Studies on phosphine toxicity and resistance mechanisms in Caenorhabditis elegans

Qiang Cheng

Unknown Date

Phosphine, hydrogen phosphide (PH3), gas is a fumigant that is used worldwide to protect stored grain from infestation by insect pests. Despite a long history of phosphine use, little is known about either the mode of action of this compound or the mechanisms whereby insect pests have become resistant. To better understand phosphine toxicity and resistance mechanisms, a genetically well-characterised model organism, Caenorhabditis elegans, was used in my PhD project. Three previously created phosphine resistant C. elegans mutants (pre-1, pre-7 and pre-33) developed from the wild type N2 strain were used in this study, though analysis of pre-33 was the primary focus. The three mutants were determined to be 2, 5 and 9 times more resistant toward phosphine than was the parental N2 strain by comparison of LC50 values. Molecular oxygen was shown to be an extremely effective synergist with phosphine as, under hyperoxic conditions, 100% mortality was observed in wild-type nematodes exposed to 0.1 mg/l phosphine, a non-lethal concentration in air. All three mutants were resistant to the synergistic effects of oxygen in proportion to their resistance to phosphine with one mutant, pre-33, showing complete resistance to this synergism. I take the proportionality of cross-resistance between phosphine and the synergistic effect of oxygen to imply that all three mutants circumvent a mechanism of phosphine toxicity that is directly coupled to oxygen metabolism. Compared with the wild-type strain, each of the three mutants has an extended average life expectancy of 12.5 to 25.3%. This is consistent with the proposed involvement of oxidative stress in both phosphine toxicity and ageing. Indeed, a correlation between phosphine resistance and resistance to other stressors (e.g. heavy metal, heat and UV) was also detected. On the other hand, no significant difference in methyl viologen sensitivity was found between pre-33 and N2 strains, suggesting that pre-33 mutant does not seem to provide resistance to phosphine via protection against oxidative damage. Additionally, to test for possible involvement of the DAF-2/DAF-16 signalling pathway in the phosphine response, the levels of phosphine sensitivity of mutants in this pathway were tested. Phosphine resistance levels were increased in daf-2 and age-1 mutants but decreased in daf-16 nematodes, which mirrors the longevity phenotypes of these mutants, suggesting some congruence in glucose signalling between the phosphine resistance and longevity traits. In contrast, no congruence is observed between phosphine resistance and oxidative metabolism as the clk-mutation, which disrupts oxidative metabolism does not cause phosphine resistance and neither do the phosphine resistant mutants cause the severe developmental delay of the clk-1 mutation. The phosphine induced time-dependent mortality was assessed in both N2 and pre-33 nematodes at two fixed phosphine concentrations (0.3 and 3.0 mg/l), allowing the determination of minimum exposure periods required for any mortality as well as the exposure time required to achieve 50% mortality. As a result, it was determined that 15 hours of exposure was needed for significant mortality in N2 and pre-33 strain when exposed to 0.3 and 3.0 mg/l of phosphine, respectively; whereas this period is 5 hours for N2 when treated with 3.0 mg/l phosphine. The fact that the LT50 value for N2 at 0.3 mg/l phosphine is indistinguishable from that of pre-33 at 3.0 mg/l (24.6 and 24.5 respectively) suggests that 0.3 and 3.0 mg/l of phosphine have the same toxic effects on N2 and pre-33 nematodes respectively. This result is consistent with the finding that pre-33 is ~9 fold more resistant to phosphine than is the N2 strain. Moreover, the LT50 was determined to be 8.4 hours for N2 when treated with 3.0 mg/l of phosphine, which is only three times faster than pre-33 when exposed to the same level of phosphine. In contrast to the differential toxicity of phosphine between the N2 and pre-33 lines, the delay in reaching reproductive maturity caused by phosphine exposure is indistinguishable between WT and pre-33 nematodes. This indicates that the phosphine induced delay in maturation is independent of the toxic effects of phosphine. Since the inhibition of complex IV (cytochrome c oxidase) in the mitochondrial electron transport chain has been proposed as a mechanism of phosphine toxicity, the phosphine effects on cellular ATP metabolism, presented as ATP+ADP content and ATP/ADP ratio, were also assessed. Phosphine exposure (0.3 mg/l, 25 hours) led to a significant decrease in ATP+ADP levels as well as the ATP/ADP ratio in N2 nematodes. Similar results were also detected in pre-33 nematodes when exposed to 3.0 mg/l phosphine for 25 hours. These observations indicate that phosphine can interrupt cellular ATP metabolism, which is associated with phosphine induced mortality. Additionally, the fact that mutant pre-33 can maintain its ATP levels under phosphine exposure at 0.3 mg/l suggests it has a greater ability to maintain mitochondrial function than does the N2 strain. To better understand the mechanism of phosphine toxicity in the wild type N2 strain, gene expression profiling by DNA microarray analysis was employed. A significant overlap between phosphine and DAF-16 regulated genes was detected, supporting the previous finding that the DAF-2/DAF-16 pathway can contribute to phosphine resistance. Phosphine exposure also strongly induced xenobiotic detoxification and stress responses, indicating nematodes are able to sense phosphine induced toxic effects and protect themselves by switching on native detoxification mechanisms. Furthermore, glycolysis and gluconeogenesis were also up-regulated by phosphine, possibly due to an increase in energy demand caused by increased xenobiotic detoxification activities. Consistent with the previous findings that phosphine delays median reproductive age and reduces fertility, expressions of a large number of genes involved in growth, embryonic development and reproduction were suppressed by phosphine. Moreover, the microarray results of seven genes whose expression levels were significantly altered by phosphine were validated using RT-PCR, confirming the robustness of the microarray results. The most direct way to determine the phosphine resistance mechanism in mutant pre-33 is to identify and characterise the mutation itself. Using a classic F1 test, the resistance mutation in pre-33 was determined to be incompletely recessive. Additionally, using three mapping strategies, the resistance mutation was mapped to Chromosome IV between 12,591,683 and 12,879,637 bp with 45 genes located in this small region. In an attempt to identify the resistance gene, the effect of suppressing each of 28 of the 45 genes in the interval was determined using a commercially available gene suppression library. It was observed that only knockdown of gene vha-7 resulted in a slight decrease in phosphine sensitivity (84.6%) compared to N2 (97.6%). However, this result does not clearly implicate vha-7 as the resistance gene in pre-33. The microarray results indicated that linoleate and arachidonate signalling pathways might be activated by phosphine. This was observed as induction of a phospholipase A2 gene that regulates the release of arachidonic acid from the C-2 position of membrane phospholipids, as well as several CYP genes predicted to catalyse the oxidation of linoleate and arachidonate. Therefore, phosphine effects on the linoleate and arachidonate dependent signalling pathways were assessed. It was found that, in the presence of phosphine, the pre-33 mutant has a greater ability to transform linoleate and arachidonate epoxides to diols than does N2. This activity may help pre-33 to better maintain mitochondrial function and, therefore, ATP metabolism than N2 during phosphine exposure. The microarray results also showed that phosphine exposure caused up-regulation of glycolysis and gluconeogenesis, indicating phosphine regulation of carbohydrate metabolism. As expected, a preliminary metabonomic analysis by 1H nuclear magnetic resonance (NMR) into the effect of phosphine exposure on metabolism in N2 nematodes revealed significant alteration of the metabonomic profile.

