Line 154: | Line 154: | ||
Hydroxyl radicals are highly reactive and react with almost every molecule. Since it is highly reactive, its reaction rate is limited by diffusion. The reactivity of hydroxyl radicals derives from its high standard electrode potential (+2.3 V). Therefore, it is able to oxidize almost any molecule other than ozone (Zhang <i>et al.</i>, 2018).</br> | Hydroxyl radicals are highly reactive and react with almost every molecule. Since it is highly reactive, its reaction rate is limited by diffusion. The reactivity of hydroxyl radicals derives from its high standard electrode potential (+2.3 V). Therefore, it is able to oxidize almost any molecule other than ozone (Zhang <i>et al.</i>, 2018).</br> | ||
There are several origins for the different types of ROS: Superoxide anion is formed by autoxidation of distinct dehydrogenases and certain reductases, e.g. glutathione reductase. Non-enzymatic production is achieved by autoxidation of certain cellular components such as ubiquinols. Hydrogen peroxidase derives from several oxidases and the superoxide dismutase. UV radiation breaks it down into hydroxyl radicals (Mignolet-Spruyt <i>et al.</i>, 2016). Other mechanisms for the generation of hydroxyl radicals are the Fenton and/or Haber-Weiss reaction (Fagali <i>et al.</i>, 2015; Kehrer, 2000).</br> | There are several origins for the different types of ROS: Superoxide anion is formed by autoxidation of distinct dehydrogenases and certain reductases, e.g. glutathione reductase. Non-enzymatic production is achieved by autoxidation of certain cellular components such as ubiquinols. Hydrogen peroxidase derives from several oxidases and the superoxide dismutase. UV radiation breaks it down into hydroxyl radicals (Mignolet-Spruyt <i>et al.</i>, 2016). Other mechanisms for the generation of hydroxyl radicals are the Fenton and/or Haber-Weiss reaction (Fagali <i>et al.</i>, 2015; Kehrer, 2000).</br> | ||
− | + | ||
Haber-Weiss: Fe<sup>3+</sup> + •O<sub>2</sub><sup>-</sup> → Fe<sup>2+</sup> + O<sub>2</sub></br> | Haber-Weiss: Fe<sup>3+</sup> + •O<sub>2</sub><sup>-</sup> → Fe<sup>2+</sup> + O<sub>2</sub></br> | ||
Fenton: Fe<sup>2+</sup> + H<sub>2</sub>O<sub>2</sub> → Fe<sup>3+</sup> + OH<sup>-</sup> + •OH</br> | Fenton: Fe<sup>2+</sup> + H<sub>2</sub>O<sub>2</sub> → Fe<sup>3+</sup> + OH<sup>-</sup> + •OH</br> | ||
− | + | ||
In order to neutralize the ROS and repair the occurred damage bacteria have different mechanisms they can rely on. Two types of superoxide dismutase (SOD) dismutate O2- into H<sub>2</sub>O<sub>2</sub>: MnSOD and FeSOD (encoded by <i>sodA</i> and <i>sodB</i>) (Broxton & Culotta, 2016). Catalases (encoded by <i>katE</i> and <i>katG</i>) are able to disproportionate H<sub>2</sub>O<sub>2</sub> into the nontoxic components H<sub>2</sub>O and O<sub>2</sub> (Chaithawiwat <i>et al.</i>, 2016). Further detoxification is achieved by the alkyl hydroperoxide reductase Ahp (encoded by <i>ahpC</i> and <i>ahpF</i>) which scavenges various free organic hydroperoxides (Kamariah <i>et al.</i>, 2016). These genes are in <i>E. coli</i> under the control of various global regulators such as OxyR and SoxR. The regulators also promote the expression of genes involved in the repair of the damaged cell membranes, DNA and proteins and are activated by a conformational change induced by oxidative stress (Dubbs & Mongkolsuk, 2016; Seo <i>et al.