Folding and Stability Studies on Amyotrophic Lateral Sclerosis-Associated apo Cu, Zn Superoxide dismutases

Vassall, Kenrick

January 2009

Amyotrophic lateral sclerosis (ALS) is a debilitating, incurable, neurodegenerative disease characterized by degradation of motor neurons leading to paralysis and ultimately death in ~3-5 years. Approximately 10% of ALS cases have a dominant inheritance pattern, termed familial ALS (fALS). Mutations in the gene encoding the dimeric superoxide scavenger Cu, Zn superoxide dismutase (SOD), were found to be associated with ~20% of fALS cases. Over 110 predominantly missense SOD mutations lead to fALS by an unknown mechanism; however, it is thought that mutant SOD acquires a toxic gain of function. Mice as well as human post mortem studies have identified mutant SOD-rich aggregates in affected neurons, leading to the hypothesis that mutations in SOD increase the tendency of the protein to form toxic aggregates. SOD has a complex maturation process whereby the protein is synthesized in an apo or demetalated state, followed by formation of an intramolecular disulfide bond and binding of Zn2+ and Cu2+. Each of these post-translational modifications increases the stability of the protein. SOD has been shown to aggregate more readily from destabilized immature states, including the apo state both with and without the disulfide bond, highlighting the importance of these states. Thermal unfolding monitored by differential scanning calorimetry (DSC) and chemical denaturation monitored by optical spectroscopy were used to elucidate the folding mechanism and stability of both the apo SOD disulfide-intact and disulfide-reduced states. Chemically and structurally diverse fALS-associated mutants were investigated to gain insights into why mutant SODs may be more prone to misfold and ultimately aggregate. The mutations were introduced into a pseudo wild-type (PWT) background lacking free cysteines, resulting in highly reversible unfolding amenable to accurate thermodynamic analysis. Similarly to what was previously described for fully metallated (holo) SODs, chemical denaturation of the apo disulfide-intact SODs is well described by a 3-state dimer mechanism with native dimer, monomeric intermediate and unfolded monomer populated at equilibrium. Although removal of metals has a relatively small effect on the stability of the dimer interface, the stability of the monomer intermediate is dramatically reduced. Thermal unfolding of some disulfide-intact apo SOD mutants as well as PWT is well described by a 2-state dimer mechanism, while others unfold via a 3-state mechanism similar to chemical denaturation. All but one of the studied disulfide-intact apo mutations are destabilizing as evidenced by reductions in ΔG of unfolding. Additionally, several mutants show an increased tendency to aggregate in thermal unfolding studies through increased ratios of van’t Hoff to calorimetric enthalpy (HvH/ Hcal ). The effects of the mutations on dimer interface stability in the apo disulfide-intact form were further investigated by isothermal titration calorimetry (ITC) which provided a quantitative measure of the dissociation constant of the dimer (Kd). ITC results revealed that disulfide-intact apo SOD mutants generally have increased Kd values and hence favor dimer dissociation to the less stable monomer which has been proposed to be a precursor to toxic aggregate formation. Reduction of the disulfide bond in apo SOD leads to marked destabilization of the dimer interface, and both thermal unfolding and chemical denaturation of PWT and mutants are well described by a 2-state monomer unfolding mechanism. Most mutations destabilize the disulfide-reduced apo SOD to such an extent that the population of unfolded monomer under physiological conditions exceeds 50%. The disulfide-reduced apo mutants show increased tendency to aggregate relative to PWT in DSC experiments through increased HvH /Hcal, low or negative change in heat capacity of unfolding and/or decreased unfolding reversibility. Further evidence of enhanced aggregation tendency of disulfide-reduced apo mutants was derived from analytical ultracentrifugation sedimentation equilibrium experiments that revealed the presence of weakly associated aggregates. Overall, the results presented here provide novel insights into SOD maturation and the possible impact of stability on aggregation.

