BME103:W930 Group1

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Contents

OUR TEAM

Name: Kevin ChuExperimental Protocol Planner
Name: Kevin Chu
Experimental Protocol Planner
Name: Michael DennisonExperimental Protocol Planner
Name: Michael Dennison
Experimental Protocol Planner
Name: Zhiyue YangMachine Engineer
Name: Zhiyue Yang
Machine Engineer
Name: StudentRole(s)
Name: Student
Role(s)
Name: StudentRole(s)
Name: Student
Role(s)

LAB 1 WRITE-UP

Initial Machine Testing

The Original Design
Image:Open_PCR_with_labels.png)
Original design of the Open PCR machine showing inner mechanisms. As the image shows, this Open PCR machine primarily consists of 5 parts, which are LCD screen, heating lid, heater, circuit board and fan. While the machine is portable and easy to use, the design is fragile and has a high failure rate, along with several other design flaws.

Experimenting With the Connections

When we unplugged part LCD screen from the circuit board, the machine's screen stopped displaying.

When we unplugged the white wire that connects the circuit board to the heated lid, the machine stopped controlling the temperature.


Test Run

During our first test run on October 24, 2012, the machine's fan would not work and therefore we could not complete the DNA replication.




Protocols

Polymerase Chain Reaction

How PCR Works
Polymerase chain reaction (PCR) is a process that amplifies minute quantities of DNA in order to obtain a sufficient number of samples for analysis. DNA is a useful health marker and can predict the likelihood that a patient has cancer. During PCR, the double helix structure is unzipped to expose the bases. DNA primer is added to the DNA solution and binds to the gene that causes cancer. Because a non-cancer gene has a different nucleotide sequence from the cancer gene, the primer will not be able to attach to the exposed bases, so the DNA cannot be amplified. DNA amplification involves a sequence of steps called thermal cycling.

Thermal Cycling
1. To separate complementary base pairs, the sample was heated at 95°C for two minutes.
2. During annealing, the temperature was decreased to 57°C to allow the specific primers to attach. This step usually lasts between 30 seconds and one minute.
3. During extension, the temperature is increased to 72°C for one minute to allow Taq DNA polymerase to bind deoxynucleoside triphosphates (dNTPs) on the template DNA, lengthening the synthetic strand.
4. To obtain a sufficient number of samples, the process was repeated 30 times.

Components of the PCR master mix

• 2X Colorless Go Taq ® Reaction Buffer (pH 8.5)
• 400μM dATP
• 400μM dGTP
• 400μM dCTP
• 400μM dTTP
• 3mM MgCl2


Reagent Volume
Template DNA (20 ng)0.1μL
10μM forward primer0.5μL
10μM reverse primer0.5μL
GoTaq master mix25.0μL
dH2O23.9μL
Total Volume50.0μL

Positive Control
Cancer DNA template

Negative Control
DNA Template

Patient 1
Replicate 1
ID: 92336
Gender: Male
Age: 58

Patient 1
Replicate 2
ID: 92336
Gender: Male
Age: 58

Patient 1
Replicate 3
ID: 92336
Gender: Male
Age: 58

Patient 2
Replicate 1
ID: 44606
Gender: Male
Age: 47

Patient 2
Replicate 2
ID: 44606
Gender: Male
Age: 47

Patient 2
Replicate 3
ID: 44606
Gender: Male
Age: 47



Flourimeter Measurements





Research and Development

Specific Cancer Marker Detection - The Underlying Technology

The primer sequence of the single nucleotide polymorphism (SNP) that is linked to colorectal cancer is GGAAGTGGGTCCTAAAAACTCTTACA[C/T]TGCATACATAGAAGATCAGAGTGGC. The gene being affected is CHK2 (checkpoint kinase 2). The allele change is from T to C, which signifies the cancer sequence. The cancer sequence-binding primer, or the reverse primer, is AACTCTACA[C]TGCATACAT. The coordinate of the cancer base pair "C" is at 29,121,087 of the DNA sequence. 20 base pairs (bp) to the left of the cancer sequence was TA, which occurred at coordinate 29,121,067.

Baye's reasoning and statistical formulas can be applied to find the link between the development of cancer and the presence of the cancer gene. In a sample size of 180 patients, 1.1% of contained a single copy of the colorectal cancer (CRC) gene in their DNA (C/T) and 98.9% had no copy of the cancer gene (T/T). According to Baye's rule, the probability of having cancer and also expressing the "C" cancer gene is 1.1% when the probability of expressing the "C" gene and also having cancer is 7.8%, the probability of having cancer is unknown, and standard probability of having cancer over the population is 5.3%. Therefore, the probability of having cancer with the "C" gene is 0.74%.

(BONUS points: Use a program like Powerpoint, Word, Illustrator, Microsoft Paint, etc. to illustrate how primers bind to the cancer DNA template, and how Taq polymerases amplify the DNA. Screen-captures from the OpenPCR tutorial might be useful. Be sure to credit the source if you borrow images.)




Results

Sample Integrated Density DNA μg/mL Conclusion
PCR: Negative Control E6 F6 G6
PCR: Positive Control E7 F7 G7
PCR: Patient 1 ID 92336, rep 1 E8 F8 G8
PCR: Patient 1 ID 92336, rep 2 E9 F9 G9
PCR: Patient 1 ID 92336, rep 3 E10 F10 G10
PCR: Patient 2 ID 44606, rep 1 E11 F11 G11
PCR: Patient 2 ID 44606, rep 2 E12 F12 G12
PCR: Patient 2 ID 44606, rep 3 E13 F13 G13


KEY

  • Sample =
  • Integrated Density =
  • DNA μg/mL =
  • Conclusion =
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