</i>, 2015). Furthermore, the tripeptide glutathione plays a vital role in the detoxification of the cell regarding the decomposition of radicals to deal with oxidative stress. The enzymes encoded by <i>gshA</i> and <i>gshB</i> are responsible for the synthesis of glutathione. However, the crucial part in fighting oxidative stress via glutathione is executed by the glutathione peroxidase BtuE, encoded by <i>btuE</i>, and the glutathione reductase GSR, encoded by <i>gor</i>. BtuE uses glutathione as a reducing agent to scavenge hydrogen peroxide and peroxide radicals.</br> | In order to neutralize the ROS and repair the occurred damage bacteria have different mechanisms they can rely on. Two types of superoxide dismutase (SOD) dismutate O2- into H<sub>2</sub>O<sub>2</sub>: MnSOD and FeSOD (encoded by <i>sodA</i> and <i>sodB</i>) (Broxton & Culotta, 2016). Catalases (encoded by <i>katE</i> and <i>katG</i>) are able to disproportionate H<sub>2</sub>O<sub>2</sub> into the nontoxic components H<sub>2</sub>O and O<sub>2</sub> (Chaithawiwat <i>et al.</i>, 2016). Further detoxification is achieved by the alkyl hydroperoxide reductase Ahp (encoded by <i>ahpC</i> and <i>ahpF</i>) which scavenges various free organic hydroperoxides (Kamariah <i>et al.</i>, 2016). These genes are in <i>E. coli</i> under the control of various global regulators such as OxyR and SoxR. The regulators also promote the expression of genes involved in the repair of the damaged cell membranes, DNA and proteins and are activated by a conformational change induced by oxidative stress (Dubbs & Mongkolsuk, 2016; Seo <i>et al.</i>, 2015). Furthermore, the tripeptide glutathione plays a vital role in the detoxification of the cell regarding the decomposition of radicals to deal with oxidative stress. The enzymes encoded by <i>gshA</i> and <i>gshB</i> are responsible for the synthesis of glutathione. However, the crucial part in fighting oxidative stress via glutathione is executed by the glutathione peroxidase BtuE, encoded by <i>btuE</i>, and the glutathione reductase GSR, encoded by <i>gor</i>. BtuE uses glutathione as a reducing agent to scavenge hydrogen peroxide and peroxide radicals.</br> | ||
− | + | ROOH + 2GSH → ROH + GSSG + H<sub>2</sub>O</br> | |
− | GSR then recovers the used glutathione by reducing the generated glutathione disulfide under the consumption of NADPH. The phytochelatin synthase (PCS) or also called glutathione gamma-glutamylcysteinyltransferase catalyzes the reaction to form phytochelatin out of the precursor glutathione in plants and fungi (Grill <i>et al.</i>, 1989). The enzyme transfers γ-Glu-Cys moieties of glutathione to glutathione or (γ-Glu-Cys)n-Gly.<img src="https://static.igem.org/mediawiki/parts/ | + | GSR then recovers the used glutathione by reducing the generated glutathione disulfide under the consumption of NADPH. The phytochelatin synthase (PCS) or also called glutathione gamma-glutamylcysteinyltransferase catalyzes the reaction to form phytochelatin out of the precursor glutathione in plants and fungi (Grill <i>et al.</i>, 1989). The enzyme transfers γ-Glu-Cys moieties of glutathione to glutathione or (γ-Glu-Cys)n-Gly.<img src="https://static.igem.org/mediawiki/parts/f/f6/T--Bielefeld-CeBiTec--Reaction_mechanismPhySyn_MO.png" width="40%" height="100" style="float:left;"/> The product of this enzyme reaction are the peptides (γ-Glu-Cys)n+1-Gly with n=2-10. This enzyme plays an important role in the metal detoxification process. It has been found out that PCS is activated by heavy metal ions such as cadmium and copper in <i>Arabidopsis thaliana</i> cells (Heiss <i>et al.</i>, 2003). Therefore, this enzyme helps <i>E. coli</i> to bear with the toxicity of the imported copper ions.<img src="https://static.igem.org/mediawiki/parts/8/80/T--Bielefeld-CeBiTec--PhySynFunctioning_MO.png" width="40%" height="100" style="float:left;"/></br> |
