Team:Caltech/Week 2

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Contents

Monday 6/21

  • Transformed additional bricks from distribution with other antibiotic resistances onto plates & liquid culture.
    • [http://partsregistry.org/wiki/index.php?title=Part:BBa_I15008 I15008], [http://partsregistry.org/wiki/index.php?title=Part:BBa_I15009 I15009], [http://partsregistry.org/wiki/index.php?title=Part:BBa_I15010 I15010], [http://partsregistry.org/wiki/index.php?title=Part:BBa_E0033 E0033], [http://partsregistry.org/wiki/index.php?title=Part:BBa_M30109 M30109], [http://partsregistry.org/wiki/index.php?title=Part:BBa_K112000 K112000], [http://partsregistry.org/wiki/index.php?title=Part:BBa_J09250 J09250]

Tuesday 6/22

  • Transformation success is ambiguous - the plates are covered in a lawn of bacteria, apparently indicating an issue with the antibiotic selection. This implies either a problem with the stock solution of antibiotic (Kan/Strep), or the procedure of plating the antibiotics on the surface of the LB-agar plates.
    • To find out what happened, we set up a simple experiment for both ampicillin (amp) and streptomyocin (strep):
Take 3 LB-agar plates with no antibiotic and plate 50uL of 1000x, 10x, or 2x antibiotic stock solution on each, spreading with sterile glass beads. Let the plates dry for 1 hour at RT. Additionally, prepare an LB-agar plate containing the desired antibiotic in the agar. Split all four plates in half and streak each plate with both a cell strain that should be resistant to your antibiotic, as well as a strain the should not be. Incubate the plates overnight at 37C.
If the antibiotic was prepared correctly, and is present in high enough concentration on the plate, only half of the plate should have any colonies present: the side with the desired resistance. Plates with cells on both sides do not have enough antibiotic; those with no cells have too much.
  • Re-performed the transformations on two of the bricks & plated on LB-agar plates with the antibiotic incorporated.

Wednesday 6/23

  • Transformation plates are still covered in a film of bacteria. The negative control for the kanamycin test grew bacteria, suggesting that there is an issue with the kanamycin stock, which we will have to remake.
  • The amp & strep antibiotic test plates indicate that plating 50uL of 1000x stock is sufficient for proper bacterial selection:

Thursday 6/24

  • Our NEB Biobrick assembly kit arrived today! We began digesting & ligating bricks to assemble our light induction/lysis construct.
    • Desired construct: R0082 (light-induced promoter) + B0034 (RBS) + K124017 (lysis gene cassette) + B0015 (terminator) in a non-amp/non-cm backbone (since our light transduction brick, M30109, is A/C resistant).
    • Began five digests according to the NEB Biobrick assembly kit protocol:
      • R0082 (us)
      • B0034 (ds)
      • K124017 (us)
      • B0015 (ds)
      • Cm linear backbone (pSB1C3)
    • Began two ligation reactions according to the Biobrick assembly kit protocol:
      • R0082/B0034/pSB1C3
      • K124017/B0015/pSB1C3
    • Transformed the ligation products into DH5alpha (Invitrogen) competent cells via heat shock and plated (incorrectly) on LB-amp plates.
    • Set up antibiotic test plates for kanamycin (kan) & tetracycline (tet), just as on 6/22.

Friday 6/25

  • Re-transformed the ligation products from 6/24 into DH5alpha cells via heat shock and both: plated 100uL of cells on LB-cm plates and added remainder to create LB-cm liquid culture. Both were incubated overnight at 37C.
  • Checked kan/tet antibiotic test plates: again, plating 50uL of 1000x stock antibiotic appears to be adequate for proper selection. Unfortunately, the XL1 Blue cells we used last week do not appear to actually be tet-resistant (as advertised).
  • Designed forward & reverse sequencing primers, using the sequences of G00100 & G00101, which bind to the standard prefix & suffix of the provided plasmid backbone. Note: according to the IDT primer analysis page, the forward primer creates a strong (~9kcal/mol) homodimer, which melts at about the primer melting temp of 55C (according to NUPACK.org analysis). We decided to take a chance and order the G00100 provided sequence since it is specified by the Registry (and therefore hopefully works), even though a better primer could conceivably have been designed (which would probably require different forward primers for each different plasmid). Placed the order for these primers with IDT today.

Weekend 6/26-27

  • Mini-prepped the transformation liquid cultures of the ligation products from 6/25 to extract the plasmid DNA. The pBAD18 positive control contained > 500 colonies (while the pBAD cells in the LB-cm liquid culture did not grow, as expected). Each of the LB-cm agar plates contained 3 colonies, indicating that we should transform > 1uL of ligation DNA in future transformations or change the ligation reaction concentrations.
Concentration (ng/uL) A260/A280
75.5 2.013
86.0 1.955
  • Began 3 digestions on the miniprepped DNA:
    • Ligation prod 1 (promoter + RBS, us)
    • Ligation prod 2 (lysis gene cassette + terminator, ds)
    • Linear backbone, tet resistant (pSB1T3)
  • Began a ligation reaction using 4uL of digest DNA and 2uL backbone digest DNA (20uL total):
    • LigProd1/LigProd2/pSB1T3
  • Transformed the ligation product into DH5alpha cells via heat shock (2uL ligation product, 1uL pBAD18 positive control DNA in 20uL aliquots of competent cells).
    • Plated 100uL of ligation product cells on an LB-tet agar plate, 100uL of pBAD control cells on LB-amp agar.
    • Transferred remainder of cells of each into 5mL LB-tet liquid culture.
    • Incubated all overnight at 37C.
 
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