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== Verifying Genomic Integration ==
Back to [[Silver:_Protocols|Protocols]]
*Single colony PCR is used to identify transformants which have the gene of interest integrated at the genomic locus.
*One set of PCR primers is designed to identify whether the prototrophic or auxotrophic allele is at the genomic locus, e.g. Is leu2D1 or wt LEU2 present at the genomic LEU2 locus? The second set of PCR primers is designed to identify whether the Sikowski vector are at the genomic locus, e.g. Are there regions of the Sikowski vector at the LEU2 locus?
# Typically, 3 transformants are screened per desired strain. Re-streak each colony onto the appropriate selection plate.
# Pick a colony at least 2 mm in diameter using a wooden toothpick. Resuspend it into 11 uL Lyse-N-Go (Pierce) in a thick-walled PCR tube. You will need an additional empty PCR tube for each colony.
# Load all the tubes into the PCR machine and run the Lyse N Go PCR protocol.
**65 C for 0.5 min
** 8 C  for 0.5 min
** 65 C for 1.5 min
** 97 C for 3 min
** 8 C  for 1 min
** 65 C for 3 min
** 97 C for 1 min
** 65 C for 1 min
** 80 C forever
# Immediately after the final cycling step, resuspend the lysate with a pipet, and transfer 5 uL of it to the second PCR tube. Do this while both tubes are in the PCR block at 80 C.
# Add 45 uL PCR mix. This is composed of:
**0.125 uL 100 uM forward primer (see table below)
**0.125 uL 100 uM reverse primer (see table below)
**1 uL 10 mM dNTP mix (each dNTP is 10 mM)
**0.5 uL Taq DNA polymerase (Fischer Scientific)
**5 uL 10x Buffer A (Fischer Scientific)
**38.25 uL ddH2O


*<table border=1 align=center>
== Verifying Genomic Integration ==
<tr><td> Sikorski vector </td><td> insert & vector digest </td><td> </tr>
 
<tr><td> pRS304* (TRP1) </td><td>EcoRI, SpeI </td></tr>
=='''Lysing cells and setting up reactions'''==
<tr><td> pRS305 (LEU2) </td><td>XbaI, PstI</td></tr>
*Single colony PCR is used to identify transformants which have the gene of interest integrated at the genomic locus. One set of PCR primers is designed to identify whether the prototrophic or auxotrophic allele is at the genomic locus. In this case, one primer binds to the genomic DNA and the second primer binds to the coding sequence of the auxotrophic gene. The second set of PCR primers is designed to identify whether the Sikorski vector is at the genomic locus. In this case, one primer binds to the genomic DNA and the second primer binds to the Sikorski vector.
<tr><td> pRS306 (URA3) </td><td>EcoRI, SpeI </td></tr>
* Typically, 3 transformants are screened per desired strain. Re-streak each colony onto the appropriate selection plate.
==Lyse-and-go==
* Pick a colony at least 2 mm in diameter using a wooden toothpick. Resuspend it into 11 uL Lyse-N-Go (Pierce) in a thick-walled PCR tube. Transfer 5.5 uL of the mixture into a second PCR tube.
* Load all the tubes into the PCR machine and run the Lyse N Go PCR protocol.<br>
**65 C for 0.5 min
**8 C  for 0.5 min
**65 C for 1.5 min
**97 C for 3 min
**8 C  for 1 min
**65 C for 3 min
**97 C for 1 min
**65 C for 1 min
**80 C forever
* DO NOT remove the tubes from the pcr block for the next step.
* Add 45 uL PCR mix to each tube, while in the pcr block. Pipet up and down to mix. For each colony, you will have two PCR reactions corresponding to the two sets of PCR primers. The PCR mix is composed of:
** 5 uL 10x Thermopol buffer
** 1 uL 10 mM dNTPs
** 0.25 uL 100 uM forward primer
** 0.25 uL 100 uM reverse primer
** 0.5 uL NEB Vent polymerase
** 38 uL water (to 45 uL total)
 
== Zymo ==
*Alternatively you can use the zymolyase/epitaq protocol which usually works better
* Pick a colony at least 2 mm in diameter using a wooden toothpick. Resuspend it into 15 uL Zymolyase in a thick-walled PCR tube.
* Load all the tubes into the PCR machine and run the Zymo protocol.<br>
**37 for 15 minutes
**95 for 5 minutes
**10 forever
* The PCR mix is composed of:
**5 uL 1:5 dilution of lysed cell mix
** 5 uL 10x Eppendorf buffer A
** 1 uL 10 mM dNTPs
** 0.5 uL 100 uM forward primer
** 0.5 uL 100 uM reverse primer
** 0.25 uL NEB EpiTaq polymerase
** 37.75 uL water (to 50 uL total)
 