In order to increase the cell’s resistance to oxidative stress a sophisticated approach is needed. An overexpression of the oxidative stress dependent regulators SoxR and OxyR should improve the cell’s ability to cope with an elevated number of ROS. Various combinations of the defense mechanisms are tested in order to determine the ideal defense against oxidative stress in order to maximize the longevity in presence of heavy metals. Agents like phytochelatin which are rich in cysteine and/or histidine residues are meant to bind free metal ions to lower the potential for Fenton and/or Haber-Weiss reactions. | In order to increase the cell’s resistance to oxidative stress a sophisticated approach is needed. An overexpression of the oxidative stress dependent regulators SoxR and OxyR should improve the cell’s ability to cope with an elevated number of ROS. Various combinations of the defense mechanisms are tested in order to determine the ideal defense against oxidative stress in order to maximize the longevity in presence of heavy metals. Agents like phytochelatin which are rich in cysteine and/or histidine residues are meant to bind free metal ions to lower the potential for Fenton and/or Haber-Weiss reactions. | ||
</article> | </article> |
Revision as of 19:06, 17 October 2018
Toxicity
Gold
Silver
Copper
Iron
Reactive oxygen species
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Alum, A., Alboloushi, A., & Abbaszadegan, M. (2018). Copper nanoparticles toxicity: Laboratory strains verses environmental bacterial isolates. Journal of Environmental Science and Health, Part A, 1-8.
Bi, D.Q., Xu, Y.M. (2012). Influence of iron oxide doping on the photocatalytic degradation of organic dye X3B over tungsten oxide. Acta Physico-Chimica Sinica, 28, 1777-1782.
Bortner, C. D., Cidlowski, J. A. (2007). Cell shrinkage and monovalent cation fluxes: role in apoptosis. Archives of Biochemistry and Biophysics, 462(2), 176-188.
Broxton, C. N., & Culotta, V. C. (2016). SOD enzymes and microbial pathogens: surviving the oxidative storm of infection. PLoS pathogens, 12(1), e1005295.
Brust, M., Fink, J., Bethell, D., Schiffrin, D. J., & Kiely, C. (1995). Synthesis and reactions of functionalised gold nanoparticles. Journal of the Chemical Society, Chemical Communications, (16), 1655-1656.
Burgess, J. E., Quarmby, J., & Stephenson, T. (1999). Role of micronutrients in activated sludge-based biotreatment of industrial effluents. Biotechnology advances, 17(1), 49-70.
Caruntu D, Remond Y, Chou NH, Jun M-J, Caruntu G, He J, Goloverda G, O'Connor C, Kolesnichenko V (2002). Reactivity of 3d transition metal cations in diethylene glycol solutions. Synthesis of transition metal ferrites with the structure of discrete nanoparticles complexed with long-chain carboxylate anions. Inorganic chemistry, 41(23), 6137-6146.
Chaithawiwat, K., Vangnai, A., McEvoy, J. M., Pruess, B., Krajangpan, S., & Khan, E. (2016). Role of oxidative stress in inactivation of Escherichia coli BW25113 by nanoscale zero-valent iron. Science of the Total Environment, 565, 857-862.
Cioffi, N., Torsi, L., Ditaranto, N., Tantillo, G., Ghibelli, L., Sabbatini, L., Bleve-Zacheo, T., D’Alessio, M., Zambonin, P.G., Traversa, E. (2005). Copper nanoparticle/polymer composites with antifungal and bacteriostatic properties. Chemistry of Materials, 17(21), 5255-5262.
