Imperial/Wet Lab/Protocols/ID2.1

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==Protocols for DNA concentration experiments==
 +
Experiments to be carried out are to determine the optimum concentration of the ID and CBD constructs, in-vitro, so that we get the highest level of protein expression after a period of 6hours. The two constructs to be tested are pTet-luxR-pLux-GFP and pTet-GFP.  <br>
 +
<br>The concentrations of DNA that will be tested are: 1, 2, 4 and 6&micro;g. For ID construct, Each concentration of DNA will be tested over a period of 6 hours at 25°C, as it is expected that the system will respond within about 2-3 hours to AHL (50nM). For ID the samples will be kept at 37&deg;C. The evaporation of the samples will be taken into account when analysing the data. 
-
= Wet Lab: Protocols: Preliminary AHL Testing  =
+
'''Aims'''
 +
*To determine the concentration of pLux construct for which the response to AHL (at 50nM) being induced is optimum, in terms of the reponse time and the output fluorescence at the end of the experiment time.
 +
*To determine the concentration of pTet construct for which output is optimum, in terms of the reponse time and the output fluorescence at the end of the experiment time.
-
'''Aims:'''
 
-
*To make a rough estimate of the sensitivity of the system to a large range of AHL concentrations
 
-
*To determine approximations of the threshold of response, time of response, life span and rate of GFP produced
 
-
 
-
==Day 1==
 
===Equipment===
===Equipment===
-
*Eppendorf Tubes
+
*Fluorometer + PC  
-
*Gilson pipettes p1000, p200, p20, p10
+
*25°C water bath  
-
===Reagents===
+
*Fluorometer plate (black)
-
*AHL stock solution of 1mM
+
-
*Nuclease free water
+
-
===Protocols===
+
-
*Prepare AHL serial dilutions for experiment, to make up a total of 100nM, 50nM and 10nM
+
-
*Using stock solution of 1mM of AHL, carry out the following dilutions using nuclease free water:
+
-
#Add 2.1ul of AHL to 997.9ul of water in an eppendorf tube, making up solution A.
+
-
#Remove 10ul from solution A into another eppendorf tube and add another 10ul of water, making up solution B.
+
-
#Remove 1ul of solution A into the third eppendorf tube and add 9ul of water to it, making up solution C.
+
-
 