Oxidative Stress

Longevity

Microarray

Metabonomics

Mitochondria

ATP metabolism

Studies on phosphine toxicity and resistance mechanisms in Caenorhabditis elegans

Qiang Cheng

Unknown Date

Phosphine, hydrogen phosphide (PH3), gas is a fumigant that is used worldwide to protect stored grain from infestation by insect pests. Despite a long history of phosphine use, little is known about either the mode of action of this compound or the mechanisms whereby insect pests have become resistant. To better understand phosphine toxicity and resistance mechanisms, a genetically well-characterised model organism, Caenorhabditis elegans, was used in my PhD project. Three previously created phosphine resistant C. elegans mutants (pre-1, pre-7 and pre-33) developed from the wild type N2 strain were used in this study, though analysis of pre-33 was the primary focus. The three mutants were determined to be 2, 5 and 9 times more resistant toward phosphine than was the parental N2 strain by comparison of LC50 values. Molecular oxygen was shown to be an extremely effective synergist with phosphine as, under hyperoxic conditions, 100% mortality was observed in wild-type nematodes exposed to 0.1 mg/l phosphine, a non-lethal concentration in air. All three mutants were resistant to the synergistic effects of oxygen in proportion to their resistance to phosphine with one mutant, pre-33, showing complete resistance to this synergism. I take the proportionality of cross-resistance between phosphine and the synergistic effect of oxygen to imply that all three mutants circumvent a mechanism of phosphine toxicity that is directly coupled to oxygen metabolism. Compared with the wild-type strain, each of the three mutants has an extended average life expectancy of 12.5 to 25.3%. This is consistent with the proposed involvement of oxidative stress in both phosphine toxicity and ageing. Indeed, a correlation between phosphine resistance and resistance to other stressors (e.g. heavy metal, heat and UV) was also detected. On the other hand, no significant difference in methyl viologen sensitivity was found between pre-33 and N2 strains, suggesting that pre-33 mutant does not seem to provide resistance to phosphine via protection against oxidative damage. Additionally, to test for possible involvement of the DAF-2/DAF-16 signalling pathway in the phosphine response, the levels of phosphine sensitivity of mutants in this pathway were tested. Phosphine resistance levels were increased in daf-2 and age-1 mutants but decreased in daf-16 nematodes, which mirrors the longevity phenotypes of these mutants, suggesting some congruence in glucose signalling between the phosphine resistance and longevity traits. In contrast, no congruence is observed between phosphine resistance and oxidative metabolism as the clk-mutation, which disrupts oxidative metabolism does not cause phosphine resistance and neither do the phosphine resistant mutants cause the severe developmental delay of the clk-1 mutation. The phosphine induced time-dependent mortality was assessed in both N2 and pre-33 nematodes at two fixed phosphine concentrations (0.3 and 3.0 mg/l), allowing the determination of minimum exposure periods required for any mortality as well as the exposure time required to achieve 50% mortality. As a result, it was determined that 15 hours of exposure was needed for significant mortality in N2 and pre-33 strain when exposed to 0.3 and 3.0 mg/l of phosphine, respectively; whereas this period is 5 hours for N2 when treated with 3.0 mg/l phosphine. The fact that the LT50 value for N2 at 0.3 mg/l phosphine is indistinguishable from that of pre-33 at 3.0 mg/l (24.6 and 24.5 respectively) suggests that 0.3 and 3.0 mg/l of phosphine have the same toxic effects on N2 and pre-33 nematodes respectively. This result is consistent with the finding that pre-33 is ~9 fold more resistant to phosphine than is the N2 strain. Moreover, the LT50 was determined to be 8.4 hours for N2 when treated with 3.0 mg/l of phosphine, which is only three times faster than pre-33 when exposed to the same level of phosphine. In contrast to the differential toxicity of phosphine between the N2 and pre-33 lines, the delay in reaching reproductive