Chang, M. L., Chen, J. C., Yeh, C. T., Chang, M. Y., Liang, C. K., Chiu, C. T., Lin D.Y., Liaw, Y. F. (2008). Gene gun bombardment with DNA-coated gold particles is a potential alternative to hydrodynamics-based transfection for delivering genes into superficial hepatocytes. Human gene therapy, 19(4), 391-395.
Colman, B. P., Arnaout, C. L., Anciaux, S., Gunsch, C. K., Hochella Jr, M. F., Kim, B., Lowry, G.V., McGill, B.M., Reinsch, B.C., Richardson, C.J., Unrine, J. M., Wright, J.P., Yin, L., Bernhardt, E.S. (2013). Low concentrations of silver nanoparticles in biosolids cause adverse ecosystem responses under realistic field scenario. PLoS One, 8(2), e57189.
Dubbs, J. M., & Mongkolsuk, S. (2016). Peroxide‐Sensing Transcriptional Regulators in Bacteria. Stress and Environmental Regulation of Gene Expression and Adaptation in Bacteria, 587-602.
Eid, R., Arab, N.T.T., Greenwood, M.T. (2017). Iron mediated toxicity and programmed cell death: A review and a re-examination of existing paradigms. Biochimica et Biophysica Acta (BBA) - Molecular Cell Research, 1864(2), 399-430.
Fagali, N. S., Grillo, C. A., Puntarulo, S., & Lorenzo, M. A. F. (2015). Biodegradation of metallic biomaterials: its relation with the generation of reactive oxygen species. REACTIVE OXYGEN SPECIES, LIPID PEROXIDATION AND PROTEIN OXIDATION, 127.
Farr, S. B., Kogoma, T. (1991). Oxidative Stress Responses in Escherichia coli and Salmonella typhimurium. Microbiological Reviews, 55(4), 561-585.
Halliwell, B. (1991). Reactive oxygen species in living systems: Source, biochemistry, and role in human disease. The American Journal of Medicine, 91(3), S14-S22.
Halliwell, B. (2007). Biochemistry of oxidative stress. Biochem Soc Trans, 35(5), 1147-1150.
Halliwell, B., & Gutteridge, J. M. (2015). Free radicals in biology and medicine. Oxford University Press, USA.
Holleman, A. F.; Wiberg, N. (2001). Inorganic Chemistry. San Diego: Academic Press.
Huang, Q., Cao, M.H., Ai, Z.H., Zhang, L.Z. (2015). Reactive oxygen species dependent degradation pathway of 4-chlorophenol with Fe@Fe2O3 core-shell nanowires. Appl Catal B-Environ, 162, 319-326.
Hwang, E. T., Lee, J. H., Chae, Y. J., Kim, Y. S., Kim, B. C., Sang, B. I., & Gu, M. B. (2008). Analysis of the toxic mode of action of silver nanoparticles using stress‐specific bioluminescent bacteria. Small, 4(6), 746-750.
Ivask, A., ElBadawy, A., Kaweeteerawat, C., Boren, D., Fischer, H., Ji, Z., Chang, C.H., Liu, R., Tolaymat, T., Telesca, D., Zink, J. I., Cohen, Y., Holden, P.A., Godwin, H.A., (2013). Toxicity mechanisms in Escherichia coli vary for silver nanoparticles and differ from ionic silver. Acs Nano, 8(1), 374-386.
Kamariah, N., Nartey, W., Eisenhaber, B., Eisenhaber, F., & Grüber, G. (2016). Low resolution solution structure of an enzymatic active AhpC10: AhpF2 ensemble of the Escherichia coli Alkyl hydroperoxide Reductase. Journal of structural biology, 193(1), 13-22.
Kaplan, J. H., & Lutsenko, S. (2009). Copper transport in mammalian cells: special care for a metal with special needs. Journal of Biological Chemistry, 284(38), 25461-25465.
