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− | Gold nanoparticles (AuNPs) are popular in many scientific applications, e.g. the transfection of human cells (Chang <i>et al.</i>, 2008). However, there are several contradicting reports regarding their toxicity (Brust et al., 1995; Caruntu <i>et al.</i>, 2002; Zhang <i>et al.</i>, 2015). AuNPs in the form of rod-shaped nanoparticles ("nanorods") were identified as non-toxic, solely the coating agent was found to be toxic (Alkilany <i>et al.</i>, 2009). AuNPs in general do not possess toxic properties. Reported toxic effects of AuNPs resulted from poor purification of the AuNPs from Au(III) (Shareena Dasari, 2015).</br> | + | Gold nanoparticles (AuNPs) are popular in many scientific applications, e.g. the transfection of human cells (Chang <i>et al.</i>, 2008). However, there are several contradicting reports regarding their toxicity (Brust <i>et al.</i>, 1995; Caruntu <i>et al.</i>, 2002; Zhang <i>et al.</i>, 2015). AuNPs in the form of rod-shaped nanoparticles ("nanorods") were identified as non-toxic, solely the coating agent was found to be toxic (Alkilany <i>et al.</i>, 2009). AuNPs in general do not possess toxic properties. Reported toxic effects of AuNPs resulted from poor purification of the AuNPs from Au(III) (Shareena Dasari, 2015).</br> |
However, gold ions, such as Au(I) and Au(III), have toxic properties. Shareena Dasari <i>et al.</i> demonstrated in 2015 that exposure to Au(I) and Au(III) inhibits the growth of nonpathogenic <i>Escherichia coli</i> as seen in figure 1. Furthermore, they determined the half maximal inhibitory concentrations (IC<sub>50</sub>) for both ions in the examined buffers as seen in table 1, clearly indicating that gold ions possess toxic properties to <i>E. coli</i>. The toxic effect of gold ions is due to its ability to oxidative cleavage of peptide and protein disulfide bonds (Witkiewicz & Shaw, 1981). | However, gold ions, such as Au(I) and Au(III), have toxic properties. Shareena Dasari <i>et al.</i> demonstrated in 2015 that exposure to Au(I) and Au(III) inhibits the growth of nonpathogenic <i>Escherichia coli</i> as seen in figure 1. Furthermore, they determined the half maximal inhibitory concentrations (IC<sub>50</sub>) for both ions in the examined buffers as seen in table 1, clearly indicating that gold ions possess toxic properties to <i>E. coli</i>. The toxic effect of gold ions is due to its ability to oxidative cleavage of peptide and protein disulfide bonds (Witkiewicz & Shaw, 1981). | ||
Since gold ions are toxic to the NP producing cell, the reduction to AuNPs is desirable, however the stress to the cell and its inhibitory effect have to be investigated. | Since gold ions are toxic to the NP producing cell, the reduction to AuNPs is desirable, however the stress to the cell and its inhibitory effect have to be investigated. | ||
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<h2>Copper</h2> | <h2>Copper</h2> | ||
<article> | <article> | ||
− | Copper is known for its toxic and bactericidal properties and is often used as an antimicrobial agent in form of copper nanoparticles (CuNPs) (Cioffi <i>et al.</i>, 2005). Recent studies revealed that the inactivation and bactericidal activity works in a size-dependent manner. The smaller a CuNP is the higher is its inhibitory potential to bacteria. Furthermore, the toxicity is probably elicited in a strain-specific manner in <i>E. coli</i> obtained from different sources (Alum et al., 2018). CuNPs’ toxic properties appear to result from oxidative stress and protein damage, DNA damage and membrane damage. The generation of hydroxyl peroxide by CuNPs is assumed to be the reason for the toxicity of CuNPs. Li <i>et al.</i> reported 2013 the release of copper and the production of Cu(I) ions.</br> | + | Copper is known for its toxic and bactericidal properties and is often used as an antimicrobial agent in form of copper nanoparticles (CuNPs) (Cioffi <i>et al.</i>, 2005). Recent studies revealed that the inactivation and bactericidal activity works in a size-dependent manner. The smaller a CuNP is the higher is its inhibitory potential to bacteria. Furthermore, the toxicity is probably elicited in a strain-specific manner in <i>E. coli</i> obtained from different sources (Alum <i>et al.</i>, 2018). CuNPs’ toxic properties appear to result from oxidative stress and protein damage, DNA damage and membrane damage. The generation of hydroxyl peroxide by CuNPs is assumed to be the reason for the toxicity of CuNPs. Li <i>et al.</i> reported 2013 the release of copper and the production of Cu(I) ions.</br> |
