User:Dong Woo Chin/Sandbox 1
From Proteopedia
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| - | <applet load='1kys' size='400' color='white' frame='true' align='right | + | ==GFP-based Zinc Biosensor== |
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===Background=== | ===Background=== | ||
| - | Heavy metals are often harmful to human health because of their toxicities. The detection techniques of heavy metals in food or water have become an essential tool to prevent food-poisoning in public. Modification of GFP is another technique that was recently introduced to detect heavy metals. When a recombinant gene of a GFP-based biosensor is engineered into E. coli with a heavy metal resistant gene, the genetically engineered E. coli fluoresce. This fluorescence is activated even in a very low concentration of a particular heavy metal. Therefore, the development, modification, and application of GFP-based biosensor can improve the public health and protect people from heavy metal related poisonings. | + | Heavy metals are often harmful to human health because of their toxicities. The detection techniques of heavy metals in food or water have become an essential tool to prevent food-poisoning in public. Modification of GFP is another technique that was recently introduced to detect heavy metals. When a recombinant gene of a GFP-based biosensor is engineered into E. coli with a heavy metal resistant gene, the genetically engineered E. coli fluoresce. This fluorescence is activated even in a very low concentration of a particular heavy metal. Therefore, the development, modification, and application of GFP-based biosensor can improve the public health and protect people from heavy metal related poisonings. |
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===Modifications from GFP=== | ===Modifications from GFP=== | ||
| - | There are <scene name='User:Dong_Woo_Chin/Sandbox_1/Zinc_mutation/1'>two core mutations </scene>(Tyrosine-66-Histidine and Tyrosine-145-Phenylalanine) in the zinc biosensor. However, the brightness of the protein could be enhanced with <scene name='User:Dong_Woo_Chin/Sandbox_1/Zinc_color_mutations/1'>more mutations</scene> at F64, F99, H148, M153, and V163 to change them into L64, S99, G148, T153, and A163 (F64L, F99S, H148G, M153T, V163A) | + | There are <scene name='User:Dong_Woo_Chin/Sandbox_1/Zinc_mutation/1'>two core mutations </scene>(Tyrosine-66-Histidine and Tyrosine-145-Phenylalanine) in the zinc biosensor. However, the brightness of the protein could be enhanced with <scene name='User:Dong_Woo_Chin/Sandbox_1/Zinc_color_mutations/1'>more mutations</scene> at F64, F99, H148, M153, and V163 to change them into L64, S99, G148, T153, and A163 (F64L, F99S, H148G, M153T, V163A). |
===Applications=== | ===Applications=== | ||
Application of the biosensor is not limited to the food-poisoning prevention in the public. Biosensor can be used to measure heavy metal contaminations in soils, to trace heavy metals in a biological system, and to detect explosives. The genetic engineering of GFP gene is essential to reveal the full potential of GFP in its applications. | Application of the biosensor is not limited to the food-poisoning prevention in the public. Biosensor can be used to measure heavy metal contaminations in soils, to trace heavy metals in a biological system, and to detect explosives. The genetic engineering of GFP gene is essential to reveal the full potential of GFP in its applications. | ||
Revision as of 23:58, 7 March 2009
Contents |
GFP-based Zinc Biosensor
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Background
Heavy metals are often harmful to human health because of their toxicities. The detection techniques of heavy metals in food or water have become an essential tool to prevent food-poisoning in public. Modification of GFP is another technique that was recently introduced to detect heavy metals. When a recombinant gene of a GFP-based biosensor is engineered into E. coli with a heavy metal resistant gene, the genetically engineered E. coli fluoresce. This fluorescence is activated even in a very low concentration of a particular heavy metal. Therefore, the development, modification, and application of GFP-based biosensor can improve the public health and protect people from heavy metal related poisonings.
Modifications from GFP
There are (Tyrosine-66-Histidine and Tyrosine-145-Phenylalanine) in the zinc biosensor. However, the brightness of the protein could be enhanced with at F64, F99, H148, M153, and V163 to change them into L64, S99, G148, T153, and A163 (F64L, F99S, H148G, M153T, V163A).
Applications
Application of the biosensor is not limited to the food-poisoning prevention in the public. Biosensor can be used to measure heavy metal contaminations in soils, to trace heavy metals in a biological system, and to detect explosives. The genetic engineering of GFP gene is essential to reveal the full potential of GFP in its applications.