+
-
 
+
-
==Day 2==
+
-
===Equipments===
+
-
*Fluorometer + PC
+
-
*Water bath in cold room at 10&deg;C/15&deg;C/20&deg;C
+
-
*25&deg;C water bath
+
-
*1 Fluorometer plate (black)
+
*Sticky seal tape
*Sticky seal tape
-
*Gilson pipettes p200 p20 p10
+
*Gilson pipettes 200, 20, 10
-
*Eppendorf Tubes
+
*Eppendorf Tubes x 7
*Stopwatch
*Stopwatch
 +
*Foil
===Reagents===
===Reagents===
Line 41: Line 25:
**450µl S30 Extract, Circular (3 × 150µl)
**450µl S30 Extract, Circular (3 × 150µl)
**750µl S30 Premix Without Amino Acids
**750µl S30 Premix Without Amino Acids
-
*Nuclease Free water
+
*Nuclease Free water x1ml
-
*AHL solutions A B C
+
*DNA pTet-GFP from midiprep
-
*DNA pTet-LuxR-pLux-GFP from midiprep
+
-
===Protocols===
+
===Preparation of reactions===
-
#First collect all equipment and reagents and ensure that the fluorometer and that the PC connected has a data collection protocol installed.
+
#First collect all equipment and reagents and ensure that the fluorometer and the PC connected has a data collection protocol installed.  
-
#Place the 96 well plates together with their plate mates in their respective incubators so as to heat them up to the appropriate temperature before the experiments start.
+
#Place one of the 96well plates into the 25&deg;C water bath and the other in the 37&deg;C incubator.
-
#For the next step of the go to the biochemistry level 5 and remove:
+
#For the cell extract, get the following out of the cell extract kit:
-
#*A.A's from kits
+
#*A.A's from kits  
-
#*Premix tubes (140ul)
+
#*Premix tube
-
#*S30 tubes (105ul)
+
#*S30 tubes
-
#'''For each AHL concentration Tested Prepare the following'''
+
#To prepare the commercial E.coli Cell Extract, carry out the following Procedure, two times:<br>
-
#''Commercial E.coli Cell Extract'': First prepare a complete amino acid mixture for both extract solutions: Add the 17.5μl volume of two amino acid minus mixtures into an labeled eppendorf to give a volume of 35μl. Each amino acid minus mixture is missing one type of amino acid, and so by combining two solutions we are complementing each solution for the missing amino acid. Place eppendorf in a rack on bench.  
+
##First prepare a complete amino acid mixture for the extract solution: Add the 25µl volume of two amino acid minus mixtures into an labeled eppendorf to give a volume of 50µl. Each amino acid minus mixture is missing one type of amino acid.  
-
#''Commercial E.coli Cell Extract'':Add all of the E.coli complete amino acid mixture to S30 Premix Without Amino Acid and 45µl of S30 Extract Circular. Place the eppendorf tube in a rack on the bench.  
+
##Take an eppendorf tube and add the 50µl of the E.coli complete amino acid mixture.
-
#Vortex the tubes to mix thoroughly and place 40ul into each well-B4, B6, C5, C7, D2, D4, and E8.
+
##Add 200µl of S30 Premix (Without Amino Acid) into the eppendorf tube.
-
#Place 20ul of midipreped DNA plasmid into each of the filled wells.
+
##Then add 150µl of S30 Extract Circular too.  
 +
##The final volume of cell extract is: 400&micro;l
 +
##Any left over premix or cell extract should be returned to the freezer (biochemistry level 5) and labeled with new volumes.
 +
#Each cell extract will be used to test one of the constructs. Label the tubes, identifying which construct it will be used for.
 +
#Incubate cell extract mixture for ID in the water bath set at 25&deg;C and the one for CBD in the 37&deg;C incubator.
 +
#Get 30&micro;l out of the 1000nM stock solution of AHL and put in to the eppendorf tube with the cell extract for the pLux construct. This will give a AHL concentration of 50nM in the final 60&micro;l of the samples. Incubate the eppendorf tube in the 25&deg;C water bath.
 +
#Prepare the different DNA concentrations for pLux construct(concentration of pLux DNA = 460ng/&micro;l):
 +
##Concentration 1 = 1&micro;g: Add 4.4&micro;l of DNA in 29.6&micro;l nuclease free water.
 +
##Concentration 2 = 2&micro;g: Add 8.8&micro;l of DNA in 25.2&micro;l nuclease free water.
 +
##Concentration 3 = 4&micro;g: Add 17.4&micro;l of DNA in 16.6&micro;l nuclease free water.
 +
##Concentration 4 = 6&micro;g: Add 26&micro;l of DNA in 8&micro;l nuclease free water.
 +
#This will give a total volume of 34µl of each DNA concentration. Put each DNA into a seperate, labeled eppendorf tube and place them in the 25&deg;C water bath.
 +
#Prepare the different DNA concentrations for pTet construct(concentration of pTet DNA = 500ng/&micro;l):
 +
##Concentration 1 = 1&micro;g: Add 4&micro;l of DNA in 36&micro;l nuclease free water.
 +
##Concentration 2 = 2&micro;g: Add 8&micro;l of DNA in 32&micro;l nuclease free water.
 +
##Concentration 3 = 4&micro;g: Add 12&micro;l of DNA in 28&micro;l nuclease free water.
 +
##Concentration 4 = 6&micro;g: Add 16&micro;l of DNA in 16&micro;l nuclease free water.
 +
#This will give a total volume of 40µl of each DNA concentration. Put each DNA into a seperate, labeled eppendorf tube and place them in the 37&deg;C water bath.
-
 