maturity caused by phosphine exposure is indistinguishable between WT and pre-33 nematodes. This indicates that the phosphine induced delay in maturation is independent of the toxic effects of phosphine. Since the inhibition of complex IV (cytochrome c oxidase) in the mitochondrial electron transport chain has been proposed as a mechanism of phosphine toxicity, the phosphine effects on cellular ATP metabolism, presented as ATP+ADP content and ATP/ADP ratio, were also assessed. Phosphine exposure (0.3 mg/l, 25 hours) led to a significant decrease in ATP+ADP levels as well as the ATP/ADP ratio in N2 nematodes. Similar results were also detected in pre-33 nematodes when exposed to 3.0 mg/l phosphine for 25 hours. These observations indicate that phosphine can interrupt cellular ATP metabolism, which is associated with phosphine induced mortality. Additionally, the fact that mutant pre-33 can maintain its ATP levels under phosphine exposure at 0.3 mg/l suggests it has a greater ability to maintain mitochondrial function than does the N2 strain. To better understand the mechanism of phosphine toxicity in the wild type N2 strain, gene expression profiling by DNA microarray analysis was employed. A significant overlap between phosphine and DAF-16 regulated genes was detected, supporting the previous finding that the DAF-2/DAF-16 pathway can contribute to phosphine resistance. Phosphine exposure also strongly induced xenobiotic detoxification and stress responses, indicating nematodes are able to sense phosphine induced toxic effects and protect themselves by switching on native detoxification mechanisms. Furthermore, glycolysis and gluconeogenesis were also up-regulated by phosphine, possibly due to an increase in energy demand caused by increased xenobiotic detoxification activities. Consistent with the previous findings that phosphine delays median reproductive age and reduces fertility, expressions of a large number of genes involved in growth, embryonic development and reproduction were suppressed by phosphine. Moreover, the microarray results of seven genes whose expression levels were significantly altered by phosphine were validated using RT-PCR, confirming the robustness of the microarray results. The most direct way to determine the phosphine resistance mechanism in mutant pre-33 is to identify and characterise the mutation itself. Using a classic F1 test, the resistance mutation in pre-33 was determined to be incompletely recessive. Additionally, using three mapping strategies, the resistance mutation was mapped to Chromosome IV between 12,591,683 and 12,879,637 bp with 45 genes located in this small region. In an attempt to identify the resistance gene, the effect of suppressing each of 28 of the 45 genes in the interval was determined using a commercially available gene suppression library. It was observed that only knockdown of gene vha-7 resulted in a slight decrease in phosphine sensitivity (84.6%) compared to N2 (97.6%). However, this result does not clearly implicate vha-7 as the resistance gene in pre-33. The microarray results indicated that linoleate and arachidonate signalling pathways might be activated by phosphine. This was observed as induction of a phospholipase A2 gene that regulates the release of arachidonic acid from the C-2 position of membrane phospholipids, as well as several CYP genes predicted to catalyse the oxidation of linoleate and arachidonate. Therefore, phosphine effects on the linoleate and arachidonate dependent signalling pathways were assessed. It was found that, in the presence of phosphine, the pre-33 mutant has a greater ability to transform linoleate and arachidonate epoxides to diols than does N2. This activity may help pre-33 to better maintain mitochondrial function and, therefore, ATP metabolism than N2 during phosphine exposure. The microarray results also showed that phosphine exposure caused up-regulation of glycolysis and gluconeogenesis, indicating phosphine regulation of carbohydrate metabolism. As expected, a preliminary metabonomic analysis by 1H nuclear magnetic resonance (NMR) into the effect of phosphine exposure on metabolism in N2 nematodes revealed significant alteration of the metabonomic profile.