Kehrer, J.P. (2000). The Haber-Weiss reaction and mechanisms of toxicity. Toxicology, 149, 43-50.
Kim, J.S., Kuk, E., Yu, K.N., Kim, J.H., Park, S.J., Lee, H.J., Kim, S.H., Park, Y.K., Park, Y.H., Hwang, C.Y., Kim, Y.K., Lee, Y.S., Jeong, D.H., Cho, M.H., (2007). Antimicrobial effects of silver nanoparticles. Nanomedicine: Nanotechnology, Biology, and Medicine, 3, 95-101.
Letelier, M. E., Sánchez-Jofré, S., Peredo-Silva, L., Cortés-Troncoso, J., & Aracena-Parks, P. (2010). Mechanisms underlying iron and copper ions toxicity in biological systems: Pro-oxidant activity and protein-binding effects. Chemico-biological interactions, 188(1), 220-227.
Li, F., Lei, C., Shen, Q., Li, L., Wang, M., Guo, M., Huang, Y., Nie, Z., Yao, S. (2013). Analysis of copper nanoparticles toxicity based on a stress-responsive bacterial biosensor array. Nanoscale, 5(2), 653-662.
Liu, L., Wu, D., Zhao, B., Han, X., Wu, J., Hou, H., & Fan, Y. (2015). Copper (II) coordination polymers: tunable structures and a different activation effect of hydrogen peroxide for the degradation of methyl orange under visible light irradiation. Dalton Transactions, 44(3), 1406-1411.
Magner, L.N. (1992). In: Hippocrates and the Hippocratic Tradition. A History of Medicine. Duffy J, editor. Marcel Dekker, Inc; NYC: 1992. p. 393.
Masoud, R., Bizouarn, T., Trepout, S., Wien, F., Baciou, L., Marco, S., & Levin, C. H. (2015). Titanium dioxide nanoparticles increase superoxide anion production by acting on NADPH oxidase. PloS one, 10(12), e0144829.
Mignolet-Spruyt, L., Xu, E., Idänheimo, N., Hoeberichts, F. A., Mühlenbock, P., Brosché, M. & Kangasjärvi, J. (2016). Spreading the news: subcellular and organellar reactive oxygen species production and signalling. Journal of Experimental Botany, 67(13), 3831-3844.
Morones-Ramirez, J. R., Winkler, J. A., Spina, C. S., & Collins, J. J. (2013). Silver enhances antibiotic activity against gram-negative bacteria. Science translational medicine, 5(190), 190ra81-190ra81.
Ochoa-Herrera, V., León, G., Banihani, Q., Field, J. A., Sierra-Alvarez, R. (2011). Toxicity of copper (II) ions to microorganisms in biological wastewater treatment systems. Science of the total environment, 412, 380-385.
Seo, S. W., Kim, D., Szubin, R., & Palsson, B. O. (2015). Genome-wide reconstruction of OxyR and SoxRS transcriptional regulatory networks under oxidative stress in Escherichia coli K-12 MG1655. Cell Reports, 12(8), 1289-1299.
Shareena Dasari, TP, Zhang, Y, Yu, H (2015). Antibacterial Activity and Cytotoxicity of Gold (I) and (III) Ions and Gold Nanoparticles. Biochem Pharmacol (Los Angel) 4(6), 199.
Wang, X., Gu, Y., Johnson, D., Chen, C., Huang, Y. (2017). The toxicity and DNA-damage mechanism of α-Fe2O3 nanoparticles. Medicinal chemistry Research, 26(2), 384-389.
Winterbourn, C.C. (1995). Toxicity of iron and hydrogen peroxide: the Fenton reaction. Toxicol. Lett., 82-83, 969-974.
Witkiewicz, P. L., & Shaw, C. F. (1981). Oxidative cleavage of peptide and protein disulphide bonds by gold (III): a mechanism for gold toxicity. Journal of the Chemical Society, Chemical Communications, (21), 1111-1114.