+
===Loading Plate===
-
====Schematic====
+
#Take the plate out of the incubation.
-
*Throughout our series of experiments we are reusing the 96 well plates. It is important to measure each plate before the schematic is determined, this is to prevent any contamination.  
+
#For the pLux construct:
-
*Using the protocol above using wells near the edge should be avoided and the wells spread out throughout the plate
+
##Follow the schematic for the plate 1 (25&deg;C water bath) and begin by loading 43&micro;l of the in vitro expression system with AHL into the right wells.  
-
*Add 3ul of solution A to two wells B4 and B6. [AHL]=100nM
+
##Tap down the top of the plate to bring down any solution to bottom of the well.  
-
*Add 3ul of solution B to two wells C5 and C7. [AHL]=50nM
+
##Then add 17µl of purified DNA sample to each well, as indicated on the schematic. Be careful not to add to wells that DO NOT NEED DNA.
-
*Add 3ul of solution C to two wells D2 and D4. [AHL]=10nM
+
##Add 17&micro;l of nuclease free water into the two negative control wells, as shown in the schematics.
-
*Add 3ul of nuclease free water to well E8.   [AHL]=0nM
+
#For the pTet construct:
-
 
+
##Follow the schematic for the plate 2 (37&deg;C incubator) and begin by loading 40&micro;l of the in vitro expression system into the right wells.  
-
====Loading Plate====
+
##Tap down the top of the plate to bring down any solution to bottom of the well.  
-
#Follow the schematic for the plate and begin by loading the in vitro expression system into the correct wells. Before loading in the samples vortex the tubes for a few seconds to mix the solution.
+
##Then add 20µl of purified DNA sample to each well, as indicated on the schematic. Be careful not to add to wells that DO NOT NEED DNA.
-
#Tap down the top of the lid to bring down any solution to bottom of the well.
+
##Add 20&micro;l of nuclease free water into the two negative control wells, as shown in the schematics.
-
#Remove lid off the 96 well plate and place in the fluorometer. Create a file name '''insert temp''' underD:\IGEM\'''INSERT DATE'''\ID\ 25oC. Export the data here. Each file should be named as the following:
+
#Put 60&micro;l of water into some empty wells in the middle of each plate. These will be used to check for evaporation.
-
#* construct-temp-time-date
+
#After the DNA and the cell extract mixtures have been put into their respective wells, load the program on the PC to measure the fluorescence in the right wells.  
-
#This measurement will give a back ground fluorescence measurement and can be used as our time zero data.
+
#Create a file with name referring to the temperature of the plate, under: D:\IGEM\'''INSERT DATE'''\ID\ OTR , for ID and under D:\IGEM\'''INSERT DATE'''\CBD\ OTR , for CBD construct. The data from the fluoreometer will be exported here.  
-
#Then to begin the reaction add 20μl of purified DNA sample to each well indicated on the schematic. Be careful not to add to wells that DO NOT NEED DNA.
+
#Each file with the reading should be named as the following:  
 +
#*construct-temp-time-date  
#Place the plate in the fluorometer to measure its initial fluorescent reading.  
#Place the plate in the fluorometer to measure its initial fluorescent reading.  
#After the measurement, place the sticky tape across the plate, and put the plate in the 25oC water bath.
#After the measurement, place the sticky tape across the plate, and put the plate in the 25oC water bath.
 +
#Start on the next plate, and repeat procedures 2-6.
 +
#Place the plate in the 37oC water bath.
#Before placing them in the water bath, wrap aluminium foil around them to prevent photobleaching.  
#Before placing them in the water bath, wrap aluminium foil around them to prevent photobleaching.  
-
#Repeat this every 30 minutes for 6 hours.
+
#Stagger the start of both the plates by around 5 minutes.
 +
#Measure the temperature every 30 minutes for each temperature, for 6 hours.
 +
 
