reduced the rotenone-induced [Ca2+]i rise (K. Chung, unpublished). Imaging using the fluorescent dye propidium iodide (PI) to label cells with compromised membrane integrity was also conducted in acute midbrain slices. SNc neurons were retrograde-labelled with FluoroGold and then exposed to various toxic insults. The detergent Triton-X100 caused an increase in PI labelling, whilst rotenone and high concentrations of glutamate were ineffective over the period of time investigated (up to 40 min). The second part of this study, also conducted on acute rat midbrain slices, investigated the acute responses of SNc neurons to 6 OHDA (0.2 – 2 mM) exposure. Extracellular recordings of action potential firing were conducted on SNc neurons. 6 OHDA evoked rapid inhibition of firing in a similar manner to dopamine (100 µM). In the presence of D2 dopamine receptor blocker sulpiride, the inhibition of firing evoked by 6 OHDA was delayed, and an initial increase of firing was observed. Blockade of the dopamine transporter with nomifensine reduced the 6 OHDA-induced inhibition of firing, and prevented the persistent inhibition of firing after 6 OHDA washout. For comparison, the response to 6 OHDA of non-dopaminergic neurons in the subthalamic nucleus was also studied. In the subthalamic nucleus, 6 OHDA evoked an increase of spontaneous action potential firing. Rapid application of 6 OHDA (using the picospritz application technique) in voltage-clamp recorded SNc neurons evoked an outward current, similar to that observed after dopamine application. In the presence of sulpiride, 6 OHDA induced an inward current, consistent with the initial increase of firing activity observed in extracellular recordings. Microfluorometric experiments with Fura 2, showed that 6 OHDA evokes an increase in [Ca2+]i. Loading cells with the fluorescent dye Lucifer Yellow enabled visualization of 6 OHDA-induced swelling of the cell body and damage to proximal dendrites. Imaging of SNc neurons loaded with dextran-rhodamine revealed 6 OHDA-induced damage of distal dendrites. The last part of the study was performed on organotypic cultures obtained from slices of the ventral midbrain. These cultures were prepared from newborn transgenic mice expressing green fluorescent protein (GFP) under the tyrosine hydroxylase-promoter. This fluorescent marker enabled easy identification of dopamine-containing cells (including SNc neurons). Only preliminary experiments were carried out using this preparation. GFP-positive neurons did not show the classic membrane hyperpolarization in response to dopamine. For comparison, recordings from GFP-positive SNc neurons in acute slices obtained from age-matched animals did show a typical hyperpolarizing response to dopamine. GFP-neurons from organotypic cultures also lacked the Ih current – another characteristic feature of SNc neurons in vivo or in acute brain slices. In addition, atypical responses to CNQX (blocker of NMDA receptors) and baclofen (blocker of GABAB receptors) application were identified in GFP-positive neurons. These results demonstrate that the culturing process used in this study alters the functional ‘phenotype’ of dopaminergic neurons, a change which needs to be considered in future studies using this preparation. Chronic exposure of organotypic cultures to low concentration of rotenone (50 nM) evoked a delayed increase of PI labelling indicative of cell death, however technical limitations prevented detection of PI co-localization with GFP was observed. In conclusion, this study identified several key aspects of 6 OHDA and rotenone toxicity in SNc neurons. The most significant novel findings include evidence for ROS activation of KATP channels, presumed involvement of TRPM2 channels in rotenone-induced [Ca2+]i rise, and dopamine-analogous effects of 6 OHDA. The controversial role of KATP channels in neuroprotection was addressed. Findings from this study suggest therapies targeting this channel alone would be of little benefit. The proposed involvement of TRPM2 channels in rotenone-induced [Ca2+]i overload in SNc neurons is particularly interesting as it provides a mechanism for synergism between rotenone and other factors that disrupt [Ca2+]i homeostasis.