Zymolyase solution
* Make 2.5mg/ml zymolyase solution in 0.1M Sodium Phosphate buffer pH 7.5
* Mix by inverting, not all will go into solution
* Spin down and aliquot supernatant for storage at -20C
 
=='''PCR'''==
*Primer sets for each locus:
<table border=1 align=center>
<tr><td> Sikorski vector to be integrated </td><td> allele primers (positive) </td><td> vector primers (negative)</td></tr>
<tr><td> pRS304*(TRP1) </td><td>DL11, DL17</td><td>DL11, DL22</td></tr>
<tr><td> pRS305 (LEU2)</td><td>DL28, DL29</td><td>DL28, DL30</td></tr>
<tr><td> pRS306 (URA3)</td><td>IP108, IP111</td><td>IP108, DL18</td></tr>
</table>
 
* Run the following PCR cycle:
** 95C for 2 min
** 95C for 30s
** 53C for 30s
** 72C for (URA = 1:00; TRP = 1:30, LEU = 2:00)
** repeat 35 times
** 8C forever
 
* Run the PCR products on an agarose gel. Since the bands are typically rather faint, pour the gel as thick as possible, and load 35 uL PCR + dye in the 5 mm-wide lanes.
* Use the following table to determine whether the integration was successful.
 
<table border=1 align=center>
<tr><td rowspan=2>gene at locus </td><td colspan=2 align=center><b>pcr product size</b></td></tr>
<tr><td>allele primers </td><td> vector primers </td></tr>
<tr><td> TRP1 </td><td>435</td><td>1031</td></tr>
<tr><td> trpD63</td><td>none</td><td>none</td></tr>
<tr><td> LEU2</td><td>1168</td><td>1464</td></tr>
<tr><td> leu2D1</td><td>none</td><td>979</td></tr>
<tr><td> URA3</td><td>670</td><td>none</td></tr>
<tr><td> ura3-52</td><td>699</td><td>651</td></tr>
</table>
</table>
* Thaw competent cells (TOP10 from Invitrogen) on ice.
 
# Place 10-15 µL cells in pre-chilled Eppendorf tubes.
== Primer Sequences ==
# Add 2 µL BioBrick vector (either native or ligated; so that vector is ~10-20% of the final volume), and chill on ice for 30 min.
*DL11: 5'- AGA CCA ATC AGT AAA AAT CAA CGG -3'
#*Do not pipet or vortex.
*DL17: 5'- TCT ATT GGG CAC ACA TAT AAT ACC C -3'
# Heat shock at 42 °C for 30 s.
*DL22: 5'- TCT CCT TAC GCA TCT GTG CGG -3'
# Incubate on ice for 2 min.
 
# Add 170 µL SOC medium (~10 x volume; Invitrogen), and shake at 37 °C for 15 min for Amp selection, or 30 min for Kan selection.
*DL28: 5'- AAA CGC AAG GAT TGA TAA TGT AAT AGG -3'
# Add all media to a selectable marker LB plate. Use glass beads to streak the plate.
*DL29: 5'- ACA ACA ACG AAG TCA GTA CCT TTA GC -3'
# Incubate at 37 °C.  Transformants should appear within 12 hrs.
*DL30: 5'- TCT TAA CTA GGA TCA TGG CGG C -3'
 
*DL18: 5'- AAA TAT GTG AAT GTT GAG ATA ATT GTT GG -3'
*IP108: 5'- GGC AAC GGT TCA TCA TCT CAT GG -3'
*IP111: 5'- GGG ACC TAA TGC TTC AAC TAA CTC C -3'
 
== Archiving Yeast Strains ==
* Inoculate YEP media with a single yeast colony.
* Grow overnight at 30C in a roller drum.
* Mix 50% glycerol and yeast culture in a 2 mL screw-top vial to give a final glycerol concentration of 15%(v/v), e.g. 300 uL 50% glycerol and 700 uL yeast culture.

Latest revision as of 12:49, 29 February 2008

Back to Protocols

Verifying Genomic Integration

Lysing cells and setting up reactions

  • Single colony PCR is used to identify transformants which have the gene of interest integrated at the genomic locus. One set of PCR primers is designed to identify whether the prototrophic or auxotrophic allele is at the genomic locus. In this case, one primer binds to the genomic DNA and the second primer binds to the coding sequence of the auxotrophic gene. The second set of PCR primers is designed to identify whether the Sikorski vector is at the genomic locus. In this case, one primer binds to the genomic DNA and the second primer binds to the Sikorski vector.
  • Typically, 3 transformants are screened per desired strain. Re-streak each colony onto the appropriate selection plate.

