Revision as of 12:13, 7 October 2009

Project introduction. Inspired by the natural regulator of circadian bioclock exhibited in most eukaryotic organisms, our team has designed an E.coli-based genetic network with the toxin-antitoxin system so that the bacterium oscillates between two states of dormancy and activity (more...)

Protocols

Standard biobrick preparation

Centrifuge the distribution plates for a while so that the dry DNA precipitates onto the bottom of the wells;
Penetrate the aluminum foil with the tip of a pipette (Caution: avoid damaging other wells);
Add 15μl double-distilled water (ddH2O);
Take 1~2μl to perform following operations.

Transduction

Set the water bath to 42℃;
Mark and place an EP tube of E.coli competent cells (ca.100μl) in a freezing box;
Add 1~2μl plasmid solution and leave the tube in the freezing box for 30min;
Heat shock the cells in the water bath for an exact time of 90s;
Take out the tube and place it in the ice box for another 5min;
Add 400μl (or 1000μl) of liquid medium into the tube and mark it;
Shaking cultivate at 37℃ for 0.5~2h; meanwhile prepare the culture plates with corresponding antibiotic in the medium;
Inoculate and cultivate the plates upside-down in a 37℃ incubator for 12~14h.

E.coli culture

Add antibiotics of 0.1% concentration into a culture tube with 4~5ml liquid medium inside;
Pick a single colony with a pipette tip from a culture plate and inoculate it into the liquid medium;
Shaking culture in a 37℃ incubator overnight (ca. 12~16h).

Bacterium strain storage

Prepare a 1.5ml EP tube and mark it;
Add 400μl of 80% glycerin into the tube;
Add 600μl of cultivated liquid medium into the tube;
Store the tube in a -80C℃ fridge.

Agarose gel electrophoresis

Gel preparation:
- Ingredients:
  - (for a smaller piece of gel) 0.3g of agarose + 30ml of TBE + 4μl of EB;
  - (for a larger piece of gel) 0.8g of agarose + 80ml of TBE + 4μl of EB;

Weigh out the required amount of agarose powder onto a piece of weighing paper;
Add the agarose powder into a glass bottle specific for gel preparation;
Add the required amount of TBE buffer into the bottle;
Microwave the liquid with the bottle lid slightly open until it boils, so that the agarose powder gets well dissolved; meanwhile prepare the gel plates and ensure the right comb is fixed;
Cool the bottle in a sink;
When the solution feels warm but not hot (ca.60℃), add the required amount of EB with a pipette specific for gel preparation into the bottle;
Shake the bottle carefully so that the EB is well mixed;
Pour the liquid onto the gel plate;
Wait for the liquid to be cured.

Spotting:

Place a disposable glove on the experiment table;
Pipette correct amounts of loading buffer (so that the buffer will be diluted to a correct concentration) onto the glove to form a lane of buffer drops;
Pipette correct amounts of samples into the buffer drops and mix them well;
Pipette the correct DNA ladder (or marker) into a gel lane, usually the first or the middle-most one;
Pipette the mixed samples into lanes of the gel; watch out for possible leakage which occurs when the pipette tip gets too deep and penetrates through the gel lane.

Electrophoresis:
- Voltage selection:
  - (for a general resolution) 160V;
  - (for a high resolution) 120V (and correspondingly longer electrophoresis time);

After spotting the samples, install the lid of electrophoresis chamber and switch the output on;
When the fastest lane runs to the center (or 2/3 the length if follow-up gel purification is intended) of the gel, switch off the output and transfer the gel into the UVP system;
Power on UVP and observe the gel; take photos when necessary;
Switch off the system and discard the gel into a special rubbish bin.

Double digestion

System selection:
- For identification only, choose the 20μl system;
- For following ligation, choose the 100μl system;
Refer to the Takara inventory for the correct buffer. Take EcoRI and PstI for an example:
- 20μl system:
  - 0.5μl EcoRI
  - 0.5μl PstI
  - 2μl 1*H
  - 10μl plasmid (100ng/μl)
  - 7μl ddH2O
- 100μl system:
  - Plasmid 30μl (100ng/μl)
  - EcoRI 3μl
  - PstI 3μl
  - 1*H 10μl
  - ddH2O 54μl

Prepare the system on a freezing box;
Place the system under 37℃ temperature for 2~3h (for identification) or 9~12h (for ligation).

Tips for digestion

Better limit the volume of restriction enzymes to less than 1/10 of the whole system, for the star activity would be enhanced under high concentration conditions. In most cases it is about 1/20 of the whole system.
To avoid the case in which DNA concentration is too low and hence electrophoresis yields no result, ensure a minimum DNA amount of 50ng.
For identification only, an estimated amount of 0.5μl of enzyme (8~20U) should correspond to 1μg of DNA; For ligation, 1μl of enzyme to 1μg of DNA.
For identification only, a digestion time of 2~3h is enough; for ligation it’s better to leave the system overnight, otherwise massive false positive colonies would occur during the following steps of transduction and culture.