Chemistry

Folding and Stability Studies on Amyotrophic Lateral Sclerosis-Associated apo Cu, Zn Superoxide dismutases

Vassall, Kenrick

January 2009

Amyotrophic lateral sclerosis (ALS) is a debilitating, incurable, neurodegenerative disease characterized by degradation of motor neurons leading to paralysis and ultimately death in ~3-5 years. Approximately 10% of ALS cases have a dominant inheritance pattern, termed familial ALS (fALS). Mutations in the gene encoding the dimeric superoxide scavenger Cu, Zn superoxide dismutase (SOD), were found to be associated with ~20% of fALS cases. Over 110 predominantly missense SOD mutations lead to fALS by an unknown mechanism; however, it is thought that mutant SOD acquires a toxic gain of function. Mice as well as human post mortem studies have identified mutant SOD-rich aggregates in affected neurons, leading to the hypothesis that mutations in SOD increase the tendency of the protein to form toxic aggregates. SOD has a complex maturation process whereby the protein is synthesized in an apo or demetalated state, followed by formation of an intramolecular disulfide bond and binding of Zn2+ and Cu2+. Each of these post-translational modifications increases the stability of the protein. SOD has been shown to aggregate more readily from destabilized immature states, including the apo state both with and without the disulfide bond, highlighting the importance of these states. Thermal unfolding monitored by differential scanning calorimetry (DSC) and chemical denaturation monitored by optical spectroscopy were used to elucidate the folding mechanism and stability of both the apo SOD disulfide-intact and disulfide-reduced states. Chemically and structurally diverse fALS-associated mutants were investigated to gain insights into why mutant SODs may be more prone to misfold and ultimately aggregate. The mutations were introduced into a pseudo wild-type (PWT) background lacking free cysteines, resulting in highly reversible unfolding amenable to accurate thermodynamic analysis. Similarly to what was previously described for fully metallated (holo) SODs, chemical denaturation of the apo disulfide-intact SODs is well described by a 3-state dimer mechanism with native dimer, monomeric intermediate and unfolded monomer populated at equilibrium. Although removal of metals has a relatively small effect on the stability of the dimer interface, the stability of the monomer intermediate is dramatically reduced. Thermal unfolding of some disulfide-intact apo SOD mutants as well as PWT is well described by a 2-state dimer mechanism, while others unfold via a 3-state mechanism similar to chemical denaturation. All but one of the studied disulfide-intact apo mutations are destabilizing as evidenced by reductions in ΔG of unfolding. Additionally, several mutants show an increased tendency to aggregate in thermal unfolding studies through increased ratios of van’t Hoff to calorimetric enthalpy (HvH/ Hcal ). The effects of the mutations on dimer interface stability in the apo disulfide-intact form were further investigated by isothermal titration calorimetry (ITC) which provided a quantitative measure of the dissociation constant of the dimer (Kd). ITC results revealed that disulfide-intact apo SOD mutants generally have increased Kd values and hence favor dimer dissociation to the less stable monomer which has been proposed to be a precursor to toxic aggregate formation. Reduction of the disulfide bond in apo SOD leads to marked destabilization of the dimer interface, and both thermal unfolding and chemical denaturation of PWT and mutants are well described by a 2-state monomer unfolding mechanism. Most mutations destabilize the disulfide-reduced apo SOD to such an extent that the population of unfolded monomer under physiological conditions exceeds 50%. The disulfide-reduced apo mutants show increased tendency to aggregate relative to PWT in DSC experiments through increased HvH /Hcal, low or negative change in heat capacity of unfolding and/or decreased unfolding reversibility. Further evidence of enhanced aggregation tendency of disulfide-reduced apo mutants was derived from analytical ultracentrifugation sedimentation equilibrium experiments that revealed the presence of weakly associated aggregates. Overall, the results presented here provide novel insights into SOD maturation and the possible impact of stability on aggregation.