Lyse-and-go

  • Pick a colony at least 2 mm in diameter using a wooden toothpick. Resuspend it into 11 uL Lyse-N-Go (Pierce) in a thick-walled PCR tube. Transfer 5.5 uL of the mixture into a second PCR tube.
  • Load all the tubes into the PCR machine and run the Lyse N Go PCR protocol.
    • 65 C for 0.5 min
    • 8 C for 0.5 min
    • 65 C for 1.5 min
    • 97 C for 3 min
    • 8 C for 1 min
    • 65 C for 3 min
    • 97 C for 1 min
    • 65 C for 1 min
    • 80 C forever
  • DO NOT remove the tubes from the pcr block for the next step.
  • Add 45 uL PCR mix to each tube, while in the pcr block. Pipet up and down to mix. For each colony, you will have two PCR reactions corresponding to the two sets of PCR primers. The PCR mix is composed of:
    • 5 uL 10x Thermopol buffer
    • 1 uL 10 mM dNTPs
    • 0.25 uL 100 uM forward primer
    • 0.25 uL 100 uM reverse primer
    • 0.5 uL NEB Vent polymerase
    • 38 uL water (to 45 uL total)

Zymo

  • Alternatively you can use the zymolyase/epitaq protocol which usually works better
  • Pick a colony at least 2 mm in diameter using a wooden toothpick. Resuspend it into 15 uL Zymolyase in a thick-walled PCR tube.
  • Load all the tubes into the PCR machine and run the Zymo protocol.
    • 37 for 15 minutes
    • 95 for 5 minutes
    • 10 forever
  • The PCR mix is composed of:
    • 5 uL 1:5 dilution of lysed cell mix
    • 5 uL 10x Eppendorf buffer A
    • 1 uL 10 mM dNTPs
    • 0.5 uL 100 uM forward primer
    • 0.5 uL 100 uM reverse primer
    • 0.25 uL NEB EpiTaq polymerase
    • 37.75 uL water (to 50 uL total)

Zymolyase solution

  • Make 2.5mg/ml zymolyase solution in 0.1M Sodium Phosphate buffer pH 7.5
  • Mix by inverting, not all will go into solution
  • Spin down and aliquot supernatant for storage at -20C

PCR

  • Primer sets for each locus:
Sikorski vector to be integrated allele primers (positive) vector primers (negative)
pRS304*(TRP1) DL11, DL17DL11, DL22
pRS305 (LEU2)DL28, DL29DL28, DL30
pRS306 (URA3)IP108, IP111IP108, DL18
  • Run the following PCR cycle:
    • 95C for 2 min
    • 95C for 30s
    • 53C for 30s
    • 72C for (URA = 1:00; TRP = 1:30, LEU = 2:00)
    • repeat 35 times
    • 8C forever
  • Run the PCR products on an agarose gel. Since the bands are typically rather faint, pour the gel as thick as possible, and load 35 uL PCR + dye in the 5 mm-wide lanes.
  • Use the following table to determine whether the integration was successful.
gene at locus pcr product size
allele primers vector primers
TRP1 4351031
trpD63nonenone
LEU211681464
leu2D1none979
URA3670none
ura3-52699651

Primer Sequences

  • DL11: 5'- AGA CCA ATC AGT AAA AAT CAA CGG -3'
  • DL17: 5'- TCT ATT GGG CAC ACA TAT AAT ACC C -3'
  • DL22: 5'- TCT CCT TAC GCA TCT GTG CGG -3'
  • DL28: 5'- AAA CGC AAG GAT TGA TAA TGT AAT AGG -3'
  • DL29: 5'- ACA ACA ACG AAG TCA GTA CCT TTA GC -3'
  • DL30: 5'- TCT TAA CTA GGA TCA TGG CGG C -3'
  • DL18: 5'- AAA TAT GTG AAT GTT GAG ATA ATT GTT GG -3'
  • IP108: 5'- GGC AAC GGT TCA TCA TCT CAT GG -3'
  • IP111: 5'- GGG ACC TAA TGC TTC AAC TAA CTC C -3'

Archiving Yeast Strains

  • Inoculate YEP media with a single yeast colony.
  • Grow overnight at 30C in a roller drum.
  • Mix 50% glycerol and yeast culture in a 2 mL screw-top vial to give a final glycerol concentration of 15%(v/v), e.g. 300 uL 50% glycerol and 700 uL yeast culture.
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