Difference between revisions of "Part:BBa K3763042"
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[[File:T--WHU China--42 1 Bacground1.png|500px|Figure 1. '''Figure1. The FadE catalytic principle.''']] | [[File:T--WHU China--42 1 Bacground1.png|500px|Figure 1. '''Figure1. The FadE catalytic principle.''']] | ||
− | + | Figure1. The FadE catalytic principle. | |
==Design== | ==Design== | ||
In our experiment, we hope to improve the β-oxidation capacity of our engineered bacteria by | In our experiment, we hope to improve the β-oxidation capacity of our engineered bacteria by |
Revision as of 09:03, 21 October 2021
No part name specified with partinfo tag. ( The correct title should be: pFadD promoter with LacI repressor regulating downstream RFP)
Background
FadE, which is also called acyl-CoA dehydrogenases , catalyze the first reaction of the b-oxidation cycle. All acyl-CoA dehydrogenases carry noncovalently (but tightly) bound FAD, which is reduced during the oxidation of the fatty acid. As shown in Figure, FADH2 trans- fers its electrons to an electron transfer flavoprotein (ETF). Reduced ETF is reoxidized by a specific oxidoreductase (an iron–sulfur protein), which in turn sends the electrons on to the electron-transport chain at the level of coenzyme Q. The mitochondrial oxidation of FAD in this way eventually results in the net formation of about 1.5 ATPs. The mechanism of the acyl-CoA dehydrogenase involves deprotonation of the fatty acid chain at the a-carbon, followed by hydride transfer from the b-carbon to FAD.
Figure1. The FadE catalytic principle.
Design
In our experiment, we hope to improve the β-oxidation capacity of our engineered bacteria by
overexpressing FadE protein . As shown in the figure below, we constructed a recombinant plasmid
containing FadE gene and introduced it into our engineered bacteria.
Figure2.Schematic diagram of recombinant vector containing FadE.
Result
After confirming that we correctly constructed and transferred the recombinant plasmid into the engineering strain E. coli DH5 α, we used arabinose to induce the expression of FadE and tested its improvement on the fatty acid decomposition ability of engineered bacteria. Our experimental results showed that induced overexpression of FadE did not significantly improve the fatty acid decomposition ability of engineered bacteria, and did not reproduce the experimental results in references.
Figure1. Changes of fatty acid decomposition ability of engineering bacteria overexpressing FadE protein.
Sequence and Features
No part name specified with partinfo tag.