Parkinson's Disease

Neurotoxicity

Intracellular Calcium

Reactive Oxygen Species

Mitochondria

Electrophysiology

TRPM2

KATP

Effects of Rotenone and 6-OHDA on Dopaminergic Neurons of the Substantia Nigra Studied In Vitro

Freestone, Peter Stuart

January 2009

This study investigated the neurotoxic effects of rotenone and 6-hyroxydopamine (6 OHDA), two compounds which have been implicated in Parkinson’s disease (PD). PD is a neurodegenerative disorder that results in the impairment of movement. During the disease process, a group of dopamine-containing cells in the brain region called the Substantia Nigra pars compacta (SNc), degenerate. Whilst genetic factors contribute to approximately 5% of PD cases, the causes of the remaining 95% are unknown. What does seem clear is the pivotal role of mitochondrial dysfunction as observed in post-mortem human tissue. Mitochondrial dysfunction leads to energy depletion and the generation of harmful reactive oxygen species (ROS). However, despite the fact that the involvement of mitochondria in the disease process has been well established, the cellular events that lead to, and result from, mitochondrial dysfunction remain poorly understood. Rotenone and 6 OHDA have been implicated in PD for two reasons: (1) both toxins can relatively selectively kill SNc neurons in animal models of PD, and (2) there is evidence for both compounds having a potential causative role in the etiology of the disease in humans. When 6 OHDA is injected into the brain, or rotenone applied systemically, both toxins cause degeneration of SNc neurons. This ability makes them excellent tools for studying mechanisms of PD in animal models. In addition, both toxins inhibit mitochondrial function. Despite extensive use in models of PD, the mechanisms by which each toxin cause cell damage remains elusive. The first part of this study investigated the acute responses of dopaminergic SNc neurons to rotenone exposure (5 nM – 1 µM). The experiments were conducted on brain slices obtained from rats. Electrophysiological recordings (whole-cell patch-clamp technique) were used to detect activation of specific membrane channels as well as cell firing and changes to the membrane potential. In addition, imaging of several fluorescent dyes sensitive to specific cellular events was carried out. In voltage-clamp experiments, acute rotenone (200 nM – 1 µM) application evoked a concentration-dependent outward current which was mediated by tolbutamide-sensitive KATP channels. The current was associated with a drop in cell input resistance (Rm) and, in current-clamp, membrane hyperpolarization and inhibition of spontaneous action potentials. The mechanisms by which rotenone activates KATP channels is controversial, with some studies suggesting activation by ATP depletion and others by elevated reactive oxygen species (ROS). To address this issue, experiments were conducted with high levels of ATP in the pipette solution. Since the rotenone-induced outward current was unaffected by high ATP levels, it was concluded that KATP channel activation was due to oxidative stress. Indeed, the antioxidant Trolox significantly attenuated the current response. Confirmation of elevated ROS production was obtained by recording increased mitochondrial superoxide production, using the fluorescent dye MitoSOX. In addition, rotenone evoked depolarization of mitochondrial membrane potential (ΔΨm). Measurements of intracellular Ca2+ and Na+ were performed using the fluorescent dyes Fura 2 and SBFI, respectively. Rotenone evoked increases to both [Ca2+]i and [Na+]i in a concentration-dependent manner. The rotenone-induced [Ca2+]i rise was unaffected by blocking KATP channels with Cs+. The elevation of [Ca2+]i is particularly important in relation to cell death, since [Ca2+]i overload is known to activate pathways leading to necrosis and apoptosis. There has been growing interest in the synergistic action of rotenone with other toxins/conditions which also enhance [Ca2+]i. This concept was explored in the present study by testing the relationship between the baseline [Ca2+]i level and the rotenone-induced [Ca2+]i increase. Two approaches were taken. Firstly, baseline [Ca2+]i was deliberately raised by activation of voltage-gated calcium channels. When rotenone was applied in the presence of this raised baseline calcium level, the rotenone-induced [Ca2+]i rise was significantly greater. The second approach involved post-hoc analysis of the relationship between the normal cellular variation in baseline [Ca2+]i and the rotenone-induced [Ca2+]i elevation. This analysis also revealed a dependency of the rotenone-induced [Ca2+]i elevation on the baseline calcium level. From this finding, as well as the observation