20.109(F08): Mod 2 Day 3 Colony PCR and journal article discussion: Difference between revisions

Introduction

To begin today’s experiment, you will “pop” some trp+ yeast from your transformation plates and then amplify the relevant portion of the released genomic DNA. The primers you will use are expected to give a ~554 base pair product only if the TAP tag is fused to the 3' region of the gene you have tried to modify.

This is accomplished by using a forward primer to the very C-terminal sequence of the gene you're modifying and a reverse primer that anneals to a region within the TAP gene sequence. If the TAP tag is fused elsewhere in the genome (giving rise to the trp+ phenotype) but the SAGA- or SAGA-controlled gene remains intact, then you will see no product from this reaction. Note, however, that a negative result from these reactions (i.e. no PCR product) can just as easily be explained as a failed PCR (bad primers, dead enzyme, wrong reaction conditions, etc), and might incorrectly lead you to toss out perfectly correct samples. Only the positive result is meaningful in this experiment and we will not know the result until you see the results of the agarose gel. However, we will remain optimistic and set up overnight cultures of both the candidates you are examining today. In this way you will have cells to examine next time, when you will check them for the TAP-tag by Western blot and when you will isolate total RNA from them for microarray analysis.

Protocols

Part 1: Colony PCR

1. Begin by counting the colonies that arose from the transformation experiment you performed last time. Choose two candidates (when possible) to pursue, circling the colonies on the back of the petri dish and clearly labeling them "A," and "B."If you do not have enough colonies, don't despair. You can get some additional ones from another group or from the teaching faculty. Note, however, that by doing so, you may be switching the gene you'll study for the rest of the module, and you will have to rethink the work you have planned so far. And if applicable, it will be worth noting the "negative" result in the research article you write, since it may indicate that despite the gene being deemed non-essential, cells may fair less well than wild-type cells when the gene is modified and so modified forms may be difficult to isolate.
2. You will use the microwave to release the DNA from the yeast. On the tip of a sterile toothpick, pick-up 1/2 of the colony that is candidate "A" and swirl the cells in 20 μl of sterile water in an eppendorf tube. Be sure to label the tube so you know it belongs to your group and which candidate it contains. Repeat with the second candidate you've selected as well as with the parental strain, NY411 and a positive control strain for this part of the experiment, either NY412 (same as NY411 but SPT3-TAP tagged) or NY413 (same as NY411 but SPT7-TAP tagged). The teaching faculty will have the control strains streaked out on petri dishes. You should mix 1/2 of a colony from these plate with 20 μl of sterile water as you did for your candidate colonies.
3. Close the caps to the four tubes and microwave them in an eppendorf rack for 15 seconds.
4. Move 2.5 μl of the microwaved mixes, yeast debris and all, into a 200 μl PCR tube. Again label your tubes well (write small!).
5. Prepare your positive control PCR. This reaction will include
   • 2.5 μl microwaved cells from NY413 or NY414
   • 10 μl 2.5X PCR mastermix
   • 0.5 μl forward primer NO258 or NO 259, specific to SPT3 or SPT7 respectively
   • 0.5 μl universal reverse primer NO225, specific for TAP-TRP sequence
   • water to a final volume of 25 μl.
6. Prepare your experimental PCR. These are best performed with a reaction cocktail that contains the reagents common to all 3 reactions. In a new eppendorf tube (normal size this time), prepare a PCR cocktail enough for 4 reactions. Each reaction will include:
   • 10 μl 2.5X PCR mastermix
   • 0.5 μl forward primer specific to your gene of interest
   • 0.5 μl universal reverse primer NO225, specific for TAP-TRP sequence
   • water to a final volume of 22.5 μl.
7. Add 22.5 μl of PCR cocktail to each PCR tube with yeast and leave the tubes chilling until everyone is ready.
8. Cycle the reactions as:
   • 95° 4 minutes
   • 95° 1 minute
   • 58° 1 minute
   • 72° 1 minute
   • repeat steps 2-4 35 times
   • 72° 10 minutes
   • 4° forever

Part 2: Overnight cultures

1. Using sterile technique, aliquot 3 ml of YPD into four sterile test tubes.
2. Label the caps with your team color, and either "parent" "+control" "A" or "B."
3. Use sterile dowels to move the second 1/2 of each yeast colony from your transformation plates to the media. Swirl the dowel to remove the yeast from the stick and vortex the solution to fully resuspend them.
4. Use a sterile dowel to innoculate the "parent" and "+control" cultures, using the NY411 and NY412 or NY413 plates that the teaching faculty have prepared.
5. Leave your tubes with the teaching faculty who will place them on the roller drum in the 30° incubator. The cultures will grow for 24 hours and then be placed in the 4° fridge until next lab.
6. When everyone is ready we will discuss the journal article that was assigned for today.