Chemistry

Oxygen free radicals : mediators of vascular tone

Bharadwaj, Lalita Anne

01 January 1997

<i>In vivo</i> and <i>in vitro</i> studies on numerous types of blood vessels obtained from a variety of vascular beds and species have demonstrated that oxygen free radicals (OFRs) can evoke both vasodilation and vasoconstriction. Specific OFRs have been shown to elicit different and often times opposite effects on vascular smooth muscle. Therefore, this thesis attempts to define the vascular actions and mechanism of oxygen free radicals (OFRs) [superoxide anion (O₂^-), hydrogen peroxide (HO₂) and hydroxyl radical (OH)] on isolated rabbit aorta. This thesis will examine the role of OH in Ach- and nitroglycerin (NTG)-induced relaxation of isolated rabbit aorta. Superoxide anions generated by xanthine (X) plus xanthine oxidase (XO) produced concentration-dependent contractions of isolated rabbit aorta. The contractile response to O₂^- was completely abolished in preparations denuded of endothellum or pretreated with superoxide dismutase (SOD), a scavenger of O₂^-. The contractile response was reduced by indomethacin (I), a cyclooxygenase inhibitor. These results suggest that O₂^- mediated by vasoconstrictor arachidonic acid metabolites. Hydrogen peroxide generated by glucose and glucose oxidase produced contraction (low concentrations) and relaxation followed by contraction (high concentrations) in isolated rabbit aorta. The contractile response was abolished in the presence of catalase, a scavenger of H₂O₂ however the relaxant effect was exaggerated. Indomethacin markedly reduced the H₂O₂-induced contraction. Relaxation was completely prevented by de-endothelialization or pretreatment with N^G-monomethyl-L-arginine (LNMMA), an inhibitor of nitric oxide synthetase. These results suggest that H₂O₂ in large concentrations produces a biphasic response, relaxation followed by contraction. Relaxation is endothelium dependent and is mediated by endothelium-derived relaxing factor (EDRF), nitric oxide (NO). The contractile response is endothelium independent and is mediated by vasoconstrictor arachidonic acid metabolites of smooth muscle. Hydroxyl radicals generated by dihydroxyfumarate (DHF), ferric chloride (FeCl₃) and adenosine diphosphate (ADP) (DHF/FeCl₃-ADP) produced concentration dependent relaxations of NE-precontracted rabbit aorta. Mannitol (Ml) completely inhibited OH-induced relaxation. Relaxation was markedly reduced in aortic rings mechanically denuded of endothelium. The relaxant effect was reduced by an inhibitor of NO synthesis (LNMMA), by an inhibitor of guanylate cyclase (methylene blue), by an inhibitor of cyclooxygenase (indomethacin) and by an inhibitor of an ATP-sensitive K⁺ channel blocker (glyburide). These results indicate that OH produces relaxation that is endothelium-dependent and partially mediated by an endothelium-derived relaxing factor (NO), vasodilatory arachidonic acid metabolites and an ATP-sensitive K⁺ channel. We hypothesized that Ach-induced vascular relaxation is mediated by OH derived from the interaction of NO and O₂^-. To test this hypothesis we investigated the effect of Ach and NTG on NE-precontracted isolated rabbit aortic preparations in the absence or presence of scavengers of O₂^- (SOD), and OH (dimethylthiourea (DMTU) or mannitol or Garlicin). The OFR scavengers (SOD, dimethylthiourea, mannitol, garlicin and histidine) alone or the combination of SOD and DMTU markedly reduced Ach- or NTG-induced relaxation. However, the combination of histidine, (a ¹O₂ scavenger) SOD and DMTU completely abolished Ach-induced relaxation.

hydrogen peroxide

superoxide anion

vascular smooth muscle tone

oxygen free radicals

biochemistry

hydroxyl radical

Studies on the Chemical Constituents from the Formosan Corals Rumphella antipathies and Echionmuricea sp.

