Team:Fatih Turkey/Sporocide
From 2011.igem.org
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The reason that we chose B.subtilis in our project is the LPS binding character of LALF. Gram positive bacteria such as B.subtilis have no LPS layer on their cell wall. This obligation of choosing alternative bacterium leads to another problem: B.subtilis has the ability to form endospores. <br /> | The reason that we chose B.subtilis in our project is the LPS binding character of LALF. Gram positive bacteria such as B.subtilis have no LPS layer on their cell wall. This obligation of choosing alternative bacterium leads to another problem: B.subtilis has the ability to form endospores. <br /> | ||
B.subtilis, normally, has no pathogenic character unless it forms endospores under some circumstances like high temperature, limit pH levels or deoxygenized media. The inhalation of endospores is very dangerous and must be avoided in the case of study on B.subtilis.<br /> | B.subtilis, normally, has no pathogenic character unless it forms endospores under some circumstances like high temperature, limit pH levels or deoxygenized media. The inhalation of endospores is very dangerous and must be avoided in the case of study on B.subtilis.<br /> | ||
- | Decontamination of biological endospores is very important considering the necessary of the safety in synthetic biology laboratories. Especially in iGEM, teams may need alternative creatures to plan and perform their projects properly like in our project. Because of this, we began to look through the web and hope to find a solution for this safety problem. Fortunately, some specific dilutions are characterized to solve possible safety problems in order to assemble aseptic surfaces. <strong>Fenton reagents</strong>, which kill septic microorganisms with mechanism of hydroxyl radicals, were traditionally being used. However; its major ingredient, hydrogen peroxide, was examined and was compared with aqueous dissolved oxygen about their capability of killing the spores. (J. B. Cross, 2003)<br /> | + | Decontamination of biological endospores is very important considering the necessary of the safety in synthetic biology laboratories. Especially in iGEM, teams may need alternative creatures to plan and perform their projects properly like in our project. Because of this, we began to look through the web and hope to find a solution for this safety problem. Fortunately, some specific dilutions are characterized to solve possible safety problems in order to assemble aseptic surfaces. <strong>Fenton reagents</strong>, which kill septic microorganisms with mechanism of hydroxyl radicals, were traditionally being used. However; its major ingredient, hydrogen peroxide, was examined and was compared with aqueous dissolved oxygen about their capability of killing the spores. (J. B. Cross, 2003)1 |
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It is said that in addition to aqueous dissolved oxygen, cupric chloride, ascorbic acid, sodium chloride and a little sulfactant dilution which are used as modified Fenton reagent are more effective on endospores of gram positive bacteria. In contrast; classic Fenton reagent, which possess hydrogen peroxide and copper ion, shows that gram negative bacteria are more vulnerable to this formulation. The mechanism of these dilutions is not well-characterized; however, comparing with other dilutions that include specific oxidizing agents such as ozone, some differences in the images that are gained from effected bacteria are indicated. It is deduced that modified Fenton reagent affects the inside mechanism of the bacteria; although the dilutions with ozone damages the coat of the bacteria. After formation of hydroxyl radicals within the spore, these highly reactive molecules attack either the DNA or enzymes necessary for the spore conversion to a bacterial cell. Further investigations of ion transport into spores and oxidation-reductions with in spores will be needed to determine precisely the mechanism of spore kill under these conditions.<br /> | It is said that in addition to aqueous dissolved oxygen, cupric chloride, ascorbic acid, sodium chloride and a little sulfactant dilution which are used as modified Fenton reagent are more effective on endospores of gram positive bacteria. In contrast; classic Fenton reagent, which possess hydrogen peroxide and copper ion, shows that gram negative bacteria are more vulnerable to this formulation. The mechanism of these dilutions is not well-characterized; however, comparing with other dilutions that include specific oxidizing agents such as ozone, some differences in the images that are gained from effected bacteria are indicated. It is deduced that modified Fenton reagent affects the inside mechanism of the bacteria; although the dilutions with ozone damages the coat of the bacteria. After formation of hydroxyl radicals within the spore, these highly reactive molecules attack either the DNA or enzymes necessary for the spore conversion to a bacterial cell. Further investigations of ion transport into spores and oxidation-reductions with in spores will be needed to determine precisely the mechanism of spore kill under these conditions.<br /> | ||
The effectiveness of modified Fenton Reagent and the advantages/disadvantages of different Fenton Reagent solutions are characterized during our experiments. For more information about Fenton Reagent experiments, please visit <u>Fenton Reagent Experiments</u> page.<br /> | The effectiveness of modified Fenton Reagent and the advantages/disadvantages of different Fenton Reagent solutions are characterized during our experiments. For more information about Fenton Reagent experiments, please visit <u>Fenton Reagent Experiments</u> page.<br /> | ||
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As a conclusion, we observed <strong>distilled water</strong> included Fenton Reagent (DFR) is more effective than <strong>oxygenated water</strong> included Fenton Reagent (OFR) against E.coli. When 25 uL OFR and DFR have been added in E.coli cultures, 82% of DFR treated culture was dead and 47% of OFR treated culture was dead. We did not see any colony which included 50 uL and more volumes of DFR. In contrast, after 75 uL and more addition of OFR, no colony formation has been observed.</p> | As a conclusion, we observed <strong>distilled water</strong> included Fenton Reagent (DFR) is more effective than <strong>oxygenated water</strong> included Fenton Reagent (OFR) against E.coli. When 25 uL OFR and DFR have been added in E.coli cultures, 82% of DFR treated culture was dead and 47% of OFR treated culture was dead. We did not see any colony which included 50 uL and more volumes of DFR. In contrast, after 75 uL and more addition of OFR, no colony formation has been observed.</p> | ||
<p>On the other hand, we observed OFR is more effective than DFR against Bacillus subtilis. When 10 uL OFR and DFR have been added in Bacillus subtilis cultures, 38% of DFR treated culture was dead and 98.3% of OFR treated culture was dead. Not only the 25 uL OFR treated but also 25 uL DFR treated culture was dead.</p> | <p>On the other hand, we observed OFR is more effective than DFR against Bacillus subtilis. When 10 uL OFR and DFR have been added in Bacillus subtilis cultures, 38% of DFR treated culture was dead and 98.3% of OFR treated culture was dead. Not only the 25 uL OFR treated but also 25 uL DFR treated culture was dead.</p> | ||
- | <p>If we want to compare E.coli and B. subtilis, we can say that Fenton Reagent application is more fatal for Bacillus subtilis. Both 25 uL OFR and DFR treated Bacillus subtilis culture was dead but 25 uL OFR and DFR treated E.coli culture was still alive.</p> | + | <p>If we want to compare E.coli and B. subtilis, we can say that Fenton Reagent application is more fatal for Bacillus subtilis. Both 25 uL OFR and DFR treated Bacillus subtilis culture was dead but 25 uL OFR and DFR treated E.coli culture was still alive. |
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+ | 1 Killing of Bacillus Spores by Aqueous Dissolved Oxygen, Ascorbic Acid, and Copper Ions; J. B. Cross, R. P. Currier, D. J. Torraco, L. A. Vanderberg, G. L. Wagner, and P. D. Gladen Chemistry Division1 and Biosciences Division,2 Los Alamos National Laboratory, Los Alamos, New Mexico 87545 </p> | ||
Revision as of 23:54, 28 October 2011
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