Team:UCL London/Research/Stresslights/Experiments

From 2011.igem.org

(Difference between revisions)
 
Line 122: Line 122:
# Use 1 ml of the cell sample to take OD (optical density) measurements and use the other 1 ml for centrifugation to pellet the cell and store it at -20 °C
# Use 1 ml of the cell sample to take OD (optical density) measurements and use the other 1 ml for centrifugation to pellet the cell and store it at -20 °C
# Resuspend stored cell pellets in 400 μl of distilled water and load 200 μl of each cell sample on a 96 well for a YFP scan using the Tecan Safire2 microplate reader
# Resuspend stored cell pellets in 400 μl of distilled water and load 200 μl of each cell sample on a 96 well for a YFP scan using the Tecan Safire2 microplate reader
-
# Analyse the fluorescence scans to compare the half-life of the fluorescence proteins  
+
# Analyse the fluorescence scans to compare the half-life of the fluorescence proteins and the sensitivity of theyr assays
 +
[[File:Ucl-content-Stresslightslig.jpg|center]]
</div>
</div>
{{:Team:UCL_London/Template/Footer}}
{{:Team:UCL_London/Template/Footer}}

Latest revision as of 02:07, 22 September 2011

Contents

Modifying Oximeter in the lab

Aim: To modify and improve the oximeter device (BBa_K239011) using modified nark promoter (BBa_K239006) submitted by 2009 UCL iGEM team. Changes included replacing the normal GFP (green fluorescent protein) with an enhanced YFP (yellow fluorescent protein), which has an LVA tag added to its C terminal.

Ucl-content-Oximieter-circuit.jpg

Parts used

Part Name

Parts  ID

Parts Description

Length (bp)

Plasmid Backbone

mNARK promoter

BBa_K239006

promoter sensitive to hypoxia

89

on pUC57 (2710 bp) - ampicillin resistance

RBS

BBa_B0034

ribosome binding site

12

on pSB1A2 (2079 bp) - ampicillin resistance

YFP.LVA

BBa_E0032

enhanced yellow fluorescent protein with LVA tag

759

on pSB1A2 (2079 bp)

Terminator

BBa_B0015

double terminator (B0010-B0012)

129

on pSB1A2 (2079 bp)

pSB1K3

n/a

standard plasmid backbone (kanamycin resistance)

2204

n/a

pSB1T3

n/a

standard plasmid backbone (tetracycline resistance)

2463

n/a

pSB1C3

n/a

standard plasmid backbone (chloramphenicol resistance)

2070

n/a

Procedure for preparing BioBrick

  1. Carried out digestion of the mNARK promoter and YFP.LVA protein on their relevant plasmid backbones with EcoRI and SpeI. Also digested RBS and Terminator on their respective plasmid backbones with XbaI and PstI
  2. Carried out digestion of linearised pSB1K3, pSB1T3, pSB1C3 plasmid backbones with EcoRI and PstI
  3. Performed gel electrophoresis with a sample from all the digestion mixtures to confirm the parts
  4. Carried out ligation of the mNARK, RBS and pSB1K3 plasmid. Also ligated YFP.LVA, terminator and pSB1T3.
  5. Transformed separate stocks of competent TOP10 E. coli cells with the ligation mixtures and grew them overnight on antibiotic plates and then selective LB medium.
  6. Mini-prepped the overnight cultures to extract the plasmids.
  7. Digested the mNark/RBS/pSB1K3 with EcoRI and SpeI. Also digested YFP.LVA/Terminator/pSB1T3 with XbaI and PstI
  8. Performed gel electrophoresis with a sample from both digestion mixtures to confirm the composite parts
  9. Carried out ligation of mNark/RBS, YFP.LVA.TER and pSB1C3
  10. Transformed a stock of competent TOP10 E. coli cells with the ligation mixture and grew the cells overnight on chloramphenicol plates, followed by overnight culture in selective LB medium
  11. Set up a glycerol stock from overnight culture (for storage at -80 °C) and mini-prepped the rest to extract plasmid with the final construct into 50 μl sample
  12. Carried out digestion of mini-prep sample with EcoRI and PstI and performed gel electrophoresis to confirm the length of the final construct on gel
  13. Sent a sample of the mini-prep for sequencing to confirm the final construct
  14. Submitted the improved BioBrick (BBa_K676002) to the registry

Parts submitted to Registry

Part Name

Parts  ID

Parts Description

Length (bp)

Plasmid Backbone

mNARK with YFP.LVA

BBa_K676002

Improved oximeter for detecting hypoxia and express YFP

1014

on pSB1C3 (2070 bp) - chloramphenicol resistance

Characterisation Plan for the new improved Oximeter

Aim: To compare the sensitivity and half-life of fluorescence assays between Oximeter 2.0 (mNark/RBS/YFP.LVA/Terminator on pSB1C3) and Oximeter 1.0 (mNark/RBS/YFP/Terminator on pSB1C3)

  1. Carry out 3A assemblies to construct the Oximeter 1.0 device with wild type YFP (yellow fluorescent protein)
  2. Transform two separate stocks of competent TOP10 E. coli cells with the mini-prep DNA for Oximeter 1.0 and Oximeter 2.0
  3. Prepare glycerol stocks from the overnight cultures of the transformed cells (for storage at -20 °C).
  4. Inoculate 5 ml LB (lysogeny broth) medium (with no antibiotic) from glycerol stocks of both oximeters to prepare two overnight cultures
  5. Use 5 ml LB culture from previous step to inoculate 200 ml of LB media (containing chloramphenicol) and incubate both YFP and YFP.LVA shake flasks at 30°C in an orbital shaker (200 rpm) for 3-4 hours to an OD600 1-3.
  6. Use 20 ml of over-day LB culture to inoculate 200 ml of defined media, (containing chloramphenicol) and incubate at 30 °C for 18-22 hours until OD600 is between 1.5 - 2.0
  7. Transfer the 20 ml culture from shake flask to two bioreactors and add 900 ml of defined medium, followed by 180 μl of polypropylene glycol
  8. Start fermentation immediately with optimal growth conditions according to the bioreactor fermentation protocol
  9. Check initial DOT (dissolved oxygen concentration) and maintain the DOT level AT 100% for the first two hours and then collect the first cell sample (2 ml)
  10. Set DOT level to decrease by 25% every 2 hours for the next 8 hours until DOT reaches 0% (to induce hypoxia) and maintain this DOT
  11. Collect 2 ml samples from both bioreactors at two hours intervals
  12. Use 1 ml of the cell sample to take OD (optical density) measurements and use the other 1 ml for centrifugation to pellet the cell and store it at -20 °C
  13. Resuspend stored cell pellets in 400 μl of distilled water and load 200 μl of each cell sample on a 96 well for a YFP scan using the Tecan Safire2 microplate reader
  14. Analyse the fluorescence scans to compare the half-life of the fluorescence proteins and the sensitivity of theyr assays
Ucl-content-Stresslightslig.jpg