Chung, Hsu-Ming

14 February 2012

In the interest of identifying natural substances from marine invertebrates collected off the waters of Taiwan, we have searched the bioactive metabolites from the organic extracts of gorgonian corals Rumphella antipathies and Echinomuricea sp. This study had led to the isolation of thirty compounds (1¡V30), including nine new caryophyllane-related metabolites, rumphellaones A (1), B (2) and C (3), rumphelloic acids A (4) B (5) and C (6), rumphellolides J (7), K (8) and L (9), five new clovane-related metabolites, rumphellclovanes A (12), B (13), C (14), D (15) and E (16), two new disesquiterpenoid dimers, rumphelladimers A (24) and B (25), eight new natural products, (8R,9R)-isocaryolane-8,9-diol (10), 4£],8£]-epoxycaryophyllan-5-ol (11), 9£\-hydroxyclovan-2-one (17), 2£]-hydroxyclovan-9-one (18), clovan-2,9-dione (19), 2£]-acetoxyclovan-9£\-ol (20), 9£\-acetoxyclovan-2£]-ol (21) and 2£],9£]-dihydroxyclovane (22), along with a known compound, clovan-2£],9£\-diol (23) from Rumphella antipathies. In addition, three new labdane-, halimane-, and clerodane-related metabolites, echinolids A (26), B (27) and C (28), a new sesquiterpenoid natural product, (7S,10R)-(+)-10,11-epoxycurcuphenol (29), along with a known compound, (+)-curcuphenol (30) were also found in Echinomuricea sp. The structures of metabolites 1¡V30 were established by spectroscopic methods and by comparison of the spectral data with those of related known compounds. The absolute configurations of clovane-type compounds were determined using a modified Mosher¡¦s method for 23. The biosyntheses of compounds 1¡V5 and 12 were proposed. In the biological activity experiments, compounds 5 and 19 displayed significant inhibitory effects on superoxide anion generation and elastase release by human neutrophils in response to FMLP/CB. Compounds 24 and 27 displayed significant inhibitory effects on elastase release by human neutrophils. Compound 27 was found to exhibit inhibition against the growth of DLD-1 (human colon adenocarcinoma) and Lovo (human colorectal adenocarcinoma) tumor cells.

human colorectal adenocarcinoma

human colon adenocarcinoma

Echinomuricea sp.

superoxide anion generation

Rumphella antipathies

elastase release

Theoretical Studies of Structures and Mechanisms in Organometallic and Bioinorganic Chemistry: Heck Reaction with Palladium Phosphines, Active Sites of Superoxide Reductase and Cytochrome P450 Monooxygenase, and Tetrairon Hexathiolate Hydrogenase Model

Surawatanawong, Panida

2009 May 1900

The electronic structures and reaction mechanisms of transition-metal complexes can be calculated accurately by density functional theory (DFT) in cooperation with the continuum solvation model. The palladium catalyzed Heck reaction, iron-model complexes for cytochrome P450 and superoxide reductase (SOR), and tetrairon hexathiolate hydrogenase model were investigated. The DFT calculations on the catalytic Heck reaction (between phenyl-bromide and ethylene to form the styrene product), catalyzed by palladium diphosphine indicate a four-step mechanism: oxidative addition of C6H5Br, migratory insertion of C6H5 to C2H4, b-hydride transfer/olefin elimination of styrene product, and catalyst regeneration by removal of HBr. For the oxidative addition, the rate-determining step, the reaction through monophosphinopalladium complex is more favorable than that through either the diphosphinopalladium or ethylene-bound monophosphinopalladium. In further study, for a steric phosphine, PtBu3, the oxidative-addition barrier is lower on monopalladium monophosphine than dipalladium diphosphine whereas for a small phosphine, PMe3, the oxidative addition proceeds more easily via dipalladium diphosphine. Of the phosphine-free palladium complexes examined: free-Pd, PdBr-, and Pd(h2-C2H4), the olefin-coordinated intermediate has the lowest barrier for the oxidativeaddition. P450 and SOR have the same first-coordination-sphere, Fe[N4S], at their active sites but proceed through different reaction paths. The different ground spin states of the intermediate FeIII(OOH)(SCH3)(L) model {L = porphyrin for P450 and four imidazoles for SOR} produce geometric and electronic structures that assist i) the protonation on distal oxygen for P450, which leads to O-O bond cleavage and formation of (FeIV=O)(SCH3)(L) H2O, and ii) the protonation on proximal oxygen for SOR, which leads to (FeIII-HOOH)(SCH3)(L) formation before the Fe-O bond cleavage and H2O2 production. The hydrogen bonding from explicit waters also stabilizes FeIII-HOOH over FeIV=O H2O products in SOR. The electrochemical hydrogen production by Fe4[MeC(CH2S)3]2(CO)8 (1) with 2,6-dimethylpyridinium (LutH ) were studied by the DFT calculations of proton-transfer free energies relative to LutH and reduction potentials (vs. Fc/Fc ) of possible intermediates. In hydrogen production by 1, the second, more highly reductive, applied potential (-1.58 V) has the advantage over the first applied potential (-1.22 V) in that the more highly reduced intermediates can more easily add protons to produce H2.