that rotenone evoked ROS production, Transient Receptor Protein subtype M2 (TRPM2) channels were proposed as the likely underlying mechanism. The potentiation of the rotenone-induced [Ca2+]i rise by an elevation in baseline calcium level can be attributed to the calcium-dependence of ROS-sensitive TRPM2 channels, known to respond with increased channel opening to increased [Ca2+]i. Recent findings from our laboratory have confirmed TRPM2 involvement in rotenone toxicity, since blockade of these channels with ACA reduced the rotenone-induced [Ca2+]i rise (K. Chung, unpublished). Imaging using the fluorescent dye propidium iodide (PI) to label cells with compromised membrane integrity was also conducted in acute midbrain slices. SNc neurons were retrograde-labelled with FluoroGold and then exposed to various toxic insults. The detergent Triton-X100 caused an increase in PI labelling, whilst rotenone and high concentrations of glutamate were ineffective over the period of time investigated (up to 40 min). The second part of this study, also conducted on acute rat midbrain slices, investigated the acute responses of SNc neurons to 6 OHDA (0.2 – 2 mM) exposure. Extracellular recordings of action potential firing were conducted on SNc neurons. 6 OHDA evoked rapid inhibition of firing in a similar manner to dopamine (100 µM). In the presence of D2 dopamine receptor blocker sulpiride, the inhibition of firing evoked by 6 OHDA was delayed, and an initial increase of firing was observed. Blockade of the dopamine transporter with nomifensine reduced the 6 OHDA-induced inhibition of firing, and prevented the persistent inhibition of firing after 6 OHDA washout. For comparison, the response to 6 OHDA of non-dopaminergic neurons in the subthalamic nucleus was also studied. In the subthalamic nucleus, 6 OHDA evoked an increase of spontaneous action potential firing. Rapid application of 6 OHDA (using the picospritz application technique) in voltage-clamp recorded SNc neurons evoked an outward current, similar to that observed after dopamine application. In the presence of sulpiride, 6 OHDA induced an inward current, consistent with the initial increase of firing activity observed in extracellular recordings. Microfluorometric experiments with Fura 2, showed that 6 OHDA evokes an increase in [Ca2+]i. Loading cells with the fluorescent dye Lucifer Yellow enabled visualization of 6 OHDA-induced swelling of the cell body and damage to proximal dendrites. Imaging of SNc neurons loaded with dextran-rhodamine revealed 6 OHDA-induced damage of distal dendrites. The last part of the study was performed on organotypic cultures obtained from slices of the ventral midbrain. These cultures were prepared from newborn transgenic mice expressing green fluorescent protein (GFP) under the tyrosine hydroxylase-promoter. This fluorescent marker enabled easy identification of dopamine-containing cells (including SNc neurons). Only preliminary experiments were carried out using this preparation. GFP-positive neurons did not show the classic membrane hyperpolarization in response to dopamine. For comparison, recordings from GFP-positive SNc neurons in acute slices obtained from age-matched animals did show a typical hyperpolarizing response to dopamine. GFP-neurons from organotypic cultures also lacked the Ih current – another characteristic feature of SNc neurons in vivo or in acute brain slices. In addition, atypical responses to CNQX (blocker of NMDA receptors) and baclofen (blocker of GABAB receptors) application were identified in GFP-positive neurons. These results demonstrate that the culturing process used in this study alters the functional ‘phenotype’ of dopaminergic neurons, a change which needs to be considered in future studies using this preparation. Chronic exposure of organotypic cultures to low concentration of rotenone (50 nM) evoked a delayed increase of PI labelling indicative of cell death, however technical limitations prevented detection of PI co-localization with GFP was observed. In conclusion, this study identified several key aspects of 6 OHDA and rotenone toxicity in SNc neurons. The most significant novel findings include evidence for ROS activation of KATP channels, presumed involvement of TRPM2 channels in rotenone-induced [Ca2+]i rise, and dopamine-analogous effects of 6 OHDA. The controversial role of KATP channels in neuroprotection was addressed. Findings from this study suggest therapies targeting this channel alone would be of little benefit. The proposed involvement of TRPM2 channels in rotenone-induced [Ca2+]i overload in SNc neurons is particularly interesting as it provides a mechanism for synergism between rotenone and other factors that disrupt [Ca2+]i homeostasis.

