User:Lu Wang/Notebook/Team Allergy/2010/06/17: Difference between revisions
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==Gel Electrophoresis | ==Procedures== | ||
'''Gel Electrophoresis''' | |||
Today, we loaded gel slots to run our 6 DNA samples against a 1kb ladder. The order of our slots were: ladder, ladder, sense 1, sense 1, sense 2, sense 2, sense 3, sense 3, antisense 1, antisense 1, antisense 2, antisense 2, antisense3, and antisense 3. We had to load two slots because there was more than 50 microliters of DNA and it would not fit into one slot. We also loaded two ladders. We ran the gel for 30 minutes at 100 volts. Our goal is to have the majority of the amplified DNA to be 300bps long. | Today, we loaded gel slots to run our 6 DNA samples against a 1kb ladder. The order of our slots were: ladder, ladder, sense 1, sense 1, sense 2, sense 2, sense 3, sense 3, antisense 1, antisense 1, antisense 2, antisense 2, antisense3, and antisense 3. We had to load two slots because there was more than 50 microliters of DNA and it would not fit into one slot. We also loaded two ladders. We ran the gel for 30 minutes at 100 volts. Our goal is to have the majority of the amplified DNA to be 300bps long. | ||
Thirty minutes later, we examined our gel under UV light. All of the DNA were smaller than 100bp, suggesting that the Phusion Polymerase did not amplify the correct DNA segment. Our sample looks like a primer dimer. | Thirty minutes later, we examined our gel under UV light. All of the DNA were smaller than 100bp, suggesting that the Phusion Polymerase did not amplify the correct DNA segment. Our sample looks like a primer dimer. | ||
==The Next Step...== | ==The Next Step...== |
Revision as of 11:23, 17 June 2010
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ProceduresGel Electrophoresis Today, we loaded gel slots to run our 6 DNA samples against a 1kb ladder. The order of our slots were: ladder, ladder, sense 1, sense 1, sense 2, sense 2, sense 3, sense 3, antisense 1, antisense 1, antisense 2, antisense 2, antisense3, and antisense 3. We had to load two slots because there was more than 50 microliters of DNA and it would not fit into one slot. We also loaded two ladders. We ran the gel for 30 minutes at 100 volts. Our goal is to have the majority of the amplified DNA to be 300bps long. Thirty minutes later, we examined our gel under UV light. All of the DNA were smaller than 100bp, suggesting that the Phusion Polymerase did not amplify the correct DNA segment. Our sample looks like a primer dimer. The Next Step...If our Phusion Polymerase had worked, then we would have continued to extract the correctly formed DNA segments, performed a restriction digest and cut the PCR products into a B0120 biobrick with Xba1 and Pst1, ligate, and transform into E. coli. However, since we do not have the correct DNA, we cannot move forward. Errors and Correction Attempts There are several reasons for why our gel did not work. The most likely reasons is that the RNA extraction did not work properly. We used strawberry fruit as our sample for RNA extraction. Because RNA is constantly being degraded by RNAases, the integrity of our RNA may have been compromised before the addition of the denaturant.We will re-extract DNA from our plant samples, now including arabidopsis, probably tomorrow. Another potential error could have occurred during the Phusion Polymerase. We set our annealing temperature at 72°C, which could have been too high for three of our four primers. We'll rerun our PCR with a gradient PCR of annealing temperatures to see if we can get a better result. The amount of DNA added by template was also much higher than the optimal 50~250 nanograms per 50 micrograms of PCR reactants. We will dilute the DNA templates to 100 micromolar and use one microliter per reaction so that there are approximately 100 nanograms of DNA per reaction.
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