Palladium

Heck reaction

Superoxide Reductase

Cytochrome P450

Hydrogenase

Density Functional Theory

Effect Of Cold Stress On Barley (hordeum Vulgare L.) Superoxide Dismutase Isozyme Activities And Expression Levels Of Cu/znsod Gene

Kayihan, Ceyhun

01 July 2007

In this study, effect of cold stress and recovery on the superoxide dismutase (SOD) activities and the expression levels of Cu/ZnSOD gene were investigated in two barley cultivars (Tarm-92-winter type, Zafer-160-spring type). Eight days old barley seedlings were subjected to two different cold stresses / chilling stress at 4&deg / C for 1, 3, 7 days and freezing stress at -3&deg / C and -7&deg / C. Analyses were performed both on leaf and root tissues. The SOD activities and isozyme patterns were determined by Native PAGE activity staining technique. Relative RT-PCR was used for the transcript levels of Cu/ZnSOD gene. The SOD activities and expression levels of control and cold stressed plants were compared by densitometric analysis. Under chilling stress, the activities of Cu/ZnSODx and Cu/ZnSOD2 did not have any significant change in leaf and root tissues of both cultivars. However, the expression levels of Cu/ZnSOD gene were more variable than activity results. After -3&deg / C freezing stress, the activities of SOD enzyme in leaf tissues of Tarm-92 increased significantly, however, these activities significantly decreased in leaves of Zafer-160. These results suggested that both cultivars were not affected by chilling stress in terms of SOD enzyme activities and expression levels. Furthermore, under freezing stress conditions, the increment of SOD activities and expression levels in Zafer-160 was higher than Tarm-92. In conclusion, the changes in SOD isozyme activities and expression levels may not be enough for understanding of the cold stress mechanism. Therefore, further studies have to be carried on other antioxidant enzyme systems.

Q General Science 1-385

Dysfunction of Mitochondrial Respiratory Chain in Rostral Ventrolateral Medulla During Experimental Endotoxemia

Chuang, Yao-Chung

08 January 2003

Dysfunction of Mitochondrial Respiratory Chain in Rostral Ventrolateral Medulla During Experimental Endotoxemia Sepsis is a complex pathophysiologic state resulting from an exaggerated whole-body inflammatory response to infection or injury. Metabolic disturbances, abnormal regulation of blood flow and diminished utilization of oxygen at the cellular level may account for tissue damage and lead to multiple organ failure and death. As the primary site of cellular energy generation is the mitochondrion, it presents itself as an important target for the septic cascade. In this regard, the notion that bioenergetic failure due to mitochondrial dysfunction contributes to organ failure during sepsis has received attention. We established the low frequency fluctuations in the systemic arterial pressure signals are related to the sympathetic neurogenic vasomotor tone, and reflect the functional integrity of the brain stem. Their origin is subsequently traced to the premotor sympathetic neurons at the rostral ventrolateral medulla (RVLM), whose neuronal activity is intimately related to the ¡§life-and-death¡¨ process. Based on a rat model of experimental endotoxemia that provides continuous information on changes in neuronal activity in the RVLM, the present study was undertaken to evaluate whether changes in mitochondrial respiratory functions are associated with death arising from sepsis. We also evaluated the efficacy of a new water-soluble coenzyme Q10 (CoQ10, ubiquinone) formula in the protection against fatality during endotoxemia by microinjection into bilateral RVLM. Dysfunction of Mitochondrial Respiratory Chain in Rostral Ventrolateral Medulla During Experimental Endotoxemia in the Rat We investigated the functional changes in mitochondrial respiratory chain at the RVLM in an experimental model of endotoxemia that mimics systemic inflammatory response syndrome. Experiments were carried out in adult male Sprague-Dawley rats that were maintained under propofol anesthesia. Intravenous administration of E. coli lipopolysaccharide (LPS; 30 mg/kg) induced progressive hypotension, with death ensued within 4 hours. The sequence of cardiovascular events during this LPS-induced endotoxemia can be divided into a reduction (Phase I), followed by an augmentation (Phase II; ¡§pro-life¡¨ phase) and a secondary decrease (Phase III; ¡§pro-death¡¨ phase) in the power density of the vasomotor components (0-0.8 Hz) of systemic arterial pressure (SAP) signals. Enzyme assay revealed significant decrease of the activity of NADH cytochrome c reductase (Complex I+III) and cytochrome c oxidase (Complex IV) in the RVLM during all 3 phases of endotoxemia. On the other hand, the activity of succinate cytochrome c reductase (Complex II+III) remained unaltered. Neuroprotective Effects of Coenzyme Q10 at Rostral ventrolateral Medulla Against Fatality During Experimental Endotoxemia in the Rat CoQ10 is a highly mobile electron carrier in the mitochondrial respiratory chain that also acts as an antioxidant. We evaluated the neuroprotective efficacy of CoQ10 against fatality in an experimental model of endotoxemia, using a novel water-soluble formulation of this quinone derivative. In Sprague-Dawley rats maintained under propofol anesthesia, intravenous administration of E. coli LPS (30 mg/kg) induced experimental endotoxemia. Pretreatment by microinjection bilaterally of CoQ10 (1 or 2 mg) into RVLM significantly diminished mortality, prolonged survival time, and reduced the slope or magnitude of the LPS-induced hypotension. CoQ10 pretreatment also significantly prolonged the duration of Phase II endotoxemia and augmented the total power density of the vasomotor components of SAP signals in Phase II endotoxemia. The increase in superoxide anion production induced by LPS at the RVLM during Phases II and III endotoxemia was also significantly blunted. Conclusion The present study revealed that selective dysfunction of respiratory enzyme Complexes I and IV in the mitochondrial respiratory chain at the RVLM is closely associated with fatal endotoxemia. CoQ10 provides neuroprotection against fatality during endotoxemia by acting on the RVLM. We further found that a reduction in superoxide anion produced during endotoxemia at the RVLM may be one of the mechanisms that underlie the elicited neuroprotection of CoQ10. These findings therefore open a new direction for future development of therapeutic strategy in this critical, complicated and highly fatal condition known as sepsis.