− | Copper is considered to be essential in small amounts to both human and bacteria (Burgess <i>et al.</i>, 1999). It plays an important role in electron-transfer reactions (Kaplan & Lutsenko, 2009). Yet copper ions can induce cell death and exhibit toxic effects. This is due to copper ions interfering with the cell proteins or enzymes by chelating sulfhydryl groups and peroxidizing the lipids of the cell membrane (Yeager, 1991). A broad variety of microorganisms, such as <i>E. coli</i>, are inhibited in growth or killed by exposure to Cu(II) (Ochoa-Herrera <i>et al.</i>, 2011). Furthermore, copper ions can interact with oxygen by catalyzing Haber-Weiss and/or Fenton reactions. This results in the generation of ROS which can ultimately damage biomolecules (Halliwell, 2007; Halliwell & Gutteridge, 2015).</br> | + | Copper is considered to be essential in small amounts to both human and bacteria (Burgess <i>et al.</i>, 1999). It plays an important role in electron-transfer reactions (Kaplan & Lutsenko, 2009). Yet copper ions can induce cell death and exhibit toxic effects. This is due to copper ions interfering with the cell proteins or enzymes by chelating sulfhydryl groups and peroxidizing the lipids of the cell membrane (Yeager, 1991). A broad variety of microorganisms, such as <i>E. coli</i>, are inhibited in growth or killed by exposure to Cu(II) (Ochoa-Herrera <i>et al.</i>, 2011). Furthermore, copper ions can interact with oxygen by catalyzing Haber-Weiss and/or Fenton reactions. This results in the generation of ROS which can ultimately damage biomolecules (Halliwell, 2007; Halliwell & Gutteridge, 2015).</br> |
Copper is toxic in both of its forms: as a nanoparticle and as dissolved ions. Therefore, an approach to decrease the toxic effect on the cell is needed. | Copper is toxic in both of its forms: as a nanoparticle and as dissolved ions. Therefore, an approach to decrease the toxic effect on the cell is needed. | ||
</article> | </article> | ||
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<article> | <article> | ||
Iron is crucial for certain biological functions and necessary for the cell in order to work properly. Especially when it comes to electron transfer reactions iron as a cofactor is critical for the formation of biomolecules (Zhang, 2014). However, free non-bound iron bears risks for the cell. Iron regularly appears as a ferrous (Fe(II)) or as a ferric ion (Fe(III)) and is able to accept an electron from neighboring molecules which leads to the generation of ROS and causes damage to cellular components. The generation of ROS occurs by Fenton and Haber-Weiss reactions (Kehrer, 2000; Winterbourn, 1995).</br> | Iron is crucial for certain biological functions and necessary for the cell in order to work properly. Especially when it comes to electron transfer reactions iron as a cofactor is critical for the formation of biomolecules (Zhang, 2014). However, free non-bound iron bears risks for the cell. Iron regularly appears as a ferrous (Fe(II)) or as a ferric ion (Fe(III)) and is able to accept an electron from neighboring molecules which leads to the generation of ROS and causes damage to cellular components. The generation of ROS occurs by Fenton and Haber-Weiss reactions (Kehrer, 2000; Winterbourn, 1995).</br> | ||
− | The desired iron nanoparticles should be composed of Fe<sub>2</sub>O<sub>3</sub> which is one of the most abundant transition metal oxides and ubiquitous in the environment (Bi & Xu, 2012). Toxic effects by these nanoparticles arise from the formation of ROS by converting H<sub>2</sub>O<sub>2</sub> or O<sub>2</sub> (Huang <i>et al.</i>, 2015). Further studies performed by Wang et al. (2017) regarding the photocatalytic degradation of DNA who found that the majority of intracellular damage especially concerning the DNA arises from ROS. | + | The desired iron nanoparticles should be composed of Fe<sub>2</sub>O<sub>3</sub> which is one of the most abundant transition metal oxides and ubiquitous in the environment (Bi & Xu, 2012). Toxic effects by these nanoparticles arise from the formation of ROS by converting H<sub>2</sub>O<sub>2</sub> or O<sub>2</sub> (Huang <i>et al.</i>, 2015). Further studies performed by Wang <i>et al.</i> (2017) regarding the photocatalytic degradation of DNA who found that the majority of intracellular damage especially concerning the DNA arises from ROS. |
</article> | </article> | ||
<a name="ros" id="ros" class="shifted-anchor"></a> | <a name="ros" id="ros" class="shifted-anchor"></a> | ||
− | <h2>Reactive | + | <h2>Reactive Oxygen Species</h2> |
<article> | <article> | ||