Part 3: Journal article discussion

As part of your assignment for today, you have read the relevant article by Wu et al, published in Mol Cell in 2004. There is also an associated review article PMID: 15653319 that was written to celebrate and highlight this important work on the structure of the SAGA complex. You and your partner will be randomly assigned a portion of the text to describe to the class but be prepared to engage in conversation about other parts of this paper even if you're not "assigned" to the section being discussed.

DONE!

For next time

1. Prepare a table with your transformation results. Include a legend for the table. This legend should have a number, title and description of the table similar to the tables you might find in a scientific publication. Ideally this homework assignment will be included in the research article you'll hand in a few weeks from now.
2. You are not required to hand in a revised Materials and Methods section, but consider adding the experiment you performed today to the assignment from last time.
3. Sign up for one of the two Journal Club presentations days here. We must split the class evenly between the two available days. First come first served. You do not have to select a paper to present yet (unless you want to!).

Reagents list

• YPD
  • 10g yeast extract
  • 20g peptone
  • 20g glucose
  • 20g agar (for liquid media, leave agar out!)
  • add 1L water, autoclave 20min, stir to cool
• PCR reaction mix
• Primers
  • Universal reverse primer
    • NO225 TCA GGT TGA CTT CCC CGC GGA ATT CGC GTC TAC
    • use with fwd primer from tagging PCR or positive control primers NO258 or NO259
    • expect length of TAP seq + TRP K. l seq = 554 bps (from 2147 to 2701 in pBS1479)
    • Tm = 68
  • Other TAP-tagging primers specific to gene of interest, see reagents, Day 1
  • Positive control primers
    • NO258 for SPT3-TAP strain NY412, TTT AAA GGT GGT AGA CTC AGT TCT AAA CCA ATT ATC ATG tcc atg gaa aag aga aga tg
    • NO259 for SPT7-TAP strain NY413, AAT AGT TCA TTT AGC TTG AGC CTT CCT CGC CTT AAT CAA tcc atg gaa aag aga aga tg
    • NO260 = SPT3_fwd, GCT TTG ACC AAC TTT AAA GGT GGT AGA CTC AGT TCT AAA CCA ATT ATC ATG TAA, Tm = 64
    • NO261 = SPT7_fwd, TAC CAA TAT GGG CAG CAA TAG TTC ATT TAG CTT GAG CCT TCC TCG CCT TAA TCA ATA A, Tm = 67
  • Experimental primers for checking TAP tag
    • NO262 = SGF73_fwd, ATT GAA GTA GGT ATT GGA AAT TCT GTG AAC CCC TAC AAT GGC AGA ATA AAT TAA, Tm = 64
    • NO263 = SGF29_fwd, GCC TTC GCC AAC GGC TTT GGC AAA CCT AGC AAG GAA ATA G, Tm = 68
    • NO264 = SGF11_fwd, ACT AGC AGC TCA TTT ACA GAG ATG TTT GAG TAG GGG TGC TAG ACG TTG A , Tm = 67
    • NO265 = UBP8_fwd, GGT TTT AAA GGA ACA GGC ATA TTT ATT ATT CTA CAC CAT TCG TCA AGT AAA TTG A, Tm = 63
    • NO266 = SUS1_fwd, GGG AAA CCG TTT TAA AGC AAA TAA GGG AAT TTC TTG AAG AGA TTG TAG ATA CAC AAT GA, Tm = 65
    • NO277 = RNT1_fwd, GAT CCC TCA CAA AAG AAT AAG AAA AGA AAA TTC TCA GAT ACA AGC TGA, Tm = 62