Difference between revisions of "Team:Aix-Marseille/Design"

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==Mobilisation by a siderophore==

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~~===Improving recoveries of platinum and palladium from oxidized Platinum-group element ores of the Great Dyke, Zimbabwe, using the biogenic siderophore Desferrioxamine B, Dennis Kraemer & al.===~~

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In the previous article, authors made bioleaching with synthetised siderophores. By this way, they extracted approximately 80% of the total platinum found in the ore. But we were looking for a synthetic biological approach.

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In the previous article<ref>Improving recoveries of platinum and palladium from oxidized Platinum-group element ores of the Great Dyke, Zimbabwe, using the biogenic siderophore Desferrioxamine B, Dennis Kraemer & al.

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</ref>, authors made bioleaching with synthetised siderophores. By this way, they extracted approximately 80% of the total platinum found in the ore. But we were looking for a synthetic biological approach.

===Pathway of the desferrioxamine B biosynthesis===

[[File:T--Aix-Marseille--desABCD.jpeg|600px|center|thumb|Desferrioxamine B pathway]]

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Previous work showed that siderophore which are molecule secreted by bacteria to catch iron are able to catch other metals by default. Especifically, many articles showed a high affinity of Desferrioxamine B ( produce by ''Streptomyces coelicolor'') for tetravalent metal ions and more specifically platinum. These results encouraged us to make a biobrick coding the sequence corresponding to the 4 enzymes involved on the metabolic pathway of Desferrioxamine B. <i>E. coli</i> was used to produce this biobrick. Produce a gram positive bacteria pathway in a gram negative bacteria is restrictive<ref> Wandersman & Delepaire https://www.ncbi.nlm.nih.gov/pubmed/15487950 </ref> , considering the risk of toxicity for the conductress bacteria. To counter this potential issue, we regulate trasnscription using the control of an inductible promotor (pBAD/araC).

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Previous work showed that siderophore which are molecule secreted by bacteria to catch iron are able to catch other metals by default. Especifically, many articles showed a high affinity of Desferrioxamine B ( produce by ''Streptomyces coelicolor'') for tetravalent metal ions and more specifically platinum. These results encouraged us to make a biobrick coding the sequence corresponding to the 4 enzymes involved on the metabolic pathway of Desferrioxamine B. ''E. coli'' was used to produce this biobrick. Produce a gram positive bacteria pathway in a gram negative bacteria is restrictive, considering the risk of toxicity for the conductress bacteria. To counter this potential issue, we regulate trasnscription using the control of an inductible promotor (pBAD/araC).

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Our strategy for the siderophore mobilisation results in two main steps :

Difference between revisions of "Team:Aix-Marseille/Design"

Revision as of 11:32, 14 October 2016

Contents

Design

Source of platinum

Mobilisation by a siderophore

Pathway of the desferrioxamine B biosynthesis

Biosorption and reduction using flagellin and peptides

@@ Line 6: / Line 6: @@
 ==Mobilisation by a siderophore==
-===Improving recoveries of platinum and palladium from oxidized Platinum-group element ores of the Great Dyke, Zimbabwe, using the biogenic siderophore Desferrioxamine B, Dennis Kraemer & al.===
-In the previous article, authors made bioleaching with synthetised siderophores. By this way, they extracted approximately 80% of the total platinum found in the ore. But we were looking for a synthetic biological approach.
+In the previous article<ref>Improving recoveries of platinum and palladium from oxidized Platinum-group element ores of the Great Dyke, Zimbabwe, using the biogenic siderophore Desferrioxamine B, Dennis Kraemer & al.
+</ref>, authors made bioleaching with synthetised siderophores. By this way, they extracted approximately 80% of the total platinum found in the ore. But we were looking for a synthetic biological approach.
 ===Pathway of the desferrioxamine B biosynthesis===
 [[File:T--Aix-Marseille--desABCD.jpeg|600px|center|thumb|Desferrioxamine B pathway]]
+Previous work showed that siderophore which are molecule secreted by bacteria to catch iron are able to catch other metals by default. Especifically, many articles showed a high affinity of Desferrioxamine B ( produce by ''Streptomyces coelicolor'') for tetravalent metal ions and more specifically platinum. These results encouraged us to make a biobrick coding the sequence corresponding to the 4 enzymes involved on the metabolic pathway of Desferrioxamine B. <i>E. coli</i> was used to produce this biobrick. Produce a gram positive bacteria pathway in a gram negative bacteria is restrictive<ref> Wandersman & Delepaire https://www.ncbi.nlm.nih.gov/pubmed/15487950  </ref> , considering the risk of toxicity for the conductress bacteria. To counter this potential issue, we regulate trasnscription using the control of an inductible promotor (pBAD/araC).
-Previous work showed that siderophore which are molecule secreted by bacteria to catch iron are able to catch other metals by default. Especifically, many articles showed a high affinity of Desferrioxamine B ( produce by ''Streptomyces coelicolor'') for tetravalent metal ions and more specifically platinum. These results encouraged us to make a biobrick coding the sequence corresponding to the 4 enzymes involved on the metabolic pathway of Desferrioxamine B. ''E. coli'' was used to produce this biobrick. Produce a gram positive bacteria pathway in a gram negative bacteria is restrictive, considering the risk of toxicity for the conductress bacteria. To counter this potential issue, we regulate trasnscription using the control of an inductible promotor (pBAD/araC).
 Our strategy for the siderophore mobilisation results in two main steps :