Our Own Dna From Our Cheek Cells example essay topic

1,300 words
Josh Hyman Per. 5 Plasmid Fusion & PCR The AMGEN Lab that we have been doing for the past two weeks consisted of two parts; Plasmid Fusion and PCR. Each one is a complicated procedure of genetic engineering, with our own cheek cells and E. Coli supplied by AMGEN. I will start by explaining the Plasmid Fusion lab.

The Plasmid Fusion lab consisted of four major parts; plasmid digestion, gel electrophoresis, restriction enzyme inactivation and ligation, and the final step, plating out. But, before I get into that I should define some parts of the lab. The main pieces of genetic information we will be working with are plasmids. Plasmids are gene sequences found in a loop outside of the main chromosome. Their main purpose is to code enzymes that digest antibiotic enzymes. Antibiotics are chemicals that kill bacteria or interfere with their growth or metabolism.

Cells that have antibiotic resistance have an advantage because they are able to grow in places that other cells can not. Our main purpose in this lab is to give an E. Coli cell immunity to the antibacterials, Ampicillin and Chloramphenicol by genetically doctoring its plasmids. The first step in doing this is to cut the plasmids so that we can ligate the new pieces on later. The DNA will be cut once twice or not at all because the process does not work all of the time with all DNA. The part that makes the resistance enzyme will be left in tact and separated into a smaller section of DNA.

We do this so that we can isolate the genome so that we can later attach other sections of DNA to it. The next step involves checking to see if the Restriction Enzymes did their job by a process called Electrophoresis. First we suspend the DNA in a solution of Agarose. Then an electric is applied, on end is + and the other -. DNA forms ions, like most substances that dissolve in water. It separates into H+ and DNA-.

The DNA will move toward the + end through the Agarose. Since the Agarose will stop many of the bigger pieces but the pieces that were cut will pass through because they are smaller. Using a chemical called Ethidium Bromide (E tBr) and UV light we can see how far our DNA made the journey. The farther it went the smaller the pieces and the smaller the pieces the better the Restriction Enzymes worked.

The next step involves three chemicals; the two separated plasmids and a T 4 legator. Mixing these three together should form one final strand. The two pieces will be ligated to form the correct genome. The next step is to put the new resistant strand of DNA back into the E. Coli. This process involves mainly hot and cold water. The DNA will be put in a iced solution with the cells.

The cells should have small holes in them to let the plasmid back in. They will then be shocked by putting them in a hot water bath for two minutes and then put back into the ice. The shock should open up the cell long enough for the plasmids to get through. If the plasmid makes it through, the cell should accept the new plasmid and start producing the resistance enzyme to Chloraphenicol and Ampicillin. The next and final part of the experiment is referred to as plating out. The process involves four petri dishes, each divided in half.

Each petri dish contains a different substance. There is a Luria Broth (LB) plate (Luria Broth is a excellent nutrient source for the E. Coli), a Chloraphenicol plate (CAM), an Ampicillin plate (AMP) and a Chloraphenicol and Ampicillin plate (CAM+AMP). We spread our new E. Coli over each plate and let it stand for 36 hours. The following results took place. LB AMP CAM CAM / AMP growth = + + +- + +- none = - little = +- What these results mean is the following: Since there is growth on the Luria Broth solution the cells are still alive and are able to reproduce; Since only two very tiny colonies grew on the AMP plate we can assume that only a very few gained the Ampicillin resistance; Since there was growth all over the Chloraphenicol we can assume that the cells have been altered and that they can now grow in a antibacterial environment that would have once killed them; Since there was only very little growth on the Ampicillin and Chloraphenicol plate I will have to assume that the plate had either too much Ampicillin or that just the presence of it in cell growth will kill cells. The PCR lab was the second lab we did.

PCR which stands for Polymerase chain reaction. The main purpose of this lab was to extract our own DNA from our cheek cells, prepare in for the PCR and then put it in the PCR machine. What PCR does and allows us to do is make indefinite copies of DNA. Not just the whole strand, nature does that for us, but we can copy just part of the DNA for intense studies.

The first part of the lab is to extract our own cells for the project. We did this by gargling with a saline solution for one minute while we bit our cheeks. I was incredibly sick with a fever at the time so this might have affected my results. The next part is to get the cells ready for the machine. To do this we mixed the cells in a micropipeter with a substance called Che lex. We then mixed our buccal cells with two compounds called Master Mix I and Master Mix II.

Now is the most important part, the thermalcycler. The thermalcycler's main purpose is to break down the DNA in to small parts. The hydrogen bonds around the base pairs break apart and the DNA is suspended in the solution. The next and final step in the lab is to run a gel electrophoresis on the sample. After adding the loading buffer you can run the gel. The expected results should be that the well in which we loaded the solution into is now a bright glowing color and the band start bright and eventually fade into black.

What the lab actually tested was the presence of a genome called tPA-25-ALU. tPA-25-ALU is a gene inside the tPA gene (which everyone has a copy of) which is not found in all people since it is an inherited trait. We have either 2, 1 or 0 copies of it in our body. The reason that that specific part of the gene was targeted was the different Primers we used. The primer selects the certain gene in want to copy by it's nucleotide sequence. It then saves that part and replicates it because it is the only strand in the entire PCR mix to reproduce.

I think that the fact that the wells were glowing means that the PCR did work and that the glowing product in the wells is the product of the PCR experiment. This is because in the PCR machine all the DNA is separated and jumbled, the primer helps to form the only full DNA structure so when we added the yellow loading buffer it could only bond with the full DNA which was the tPA-25-ALU.