 +
===Schematic===
 +
 
 +
====Plate 1====
{| border="1" cellpadding="1"
{| border="1" cellpadding="1"
-
|
+
!<u>Well</u> || <u>Test Construct</u> !! <u> Concentration of DNA</u> !! <u>In vitro chassis</u>  
-
{| border="1" cellpadding="2"
+
-
!<u>Well </u> || <u>Test Construct</u> || <u>Stock Volume (ul)</u> !! <u>AHL (ul)</u> !! <u>Final [AHL]</u>
+
|-
|-
-
|<font color="blue">B4
+
|<font color=blue> E5
-
|<font color="blue">pTet-LuxR-pLux-GFP
+
|<font color=blue> Nuclease Free Water + AHL (Negative control)
-
|<font color="blue">60
+
|<font color=blue> 0&micro;g
-
|<font color="blue">3ul
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|<font color=blue> Commercial E.coli extract
-
|<font color="blue">100nM
+
|-
|-
-
|<font color="blue">B6
+
|<font color=blue> E7
-
|<font color="blue">pTet-LuxR-pLux-GFP
+
|<font color=blue> Nuclease Free Water + AHL (Negative control)
-
|<font color="blue">60
+
|<font color=blue> 0&micro;g
-
|<font color="blue">3ul
+
|<font color=blue> Commercial E.coli extract
-
|<font color="blue">100nM
+
|-
|-
-
|<font color="blue">C5
+
|<font color=blue> C3
-
|<font color="blue">pTet-LuxR-pLux-GFP
+
|<font color=blue> pTet-luxR-pLux-GFP + AHL
-
|<font color="blue">60
+
|<font color=blue> 1&micro;g
-
|<font color="blue">3ul
+
|<font color=blue> Commercial E.coli extract
-
|<font color="blue">50nM
+
|-
|-
-
|<font color="blue">C7
+
|<font color=blue> C5
-
|<font color="blue">pTet-LuxR-pLux-GFP
+
|<font color=blue> pTet-luxR-pLux-GFP + AHL
-
|<font color="blue">60
+
|<font color=blue> 1&micro;g
-
|<font color="blue">3ul
+
|<font color=blue>Commercial E.coli extract
-
|<font color="blue">50nM
+
|-
|-
-
|<font color="blue">D4
+
|<font color=blue> C7
-
|<font color="blue">pTet-LuxR-pLux-GFP
+
|<font color=blue> pTet-luxR-pLux-GFP + AHL (positive control)
-
|<font color="blue">60
+
|<font color=blue> 2&micro;g
-
|<font color="blue">3ul
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|<font color=blue> Commercial E.coli extract
-
|<font color="blue">10nM
+
|-
|-
-
|<font color="blue">D6
+
|<font color=blue> C9
-
|<font color="blue">pTet-LuxR-pLux-GFP
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|<font color=blue> pTet-luxR-pLux-GFP + AHL (positive control)
-
|<font color="blue">60
+
|<font color=blue> 2&micro;g
-
|<font color="blue">3ul
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|<font color=blue> Commercial E.coli extract
-
|<font color="blue">10nM
+
|-
 +
|<font color=blue> D4
 +
|<font color=blue> pTet-luxR-pLux-GFP + AHL
 +
|<font color=blue> 4&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D6
 +
|<font color=blue> pTet-luxR-pLux-GFP + AHL
 +
|<font color=blue> 4&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D8
 +
|<font color=blue> pTet-luxR-pLux-GFP + AHL
 +
|<font color=blue> 6&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D10
 +
|<font color=blue> pTet-luxR-pLux-GFP + AHL
 +
|<font color=blue> 6&micro;g
 +
|<font color=blue> Commercial E.coli extract
|-
|-
-
|<font color="blue">E8
 
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|<font color="blue">pTet-LuxR-pLux-GFP
 
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|<font color="blue">60
 
-
|<font color="blue">0
 
-
|<font color="blue">0
 
|}
|}
-
|
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-
[[Image:Working9.png|450px|top|In vivo Testing 96 well plate]]
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<br=clear all>
 +
 
 +
====Plate 2====
 +
 
 +
{| border="1" cellpadding="1"
 +
!<u>Well</u> || <u>Test Construct</u> !! <u> Concentration of DNA</u> !! <u>In vitro chassis</u>
 +
|-
 +
|<font color=blue> E5
 +
|<font color=blue> Nuclease Free Water (Negative control)
 +
|<font color=blue> 0&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> E7
 +
|<font color=blue> Nuclease Free Water (Negative control)
 +
|<font color=blue> 0&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> C3
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 1&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> C5
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 1&micro;g
 +
|<font color=blue>Commercial E.coli extract
 +
|-
 +
|<font color=blue> C7
 +
|<font color=blue> pTet-GFP (positive control)
 +
|<font color=blue> 2&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> C9
 +
|<font color=blue> pTet-GFP (positive control)
 +
|<font color=blue> 2&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D4
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 4&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D6
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 4&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D8
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 6&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
 +
|<font color=blue> D10
 +
|<font color=blue> pTet-GFP
 +
|<font color=blue> 6&micro;g
 +
|<font color=blue> Commercial E.coli extract
 +
|-
|}
|}
-
<br>
+
 
 +
<br=clear all>
 +
 
 +
-----

Revision as of 13:47, 25 October 2007

Protocols for DNA concentration experiments

Experiments to be carried out are to determine the optimum concentration of the ID and CBD constructs, in-vitro, so that we get the highest level of protein expression after a period of 6hours. The two constructs to be tested are pTet-luxR-pLux-GFP and pTet-GFP.

