Team:Hong Kong HKUST/experiment/exp2

From 2013.igem.org

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<p id="yo">After several attempts of site-mutagenesis of promoter in FABP1 – eGFP – BBa_J176171 construct, we found that the plasmid degrades at a high temperature. We tested heat sensitivity of the plasmid BBa_J176171 and found that the plasmid degrades at denaturation step (95 °C) of polymerase chain reaction. Then, we took an alternative experiment by cloning FABP1 promoter into pBlueScript KS(+). Due to time constrain, two mutagenesis attempts were taken but both of them were not successful.  
<p id="yo">After several attempts of site-mutagenesis of promoter in FABP1 – eGFP – BBa_J176171 construct, we found that the plasmid degrades at a high temperature. We tested heat sensitivity of the plasmid BBa_J176171 and found that the plasmid degrades at denaturation step (95 °C) of polymerase chain reaction. Then, we took an alternative experiment by cloning FABP1 promoter into pBlueScript KS(+). Due to time constrain, two mutagenesis attempts were taken but both of them were not successful.  
</p><br>
</p><br>
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<h1>Peroxisome Proliferator-Activated Receptor-alpha (PPAR-alpha) Promoter</h1>
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<p id="yo">We planned to clone  PPAR-alpha promoter from human genomic DNA using polymerase chain reaction. We designed three sets of primers in upstream and downstream of promoter sequence, for different polymerases and referencing on Pineda Torra team’s experiment2. In addition, polymerase chain reaction was conducted at different temperatures, primer concentrations and buffers. However, none of the primers could successfully clone the PPAR-alpha promoter. </p><br>
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<h3>Primers used to extract PPAR-alpha promoter from gDNA:</h3>
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<p id="yo">
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Forward GATCATATTAATGAATTCGCGGCCGCTTCTAGAGTTCCCTCACCAAACACAACAGGATGA</p>
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<p id="yo">Reverse GATCATGGATCCTACTAGTAGCGGCCGCTGCAGCGCAAGAGTCCTCGGTGT</p>
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<p id="yo">Forward GATCAT ATTAATGAATTCGCGGCCGCTTCTAGAGGGTATGCCAGGTAATGTCTT</p>
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<p id="yo">Reverse GATCATGGATCCCTGCAGCGGCCGCTACTAGTACAAGAGTCCTCGGTGTGT</p>
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<p id="yo">Forward from reference paper
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GATCAT ATTAAT GAATTCGCGGCCGCTTCTAGAGGAGCGTCACGGCCCGAACAAAGC</p>
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<p id="yo">Reverse from reference papers+ RFC10 prefix and suffix
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GATCATGGATCCCTGCAGCGGCCGCTACTAGTAAGTCCTCGGTGTGTGTCCTCGCTCCTC</p>
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<p id="yo">Since the PPAR-alpha promoter coding sequence could not be obtained from human genomic DNA, further experiment could not be preceded. </p>
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Revision as of 18:54, 27 September 2013




Fatty Acid Sensing Mechanism


BBa_J176171

BBa_ J176171 was planned to be used as a mammalian vector backbone for the promoters. After running PCR (Polymerase Chain Reaction) to amplify the FABP1 promoter and ligated it with GFP and the backbone, we did mutagenesis for the vector. Based on the gel photo, we concluded that the vector was easy to get degraded. Finally we figured out that BBa-J176171 was heat unstable and changed our plan.


Liver Fatty Acid Binding Protein 1 (FABP1) Promoter

This promoter was cloned from human genomic DNA (gDNA) (see gDNA extractionand PCR protocols) with engineered RFC10 prefix and suffix for BioBrick submission. The promoter was then ligated with enhanced green fluorescence protein (eGFP) from pEGFP-N1 (Addgene), and cloned into BBa_J176171 mammalian backbone. The promoter and eGFP were successfully cloned into BBa_J176171 by digestion and ligation.

The confirmed construct was transfected into two mammalian cells, HEK293FT and HepG2 cell lines. GFP signal of the construct was compared with pEGF-N1 plasmid that contains constitutive CMV promoter. However, no GFP signal could be detected.

Since FABP1 promoter contained illegal restriction sites for BioBrick submission, we conducted multi site-directed mutagenesis to elimitate EcoRI and PstI from the coding sequence. (see Mutagenesis protocol 1,2 and 3).

The FABP1 promoter was to be characterized by over-expression of eGFP reporter in the presence of high fatty acid concentration in the medium1. However, no eGFP signal could be detected.

After several attempts of site-mutagenesis of promoter in FABP1 – eGFP – BBa_J176171 construct, we found that the plasmid degrades at a high temperature. We tested heat sensitivity of the plasmid BBa_J176171 and found that the plasmid degrades at denaturation step (95 °C) of polymerase chain reaction. Then, we took an alternative experiment by cloning FABP1 promoter into pBlueScript KS(+). Due to time constrain, two mutagenesis attempts were taken but both of them were not successful.


Peroxisome Proliferator-Activated Receptor-alpha (PPAR-alpha) Promoter

We planned to clone PPAR-alpha promoter from human genomic DNA using polymerase chain reaction. We designed three sets of primers in upstream and downstream of promoter sequence, for different polymerases and referencing on Pineda Torra team’s experiment2. In addition, polymerase chain reaction was conducted at different temperatures, primer concentrations and buffers. However, none of the primers could successfully clone the PPAR-alpha promoter.


Primers used to extract PPAR-alpha promoter from gDNA:

Forward GATCATATTAATGAATTCGCGGCCGCTTCTAGAGTTCCCTCACCAAACACAACAGGATGA

Reverse GATCATGGATCCTACTAGTAGCGGCCGCTGCAGCGCAAGAGTCCTCGGTGT

Forward GATCAT ATTAATGAATTCGCGGCCGCTTCTAGAGGGTATGCCAGGTAATGTCTT

Reverse GATCATGGATCCCTGCAGCGGCCGCTACTAGTACAAGAGTCCTCGGTGTGT

Forward from reference paper GATCAT ATTAAT GAATTCGCGGCCGCTTCTAGAGGAGCGTCACGGCCCGAACAAAGC

Reverse from reference papers+ RFC10 prefix and suffix GATCATGGATCCCTGCAGCGGCCGCTACTAGTAAGTCCTCGGTGTGTGTCCTCGCTCCTC

Since the PPAR-alpha promoter coding sequence could not be obtained from human genomic DNA, further experiment could not be preceded.