superoxide anion

rostral ventrolateral medulla

experimental endotoxemia

respiratory enzyme

coenzyme Q10

mitochondrial respiratory chain

neuroprotection

Localization and partial immunological characterization of Fasciola hepatica Thioredoxin

McKown, Richard Dwayne

17 February 2005

This study reports the localization and partial characterization of thioredoxin from the parasitic trematode Fasciola hepatica. Snails (Pseudosuccinia columella) were raised in culture and infected with F. hepatica so that Western blotting and immunohistochemical techniques could be utilized to determine the presence of thioredoxin in different stages of the parasite’s development. The results of these experiments showed that thioredoxin was present in the tegument, gut epithelium, excretory canal epithelium and sperm, of the adult parasite as well as in the tegument and gut of the redia and cercaria intermediate stages. In situ hybridization was used to determine the localization and possible differential mRNA expression of two different F. hepatica thioredoxin isotypes (Fh2020.A and Fh2020.SL) in the adult parasite. The in situ hybridization results showed that both isotypes are expressed in the tegument and gut epithelium. Fh2020.A stains with a greater intensity possibly demonstrating a difference in the amount of expression between the two isotypes. Recombinant F. hepatica thioredoxin expressed in bacteria using the pMAL™ Protein Fusion and Expression System was used to test its affects on the production of super oxide anion by murine peritoneal macrophages, bovine monocyte-derived macrophages and bovine whole blood neutrophils, and nitric oxide production by mouse peritoneal macrophages and bovine monocyte-derived macrophages. The results of the cellular assays were not definitive due to the fact that the maltose binding protein (MBP) moiety of the recombinant thioredoxin, when tested alone, increased production of nitric oxide by bovine monocyte-derived macrophages. Consequently, since the MBP could not be effectively separated from the thioredoxin portion of the recombinant, allowing the thioredoxin affects to be tested independently, no true conclusions regarding its affects on the host immune cells tested could be drawn. This is the first report of the localization of thioredoxin in both the adult F. hepatica as well as in specific intermediate stages of the parasite. These studies demonstrate the possible affects that a protein tag can have on experimental results and demonstrate how such data may be interpreted when a non-cleaved recombinant protein is used in cellular or other assays when compared to native or cleaved recombinant proteins.

thioredoxin

Fasciola hepatica

liver fluke

immunohistochemistry

in situ hybridization

nitric oxide

superoxide

IMPROVING SELF-RESCUE EQUIPMENT : Can a self-contained self-rescue unit be more comfortable to wear over long periods of time, not damage other equipment and be donned easily?