Parkinson's Disease

Neurotoxicity

Intracellular Calcium

Reactive Oxygen Species

Mitochondria

Electrophysiology

TRPM2

KATP

Effects of Rotenone and 6-OHDA on Dopaminergic Neurons of the Substantia Nigra Studied In Vitro

Freestone, Peter Stuart

January 2009

This study investigated the neurotoxic effects of rotenone and 6-hyroxydopamine (6 OHDA), two compounds which have been implicated in Parkinson’s disease (PD). PD is a neurodegenerative disorder that results in the impairment of movement. During the disease process, a group of dopamine-containing cells in the brain region called the Substantia Nigra pars compacta (SNc), degenerate. Whilst genetic factors contribute to approximately 5% of PD cases, the causes of the remaining 95% are unknown. What does seem clear is the pivotal role of mitochondrial dysfunction as observed in post-mortem human tissue. Mitochondrial dysfunction leads to energy depletion and the generation of harmful reactive oxygen species (ROS). However, despite the fact that the involvement of mitochondria in the disease process has been well established, the cellular events that lead to, and result from, mitochondrial dysfunction remain poorly understood. Rotenone and 6 OHDA have been implicated in PD for two reasons: (1) both toxins can relatively selectively kill SNc neurons in animal models of PD, and (2) there is evidence for both compounds having a potential causative role in the etiology of the disease in humans. When 6 OHDA is injected into the brain, or rotenone applied systemically, both toxins cause degeneration of SNc neurons. This ability makes them excellent tools for studying mechanisms of PD in animal models. In addition, both toxins inhibit mitochondrial function. Despite extensive use in models of PD, the mechanisms by which each toxin cause cell damage remains elusive. The first part of this study investigated the acute responses of dopaminergic SNc neurons to rotenone exposure (5 nM – 1 µM). The experiments were conducted on brain slices obtained from rats. Electrophysiological recordings (whole-cell patch-clamp technique) were used to detect activation of specific membrane channels as well as cell firing and changes to the membrane potential. In addition, imaging of several fluorescent dyes sensitive to specific cellular events was carried out. In voltage-clamp experiments, acute rotenone (200 nM – 1 µM) application evoked a concentration-dependent outward current which was mediated by tolbutamide-sensitive KATP channels. The current was associated with a drop in cell input resistance (Rm) and, in current-clamp, membrane hyperpolarization and inhibition of spontaneous action potentials. The mechanisms by which rotenone activates KATP channels is controversial, with some studies suggesting activation by ATP depletion and others by elevated reactive oxygen species (ROS). To address this issue, experiments were conducted with high levels of ATP in the pipette solution. Since the rotenone-induced outward current was unaffected by high ATP levels, it was concluded that KATP channel activation was due to oxidative stress. Indeed, the antioxidant Trolox significantly attenuated the current response. Confirmation of elevated ROS production was obtained by recording increased mitochondrial superoxide production, using the fluorescent dye MitoSOX. In addition, rotenone evoked depolarization of mitochondrial membrane potential (ΔΨm). Measurements of intracellular Ca2+ and Na+ were performed using the fluorescent dyes Fura 2 and SBFI, respectively. Rotenone evoked increases to both [Ca2+]i and [Na+]i in a concentration-dependent manner. The rotenone-induced [Ca2+]i rise was unaffected by blocking KATP channels with Cs+. The elevation of [Ca2+]i is particularly important in relation to cell death, since [Ca2+]i overload is known to activate pathways leading to necrosis and apoptosis. There has been growing interest in the synergistic action of rotenone with other toxins/conditions which also enhance [Ca2+]i. This concept was explored in the present study by testing the relationship between the baseline [Ca2+]i level and the rotenone-induced [Ca2+]i increase. Two approaches were taken. Firstly, baseline [Ca2+]i was deliberately raised by activation of voltage-gated calcium channels. When rotenone was applied in the presence of this raised baseline calcium level, the rotenone-induced [Ca2+]i rise was significantly greater. The second approach involved post-hoc analysis of the relationship between the normal cellular variation in baseline [Ca2+]i and the rotenone-induced [Ca2+]i elevation. This analysis also revealed a dependency of the rotenone-induced [Ca2+]i elevation on the baseline calcium level. From this finding, as well as the observation