Oxidative Stress

Longevity

Microarray

Metabonomics

Mitochondria

ATP metabolism

Studies on phosphine toxicity and resistance mechanisms in Caenorhabditis elegans

Qiang Cheng

Unknown Date

Phosphine, hydrogen phosphide (PH3), gas is a fumigant that is used worldwide to protect stored grain from infestation by insect pests. Despite a long history of phosphine use, little is known about either the mode of action of this compound or the mechanisms whereby insect pests have become resistant. To better understand phosphine toxicity and resistance mechanisms, a genetically well-characterised model organism, Caenorhabditis elegans, was used in my PhD project. Three previously created phosphine resistant C. elegans mutants (pre-1, pre-7 and pre-33) developed from the wild type N2 strain were used in this study, though analysis of pre-33 was the primary focus. The three mutants were determined to be 2, 5 and 9 times more resistant toward phosphine than was the parental N2 strain by comparison of LC50 values. Molecular oxygen was shown to be an extremely effective synergist with phosphine as, under hyperoxic conditions, 100% mortality was observed in wild-type nematodes exposed to 0.1 mg/l phosphine, a non-lethal concentration in air. All three mutants were resistant to the synergistic effects of oxygen in proportion to their resistance to phosphine with one mutant, pre-33, showing complete resistance to this synergism. I take the proportionality of cross-resistance between phosphine and the synergistic effect of oxygen to imply that all three mutants circumvent a mechanism of phosphine toxicity that is directly coupled to oxygen metabolism. Compared with the wild-type strain, each of the three mutants has an extended average life expectancy of 12.5 to 25.3%. This is consistent with the proposed involvement of oxidative stress in both phosphine toxicity and ageing. Indeed, a correlation between phosphine resistance and resistance to other stressors (e.g. heavy metal, heat and UV) was also detected. On the other hand, no significant difference in methyl viologen sensitivity was found between pre-33 and N2 strains, suggesting that pre-33 mutant does not seem to provide resistance to phosphine via protection against oxidative damage. Additionally, to test for possible involvement of the DAF-2/DAF-16 signalling pathway in the phosphine response, the levels of phosphine sensitivity of mutants in this pathway were tested. Phosphine resistance levels were increased in daf-2 and age-1 mutants but decreased in daf-16 nematodes, which mirrors the longevity phenotypes of these mutants, suggesting some congruence in glucose signalling between the phosphine resistance and longevity traits. In contrast, no congruence is observed between phosphine resistance and oxidative metabolism as the clk-mutation, which disrupts oxidative metabolism does not cause phosphine resistance and neither do the phosphine resistant mutants cause the severe developmental delay of the clk-1 mutation. The phosphine induced time-dependent mortality was assessed in both N2 and pre-33 nematodes at two fixed phosphine concentrations (0.3 and 3.0 mg/l), allowing the determination of minimum exposure periods required for any mortality as well as the exposure time required to achieve 50% mortality. As a result, it was determined that 15 hours of exposure was needed for significant mortality in N2 and pre-33 strain when exposed to 0.3 and 3.0 mg/l of phosphine, respectively; whereas this period is 5 hours for N2 when treated with 3.0 mg/l phosphine. The fact that the LT50 value for N2 at 0.3 mg/l phosphine is indistinguishable from that of pre-33 at 3.0 mg/l (24.6 and 24.5 respectively) suggests that 0.3 and 3.0 mg/l of phosphine have the same toxic effects on N2 and pre-33 nematodes respectively. This result is consistent with the finding that pre-33 is ~9 fold more resistant to phosphine than is the N2 strain. Moreover, the LT50 was determined to be 8.4 hours for N2 when treated with 3.0 mg/l of phosphine, which is only three times faster than pre-33 when exposed to the same level of phosphine. In contrast to the differential toxicity of phosphine between the N2 and pre-33 lines, the delay in reaching reproductive