Difference between revisions of "20.109(S08):Site-directed mutagenesis (Day2)"
(→Part 3: prepare tubes for liquid O/N cultures) |
(→Protocols) |
||
Line 13: | Line 13: | ||
===Part 2: site-directed mutagenesis=== | ===Part 2: site-directed mutagenesis=== | ||
− | We will be using the QuickChange® kit from Stratagene to perform our site-directed mutageneses. Each group will set up | + | We will be using the QuickChange® kit from Stratagene to perform our site-directed mutageneses. Each group will set up two reactions. Meanwhile, your TA will set up a single positive control reaction, to ensure that all the reagents are working properly. You should work quickly but carefully, and keep your tubes in a chilled container at all times. |
− | #Read through the following protocol and | + | #Read through the following protocol and prepare all calculations before beginning physical manipulations of your samples. |
#You will be given an X μL mixture that contains buffer and dNTPs when you are ready to begin. Aliquot 40 μL per tube. | #You will be given an X μL mixture that contains buffer and dNTPs when you are ready to begin. Aliquot 40 μL per tube. | ||
− | #Add 2 μL of template DNA (“IPC plasmid”) to each of your | + | #Add 2 μL of template DNA (“IPC plasmid”) to each of your two reaction tubes. |
#*Note: mutagenesis reactions are expected to run smoothly with 5-50 ng of plasmid DNA. You have been given a 1:200 dilution of miniprep DNA. | #*Note: mutagenesis reactions are expected to run smoothly with 5-50 ng of plasmid DNA. You have been given a 1:200 dilution of miniprep DNA. | ||
− | #Increase the volume of each reaction to 50 μL by adding the appropriate amount of water | + | #Increase the volume of each reaction to 50 μL by adding the appropriate amount of water. |
#Finally, add 1 μL of ''PfuTurbo'' DNA polymerase to each reaction. | #Finally, add 1 μL of ''PfuTurbo'' DNA polymerase to each reaction. | ||
#Once each group is ready, we will begin the thermocycler, under the following conditions: | #Once each group is ready, we will begin the thermocycler, under the following conditions: | ||
Line 63: | Line 63: | ||
#Tomorrow, two candidate colonies will be chosen from each plate. The efficiency of this mutagenesis protocol is reported to be 80%. We will sequence two candidates per mutation to cover our bases, so to speak. | #Tomorrow, two candidate colonies will be chosen from each plate. The efficiency of this mutagenesis protocol is reported to be 80%. We will sequence two candidates per mutation to cover our bases, so to speak. | ||
− | ===Part 3: | + | ===Part 3: Prepare tubes for liquid O/N cultures=== |
− | You will make your teaching | + | You will make your teaching faculty very happy if you contribute to their preparatory work. Please label 4 large glass test tubes with your team color and sample name. Mix 12 ml LB with 12 μL each of ampicillin and chloramphenicol. Aliquot 2.5 mL of LB+Amp/Cam per tube. These will be used to set up overnight cultures for you for next time. |
===Part 4: journal article discussion=== | ===Part 4: journal article discussion=== |
Revision as of 20:43, 20 December 2007
Contents
Introduction
Protocols
Part 1: primer preparation
- Calculate the amount of water needed for each primer to give a concentration of 1 ng/mL.
- Touch-spin your primers, resuspend each in the appropriate volume of water, and touch-spin again.
- Calculate the dilution of primer that you need to prepare in order to have 125 ng present in 2.5 μL. Prepare 100-200 μL of this dilution and keep it on ice.
Part 2: site-directed mutagenesis
We will be using the QuickChange® kit from Stratagene to perform our site-directed mutageneses. Each group will set up two reactions. Meanwhile, your TA will set up a single positive control reaction, to ensure that all the reagents are working properly. You should work quickly but carefully, and keep your tubes in a chilled container at all times.
- Read through the following protocol and prepare all calculations before beginning physical manipulations of your samples.
- You will be given an X μL mixture that contains buffer and dNTPs when you are ready to begin. Aliquot 40 μL per tube.
- Add 2 μL of template DNA (“IPC plasmid”) to each of your two reaction tubes.
- Note: mutagenesis reactions are expected to run smoothly with 5-50 ng of plasmid DNA. You have been given a 1:200 dilution of miniprep DNA.
- Increase the volume of each reaction to 50 μL by adding the appropriate amount of water.
- Finally, add 1 μL of PfuTurbo DNA polymerase to each reaction.
- Once each group is ready, we will begin the thermocycler, under the following conditions:
Segment | Cycles | Temperature (° C) | Time |
---|---|---|---|
1 | 1 | 95 | 30 sec |
2 | 18 | 95 | 30 sec |
55 | 1 min | ||
68 | 5 min | ||
3 | 1 | 4 | indefinite |
- After the cycling is completed, each group should add 1 μL of DpnI per tube. Samples will be incubated for one hour at 37 ° C. You will be asked to consider why in your homework assignments.
- This final incubation step will take us past lab closing time, at which point the teaching staff will take over. Each reaction will be transformed into XL1-Blue competent cells under delicate conditions. (*define procedure in note below).
- Tomorrow, two candidate colonies will be chosen from each plate. The efficiency of this mutagenesis protocol is reported to be 80%. We will sequence two candidates per mutation to cover our bases, so to speak.
Part 3: Prepare tubes for liquid O/N cultures
You will make your teaching faculty very happy if you contribute to their preparatory work. Please label 4 large glass test tubes with your team color and sample name. Mix 12 ml LB with 12 μL each of ampicillin and chloramphenicol. Aliquot 2.5 mL of LB+Amp/Cam per tube. These will be used to set up overnight cultures for you for next time.
Part 4: journal article discussion
During the production of the mutagenized DNA, we will discuss the following journal article (link). The purpose of this discussion will be two-fold: 1) to familiarize ourselves with the history of our protein of interest ??and/or?? the state-of-the-art in protein design, 2) to explore ways of talking about the scientific literature.