that rotenone evoked ROS production, Transient Receptor Protein subtype M2 (TRPM2) channels were proposed as the likely underlying mechanism. The potentiation of the rotenone-induced [Ca2+]i rise by an elevation in baseline calcium level can be attributed to the calcium-dependence of ROS-sensitive TRPM2 channels, known to respond with increased channel opening to increased [Ca2+]i. Recent findings from our laboratory have confirmed TRPM2 involvement in rotenone toxicity, since blockade of these channels with ACA reduced the rotenone-induced [Ca2+]i rise (K. Chung, unpublished). Imaging using the fluorescent dye propidium iodide (PI) to label cells with compromised membrane integrity was also conducted in acute midbrain slices. SNc neurons were retrograde-labelled with FluoroGold and then exposed to various toxic insults. The detergent Triton-X100 caused an increase in PI labelling, whilst rotenone and high concentrations of glutamate were ineffective over the period of time investigated (up to 40 min). The second part of this study, also conducted on acute rat midbrain slices, investigated the acute responses of SNc neurons to 6 OHDA (0.2 – 2 mM) exposure. Extracellular recordings of action potential firing were conducted on SNc neurons. 6 OHDA evoked rapid inhibition of firing in a similar manner to dopamine (100 µM). In the presence of D2 dopamine receptor blocker sulpiride, the inhibition of firing evoked by 6 OHDA was delayed, and an initial increase of firing was observed. Blockade of the dopamine transporter with nomifensine reduced the 6 OHDA-induced inhibition of firing, and prevented the persistent inhibition of firing after 6 OHDA washout. For comparison, the response to 6 OHDA of non-dopaminergic neurons in the subthalamic nucleus was also studied. In the subthalamic nucleus, 6 OHDA evoked an increase of spontaneous action potential firing. Rapid application of 6 OHDA (using the picospritz application technique) in voltage-clamp recorded SNc neurons evoked an outward current, similar to that observed after dopamine application. In the presence of sulpiride, 6 OHDA induced an inward current, consistent with the initial increase of firing activity observed in extracellular recordings. Microfluorometric experiments with Fura 2, showed that 6 OHDA evokes an increase in [Ca2+]i. Loading cells with the fluorescent dye Lucifer Yellow enabled visualization of 6 OHDA-induced swelling of the cell body and damage to proximal dendrites. Imaging of SNc neurons loaded with dextran-rhodamine revealed 6 OHDA-induced damage of distal dendrites. The last part of the study was performed on organotypic cultures obtained from slices of the ventral midbrain. These cultures were prepared from newborn transgenic mice expressing green fluorescent protein (GFP) under the tyrosine hydroxylase-promoter. This fluorescent marker enabled easy identification of dopamine-containing cells (including SNc neurons). Only preliminary experiments were carried out using this preparation. GFP-positive neurons did not show the classic membrane hyperpolarization in response to dopamine. For comparison, recordings from GFP-positive SNc neurons in acute slices obtained from age-matched animals did show a typical hyperpolarizing response to dopamine. GFP-neurons from organotypic cultures also lacked the Ih current – another characteristic feature of SNc neurons in vivo or in acute brain slices. In addition, atypical responses to CNQX (blocker of NMDA receptors) and baclofen (blocker of GABAB receptors) application were identified in GFP-positive neurons. These results demonstrate that the culturing process used in this study alters the functional ‘phenotype’ of dopaminergic neurons, a change which needs to be considered in future studies using this preparation. Chronic exposure of organotypic cultures to low concentration of rotenone (50 nM) evoked a delayed increase of PI labelling indicative of cell death, however technical limitations prevented detection of PI co-localization with GFP was observed. In conclusion, this study identified several key aspects of 6 OHDA and rotenone toxicity in SNc neurons. The most significant novel findings include evidence for ROS activation of KATP channels, presumed involvement of TRPM2 channels in rotenone-induced [Ca2+]i rise, and dopamine-analogous effects of 6 OHDA. The controversial role of KATP channels in neuroprotection was addressed. Findings from this study suggest therapies targeting this channel alone would be of little benefit. The proposed involvement of TRPM2 channels in rotenone-induced [Ca2+]i overload in SNc neurons is particularly interesting as it provides a mechanism for synergism between rotenone and other factors that disrupt [Ca2+]i homeostasis.