As most problems from heavy metals arise from the generation of ROS, the efforts to improve the resistance to their toxic effects need to focus on the repair of the damage of biomolecules and the prevention of further damage. | As most problems from heavy metals arise from the generation of ROS, the efforts to improve the resistance to their toxic effects need to focus on the repair of the damage of biomolecules and the prevention of further damage. | ||
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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 | + | 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 O<sub>2</sub><sup>-</sup> 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 + 2 GSH → ROH + GSSG + H<sub>2</sub>O</br> | ROOH + 2 GSH → 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 (PCS1) or also called glutathione gamma-glutamylcysteinyltransferase catalyzes the formation of 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, ultimately producing (γ-Glu-Cys)<sub>n+1</sub>-Gly peptides with n in the range from 2 to 10 (Figure 4). | GSR then recovers the used glutathione by reducing the generated glutathione disulfide under the consumption of NADPH. The phytochelatin synthase (PCS1) or also called glutathione gamma-glutamylcysteinyltransferase catalyzes the formation of 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, ultimately producing (γ-Glu-Cys)<sub>n+1</sub>-Gly peptides with n in the range from 2 to 10 (Figure 4). | ||
The phytochelatin synthase plays a crucial role in the metal detoxification process. There are reports (Heiss <i>et al.</i>, 2003) that PCS is activated by heavy metal ions such as cadmium and copper in <i>Arabidopsis thaliana</i> cells. We think that heterologous expression of this enzyme in <i>E. coli</i> helps the bacterium to better endure the toxicity of the imported copper ions. The phytochelatin synthase is activated by heavy metal ions such as cadmium which can be seen in figure 4. | The phytochelatin synthase plays a crucial role in the metal detoxification process. There are reports (Heiss <i>et al.</i>, 2003) that PCS is activated by heavy metal ions such as cadmium and copper in <i>Arabidopsis thaliana</i> cells. We think that heterologous expression of this enzyme in <i>E. coli</i> helps the bacterium to better endure the toxicity of the imported copper ions. The phytochelatin synthase is activated by heavy metal ions such as cadmium which can be seen in figure 4. | ||
<img src="https://static.igem.org/mediawiki/parts/0/0f/T--Bielefeld-CeBiTec--jr--OttoPhy.png" width="100%" style="float:right;"/><figcaption> | <img src="https://static.igem.org/mediawiki/parts/0/0f/T--Bielefeld-CeBiTec--jr--OttoPhy.png" width="100%" style="float:right;"/><figcaption> | ||
− | <b>Figure 4:</b> <b>A: </b>Schematic illustration of the phytochelatin synthase functioning. The C-terminal domain works as a local sensor of heavy metal ions, such as | + | <b>Figure 4:</b> <b>A: </b>Schematic illustration of the phytochelatin synthase functioning. The C-terminal domain works as a local sensor of heavy metal ions, such as cadmium (Cd). Cysteine residues (C) bind Cd ions which are transferred to the activation site in the N-terminal catalytic domain. The activated domain catalyses the relocation of the γ-Glu-Cys moiety of a glutathione (GSH; γ-Glu-Cys-Gly) molecule onto a second glutathione molecule or an existing PC<sub>n</sub> molecule to form a PC<sub>n+1</sub> product (Cobbett, 1999). <B>B: </b>Catalyzed reaction by phytochelatin synthase. The transpeptidase uses glutathione as a substrate and transfers γ-Glu-Cys moieties on glutathione or (γ-Glu-Cys)n-Gly to form phytochelatins ((γ-Glu-Cys)n-Gly with n between 2 and 10).</figcaption> |
</br> | </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 | + | In order to increase the cell’s resistance to oxidative stress a sophisticated approach is needed. An overexpression of the oxidative stress dependent regulators <i>soxR</i> and <i>oxyR</i> 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> | ||
<h2>The results for the toxicity can be found <a href="https://2018.igem.org/Team:Bielefeld-CeBiTec/Toxicity_Results">here</a></h2> | <h2>The results for the toxicity can be found <a href="https://2018.igem.org/Team:Bielefeld-CeBiTec/Toxicity_Results">here</a></h2> |
Latest revision as of 02:31, 10 December 2018
Toxicity
Short Summary
Gold
Silver
Copper
Iron
Reactive Oxygen Species
The results for the toxicity can be found here
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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.
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