Yaeger C.C. (1991). Copper and zinc preservatives. In S.S. Block (ed.), Disinfection, sterilization, and preservation. 4th edn, Lea & Fiebiger Press, Philadelphia, USA, 358-361.
Yun, J., Lee, D.G. (2017). Silver Nanoparticles: A Novel Antimicrobial Agent. Antimicrobial Nanoarchitectonics, 139-166.
Zhang, C. (2014). Essential functions of iron-requiring proteins in DNA replication, repair and cell cycle control. Protein Cell, 5, 750-760.
Zhang, Y., Newton, B., Lewis, E., Fu, P. P., Kafoury, R., Ray, P. C., & Yu, H. (2015). Cytotoxicity of organic surface coating agents used for nanoparticles synthesis and stability. Toxicology in Vitro, 29(4), 762-768.
Zhang, H., Jiang, X., Cao, G., Zhang, X., Croley, T. R., Wu, X., & Yin, J. J. (2018). Effects of noble metal nanoparticles on the hydroxyl radical scavenging ability of dietary antioxidants. Journal of Environmental Science and Health, Part C, 36(2), 84-97.
Zhao, G, Stevens, SE Jr. (1998). Multiple parameters for the comprehensive evaluation of the susceptibility of Escherichia coli to the silver ion. BioMetals 11(1), 27-32.
Alum, A., Alboloushi, A., & Abbaszadegan, M. (2018). Copper nanoparticles toxicity: Laboratory strains verses environmental bacterial isolates. Journal of Environmental Science and Health, Part A, 1-8.
Bi, D.Q., Xu, Y.M. (2012). Influence of iron oxide doping on the photocatalytic degradation of organic dye X3B over tungsten oxide. Acta Physico-Chimica Sinica, 28, 1777-1782.
Bortner, C. D., Cidlowski, J. A. (2007). Cell shrinkage and monovalent cation fluxes: role in apoptosis. Archives of Biochemistry and Biophysics, 462(2), 176-188.
Broxton, C. N., & Culotta, V. C. (2016). SOD enzymes and microbial pathogens: surviving the oxidative storm of infection. PLoS pathogens, 12(1), e1005295.
Brust, M., Fink, J., Bethell, D., Schiffrin, D. J., & Kiely, C. (1995). Synthesis and reactions of functionalised gold nanoparticles. Journal of the Chemical Society, Chemical Communications, (16), 1655-1656.
Burgess, J. E., Quarmby, J., & Stephenson, T. (1999). Role of micronutrients in activated sludge-based biotreatment of industrial effluents. Biotechnology advances, 17(1), 49-70.
Caruntu D, Remond Y, Chou NH, Jun M-J, Caruntu G, He J, Goloverda G, O'Connor C, Kolesnichenko V (2002). Reactivity of 3d transition metal cations in diethylene glycol solutions. Synthesis of transition metal ferrites with the structure of discrete nanoparticles complexed with long-chain carboxylate anions. Inorganic chemistry, 41(23), 6137-6146.
Chaithawiwat, K., Vangnai, A., McEvoy, J. M., Pruess, B., Krajangpan, S., & Khan, E. (2016). Role of oxidative stress in inactivation of Escherichia coli BW25113 by nanoscale zero-valent iron. Science of the Total Environment, 565, 857-862.
Cioffi, N., Torsi, L., Ditaranto, N., Tantillo, G., Ghibelli, L., Sabbatini, L., Bleve-Zacheo, T., D’Alessio, M., Zambonin, P.G., Traversa, E. (2005). Copper nanoparticle/polymer composites with antifungal and bacteriostatic properties. Chemistry of Materials, 17(21), 5255-5262.
Chang, M. L., Chen, J. C., Yeh, C. T., Chang, M. Y., Liang, C. K., Chiu, C. T., Lin D.Y., Liaw, Y. F. (2008). Gene gun bombardment with DNA-coated gold particles is a potential alternative to hydrodynamics-based transfection for delivering genes into superficial hepatocytes. Human gene therapy, 19(4), 391-395.