Parkinson's Disease

Neurotoxicity

Intracellular Calcium

Reactive Oxygen Species

Mitochondria

Electrophysiology

TRPM2

KATP

Cellular mechanisms affecting redox homeostasis in response to stress in Saccharomyces cerevisiae

Tan, Shixiong , Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Maintainence of appropriate redox homeostasis is crucial for processes such as protein folding in the endoplasmic reticulum (ER) and to minimise genesis of oxidative stress. Previous studies have indicated a possible link between ER stress and production of reactive oxygen species (ROS) although the cellular mechanisms involved were not fully elucidated. To investigate the cellular mechanisms involved in tolerance to oxidative stress and ER stress, genome-wide screens were performed to identify mutants sensitive to chronic ER stress induced by dithiothreitol and tunicamycin. These screens identified the Cu,Zn superoxide dismutase (SOD1) and genes involved in NADPH generation (RPE1, TKL1) as important for chronic ER stress tolerance. Superoxide anion has been identified as one of the ROS generated during ER stress. The ER oxidoreductase Ero1p, previously implicated in ROS production in vitro, did not appear to be a source of superoxide when the protein was over-expressed. It was also found that cellular NADP(H) levels affected induction of the unfolded protein response (UPR), since cells lacking TKL1 or RPE1 exhibited decreased UPR induction. These data indicate an important role for superoxide dismutase and cellular NADP(H) in survival of cells during ER stress. Subsequent analysis determined that NADPH generation was also required for adaptation to H2O2. Mutants affected in NADPH production were chronically sensitive to H2O2 but resistant to an acute dose. These mutants over-accumulated reduced glutathione (GSH) but maintained normal cellular redox homeostasis. This over- production of GSH was not regulated at the transcriptional level of GSH1 encoding ??- glutamyl cysteine synthetase. These data raise the important question as to how cells maintain cellular glutathione redox balance. To better understand how cells respond to perturbations in glutathione redox homeostasis, cells deleted for GLR1, encoding GSSG reductase, were exposed to extracellular oxidised glutathione (GSSG) and intracellular GSH and GSSG were monitored over time. Intriguingly cells lacking GLR1 showed increased levels of GSH accumulation upon GSSG treatment in a manner independent of GSH synthesis. It was subsequently found that the cytosolic thioredoxin-thioredoxin reductase system contributes to the reduction of GSSG in vivo.

Reactive oxygen species

Redox

Gluatathione

Endoplasmic reticulum

Unfolded protein response

Oxidative stress

Saccharomyces cerevisiae

NADPH

Thioredoxin

Superoxide dismutase

Activation of astrocytes involvement of NADPH oxidase and cytosolic phospholipase A2 /

Hu, Chunhua.