@@ Line 2: / Line 2: @@
 {{Template:SJTU09_menubar}}
 =Protocols=
-How we extracted our plasmids >.<
+==Standard biobrick preparation==
+#Centrifuge the distribution plates for a while so that the dry DNA precipitates onto the bottom of the wells;
+#Penetrate the aluminum foil with the tip of a pipette (Caution: avoid damaging other wells);
+#Add 15μl double-distilled water (ddH2O);
+#Take 1~2μl to perform following operations.
-Here is the content to be editted. Please leave the templates intact when you have finished editting the contents.
+==Transduction==
+#Set the water bath to 42℃;
+#Mark and place an EP tube of E.coli competent cells (ca.100μl) in a freezing box;
+#Add 1~2μl plasmid solution and leave the tube in the freezing box for 30min;
+#Heat shock the cells in the water bath for an exact time of 90s;
+#Take out the tube and place it in the ice box for another 5min;
+#Add 400μl (or 1000μl) of liquid medium into the tube and mark it;
+#Shaking cultivate at 37℃ for 0.5~2h; meanwhile prepare the culture plates with corresponding antibiotic in the medium;
+#Inoculate and cultivate the plates upside-down in a 37℃ incubator for 12~14h.
+==E.coli culture==
+#Add antibiotics of 0.1% concentration into a culture tube with 4~5ml liquid medium inside;
+#Pick a single colony with a pipette tip from a culture plate and inoculate it into the liquid medium;
+#Shaking culture in a 37℃ incubator overnight (ca. 12~16h).
+==Bacterium strain storage==
+#Prepare a 1.5ml EP tube and mark it;
+#Add 400μl of 80% glycerin into the tube;
+#Add 600μl of cultivated liquid medium into the tube;
+#Store the tube in a -80C℃ fridge.
+==Agarose gel electrophoresis==
+*Gel preparation:
+**Ingredients:
+***(for a smaller piece of gel) 0.3g of agarose + 30ml of TBE + 4μl of EB;
+***(for a larger piece of gel) 0.8g of agarose + 80ml of TBE + 4μl of EB;
+#Weigh out the required amount of agarose powder onto a piece of weighing paper;
+#Add the agarose powder into a glass bottle specific for gel preparation;
+#Add the required amount of TBE buffer into the bottle;
+#Microwave the liquid with the bottle lid slightly open until it boils, so that the agarose powder gets well dissolved; meanwhile prepare the gel plates and ensure the right comb is fixed;
+#Cool the bottle in a sink;
+#When the solution feels warm but not hot (ca.60℃), add the required amount of EB with a pipette specific for gel preparation into the bottle;
+#Shake the bottle carefully so that the EB is well mixed;
+#Pour the liquid onto the gel plate;
+#Wait for the liquid to be cured.
+*Spotting:
+#Place a disposable glove on the experiment table;
+#Pipette correct amounts of loading buffer (so that the buffer will be diluted to a correct concentration) onto the glove to form a lane of buffer drops;
+#Pipette correct amounts of samples into the buffer drops and mix them well;
+#Pipette the correct DNA ladder (or marker) into a gel lane, usually the first or the middle-most one;
+#Pipette the mixed samples into lanes of the gel; watch out for possible leakage which occurs when the pipette tip gets too deep and penetrates through the gel lane.
+*Electrophoresis:
+**Voltage selection:
+***(for a general resolution) 160V;
+***(for a high resolution) 120V (and correspondingly longer electrophoresis time);
+#After spotting the samples, install the lid of electrophoresis chamber and switch the output on;
+#When the fastest lane runs to the center (or 2/3 the length if follow-up gel purification is intended) of the gel, switch off the output and transfer the gel into the UVP system;
+#Power on UVP and observe the gel; take photos when necessary;
+#Switch off the system and discard the gel into a special rubbish bin.
+==Double digestion==
+*System selection:
+**For identification only, choose the 20μl system;
+**For following ligation, choose the 100μl system;
+*Refer to the Takara inventory for the correct buffer. Take EcoRI and PstI for an example:
+**20μl system:
+***0.5μl EcoRI
+***0.5μl PstI
+***2μl 1*H
+***10μl plasmid (100ng/μl)
+***7μl ddH2O
+**100μl system:
+***Plasmid 30μl (100ng/μl)
+***EcoRI 3μl
+***PstI 3μl
+***1*H 10μl
+***ddH2O 54μl
+#Prepare the system on a freezing box;
+#Place the system under 37℃ temperature for 2~3h (for identification) or 9~12h (for ligation).
+==Tips for digestion==
+#Better limit the volume of restriction enzymes to less than 1/10 of the whole system, for the star activity would be enhanced under high concentration conditions. In most cases it is about 1/20 of the whole system.
+#To avoid the case in which DNA concentration is too low and hence electrophoresis yields no result, ensure a minimum DNA amount of 50ng.
+#For identification only, an estimated amount of 0.5μl of enzyme (8~20U) should correspond to 1μg of DNA; For ligation, 1μl of enzyme to 1μg of DNA.
+#For identification only, a digestion time of 2~3h is enough; for ligation it’s better to leave the system overnight, otherwise massive false positive colonies would occur during the following steps of transduction and culture.
 {{Template:SJTU09_enddiv}}

Team:SJTU-BioX-Shanghai/Protocols

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Revision as of 12:13, 7 October 2009

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