The concentrations of DNA that will be tested are: 1, 2, 4 and 6µg. For ID construct, Each concentration of DNA will be tested over a period of 6 hours at 25°C, as it is expected that the system will respond within about 2-3 hours to AHL (50nM). For ID the samples will be kept at 37°C. The evaporation of the samples will be taken into account when analysing the data.

Aims

  • To determine the concentration of pLux construct for which the response to AHL (at 50nM) being induced is optimum, in terms of the reponse time and the output fluorescence at the end of the experiment time.
  • To determine the concentration of pTet construct for which output is optimum, in terms of the reponse time and the output fluorescence at the end of the experiment time.

Equipment

  • Fluorometer + PC
  • 25°C water bath
  • Fluorometer plate (black)
  • Sticky seal tape
  • Gilson pipettes 200, 20, 10
  • Eppendorf Tubes x 7
  • Stopwatch
  • Foil

Reagents

  • Commercial S30 E.coli extract. Including:
    • 175µl Amino Acid Mixture Minus Cysteine, 1mM
    • 175µl Amino Acid Mixture Minus Methionine, 1mM
    • 175µl Amino Acid Mixture Minus Leucine, 1mM
    • 450µl S30 Extract, Circular (3 × 150µl)
    • 750µl S30 Premix Without Amino Acids
  • Nuclease Free water x1ml
  • DNA pTet-GFP from midiprep

Preparation of reactions

  1. First collect all equipment and reagents and ensure that the fluorometer and the PC connected has a data collection protocol installed.
  2. Place one of the 96well plates into the 25°C water bath and the other in the 37°C incubator.
  3. For the cell extract, get the following out of the cell extract kit:
    • A.A's from kits
    • Premix tube
    • S30 tubes
  4. To prepare the commercial E.coli Cell Extract, carry out the following Procedure, two times:
    1. First prepare a complete amino acid mixture for the extract solution: Add the 25µl volume of two amino acid minus mixtures into an labeled eppendorf to give a volume of 50µl. Each amino acid minus mixture is missing one type of amino acid.
    2. Take an eppendorf tube and add the 50µl of the E.coli complete amino acid mixture.
    3. Add 200µl of S30 Premix (Without Amino Acid) into the eppendorf tube.
    4. Then add 150µl of S30 Extract Circular too.
    5. The final volume of cell extract is: 400µl
    6. Any left over premix or cell extract should be returned to the freezer (biochemistry level 5) and labeled with new volumes.
  5. Each cell extract will be used to test one of the constructs. Label the tubes, identifying which construct it will be used for.
  6. Incubate cell extract mixture for ID in the water bath set at 25°C and the one for CBD in the 37°C incubator.
  7. Get 30µl out of the 1000nM stock solution of AHL and put in to the eppendorf tube with the cell extract for the pLux construct. This will give a AHL concentration of 50nM in the final 60µl of the samples. Incubate the eppendorf tube in the 25°C water bath.
  8. Prepare the different DNA concentrations for pLux construct(concentration of pLux DNA = 460ng/µl):
    1. Concentration 1 = 1µg: Add 4.4µl of DNA in 29.6µl nuclease free water.
    2. Concentration 2 = 2µg: Add 8.8µl of DNA in 25.2µl nuclease free water.
    3. Concentration 3 = 4µg: Add 17.4µl of DNA in 16.6µl nuclease free water.
    4. Concentration 4 = 6µg: Add 26µl of DNA in 8µl nuclease free water.
  9. This will give a total volume of 34µl of each DNA concentration. Put each DNA into a seperate, labeled eppendorf tube and place them in the 25°C water bath.
  10. Prepare the different DNA concentrations for pTet construct(concentration of pTet DNA = 500ng/µl):
    1. Concentration 1 = 1µg: Add 4µl of DNA in 36µl nuclease free water.
    2. Concentration 2 = 2µg: Add 8µl of DNA in 32µl nuclease free water.
    3. Concentration 3 = 4µg: Add 12µl of DNA in 28µl nuclease free water.
    4. Concentration 4 = 6µg: Add 16µl of DNA in 16µl nuclease free water.
  11. This will give a total volume of 40µl of each DNA concentration. Put each DNA into a seperate, labeled eppendorf tube and place them in the 37°C water bath.