Colman, B. P., Arnaout, C. L., Anciaux, S., Gunsch, C. K., Hochella Jr, M. F., Kim, B., Lowry, G.V., McGill, B.M., Reinsch, B.C., Richardson, C.J., Unrine, J. M., Wright, J.P., Yin, L., Bernhardt, E.S. (2013). Low concentrations of silver nanoparticles in biosolids cause adverse ecosystem responses under realistic field scenario. PLoS One, 8(2), e57189.
Dubbs, J. M., & Mongkolsuk, S. (2016). Peroxide‐Sensing Transcriptional Regulators in Bacteria. Stress and Environmental Regulation of Gene Expression and Adaptation in Bacteria, 587-602.
Eid, R., Arab, N.T.T., Greenwood, M.T. (2017). Iron mediated toxicity and programmed cell death: A review and a re-examination of existing paradigms. Biochimica et Biophysica Acta (BBA) - Molecular Cell Research, 1864(2), 399-430.
Fagali, N. S., Grillo, C. A., Puntarulo, S., & Lorenzo, M. A. F. (2015). Biodegradation of metallic biomaterials: its relation with the generation of reactive oxygen species. REACTIVE OXYGEN SPECIES, LIPID PEROXIDATION AND PROTEIN OXIDATION, 127.
Farr, S. B., Kogoma, T. (1991). Oxidative Stress Responses in Escherichia coli and Salmonella typhimurium. Microbiological Reviews, 55(4), 561-585.
Halliwell, B. (1991). Reactive oxygen species in living systems: Source, biochemistry, and role in human disease. The American Journal of Medicine, 91(3), S14-S22.
Halliwell, B. (2007). Biochemistry of oxidative stress. Biochem Soc Trans, 35(5), 1147-1150.
Halliwell, B., & Gutteridge, J. M. (2015). Free radicals in biology and medicine. Oxford University Press, USA.
Holleman, A. F.; Wiberg, N. (2001). Inorganic Chemistry. San Diego: Academic Press.
Huang, Q., Cao, M.H., Ai, Z.H., Zhang, L.Z. (2015). Reactive oxygen species dependent degradation pathway of 4-chlorophenol with Fe@Fe2O3 core-shell nanowires. Appl Catal B-Environ, 162, 319-326.
Hwang, E. T., Lee, J. H., Chae, Y. J., Kim, Y. S., Kim, B. C., Sang, B. I., & Gu, M. B. (2008). Analysis of the toxic mode of action of silver nanoparticles using stress‐specific bioluminescent bacteria. Small, 4(6), 746-750.
Ivask, A., ElBadawy, A., Kaweeteerawat, C., Boren, D., Fischer, H., Ji, Z., Chang, C.H., Liu, R., Tolaymat, T., Telesca, D., Zink, J. I., Cohen, Y., Holden, P.A., Godwin, H.A., (2013). Toxicity mechanisms in Escherichia coli vary for silver nanoparticles and differ from ionic silver. Acs Nano, 8(1), 374-386.
Kamariah, N., Nartey, W., Eisenhaber, B., Eisenhaber, F., & Grüber, G. (2016). Low resolution solution structure of an enzymatic active AhpC10: AhpF2 ensemble of the Escherichia coli Alkyl hydroperoxide Reductase. Journal of structural biology, 193(1), 13-22.
Kaplan, J. H., & Lutsenko, S. (2009). Copper transport in mammalian cells: special care for a metal with special needs. Journal of Biological Chemistry, 284(38), 25461-25465.
Kehrer, J.P. (2000). The Haber-Weiss reaction and mechanisms of toxicity. Toxicology, 149, 43-50.