maturity caused by phosphine exposure is indistinguishable between WT and pre-33 nematodes. This indicates that the phosphine induced delay in maturation is independent of the toxic effects of phosphine. Since the inhibition of complex IV (cytochrome c oxidase) in the mitochondrial electron transport chain has been proposed as a mechanism of phosphine toxicity, the phosphine effects on cellular ATP metabolism, presented as ATP+ADP content and ATP/ADP ratio, were also assessed. Phosphine exposure (0.3 mg/l, 25 hours) led to a significant decrease in ATP+ADP levels as well as the ATP/ADP ratio in N2 nematodes. Similar results were also detected in pre-33 nematodes when exposed to 3.0 mg/l phosphine for 25 hours. These observations indicate that phosphine can interrupt cellular ATP metabolism, which is associated with phosphine induced mortality. Additionally, the fact that mutant pre-33 can maintain its ATP levels under phosphine exposure at 0.3 mg/l suggests it has a greater ability to maintain mitochondrial function than does the N2 strain. To better understand the mechanism of phosphine toxicity in the wild type N2 strain, gene expression profiling by DNA microarray analysis was employed. A significant overlap between phosphine and DAF-16 regulated genes was detected, supporting the previous finding that the DAF-2/DAF-16 pathway can contribute to phosphine resistance. Phosphine exposure also strongly induced xenobiotic detoxification and stress responses, indicating nematodes are able to sense phosphine induced toxic effects and protect themselves by switching on native detoxification mechanisms. Furthermore, glycolysis and gluconeogenesis were also up-regulated by phosphine, possibly due to an increase in energy demand caused by increased xenobiotic detoxification activities. Consistent with the previous findings that phosphine delays median reproductive age and reduces fertility, expressions of a large number of genes involved in growth, embryonic development and reproduction were suppressed by phosphine. Moreover, the microarray results of seven genes whose expression levels were significantly altered by phosphine were validated using RT-PCR, confirming the robustness of the microarray results. The most direct way to determine the phosphine resistance mechanism in mutant pre-33 is to identify and characterise the mutation itself. Using a classic F1 test, the resistance mutation in pre-33 was determined to be incompletely recessive. Additionally, using three mapping strategies, the resistance mutation was mapped to Chromosome IV between 12,591,683 and 12,879,637 bp with 45 genes located in this small region. In an attempt to identify the resistance gene, the effect of suppressing each of 28 of the 45 genes in the interval was determined using a commercially available gene suppression library. It was observed that only knockdown of gene vha-7 resulted in a slight decrease in phosphine sensitivity (84.6%) compared to N2 (97.6%). However, this result does not clearly implicate vha-7 as the resistance gene in pre-33. The microarray results indicated that linoleate and arachidonate signalling pathways might be activated by phosphine. This was observed as induction of a phospholipase A2 gene that regulates the release of arachidonic acid from the C-2 position of membrane phospholipids, as well as several CYP genes predicted to catalyse the oxidation of linoleate and arachidonate. Therefore, phosphine effects on the linoleate and arachidonate dependent signalling pathways were assessed. It was found that, in the presence of phosphine, the pre-33 mutant has a greater ability to transform linoleate and arachidonate epoxides to diols than does N2. This activity may help pre-33 to better maintain mitochondrial function and, therefore, ATP metabolism than N2 during phosphine exposure. The microarray results also showed that phosphine exposure caused up-regulation of glycolysis and gluconeogenesis, indicating phosphine regulation of carbohydrate metabolism. As expected, a preliminary metabonomic analysis by 1H nuclear magnetic resonance (NMR) into the effect of phosphine exposure on metabolism in N2 nematodes revealed significant alteration of the metabonomic profile.