January 2007

Thesis (M.S.)--University of Missouri-Columbia, 2007. / "August 2007" The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Includes bibliographical references.

Identification and functional characterization of novel thioredoxin systems /

Damdimopoulos, Anastasios E.,

January 2003

Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 6 uppsatser.

Effect of high salt intake on arteriolar responses to metabolic stimuli

Marvar, Paul J.

January 2006

Thesis (Ph. D.)--West Virginia University, 2006. / Title from document title page. Document formatted into pages; contains xiv, 197 p. : ill. Vita. Includes abstract. Includes bibliographical references.

Μελέτη απόπτωσης και οξειδωτικού στρες σε κύτταρα μυελικής σειράς με διαταραγμένο φαινότυπο ασθενών με μυελοδυσπλαστικό σύνδρομο

Σκαρλάτος, Παράσχος

24 January 2011

Τα μυελοδυσπλαστικά σύνδρομα (ΜΔΣ) χαρακτηρίζονται από μη αποδοτική αιμοποίηση, αναστολή ωρίμανσης των προγονικών κυττάρων του μυελού και αυξημένη ενδομυελική απόπτωση. Η συσχέτιση του ΜΔΣ με την παρουσία αυξημένου οξειδωτικού στρες και οξειδωτικά τροποποιημένων πρωτεϊνών στα προγονικά αιμοποιητικά κύτταρα του μυελού έχει προηγουμένως αναφερθεί. Πρόσφατα βιβλιογραφικά δεδομένα δηλώνουν τη δυνατότητα διάκρισης δύο υποπληθυσμών της μυελικής σειράς βάσει σκεδαστικών χαρακτηριστικών και της έκφρασης του CD45, CD45dim (Neutrophil granulocytic subpopulation-1, NGS1) και CD45high (Neutrophil granulocytic subpopulation-2, NGS2). Ο υποπληθυσμός CD45dim φέρει άωρα κύτταρα, που στην πλειοψηφία τους δεν ωριμάζουν έως τελικού σταδίου[1]. Ο πλήρης χαρακτηρισμός των πληθυσμών αυτών, καθώς επίσης, και η συμμετοχή τους στη μη αποδοτική αιμοποίηση των ΜΔΣ και στην εξέλιξη της νόσου είναι στοιχεία άγνωστα. Σκοπός της παρούσης εργασίας ήταν η διερεύνηση δεικτών απόπτωσης και οξειδωτικού φορτίου (ελεύθερες ρίζες οξυγόνου-ROS) στους υποπληθυσμούς της μυελικής σειράς CD45dim και CD45high. Μελετήθηκαν 17 δείγματα μυελού ασθενών με ΜΔΣ μετά από ανάλυση συνδυασμού 5 χρωμάτων με κυτταρομετρία ροής, για τους δείκτες CD11b/CD16, annexin-V/7-AAD και 2,7-dichlorodihydrofluo-rescein-diacetate(DCF). Η στατιστική ανάλυση των αποτελεσμάτων πραγματοποιήθηκε με τη χρήση του κατάλληλου προγράμματος με μη παραμετρικά κριτήρια (Wilcoxon & Mann-Whitney). Το ποσοστό των αποπτωτικών 7-AAD/annexin-V+ κυττάρων ήταν σημαντικά αυξημένο στα CD45high/ CD11b+/CD16+ της μυελικής σειράς συγκριτικά με τα CD45dim/CD11b+/CD16- κύτταρα. Τα CD45dim και CD45high κύτταρα μυελού με τη χρήση του ειδικού ανιχνευτή των επιπέδων των ελεύθερων ριζών οξυγόνου DCF αναλύθηκαν σε ROSLow και ROSHigh πληθυσμούς. Η ανάλυση με τη χρήση των παραπάνω κριτηρίων έδειξε σημαντική αύξηση του ποσοστού των ROSHigh κυττάρων στα CD45high κύτταρα, συμπεραίνοντας έτσι ότι ο υποπληθυσμός CD45dim έχει χαμηλότερα επίπεδα ενδοκυττάριων ROS εν συγκρίσει με τον CD45high υποπληθυσμό. Ο CD45high υποπληθυσμός της μυελικής σειράς χαρακτηρίζεται από μεγαλύτερα ποσοστά έκφρασης αποπτωτικών δεικτών καθώς επίσης και από τη παρουσία αυξημένου οξειδωτικού φορτίου συγκριτικά με τα CD45dim κύτταρα. Η περεταίρω διερεύνηση του ρόλου των πληθυσμών αυτών στις διαδικασίες ανάπτυξης του ΜΔΣ και στην εξέλιξη της νόσου είναι υπό εξέλιξη. / --

