Team:ArtScienceBangalore/Project
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Revision as of 14:15, 5 October 2011
Project
The Biobrick has been used as an abstraction or template for creating standardized functional parts. This year's ArtScienceBangalore project proposes alternate re-appropriations of the BioBrick by using existing BioBrick primers as random-PCR primers in investigating soil samples. This random PCR will provide a succinct signature of the biological diversity present in these samples. These investigations of soil lead us to ask questions about citizen’s science "performed" by non-institutional actors using accessible tools as well as gives us a glimpse into the "post-natural world" where BioBricks may end up in our environment and may very well show up as bands in a gel. By imagining a world in which the Biobrick has become the accepted standard for synthetic biology, and where these engineered products are ubiquitous in our lives and environments, the samples we archive will serve as the baseline from which the subsequent extent of human influence can be measured.
Project Description
We collected various soil samples from which we extracted DNA and ran it through a PCR machine (using standard Biobrick primers) followed by gel electrophoresis to characterize the combined flora and fauna of a site visually; the ecology’s fingerprint, if you will.
Later we compared the results from various samples in an attempt to find correlations.
Each soil site was documented through aerial photography. This was achieved by the use of a handmade helium-filled balloon mount and a camera. The photographs from these were sown together to produce a comprehensive map of the immediate surroundings.
Extraction of DNA from soil samples
Protocol 1
1. Before the DNA can be extracted the cell walls must be broken open. This process is called lysing and the agent used is called a lysosome. We did this by vortexing using phenol-chloroform, and further the addition of SDS (a detergent) to remove the membranes of lipids.
2. Next comes the centrifuging to separate the layers. The DNA lies in the interface between the two phases (proteins and reagents).
3. After the protein is removed the DNA can be precipitated using cold ethanol or isopropanol (propan-2-ol). The DNA, being insoluble in alcohol, will come out of the solution. Additionally the alcohol serves as a wash to remove the added salts.
4. The resulting DNA pellet should be washed with cold ethanol and centrifuged.
5. After drying the pellet the DNA should be resuspended in a Tris buffer solution.
6. Presence of DNA can be confirmed by electrophoresing on an agarose gel containing ethidium bromide, or another fluorescent dye that reacts with the DNA, and checking under UV light.
Protocol 2
1. For dissolving the DNA present in the soil, mix the soil sample (5 g) in Tris Buffer (5 mL of 25 mM buffer) and mix thoroughly.
2. Then in order to separate the cells out of the solution, filter using 5μm cellulose nitrate filter. Most microbial cells are between 0μm & 5μm, and will be a part of the filtrate.
3. In order to separate the different components of the filtrate, it is centrifuged at 13.2 krpm for 10 mins at room temperature(25°C).
4. The pellet, containing the concentrated DNA (after centrifugation) is separated from the supernatant, and dissolved in 100μL autoclaved milliQ water.
5. The resultant mixture is boiled at 100°C for 20 minutes.
6. Presence of DNA can be confirmed by electrophoresing on an agarose gel containing ethidium bromide, or another fluorescent dye that reacts with the DNA, and checking under UV light.
Protocol 3
1. For dissolving the DNA present in the soil, mix the soil sample in Tris Buffer (2 gm soil sample in 2 mL 25mM Tris Buffer) and mix thoroughly.
2. Freeze the eppendorf tubes containing the above mixture in liquid nitrogen, and then boil (at 100°C for 20 mins). This will cause breakdown of the cell, and release the DNA into the mixture.
3. It is then centrifuged at 13.2 krpm for 10 mins at 25°C. This will result in the separation of the DNA from the soil particles.
4. Discard the soil particles, and collect the supernatant.
5. Presence of DNA can be confirmed by electrophoresing on an agarose gel containing ethidium bromide, or another fluorescent dye that reacts with the DNA, and checking under UV light.
Gel Electrophoresis
Presence of DNA can be confirmed by electrophoresing on an agarose gel containing ethidium bromide, or another fluorescent dye that reacts with the DNA, and checking under UV light.
Preparing an agarose gel solution
1. Add the tris buffer to the agarose powder, heat at 50 degrees centigrade till you obtain a clear solution and add Ethidium bromide.
2. Pour into the Gel box, add the comb to form wells, get rid of any air bubbles and let it settle for 30 minutes.
3. Load 3 micro litres of the samples in the wells
4. Begin Gel electrophoresis