Oxidative Stress

Longevity

Microarray

Metabonomics

Mitochondria

ATP metabolism

Physiology of Chilling-Related Postharvest Rind Breakdown of Navel Oranges (Citrus Sinensis (L.) Osbeck)

Lindhout, Katina, Lynette.Brown@latrobe.edu.au

January 2007

Chilling-related postharvest rind breakdown of navel oranges is a significant economic problem worldwide. Chilling injury (CI) symptoms on navel orange fruit vary, and descriptive classification is generally ad hoc, making inter-study comparisons difficult. In this study, external symptoms of CI were related to patterns of cellular collapse in affected flavedo tissue, and a classification system developed to aid consistent symptom identification and improve communication within the supply chain. Potential markers of senescence were evaluated because older fruit were found to be more susceptible to CI. Electrolyte leakage, moisture content and protein content of flavedo tissue were ineffective indicators of both senescence and chilling stress. Rind colour and internal maturity were generally good indicators of fruit age, but lacked sensitivity over short time periods to be of use. Although there was a strong seasonal effect on CI incidence, pre-storage treatments, including hot water and methyl jasmonate, generally reduced the incidence of CI. Because these treatments elicit defence responses that protect tissue from chilling stress, the response and efficiency of plant defence systems is probably an important factor in chilling tolerance. The concentration of lipid hydroperoxides (LOOH) in flavedo tissue was lower in fruit that were stored at a chilling temperature (1�C) compared to fruit that were stored at a non-chilling temperature (12�C) and lipid peroxidation did not increase during storage at 1�C. There was also a lower concentration of LOOH in the chilling sensitive variety than in the chilling tolerant variety. Therefore, increased lipid peroxidation is not related to chilling stress and subsequent injury but the results do suggest a role for LOOH in stress signalling. Antioxidant activity in the lipophilic fraction of flavedo tissue extracts increased as fruit senesced and was strongly correlated with carotenoid content. LOOH concentrations in flavedo tissue also increased as fruit senesced. The antioxidant activity of both the lipophilic and hydrophilic fractions of flavedo tissue extracts was higher in fruit stored at 12�C than in fruit stored at 1�C.