Απόπτωση

Οξειδωτικό στρες

616.994 180 7

Reactive oxygen species (ROS)

Apoptosis

Myelodysplastic syndrome (MDS)

Oxidative stress

Crescimento e perfil oxidativo de juvenis de Rhamdia quelen alimentados com diferentes níveis de vitamina e (α-tocoferol) na dieta / Growth and oxidative profile of rhamdia quelen juveniles fed different levels of dietary vitamin e (α-tocopherol)

Uczay, Juliano

04 December 2013

The growth parameters, biochemical, and blood oxidative stress were evaluated in juvenile jundiás fed different levels of vitamin E (0, 200, 300 and 400 mg kg-1 in diet) after 60 days. At the end of the experiment, we observed improvements in growth variables: total length, standard, specific growth rate and condition factor, with the addition of vitamin E in the diet. The erythrocyte count was higher in diets containing vitamin E. The level of 400 mg kg-1 of vitamin E, decreased plasma triglyceride content and increased resistance of erythrocytes. Doses of 300 and 400 mg kg-1, reduced oxidative stress as oxidative biomarkers evaluated in the brain, liver, gills and muscle substances which thiobarbituric acid reactive substances (TBARS), lipid hydroperoxides (LOOH), superoxide dismutase (SOD), catalase (CAT), glutathione-S- transferase (GST) and the content of non-protein thiol groups (NPSH). Doses of vitamin E in the diet of juvenile catfishes above 300 mg kg-1 promotes improvements in growth parameters , and blood antioxidant system . / Os parâmetros de crescimento, bioquímicos, sanguíneos e de estresse oxidativo foram avaliados em juvenis de jundiás alimentados com diferentes níveis de vitamina E (0, 200, 300 e 400 mg kg-1 na dieta) após 60 dias. Ao final do experimento, observaram-se melhoras nas variáveis de crescimento: comprimento total, padrão, taxa de crescimento específico e fator de condição, com a adição de vitamina E na ração. A contagem de eritrócitos foi maior nas dietas contendo vitamina E. O nível 400 mg kg-1 de vitamina E, diminuiu o teor de triglicerídeos plasmáticos e aumentou a resistência dos eritrócitos. As doses de 300 e 400 mg kg-1, reduziram o estresse oxidativo conforme os biomarcadores oxidativos, avaliados no encéfalo, fígado, brânquias e músculo: substâncias que reagem ao ácido tiobarbitúrico (TBARS), hidroperóxidos lipídicos (LOOH), superóxido dismutase (SOD), catalase (CAT), glutationa-S-transferase (GST) e o conteúdo dos grupos tióis não proteicos (NPSH). Doses de vitamina E na dieta de juvenis de jundiás acima de 300 mg kg-1 promovem melhoras nos parâmetros de crescimento, sanguíneos e do sistema antioxidante.

Dano oxidativo

Nutrição

Espécies reativas de Oxigênio

Hematologia

Oxidative stress

Nutrition

Reactive oxygen species

Hematology

CNPQ::CIENCIAS AGRARIAS::ZOOTECNIA