Kim, J.S., Kuk, E., Yu, K.N., Kim, J.H., Park, S.J., Lee, H.J., Kim, S.H., Park, Y.K., Park, Y.H., Hwang, C.Y., Kim, Y.K., Lee, Y.S., Jeong, D.H., Cho, M.H., (2007). Antimicrobial effects of silver nanoparticles. Nanomedicine: Nanotechnology, Biology, and Medicine, 3, 95-101.
Letelier, M. E., Sánchez-Jofré, S., Peredo-Silva, L., Cortés-Troncoso, J., & Aracena-Parks, P. (2010). Mechanisms underlying iron and copper ions toxicity in biological systems: Pro-oxidant activity and protein-binding effects. Chemico-biological interactions, 188(1), 220-227.
Li, F., Lei, C., Shen, Q., Li, L., Wang, M., Guo, M., Huang, Y., Nie, Z., Yao, S. (2013). Analysis of copper nanoparticles toxicity based on a stress-responsive bacterial biosensor array. Nanoscale, 5(2), 653-662.
Liu, L., Wu, D., Zhao, B., Han, X., Wu, J., Hou, H., & Fan, Y. (2015). Copper (II) coordination polymers: tunable structures and a different activation effect of hydrogen peroxide for the degradation of methyl orange under visible light irradiation. Dalton Transactions, 44(3), 1406-1411.
Magner, L.N. (1992). In: Hippocrates and the Hippocratic Tradition. A History of Medicine. Duffy J, editor. Marcel Dekker, Inc; NYC: 1992. p. 393.
Masoud, R., Bizouarn, T., Trepout, S., Wien, F., Baciou, L., Marco, S., & Levin, C. H. (2015). Titanium dioxide nanoparticles increase superoxide anion production by acting on NADPH oxidase. PloS one, 10(12), e0144829.
Mignolet-Spruyt, L., Xu, E., Idänheimo, N., Hoeberichts, F. A., Mühlenbock, P., Brosché, M. & Kangasjärvi, J. (2016). Spreading the news: subcellular and organellar reactive oxygen species production and signalling. Journal of Experimental Botany, 67(13), 3831-3844.
Morones-Ramirez, J. R., Winkler, J. A., Spina, C. S., & Collins, J. J. (2013). Silver enhances antibiotic activity against gram-negative bacteria. Science translational medicine, 5(190), 190ra81-190ra81.
Ochoa-Herrera, V., León, G., Banihani, Q., Field, J. A., Sierra-Alvarez, R. (2011). Toxicity of copper (II) ions to microorganisms in biological wastewater treatment systems. Science of the total environment, 412, 380-385.
Seo, S. W., Kim, D., Szubin, R., & Palsson, B. O. (2015). Genome-wide reconstruction of OxyR and SoxRS transcriptional regulatory networks under oxidative stress in Escherichia coli K-12 MG1655. Cell Reports, 12(8), 1289-1299.
Shareena Dasari, TP, Zhang, Y, Yu, H (2015). Antibacterial Activity and Cytotoxicity of Gold (I) and (III) Ions and Gold Nanoparticles. Biochem Pharmacol (Los Angel) 4(6), 199.
Wang, X., Gu, Y., Johnson, D., Chen, C., Huang, Y. (2017). The toxicity and DNA-damage mechanism of α-Fe2O3 nanoparticles. Medicinal chemistry Research, 26(2), 384-389.
Winterbourn, C.C. (1995). Toxicity of iron and hydrogen peroxide: the Fenton reaction. Toxicol. Lett., 82-83, 969-974.
Witkiewicz, P. L., & Shaw, C. F. (1981). Oxidative cleavage of peptide and protein disulphide bonds by gold (III): a mechanism for gold toxicity. Journal of the Chemical Society, Chemical Communications, (21), 1111-1114.
Yaeger C.C. (1991). Copper and zinc preservatives. In S.S. Block (ed.), Disinfection, sterilization, and preservation. 4th edn, Lea & Fiebiger Press, Philadelphia, USA, 358-361.
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