Citrus

cold storage

temperature stress

cross-tolerance

oxidation

oxidative stress.

Effect of Bcl-2 on the cellular response to oxidative stress

Cox, Andrew Graham

January 2006

Exposure of cells to hydrogen peroxide can cause oxidative damage to cellular constituents including lipids, protein, and DNA. At elevated concentrations, hydrogen peroxide can trigger cell death by apoptosis or necrosis. Apoptotic cell death can be prevented by overexpression of the oncoprotein Bcl-2. The exact mechanism by which Bcl-2 blocks cell death is controversial. Some researchers believe that Bcl-2 possesses antioxidant properties that protect cells from apoptosis. The purpose of this thesis was to assess oxidative stress and apoptosis following hydrogen peroxide exposure in Jurkat T cells overexpressing Bcl-2. One of the major objectives was to ascertain whether or not Bcl-2 overexpression elevated the antioxidant capacity of Jurkat T cells to provide protection from oxidant-induced cell death. Hydrogen peroxide treated Jurkat cells became apoptotic at moderate levels of oxidant (25-100 uM H2O2), and necrotic at higher doses (greater than 200 uM H2O2). Bcl-2 overexpression prevented caspase activation and cell death at the apoptotic doses of H2O2, but not the necrotic doses. Caspase inhibition studies demonstrated that Bcl-2 overexpression provided a greater level of resistance from H2O2-induced cell death than the broad-spectrum caspase inhibitor z-VAD.fmk. A systematic study was carried out examining the antioxidant status of Jurkat cells overexpressing Bcl-2. Several Bcl-2 transfectants were utilised for the study, so that any differences seen could be correlated to the level of Bcl-2 expression. Surprisingly, there were no statistically significant differences among the Bcl-2 transfectants for any of the antioxidant enzymes. Jurkat cells overexpressing Bcl-2 exhibited the same level of oxidative damage to lipids and protein in response to H2O2 exposure as the parental Jurkat cells. Interestingly, Jurkat cells overexpressing Bcl-2 continued to grow in culture after H2O2 exposure, despite harboring damage to cellular constituents. Consistent with these results, H2O2 treated Jurkat cells overexpressing Bcl-2, which failed to undergo apoptosis, were more prone to genomic instability. Together, these findings suggest that Bcl-2 overexpression protects Jurkat cells from H2O2-induced cell death by blocking apoptosis. Jurkat cells overexpressing Bcl-2 were no better at detoxifying oxidants and showed the same level of oxidative damage following H2O2 exposure. As a result, the overexpression of Bcl-2 considerably enhanced the mutagenicity of H2O2.

Bcl-2

antioxidant

oxidative stress

apoptosis

genomic instability

Investigation of zeolite systems focus on Fenton chemistry oxidative stress from asbestos like minerals and zeolite-based dissolved oxygen sensing /

Ruda, Toni Ann,

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 207-225).

Exercise-induced muscle damage and immune cell apoptosis

Park, Kyung-Shin.

January 2006

Thesis (Ph. D.)--Purdue University, 2006. / Includes bibliographical references (leaves 89-113). Also available online (PDF file) by a subscription to the set or by purchasing the individual file.

Exercise-induced muscle damage and immune cell apoptosis

Park, Kyung-Shin.

January 2006

Thesis (Ph. D.)--Purdue University, 2006. / Includes bibliographical references (leaves 89-113).

Development of an oxidatively-releasable caged biosensor system and application to the release of antioxidants and fluorescent probes /

Trumbull, Kari Adele,

January 2007

Thesis (Ph. D.)--University of Oregon, 2007. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 137-158). Also available for download via the World Wide Web; free to University of Oregon users.

Oxidative stress and aging processes in transgenic growth hormone mice

Lemon, Jennifer. Rollo, C. David.

January 2005

Thesis (Ph.D.)--McMaster University, 2005. / Supervisor: C.D. Rollo and D.R. Boreham. Includes bibliographical references.