Loading Plate

  1. Take the plate out of the incubation.
  2. For the pLux construct:
    1. Follow the schematic for the plate 1 (25°C water bath) and begin by loading 43µl of the in vitro expression system with AHL into the right wells.
    2. Tap down the top of the plate to bring down any solution to bottom of the well.
    3. Then add 17µl of purified DNA sample to each well, as indicated on the schematic. Be careful not to add to wells that DO NOT NEED DNA.
    4. Add 17µl of nuclease free water into the two negative control wells, as shown in the schematics.
  3. For the pTet construct:
    1. Follow the schematic for the plate 2 (37°C incubator) and begin by loading 40µl of the in vitro expression system into the right wells.
    2. Tap down the top of the plate to bring down any solution to bottom of the well.
    3. Then add 20µl of purified DNA sample to each well, as indicated on the schematic. Be careful not to add to wells that DO NOT NEED DNA.
    4. Add 20µl of nuclease free water into the two negative control wells, as shown in the schematics.
  4. Put 60µl of water into some empty wells in the middle of each plate. These will be used to check for evaporation.
  5. After the DNA and the cell extract mixtures have been put into their respective wells, load the program on the PC to measure the fluorescence in the right wells.
  6. Create a file with name referring to the temperature of the plate, under: D:\IGEM\INSERT DATE\ID\ OTR , for ID and under D:\IGEM\INSERT DATE\CBD\ OTR , for CBD construct. The data from the fluoreometer will be exported here.
  7. Each file with the reading should be named as the following:
    • construct-temp-time-date
  8. Place the plate in the fluorometer to measure its initial fluorescent reading.
  9. After the measurement, place the sticky tape across the plate, and put the plate in the 25oC water bath.
  10. Start on the next plate, and repeat procedures 2-6.
  11. Place the plate in the 37oC water bath.
  12. Before placing them in the water bath, wrap aluminium foil around them to prevent photobleaching.
  13. Stagger the start of both the plates by around 5 minutes.
  14. Measure the temperature every 30 minutes for each temperature, for 6 hours.

Schematic

Plate 1

Well Test Construct Concentration of DNA In vitro chassis
E5 Nuclease Free Water + AHL (Negative control) 0µg Commercial E.coli extract
E7 Nuclease Free Water + AHL (Negative control) 0µg Commercial E.coli extract
C3 pTet-luxR-pLux-GFP + AHL 1µg Commercial E.coli extract
C5 pTet-luxR-pLux-GFP + AHL 1µg Commercial E.coli extract
C7 pTet-luxR-pLux-GFP + AHL (positive control) 2µg Commercial E.coli extract
C9 pTet-luxR-pLux-GFP + AHL (positive control) 2µg Commercial E.coli extract
D4 pTet-luxR-pLux-GFP + AHL 4µg Commercial E.coli extract
D6 pTet-luxR-pLux-GFP + AHL 4µg Commercial E.coli extract
D8 pTet-luxR-pLux-GFP + AHL 6µg Commercial E.coli extract
D10 pTet-luxR-pLux-GFP + AHL 6µg Commercial E.coli extract


Plate 2

Well Test Construct Concentration of DNA In vitro chassis
E5 Nuclease Free Water (Negative control) 0µg Commercial E.coli extract
E7 Nuclease Free Water (Negative control) 0µg Commercial E.coli extract
C3 pTet-GFP 1µg Commercial E.coli extract
C5 pTet-GFP 1µg Commercial E.coli extract
C7 pTet-GFP (positive control) 2µg Commercial E.coli extract
C9 pTet-GFP (positive control) 2µg Commercial E.coli extract
D4 pTet-GFP 4µg Commercial E.coli extract
D6 pTet-GFP 4µg Commercial E.coli extract
D8 pTet-GFP 6µg Commercial E.coli extract
D10 pTet-GFP 6µg Commercial E.coli extract