Team:Westminster/Experiments

From 2012.igem.org

(Difference between revisions)
 
Line 345: Line 345:
<div id="home-main-text">
<div id="home-main-text">
-
<h2>Promoter Seqeunce Identification</h2>
+
<h2>Promoter Sequence Identification</h2>
<p>The team isolated regions of approximately 1kbp where the gene promoter was likely to be found. These were compared with commercial promoters (if available) and European Promoter database (EPD). The promoter sequences that appeared on the EPD site have been experimentally analysed, and also did not contain any illegal sites. Thus they were selected, in case of ADH1A1 and ALDH3A1. ALDH1A3 identified by the team had no illegal site, so it was maintained. However, ALDH2 promoter sequence on the EPD site was too small to be included. Therefore a commercial promoter of ALDH2 was selected.</p>
<p>The team isolated regions of approximately 1kbp where the gene promoter was likely to be found. These were compared with commercial promoters (if available) and European Promoter database (EPD). The promoter sequences that appeared on the EPD site have been experimentally analysed, and also did not contain any illegal sites. Thus they were selected, in case of ADH1A1 and ALDH3A1. ALDH1A3 identified by the team had no illegal site, so it was maintained. However, ALDH2 promoter sequence on the EPD site was too small to be included. Therefore a commercial promoter of ALDH2 was selected.</p>
<p>The following gives an example of how a promoter sequences were identified by the iSTEM team:</p>
<p>The following gives an example of how a promoter sequences were identified by the iSTEM team:</p>

Latest revision as of 23:44, 26 September 2012

Welcome

Promoter Sequence Identification

The team isolated regions of approximately 1kbp where the gene promoter was likely to be found. These were compared with commercial promoters (if available) and European Promoter database (EPD). The promoter sequences that appeared on the EPD site have been experimentally analysed, and also did not contain any illegal sites. Thus they were selected, in case of ADH1A1 and ALDH3A1. ALDH1A3 identified by the team had no illegal site, so it was maintained. However, ALDH2 promoter sequence on the EPD site was too small to be included. Therefore a commercial promoter of ALDH2 was selected.

The following gives an example of how a promoter sequences were identified by the iSTEM team:

ALDH1A1

ALDH1A1 directions

Directionality:5-3

ALDH1A1 directions

TAATAA= TATA box

GCTGCATACetc = the 5’UTR region.

The promoter includes elements of the 5’UTR plus the grey sequence upstream of it, up to and including the yellow region coding for the forward primer (about 1,000bp in total).

ATGTCATCCetc = start of gene at -75567940 approx

F: GTTTCTTCGAATTCGCGGCCGCTTCTAGAGCATCATATGACTTTTTTCAAC

R: GTTTCTTCCTGCAGCGGCCGCTACTAGTATTCTGATTCGGCTCCTGGAA

ALDH1A1 directions

The promoter sequences identified are represented below:

ALDH1A1 (552BP)

ALDH1A1 directions

ALDH2 (903BP)

ALDH1A1 directions

ALDH1A3 (932BP)

ALDH1A1 directions

ALDH3A1 (600BP)

ALDH1A1 directions

Primer Design

The primers for these sequences were designed using Gingko bioworks part design tool that allows the sequences to be flanked with biobrick suffix and prefix. The primers are represented in the table below:

ALDH1A1 directions

Experimental Design

Experiment 1:Identification

This experiment is designed to help in identifying cancer stem cells from normal cancer cells, by using their ability to characteristically express ALDH. The genetic construct resulting from this experiment would contain fluorescent reporters and a bacterial selection marker. Only stem cells with ALDH activity will be express ALDH promoter activity resulting in Fluorescence of those cells. These cells can be visually identified.

ALDH1A1 directions

Experiment 2:Isolation

The second part of the experiment is designed to isolate the cancer stem cells form normal cells by rendering them resistance to antibiotics. Neomycin was used as the mammalian selection marker. When grown in a medium containing the corresponding antibiotic, only those cells with resistance will survive.

ALDH1A1 directions

Experiment 3:Destruction

The final part of the experiment is to make a construct that will help to destroy the cancer stem cells. The antibiotic resistance marker will be flanked with two lox sites that will be excised in the presence of cre recombinase. The cre will be induced by the presence of doxycycline in the medium.

ALDH1A1 directions

Assembly Strategy

The assembly strategy followed in the project is ‘Plug and Play’, developed by DTU. This strategy was chosen as this considerably reduces cloning time and helps in focusing on the experiment strategy. The primers (linkers) for each part of each experiment were generated using the software PHUSER version1.2. Care was taken to ensure that the construct in its entirety, and the promoters was flanked by biobrick prefix and suffix.

ALDH1A1 directions"