Sandström, Anders

January 2015

A self-contained self-rescue unit is a device that is used in the mining industry in case of fires or release of toxic gases that depletes or contaminates breathable oxygen in the surrounding atmosphere. These units are the first line of defense by providing oxygen in a closed breathing cycle, allowing personnel to get themselves to safety. The goal of this project was to design a unit that is more comfortable to carry during the daily operations in and outside the mines. A unit that is easier to done and less likely to damage the users and/or surrounding mining equipment. It is developed in close collaboration with Atlas Copco, as the main sponsor, as well as Dräger and personnel working at Zink Gruvan Mining.  The result is a unit with an operational time of twenty minutes and a reduced size and weight. It’s position can be adjusted to be worn around the waist or the chest, depending on the tasks the user performs, as well as simplifying the donning procedure.

Mining

Self-Rescue

Emergency

Evacuation

Breathing

Rebreather

Potassium Superoxide

SCSR

Mining industry

Mining equipment

The effect of elevated glutathione reductase and superoxide dismutase activities in stressed transgenic tobacco.

Penter, Mark Gavin.

January 1996

Life as we know it would be impossible in the absence of oxygen. However, too much oxygen can be toxic to the aerobic organisms which depend on it for their very existence. This apparent paradox arises as a result of oxygen's ability to accept electrons, forming highly reactive (reduced) oxygen species such as superoxide, hydrogen peroxide and the hydroxyl radical. The toxicity of oxygen is greatly enhanced in illuminated plants, due to the photosynthetic reactions which produce both oxygen and highly energetic electrons in close proximity to one another. These problems are further exacerbated when plants are exposed to a variety of stress conditions, since these conditions reduce the ability of plants to utilise excess electrons. As a result of the danger posed by· these reactive oxygen species, plants have· evolved a complex antioxidant system for their scavenging. Research has shown that plants with naturally elevated levels of the components of the antioxidant system are better equipped to deal with stress conditions which enhance the production of reactive oxygen species. A considerable amount of research has thus been dedicated to the elucidation of the antioxidant system. Almost as much research has been dedicated to enhancing the antioxidant system, with the aim of improving plant productivity under stress conditions. This study sought to evaluate plants carrying elevated levels of two of the enzymes of the antioxidant system. For these purposes, tobacco was transformed with the gene for E. coli glutathione reductase (GR), an enzyme believed to catalyse the rate limiting reaction in the scavenging of hydrogen peroxide. This gene was fused to the gene for the RUBISCO small subunit transit peptide - a peptide capable of targeting proteins to the chloroplast. Due to the presence of this peptide the transformed plants exhibited high chloroplastic levels of GR activity. These plants were crossed with a second tobacco transformant carrying high levels of chloroplastic tomato superoxide dismutase (SOD) - an enzyme responsible for the scavenging of superoxide. These hybrid plants were shown to exhibit high GR and SOD activities in the chloroplast .- the subcellular compartment most susceptible to damage caused by reactive oxygen species. The transgenic hybrids were evaluated for their ability to tolerate oxidative stress by treating them with paraquat - a herbicide whose mode of action involves the production of large quantities of activated oxygen. Under stress conditions, plants carrying just E. coli GR showed a slight improvement in their ability to deal with oxidative stress. In contrast to this, the SOD transformants showed more cellular damage than untransformed control plants. This was attributed to the inability of other enzymes in the antioxidant pathway to deal with the increased flow of metabolites through the pathway. The hybrid transformants showed enhanced stress tolerance in the initial stages of oxidative stress, but this declined with ongoing exposure to stress conditions. As with the SOD transformants, this decline in protection was . ascribed to the relatively low activities of the other enzymes in the antioxidant pathway. It was concluded that elevated levels of the two enzymes conferred greater stress tolerance than just one of the enzymes, but for true stress tolerance it will be necessary to evaluate the antioxidant system and enhance the activity of further enzymes in the pathway. It may also be necessary to improve the regulation of transgene expression, ensuring that none of the enzymes are overwhelmed by the increased flow of metabolites through the system. / Thesis (M.Sc.)-University of Natal, 1996

Glutathione.

Tobacco.

Antioxidants.

Escherichia Coli.

Nicotiana tabacum.

Superoxide dismutase

Theses--Botany.